This is doc/g77.info, produced by makeinfo version 4.2 from ../../gcc/gcc/f/g77.texi. Copyright (C) 1995,1996,1997,1998,1999,2000,2001,2002,2003,2004 Free Software Foundation, Inc. Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with the Invariant Sections being "GNU General Public License" and "Funding Free Software", the Front-Cover texts being (a) (see below), and with the Back-Cover Texts being (b) (see below). A copy of the license is included in the section entitled "GNU Free Documentation License". (a) The FSF's Front-Cover Text is: A GNU Manual (b) The FSF's Back-Cover Text is: You have freedom to copy and modify this GNU Manual, like GNU software. Copies published by the Free Software Foundation raise funds for GNU development. INFO-DIR-SECTION Programming START-INFO-DIR-ENTRY * g77: (g77). The GNU Fortran compiler. END-INFO-DIR-ENTRY This file documents the use and the internals of the GNU Fortran (`g77') compiler. It corresponds to the GCC-3.4.2 version of `g77'. Published by the Free Software Foundation 59 Temple Place - Suite 330 Boston, MA 02111-1307 USA Copyright (C) 1995,1996,1997,1998,1999,2000,2001,2002,2003,2004 Free Software Foundation, Inc. Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with the Invariant Sections being "GNU General Public License" and "Funding Free Software", the Front-Cover texts being (a) (see below), and with the Back-Cover Texts being (b) (see below). A copy of the license is included in the section entitled "GNU Free Documentation License". (a) The FSF's Front-Cover Text is: A GNU Manual (b) The FSF's Back-Cover Text is: You have freedom to copy and modify this GNU Manual, like GNU software. Copies published by the Free Software Foundation raise funds for GNU development. Contributed by James Craig Burley (). Inspired by a first pass at translating `g77-0.5.16/f/DOC' that was contributed to Craig by David Ronis ().  File: g77.info, Node: Top, Next: Copying, Up: (DIR) Introduction ************ This manual documents how to run, install and port `g77', as well as its new features and incompatibilities, and how to report bugs. It corresponds to the GCC-3.4.2 version of `g77'. * Menu: * Copying:: GNU General Public License says how you can copy and share GNU Fortran. * GNU Free Documentation License:: How you can copy and share this manual. * Contributors:: People who have contributed to GNU Fortran. * Funding:: How to help assure continued work for free software. * Funding GNU Fortran:: How to help assure continued work on GNU Fortran. * Getting Started:: Finding your way around this manual. * What is GNU Fortran?:: How `g77' fits into the universe. * G77 and GCC:: You can compile Fortran, C, or other programs. * Invoking G77:: Command options supported by `g77'. * News:: News about recent releases of `g77'. * Changes:: User-visible changes to recent releases of `g77'. * Language:: The GNU Fortran language. * Compiler:: The GNU Fortran compiler. * Other Dialects:: Dialects of Fortran supported by `g77'. * Other Compilers:: Fortran compilers other than `g77'. * Other Languages:: Languages other than Fortran. * Debugging and Interfacing:: How `g77' generates code. * Collected Fortran Wisdom:: How to avoid Trouble. * Trouble:: If you have trouble with GNU Fortran. * Open Questions:: Things we'd like to know. * Bugs:: How, why, and where to report bugs. * Service:: How to find suppliers of support for GNU Fortran. * Adding Options:: Guidance on teaching `g77' about new options. * Projects:: Projects for `g77' internals hackers. * Front End:: Design and implementation of the `g77' front end. * M: Diagnostics. Diagnostics produced by `g77'. * Keyword Index:: Index of concepts and symbol names.  File: g77.info, Node: Copying, Next: GNU Free Documentation License, Prev: Top, Up: Top GNU GENERAL PUBLIC LICENSE ************************** Version 2, June 1991 Copyright (C) 1989, 1991 Free Software Foundation, Inc. 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA Everyone is permitted to copy and distribute verbatim copies of this license document, but changing it is not allowed. Preamble ======== The licenses for most software are designed to take away your freedom to share and change it. By contrast, the GNU General Public License is intended to guarantee your freedom to share and change free software--to make sure the software is free for all its users. This General Public License applies to most of the Free Software Foundation's software and to any other program whose authors commit to using it. (Some other Free Software Foundation software is covered by the GNU Library General Public License instead.) You can apply it to your programs, too. When we speak of free software, we are referring to freedom, not price. Our General Public Licenses are designed to make sure that you have the freedom to distribute copies of free software (and charge for this service if you wish), that you receive source code or can get it if you want it, that you can change the software or use pieces of it in new free programs; and that you know you can do these things. To protect your rights, we need to make restrictions that forbid anyone to deny you these rights or to ask you to surrender the rights. These restrictions translate to certain responsibilities for you if you distribute copies of the software, or if you modify it. For example, if you distribute copies of such a program, whether gratis or for a fee, you must give the recipients all the rights that you have. You must make sure that they, too, receive or can get the source code. And you must show them these terms so they know their rights. We protect your rights with two steps: (1) copyright the software, and (2) offer you this license which gives you legal permission to copy, distribute and/or modify the software. Also, for each author's protection and ours, we want to make certain that everyone understands that there is no warranty for this free software. If the software is modified by someone else and passed on, we want its recipients to know that what they have is not the original, so that any problems introduced by others will not reflect on the original authors' reputations. Finally, any free program is threatened constantly by software patents. We wish to avoid the danger that redistributors of a free program will individually obtain patent licenses, in effect making the program proprietary. To prevent this, we have made it clear that any patent must be licensed for everyone's free use or not licensed at all. The precise terms and conditions for copying, distribution and modification follow. TERMS AND CONDITIONS FOR COPYING, DISTRIBUTION AND MODIFICATION 0. This License applies to any program or other work which contains a notice placed by the copyright holder saying it may be distributed under the terms of this General Public License. The "Program", below, refers to any such program or work, and a "work based on the Program" means either the Program or any derivative work under copyright law: that is to say, a work containing the Program or a portion of it, either verbatim or with modifications and/or translated into another language. (Hereinafter, translation is included without limitation in the term "modification".) Each licensee is addressed as "you". Activities other than copying, distribution and modification are not covered by this License; they are outside its scope. The act of running the Program is not restricted, and the output from the Program is covered only if its contents constitute a work based on the Program (independent of having been made by running the Program). Whether that is true depends on what the Program does. 1. You may copy and distribute verbatim copies of the Program's source code as you receive it, in any medium, provided that you conspicuously and appropriately publish on each copy an appropriate copyright notice and disclaimer of warranty; keep intact all the notices that refer to this License and to the absence of any warranty; and give any other recipients of the Program a copy of this License along with the Program. You may charge a fee for the physical act of transferring a copy, and you may at your option offer warranty protection in exchange for a fee. 2. You may modify your copy or copies of the Program or any portion of it, thus forming a work based on the Program, and copy and distribute such modifications or work under the terms of Section 1 above, provided that you also meet all of these conditions: a. You must cause the modified files to carry prominent notices stating that you changed the files and the date of any change. b. You must cause any work that you distribute or publish, that in whole or in part contains or is derived from the Program or any part thereof, to be licensed as a whole at no charge to all third parties under the terms of this License. c. If the modified program normally reads commands interactively when run, you must cause it, when started running for such interactive use in the most ordinary way, to print or display an announcement including an appropriate copyright notice and a notice that there is no warranty (or else, saying that you provide a warranty) and that users may redistribute the program under these conditions, and telling the user how to view a copy of this License. (Exception: if the Program itself is interactive but does not normally print such an announcement, your work based on the Program is not required to print an announcement.) These requirements apply to the modified work as a whole. If identifiable sections of that work are not derived from the Program, and can be reasonably considered independent and separate works in themselves, then this License, and its terms, do not apply to those sections when you distribute them as separate works. But when you distribute the same sections as part of a whole which is a work based on the Program, the distribution of the whole must be on the terms of this License, whose permissions for other licensees extend to the entire whole, and thus to each and every part regardless of who wrote it. Thus, it is not the intent of this section to claim rights or contest your rights to work written entirely by you; rather, the intent is to exercise the right to control the distribution of derivative or collective works based on the Program. In addition, mere aggregation of another work not based on the Program with the Program (or with a work based on the Program) on a volume of a storage or distribution medium does not bring the other work under the scope of this License. 3. You may copy and distribute the Program (or a work based on it, under Section 2) in object code or executable form under the terms of Sections 1 and 2 above provided that you also do one of the following: a. Accompany it with the complete corresponding machine-readable source code, which must be distributed under the terms of Sections 1 and 2 above on a medium customarily used for software interchange; or, b. Accompany it with a written offer, valid for at least three years, to give any third party, for a charge no more than your cost of physically performing source distribution, a complete machine-readable copy of the corresponding source code, to be distributed under the terms of Sections 1 and 2 above on a medium customarily used for software interchange; or, c. Accompany it with the information you received as to the offer to distribute corresponding source code. (This alternative is allowed only for noncommercial distribution and only if you received the program in object code or executable form with such an offer, in accord with Subsection b above.) The source code for a work means the preferred form of the work for making modifications to it. For an executable work, complete source code means all the source code for all modules it contains, plus any associated interface definition files, plus the scripts used to control compilation and installation of the executable. However, as a special exception, the source code distributed need not include anything that is normally distributed (in either source or binary form) with the major components (compiler, kernel, and so on) of the operating system on which the executable runs, unless that component itself accompanies the executable. If distribution of executable or object code is made by offering access to copy from a designated place, then offering equivalent access to copy the source code from the same place counts as distribution of the source code, even though third parties are not compelled to copy the source along with the object code. 4. You may not copy, modify, sublicense, or distribute the Program except as expressly provided under this License. Any attempt otherwise to copy, modify, sublicense or distribute the Program is void, and will automatically terminate your rights under this License. However, parties who have received copies, or rights, from you under this License will not have their licenses terminated so long as such parties remain in full compliance. 5. You are not required to accept this License, since you have not signed it. However, nothing else grants you permission to modify or distribute the Program or its derivative works. These actions are prohibited by law if you do not accept this License. Therefore, by modifying or distributing the Program (or any work based on the Program), you indicate your acceptance of this License to do so, and all its terms and conditions for copying, distributing or modifying the Program or works based on it. 6. 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For example, if a patent license would not permit royalty-free redistribution of the Program by all those who receive copies directly or indirectly through you, then the only way you could satisfy both it and this License would be to refrain entirely from distribution of the Program. If any portion of this section is held invalid or unenforceable under any particular circumstance, the balance of the section is intended to apply and the section as a whole is intended to apply in other circumstances. It is not the purpose of this section to induce you to infringe any patents or other property right claims or to contest validity of any such claims; this section has the sole purpose of protecting the integrity of the free software distribution system, which is implemented by public license practices. Many people have made generous contributions to the wide range of software distributed through that system in reliance on consistent application of that system; it is up to the author/donor to decide if he or she is willing to distribute software through any other system and a licensee cannot impose that choice. This section is intended to make thoroughly clear what is believed to be a consequence of the rest of this License. 8. If the distribution and/or use of the Program is restricted in certain countries either by patents or by copyrighted interfaces, the original copyright holder who places the Program under this License may add an explicit geographical distribution limitation excluding those countries, so that distribution is permitted only in or among countries not thus excluded. In such case, this License incorporates the limitation as if written in the body of this License. 9. The Free Software Foundation may publish revised and/or new versions of the General Public License from time to time. Such new versions will be similar in spirit to the present version, but may differ in detail to address new problems or concerns. Each version is given a distinguishing version number. If the Program specifies a version number of this License which applies to it and "any later version", you have the option of following the terms and conditions either of that version or of any later version published by the Free Software Foundation. If the Program does not specify a version number of this License, you may choose any version ever published by the Free Software Foundation. 10. If you wish to incorporate parts of the Program into other free programs whose distribution conditions are different, write to the author to ask for permission. For software which is copyrighted by the Free Software Foundation, write to the Free Software Foundation; we sometimes make exceptions for this. Our decision will be guided by the two goals of preserving the free status of all derivatives of our free software and of promoting the sharing and reuse of software generally. NO WARRANTY 11. BECAUSE THE PROGRAM IS LICENSED FREE OF CHARGE, THERE IS NO WARRANTY FOR THE PROGRAM, TO THE EXTENT PERMITTED BY APPLICABLE LAW. EXCEPT WHEN OTHERWISE STATED IN WRITING THE COPYRIGHT HOLDERS AND/OR OTHER PARTIES PROVIDE THE PROGRAM "AS IS" WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE PROGRAM IS WITH YOU. SHOULD THE PROGRAM PROVE DEFECTIVE, YOU ASSUME THE COST OF ALL NECESSARY SERVICING, REPAIR OR CORRECTION. 12. IN NO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN WRITING WILL ANY COPYRIGHT HOLDER, OR ANY OTHER PARTY WHO MAY MODIFY AND/OR REDISTRIBUTE THE PROGRAM AS PERMITTED ABOVE, BE LIABLE TO YOU FOR DAMAGES, INCLUDING ANY GENERAL, SPECIAL, INCIDENTAL OR CONSEQUENTIAL DAMAGES ARISING OUT OF THE USE OR INABILITY TO USE THE PROGRAM (INCLUDING BUT NOT LIMITED TO LOSS OF DATA OR DATA BEING RENDERED INACCURATE OR LOSSES SUSTAINED BY YOU OR THIRD PARTIES OR A FAILURE OF THE PROGRAM TO OPERATE WITH ANY OTHER PROGRAMS), EVEN IF SUCH HOLDER OR OTHER PARTY HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. END OF TERMS AND CONDITIONS How to Apply These Terms to Your New Programs ============================================= If you develop a new program, and you want it to be of the greatest possible use to the public, the best way to achieve this is to make it free software which everyone can redistribute and change under these terms. To do so, attach the following notices to the program. It is safest to attach them to the start of each source file to most effectively convey the exclusion of warranty; and each file should have at least the "copyright" line and a pointer to where the full notice is found. ONE LINE TO GIVE THE PROGRAM'S NAME AND A BRIEF IDEA OF WHAT IT DOES. Copyright (C) YEAR NAME OF AUTHOR This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. Also add information on how to contact you by electronic and paper mail. If the program is interactive, make it output a short notice like this when it starts in an interactive mode: Gnomovision version 69, Copyright (C) YEAR NAME OF AUTHOR Gnomovision comes with ABSOLUTELY NO WARRANTY; for details type `show w'. This is free software, and you are welcome to redistribute it under certain conditions; type `show c' for details. The hypothetical commands `show w' and `show c' should show the appropriate parts of the General Public License. Of course, the commands you use may be called something other than `show w' and `show c'; they could even be mouse-clicks or menu items--whatever suits your program. You should also get your employer (if you work as a programmer) or your school, if any, to sign a "copyright disclaimer" for the program, if necessary. Here is a sample; alter the names: Yoyodyne, Inc., hereby disclaims all copyright interest in the program `Gnomovision' (which makes passes at compilers) written by James Hacker. SIGNATURE OF TY COON, 1 April 1989 Ty Coon, President of Vice This General Public License does not permit incorporating your program into proprietary programs. If your program is a subroutine library, you may consider it more useful to permit linking proprietary applications with the library. If this is what you want to do, use the GNU Library General Public License instead of this License.  File: g77.info, Node: GNU Free Documentation License, Next: Contributors, Prev: Copying, Up: Top GNU Free Documentation License ****************************** Version 1.2, November 2002 Copyright (C) 2000,2001,2002 Free Software Foundation, Inc. 59 Temple Place, Suite 330, Boston, MA 02111-1307, USA Everyone is permitted to copy and distribute verbatim copies of this license document, but changing it is not allowed. 0. PREAMBLE The purpose of this License is to make a manual, textbook, or other functional and useful document "free" in the sense of freedom: to assure everyone the effective freedom to copy and redistribute it, with or without modifying it, either commercially or noncommercially. Secondarily, this License preserves for the author and publisher a way to get credit for their work, while not being considered responsible for modifications made by others. This License is a kind of "copyleft", which means that derivative works of the document must themselves be free in the same sense. It complements the GNU General Public License, which is a copyleft license designed for free software. We have designed this License in order to use it for manuals for free software, because free software needs free documentation: a free program should come with manuals providing the same freedoms that the software does. 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Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts. A copy of the license is included in the section entitled ``GNU Free Documentation License''. If you have Invariant Sections, Front-Cover Texts and Back-Cover Texts, replace the "with...Texts." line with this: with the Invariant Sections being LIST THEIR TITLES, with the Front-Cover Texts being LIST, and with the Back-Cover Texts being LIST. If you have Invariant Sections without Cover Texts, or some other combination of the three, merge those two alternatives to suit the situation. If your document contains nontrivial examples of program code, we recommend releasing these examples in parallel under your choice of free software license, such as the GNU General Public License, to permit their use in free software.  File: g77.info, Node: Contributors, Next: Funding, Prev: GNU Free Documentation License, Up: Top Contributors to GNU Fortran *************************** In addition to James Craig Burley, who wrote the front end, many people have helped create and improve GNU Fortran. * The packaging and compiler portions of GNU Fortran are based largely on the GCC compiler. *Note Contributors to GCC: (gcc)Contributors, for more information. * The run-time library used by GNU Fortran is a repackaged version of the `libf2c' library (combined from the `libF77' and `libI77' libraries) provided as part of `f2c', available for free from `netlib' sites on the Internet. * Cygnus Support and The Free Software Foundation contributed significant money and/or equipment to Craig's efforts. * The following individuals served as alpha testers prior to `g77''s public release. This work consisted of testing, researching, sometimes debugging, and occasionally providing small amounts of code and fixes for `g77', plus offering plenty of helpful advice to Craig: Jonathan Corbet Dr. Mark Fernyhough Takafumi Hayashi (The University of Aizu)-- Kate Hedstrom Michel Kern (INRIA and Rice University)-- Dr. A. O. V. Le Blanc Dave Love Rick Lutowski Toon Moene Rick Niles Derk Reefman Wayne K. Schroll Bill Thorson Pedro A. M. Vazquez Ian Watson * Dave Love () wrote the libU77 part of the run-time library. * Scott Snyder () provided the patch to add rudimentary support for `INTEGER*1', `INTEGER*2', and `LOGICAL*1'. This inspired Craig to add further support, even though the resulting support would still be incomplete. This support is believed to be completed at version 3.4 of `gcc' by Roger Sayle (). * David Ronis () inspired and encouraged Craig to rewrite the documentation in texinfo format by contributing a first pass at a translation of the old `g77-0.5.16/f/DOC' file. * Toon Moene () performed some analysis of generated code as part of an overall project to improve `g77' code generation to at least be as good as `f2c' used in conjunction with `gcc'. So far, this has resulted in the three, somewhat experimental, options added by `g77' to the `gcc' compiler and its back end. (These, in turn, had made their way into the `egcs' version of the compiler, and do not exist in `gcc' version 2.8 or versions of `g77' based on that version of `gcc'.) * John Carr () wrote the alias analysis improvements. * Thanks to Mary Cortani and the staff at Craftwork Solutions () for all of their support. * Many other individuals have helped debug, test, and improve `g77' over the past several years, and undoubtedly more people will be doing so in the future. If you have done so, and would like to see your name listed in the above list, please ask! The default is that people wish to remain anonymous.  File: g77.info, Node: Funding, Next: Funding GNU Fortran, Prev: Contributors, Up: Top Funding Free Software ********************* If you want to have more free software a few years from now, it makes sense for you to help encourage people to contribute funds for its development. The most effective approach known is to encourage commercial redistributors to donate. Users of free software systems can boost the pace of development by encouraging for-a-fee distributors to donate part of their selling price to free software developers--the Free Software Foundation, and others. The way to convince distributors to do this is to demand it and expect it from them. So when you compare distributors, judge them partly by how much they give to free software development. Show distributors they must compete to be the one who gives the most. To make this approach work, you must insist on numbers that you can compare, such as, "We will donate ten dollars to the Frobnitz project for each disk sold." Don't be satisfied with a vague promise, such as "A portion of the profits are donated," since it doesn't give a basis for comparison. Even a precise fraction "of the profits from this disk" is not very meaningful, since creative accounting and unrelated business decisions can greatly alter what fraction of the sales price counts as profit. If the price you pay is $50, ten percent of the profit is probably less than a dollar; it might be a few cents, or nothing at all. Some redistributors do development work themselves. This is useful too; but to keep everyone honest, you need to inquire how much they do, and what kind. Some kinds of development make much more long-term difference than others. For example, maintaining a separate version of a program contributes very little; maintaining the standard version of a program for the whole community contributes much. Easy new ports contribute little, since someone else would surely do them; difficult ports such as adding a new CPU to the GNU Compiler Collection contribute more; major new features or packages contribute the most. By establishing the idea that supporting further development is "the proper thing to do" when distributing free software for a fee, we can assure a steady flow of resources into making more free software. Copyright (C) 1994 Free Software Foundation, Inc. Verbatim copying and redistribution of this section is permitted without royalty; alteration is not permitted.  File: g77.info, Node: Funding GNU Fortran, Next: Getting Started, Prev: Funding, Up: Top Funding GNU Fortran ******************* James Craig Burley (), the original author of `g77', stopped working on it in September 1999 (He has a web page at `http://world.std.com/%7Eburley/'.) GNU Fortran is currently maintained by Toon Moene (), with the help of countless other volunteers. As with other GNU software, funding is important because it can pay for needed equipment, personnel, and so on. The FSF provides information on the best way to fund ongoing development of GNU software (such as GNU Fortran) in documents such as the "GNUS Bulletin". Email for information on funding the FSF. Another important way to support work on GNU Fortran is to volunteer to help out. Email to volunteer for this work. However, we strongly expect that there will never be a version 0.6 of `g77'. Work on this compiler has stopped as of the release of GCC 3.1, except for bug fixing. `g77' will be succeeded by `g95' - see `http://g95.sourceforge.net'. *Note Funding Free Software: Funding, for more information.  File: g77.info, Node: Getting Started, Next: What is GNU Fortran?, Prev: Funding GNU Fortran, Up: Top Getting Started *************** If you don't need help getting started reading the portions of this manual that are most important to you, you should skip this portion of the manual. If you are new to compilers, especially Fortran compilers, or new to how compilers are structured under UNIX and UNIX-like systems, you'll want to see *Note What is GNU Fortran?::. If you are new to GNU compilers, or have used only one GNU compiler in the past and not had to delve into how it lets you manage various versions and configurations of `gcc', you should see *Note G77 and GCC::. Everyone except experienced `g77' users should see *Note Invoking G77::. If you're acquainted with previous versions of `g77', you should see *Note News About GNU Fortran: News. Further, if you've actually used previous versions of `g77', especially if you've written or modified Fortran code to be compiled by previous versions of `g77', you should see *Note Changes::. If you intend to write or otherwise compile code that is not already strictly conforming ANSI FORTRAN 77--and this is probably everyone--you should see *Note Language::. If you run into trouble getting Fortran code to compile, link, run, or work properly, you might find answers if you see *Note Debugging and Interfacing::, see *Note Collected Fortran Wisdom::, and see *Note Trouble::. You might also find that the problems you are encountering are bugs in `g77'--see *Note Bugs::, for information on reporting them, after reading the other material. If you need further help with `g77', or with freely redistributable software in general, see *Note Service::. If you would like to help the `g77' project, see *Note Funding GNU Fortran::, for information on helping financially, and see *Note Projects::, for information on helping in other ways. If you're generally curious about the future of `g77', see *Note Projects::. If you're curious about its past, see *Note Contributors::, and see *Note Funding GNU Fortran::. To see a few of the questions maintainers of `g77' have, and that you might be able to answer, see *Note Open Questions::.  File: g77.info, Node: What is GNU Fortran?, Next: G77 and GCC, Prev: Getting Started, Up: Top What is GNU Fortran? ******************** GNU Fortran, or `g77', is designed initially as a free replacement for, or alternative to, the UNIX `f77' command. (Similarly, `gcc' is designed as a replacement for the UNIX `cc' command.) `g77' also is designed to fit in well with the other fine GNU compilers and tools. Sometimes these design goals conflict--in such cases, resolution often is made in favor of fitting in well with Project GNU. These cases are usually identified in the appropriate sections of this manual. As compilers, `g77', `gcc', and `f77' share the following characteristics: * They read a user's program, stored in a file and containing instructions written in the appropriate language (Fortran, C, and so on). This file contains "source code". * They translate the user's program into instructions a computer can carry out more quickly than it takes to translate the instructions in the first place. These instructions are called "machine code"--code designed to be efficiently translated and processed by a machine such as a computer. Humans usually aren't as good writing machine code as they are at writing Fortran or C, because it is easy to make tiny mistakes writing machine code. When writing Fortran or C, it is easy to make big mistakes. * They provide information in the generated machine code that can make it easier to find bugs in the program (using a debugging tool, called a "debugger", such as `gdb'). * They locate and gather machine code already generated to perform actions requested by statements in the user's program. This machine code is organized into "libraries" and is located and gathered during the "link" phase of the compilation process. (Linking often is thought of as a separate step, because it can be directly invoked via the `ld' command. However, the `g77' and `gcc' commands, as with most compiler commands, automatically perform the linking step by calling on `ld' directly, unless asked to not do so by the user.) * They attempt to diagnose cases where the user's program contains incorrect usages of the language. The "diagnostics" produced by the compiler indicate the problem and the location in the user's source file where the problem was first noticed. The user can use this information to locate and fix the problem. (Sometimes an incorrect usage of the language leads to a situation where the compiler can no longer make any sense of what follows--while a human might be able to--and thus ends up complaining about many "problems" it encounters that, in fact, stem from just one problem, usually the first one reported.) * They attempt to diagnose cases where the user's program contains a correct usage of the language, but instructs the computer to do something questionable. These diagnostics often are in the form of "warnings", instead of the "errors" that indicate incorrect usage of the language. How these actions are performed is generally under the control of the user. Using command-line options, the user can specify how persnickety the compiler is to be regarding the program (whether to diagnose questionable usage of the language), how much time to spend making the generated machine code run faster, and so on. `g77' consists of several components: * A modified version of the `gcc' command, which also might be installed as the system's `cc' command. (In many cases, `cc' refers to the system's "native" C compiler, which might be a non-GNU compiler, or an older version of `gcc' considered more stable or that is used to build the operating system kernel.) * The `g77' command itself, which also might be installed as the system's `f77' command. * The `libg2c' run-time library. This library contains the machine code needed to support capabilities of the Fortran language that are not directly provided by the machine code generated by the `g77' compilation phase. `libg2c' is just the unique name `g77' gives to its version of `libf2c' to distinguish it from any copy of `libf2c' installed from `f2c' (or versions of `g77' that built `libf2c' under that same name) on the system. The maintainer of `libf2c' currently is . * The compiler itself, internally named `f771'. Note that `f771' does not generate machine code directly--it generates "assembly code" that is a more readable form of machine code, leaving the conversion to actual machine code to an "assembler", usually named `as'. `gcc' is often thought of as "the C compiler" only, but it does more than that. Based on command-line options and the names given for files on the command line, `gcc' determines which actions to perform, including preprocessing, compiling (in a variety of possible languages), assembling, and linking. For example, the command `gcc foo.c' "drives" the file `foo.c' through the preprocessor `cpp', then the C compiler (internally named `cc1'), then the assembler (usually `as'), then the linker (`ld'), producing an executable program named `a.out' (on UNIX systems). As another example, the command `gcc foo.cc' would do much the same as `gcc foo.c', but instead of using the C compiler named `cc1', `gcc' would use the C++ compiler (named `cc1plus'). In a GNU Fortran installation, `gcc' recognizes Fortran source files by name just like it does C and C++ source files. It knows to use the Fortran compiler named `f771', instead of `cc1' or `cc1plus', to compile Fortran files. Non-Fortran-related operation of `gcc' is generally unaffected by installing the GNU Fortran version of `gcc'. However, without the installed version of `gcc' being the GNU Fortran version, `gcc' will not be able to compile and link Fortran programs--and since `g77' uses `gcc' to do most of the actual work, neither will `g77'! The `g77' command is essentially just a front-end for the `gcc' command. Fortran users will normally use `g77' instead of `gcc', because `g77' knows how to specify the libraries needed to link with Fortran programs (`libg2c' and `lm'). `g77' can still compile and link programs and source files written in other languages, just like `gcc'. The command `g77 -v' is a quick way to display lots of version information for the various programs used to compile a typical preprocessed Fortran source file--this produces much more output than `gcc -v' currently does. (If it produces an error message near the end of the output--diagnostics from the linker, usually `ld'--you might have an out-of-date `libf2c' that improperly handles complex arithmetic.) In the output of this command, the line beginning `GNU Fortran Front End' identifies the version number of GNU Fortran; immediately preceding that line is a line identifying the version of `gcc' with which that version of `g77' was built. The `libf2c' library is distributed with GNU Fortran for the convenience of its users, but is not part of GNU Fortran. It contains the procedures needed by Fortran programs while they are running. For example, while code generated by `g77' is likely to do additions, subtractions, and multiplications "in line"--in the actual compiled code--it is not likely to do trigonometric functions this way. Instead, operations like trigonometric functions are compiled by the `f771' compiler (invoked by `g77' when compiling Fortran code) into machine code that, when run, calls on functions in `libg2c', so `libg2c' must be linked with almost every useful program having any component compiled by GNU Fortran. (As mentioned above, the `g77' command takes care of all this for you.) The `f771' program represents most of what is unique to GNU Fortran. While much of the `libg2c' component comes from the `libf2c' component of `f2c', a free Fortran-to-C converter distributed by Bellcore (AT&T), plus `libU77', provided by Dave Love, and the `g77' command is just a small front-end to `gcc', `f771' is a combination of two rather large chunks of code. One chunk is the so-called "GNU Back End", or GBE, which knows how to generate fast code for a wide variety of processors. The same GBE is used by the C, C++, and Fortran compiler programs `cc1', `cc1plus', and `f771', plus others. Often the GBE is referred to as the "gcc back end" or even just "gcc"--in this manual, the term GBE is used whenever the distinction is important. The other chunk of `f771' is the majority of what is unique about GNU Fortran--the code that knows how to interpret Fortran programs to determine what they are intending to do, and then communicate that knowledge to the GBE for actual compilation of those programs. This chunk is called the "Fortran Front End" (FFE). The `cc1' and `cc1plus' programs have their own front ends, for the C and C++ languages, respectively. These fronts ends are responsible for diagnosing incorrect usage of their respective languages by the programs the process, and are responsible for most of the warnings about questionable constructs as well. (The GBE handles producing some warnings, like those concerning possible references to undefined variables.) Because so much is shared among the compilers for various languages, much of the behavior and many of the user-selectable options for these compilers are similar. For example, diagnostics (error messages and warnings) are similar in appearance; command-line options like `-Wall' have generally similar effects; and the quality of generated code (in terms of speed and size) is roughly similar (since that work is done by the shared GBE).  File: g77.info, Node: G77 and GCC, Next: Invoking G77, Prev: What is GNU Fortran?, Up: Top Compile Fortran, C, or Other Programs ************************************* A GNU Fortran installation includes a modified version of the `gcc' command. In a non-Fortran installation, `gcc' recognizes C, C++, and Objective-C source files. In a GNU Fortran installation, `gcc' also recognizes Fortran source files and accepts Fortran-specific command-line options, plus some command-line options that are designed to cater to Fortran users but apply to other languages as well. *Note Programming Languages Supported by GCC: (gcc)G++ and GCC, for information on the way different languages are handled by the GCC compiler (`gcc'). Also provided as part of GNU Fortran is the `g77' command. The `g77' command is designed to make compiling and linking Fortran programs somewhat easier than when using the `gcc' command for these tasks. It does this by analyzing the command line somewhat and changing it appropriately before submitting it to the `gcc' command. Use the `-v' option with `g77' to see what is going on--the first line of output is the invocation of the `gcc' command.  File: g77.info, Node: Invoking G77, Next: News, Prev: G77 and GCC, Up: Top GNU Fortran Command Options *************************** The `g77' command supports all the options supported by the `gcc' command. *Note GCC Command Options: (gcc)Invoking GCC, for information on the non-Fortran-specific aspects of the `gcc' command (and, therefore, the `g77' command). All `gcc' and `g77' options are accepted both by `g77' and by `gcc' (as well as any other drivers built at the same time, such as `g++'), since adding `g77' to the `gcc' distribution enables acceptance of `g77' options by all of the relevant drivers. In some cases, options have positive and negative forms; the negative form of `-ffoo' would be `-fno-foo'. This manual documents only one of these two forms, whichever one is not the default. * Menu: * Option Summary:: Brief list of all `g77' options, without explanations. * Overall Options:: Controlling the kind of output: an executable, object files, assembler files, or preprocessed source. * Shorthand Options:: Options that are shorthand for other options. * Fortran Dialect Options:: Controlling the variant of Fortran language compiled. * Warning Options:: How picky should the compiler be? * Debugging Options:: Symbol tables, measurements, and debugging dumps. * Optimize Options:: How much optimization? * Preprocessor Options:: Controlling header files and macro definitions. Also, getting dependency information for Make. * Directory Options:: Where to find header files and libraries. Where to find the compiler executable files. * Code Gen Options:: Specifying conventions for function calls, data layout and register usage. * Environment Variables:: Env vars that affect GNU Fortran.  File: g77.info, Node: Option Summary, Next: Overall Options, Up: Invoking G77 Option Summary ============== Here is a summary of all the options specific to GNU Fortran, grouped by type. Explanations are in the following sections. _Overall Options_ *Note Options Controlling the Kind of Output: Overall Options. -fversion -fset-g77-defaults -fno-silent _Shorthand Options_ *Note Shorthand Options::. -ff66 -fno-f66 -ff77 -fno-f77 -fno-ugly _Fortran Language Options_ *Note Options Controlling Fortran Dialect: Fortran Dialect Options. -ffree-form -fno-fixed-form -ff90 -fvxt -fdollar-ok -fno-backslash -fno-ugly-args -fno-ugly-assign -fno-ugly-assumed -fugly-comma -fugly-complex -fugly-init -fugly-logint -fonetrip -ftypeless-boz -fintrin-case-initcap -fintrin-case-upper -fintrin-case-lower -fintrin-case-any -fmatch-case-initcap -fmatch-case-upper -fmatch-case-lower -fmatch-case-any -fsource-case-upper -fsource-case-lower -fsource-case-preserve -fsymbol-case-initcap -fsymbol-case-upper -fsymbol-case-lower -fsymbol-case-any -fcase-strict-upper -fcase-strict-lower -fcase-initcap -fcase-upper -fcase-lower -fcase-preserve -ff2c-intrinsics-delete -ff2c-intrinsics-hide -ff2c-intrinsics-disable -ff2c-intrinsics-enable -fbadu77-intrinsics-delete -fbadu77-intrinsics-hide -fbadu77-intrinsics-disable -fbadu77-intrinsics-enable -ff90-intrinsics-delete -ff90-intrinsics-hide -ff90-intrinsics-disable -ff90-intrinsics-enable -fgnu-intrinsics-delete -fgnu-intrinsics-hide -fgnu-intrinsics-disable -fgnu-intrinsics-enable -fmil-intrinsics-delete -fmil-intrinsics-hide -fmil-intrinsics-disable -fmil-intrinsics-enable -funix-intrinsics-delete -funix-intrinsics-hide -funix-intrinsics-disable -funix-intrinsics-enable -fvxt-intrinsics-delete -fvxt-intrinsics-hide -fvxt-intrinsics-disable -fvxt-intrinsics-enable -ffixed-line-length-N -ffixed-line-length-none _Warning Options_ *Note Options to Request or Suppress Warnings: Warning Options. -fsyntax-only -pedantic -pedantic-errors -fpedantic -w -Wno-globals -Wimplicit -Wunused -Wuninitialized -Wall -Wsurprising -Werror -W _Debugging Options_ *Note Options for Debugging Your Program or GCC: Debugging Options. -g _Optimization Options_ *Note Options that Control Optimization: Optimize Options. -malign-double -ffloat-store -fforce-mem -fforce-addr -fno-inline -ffast-math -fstrength-reduce -frerun-cse-after-loop -funsafe-math-optimizations -ffinite-math-only -fno-trapping-math -fexpensive-optimizations -fdelayed-branch -fschedule-insns -fschedule-insn2 -fcaller-saves -funroll-loops -funroll-all-loops -fno-move-all-movables -fno-reduce-all-givs -fno-rerun-loop-opt _Directory Options_ *Note Options for Directory Search: Directory Options. -IDIR -I- _Code Generation Options_ *Note Options for Code Generation Conventions: Code Gen Options. -fno-automatic -finit-local-zero -fno-f2c -ff2c-library -fno-underscoring -fno-ident -fpcc-struct-return -freg-struct-return -fshort-double -fno-common -fpack-struct -fzeros -fno-second-underscore -femulate-complex -falias-check -fargument-alias -fargument-noalias -fno-argument-noalias-global -fno-globals -fflatten-arrays -fbounds-check -ffortran-bounds-check * Menu: * Overall Options:: Controlling the kind of output: an executable, object files, assembler files, or preprocessed source. * Shorthand Options:: Options that are shorthand for other options. * Fortran Dialect Options:: Controlling the variant of Fortran language compiled. * Warning Options:: How picky should the compiler be? * Debugging Options:: Symbol tables, measurements, and debugging dumps. * Optimize Options:: How much optimization? * Preprocessor Options:: Controlling header files and macro definitions. Also, getting dependency information for Make. * Directory Options:: Where to find header files and libraries. Where to find the compiler executable files. * Code Gen Options:: Specifying conventions for function calls, data layout and register usage.  File: g77.info, Node: Overall Options, Next: Shorthand Options, Prev: Option Summary, Up: Invoking G77 Options Controlling the Kind of Output ====================================== Compilation can involve as many as four stages: preprocessing, code generation (often what is really meant by the term "compilation"), assembly, and linking, always in that order. The first three stages apply to an individual source file, and end by producing an object file; linking combines all the object files (those newly compiled, and those specified as input) into an executable file. For any given input file, the file name suffix determines what kind of program is contained in the file--that is, the language in which the program is written is generally indicated by the suffix. Suffixes specific to GNU Fortran are listed below. *Note Options Controlling the Kind of Output: (gcc)Overall Options, for information on suffixes recognized by GCC. `FILE.f' `FILE.for' `FILE.FOR' Fortran source code that should not be preprocessed. Such source code cannot contain any preprocessor directives, such as `#include', `#define', `#if', and so on. You can force `.f' files to be preprocessed by `cpp' by using `-x f77-cpp-input'. *Note LEX::. `FILE.F' `FILE.fpp' `FILE.FPP' Fortran source code that must be preprocessed (by the C preprocessor `cpp', which is part of GCC). Note that preprocessing is not extended to the contents of files included by the `INCLUDE' directive--the `#include' preprocessor directive must be used instead. `FILE.r' Ratfor source code, which must be preprocessed by the `ratfor' command, which is available separately (as it is not yet part of the GNU Fortran distribution). A public domain version in C is at `http://sepwww.stanford.edu/sep/prof/ratfor.shar.2'. UNIX users typically use the `FILE.f' and `FILE.F' nomenclature. Users of other operating systems, especially those that cannot distinguish upper-case letters from lower-case letters in their file names, typically use the `FILE.for' and `FILE.fpp' nomenclature. Use of the preprocessor `cpp' allows use of C-like constructs such as `#define' and `#include', but can lead to unexpected, even mistaken, results due to Fortran's source file format. It is recommended that use of the C preprocessor be limited to `#include' and, in conjunction with `#define', only `#if' and related directives, thus avoiding in-line macro expansion entirely. This recommendation applies especially when using the traditional fixed source form. With free source form, fewer unexpected transformations are likely to happen, but use of constructs such as Hollerith and character constants can nevertheless present problems, especially when these are continued across multiple source lines. These problems result, primarily, from differences between the way such constants are interpreted by the C preprocessor and by a Fortran compiler. Another example of a problem that results from using the C preprocessor is that a Fortran comment line that happens to contain any characters "interesting" to the C preprocessor, such as a backslash at the end of the line, is not recognized by the preprocessor as a comment line, so instead of being passed through "raw", the line is edited according to the rules for the preprocessor. For example, the backslash at the end of the line is removed, along with the subsequent newline, resulting in the next line being effectively commented out--unfortunate if that line is a non-comment line of important code! _Note:_ The `-traditional' and `-undef' flags are supplied to `cpp' by default, to help avoid unpleasant surprises. *Note Options Controlling the Preprocessor: (gcc)Preprocessor Options. This means that ANSI C preprocessor features (such as the `#' operator) aren't available, and only variables in the C reserved namespace (generally, names with a leading underscore) are liable to substitution by C predefines. Thus, if you want to do system-specific tests, use, for example, `#ifdef __linux__' rather than `#ifdef linux'. Use the `-v' option to see exactly how the preprocessor is invoked. Unfortunately, the `-traditional' flag will not avoid an error from anything that `cpp' sees as an unterminated C comment, such as: C Some Fortran compilers accept /* as starting C an inline comment. *Note Trailing Comment::. The following options that affect overall processing are recognized by the `g77' and `gcc' commands in a GNU Fortran installation: `-fversion' Ensure that the `g77' version of the compiler phase is reported, if run, and, starting in `egcs' version 1.1, that internal consistency checks in the `f771' program are run. This option is supplied automatically when `-v' or `--verbose' is specified as a command-line option for `g77' or `gcc' and when the resulting commands compile Fortran source files. In GCC 3.1, this is changed back to the behavior `gcc' displays for `.c' files. `-fset-g77-defaults' _Version info:_ This option was obsolete as of `egcs' version 1.1. The effect is instead achieved by the `lang_init_options' routine in `gcc/gcc/f/com.c'. Set up whatever `gcc' options are to apply to Fortran compilations, and avoid running internal consistency checks that might take some time. This option is supplied automatically when compiling Fortran code via the `g77' or `gcc' command. The description of this option is provided so that users seeing it in the output of, say, `g77 -v' understand why it is there. Also, developers who run `f771' directly might want to specify it by hand to get the same defaults as they would running `f771' via `g77' or `gcc' However, such developers should, after linking a new `f771' executable, invoke it without this option once, e.g. via `./f771 -quiet < /dev/null', to ensure that they have not introduced any internal inconsistencies (such as in the table of intrinsics) before proceeding--`g77' will crash with a diagnostic if it detects an inconsistency. `-fno-silent' Print (to `stderr') the names of the program units as they are compiled, in a form similar to that used by popular UNIX `f77' implementations and `f2c' *Note Options Controlling the Kind of Output: (gcc)Overall Options, for information on more options that control the overall operation of the `gcc' command (and, by extension, the `g77' command).  File: g77.info, Node: Shorthand Options, Next: Fortran Dialect Options, Prev: Overall Options, Up: Invoking G77 Shorthand Options ================= The following options serve as "shorthand" for other options accepted by the compiler: `-fugly' _Note:_ This option is no longer supported. The information, below, is provided to aid in the conversion of old scripts. Specify that certain "ugly" constructs are to be quietly accepted. Same as: -fugly-args -fugly-assign -fugly-assumed -fugly-comma -fugly-complex -fugly-init -fugly-logint These constructs are considered inappropriate to use in new or well-maintained portable Fortran code, but widely used in old code. *Note Distensions::, for more information. `-fno-ugly' Specify that all "ugly" constructs are to be noisily rejected. Same as: -fno-ugly-args -fno-ugly-assign -fno-ugly-assumed -fno-ugly-comma -fno-ugly-complex -fno-ugly-init -fno-ugly-logint *Note Distensions::, for more information. `-ff66' Specify that the program is written in idiomatic FORTRAN 66. Same as `-fonetrip -fugly-assumed'. The `-fno-f66' option is the inverse of `-ff66'. As such, it is the same as `-fno-onetrip -fno-ugly-assumed'. The meaning of this option is likely to be refined as future versions of `g77' provide more compatibility with other existing and obsolete Fortran implementations. `-ff77' Specify that the program is written in idiomatic UNIX FORTRAN 77 and/or the dialect accepted by the `f2c' product. Same as `-fbackslash -fno-typeless-boz'. The meaning of this option is likely to be refined as future versions of `g77' provide more compatibility with other existing and obsolete Fortran implementations. `-fno-f77' The `-fno-f77' option is _not_ the inverse of `-ff77'. It specifies that the program is not written in idiomatic UNIX FORTRAN 77 or `f2c' but in a more widely portable dialect. `-fno-f77' is the same as `-fno-backslash'. The meaning of this option is likely to be refined as future versions of `g77' provide more compatibility with other existing and obsolete Fortran implementations.  File: g77.info, Node: Fortran Dialect Options, Next: Warning Options, Prev: Shorthand Options, Up: Invoking G77 Options Controlling Fortran Dialect =================================== The following options control the dialect of Fortran that the compiler accepts: `-ffree-form' `-fno-fixed-form' Specify that the source file is written in free form (introduced in Fortran 90) instead of the more-traditional fixed form. `-ff90' Allow certain Fortran-90 constructs. This option controls whether certain Fortran 90 constructs are recognized. (Other Fortran 90 constructs might or might not be recognized depending on other options such as `-fvxt', `-ff90-intrinsics-enable', and the current level of support for Fortran 90.) *Note Fortran 90::, for more information. `-fvxt' Specify the treatment of certain constructs that have different meanings depending on whether the code is written in GNU Fortran (based on FORTRAN 77 and akin to Fortran 90) or VXT Fortran (more like VAX FORTRAN). The default is `-fno-vxt'. `-fvxt' specifies that the VXT Fortran interpretations for those constructs are to be chosen. *Note VXT Fortran::, for more information. `-fdollar-ok' Allow `$' as a valid character in a symbol name. `-fno-backslash' Specify that `\' is not to be specially interpreted in character and Hollerith constants a la C and many UNIX Fortran compilers. For example, with `-fbackslash' in effect, `A\nB' specifies three characters, with the second one being newline. With `-fno-backslash', it specifies four characters, `A', `\', `n', and `B'. Note that `g77' implements a fairly general form of backslash processing that is incompatible with the narrower forms supported by some other compilers. For example, `'A\003B'' is a three-character string in `g77' whereas other compilers that support backslash might not support the three-octal-digit form, and thus treat that string as longer than three characters. *Note Backslash in Constants::, for information on why `-fbackslash' is the default instead of `-fno-backslash'. `-fno-ugly-args' Disallow passing Hollerith and typeless constants as actual arguments (for example, `CALL FOO(4HABCD)'). *Note Ugly Implicit Argument Conversion::, for more information. `-fugly-assign' Use the same storage for a given variable regardless of whether it is used to hold an assigned-statement label (as in `ASSIGN 10 TO I') or used to hold numeric data (as in `I = 3'). *Note Ugly Assigned Labels::, for more information. `-fugly-assumed' Assume any dummy array with a final dimension specified as `1' is really an assumed-size array, as if `*' had been specified for the final dimension instead of `1'. For example, `DIMENSION X(1)' is treated as if it had read `DIMENSION X(*)'. *Note Ugly Assumed-Size Arrays::, for more information. `-fugly-comma' In an external-procedure invocation, treat a trailing comma in the argument list as specification of a trailing null argument, and treat an empty argument list as specification of a single null argument. For example, `CALL FOO(,)' is treated as `CALL FOO(%VAL(0), %VAL(0))'. That is, _two_ null arguments are specified by the procedure call when `-fugly-comma' is in force. And `F = FUNC()' is treated as `F = FUNC(%VAL(0))'. The default behavior, `-fno-ugly-comma', is to ignore a single trailing comma in an argument list. So, by default, `CALL FOO(X,)' is treated exactly the same as `CALL FOO(X)'. *Note Ugly Null Arguments::, for more information. `-fugly-complex' Do not complain about `REAL(EXPR)' or `AIMAG(EXPR)' when EXPR is a `COMPLEX' type other than `COMPLEX(KIND=1)'--usually this is used to permit `COMPLEX(KIND=2)' (`DOUBLE COMPLEX') operands. The `-ff90' option controls the interpretation of this construct. *Note Ugly Complex Part Extraction::, for more information. `-fno-ugly-init' Disallow use of Hollerith and typeless constants as initial values (in `PARAMETER' and `DATA' statements), and use of character constants to initialize numeric types and vice versa. For example, `DATA I/'F'/, CHRVAR/65/, J/4HABCD/' is disallowed by `-fno-ugly-init'. *Note Ugly Conversion of Initializers::, for more information. `-fugly-logint' Treat `INTEGER' and `LOGICAL' variables and expressions as potential stand-ins for each other. For example, automatic conversion between `INTEGER' and `LOGICAL' is enabled, for many contexts, via this option. *Note Ugly Integer Conversions::, for more information. `-fonetrip' Executable iterative `DO' loops are to be executed at least once each time they are reached. ANSI FORTRAN 77 and more recent versions of the Fortran standard specify that the body of an iterative `DO' loop is not executed if the number of iterations calculated from the parameters of the loop is less than 1. (For example, `DO 10 I = 1, 0'.) Such a loop is called a "zero-trip loop". Prior to ANSI FORTRAN 77, many compilers implemented `DO' loops such that the body of a loop would be executed at least once, even if the iteration count was zero. Fortran code written assuming this behavior is said to require "one-trip loops". For example, some code written to the FORTRAN 66 standard expects this behavior from its `DO' loops, although that standard did not specify this behavior. The `-fonetrip' option specifies that the source file(s) being compiled require one-trip loops. This option affects only those loops specified by the (iterative) `DO' statement and by implied-`DO' lists in I/O statements. Loops specified by implied-`DO' lists in `DATA' and specification (non-executable) statements are not affected. `-ftypeless-boz' Specifies that prefix-radix non-decimal constants, such as `Z'ABCD'', are typeless instead of `INTEGER(KIND=1)'. You can test for yourself whether a particular compiler treats the prefix form as `INTEGER(KIND=1)' or typeless by running the following program: EQUIVALENCE (I, R) R = Z'ABCD1234' J = Z'ABCD1234' IF (J .EQ. I) PRINT *, 'Prefix form is TYPELESS' IF (J .NE. I) PRINT *, 'Prefix form is INTEGER' END Reports indicate that many compilers process this form as `INTEGER(KIND=1)', though a few as typeless, and at least one based on a command-line option specifying some kind of compatibility. `-fintrin-case-initcap' `-fintrin-case-upper' `-fintrin-case-lower' `-fintrin-case-any' Specify expected case for intrinsic names. `-fintrin-case-lower' is the default. `-fmatch-case-initcap' `-fmatch-case-upper' `-fmatch-case-lower' `-fmatch-case-any' Specify expected case for keywords. `-fmatch-case-lower' is the default. `-fsource-case-upper' `-fsource-case-lower' `-fsource-case-preserve' Specify whether source text other than character and Hollerith constants is to be translated to uppercase, to lowercase, or preserved as is. `-fsource-case-lower' is the default. `-fsymbol-case-initcap' `-fsymbol-case-upper' `-fsymbol-case-lower' `-fsymbol-case-any' Specify valid cases for user-defined symbol names. `-fsymbol-case-any' is the default. `-fcase-strict-upper' Same as `-fintrin-case-upper -fmatch-case-upper -fsource-case-preserve -fsymbol-case-upper'. (Requires all pertinent source to be in uppercase.) `-fcase-strict-lower' Same as `-fintrin-case-lower -fmatch-case-lower -fsource-case-preserve -fsymbol-case-lower'. (Requires all pertinent source to be in lowercase.) `-fcase-initcap' Same as `-fintrin-case-initcap -fmatch-case-initcap -fsource-case-preserve -fsymbol-case-initcap'. (Requires all pertinent source to be in initial capitals, as in `Print *,SqRt(Value)'.) `-fcase-upper' Same as `-fintrin-case-any -fmatch-case-any -fsource-case-upper -fsymbol-case-any'. (Maps all pertinent source to uppercase.) `-fcase-lower' Same as `-fintrin-case-any -fmatch-case-any -fsource-case-lower -fsymbol-case-any'. (Maps all pertinent source to lowercase.) `-fcase-preserve' Same as `-fintrin-case-any -fmatch-case-any -fsource-case-preserve -fsymbol-case-any'. (Preserves all case in user-defined symbols, while allowing any-case matching of intrinsics and keywords. For example, `call Foo(i,I)' would pass two _different_ variables named `i' and `I' to a procedure named `Foo'.) `-fbadu77-intrinsics-delete' `-fbadu77-intrinsics-hide' `-fbadu77-intrinsics-disable' `-fbadu77-intrinsics-enable' Specify status of UNIX intrinsics having inappropriate forms. `-fbadu77-intrinsics-enable' is the default. *Note Intrinsic Groups::. `-ff2c-intrinsics-delete' `-ff2c-intrinsics-hide' `-ff2c-intrinsics-disable' `-ff2c-intrinsics-enable' Specify status of f2c-specific intrinsics. `-ff2c-intrinsics-enable' is the default. *Note Intrinsic Groups::. `-ff90-intrinsics-delete' `-ff90-intrinsics-hide' `-ff90-intrinsics-disable' `-ff90-intrinsics-enable' Specify status of F90-specific intrinsics. `-ff90-intrinsics-enable' is the default. *Note Intrinsic Groups::. `-fgnu-intrinsics-delete' `-fgnu-intrinsics-hide' `-fgnu-intrinsics-disable' `-fgnu-intrinsics-enable' Specify status of Digital's COMPLEX-related intrinsics. `-fgnu-intrinsics-enable' is the default. *Note Intrinsic Groups::. `-fmil-intrinsics-delete' `-fmil-intrinsics-hide' `-fmil-intrinsics-disable' `-fmil-intrinsics-enable' Specify status of MIL-STD-1753-specific intrinsics. `-fmil-intrinsics-enable' is the default. *Note Intrinsic Groups::. `-funix-intrinsics-delete' `-funix-intrinsics-hide' `-funix-intrinsics-disable' `-funix-intrinsics-enable' Specify status of UNIX intrinsics. `-funix-intrinsics-enable' is the default. *Note Intrinsic Groups::. `-fvxt-intrinsics-delete' `-fvxt-intrinsics-hide' `-fvxt-intrinsics-disable' `-fvxt-intrinsics-enable' Specify status of VXT intrinsics. `-fvxt-intrinsics-enable' is the default. *Note Intrinsic Groups::. `-ffixed-line-length-N' Set column after which characters are ignored in typical fixed-form lines in the source file, and through which spaces are assumed (as if padded to that length) after the ends of short fixed-form lines. Popular values for N include 72 (the standard and the default), 80 (card image), and 132 (corresponds to "extended-source" options in some popular compilers). N may be `none', meaning that the entire line is meaningful and that continued character constants never have implicit spaces appended to them to fill out the line. `-ffixed-line-length-0' means the same thing as `-ffixed-line-length-none'. *Note Source Form::, for more information.  File: g77.info, Node: Warning Options, Next: Debugging Options, Prev: Fortran Dialect Options, Up: Invoking G77 Options to Request or Suppress Warnings ======================================= Warnings are diagnostic messages that report constructions which are not inherently erroneous but which are risky or suggest there might have been an error. You can request many specific warnings with options beginning `-W', for example `-Wimplicit' to request warnings on implicit declarations. Each of these specific warning options also has a negative form beginning `-Wno-' to turn off warnings; for example, `-Wno-implicit'. This manual lists only one of the two forms, whichever is not the default. These options control the amount and kinds of warnings produced by GNU Fortran: `-fsyntax-only' Check the code for syntax errors, but don't do anything beyond that. `-pedantic' Issue warnings for uses of extensions to ANSI FORTRAN 77. `-pedantic' also applies to C-language constructs where they occur in GNU Fortran source files, such as use of `\e' in a character constant within a directive like `#include'. Valid ANSI FORTRAN 77 programs should compile properly with or without this option. However, without this option, certain GNU extensions and traditional Fortran features are supported as well. With this option, many of them are rejected. Some users try to use `-pedantic' to check programs for strict ANSI conformance. They soon find that it does not do quite what they want--it finds some non-ANSI practices, but not all. However, improvements to `g77' in this area are welcome. `-pedantic-errors' Like `-pedantic', except that errors are produced rather than warnings. `-fpedantic' Like `-pedantic', but applies only to Fortran constructs. `-w' Inhibit all warning messages. `-Wno-globals' Inhibit warnings about use of a name as both a global name (a subroutine, function, or block data program unit, or a common block) and implicitly as the name of an intrinsic in a source file. Also inhibit warnings about inconsistent invocations and/or definitions of global procedures (function and subroutines). Such inconsistencies include different numbers of arguments and different types of arguments. `-Wimplicit' Warn whenever a variable, array, or function is implicitly declared. Has an effect similar to using the `IMPLICIT NONE' statement in every program unit. (Some Fortran compilers provide this feature by an option named `-u' or `/WARNINGS=DECLARATIONS'.) `-Wunused' Warn whenever a variable is unused aside from its declaration. `-Wuninitialized' Warn whenever an automatic variable is used without first being initialized. These warnings are possible only in optimizing compilation, because they require data-flow information that is computed only when optimizing. If you don't specify `-O', you simply won't get these warnings. These warnings occur only for variables that are candidates for register allocation. Therefore, they do not occur for a variable whose address is taken, or whose size is other than 1, 2, 4 or 8 bytes. Also, they do not occur for arrays, even when they are in registers. Note that there might be no warning about a variable that is used only to compute a value that itself is never used, because such computations may be deleted by data-flow analysis before the warnings are printed. These warnings are made optional because GNU Fortran is not smart enough to see all the reasons why the code might be correct despite appearing to have an error. Here is one example of how this can happen: SUBROUTINE DISPAT(J) IF (J.EQ.1) I=1 IF (J.EQ.2) I=4 IF (J.EQ.3) I=5 CALL FOO(I) END If the value of `J' is always 1, 2 or 3, then `I' is always initialized, but GNU Fortran doesn't know this. Here is another common case: SUBROUTINE MAYBE(FLAG) LOGICAL FLAG IF (FLAG) VALUE = 9.4 ... IF (FLAG) PRINT *, VALUE END This has no bug because `VALUE' is used only if it is set. `-Wall' The `-Wunused' and `-Wuninitialized' options combined. These are all the options which pertain to usage that we recommend avoiding and that we believe is easy to avoid. (As more warnings are added to `g77' some might be added to the list enabled by `-Wall'.) The remaining `-W...' options are not implied by `-Wall' because they warn about constructions that we consider reasonable to use, on occasion, in clean programs. `-Wsurprising' Warn about "suspicious" constructs that are interpreted by the compiler in a way that might well be surprising to someone reading the code. These differences can result in subtle, compiler-dependent (even machine-dependent) behavioral differences. The constructs warned about include: * Expressions having two arithmetic operators in a row, such as `X*-Y'. Such a construct is nonstandard, and can produce unexpected results in more complicated situations such as `X**-Y*Z'. `g77' along with many other compilers, interprets this example differently than many programmers, and a few other compilers. Specifically, `g77' interprets `X**-Y*Z' as `(X**(-Y))*Z', while others might think it should be interpreted as `X**(-(Y*Z))'. A revealing example is the constant expression `2**-2*1.', which `g77' evaluates to .25, while others might evaluate it to 0., the difference resulting from the way precedence affects type promotion. (The `-fpedantic' option also warns about expressions having two arithmetic operators in a row.) * Expressions with a unary minus followed by an operand and then a binary operator other than plus or minus. For example, `-2**2' produces a warning, because the precedence is `-(2**2)', yielding -4, not `(-2)**2', which yields 4, and which might represent what a programmer expects. An example of an expression producing different results in a surprising way is `-I*S', where I holds the value `-2147483648' and S holds `0.5'. On many systems, negating I results in the same value, not a positive number, because it is already the lower bound of what an `INTEGER(KIND=1)' variable can hold. So, the expression evaluates to a positive number, while the "expected" interpretation, `(-I)*S', would evaluate to a negative number. Even cases such as `-I*J' produce warnings, even though, in most configurations and situations, there is no computational difference between the results of the two interpretations--the purpose of this warning is to warn about differing interpretations and encourage a better style of coding, not to identify only those places where bugs might exist in the user's code. * `DO' loops with `DO' variables that are not of integral type--that is, using `REAL' variables as loop control variables. Although such loops can be written to work in the "obvious" way, the way `g77' is required by the Fortran standard to interpret such code is likely to be quite different from the way many programmers expect. (This is true of all `DO' loops, but the differences are pronounced for non-integral loop control variables.) *Note Loops::, for more information. `-Werror' Make all warnings into errors. `-W' Turns on "extra warnings" and, if optimization is specified via `-O', the `-Wuninitialized' option. (This might change in future versions of `g77' "Extra warnings" are issued for: * Unused parameters to a procedure (when `-Wunused' also is specified). * Overflows involving floating-point constants (not available for certain configurations). *Note Options to Request or Suppress Warnings: (gcc)Warning Options, for information on more options offered by the GBE shared by `g77' `gcc' and other GNU compilers. Some of these have no effect when compiling programs written in Fortran: `-Wcomment' `-Wformat' `-Wparentheses' `-Wswitch' `-Wswitch-default' `-Wswitch-enum' `-Wtraditional' `-Wshadow' `-Wid-clash-LEN' `-Wlarger-than-LEN' `-Wconversion' `-Waggregate-return' `-Wredundant-decls' These options all could have some relevant meaning for GNU Fortran programs, but are not yet supported.  File: g77.info, Node: Debugging Options, Next: Optimize Options, Prev: Warning Options, Up: Invoking G77 Options for Debugging Your Program or GNU Fortran ================================================= GNU Fortran has various special options that are used for debugging either your program or `g77' `-g' Produce debugging information in the operating system's native format (stabs, COFF, XCOFF, or DWARF). GDB can work with this debugging information. A sample debugging session looks like this (note the use of the breakpoint): $ cat gdb.f PROGRAM PROG DIMENSION A(10) DATA A /1.,2.,3.,4.,5.,6.,7.,8.,9.,10./ A(5) = 4. PRINT*,A END $ g77 -g -O gdb.f $ gdb a.out ... (gdb) break MAIN__ Breakpoint 1 at 0x8048e96: file gdb.f, line 4. (gdb) run Starting program: /home/toon/g77-bugs/./a.out Breakpoint 1, MAIN__ () at gdb.f:4 4 A(5) = 4. Current language: auto; currently fortran (gdb) print a(5) $1 = 5 (gdb) step 5 PRINT*,A (gdb) print a(5) $2 = 4 ... One could also add the setting of the breakpoint and the first run command to the file `.gdbinit' in the current directory, to simplify the debugging session. *Note Options for Debugging Your Program or GCC: (gcc)Debugging Options, for more information on debugging options.  File: g77.info, Node: Optimize Options, Next: Preprocessor Options, Prev: Debugging Options, Up: Invoking G77 Options That Control Optimization ================================= Most Fortran users will want to use no optimization when developing and testing programs, and use `-O' or `-O2' when compiling programs for late-cycle testing and for production use. However, note that certain diagnostics--such as for uninitialized variables--depend on the flow analysis done by `-O', i.e. you must use `-O' or `-O2' to get such diagnostics. The following flags have particular applicability when compiling Fortran programs: `-malign-double' (Intel x86 architecture only.) Noticeably improves performance of `g77' programs making heavy use of `REAL(KIND=2)' (`DOUBLE PRECISION') data on some systems. In particular, systems using Pentium, Pentium Pro, 586, and 686 implementations of the i386 architecture execute programs faster when `REAL(KIND=2)' (`DOUBLE PRECISION') data are aligned on 64-bit boundaries in memory. This option can, at least, make benchmark results more consistent across various system configurations, versions of the program, and data sets. _Note:_ The warning in the `gcc' documentation about this option does not apply, generally speaking, to Fortran code compiled by `g77' *Note Aligned Data::, for more information on alignment issues. _Also also note:_ The negative form of `-malign-double' is `-mno-align-double', not `-benign-double'. `-ffloat-store' Might help a Fortran program that depends on exact IEEE conformance on some machines, but might slow down a program that doesn't. This option is effective when the floating-point unit is set to work in IEEE 854 `extended precision'--as it typically is on x86 and m68k GNU systems--rather than IEEE 754 double precision. `-ffloat-store' tries to remove the extra precision by spilling data from floating-point registers into memory and this typically involves a big performance hit. However, it doesn't affect intermediate results, so that it is only partially effective. `Excess precision' is avoided in code like: a = b + c d = a * e but not in code like: d = (b + c) * e For another, potentially better, way of controlling the precision, see *Note Floating-point precision::. `-fforce-mem' `-fforce-addr' Might improve optimization of loops. `-fno-inline' Don't compile statement functions inline. Might reduce the size of a program unit--which might be at expense of some speed (though it should compile faster). Note that if you are not optimizing, no functions can be expanded inline. `-ffast-math' Might allow some programs designed to not be too dependent on IEEE behavior for floating-point to run faster, or die trying. Sets `-funsafe-math-optimizations', `-ffinite-math-only', and `-fno-trapping-math'. `-funsafe-math-optimizations' Allow optimizations that may be give incorrect results for certain IEEE inputs. `-ffinite-math-only' Allow optimizations for floating-point arithmetic that assume that arguments and results are not NaNs or +-Infs. This option should never be turned on by any `-O' option since it can result in incorrect output for programs which depend on an exact implementation of IEEE or ISO rules/specifications. The default is `-fno-finite-math-only'. `-fno-trapping-math' Allow the compiler to assume that floating-point arithmetic will not generate traps on any inputs. This is useful, for example, when running a program using IEEE "non-stop" floating-point arithmetic. `-fstrength-reduce' Might make some loops run faster. `-frerun-cse-after-loop' `-fexpensive-optimizations' `-fdelayed-branch' `-fschedule-insns' `-fschedule-insns2' `-fcaller-saves' Might improve performance on some code. `-funroll-loops' Typically improves performance on code using iterative `DO' loops by unrolling them and is probably generally appropriate for Fortran, though it is not turned on at any optimization level. Note that outer loop unrolling isn't done specifically; decisions about whether to unroll a loop are made on the basis of its instruction count. Also, no `loop discovery'(1) is done, so only loops written with `DO' benefit from loop optimizations, including--but not limited to--unrolling. Loops written with `IF' and `GOTO' are not currently recognized as such. This option unrolls only iterative `DO' loops, not `DO WHILE' loops. `-funroll-all-loops' Probably improves performance on code using `DO WHILE' loops by unrolling them in addition to iterative `DO' loops. In the absence of `DO WHILE', this option is equivalent to `-funroll-loops' but possibly slower. `-fno-move-all-movables' `-fno-reduce-all-givs' `-fno-rerun-loop-opt' In general, the optimizations enabled with these options will lead to faster code being generated by GNU Fortran; hence they are enabled by default when issuing the `g77' command. `-fmove-all-movables' and `-freduce-all-givs' will enable loop optimization to move all loop-invariant index computations in nested loops over multi-rank array dummy arguments out of these loops. `-frerun-loop-opt' will move offset calculations resulting from the fact that Fortran arrays by default have a lower bound of 1 out of the loops. These three options are intended to be removed someday, once loop optimization is sufficiently advanced to perform all those transformations without help from these options. *Note Options That Control Optimization: (gcc)Optimize Options, for more information on options to optimize the generated machine code. ---------- Footnotes ---------- (1) "loop discovery" refers to the process by which a compiler, or indeed any reader of a program, determines which portions of the program are more likely to be executed repeatedly as it is being run. Such discovery typically is done early when compiling using optimization techniques, so the "discovered" loops get more attention--and more run-time resources, such as registers--from the compiler. It is easy to "discover" loops that are constructed out of looping constructs in the language (such as Fortran's `DO'). For some programs, "discovering" loops constructed out of lower-level constructs (such as `IF' and `GOTO') can lead to generation of more optimal code than otherwise.  File: g77.info, Node: Preprocessor Options, Next: Directory Options, Prev: Optimize Options, Up: Invoking G77 Options Controlling the Preprocessor ==================================== These options control the C preprocessor, which is run on each C source file before actual compilation. *Note Options Controlling the Preprocessor: (gcc)Preprocessor Options, for information on C preprocessor options. Some of these options also affect how `g77' processes the `INCLUDE' directive. Since this directive is processed even when preprocessing is not requested, it is not described in this section. *Note Options for Directory Search: Directory Options, for information on how `g77' processes the `INCLUDE' directive. However, the `INCLUDE' directive does not apply preprocessing to the contents of the included file itself. Therefore, any file that contains preprocessor directives (such as `#include', `#define', and `#if') must be included via the `#include' directive, not via the `INCLUDE' directive. Therefore, any file containing preprocessor directives, if included, is necessarily included by a file that itself contains preprocessor directives.  File: g77.info, Node: Directory Options, Next: Code Gen Options, Prev: Preprocessor Options, Up: Invoking G77 Options for Directory Search ============================ These options affect how the `cpp' preprocessor searches for files specified via the `#include' directive. Therefore, when compiling Fortran programs, they are meaningful when the preprocessor is used. Some of these options also affect how `g77' searches for files specified via the `INCLUDE' directive, although files included by that directive are not, themselves, preprocessed. These options are: `-I-' `-IDIR' These affect interpretation of the `INCLUDE' directive (as well as of the `#include' directive of the `cpp' preprocessor). Note that `-IDIR' must be specified _without_ any spaces between `-I' and the directory name--that is, `-Ifoo/bar' is valid, but `-I foo/bar' is rejected by the `g77' compiler (though the preprocessor supports the latter form). Also note that the general behavior of `-I' and `INCLUDE' is pretty much the same as of `-I' with `#include' in the `cpp' preprocessor, with regard to looking for `header.gcc' files and other such things. *Note Options for Directory Search: (gcc)Directory Options, for information on the `-I' option.  File: g77.info, Node: Code Gen Options, Next: Environment Variables, Prev: Directory Options, Up: Invoking G77 Options for Code Generation Conventions ======================================= These machine-independent options control the interface conventions used in code generation. Most of them have both positive and negative forms; the negative form of `-ffoo' would be `-fno-foo'. In the table below, only one of the forms is listed--the one which is not the default. You can figure out the other form by either removing `no-' or adding it. `-fno-automatic' Treat each program unit as if the `SAVE' statement was specified for every local variable and array referenced in it. Does not affect common blocks. (Some Fortran compilers provide this option under the name `-static'.) `-finit-local-zero' Specify that variables and arrays that are local to a program unit (not in a common block and not passed as an argument) are to be initialized to binary zeros. Since there is a run-time penalty for initialization of variables that are not given the `SAVE' attribute, it might be a good idea to also use `-fno-automatic' with `-finit-local-zero'. `-fno-f2c' Do not generate code designed to be compatible with code generated by `f2c' use the GNU calling conventions instead. The `f2c' calling conventions require functions that return type `REAL(KIND=1)' to actually return the C type `double', and functions that return type `COMPLEX' to return the values via an extra argument in the calling sequence that points to where to store the return value. Under the GNU calling conventions, such functions simply return their results as they would in GNU C--`REAL(KIND=1)' functions return the C type `float', and `COMPLEX' functions return the GNU C type `complex' (or its `struct' equivalent). This does not affect the generation of code that interfaces with the `libg2c' library. However, because the `libg2c' library uses `f2c' calling conventions, `g77' rejects attempts to pass intrinsics implemented by routines in this library as actual arguments when `-fno-f2c' is used, to avoid bugs when they are actually called by code expecting the GNU calling conventions to work. For example, `INTRINSIC ABS;CALL FOO(ABS)' is rejected when `-fno-f2c' is in force. (Future versions of the `g77' run-time library might offer routines that provide GNU-callable versions of the routines that implement the `f2c' intrinsics that may be passed as actual arguments, so that valid programs need not be rejected when `-fno-f2c' is used.) *Caution:* If `-fno-f2c' is used when compiling any source file used in a program, it must be used when compiling _all_ Fortran source files used in that program. `-ff2c-library' Specify that use of `libg2c' (or the original `libf2c') is required. This is the default for the current version of `g77' Currently it is not valid to specify `-fno-f2c-library'. This option is provided so users can specify it in shell scripts that build programs and libraries that require the `libf2c' library, even when being compiled by future versions of `g77' that might otherwise default to generating code for an incompatible library. `-fno-underscoring' Do not transform names of entities specified in the Fortran source file by appending underscores to them. With `-funderscoring' in effect, `g77' appends two underscores to names with underscores and one underscore to external names with no underscores. (`g77' also appends two underscores to internal names with underscores to avoid naming collisions with external names. The `-fno-second-underscore' option disables appending of the second underscore in all cases.) This is done to ensure compatibility with code produced by many UNIX Fortran compilers, including `f2c' which perform the same transformations. Use of `-fno-underscoring' is not recommended unless you are experimenting with issues such as integration of (GNU) Fortran into existing system environments (vis-a-vis existing libraries, tools, and so on). For example, with `-funderscoring', and assuming other defaults like `-fcase-lower' and that `j()' and `max_count()' are external functions while `my_var' and `lvar' are local variables, a statement like I = J() + MAX_COUNT (MY_VAR, LVAR) is implemented as something akin to: i = j_() + max_count__(&my_var__, &lvar); With `-fno-underscoring', the same statement is implemented as: i = j() + max_count(&my_var, &lvar); Use of `-fno-underscoring' allows direct specification of user-defined names while debugging and when interfacing `g77' code with other languages. Note that just because the names match does _not_ mean that the interface implemented by `g77' for an external name matches the interface implemented by some other language for that same name. That is, getting code produced by `g77' to link to code produced by some other compiler using this or any other method can be only a small part of the overall solution--getting the code generated by both compilers to agree on issues other than naming can require significant effort, and, unlike naming disagreements, linkers normally cannot detect disagreements in these other areas. Also, note that with `-fno-underscoring', the lack of appended underscores introduces the very real possibility that a user-defined external name will conflict with a name in a system library, which could make finding unresolved-reference bugs quite difficult in some cases--they might occur at program run time, and show up only as buggy behavior at run time. In future versions of `g77' we hope to improve naming and linking issues so that debugging always involves using the names as they appear in the source, even if the names as seen by the linker are mangled to prevent accidental linking between procedures with incompatible interfaces. `-fno-second-underscore' Do not append a second underscore to names of entities specified in the Fortran source file. This option has no effect if `-fno-underscoring' is in effect. Otherwise, with this option, an external name such as `MAX_COUNT' is implemented as a reference to the link-time external symbol `max_count_', instead of `max_count__'. `-fno-ident' Ignore the `#ident' directive. `-fzeros' Treat initial values of zero as if they were any other value. As of version 0.5.18, `g77' normally treats `DATA' and other statements that are used to specify initial values of zero for variables and arrays as if no values were actually specified, in the sense that no diagnostics regarding multiple initializations are produced. This is done to speed up compiling of programs that initialize large arrays to zeros. Use `-fzeros' to revert to the simpler, slower behavior that can catch multiple initializations by keeping track of all initializations, zero or otherwise. _Caution:_ Future versions of `g77' might disregard this option (and its negative form, the default) or interpret it somewhat differently. The interpretation changes will affect only non-standard programs; standard-conforming programs should not be affected. `-femulate-complex' Implement `COMPLEX' arithmetic via emulation, instead of using the facilities of the `gcc' back end that provide direct support of `complex' arithmetic. (`gcc' had some bugs in its back-end support for `complex' arithmetic, due primarily to the support not being completed as of version 2.8.1 and `egcs' 1.1.2.) Use `-femulate-complex' if you suspect code-generation bugs, or experience compiler crashes, that might result from `g77' using the `COMPLEX' support in the `gcc' back end. If using that option fixes the bugs or crashes you are seeing, that indicates a likely `g77' bugs (though, all compiler crashes are considered bugs), so, please report it. (Note that the known bugs, now believed fixed, produced compiler crashes rather than causing the generation of incorrect code.) Use of this option should not affect how Fortran code compiled by `g77' works in terms of its interfaces to other code, e.g. that compiled by `f2c' As of GCC version 3.0, this option is not necessary anymore. _Caution:_ Future versions of `g77' might ignore both forms of this option. `-falias-check' `-fargument-alias' `-fargument-noalias' `-fno-argument-noalias-global' _Version info:_ These options are not supported by versions of `g77' based on `gcc' version 2.8. These options specify to what degree aliasing (overlap) is permitted between arguments (passed as pointers) and `COMMON' (external, or public) storage. The default for Fortran code, as mandated by the FORTRAN 77 and Fortran 90 standards, is `-fargument-noalias-global'. The default for code written in the C language family is `-fargument-alias'. Note that, on some systems, compiling with `-fforce-addr' in effect can produce more optimal code when the default aliasing options are in effect (and when optimization is enabled). *Note Aliasing Assumed To Work::, for detailed information on the implications of compiling Fortran code that depends on the ability to alias dummy arguments. `-fno-globals' Disable diagnostics about inter-procedural analysis problems, such as disagreements about the type of a function or a procedure's argument, that might cause a compiler crash when attempting to inline a reference to a procedure within a program unit. (The diagnostics themselves are still produced, but as warnings, unless `-Wno-globals' is specified, in which case no relevant diagnostics are produced.) Further, this option disables such inlining, to avoid compiler crashes resulting from incorrect code that would otherwise be diagnosed. As such, this option might be quite useful when compiling existing, "working" code that happens to have a few bugs that do not generally show themselves, but which `g77' diagnoses. Use of this option therefore has the effect of instructing `g77' to behave more like it did up through version 0.5.19.1, when it paid little or no attention to disagreements between program units about a procedure's type and argument information, and when it performed no inlining of procedures (except statement functions). Without this option, `g77' defaults to performing the potentially inlining procedures as it started doing in version 0.5.20, but as of version 0.5.21, it also diagnoses disagreements that might cause such inlining to crash the compiler as (fatal) errors, and warns about similar disagreements that are currently believed to not likely to result in the compiler later crashing or producing incorrect code. `-fflatten-arrays' Use back end's C-like constructs (pointer plus offset) instead of its `ARRAY_REF' construct to handle all array references. _Note:_ This option is not supported. It is intended for use only by `g77' developers, to evaluate code-generation issues. It might be removed at any time. `-fbounds-check' `-ffortran-bounds-check' Enable generation of run-time checks for array subscripts and substring start and end points against the (locally) declared minimum and maximum values. The current implementation uses the `libf2c' library routine `s_rnge' to print the diagnostic. However, whereas `f2c' generates a single check per reference for a multi-dimensional array, of the computed offset against the valid offset range (0 through the size of the array), `g77' generates a single check per _subscript_ expression. This catches some cases of potential bugs that `f2c' does not, such as references to below the beginning of an assumed-size array. `g77' also generates checks for `CHARACTER' substring references, something `f2c' currently does not do. Use the new `-ffortran-bounds-check' option to specify bounds-checking for only the Fortran code you are compiling, not necessarily for code written in other languages. _Note:_ To provide more detailed information on the offending subscript, `g77' provides the `libg2c' run-time library routine `s_rnge' with somewhat differently-formatted information. Here's a sample diagnostic: Subscript out of range on file line 4, procedure rnge.f/bf. Attempt to access the -6-th element of variable b[subscript-2-of-2]. Aborted The above message indicates that the offending source line is line 4 of the file `rnge.f', within the program unit (or statement function) named `bf'. The offended array is named `b'. The offended array dimension is the second for a two-dimensional array, and the offending, computed subscript expression was `-6'. For a `CHARACTER' substring reference, the second line has this appearance: Attempt to access the 11-th element of variable a[start-substring]. This indicates that the offended `CHARACTER' variable or array is named `a', the offended substring position is the starting (leftmost) position, and the offending substring expression is `11'. (Though the verbage of `s_rnge' is not ideal for the purpose of the `g77' compiler, the above information should provide adequate diagnostic abilities to it users.) *Note Options for Code Generation Conventions: (gcc)Code Gen Options, for information on more options offered by the GBE shared by `g77' `gcc' and other GNU compilers. Some of these do _not_ work when compiling programs written in Fortran: `-fpcc-struct-return' `-freg-struct-return' You should not use these except strictly the same way as you used them to build the version of `libg2c' with which you will be linking all code compiled by `g77' with the same option. `-fshort-double' This probably either has no effect on Fortran programs, or makes them act loopy. `-fno-common' Do not use this when compiling Fortran programs, or there will be Trouble. `-fpack-struct' This probably will break any calls to the `libg2c' library, at the very least, even if it is built with the same option.  File: g77.info, Node: Environment Variables, Prev: Code Gen Options, Up: Invoking G77 Environment Variables Affecting GNU Fortran =========================================== GNU Fortran currently does not make use of any environment variables to control its operation above and beyond those that affect the operation of `gcc'. *Note Environment Variables Affecting GCC: (gcc)Environment Variables, for information on environment variables.  File: g77.info, Node: News, Next: Changes, Prev: Invoking G77, Up: Top News About GNU Fortran ********************** _`GCC' 3.4.x is the last edition of `GCC' to contain `g77' - from `GCC' 3.5 onwards, use `gfortran'_ Changes made to recent versions of GNU Fortran are listed below, with the most recent version first. The changes are generally listed in order: 1. Code-generation and run-time-library bug-fixes 2. Compiler and run-time-library crashes involving valid code that have been fixed 3. New features 4. Fixes and enhancements to existing features 5. New diagnostics 6. Internal improvements 7. Miscellany This order is not strict--for example, some items involve a combination of these elements. Note that two variants of `g77' are tracked below. The `egcs' variant is described vis-a-vis previous versions of `egcs' and/or an official FSF version, as appropriate. Note that all such variants are obsolete _as of July 1999_ - the information is retained here only for its historical value. Therefore, `egcs' versions sometimes have multiple listings to help clarify how they differ from other versions, though this can make getting a complete picture of what a particular `egcs' version contains somewhat more difficult. For information on bugs in the GCC-3.4.2 version of `g77', see *Note Known Bugs In GNU Fortran: Known Bugs. The following information was last updated on 2004-06-17: In `GCC' 3.4 versus `GCC' 3.3: ============================== * Problem Reports fixed (in chronological order of submission): `8485' g77 doesn't accept INTEGER*8 constant in PARAMETER multiplication. `11918' (libf2c) isatty does not call f_init. `12317' Incorrect documentation for Fortran debugging features. * Roger Sayle () fixed the remaining problems with regard to the support of INTEGER*8, INTEGER*2 and INTEGER*1 as a fallout of fixing PR 8485. In `GCC' 3.3 versus `GCC' 3.2: ============================== * Problem Reports fixed (in chronological order of submission): `1832' -list directed i/o overflow hangs, -fbounds-check doesn't detect `3924' g77 generates code which is rejected by GAS if COFF debugging info is requested `6286' Broken links on web pages `6367' (libf2c) multiple repeat counts confuse namelist read into array `6491' Logical operations error on logicals when using -fugly-logint `6742' Generation of C++ Prototype for FORTRAN and extern "C" `7113' Failure of g77.f-torture/execute/f90-intrinsic-bit.f -Os on irix6.5 `7236' (libf2c) OPEN(...,RECL=nnn,...) without ACCESS='DIRECT' should assume a direct access file `7278' g77 "bug"; the executable misbehave (use of options -O2 -fno-automatic gave wrong results) `7384' (libf2c) DATE_AND_TIME milliseconds field inactive on Windows `7388' Incorrect output with 0-based array of characters `8587' Double complex zero ** double precision number -> NaN instead of zero `9038' -ffixed-line-length-none -x f77-cpp-input gives: Warning: unknown register name line-length-none `9263' ICE caused by invalid PARAMETER in implied DO loop `10197' Direct access files not unformatted by default `10726' Documentation for function IDATE Intrinsic (UNIX) is wrong [fixed in 3.3.1]. * Richard Henderson () analyzed and improved the handling of (no-)aliasing information for dummy arguments and improved the optimization of induction variables in unrolled loops. In `GCC' 3.2 versus `GCC' 3.1: ============================== * Problem Reports fixed (in chronological order of submission): `7681' ICE in compensate_edge, at reg-stack.c:2591 `8308' gcc-3.x does not compile files with suffix .r (RATFOR) [Fixed in 3.2.1] `9258' [3.2/3.3/3.4 regression] ICE in compensate_edge, at reg-stack.c:2589 In `GCC' 3.1 (formerly known as g77-0.5.27) versus `GCC' 3.0: ============================================================= * Problem Reports fixed (in chronological order of submission): `947' Data statement initialization with subscript of kind INTEGER*2 `3743' Reference to intrinsic `ISHFT' invalid `3807' Function BESJN(integer,double) problems `3957' g77 -pipe -xf77-cpp-input sends output to stdout `4279' g77 -h" gives bogus output `4730' ICE on valid input using CALL EXIT(%VAL(...)) `4752' g77 -v -c -xf77-version /dev/null -xnone causes ice `4885' BACKSPACE example that doesn't work as of gcc/g77-3.0.x `5122' g77 rejects accepted use of INTEGER*2 as type of DATA statement loop index `5397' ICE on compiling source with 540 000 000 REAL array `5473' ICE on BESJN(integer*8,real) `5837' bug in loop unrolling `6106' sparc-sun-solaris2.7 gcc-3.1 extra g77 testsuite failures w/-m64 `6138' Incorrect acces of integer*1 variables on PA `6304' Failure of LAPACK test dtest on irix6.5 with -mabi=64 -O2 * `g77' now has its man page generated from the texinfo documentation, to guarantee that it remains up to date. * `g77' used to reject the following program on 32-bit targets: PROGRAM PROG DIMENSION A(140 000 000) END with the message: prog.f: In program `prog': prog.f:2: DIMENSION A(140 000 000) ^ Array `a' at (^) is too large to handle because 140 000 000 REALs is larger than the largest bit-extent that can be expressed in 32 bits. However, bit-sizes never play a role after offsets have been converted to byte addresses. Therefore this check has been removed, and the limit is now 2 Gbyte of memory (around 530 000 000 REALs). Note: On GNU/Linux systems one has to compile and link programs that occupy more than 1 Gbyte statically, i.e. `g77 -static ...'. * Based on work done by Juergen Pfeifer () libf2c is now a shared library. One can still link in all objects with the program by specifying the `-static' option. * Robert Anderson () thought up a two line change that enables g77 to compile such code as: SUBROUTINE SUB(A, N) DIMENSION N(2) DIMENSION A(N(1),N(2)) A(1,1) = 1. END Note the use of array elements in the bounds of the adjustable array A. * George Helffrich () implemented a change in substring index checking (when specifying `-fbounds-check') that permits the use of zero length substrings of the form `string(1:0)'. * Based on code developed by Pedro Vazquez (), the `libf2c' library is now able to read and write files larger than 2 Gbyte on 32-bit target machines, if the operating system supports this. In 0.5.26, `GCC' 3.0 versus `GCC' 2.95: ======================================= * When a REWIND was issued after a WRITE statement on an unformatted file, the implicit truncation was performed by copying the truncated file to /tmp and copying the result back. This has been fixed by using the `ftruncate' OS function. Thanks go to the GAMESS developers for bringing this to our attention. * Using options `-g', `-ggdb' or `-gdwarf[-2]' (where appropriate for your target) now also enables debugging information for COMMON BLOCK and EQUIVALENCE items to be emitted. Thanks go to Andrew Vaught () and George Helffrich () for fixing this longstanding problem. * It is not necessary anymore to use the option `-femulate-complex' to compile Fortran code using COMPLEX arithmetic, even on 64-bit machines (like the Alpha). This will improve code generation. * INTRINSIC arithmetic functions are now treated as routines that do not depend on anything but their argument(s). This enables further instruction scheduling, because it is known that they cannot read or modify arbitrary locations. * Upgrade to `libf2c' as of 2000-12-05. This fixes a bug where a namelist containing initialization of LOGICAL items and a variable starting with T or F would be read incorrectly. * The `TtyNam' intrinsics now set NAME to all spaces (at run time) if the system has no `ttyname' implementation available. * Upgrade to `libf2c' as of 1999-06-28. This fixes a bug whereby input to a `NAMELIST' read involving a repeat count, such as `K(5)=10*3', was not properly handled by `libf2c'. The first item was written to `K(5)', but the remaining nine were written elsewhere (still within the array), not necessarily starting at `K(6)'. In 0.5.25, `GCC' 2.95 (`EGCS' 1.2) versus `EGCS' 1.1.2: ======================================================= * `g77' no longer generates bad code for assignments, or other conversions, of `REAL' or `COMPLEX' constant expressions to type `INTEGER(KIND=2)' (often referred to as `INTEGER*8'). For example, `INTEGER*8 J; J = 4E10' now works as documented. * `g77' no longer truncates `INTEGER(KIND=2)' (usually `INTEGER*8') subscript expressions when evaluating array references on systems with pointers widers than `INTEGER(KIND=1)' (such as Alphas). * `g77' no longer generates bad code for an assignment to a `COMPLEX' variable or array that partially overlaps one or more of the sources of the same assignment (a very rare construction). It now assigns through a temporary, in cases where such partial overlap is deemed possible. * `libg2c' (`libf2c') no longer loses track of the file being worked on during a `BACKSPACE' operation. * `libg2c' (`libf2c') fixes a bug whereby input to a `NAMELIST' read involving a repeat count, such as `K(5)=10*3', was not properly handled by `libf2c'. The first item was written to `K(5)', but the remaining nine were written elsewhere (still within the array), not necessarily starting at `K(6)'. * Automatic arrays now seem to be working on HP-UX systems. * The `Date' intrinsic now returns the correct result on big-endian systems. * Fix `g77' so it no longer crashes when compiling I/O statements using keywords that define `INTEGER' values, such as `IOSTAT=J', where J is other than default `INTEGER' (such as `INTEGER*2'). Instead, it issues a diagnostic. * Fix `g77' so it properly handles `DATA A/RPT*VAL/', where RPT is not default `INTEGER', such as `INTEGER*2', instead of producing a spurious diagnostic. Also fix `DATA (A(I),I=1,N)', where `N' is not default `INTEGER' to work instead of crashing `g77'. * The `-ax' option is now obeyed when compiling Fortran programs. (It is passed to the `f771' driver.) * The new `-fbounds-check' option causes `g77' to compile run-time bounds checks of array subscripts, as well as of substring start and end points. * `libg2c' now supports building as multilibbed library, which provides better support for systems that require options such as `-mieee' to work properly. * Source file names with the suffixes `.FOR' and `.FPP' now are recognized by `g77' as if they ended in `.for' and `.fpp', respectively. * The order of arguments to the _subroutine_ forms of the `CTime', `DTime', `ETime', and `TtyNam' intrinsics has been swapped. The argument serving as the returned value for the corresponding function forms now is the _second_ argument, making these consistent with the other subroutine forms of `libU77' intrinsics. * `g77' now warns about a reference to an intrinsic that has an interface that is not Year 2000 (Y2K) compliant. Also, `libg2c' has been changed to increase the likelihood of catching references to the implementations of these intrinsics using the `EXTERNAL' mechanism (which would avoid the new warnings). *Note Year 2000 (Y2K) Problems::, for more information. * `g77' now warns about a reference to a function when the corresponding _subsequent_ function program unit disagrees with the reference concerning the type of the function. * `-fno-emulate-complex' is now the default option. This should result in improved performance of code that uses the `COMPLEX' data type. * The `-malign-double' option now reliably aligns _all_ double-precision variables and arrays on Intel x86 targets. * Even without the `-malign-double' option, `g77' reliably aligns local double-precision variables that are not in `EQUIVALENCE' areas and not `SAVE''d. * `g77' now open-codes ("inlines") division of `COMPLEX' operands instead of generating a run-time call to the `libf2c' routines `c_div' or `z_div', unless the `-Os' option is specified. * `g77' no longer generates code to maintain `errno', a C-language concept, when performing operations such as the `SqRt' intrinsic. * `g77' developers can temporarily use the `-fflatten-arrays' option to compare how the compiler handles code generation using C-like constructs as compared to the Fortran-like method constructs normally used. * A substantial portion of the `g77' front end's code-generation component was rewritten. It now generates code using facilities more robustly supported by the `gcc' back end. One effect of this rewrite is that some codes no longer produce a spurious "label LAB used before containing binding contour" message. * Support for the `-fugly' option has been removed. * Improve documentation and indexing, including information on Year 2000 (Y2K) compliance, and providing more information on internals of the front end. * Upgrade to `libf2c' as of 1999-05-10. In 0.5.24 versus 0.5.23: ======================== There is no `g77' version 0.5.24 at this time, or planned. 0.5.24 is the version number designated for bug fixes and, perhaps, some new features added, to 0.5.23. Version 0.5.23 requires `gcc' 2.8.1, as 0.5.24 was planned to require. Due to `EGCS' becoming `GCC' (which is now an acronym for "GNU Compiler Collection"), and `EGCS' 1.2 becoming officially designated `GCC' 2.95, there seems to be no need for an actual 0.5.24 release. To reduce the confusion already resulting from use of 0.5.24 to designate `g77' versions within `EGCS' versions 1.0 and 1.1, as well as in versions of `g77' documentation and notices during that period, "mainline" `g77' version numbering resumes at 0.5.25 with `GCC' 2.95 (`EGCS' 1.2), skipping over 0.5.24 as a placeholder version number. To repeat, there is no `g77' 0.5.24, but there is now a 0.5.25. Please remain calm and return to your keypunch units. In `EGCS' 1.1.2 versus `EGCS' 1.1.1: ==================================== * Fix the `IDate' intrinsic (VXT) (in `libg2c') so the returned year is in the documented, non-Y2K-compliant range of 0-99, instead of being returned as 100 in the year 2000. *Note IDate Intrinsic (VXT)::, for more information. * Fix the `Date_and_Time' intrinsic (in `libg2c') to return the milliseconds value properly in VALUES(8). * Fix the `LStat' intrinsic (in `libg2c') to return device-ID information properly in SARRAY(7). * Improve documentation. In `EGCS' 1.1.1 versus `EGCS' 1.1: ================================== * Fix `libg2c' so it performs an implicit `ENDFILE' operation (as appropriate) whenever a `REWIND' is done. (This bug was introduced in 0.5.23 and `egcs' 1.1 in `g77''s version of `libf2c'.) * Fix `libg2c' so it no longer crashes with a spurious diagnostic upon doing any I/O following a direct formatted write. (This bug was introduced in 0.5.23 and `egcs' 1.1 in `g77''s version of `libf2c'.) * Fix `g77' so it no longer crashes compiling references to the `Rand' intrinsic on some systems. * Fix `g77' portion of installation process so it works better on some systems (those with shells requiring `else true' clauses on `if' constructs for the completion code to be set properly). In `EGCS' 1.1 versus `EGCS' 1.0.3: ================================== * Fix bugs in the `libU77' intrinsic `HostNm' that wrote one byte beyond the end of its `CHARACTER' argument, and in the `libU77' intrinsics `GMTime' and `LTime' that overwrote their arguments. * Assumed arrays with negative bounds (such as `REAL A(-1:*)') no longer elicit spurious diagnostics from `g77', even on systems with pointers having different sizes than integers. This bug is not known to have existed in any recent version of `gcc'. It was introduced in an early release of `egcs'. * Valid combinations of `EXTERNAL', passing that external as a dummy argument without explicitly giving it a type, and, in a subsequent program unit, referencing that external as an external function with a different type no longer crash `g77'. * `CASE DEFAULT' no longer crashes `g77'. * The `-Wunused' option no longer issues a spurious warning about the "master" procedure generated by `g77' for procedures containing `ENTRY' statements. * Support `FORMAT(I)' when EXPR is a compile-time constant `INTEGER' expression. * Fix `g77' `-g' option so procedures that use `ENTRY' can be stepped through, line by line, in `gdb'. * Allow any `REAL' argument to intrinsics `Second' and `CPU_Time'. * Use `tempnam', if available, to open scratch files (as in `OPEN(STATUS='SCRATCH')') so that the `TMPDIR' environment variable, if present, is used. * `g77''s version of `libf2c' separates out the setting of global state (such as command-line arguments and signal handling) from `main.o' into distinct, new library archive members. This should make it easier to write portable applications that have their own (non-Fortran) `main()' routine properly set up the `libf2c' environment, even when `libf2c' (now `libg2c') is a shared library. * `g77' no longer installs the `f77' command and `f77.1' man page in the `/usr' or `/usr/local' hierarchy, even if the `f77-install-ok' file exists in the source or build directory. See the installation documentation for more information. * `g77' no longer installs the `libf2c.a' library and `f2c.h' include file in the `/usr' or `/usr/local' hierarchy, even if the `f2c-install-ok' or `f2c-exists-ok' files exist in the source or build directory. See the installation documentation for more information. * The `libf2c.a' library produced by `g77' has been renamed to `libg2c.a'. It is installed only in the `gcc' "private" directory hierarchy, `gcc-lib'. This allows system administrators and users to choose which version of the `libf2c' library from `netlib' they wish to use on a case-by-case basis. See the installation documentation for more information. * The `f2c.h' include (header) file produced by `g77' has been renamed to `g2c.h'. It is installed only in the `gcc' "private" directory hierarchy, `gcc-lib'. This allows system administrators and users to choose which version of the include file from `netlib' they wish to use on a case-by-case basis. See the installation documentation for more information. * The `g77' command now expects the run-time library to be named `libg2c.a' instead of `libf2c.a', to ensure that a version other than the one built and installed as part of the same `g77' version is picked up. * During the configuration and build process, `g77' creates subdirectories it needs only as it needs them. Other cleaning up of the configuration and build process has been performed as well. * `install-info' now used to update the directory of Info documentation to contain an entry for `g77' (during installation). * Some diagnostics have been changed from warnings to errors, to prevent inadvertent use of the resulting, probably buggy, programs. These mostly include diagnostics about use of unsupported features in the `OPEN', `INQUIRE', `READ', and `WRITE' statements, and about truncations of various sorts of constants. * Improve compilation of `FORMAT' expressions so that a null byte is appended to the last operand if it is a constant. This provides a cleaner run-time diagnostic as provided by `libf2c' for statements like `PRINT '(I1', 42'. * Improve documentation and indexing. * The upgrade to `libf2c' as of 1998-06-18 should fix a variety of problems, including those involving some uses of the `T' format specifier, and perhaps some build (porting) problems as well. In `EGCS' 1.1 versus `g77' 0.5.23: ================================== * Fix a code-generation bug that afflicted Intel x86 targets when `-O2' was specified compiling, for example, an old version of the `DNRM2' routine. The x87 coprocessor stack was being mismanaged in cases involving assigned `GOTO' and `ASSIGN'. * `g77' no longer produces incorrect code and initial values for `EQUIVALENCE' and `COMMON' aggregates that, due to "unnatural" ordering of members vis-a-vis their types, require initial padding. * Fix `g77' crash compiling code containing the construct `CMPLX(0.)' or similar. * `g77' no longer crashes when compiling code containing specification statements such as `INTEGER(KIND=7) PTR'. * `g77' no longer crashes when compiling code such as `J = SIGNAL(1, 2)'. * `g77' now treats `%LOC(EXPR)' and `LOC(EXPR)' as "ordinary" expressions when they are used as arguments in procedure calls. This change applies only to global (filewide) analysis, making it consistent with how `g77' actually generates code for these cases. Previously, `g77' treated these expressions as denoting special "pointer" arguments for the purposes of filewide analysis. * Fix `g77' crash (or apparently infinite run-time) when compiling certain complicated expressions involving `COMPLEX' arithmetic (especially multiplication). * Align static double-precision variables and arrays on Intel x86 targets regardless of whether `-malign-double' is specified. Generally, this affects only local variables and arrays having the `SAVE' attribute or given initial values via `DATA'. * The `g77' driver now ensures that `-lg2c' is specified in the link phase prior to any occurrence of `-lm'. This prevents accidentally linking to a routine in the SunOS4 `-lm' library when the generated code wants to link to the one in `libf2c' (`libg2c'). * `g77' emits more debugging information when `-g' is used. This new information allows, for example, `which __g77_length_a' to be used in `gdb' to determine the type of the phantom length argument supplied with `CHARACTER' variables. This information pertains to internally-generated type, variable, and other information, not to the longstanding deficiencies vis-a-vis `COMMON' and `EQUIVALENCE'. * The F90 `Date_and_Time' intrinsic now is supported. * The F90 `System_Clock' intrinsic allows the optional arguments (except for the `Count' argument) to be omitted. * Upgrade to `libf2c' as of 1998-06-18. * Improve documentation and indexing. In 0.5.23 versus 0.5.22: ======================== * This release contains several regressions against version 0.5.22 of `g77', due to using the "vanilla" `gcc' back end instead of patching it to fix a few bugs and improve performance in a few cases. Features that have been dropped from this version of `g77' due to their being implemented via `g77'-specific patches to the `gcc' back end in previous releases include: - Support for `__restrict__' keyword, the options `-fargument-alias', `-fargument-noalias', and `-fargument-noalias-global', and the corresponding alias-analysis code. (`egcs' has the alias-analysis code, but not the `__restrict__' keyword. `egcs' `g77' users benefit from the alias-analysis code despite the lack of the `__restrict__' keyword, which is a C-language construct.) - Support for the GNU compiler options `-fmove-all-movables', `-freduce-all-givs', and `-frerun-loop-opt'. (`egcs' supports these options. `g77' users of `egcs' benefit from them even if they are not explicitly specified, because the defaults are optimized for `g77' users.) - Support for the `-W' option warning about integer division by zero. - The Intel x86-specific option `-malign-double' applying to stack-allocated data as well as statically-allocate data. Note that the `gcc/f/gbe/' subdirectory has been removed from this distribution as a result of `g77' no longer including patches for the `gcc' back end. * Fix bugs in the `libU77' intrinsic `HostNm' that wrote one byte beyond the end of its `CHARACTER' argument, and in the `libU77' intrinsics `GMTime' and `LTime' that overwrote their arguments. * Support `gcc' version 2.8, and remove support for prior versions of `gcc'. * Remove support for the `--driver' option, as `g77' now does all the driving, just like `gcc'. * `CASE DEFAULT' no longer crashes `g77'. * Valid combinations of `EXTERNAL', passing that external as a dummy argument without explicitly giving it a type, and, in a subsequent program unit, referencing that external as an external function with a different type no longer crash `g77'. * `g77' no longer installs the `f77' command and `f77.1' man page in the `/usr' or `/usr/local' hierarchy, even if the `f77-install-ok' file exists in the source or build directory. See the installation documentation for more information. * `g77' no longer installs the `libf2c.a' library and `f2c.h' include file in the `/usr' or `/usr/local' hierarchy, even if the `f2c-install-ok' or `f2c-exists-ok' files exist in the source or build directory. See the installation documentation for more information. * The `libf2c.a' library produced by `g77' has been renamed to `libg2c.a'. It is installed only in the `gcc' "private" directory hierarchy, `gcc-lib'. This allows system administrators and users to choose which version of the `libf2c' library from `netlib' they wish to use on a case-by-case basis. See the installation documentation for more information. * The `f2c.h' include (header) file produced by `g77' has been renamed to `g2c.h'. It is installed only in the `gcc' "private" directory hierarchy, `gcc-lib'. This allows system administrators and users to choose which version of the include file from `netlib' they wish to use on a case-by-case basis. See the installation documentation for more information. * The `g77' command now expects the run-time library to be named `libg2c.a' instead of `libf2c.a', to ensure that a version other than the one built and installed as part of the same `g77' version is picked up. * The `-Wunused' option no longer issues a spurious warning about the "master" procedure generated by `g77' for procedures containing `ENTRY' statements. * `g77''s version of `libf2c' separates out the setting of global state (such as command-line arguments and signal handling) from `main.o' into distinct, new library archive members. This should make it easier to write portable applications that have their own (non-Fortran) `main()' routine properly set up the `libf2c' environment, even when `libf2c' (now `libg2c') is a shared library. * During the configuration and build process, `g77' creates subdirectories it needs only as it needs them, thus avoiding unnecessary creation of, for example, `stage1/f/runtime' when doing a non-bootstrap build. Other cleaning up of the configuration and build process has been performed as well. * `install-info' now used to update the directory of Info documentation to contain an entry for `g77' (during installation). * Some diagnostics have been changed from warnings to errors, to prevent inadvertent use of the resulting, probably buggy, programs. These mostly include diagnostics about use of unsupported features in the `OPEN', `INQUIRE', `READ', and `WRITE' statements, and about truncations of various sorts of constants. * Improve documentation and indexing. * Upgrade to `libf2c' as of 1998-04-20. This should fix a variety of problems, including those involving some uses of the `T' format specifier, and perhaps some build (porting) problems as well. In 0.5.22 versus 0.5.21: ======================== * Fix code generation for iterative `DO' loops that have one or more references to the iteration variable, or to aliases of it, in their control expressions. For example, `DO 10 J=2,J' now is compiled correctly. * Fix a code-generation bug that afflicted Intel x86 targets when `-O2' was specified compiling, for example, an old version of the `DNRM2' routine. The x87 coprocessor stack was being mismanaged in cases involving assigned `GOTO' and `ASSIGN'. * Fix `DTime' intrinsic so as not to truncate results to integer values (on some systems). * Fix `Signal' intrinsic so it offers portable support for 64-bit systems (such as Digital Alphas running GNU/Linux). * Fix run-time crash involving `NAMELIST' on 64-bit machines such as Alphas. * Fix `g77' version of `libf2c' so it no longer produces a spurious `I/O recursion' diagnostic at run time when an I/O operation (such as `READ *,I') is interrupted in a manner that causes the program to be terminated via the `f_exit' routine (such as via `C-c'). * Fix `g77' crash triggered by `CASE' statement with an omitted lower or upper bound. * Fix `g77' crash compiling references to `CPU_Time' intrinsic. * Fix `g77' crash (or apparently infinite run-time) when compiling certain complicated expressions involving `COMPLEX' arithmetic (especially multiplication). * Fix `g77' crash on statements such as `PRINT *, (REAL(Z(I)),I=1,2)', where `Z' is `DOUBLE COMPLEX'. * Fix a `g++' crash. * Support `FORMAT(I)' when EXPR is a compile-time constant `INTEGER' expression. * Fix `g77' `-g' option so procedures that use `ENTRY' can be stepped through, line by line, in `gdb'. * Fix a profiling-related bug in `gcc' back end for Intel x86 architecture. * Allow any `REAL' argument to intrinsics `Second' and `CPU_Time'. * Allow any numeric argument to intrinsics `Int2' and `Int8'. * Use `tempnam', if available, to open scratch files (as in `OPEN(STATUS='SCRATCH')') so that the `TMPDIR' environment variable, if present, is used. * Rename the `gcc' keyword `restrict' to `__restrict__', to avoid rejecting valid, existing, C programs. Support for `restrict' is now more like support for `complex'. * Fix `-fpedantic' to not reject procedure invocations such as `I=J()' and `CALL FOO()'. * Fix `-fugly-comma' to affect invocations of only external procedures. Restore rejection of gratuitous trailing omitted arguments to intrinsics, as in `I=MAX(3,4,,)'. * Fix compiler so it accepts `-fgnu-intrinsics-*' and `-fbadu77-intrinsics-*' options. * Improve diagnostic messages from `libf2c' so it is more likely that the printing of the active format string is limited to the string, with no trailing garbage being printed. (Unlike `f2c', `g77' did not append a null byte to its compiled form of every format string specified via a `FORMAT' statement. However, `f2c' would exhibit the problem anyway for a statement like `PRINT '(I)garbage', 1' by printing `(I)garbage' as the format string.) * Improve compilation of `FORMAT' expressions so that a null byte is appended to the last operand if it is a constant. This provides a cleaner run-time diagnostic as provided by `libf2c' for statements like `PRINT '(I1', 42'. * Fix various crashes involving code with diagnosed errors. * Fix cross-compilation bug when configuring `libf2c'. * Improve diagnostics. * Improve documentation and indexing. * Upgrade to `libf2c' as of 1997-09-23. This fixes a formatted-I/O bug that afflicted 64-bit systems with 32-bit integers (such as Digital Alpha running GNU/Linux). In `EGCS' 1.0.2 versus `EGCS' 1.0.1: ==================================== * Fix `g77' crash triggered by `CASE' statement with an omitted lower or upper bound. * Fix `g77' crash on statements such as `PRINT *, (REAL(Z(I)),I=1,2)', where `Z' is `DOUBLE COMPLEX'. * Fix `-fPIC' (such as compiling for ELF targets) on the Intel x86 architecture target so invalid assembler code is no longer produced. * Fix `-fpedantic' to not reject procedure invocations such as `I=J()' and `CALL FOO()'. * Fix `-fugly-comma' to affect invocations of only external procedures. Restore rejection of gratuitous trailing omitted arguments to intrinsics, as in `I=MAX(3,4,,)'. * Fix compiler so it accepts `-fgnu-intrinsics-*' and `-fbadu77-intrinsics-*' options. In `EGCS' 1.0.1 versus `EGCS' 1.0: ================================== * Fix run-time crash involving `NAMELIST' on 64-bit machines such as Alphas. In `EGCS' 1.0 versus `g77' 0.5.21: ================================== * Version 1.0 of `egcs' contains several regressions against version 0.5.21 of `g77', due to using the "vanilla" `gcc' back end instead of patching it to fix a few bugs and improve performance in a few cases. Features that have been dropped from this version of `g77' due to their being implemented via `g77'-specific patches to the `gcc' back end in previous releases include: - Support for the C-language `restrict' keyword. - Support for the `-W' option warning about integer division by zero. - The Intel x86-specific option `-malign-double' applying to stack-allocated data as well as statically-allocate data. Note that the `gcc/f/gbe/' subdirectory has been removed from this distribution as a result of `g77' being fully integrated with the `egcs' variant of the `gcc' back end. * Fix code generation for iterative `DO' loops that have one or more references to the iteration variable, or to aliases of it, in their control expressions. For example, `DO 10 J=2,J' now is compiled correctly. * Fix `DTime' intrinsic so as not to truncate results to integer values (on some systems). * Some Fortran code, miscompiled by `g77' built on `gcc' version 2.8.1 on m68k-next-nextstep3 configurations when using the `-O2' option, is now compiled correctly. It is believed that a C function known to miscompile on that configuration when using the `-O2 -funroll-loops' options also is now compiled correctly. * Remove support for non-`egcs' versions of `gcc'. * Remove support for the `--driver' option, as `g77' now does all the driving, just like `gcc'. * Allow any numeric argument to intrinsics `Int2' and `Int8'. * Improve diagnostic messages from `libf2c' so it is more likely that the printing of the active format string is limited to the string, with no trailing garbage being printed. (Unlike `f2c', `g77' did not append a null byte to its compiled form of every format string specified via a `FORMAT' statement. However, `f2c' would exhibit the problem anyway for a statement like `PRINT '(I)garbage', 1' by printing `(I)garbage' as the format string.) * Upgrade to `libf2c' as of 1997-09-23. This fixes a formatted-I/O bug that afflicted 64-bit systems with 32-bit integers (such as Digital Alpha running GNU/Linux). In 0.5.21: ========== * Fix a code-generation bug introduced by 0.5.20 caused by loop unrolling (by specifying `-funroll-loops' or similar). This bug afflicted all code compiled by version 2.7.2.2.f.2 of `gcc' (C, C++, Fortran, and so on). * Fix a code-generation bug manifested when combining local `EQUIVALENCE' with a `DATA' statement that follows the first executable statement (or is treated as an executable-context statement as a result of using the `-fpedantic' option). * Fix a compiler crash that occurred when an integer division by a constant zero is detected. Instead, when the `-W' option is specified, the `gcc' back end issues a warning about such a case. This bug afflicted all code compiled by version 2.7.2.2.f.2 of `gcc' (C, C++, Fortran, and so on). * Fix a compiler crash that occurred in some cases of procedure inlining. (Such cases became more frequent in 0.5.20.) * Fix a compiler crash resulting from using `DATA' or similar to initialize a `COMPLEX' variable or array to zero. * Fix compiler crashes involving use of `AND', `OR', or `XOR' intrinsics. * Fix compiler bug triggered when using a `COMMON' or `EQUIVALENCE' variable as the target of an `ASSIGN' or assigned-`GOTO' statement. * Fix compiler crashes due to using the name of a some non-standard intrinsics (such as `FTell' or `FPutC') as such and as the name of a procedure or common block. Such dual use of a name in a program is allowed by the standard. * Place automatic arrays on the stack, even if `SAVE' or the `-fno-automatic' option is in effect. This avoids a compiler crash in some cases. * The `-malign-double' option now reliably aligns `DOUBLE PRECISION' optimally on Pentium and Pentium Pro architectures (586 and 686 in `gcc'). * New option `-Wno-globals' disables warnings about "suspicious" use of a name both as a global name and as the implicit name of an intrinsic, and warnings about disagreements over the number or natures of arguments passed to global procedures, or the natures of the procedures themselves. The default is to issue such warnings, which are new as of this version of `g77'. * New option `-fno-globals' disables diagnostics about potentially fatal disagreements analysis problems, such as disagreements over the number or natures of arguments passed to global procedures, or the natures of those procedures themselves. The default is to issue such diagnostics and flag the compilation as unsuccessful. With this option, the diagnostics are issued as warnings, or, if `-Wno-globals' is specified, are not issued at all. This option also disables inlining of global procedures, to avoid compiler crashes resulting from coding errors that these diagnostics normally would identify. * Diagnose cases where a reference to a procedure disagrees with the type of that procedure, or where disagreements about the number or nature of arguments exist. This avoids a compiler crash. * Fix parsing bug whereby `g77' rejected a second initialization specification immediately following the first's closing `/' without an intervening comma in a `DATA' statement, and the second specification was an implied-DO list. * Improve performance of the `gcc' back end so certain complicated expressions involving `COMPLEX' arithmetic (especially multiplication) don't appear to take forever to compile. * Fix a couple of profiling-related bugs in `gcc' back end. * Integrate GNU Ada's (GNAT's) changes to the back end, which consist almost entirely of bug fixes. These fixes are circa version 3.10p of GNAT. * Include some other `gcc' fixes that seem useful in `g77''s version of `gcc'. (See `gcc/ChangeLog' for details--compare it to that file in the vanilla `gcc-2.7.2.3.tar.gz' distribution.) * Fix `libU77' routines that accept file and other names to strip trailing blanks from them, for consistency with other implementations. Blanks may be forcibly appended to such names by appending a single null character (`CHAR(0)') to the significant trailing blanks. * Fix `CHMOD' intrinsic to work with file names that have embedded blanks, commas, and so on. * Fix `SIGNAL' intrinsic so it accepts an optional third `Status' argument. * Fix `IDATE()' intrinsic subroutine (VXT form) so it accepts arguments in the correct order. Documentation fixed accordingly, and for `GMTIME()' and `LTIME()' as well. * Make many changes to `libU77' intrinsics to support existing code more directly. Such changes include allowing both subroutine and function forms of many routines, changing `MCLOCK()' and `TIME()' to return `INTEGER(KIND=1)' values, introducing `MCLOCK8()' and `TIME8()' to return `INTEGER(KIND=2)' values, and placing functions that are intended to perform side effects in a new intrinsic group, `badu77'. * Improve `libU77' so it is more portable. * Add options `-fbadu77-intrinsics-delete', `-fbadu77-intrinsics-hide', and so on. * Fix crashes involving diagnosed or invalid code. * `g77' and `gcc' now do a somewhat better job detecting and diagnosing arrays that are too large to handle before these cause diagnostics during the assembler or linker phase, a compiler crash, or generation of incorrect code. * Make some fixes to alias analysis code. * Add support for `restrict' keyword in `gcc' front end. * Support `gcc' version 2.7.2.3 (modified by `g77' into version 2.7.2.3.f.1), and remove support for prior versions of `gcc'. * Incorporate GNAT's patches to the `gcc' back end into `g77''s, so GNAT users do not need to apply GNAT's patches to build both GNAT and `g77' from the same source tree. * Modify `make' rules and related code so that generation of Info documentation doesn't require compilation using `gcc'. Now, any ANSI C compiler should be adequate to produce the `g77' documentation (in particular, the tables of intrinsics) from scratch. * Add `INT2' and `INT8' intrinsics. * Add `CPU_TIME' intrinsic. * Add `ALARM' intrinsic. * `CTIME' intrinsic now accepts any `INTEGER' argument, not just `INTEGER(KIND=2)'. * Warn when explicit type declaration disagrees with the type of an intrinsic invocation. * Support `*f771' entry in `gcc' `specs' file. * Fix typo in `make' rule `g77-cross', used only for cross-compiling. * Fix `libf2c' build procedure to re-archive library if previous attempt to archive was interrupted. * Change `gcc' to unroll loops only during the last invocation (of as many as two invocations) of loop optimization. * Improve handling of `-fno-f2c' so that code that attempts to pass an intrinsic as an actual argument, such as `CALL FOO(ABS)', is rejected due to the fact that the run-time-library routine is, effectively, compiled with `-ff2c' in effect. * Fix `g77' driver to recognize `-fsyntax-only' as an option that inhibits linking, just like `-c' or `-S', and to recognize and properly handle the `-nostdlib', `-M', `-MM', `-nodefaultlibs', and `-Xlinker' options. * Upgrade to `libf2c' as of 1997-08-16. * Modify `libf2c' to consistently and clearly diagnose recursive I/O (at run time). * `g77' driver now prints version information (such as produced by `g77 -v') to `stderr' instead of `stdout'. * The `.r' suffix now designates a Ratfor source file, to be preprocessed via the `ratfor' command, available separately. * Fix some aspects of how `gcc' determines what kind of system is being configured and what kinds are supported. For example, GNU Linux/Alpha ELF systems now are directly supported. * Improve diagnostics. * Improve documentation and indexing. * Include all pertinent files for `libf2c' that come from `netlib.bell-labs.com'; give any such files that aren't quite accurate in `g77''s version of `libf2c' the suffix `.netlib'. * Reserve `INTEGER(KIND=0)' for future use. In 0.5.20: ========== * The `-fno-typeless-boz' option is now the default. This option specifies that non-decimal-radix constants using the prefixed-radix form (such as `Z'1234'') are to be interpreted as `INTEGER(KIND=1)' constants. Specify `-ftypeless-boz' to cause such constants to be interpreted as typeless. (Version 0.5.19 introduced `-fno-typeless-boz' and its inverse.) *Note Options Controlling Fortran Dialect: Fortran Dialect Options, for information on the `-ftypeless-boz' option. * Options `-ff90-intrinsics-enable' and `-fvxt-intrinsics-enable' now are the defaults. Some programs might use names that clash with intrinsic names defined (and now enabled) by these options or by the new `libU77' intrinsics. Users of such programs might need to compile them differently (using, for example, `-ff90-intrinsics-disable') or, better yet, insert appropriate `EXTERNAL' statements specifying that these names are not intended to be names of intrinsics. * The `ALWAYS_FLUSH' macro is no longer defined when building `libf2c', which should result in improved I/O performance, especially over NFS. _Note:_ If you have code that depends on the behavior of `libf2c' when built with `ALWAYS_FLUSH' defined, you will have to modify `libf2c' accordingly before building it from this and future versions of `g77'. *Note Output Assumed To Flush::, for more information. * Dave Love's implementation of `libU77' has been added to the version of `libf2c' distributed with and built as part of `g77'. `g77' now knows about the routines in this library as intrinsics. * New option `-fvxt' specifies that the source file is written in VXT Fortran, instead of GNU Fortran. *Note VXT Fortran::, for more information on the constructs recognized when the `-fvxt' option is specified. * The `-fvxt-not-f90' option has been deleted, along with its inverse, `-ff90-not-vxt'. If you used one of these deleted options, you should re-read the pertinent documentation to determine which options, if any, are appropriate for compiling your code with this version of `g77'. *Note Other Dialects::, for more information. * The `-fugly' option now issues a warning, as it likely will be removed in a future version. (Enabling all the `-fugly-*' options is unlikely to be feasible, or sensible, in the future, so users should learn to specify only those `-fugly-*' options they really need for a particular source file.) * The `-fugly-assumed' option, introduced in version 0.5.19, has been changed to better accommodate old and new code. *Note Ugly Assumed-Size Arrays::, for more information. * Make a number of fixes to the `g77' front end and the `gcc' back end to better support Alpha (AXP) machines. This includes providing at least one bug-fix to the `gcc' back end for Alphas. * Related to supporting Alpha (AXP) machines, the `LOC()' intrinsic and `%LOC()' construct now return values of `INTEGER(KIND=0)' type, as defined by the GNU Fortran language. This type is wide enough (holds the same number of bits) as the character-pointer type on the machine. On most machines, this won't make a difference, whereas, on Alphas and other systems with 64-bit pointers, the `INTEGER(KIND=0)' type is equivalent to `INTEGER(KIND=2)' (often referred to as `INTEGER*8') instead of the more common `INTEGER(KIND=1)' (often referred to as `INTEGER*4'). * Emulate `COMPLEX' arithmetic in the `g77' front end, to avoid bugs in `complex' support in the `gcc' back end. New option `-fno-emulate-complex' causes `g77' to revert the 0.5.19 behavior. * Fix bug whereby `REAL A(1)', for example, caused a compiler crash if `-fugly-assumed' was in effect and A was a local (automatic) array. That case is no longer affected by the new handling of `-fugly-assumed'. * Fix `g77' command driver so that `g77 -o foo.f' no longer deletes `foo.f' before issuing other diagnostics, and so the `-x' option is properly handled. * Enable inlining of subroutines and functions by the `gcc' back end. This works as it does for `gcc' itself--program units may be inlined for invocations that follow them in the same program unit, as long as the appropriate compile-time options are specified. * Dummy arguments are no longer assumed to potentially alias (overlap) other dummy arguments or `COMMON' areas when any of these are defined (assigned to) by Fortran code. This can result in faster and/or smaller programs when compiling with optimization enabled, though on some systems this effect is observed only when `-fforce-addr' also is specified. New options `-falias-check', `-fargument-alias', `-fargument-noalias', and `-fno-argument-noalias-global' control the way `g77' handles potential aliasing. *Note Aliasing Assumed To Work::, for detailed information on why the new defaults might result in some programs no longer working the way they did when compiled by previous versions of `g77'. * The `CONJG()' and `DCONJG()' intrinsics now are compiled in-line. * The bug-fix for 0.5.19.1 has been re-done. The `g77' compiler has been changed back to assume `libf2c' has no aliasing problems in its implementations of the `COMPLEX' (and `DOUBLE COMPLEX') intrinsics. The `libf2c' has been changed to have no such problems. As a result, 0.5.20 is expected to offer improved performance over 0.5.19.1, perhaps as good as 0.5.19 in most or all cases, due to this change alone. _Note:_ This change requires version 0.5.20 of `libf2c', at least, when linking code produced by any versions of `g77' other than 0.5.19.1. Use `g77 -v' to determine the version numbers of the `libF77', `libI77', and `libU77' components of the `libf2c' library. (If these version numbers are not printed--in particular, if the linker complains about unresolved references to names like `g77__fvers__'--that strongly suggests your installation has an obsolete version of `libf2c'.) * New option `-fugly-assign' specifies that the same memory locations are to be used to hold the values assigned by both statements `I = 3' and `ASSIGN 10 TO I', for example. (Normally, `g77' uses a separate memory location to hold assigned statement labels.) *Note Ugly Assigned Labels::, for more information. * `FORMAT' and `ENTRY' statements now are allowed to precede `IMPLICIT NONE' statements. * Produce diagnostic for unsupported `SELECT CASE' on `CHARACTER' type, instead of crashing, at compile time. * Fix crashes involving diagnosed or invalid code. * Change approach to building `libf2c' archive (`libf2c.a') so that members are added to it only when truly necessary, so the user that installs an already-built `g77' doesn't need to have write access to the build tree (whereas the user doing the build might not have access to install new software on the system). * Support `gcc' version 2.7.2.2 (modified by `g77' into version 2.7.2.2.f.2), and remove support for prior versions of `gcc'. * Upgrade to `libf2c' as of 1997-02-08, and fix up some of the build procedures. * Improve general build procedures for `g77', fixing minor bugs (such as deletion of any file named `f771' in the parent directory of `gcc/'). * Enable full support of `INTEGER(KIND=2)' (often referred to as `INTEGER*8') available in `libf2c' and `f2c.h' so that `f2c' users may make full use of its features via the `g77' version of `f2c.h' and the `INTEGER(KIND=2)' support routines in the `g77' version of `libf2c'. * Improve `g77' driver and `libf2c' so that `g77 -v' yields version information on the library. * The `SNGL' and `FLOAT' intrinsics now are specific intrinsics, instead of synonyms for the generic intrinsic `REAL'. * New intrinsics have been added. These are `REALPART', `IMAGPART', `COMPLEX', `LONG', and `SHORT'. * A new group of intrinsics, `gnu', has been added to contain the new `REALPART', `IMAGPART', and `COMPLEX' intrinsics. An old group, `dcp', has been removed. * Complain about industry-wide ambiguous references `REAL(EXPR)' and `AIMAG(EXPR)', where EXPR is `DOUBLE COMPLEX' (or any complex type other than `COMPLEX'), unless `-ff90' option specifies Fortran 90 interpretation or new `-fugly-complex' option, in conjunction with `-fnot-f90', specifies `f2c' interpretation. * Make improvements to diagnostics. * Speed up compiler a bit. * Improvements to documentation and indexing, including a new chapter containing information on one, later more, diagnostics that users are directed to pull up automatically via a message in the diagnostic itself. (Hence the menu item `M' for the node `Diagnostics' in the top-level menu of the Info documentation.) In previous versions: ===================== Information on previous versions is archived in `gcc/gcc/f/news.texi' following the test of the `DOC-OLDNEWS' macro.  File: g77.info, Node: Changes, Next: Language, Prev: News, Up: Top User-visible Changes ******************** This chapter describes changes to `g77' that are visible to the programmers who actually write and maintain Fortran code they compile with `g77'. Information on changes to installation procedures, changes to the documentation, and bug fixes is not provided here, unless it is likely to affect how users use `g77'. *Note News About GNU Fortran: News, for information on such changes to `g77'. Note that two variants of `g77' are tracked below. The `egcs' variant is described vis-a-vis previous versions of `egcs' and/or an official FSF version, as appropriate. Note that all such variants are obsolete _as of July 1999_ - the information is retained here only for its historical value. Therefore, `egcs' versions sometimes have multiple listings to help clarify how they differ from other versions, though this can make getting a complete picture of what a particular `egcs' version contains somewhat more difficult. For information on bugs in the GCC-3.4.2 version of `g77', see *Note Known Bugs In GNU Fortran: Known Bugs. The following information was last updated on 2004-06-17: In `GCC' 3.4 versus `GCC' 3.3: ============================== * Problem Reports fixed (in chronological order of submission): `8485' g77 doesn't accept INTEGER*8 constant in PARAMETER multiplication. `11918' (libf2c) isatty does not call f_init. `12317' Incorrect documentation for Fortran debugging features. * Roger Sayle () fixed the remaining problems with regard to the support of INTEGER*8, INTEGER*2 and INTEGER*1 as a fallout of fixing PR 8485. In `GCC' 3.3 versus `GCC' 3.2: ============================== * Problem Reports fixed (in chronological order of submission): `1832' -list directed i/o overflow hangs, -fbounds-check doesn't detect `3924' g77 generates code which is rejected by GAS if COFF debugging info is requested `6286' Broken links on web pages `6367' (libf2c) multiple repeat counts confuse namelist read into array `6491' Logical operations error on logicals when using -fugly-logint `6742' Generation of C++ Prototype for FORTRAN and extern "C" `7113' Failure of g77.f-torture/execute/f90-intrinsic-bit.f -Os on irix6.5 `7236' (libf2c) OPEN(...,RECL=nnn,...) without ACCESS='DIRECT' should assume a direct access file `7278' g77 "bug"; the executable misbehave (use of options -O2 -fno-automatic gave wrong results) `7384' (libf2c) DATE_AND_TIME milliseconds field inactive on Windows `7388' Incorrect output with 0-based array of characters `8587' Double complex zero ** double precision number -> NaN instead of zero `9038' -ffixed-line-length-none -x f77-cpp-input gives: Warning: unknown register name line-length-none `9263' ICE caused by invalid PARAMETER in implied DO loop `10197' Direct access files not unformatted by default `10726' Documentation for function IDATE Intrinsic (UNIX) is wrong [fixed in 3.3.1]. * Richard Henderson () analyzed and improved the handling of (no-)aliasing information for dummy arguments and improved the optimization of induction variables in unrolled loops. In `GCC' 3.2 versus `GCC' 3.1: ============================== * Problem Reports fixed (in chronological order of submission): `7681' ICE in compensate_edge, at reg-stack.c:2591 `8308' gcc-3.x does not compile files with suffix .r (RATFOR) [Fixed in 3.2.1] `9258' [3.2/3.3/3.4 regression] ICE in compensate_edge, at reg-stack.c:2589 In `GCC' 3.1 (formerly known as g77-0.5.27) versus `GCC' 3.0: ============================================================= * Problem Reports fixed (in chronological order of submission): `947' Data statement initialization with subscript of kind INTEGER*2 `3743' Reference to intrinsic `ISHFT' invalid `3807' Function BESJN(integer,double) problems `3957' g77 -pipe -xf77-cpp-input sends output to stdout `4279' g77 -h" gives bogus output `4730' ICE on valid input using CALL EXIT(%VAL(...)) `4752' g77 -v -c -xf77-version /dev/null -xnone causes ice `4885' BACKSPACE example that doesn't work as of gcc/g77-3.0.x `5122' g77 rejects accepted use of INTEGER*2 as type of DATA statement loop index `5397' ICE on compiling source with 540 000 000 REAL array `5473' ICE on BESJN(integer*8,real) `5837' bug in loop unrolling `6106' sparc-sun-solaris2.7 gcc-3.1 extra g77 testsuite failures w/-m64 `6138' Incorrect acces of integer*1 variables on PA `6304' Failure of LAPACK test dtest on irix6.5 with -mabi=64 -O2 * `g77' now has its man page generated from the texinfo documentation, to guarantee that it remains up to date. * `g77' used to reject the following program on 32-bit targets: PROGRAM PROG DIMENSION A(140 000 000) END with the message: prog.f: In program `prog': prog.f:2: DIMENSION A(140 000 000) ^ Array `a' at (^) is too large to handle because 140 000 000 REALs is larger than the largest bit-extent that can be expressed in 32 bits. However, bit-sizes never play a role after offsets have been converted to byte addresses. Therefore this check has been removed, and the limit is now 2 Gbyte of memory (around 530 000 000 REALs). Note: On GNU/Linux systems one has to compile and link programs that occupy more than 1 Gbyte statically, i.e. `g77 -static ...'. * Based on work done by Juergen Pfeifer () libf2c is now a shared library. One can still link in all objects with the program by specifying the `-static' option. * Robert Anderson () thought up a two line change that enables g77 to compile such code as: SUBROUTINE SUB(A, N) DIMENSION N(2) DIMENSION A(N(1),N(2)) A(1,1) = 1. END Note the use of array elements in the bounds of the adjustable array A. * George Helffrich () implemented a change in substring index checking (when specifying `-fbounds-check') that permits the use of zero length substrings of the form `string(1:0)'. * Based on code developed by Pedro Vazquez (), the `libf2c' library is now able to read and write files larger than 2 Gbyte on 32-bit target machines, if the operating system supports this. In 0.5.26, `GCC' 3.0 versus `GCC' 2.95: ======================================= * When a REWIND was issued after a WRITE statement on an unformatted file, the implicit truncation was performed by copying the truncated file to /tmp and copying the result back. This has been fixed by using the `ftruncate' OS function. Thanks go to the GAMESS developers for bringing this to our attention. * Using options `-g', `-ggdb' or `-gdwarf[-2]' (where appropriate for your target) now also enables debugging information for COMMON BLOCK and EQUIVALENCE items to be emitted. Thanks go to Andrew Vaught () and George Helffrich () for fixing this longstanding problem. * It is not necessary anymore to use the option `-femulate-complex' to compile Fortran code using COMPLEX arithmetic, even on 64-bit machines (like the Alpha). This will improve code generation. * INTRINSIC arithmetic functions are now treated as routines that do not depend on anything but their argument(s). This enables further instruction scheduling, because it is known that they cannot read or modify arbitrary locations. In 0.5.25, `GCC' 2.95 (`EGCS' 1.2) versus `EGCS' 1.1.2: ======================================================= * The new `-fbounds-check' option causes `g77' to compile run-time bounds checks of array subscripts, as well as of substring start and end points. * `libg2c' now supports building as multilibbed library, which provides better support for systems that require options such as `-mieee' to work properly. * Source file names with the suffixes `.FOR' and `.FPP' now are recognized by `g77' as if they ended in `.for' and `.fpp', respectively. * The order of arguments to the _subroutine_ forms of the `CTime', `DTime', `ETime', and `TtyNam' intrinsics has been swapped. The argument serving as the returned value for the corresponding function forms now is the _second_ argument, making these consistent with the other subroutine forms of `libU77' intrinsics. * `g77' now warns about a reference to an intrinsic that has an interface that is not Year 2000 (Y2K) compliant. Also, `libg2c' has been changed to increase the likelihood of catching references to the implementations of these intrinsics using the `EXTERNAL' mechanism (which would avoid the new warnings). *Note Year 2000 (Y2K) Problems::, for more information. * `-fno-emulate-complex' is now the default option. This should result in improved performance of code that uses the `COMPLEX' data type. * The `-malign-double' option now reliably aligns _all_ double-precision variables and arrays on Intel x86 targets. * `g77' no longer generates code to maintain `errno', a C-language concept, when performing operations such as the `SqRt' intrinsic. * Support for the `-fugly' option has been removed. In 0.5.24 versus 0.5.23: ======================== There is no `g77' version 0.5.24 at this time, or planned. 0.5.24 is the version number designated for bug fixes and, perhaps, some new features added, to 0.5.23. Version 0.5.23 requires `gcc' 2.8.1, as 0.5.24 was planned to require. Due to `EGCS' becoming `GCC' (which is now an acronym for "GNU Compiler Collection"), and `EGCS' 1.2 becoming officially designated `GCC' 2.95, there seems to be no need for an actual 0.5.24 release. To reduce the confusion already resulting from use of 0.5.24 to designate `g77' versions within `EGCS' versions 1.0 and 1.1, as well as in versions of `g77' documentation and notices during that period, "mainline" `g77' version numbering resumes at 0.5.25 with `GCC' 2.95 (`EGCS' 1.2), skipping over 0.5.24 as a placeholder version number. To repeat, there is no `g77' 0.5.24, but there is now a 0.5.25. Please remain calm and return to your keypunch units. In `EGCS' 1.1.2 versus `EGCS' 1.1.1: ==================================== In `EGCS' 1.1.1 versus `EGCS' 1.1: ================================== In `EGCS' 1.1 versus `EGCS' 1.0.3: ================================== * Support `FORMAT(I)' when EXPR is a compile-time constant `INTEGER' expression. * Fix `g77' `-g' option so procedures that use `ENTRY' can be stepped through, line by line, in `gdb'. * Allow any `REAL' argument to intrinsics `Second' and `CPU_Time'. * Use `tempnam', if available, to open scratch files (as in `OPEN(STATUS='SCRATCH')') so that the `TMPDIR' environment variable, if present, is used. * `g77''s version of `libf2c' separates out the setting of global state (such as command-line arguments and signal handling) from `main.o' into distinct, new library archive members. This should make it easier to write portable applications that have their own (non-Fortran) `main()' routine properly set up the `libf2c' environment, even when `libf2c' (now `libg2c') is a shared library. * The `g77' command now expects the run-time library to be named `libg2c.a' instead of `libf2c.a', to ensure that a version other than the one built and installed as part of the same `g77' version is picked up. * Some diagnostics have been changed from warnings to errors, to prevent inadvertent use of the resulting, probably buggy, programs. These mostly include diagnostics about use of unsupported features in the `OPEN', `INQUIRE', `READ', and `WRITE' statements, and about truncations of various sorts of constants. In `EGCS' 1.1 versus `g77' 0.5.23: ================================== * `g77' now treats `%LOC(EXPR)' and `LOC(EXPR)' as "ordinary" expressions when they are used as arguments in procedure calls. This change applies only to global (filewide) analysis, making it consistent with how `g77' actually generates code for these cases. Previously, `g77' treated these expressions as denoting special "pointer" arguments for the purposes of filewide analysis. * Align static double-precision variables and arrays on Intel x86 targets regardless of whether `-malign-double' is specified. Generally, this affects only local variables and arrays having the `SAVE' attribute or given initial values via `DATA'. * The `g77' driver now ensures that `-lg2c' is specified in the link phase prior to any occurrence of `-lm'. This prevents accidentally linking to a routine in the SunOS4 `-lm' library when the generated code wants to link to the one in `libf2c' (`libg2c'). * `g77' emits more debugging information when `-g' is used. This new information allows, for example, `which __g77_length_a' to be used in `gdb' to determine the type of the phantom length argument supplied with `CHARACTER' variables. This information pertains to internally-generated type, variable, and other information, not to the longstanding deficiencies vis-a-vis `COMMON' and `EQUIVALENCE'. * The F90 `Date_and_Time' intrinsic now is supported. * The F90 `System_Clock' intrinsic allows the optional arguments (except for the `Count' argument) to be omitted. In 0.5.23 versus 0.5.22: ======================== * This release contains several regressions against version 0.5.22 of `g77', due to using the "vanilla" `gcc' back end instead of patching it to fix a few bugs and improve performance in a few cases. Features that have been dropped from this version of `g77' due to their being implemented via `g77'-specific patches to the `gcc' back end in previous releases include: - Support for `__restrict__' keyword, the options `-fargument-alias', `-fargument-noalias', and `-fargument-noalias-global', and the corresponding alias-analysis code. (`egcs' has the alias-analysis code, but not the `__restrict__' keyword. `egcs' `g77' users benefit from the alias-analysis code despite the lack of the `__restrict__' keyword, which is a C-language construct.) - Support for the GNU compiler options `-fmove-all-movables', `-freduce-all-givs', and `-frerun-loop-opt'. (`egcs' supports these options. `g77' users of `egcs' benefit from them even if they are not explicitly specified, because the defaults are optimized for `g77' users.) - Support for the `-W' option warning about integer division by zero. - The Intel x86-specific option `-malign-double' applying to stack-allocated data as well as statically-allocate data. * Support `gcc' version 2.8, and remove support for prior versions of `gcc'. * Remove support for the `--driver' option, as `g77' now does all the driving, just like `gcc'. * The `g77' command now expects the run-time library to be named `libg2c.a' instead of `libf2c.a', to ensure that a version other than the one built and installed as part of the same `g77' version is picked up. * `g77''s version of `libf2c' separates out the setting of global state (such as command-line arguments and signal handling) from `main.o' into distinct, new library archive members. This should make it easier to write portable applications that have their own (non-Fortran) `main()' routine properly set up the `libf2c' environment, even when `libf2c' (now `libg2c') is a shared library. * Some diagnostics have been changed from warnings to errors, to prevent inadvertent use of the resulting, probably buggy, programs. These mostly include diagnostics about use of unsupported features in the `OPEN', `INQUIRE', `READ', and `WRITE' statements, and about truncations of various sorts of constants. In 0.5.22 versus 0.5.21: ======================== * Fix `Signal' intrinsic so it offers portable support for 64-bit systems (such as Digital Alphas running GNU/Linux). * Support `FORMAT(I)' when EXPR is a compile-time constant `INTEGER' expression. * Fix `g77' `-g' option so procedures that use `ENTRY' can be stepped through, line by line, in `gdb'. * Allow any `REAL' argument to intrinsics `Second' and `CPU_Time'. * Allow any numeric argument to intrinsics `Int2' and `Int8'. * Use `tempnam', if available, to open scratch files (as in `OPEN(STATUS='SCRATCH')') so that the `TMPDIR' environment variable, if present, is used. * Rename the `gcc' keyword `restrict' to `__restrict__', to avoid rejecting valid, existing, C programs. Support for `restrict' is now more like support for `complex'. * Fix `-fugly-comma' to affect invocations of only external procedures. Restore rejection of gratuitous trailing omitted arguments to intrinsics, as in `I=MAX(3,4,,)'. * Fix compiler so it accepts `-fgnu-intrinsics-*' and `-fbadu77-intrinsics-*' options. In `EGCS' 1.0.2 versus `EGCS' 1.0.1: ==================================== * Fix compiler so it accepts `-fgnu-intrinsics-*' and `-fbadu77-intrinsics-*' options. In `EGCS' 1.0.1 versus `EGCS' 1.0: ================================== In `EGCS' 1.0 versus `g77' 0.5.21: ================================== * Version 1.0 of `egcs' contains several regressions against version 0.5.21 of `g77', due to using the "vanilla" `gcc' back end instead of patching it to fix a few bugs and improve performance in a few cases. Features that have been dropped from this version of `g77' due to their being implemented via `g77'-specific patches to the `gcc' back end in previous releases include: - Support for the C-language `restrict' keyword. - Support for the `-W' option warning about integer division by zero. - The Intel x86-specific option `-malign-double' applying to stack-allocated data as well as statically-allocate data. * Remove support for the `--driver' option, as `g77' now does all the driving, just like `gcc'. * Allow any numeric argument to intrinsics `Int2' and `Int8'. In 0.5.21: ========== * When the `-W' option is specified, `gcc', `g77', and other GNU compilers that incorporate the `gcc' back end as modified by `g77', issue a warning about integer division by constant zero. * New option `-Wno-globals' disables warnings about "suspicious" use of a name both as a global name and as the implicit name of an intrinsic, and warnings about disagreements over the number or natures of arguments passed to global procedures, or the natures of the procedures themselves. The default is to issue such warnings, which are new as of this version of `g77'. * New option `-fno-globals' disables diagnostics about potentially fatal disagreements analysis problems, such as disagreements over the number or natures of arguments passed to global procedures, or the natures of those procedures themselves. The default is to issue such diagnostics and flag the compilation as unsuccessful. With this option, the diagnostics are issued as warnings, or, if `-Wno-globals' is specified, are not issued at all. This option also disables inlining of global procedures, to avoid compiler crashes resulting from coding errors that these diagnostics normally would identify. * Fix `libU77' routines that accept file and other names to strip trailing blanks from them, for consistency with other implementations. Blanks may be forcibly appended to such names by appending a single null character (`CHAR(0)') to the significant trailing blanks. * Fix `CHMOD' intrinsic to work with file names that have embedded blanks, commas, and so on. * Fix `SIGNAL' intrinsic so it accepts an optional third `Status' argument. * Make many changes to `libU77' intrinsics to support existing code more directly. Such changes include allowing both subroutine and function forms of many routines, changing `MCLOCK()' and `TIME()' to return `INTEGER(KIND=1)' values, introducing `MCLOCK8()' and `TIME8()' to return `INTEGER(KIND=2)' values, and placing functions that are intended to perform side effects in a new intrinsic group, `badu77'. * Add options `-fbadu77-intrinsics-delete', `-fbadu77-intrinsics-hide', and so on. * Add `INT2' and `INT8' intrinsics. * Add `CPU_TIME' intrinsic. * Add `ALARM' intrinsic. * `CTIME' intrinsic now accepts any `INTEGER' argument, not just `INTEGER(KIND=2)'. * `g77' driver now prints version information (such as produced by `g77 -v') to `stderr' instead of `stdout'. * The `.r' suffix now designates a Ratfor source file, to be preprocessed via the `ratfor' command, available separately. In 0.5.20: ========== * The `-fno-typeless-boz' option is now the default. This option specifies that non-decimal-radix constants using the prefixed-radix form (such as `Z'1234'') are to be interpreted as `INTEGER(KIND=1)' constants. Specify `-ftypeless-boz' to cause such constants to be interpreted as typeless. (Version 0.5.19 introduced `-fno-typeless-boz' and its inverse.) *Note Options Controlling Fortran Dialect: Fortran Dialect Options, for information on the `-ftypeless-boz' option. * Options `-ff90-intrinsics-enable' and `-fvxt-intrinsics-enable' now are the defaults. Some programs might use names that clash with intrinsic names defined (and now enabled) by these options or by the new `libU77' intrinsics. Users of such programs might need to compile them differently (using, for example, `-ff90-intrinsics-disable') or, better yet, insert appropriate `EXTERNAL' statements specifying that these names are not intended to be names of intrinsics. * The `ALWAYS_FLUSH' macro is no longer defined when building `libf2c', which should result in improved I/O performance, especially over NFS. _Note:_ If you have code that depends on the behavior of `libf2c' when built with `ALWAYS_FLUSH' defined, you will have to modify `libf2c' accordingly before building it from this and future versions of `g77'. *Note Output Assumed To Flush::, for more information. * Dave Love's implementation of `libU77' has been added to the version of `libf2c' distributed with and built as part of `g77'. `g77' now knows about the routines in this library as intrinsics. * New option `-fvxt' specifies that the source file is written in VXT Fortran, instead of GNU Fortran. *Note VXT Fortran::, for more information on the constructs recognized when the `-fvxt' option is specified. * The `-fvxt-not-f90' option has been deleted, along with its inverse, `-ff90-not-vxt'. If you used one of these deleted options, you should re-read the pertinent documentation to determine which options, if any, are appropriate for compiling your code with this version of `g77'. *Note Other Dialects::, for more information. * The `-fugly' option now issues a warning, as it likely will be removed in a future version. (Enabling all the `-fugly-*' options is unlikely to be feasible, or sensible, in the future, so users should learn to specify only those `-fugly-*' options they really need for a particular source file.) * The `-fugly-assumed' option, introduced in version 0.5.19, has been changed to better accommodate old and new code. *Note Ugly Assumed-Size Arrays::, for more information. * Related to supporting Alpha (AXP) machines, the `LOC()' intrinsic and `%LOC()' construct now return values of `INTEGER(KIND=0)' type, as defined by the GNU Fortran language. This type is wide enough (holds the same number of bits) as the character-pointer type on the machine. On most machines, this won't make a difference, whereas, on Alphas and other systems with 64-bit pointers, the `INTEGER(KIND=0)' type is equivalent to `INTEGER(KIND=2)' (often referred to as `INTEGER*8') instead of the more common `INTEGER(KIND=1)' (often referred to as `INTEGER*4'). * Emulate `COMPLEX' arithmetic in the `g77' front end, to avoid bugs in `complex' support in the `gcc' back end. New option `-fno-emulate-complex' causes `g77' to revert the 0.5.19 behavior. * Dummy arguments are no longer assumed to potentially alias (overlap) other dummy arguments or `COMMON' areas when any of these are defined (assigned to) by Fortran code. This can result in faster and/or smaller programs when compiling with optimization enabled, though on some systems this effect is observed only when `-fforce-addr' also is specified. New options `-falias-check', `-fargument-alias', `-fargument-noalias', and `-fno-argument-noalias-global' control the way `g77' handles potential aliasing. *Note Aliasing Assumed To Work::, for detailed information on why the new defaults might result in some programs no longer working the way they did when compiled by previous versions of `g77'. * New option `-fugly-assign' specifies that the same memory locations are to be used to hold the values assigned by both statements `I = 3' and `ASSIGN 10 TO I', for example. (Normally, `g77' uses a separate memory location to hold assigned statement labels.) *Note Ugly Assigned Labels::, for more information. * `FORMAT' and `ENTRY' statements now are allowed to precede `IMPLICIT NONE' statements. * Enable full support of `INTEGER(KIND=2)' (often referred to as `INTEGER*8') available in `libf2c' and `f2c.h' so that `f2c' users may make full use of its features via the `g77' version of `f2c.h' and the `INTEGER(KIND=2)' support routines in the `g77' version of `libf2c'. * Improve `g77' driver and `libf2c' so that `g77 -v' yields version information on the library. * The `SNGL' and `FLOAT' intrinsics now are specific intrinsics, instead of synonyms for the generic intrinsic `REAL'. * New intrinsics have been added. These are `REALPART', `IMAGPART', `COMPLEX', `LONG', and `SHORT'. * A new group of intrinsics, `gnu', has been added to contain the new `REALPART', `IMAGPART', and `COMPLEX' intrinsics. An old group, `dcp', has been removed. * Complain about industry-wide ambiguous references `REAL(EXPR)' and `AIMAG(EXPR)', where EXPR is `DOUBLE COMPLEX' (or any complex type other than `COMPLEX'), unless `-ff90' option specifies Fortran 90 interpretation or new `-fugly-complex' option, in conjunction with `-fnot-f90', specifies `f2c' interpretation. In previous versions: ===================== Information on previous versions is archived in `gcc/gcc/f/news.texi' following the test of the `DOC-OLDNEWS' macro.  File: g77.info, Node: Language, Next: Compiler, Prev: Changes, Up: Top The GNU Fortran Language ************************ GNU Fortran supports a variety of extensions to, and dialects of, the Fortran language. Its primary base is the ANSI FORTRAN 77 standard, currently available on the network at `http://www.fortran.com/fortran/F77_std/rjcnf0001.html' or as monolithic text at `http://www.fortran.com/fortran/F77_std/f77_std.html'. It offers some extensions that are popular among users of UNIX `f77' and `f2c' compilers, some that are popular among users of other compilers (such as Digital products), some that are popular among users of the newer Fortran 90 standard, and some that are introduced by GNU Fortran. (If you need a text on Fortran, a few freely available electronic references have pointers from `http://www.fortran.com/F/books.html'. There is a `cooperative net project', `User Notes on Fortran Programming' at `ftp://vms.huji.ac.il/fortran/' and mirrors elsewhere; some of this material might not apply specifically to `g77'.) Part of what defines a particular implementation of a Fortran system, such as `g77', is the particular characteristics of how it supports types, constants, and so on. Much of this is left up to the implementation by the various Fortran standards and accepted practice in the industry. The GNU Fortran _language_ is described below. Much of the material is organized along the same lines as the ANSI FORTRAN 77 standard itself. *Note Other Dialects::, for information on features `g77' supports that are not part of the GNU Fortran language. _Note_: This portion of the documentation definitely needs a lot of work! * Menu: Relationship to the ANSI FORTRAN 77 standard: * Direction of Language Development:: Where GNU Fortran is headed. * Standard Support:: Degree of support for the standard. Extensions to the ANSI FORTRAN 77 standard: * Conformance:: * Notation Used:: * Terms and Concepts:: * Characters Lines Sequence:: * Data Types and Constants:: * Expressions:: * Specification Statements:: * Control Statements:: * Functions and Subroutines:: * Scope and Classes of Names:: * I/O:: * Fortran 90 Features::  File: g77.info, Node: Direction of Language Development, Next: Standard Support, Up: Language Direction of Language Development ================================= The purpose of the following description of the GNU Fortran language is to promote wide portability of GNU Fortran programs. GNU Fortran is an evolving language, due to the fact that `g77' itself is in beta test. Some current features of the language might later be redefined as dialects of Fortran supported by `g77' when better ways to express these features are added to `g77', for example. Such features would still be supported by `g77', but would be available only when one or more command-line options were used. The GNU Fortran _language_ is distinct from the GNU Fortran _compilation system_ (`g77'). For example, `g77' supports various dialects of Fortran--in a sense, these are languages other than GNU Fortran--though its primary purpose is to support the GNU Fortran language, which also is described in its documentation and by its implementation. On the other hand, non-GNU compilers might offer support for the GNU Fortran language, and are encouraged to do so. Currently, the GNU Fortran language is a fairly fuzzy object. It represents something of a cross between what `g77' accepts when compiling using the prevailing defaults and what this document describes as being part of the language. Future versions of `g77' are expected to clarify the definition of the language in the documentation. Often, this will mean adding new features to the language, in the form of both new documentation and new support in `g77'. However, it might occasionally mean removing a feature from the language itself to "dialect" status. In such a case, the documentation would be adjusted to reflect the change, and `g77' itself would likely be changed to require one or more command-line options to continue supporting the feature. The development of the GNU Fortran language is intended to strike a balance between: * Serving as a mostly-upwards-compatible language from the de facto UNIX Fortran dialect as supported by `f77'. * Offering new, well-designed language features. Attributes of such features include not making existing code any harder to read (for those who might be unaware that the new features are not in use) and not making state-of-the-art compilers take longer to issue diagnostics, among others. * Supporting existing, well-written code without gratuitously rejecting non-standard constructs, regardless of the origin of the code (its dialect). * Offering default behavior and command-line options to reduce and, where reasonable, eliminate the need for programmers to make any modifications to code that already works in existing production environments. * Diagnosing constructs that have different meanings in different systems, languages, and dialects, while offering clear, less ambiguous ways to express each of the different meanings so programmers can change their code appropriately. One of the biggest practical challenges for the developers of the GNU Fortran language is meeting the sometimes contradictory demands of the above items. For example, a feature might be widely used in one popular environment, but the exact same code that utilizes that feature might not work as expected--perhaps it might mean something entirely different--in another popular environment. Traditionally, Fortran compilers--even portable ones--have solved this problem by simply offering the appropriate feature to users of the respective systems. This approach treats users of various Fortran systems and dialects as remote "islands", or camps, of programmers, and assume that these camps rarely come into contact with each other (or, especially, with each other's code). Project GNU takes a radically different approach to software and language design, in that it assumes that users of GNU software do not necessarily care what kind of underlying system they are using, regardless of whether they are using software (at the user-interface level) or writing it (for example, writing Fortran or C code). As such, GNU users rarely need consider just what kind of underlying hardware (or, in many cases, operating system) they are using at any particular time. They can use and write software designed for a general-purpose, widely portable, heterogeneous environment--the GNU environment. In line with this philosophy, GNU Fortran must evolve into a product that is widely ported and portable not only in the sense that it can be successfully built, installed, and run by users, but in the larger sense that its users can use it in the same way, and expect largely the same behaviors from it, regardless of the kind of system they are using at any particular time. This approach constrains the solutions `g77' can use to resolve conflicts between various camps of Fortran users. If these two camps disagree about what a particular construct should mean, `g77' cannot simply be changed to treat that particular construct as having one meaning without comment (such as a warning), lest the users expecting it to have the other meaning are unpleasantly surprised that their code misbehaves when executed. The use of the ASCII backslash character in character constants is an excellent (and still somewhat unresolved) example of this kind of controversy. *Note Backslash in Constants::. Other examples are likely to arise in the future, as `g77' developers strive to improve its ability to accept an ever-wider variety of existing Fortran code without requiring significant modifications to said code. Development of GNU Fortran is further constrained by the desire to avoid requiring programmers to change their code. This is important because it allows programmers, administrators, and others to more faithfully evaluate and validate `g77' (as an overall product and as new versions are distributed) without having to support multiple versions of their programs so that they continue to work the same way on their existing systems (non-GNU perhaps, but possibly also earlier versions of `g77').  File: g77.info, Node: Standard Support, Next: Conformance, Prev: Direction of Language Development, Up: Language ANSI FORTRAN 77 Standard Support ================================ GNU Fortran supports ANSI FORTRAN 77 with the following caveats. In summary, the only ANSI FORTRAN 77 features `g77' doesn't support are those that are probably rarely used in actual code, some of which are explicitly disallowed by the Fortran 90 standard. * Menu: * No Passing External Assumed-length:: CHAR*(*) CFUNC restriction. * No Passing Dummy Assumed-length:: CHAR*(*) CFUNC restriction. * No Pathological Implied-DO:: No `((..., I=...), I=...)'. * No Useless Implied-DO:: No `(A, I=1, 1)'.  File: g77.info, Node: No Passing External Assumed-length, Next: No Passing Dummy Assumed-length, Up: Standard Support No Passing External Assumed-length ---------------------------------- `g77' disallows passing of an external procedure as an actual argument if the procedure's type is declared `CHARACTER*(*)'. For example: CHARACTER*(*) CFUNC EXTERNAL CFUNC CALL FOO(CFUNC) END It isn't clear whether the standard considers this conforming.  File: g77.info, Node: No Passing Dummy Assumed-length, Next: No Pathological Implied-DO, Prev: No Passing External Assumed-length, Up: Standard Support No Passing Dummy Assumed-length ------------------------------- `g77' disallows passing of a dummy procedure as an actual argument if the procedure's type is declared `CHARACTER*(*)'. SUBROUTINE BAR(CFUNC) CHARACTER*(*) CFUNC EXTERNAL CFUNC CALL FOO(CFUNC) END It isn't clear whether the standard considers this conforming.  File: g77.info, Node: No Pathological Implied-DO, Next: No Useless Implied-DO, Prev: No Passing Dummy Assumed-length, Up: Standard Support No Pathological Implied-DO -------------------------- The `DO' variable for an implied-`DO' construct in a `DATA' statement may not be used as the `DO' variable for an outer implied-`DO' construct. For example, this fragment is disallowed by `g77': DATA ((A(I, I), I= 1, 10), I= 1, 10) /.../ This also is disallowed by Fortran 90, as it offers no additional capabilities and would have a variety of possible meanings. Note that it is _very_ unlikely that any production Fortran code tries to use this unsupported construct.  File: g77.info, Node: No Useless Implied-DO, Prev: No Pathological Implied-DO, Up: Standard Support No Useless Implied-DO --------------------- An array element initializer in an implied-`DO' construct in a `DATA' statement must contain at least one reference to the `DO' variables of each outer implied-`DO' construct. For example, this fragment is disallowed by `g77': DATA (A, I= 1, 1) /1./ This also is disallowed by Fortran 90, as FORTRAN 77's more permissive requirements offer no additional capabilities. However, `g77' doesn't necessarily diagnose all cases where this requirement is not met. Note that it is _very_ unlikely that any production Fortran code tries to use this unsupported construct.  File: g77.info, Node: Conformance, Next: Notation Used, Prev: Standard Support, Up: Language Conformance =========== (The following information augments or overrides the information in Section 1.4 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 1 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) The definition of the GNU Fortran language is akin to that of the ANSI FORTRAN 77 language in that it does not generally require conforming implementations to diagnose cases where programs do not conform to the language. However, `g77' as a compiler is being developed in a way that is intended to enable it to diagnose such cases in an easy-to-understand manner. A program that conforms to the GNU Fortran language should, when compiled, linked, and executed using a properly installed `g77' system, perform as described by the GNU Fortran language definition. Reasons for different behavior include, among others: * Use of resources (memory--heap, stack, and so on; disk space; CPU time; etc.) exceeds those of the system. * Range and/or precision of calculations required by the program exceeds that of the system. * Excessive reliance on behaviors that are system-dependent (non-portable Fortran code). * Bugs in the program. * Bug in `g77'. * Bugs in the system. Despite these "loopholes", the availability of a clear specification of the language of programs submitted to `g77', as this document is intended to provide, is considered an important aspect of providing a robust, clean, predictable Fortran implementation. The definition of the GNU Fortran language, while having no special legal status, can therefore be viewed as a sort of contract, or agreement. This agreement says, in essence, "if you write a program in this language, and run it in an environment (such as a `g77' system) that supports this language, the program should behave in a largely predictable way".  File: g77.info, Node: Notation Used, Next: Terms and Concepts, Prev: Conformance, Up: Language Notation Used in This Chapter ============================= (The following information augments or overrides the information in Section 1.5 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 1 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) In this chapter, "must" denotes a requirement, "may" denotes permission, and "must not" and "may not" denote prohibition. Terms such as "might", "should", and "can" generally add little or nothing in the way of weight to the GNU Fortran language itself, but are used to explain or illustrate the language. For example: ``The `FROBNITZ' statement must precede all executable statements in a program unit, and may not specify any dummy arguments. It may specify local or common variables and arrays. Its use should be limited to portions of the program designed to be non-portable and system-specific, because it might cause the containing program unit to behave quite differently on different systems.'' Insofar as the GNU Fortran language is specified, the requirements and permissions denoted by the above sample statement are limited to the placement of the statement and the kinds of things it may specify. The rest of the statement--the content regarding non-portable portions of the program and the differing behavior of program units containing the `FROBNITZ' statement--does not pertain the GNU Fortran language itself. That content offers advice and warnings about the `FROBNITZ' statement. _Remember:_ The GNU Fortran language definition specifies both what constitutes a valid GNU Fortran program and how, given such a program, a valid GNU Fortran implementation is to interpret that program. It is _not_ incumbent upon a valid GNU Fortran implementation to behave in any particular way, any consistent way, or any predictable way when it is asked to interpret input that is _not_ a valid GNU Fortran program. Such input is said to have "undefined" behavior when interpreted by a valid GNU Fortran implementation, though an implementation may choose to specify behaviors for some cases of inputs that are not valid GNU Fortran programs. Other notation used herein is that of the GNU texinfo format, which is used to generate printed hardcopy, on-line hypertext (Info), and on-line HTML versions, all from a single source document. This notation is used as follows: * Keywords defined by the GNU Fortran language are shown in uppercase, as in: `COMMON', `INTEGER', and `BLOCK DATA'. Note that, in practice, many Fortran programs are written in lowercase--uppercase is used in this manual as a means to readily distinguish keywords and sample Fortran-related text from the prose in this document. * Portions of actual sample program, input, or output text look like this: `Actual program text'. Generally, uppercase is used for all Fortran-specific and Fortran-related text, though this does not always include literal text within Fortran code. For example: `PRINT *, 'My name is Bob''. * A metasyntactic variable--that is, a name used in this document to serve as a placeholder for whatever text is used by the user or programmer--appears as shown in the following example: "The `INTEGER IVAR' statement specifies that IVAR is a variable or array of type `INTEGER'." In the above example, any valid text may be substituted for the metasyntactic variable IVAR to make the statement apply to a specific instance, as long as the same text is substituted for _both_ occurrences of IVAR. * Ellipses ("...") are used to indicate further text that is either unimportant or expanded upon further, elsewhere. * Names of data types are in the style of Fortran 90, in most cases. *Note Kind Notation::, for information on the relationship between Fortran 90 nomenclature (such as `INTEGER(KIND=1)') and the more traditional, less portably concise nomenclature (such as `INTEGER*4').  File: g77.info, Node: Terms and Concepts, Next: Characters Lines Sequence, Prev: Notation Used, Up: Language Fortran Terms and Concepts ========================== (The following information augments or overrides the information in Chapter 2 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 2 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) * Menu: * Syntactic Items:: * Statements Comments Lines:: * Scope of Names and Labels::  File: g77.info, Node: Syntactic Items, Next: Statements Comments Lines, Up: Terms and Concepts Syntactic Items --------------- (Corresponds to Section 2.2 of ANSI X3.9-1978 FORTRAN 77.) In GNU Fortran, a symbolic name is at least one character long, and has no arbitrary upper limit on length. However, names of entities requiring external linkage (such as external functions, external subroutines, and `COMMON' areas) might be restricted to some arbitrary length by the system. Such a restriction is no more constrained than that of one through six characters. Underscores (`_') are accepted in symbol names after the first character (which must be a letter).  File: g77.info, Node: Statements Comments Lines, Next: Scope of Names and Labels, Prev: Syntactic Items, Up: Terms and Concepts Statements, Comments, and Lines ------------------------------- (Corresponds to Section 2.3 of ANSI X3.9-1978 FORTRAN 77.) Use of an exclamation point (`!') to begin a trailing comment (a comment that extends to the end of the same source line) is permitted under the following conditions: * The exclamation point does not appear in column 6. Otherwise, it is treated as an indicator of a continuation line. * The exclamation point appears outside a character or Hollerith constant. Otherwise, the exclamation point is considered part of the constant. * The exclamation point appears to the left of any other possible trailing comment. That is, a trailing comment may contain exclamation points in their commentary text. Use of a semicolon (`;') as a statement separator is permitted under the following conditions: * The semicolon appears outside a character or Hollerith constant. Otherwise, the semicolon is considered part of the constant. * The semicolon appears to the left of a trailing comment. Otherwise, the semicolon is considered part of that comment. * Neither a logical `IF' statement nor a non-construct `WHERE' statement (a Fortran 90 feature) may be followed (in the same, possibly continued, line) by a semicolon used as a statement separator. This restriction avoids the confusion that can result when reading a line such as: IF (VALIDP) CALL FOO; CALL BAR Some readers might think the `CALL BAR' is executed only if `VALIDP' is `.TRUE.', while others might assume its execution is unconditional. (At present, `g77' does not diagnose code that violates this restriction.)  File: g77.info, Node: Scope of Names and Labels, Prev: Statements Comments Lines, Up: Terms and Concepts Scope of Symbolic Names and Statement Labels -------------------------------------------- (Corresponds to Section 2.9 of ANSI X3.9-1978 FORTRAN 77.) Included in the list of entities that have a scope of a program unit are construct names (a Fortran 90 feature). *Note Construct Names::, for more information.  File: g77.info, Node: Characters Lines Sequence, Next: Data Types and Constants, Prev: Terms and Concepts, Up: Language Characters, Lines, and Execution Sequence ========================================= (The following information augments or overrides the information in Chapter 3 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 3 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) * Menu: * Character Set:: * Lines:: * Continuation Line:: * Statements:: * Statement Labels:: * Order:: * INCLUDE:: * Cpp-style directives::  File: g77.info, Node: Character Set, Next: Lines, Up: Characters Lines Sequence GNU Fortran Character Set ------------------------- (Corresponds to Section 3.1 of ANSI X3.9-1978 FORTRAN 77.) Letters include uppercase letters (the twenty-six characters of the English alphabet) and lowercase letters (their lowercase equivalent). Generally, lowercase letters may be used in place of uppercase letters, though in character and Hollerith constants, they are distinct. Special characters include: * Semicolon (`;') * Exclamation point (`!') * Double quote (`"') * Backslash (`\') * Question mark (`?') * Hash mark (`#') * Ampersand (`&') * Percent sign (`%') * Underscore (`_') * Open angle (`<') * Close angle (`>') * The FORTRAN 77 special characters (, `=', `+', `-', `*', `/', `(', `)', `,', `.', `$', `'', and `:') Note that this document refers to as "space", while X3.9-1978 FORTRAN 77 refers to it as "blank".  File: g77.info, Node: Lines, Next: Continuation Line, Prev: Character Set, Up: Characters Lines Sequence Lines ----- (Corresponds to Section 3.2 of ANSI X3.9-1978 FORTRAN 77.) The way a Fortran compiler views source files depends entirely on the implementation choices made for the compiler, since those choices are explicitly left to the implementation by the published Fortran standards. The GNU Fortran language mandates a view applicable to UNIX-like text files--files that are made up of an arbitrary number of lines, each with an arbitrary number of characters (sometimes called stream-based files). This view does not apply to types of files that are specified as having a particular number of characters on every single line (sometimes referred to as record-based files). Because a "line in a program unit is a sequence of 72 characters", to quote X3.9-1978, the GNU Fortran language specifies that a stream-based text file is translated to GNU Fortran lines as follows: * A newline in the file is the character that represents the end of a line of text to the underlying system. For example, on ASCII-based systems, a newline is the character, which has ASCII value 10 (decimal). * Each newline in the file serves to end the line of text that precedes it (and that does not contain a newline). * The end-of-file marker (`EOF') also serves to end the line of text that precedes it (and that does not contain a newline). * Any line of text that is shorter than 72 characters is padded to that length with spaces (called "blanks" in the standard). * Any line of text that is longer than 72 characters is truncated to that length, but the truncated remainder must consist entirely of spaces. * Characters other than newline and the GNU Fortran character set are invalid. For the purposes of the remainder of this description of the GNU Fortran language, the translation described above has already taken place, unless otherwise specified. The result of the above translation is that the source file appears, in terms of the remainder of this description of the GNU Fortran language, as if it had an arbitrary number of 72-character lines, each character being among the GNU Fortran character set. For example, if the source file itself has two newlines in a row, the second newline becomes, after the above translation, a single line containing 72 spaces.  File: g77.info, Node: Continuation Line, Next: Statements, Prev: Lines, Up: Characters Lines Sequence Continuation Line ----------------- (Corresponds to Section 3.2.3 of ANSI X3.9-1978 FORTRAN 77.) A continuation line is any line that both * Contains a continuation character, and * Contains only spaces in columns 1 through 5 A continuation character is any character of the GNU Fortran character set other than space () or zero (`0') in column 6, or a digit (`0' through `9') in column 7 through 72 of a line that has only spaces to the left of that digit. The continuation character is ignored as far as the content of the statement is concerned. The GNU Fortran language places no limit on the number of continuation lines in a statement. In practice, the limit depends on a variety of factors, such as available memory, statement content, and so on, but no GNU Fortran system may impose an arbitrary limit.  File: g77.info, Node: Statements, Next: Statement Labels, Prev: Continuation Line, Up: Characters Lines Sequence Statements ---------- (Corresponds to Section 3.3 of ANSI X3.9-1978 FORTRAN 77.) Statements may be written using an arbitrary number of continuation lines. Statements may be separated using the semicolon (`;'), except that the logical `IF' and non-construct `WHERE' statements may not be separated from subsequent statements using only a semicolon as statement separator. The `END PROGRAM', `END SUBROUTINE', `END FUNCTION', and `END BLOCK DATA' statements are alternatives to the `END' statement. These alternatives may be written as normal statements--they are not subject to the restrictions of the `END' statement. However, no statement other than `END' may have an initial line that appears to be an `END' statement--even `END PROGRAM', for example, must not be written as: END &PROGRAM  File: g77.info, Node: Statement Labels, Next: Order, Prev: Statements, Up: Characters Lines Sequence Statement Labels ---------------- (Corresponds to Section 3.4 of ANSI X3.9-1978 FORTRAN 77.) A statement separated from its predecessor via a semicolon may be labeled as follows: * The semicolon is followed by the label for the statement, which in turn follows the label. * The label must be no more than five digits in length. * The first digit of the label for the statement is not the first non-space character on a line. Otherwise, that character is treated as a continuation character. A statement may have only one label defined for it.  File: g77.info, Node: Order, Next: INCLUDE, Prev: Statement Labels, Up: Characters Lines Sequence Order of Statements and Lines ----------------------------- (Corresponds to Section 3.5 of ANSI X3.9-1978 FORTRAN 77.) Generally, `DATA' statements may precede executable statements. However, specification statements pertaining to any entities initialized by a `DATA' statement must precede that `DATA' statement. For example, after `DATA I/1/', `INTEGER I' is not permitted, but `INTEGER J' is permitted. The last line of a program unit may be an `END' statement, or may be: * An `END PROGRAM' statement, if the program unit is a main program. * An `END SUBROUTINE' statement, if the program unit is a subroutine. * An `END FUNCTION' statement, if the program unit is a function. * An `END BLOCK DATA' statement, if the program unit is a block data.  File: g77.info, Node: INCLUDE, Next: Cpp-style directives, Prev: Order, Up: Characters Lines Sequence Including Source Text --------------------- Additional source text may be included in the processing of the source file via the `INCLUDE' directive: INCLUDE FILENAME The source text to be included is identified by FILENAME, which is a literal GNU Fortran character constant. The meaning and interpretation of FILENAME depends on the implementation, but typically is a filename. (`g77' treats it as a filename that it searches for in the current directory and/or directories specified via the `-I' command-line option.) The effect of the `INCLUDE' directive is as if the included text directly replaced the directive in the source file prior to interpretation of the program. Included text may itself use `INCLUDE'. The depth of nested `INCLUDE' references depends on the implementation, but typically is a positive integer. This virtual replacement treats the statements and `INCLUDE' directives in the included text as syntactically distinct from those in the including text. Therefore, the first non-comment line of the included text must not be a continuation line. The included text must therefore have, after the non-comment lines, either an initial line (statement), an `INCLUDE' directive, or nothing (the end of the included text). Similarly, the including text may end the `INCLUDE' directive with a semicolon or the end of the line, but it cannot follow an `INCLUDE' directive at the end of its line with a continuation line. Thus, the last statement in an included text may not be continued. Any statements between two `INCLUDE' directives on the same line are treated as if they appeared in between the respective included texts. For example: INCLUDE 'A'; PRINT *, 'B'; INCLUDE 'C'; END PROGRAM If the text included by `INCLUDE 'A'' constitutes a `PRINT *, 'A'' statement and the text included by `INCLUDE 'C'' constitutes a `PRINT *, 'C'' statement, then the output of the above sample program would be A B C (with suitable allowances for how an implementation defines its handling of output). Included text must not include itself directly or indirectly, regardless of whether the FILENAME used to reference the text is the same. Note that `INCLUDE' is _not_ a statement. As such, it is neither a non-executable or executable statement. However, if the text it includes constitutes one or more executable statements, then the placement of `INCLUDE' is subject to effectively the same restrictions as those on executable statements. An `INCLUDE' directive may be continued across multiple lines as if it were a statement. This permits long names to be used for FILENAME.  File: g77.info, Node: Cpp-style directives, Prev: INCLUDE, Up: Characters Lines Sequence Cpp-style directives -------------------- `cpp' output-style `#' directives (*note C Preprocessor Output: (cpp)C Preprocessor Output.) are recognized by the compiler even when the preprocessor isn't run on the input (as it is when compiling `.F' files). (Note the distinction between these `cpp' `#' _output_ directives and `#line' _input_ directives.)  File: g77.info, Node: Data Types and Constants, Next: Expressions, Prev: Characters Lines Sequence, Up: Language Data Types and Constants ======================== (The following information augments or overrides the information in Chapter 4 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 4 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) To more concisely express the appropriate types for entities, this document uses the more concise Fortran 90 nomenclature such as `INTEGER(KIND=1)' instead of the more traditional, but less portably concise, byte-size-based nomenclature such as `INTEGER*4', wherever reasonable. When referring to generic types--in contexts where the specific precision and range of a type are not important--this document uses the generic type names `INTEGER', `LOGICAL', `REAL', `COMPLEX', and `CHARACTER'. In some cases, the context requires specification of a particular type. This document uses the `KIND=' notation to accomplish this throughout, sometimes supplying the more traditional notation for clarification, though the traditional notation might not work the same way on all GNU Fortran implementations. Use of `KIND=' makes this document more concise because `g77' is able to define values for `KIND=' that have the same meanings on all systems, due to the way the Fortran 90 standard specifies these values are to be used. (In particular, that standard permits an implementation to arbitrarily assign nonnegative values. There are four distinct sets of assignments: one to the `CHARACTER' type; one to the `INTEGER' type; one to the `LOGICAL' type; and the fourth to both the `REAL' and `COMPLEX' types. Implementations are free to assign these values in any order, leave gaps in the ordering of assignments, and assign more than one value to a representation.) This makes `KIND=' values superior to the values used in non-standard statements such as `INTEGER*4', because the meanings of the values in those statements vary from machine to machine, compiler to compiler, even operating system to operating system. However, use of `KIND=' is _not_ generally recommended when writing portable code (unless, for example, the code is going to be compiled only via `g77', which is a widely ported compiler). GNU Fortran does not yet have adequate language constructs to permit use of `KIND=' in a fashion that would make the code portable to Fortran 90 implementations; and, this construct is known to _not_ be accepted by many popular FORTRAN 77 implementations, so it cannot be used in code that is to be ported to those. The distinction here is that this document is able to use specific values for `KIND=' to concisely document the types of various operations and operands. A Fortran program should use the FORTRAN 77 designations for the appropriate GNU Fortran types--such as `INTEGER' for `INTEGER(KIND=1)', `REAL' for `REAL(KIND=1)', and `DOUBLE COMPLEX' for `COMPLEX(KIND=2)'--and, where no such designations exist, make use of appropriate techniques (preprocessor macros, parameters, and so on) to specify the types in a fashion that may be easily adjusted to suit each particular implementation to which the program is ported. (These types generally won't need to be adjusted for ports of `g77'.) Further details regarding GNU Fortran data types and constants are provided below. * Menu: * Types:: * Constants:: * Integer Type:: * Character Type::  File: g77.info, Node: Types, Next: Constants, Up: Data Types and Constants Data Types ---------- (Corresponds to Section 4.1 of ANSI X3.9-1978 FORTRAN 77.) GNU Fortran supports these types: 1. Integer (generic type `INTEGER') 2. Real (generic type `REAL') 3. Double precision 4. Complex (generic type `COMPLEX') 5. Logical (generic type `LOGICAL') 6. Character (generic type `CHARACTER') 7. Double Complex (The types numbered 1 through 6 above are standard FORTRAN 77 types.) The generic types shown above are referred to in this document using only their generic type names. Such references usually indicate that any specific type (kind) of that generic type is valid. For example, a context described in this document as accepting the `COMPLEX' type also is likely to accept the `DOUBLE COMPLEX' type. The GNU Fortran language supports three ways to specify a specific kind of a generic type. * Menu: * Double Notation:: As in `DOUBLE COMPLEX'. * Star Notation:: As in `INTEGER*4'. * Kind Notation:: As in `INTEGER(KIND=1)'.  File: g77.info, Node: Double Notation, Next: Star Notation, Up: Types Double Notation ............... The GNU Fortran language supports two uses of the keyword `DOUBLE' to specify a specific kind of type: * `DOUBLE PRECISION', equivalent to `REAL(KIND=2)' * `DOUBLE COMPLEX', equivalent to `COMPLEX(KIND=2)' Use one of the above forms where a type name is valid. While use of this notation is popular, it doesn't scale well in a language or dialect rich in intrinsic types, as is the case for the GNU Fortran language (especially planned future versions of it). After all, one rarely sees type names such as `DOUBLE INTEGER', `QUADRUPLE REAL', or `QUARTER INTEGER'. Instead, `INTEGER*8', `REAL*16', and `INTEGER*1' often are substituted for these, respectively, even though they do not always have the same meanings on all systems. (And, the fact that `DOUBLE REAL' does not exist as such is an inconsistency.) Therefore, this document uses "double notation" only on occasion for the benefit of those readers who are accustomed to it.  File: g77.info, Node: Star Notation, Next: Kind Notation, Prev: Double Notation, Up: Types Star Notation ............. The following notation specifies the storage size for a type: GENERIC-TYPE*N GENERIC-TYPE must be a generic type--one of `INTEGER', `REAL', `COMPLEX', `LOGICAL', or `CHARACTER'. N must be one or more digits comprising a decimal integer number greater than zero. Use the above form where a type name is valid. The `*N' notation specifies that the amount of storage occupied by variables and array elements of that type is N times the storage occupied by a `CHARACTER*1' variable. This notation might indicate a different degree of precision and/or range for such variables and array elements, and the functions that return values of types using this notation. It does not limit the precision or range of values of that type in any particular way--use explicit code to do that. Further, the GNU Fortran language requires no particular values for N to be supported by an implementation via the `*N' notation. `g77' supports `INTEGER*1' (as `INTEGER(KIND=3)') on all systems, for example, but not all implementations are required to do so, and `g77' is known to not support `REAL*1' on most (or all) systems. As a result, except for GENERIC-TYPE of `CHARACTER', uses of this notation should be limited to isolated portions of a program that are intended to handle system-specific tasks and are expected to be non-portable. (Standard FORTRAN 77 supports the `*N' notation for only `CHARACTER', where it signifies not only the amount of storage occupied, but the number of characters in entities of that type. However, almost all Fortran compilers have supported this notation for generic types, though with a variety of meanings for N.) Specifications of types using the `*N' notation always are interpreted as specifications of the appropriate types described in this document using the `KIND=N' notation, described below. While use of this notation is popular, it doesn't serve well in the context of a widely portable dialect of Fortran, such as the GNU Fortran language. For example, even on one particular machine, two or more popular Fortran compilers might well disagree on the size of a type declared `INTEGER*2' or `REAL*16'. Certainly there is known to be disagreement over such things among Fortran compilers on _different_ systems. Further, this notation offers no elegant way to specify sizes that are not even multiples of the "byte size" typically designated by `INTEGER*1'. Use of "absurd" values (such as `INTEGER*1000') would certainly be possible, but would perhaps be stretching the original intent of this notation beyond the breaking point in terms of widespread readability of documentation and code making use of it. Therefore, this document uses "star notation" only on occasion for the benefit of those readers who are accustomed to it.  File: g77.info, Node: Kind Notation, Prev: Star Notation, Up: Types Kind Notation ............. The following notation specifies the kind-type selector of a type: GENERIC-TYPE(KIND=N) Use the above form where a type name is valid. GENERIC-TYPE must be a generic type--one of `INTEGER', `REAL', `COMPLEX', `LOGICAL', or `CHARACTER'. N must be an integer initialization expression that is a positive, nonzero value. Programmers are discouraged from writing these values directly into their code. Future versions of the GNU Fortran language will offer facilities that will make the writing of code portable to `g77' _and_ Fortran 90 implementations simpler. However, writing code that ports to existing FORTRAN 77 implementations depends on avoiding the `KIND=' construct. The `KIND=' construct is thus useful in the context of GNU Fortran for two reasons: * It provides a means to specify a type in a fashion that is portable across all GNU Fortran implementations (though not other FORTRAN 77 and Fortran 90 implementations). * It provides a sort of Rosetta stone for this document to use to concisely describe the types of various operations and operands. The values of N in the GNU Fortran language are assigned using a scheme that: * Attempts to maximize the ability of readers of this document to quickly familiarize themselves with assignments for popular types * Provides a unique value for each specific desired meaning * Provides a means to automatically assign new values so they have a "natural" relationship to existing values, if appropriate, or, if no such relationship exists, will not interfere with future values assigned on the basis of such relationships * Avoids using values that are similar to values used in the existing, popular `*N' notation, to prevent readers from expecting that these implied correspondences work on all GNU Fortran implementations The assignment system accomplishes this by assigning to each "fundamental meaning" of a specific type a unique prime number. Combinations of fundamental meanings--for example, a type that is two times the size of some other type--are assigned values of N that are the products of the values for those fundamental meanings. A prime value of N is never given more than one fundamental meaning, to avoid situations where some code or system cannot reasonably provide those meanings in the form of a single type. The values of N assigned so far are: `KIND=0' This value is reserved for future use. The planned future use is for this value to designate, explicitly, context-sensitive kind-type selection. For example, the expression `1D0 * 0.1_0' would be equivalent to `1D0 * 0.1D0'. `KIND=1' This corresponds to the default types for `REAL', `INTEGER', `LOGICAL', `COMPLEX', and `CHARACTER', as appropriate. These are the "default" types described in the Fortran 90 standard, though that standard does not assign any particular `KIND=' value to these types. (Typically, these are `REAL*4', `INTEGER*4', `LOGICAL*4', and `COMPLEX*8'.) `KIND=2' This corresponds to types that occupy twice as much storage as the default types. `REAL(KIND=2)' is `DOUBLE PRECISION' (typically `REAL*8'), `COMPLEX(KIND=2)' is `DOUBLE COMPLEX' (typically `COMPLEX*16'), These are the "double precision" types described in the Fortran 90 standard, though that standard does not assign any particular `KIND=' value to these types. N of 4 thus corresponds to types that occupy four times as much storage as the default types, N of 8 to types that occupy eight times as much storage, and so on. The `INTEGER(KIND=2)' and `LOGICAL(KIND=2)' types are not necessarily supported by every GNU Fortran implementation. `KIND=3' This corresponds to types that occupy as much storage as the default `CHARACTER' type, which is the same effective type as `CHARACTER(KIND=1)' (making that type effectively the same as `CHARACTER(KIND=3)'). (Typically, these are `INTEGER*1' and `LOGICAL*1'.) N of 6 thus corresponds to types that occupy twice as much storage as the N=3 types, N of 12 to types that occupy four times as much storage, and so on. These are not necessarily supported by every GNU Fortran implementation. `KIND=5' This corresponds to types that occupy half the storage as the default (N=1) types. (Typically, these are `INTEGER*2' and `LOGICAL*2'.) N of 25 thus corresponds to types that occupy one-quarter as much storage as the default types. These are not necessarily supported by every GNU Fortran implementation. `KIND=7' This is valid only as `INTEGER(KIND=7)' and denotes the `INTEGER' type that has the smallest storage size that holds a pointer on the system. A pointer representable by this type is capable of uniquely addressing a `CHARACTER*1' variable, array, array element, or substring. (Typically this is equivalent to `INTEGER*4' or, on 64-bit systems, `INTEGER*8'. In a compatible C implementation, it typically would be the same size and semantics of the C type `void *'.) Note that these are _proposed_ correspondences and might change in future versions of `g77'--avoid writing code depending on them while `g77', and therefore the GNU Fortran language it defines, is in beta testing. Values not specified in the above list are reserved to future versions of the GNU Fortran language. Implementation-dependent meanings will be assigned new, unique prime numbers so as to not interfere with other implementation-dependent meanings, and offer the possibility of increasing the portability of code depending on such types by offering support for them in other GNU Fortran implementations. Other meanings that might be given unique values are: * Types that make use of only half their storage size for representing precision and range. For example, some compilers offer options that cause `INTEGER' types to occupy the amount of storage that would be needed for `INTEGER(KIND=2)' types, but the range remains that of `INTEGER(KIND=1)'. * The IEEE single floating-point type. * Types with a specific bit pattern (endianness), such as the little-endian form of `INTEGER(KIND=1)'. These could permit, conceptually, use of portable code and implementations on data files written by existing systems. Future _prime_ numbers should be given meanings in as incremental a fashion as possible, to allow for flexibility and expressiveness in combining types. For example, instead of defining a prime number for little-endian IEEE doubles, one prime number might be assigned the meaning "little-endian", another the meaning "IEEE double", and the value of N for a little-endian IEEE double would thus naturally be the product of those two respective assigned values. (It could even be reasonable to have IEEE values result from the products of prime values denoting exponent and fraction sizes and meanings, hidden bit usage, availability and representations of special values such as subnormals, infinities, and Not-A-Numbers (NaNs), and so on.) This assignment mechanism, while not inherently required for future versions of the GNU Fortran language, is worth using because it could ease management of the "space" of supported types much easier in the long run. The above approach suggests a mechanism for specifying inheritance of intrinsic (built-in) types for an entire, widely portable product line. It is certainly reasonable that, unlike programmers of other languages offering inheritance mechanisms that employ verbose names for classes and subclasses, along with graphical browsers to elucidate the relationships, Fortran programmers would employ a mechanism that works by multiplying prime numbers together and finding the prime factors of such products. Most of the advantages for the above scheme have been explained above. One disadvantage is that it could lead to the defining, by the GNU Fortran language, of some fairly large prime numbers. This could lead to the GNU Fortran language being declared "munitions" by the United States Department of Defense.  File: g77.info, Node: Constants, Next: Integer Type, Prev: Types, Up: Data Types and Constants Constants --------- (Corresponds to Section 4.2 of ANSI X3.9-1978 FORTRAN 77.) A "typeless constant" has one of the following forms: 'BINARY-DIGITS'B 'OCTAL-DIGITS'O 'HEXADECIMAL-DIGITS'Z 'HEXADECIMAL-DIGITS'X BINARY-DIGITS, OCTAL-DIGITS, and HEXADECIMAL-DIGITS are nonempty strings of characters in the set `01', `01234567', and `0123456789ABCDEFabcdef', respectively. (The value for `A' (and `a') is 10, for `B' and `b' is 11, and so on.) A prefix-radix constant, such as `Z'ABCD'', can optionally be treated as typeless. *Note Options Controlling Fortran Dialect: Fortran Dialect Options, for information on the `-ftypeless-boz' option. Typeless constants have values that depend on the context in which they are used. All other constants, called "typed constants", are interpreted--converted to internal form--according to their inherent type. Thus, context is _never_ a determining factor for the type, and hence the interpretation, of a typed constant. (All constants in the ANSI FORTRAN 77 language are typed constants.) For example, `1' is always type `INTEGER(KIND=1)' in GNU Fortran (called default INTEGER in Fortran 90), `9.435784839284958' is always type `REAL(KIND=1)' (even if the additional precision specified is lost, and even when used in a `REAL(KIND=2)' context), `1E0' is always type `REAL(KIND=2)', and `1D0' is always type `REAL(KIND=2)'.  File: g77.info, Node: Integer Type, Next: Character Type, Prev: Constants, Up: Data Types and Constants Integer Type ------------ (Corresponds to Section 4.3 of ANSI X3.9-1978 FORTRAN 77.) An integer constant also may have one of the following forms: B'BINARY-DIGITS' O'OCTAL-DIGITS' Z'HEXADECIMAL-DIGITS' X'HEXADECIMAL-DIGITS' BINARY-DIGITS, OCTAL-DIGITS, and HEXADECIMAL-DIGITS are nonempty strings of characters in the set `01', `01234567', and `0123456789ABCDEFabcdef', respectively. (The value for `A' (and `a') is 10, for `B' and `b' is 11, and so on.)  File: g77.info, Node: Character Type, Prev: Integer Type, Up: Data Types and Constants Character Type -------------- (Corresponds to Section 4.8 of ANSI X3.9-1978 FORTRAN 77.) A character constant may be delimited by a pair of double quotes (`"') instead of apostrophes. In this case, an apostrophe within the constant represents a single apostrophe, while a double quote is represented in the source text of the constant by two consecutive double quotes with no intervening spaces. A character constant may be empty (have a length of zero). A character constant may include a substring specification, The value of such a constant is the value of the substring--for example, the value of `'hello'(3:5)' is the same as the value of `'llo''.  File: g77.info, Node: Expressions, Next: Specification Statements, Prev: Data Types and Constants, Up: Language Expressions =========== (The following information augments or overrides the information in Chapter 6 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 6 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) * Menu: * %LOC()::  File: g77.info, Node: %LOC(), Up: Expressions The `%LOC()' Construct ---------------------- %LOC(ARG) The `%LOC()' construct is an expression that yields the value of the location of its argument, ARG, in memory. The size of the type of the expression depends on the system--typically, it is equivalent to either `INTEGER(KIND=1)' or `INTEGER(KIND=2)', though it is actually type `INTEGER(KIND=7)'. The argument to `%LOC()' must be suitable as the left-hand side of an assignment statement. That is, it may not be a general expression involving operators such as addition, subtraction, and so on, nor may it be a constant. Use of `%LOC()' is recommended only for code that is accessing facilities outside of GNU Fortran, such as operating system or windowing facilities. It is best to constrain such uses to isolated portions of a program--portions that deal specifically and exclusively with low-level, system-dependent facilities. Such portions might well provide a portable interface for use by the program as a whole, but are themselves not portable, and should be thoroughly tested each time they are rebuilt using a new compiler or version of a compiler. Do not depend on `%LOC()' returning a pointer that can be safely used to _define_ (change) the argument. While this might work in some circumstances, it is hard to predict whether it will continue to work when a program (that works using this unsafe behavior) is recompiled using different command-line options or a different version of `g77'. Generally, `%LOC()' is safe when used as an argument to a procedure that makes use of the value of the corresponding dummy argument only during its activation, and only when such use is restricted to referencing (reading) the value of the argument to `%LOC()'. _Implementation Note:_ Currently, `g77' passes arguments (those not passed using a construct such as `%VAL()') by reference or descriptor, depending on the type of the actual argument. Thus, given `INTEGER I', `CALL FOO(I)' would seem to mean the same thing as `CALL FOO(%VAL(%LOC(I)))', and in fact might compile to identical code. However, `CALL FOO(%VAL(%LOC(I)))' emphatically means "pass, by value, the address of `I' in memory". While `CALL FOO(I)' might use that same approach in a particular version of `g77', another version or compiler might choose a different implementation, such as copy-in/copy-out, to effect the desired behavior--and which will therefore not necessarily compile to the same code as would `CALL FOO(%VAL(%LOC(I)))' using the same version or compiler. *Note Debugging and Interfacing::, for detailed information on how this particular version of `g77' implements various constructs.  File: g77.info, Node: Specification Statements, Next: Control Statements, Prev: Expressions, Up: Language Specification Statements ======================== (The following information augments or overrides the information in Chapter 8 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 8 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) * Menu: * NAMELIST:: * DOUBLE COMPLEX::  File: g77.info, Node: NAMELIST, Next: DOUBLE COMPLEX, Up: Specification Statements `NAMELIST' Statement -------------------- The `NAMELIST' statement, and related I/O constructs, are supported by the GNU Fortran language in essentially the same way as they are by `f2c'. This follows Fortran 90 with the restriction that on `NAMELIST' input, subscripts must have the form SUBSCRIPT [ `:' SUBSCRIPT [ `:' STRIDE]] i.e. &xx x(1:3,8:10:2)=1,2,3,4,5,6/ is allowed, but not, say, &xx x(:3,8::2)=1,2,3,4,5,6/ As an extension of the Fortran 90 form, `$' and `$END' may be used in place of `&' and `/' in `NAMELIST' input, so that $&xx x(1:3,8:10:2)=1,2,3,4,5,6 $end could be used instead of the example above.  File: g77.info, Node: DOUBLE COMPLEX, Prev: NAMELIST, Up: Specification Statements `DOUBLE COMPLEX' Statement -------------------------- `DOUBLE COMPLEX' is a type-statement (and type) that specifies the type `COMPLEX(KIND=2)' in GNU Fortran.  File: g77.info, Node: Control Statements, Next: Functions and Subroutines, Prev: Specification Statements, Up: Language Control Statements ================== (The following information augments or overrides the information in Chapter 11 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 11 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) * Menu: * DO WHILE:: * END DO:: * Construct Names:: * CYCLE and EXIT::  File: g77.info, Node: DO WHILE, Next: END DO, Up: Control Statements DO WHILE -------- The `DO WHILE' statement, a feature of both the MIL-STD 1753 and Fortran 90 standards, is provided by the GNU Fortran language. The Fortran 90 "do forever" statement comprising just `DO' is also supported.  File: g77.info, Node: END DO, Next: Construct Names, Prev: DO WHILE, Up: Control Statements END DO ------ The `END DO' statement is provided by the GNU Fortran language. This statement is used in one of two ways: * The Fortran 90 meaning, in which it specifies the termination point of a single `DO' loop started with a `DO' statement that specifies no termination label. * The MIL-STD 1753 meaning, in which it specifies the termination point of one or more `DO' loops, all of which start with a `DO' statement that specify the label defined for the `END DO' statement. This kind of `END DO' statement is merely a synonym for `CONTINUE', except it is permitted only when the statement is labeled and a target of one or more labeled `DO' loops. It is expected that this use of `END DO' will be removed from the GNU Fortran language in the future, though it is likely that it will long be supported by `g77' as a dialect form.  File: g77.info, Node: Construct Names, Next: CYCLE and EXIT, Prev: END DO, Up: Control Statements Construct Names --------------- The GNU Fortran language supports construct names as defined by the Fortran 90 standard. These names are local to the program unit and are defined as follows: CONSTRUCT-NAME: BLOCK-STATEMENT Here, CONSTRUCT-NAME is the construct name itself; its definition is connoted by the single colon (`:'); and BLOCK-STATEMENT is an `IF', `DO', or `SELECT CASE' statement that begins a block. A block that is given a construct name must also specify the same construct name in its termination statement: END BLOCK CONSTRUCT-NAME Here, BLOCK must be `IF', `DO', or `SELECT', as appropriate.  File: g77.info, Node: CYCLE and EXIT, Prev: Construct Names, Up: Control Statements The `CYCLE' and `EXIT' Statements --------------------------------- The `CYCLE' and `EXIT' statements specify that the remaining statements in the current iteration of a particular active (enclosing) `DO' loop are to be skipped. `CYCLE' specifies that these statements are skipped, but the `END DO' statement that marks the end of the `DO' loop be executed--that is, the next iteration, if any, is to be started. If the statement marking the end of the `DO' loop is not `END DO'--in other words, if the loop is not a block `DO'--the `CYCLE' statement does not execute that statement, but does start the next iteration (if any). `EXIT' specifies that the loop specified by the `DO' construct is terminated. The `DO' loop affected by `CYCLE' and `EXIT' is the innermost enclosing `DO' loop when the following forms are used: CYCLE EXIT Otherwise, the following forms specify the construct name of the pertinent `DO' loop: CYCLE CONSTRUCT-NAME EXIT CONSTRUCT-NAME `CYCLE' and `EXIT' can be viewed as glorified `GO TO' statements. However, they cannot be easily thought of as `GO TO' statements in obscure cases involving FORTRAN 77 loops. For example: DO 10 I = 1, 5 DO 10 J = 1, 5 IF (J .EQ. 5) EXIT DO 10 K = 1, 5 IF (K .EQ. 3) CYCLE 10 PRINT *, 'I=', I, ' J=', J, ' K=', K 20 CONTINUE In particular, neither the `EXIT' nor `CYCLE' statements above are equivalent to a `GO TO' statement to either label `10' or `20'. To understand the effect of `CYCLE' and `EXIT' in the above fragment, it is helpful to first translate it to its equivalent using only block `DO' loops: DO I = 1, 5 DO J = 1, 5 IF (J .EQ. 5) EXIT DO K = 1, 5 IF (K .EQ. 3) CYCLE 10 PRINT *, 'I=', I, ' J=', J, ' K=', K END DO END DO END DO 20 CONTINUE Adding new labels allows translation of `CYCLE' and `EXIT' to `GO TO' so they may be more easily understood by programmers accustomed to FORTRAN coding: DO I = 1, 5 DO J = 1, 5 IF (J .EQ. 5) GOTO 18 DO K = 1, 5 IF (K .EQ. 3) GO TO 12 10 PRINT *, 'I=', I, ' J=', J, ' K=', K 12 END DO END DO 18 END DO 20 CONTINUE Thus, the `CYCLE' statement in the innermost loop skips over the `PRINT' statement as it begins the next iteration of the loop, while the `EXIT' statement in the middle loop ends that loop but _not_ the outermost loop.  File: g77.info, Node: Functions and Subroutines, Next: Scope and Classes of Names, Prev: Control Statements, Up: Language Functions and Subroutines ========================= (The following information augments or overrides the information in Chapter 15 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 15 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) * Menu: * %VAL():: * %REF():: * %DESCR():: * Generics and Specifics:: * REAL() and AIMAG() of Complex:: * CMPLX() of DOUBLE PRECISION:: * MIL-STD 1753:: * f77/f2c Intrinsics:: * Table of Intrinsic Functions::  File: g77.info, Node: %VAL(), Next: %REF(), Up: Functions and Subroutines The `%VAL()' Construct ---------------------- %VAL(ARG) The `%VAL()' construct specifies that an argument, ARG, is to be passed by value, instead of by reference or descriptor. `%VAL()' is restricted to actual arguments in invocations of external procedures. Use of `%VAL()' is recommended only for code that is accessing facilities outside of GNU Fortran, such as operating system or windowing facilities. It is best to constrain such uses to isolated portions of a program--portions the deal specifically and exclusively with low-level, system-dependent facilities. Such portions might well provide a portable interface for use by the program as a whole, but are themselves not portable, and should be thoroughly tested each time they are rebuilt using a new compiler or version of a compiler. _Implementation Note:_ Currently, `g77' passes all arguments either by reference or by descriptor. Thus, use of `%VAL()' tends to be restricted to cases where the called procedure is written in a language other than Fortran that supports call-by-value semantics. (C is an example of such a language.) *Note Procedures (SUBROUTINE and FUNCTION): Procedures, for detailed information on how this particular version of `g77' passes arguments to procedures.  File: g77.info, Node: %REF(), Next: %DESCR(), Prev: %VAL(), Up: Functions and Subroutines The `%REF()' Construct ---------------------- %REF(ARG) The `%REF()' construct specifies that an argument, ARG, is to be passed by reference, instead of by value or descriptor. `%REF()' is restricted to actual arguments in invocations of external procedures. Use of `%REF()' is recommended only for code that is accessing facilities outside of GNU Fortran, such as operating system or windowing facilities. It is best to constrain such uses to isolated portions of a program--portions the deal specifically and exclusively with low-level, system-dependent facilities. Such portions might well provide a portable interface for use by the program as a whole, but are themselves not portable, and should be thoroughly tested each time they are rebuilt using a new compiler or version of a compiler. Do not depend on `%REF()' supplying a pointer to the procedure being invoked. While that is a likely implementation choice, other implementation choices are available that preserve Fortran pass-by-reference semantics without passing a pointer to the argument, ARG. (For example, a copy-in/copy-out implementation.) _Implementation Note:_ Currently, `g77' passes all arguments (other than variables and arrays of type `CHARACTER') by reference. Future versions of, or dialects supported by, `g77' might not pass `CHARACTER' functions by reference. Thus, use of `%REF()' tends to be restricted to cases where ARG is type `CHARACTER' but the called procedure accesses it via a means other than the method used for Fortran `CHARACTER' arguments. *Note Procedures (SUBROUTINE and FUNCTION): Procedures, for detailed information on how this particular version of `g77' passes arguments to procedures.  File: g77.info, Node: %DESCR(), Next: Generics and Specifics, Prev: %REF(), Up: Functions and Subroutines The `%DESCR()' Construct ------------------------ %DESCR(ARG) The `%DESCR()' construct specifies that an argument, ARG, is to be passed by descriptor, instead of by value or reference. `%DESCR()' is restricted to actual arguments in invocations of external procedures. Use of `%DESCR()' is recommended only for code that is accessing facilities outside of GNU Fortran, such as operating system or windowing facilities. It is best to constrain such uses to isolated portions of a program--portions the deal specifically and exclusively with low-level, system-dependent facilities. Such portions might well provide a portable interface for use by the program as a whole, but are themselves not portable, and should be thoroughly tested each time they are rebuilt using a new compiler or version of a compiler. Do not depend on `%DESCR()' supplying a pointer and/or a length passed by value to the procedure being invoked. While that is a likely implementation choice, other implementation choices are available that preserve the pass-by-reference semantics without passing a pointer to the argument, ARG. (For example, a copy-in/copy-out implementation.) And, future versions of `g77' might change the way descriptors are implemented, such as passing a single argument pointing to a record containing the pointer/length information instead of passing that same information via two arguments as it currently does. _Implementation Note:_ Currently, `g77' passes all variables and arrays of type `CHARACTER' by descriptor. Future versions of, or dialects supported by, `g77' might pass `CHARACTER' functions by descriptor as well. Thus, use of `%DESCR()' tends to be restricted to cases where ARG is not type `CHARACTER' but the called procedure accesses it via a means similar to the method used for Fortran `CHARACTER' arguments. *Note Procedures (SUBROUTINE and FUNCTION): Procedures, for detailed information on how this particular version of `g77' passes arguments to procedures.  File: g77.info, Node: Generics and Specifics, Next: REAL() and AIMAG() of Complex, Prev: %DESCR(), Up: Functions and Subroutines Generics and Specifics ---------------------- The ANSI FORTRAN 77 language defines generic and specific intrinsics. In short, the distinctions are: * _Specific_ intrinsics have specific types for their arguments and a specific return type. * _Generic_ intrinsics are treated, on a case-by-case basis in the program's source code, as one of several possible specific intrinsics. Typically, a generic intrinsic has a return type that is determined by the type of one or more of its arguments. The GNU Fortran language generalizes these concepts somewhat, especially by providing intrinsic subroutines and generic intrinsics that are treated as either a specific intrinsic subroutine or a specific intrinsic function (e.g. `SECOND'). However, GNU Fortran avoids generalizing this concept to the point where existing code would be accepted as meaning something possibly different than what was intended. For example, `ABS' is a generic intrinsic, so all working code written using `ABS' of an `INTEGER' argument expects an `INTEGER' return value. Similarly, all such code expects that `ABS' of an `INTEGER*2' argument returns an `INTEGER*2' return value. Yet, `IABS' is a _specific_ intrinsic that accepts only an `INTEGER(KIND=1)' argument. Code that passes something other than an `INTEGER(KIND=1)' argument to `IABS' is not valid GNU Fortran code, because it is not clear what the author intended. For example, if `J' is `INTEGER(KIND=6)', `IABS(J)' is not defined by the GNU Fortran language, because the programmer might have used that construct to mean any of the following, subtly different, things: * Convert `J' to `INTEGER(KIND=1)' first (as if `IABS(INT(J))' had been written). * Convert the result of the intrinsic to `INTEGER(KIND=1)' (as if `INT(ABS(J))' had been written). * No conversion (as if `ABS(J)' had been written). The distinctions matter especially when types and values wider than `INTEGER(KIND=1)' (such as `INTEGER(KIND=2)'), or when operations performing more "arithmetic" than absolute-value, are involved. The following sample program is not a valid GNU Fortran program, but might be accepted by other compilers. If so, the output is likely to be revealing in terms of how a given compiler treats intrinsics (that normally are specific) when they are given arguments that do not conform to their stated requirements: PROGRAM JCB002 C Version 1: C Modified 1999-02-15 (Burley) to delete my email address. C Modified 1997-05-21 (Burley) to accommodate compilers that implement C INT(I1-I2) as INT(I1)-INT(I2) given INTEGER*2 I1,I2. C C Version 0: C Written by James Craig Burley 1997-02-20. C C Purpose: C Determine how compilers handle non-standard IDIM C on INTEGER*2 operands, which presumably can be C extrapolated into understanding how the compiler C generally treats specific intrinsics that are passed C arguments not of the correct types. C C If your compiler implements INTEGER*2 and INTEGER C as the same type, change all INTEGER*2 below to C INTEGER*1. C INTEGER*2 I0, I4 INTEGER I1, I2, I3 INTEGER*2 ISMALL, ILARGE INTEGER*2 ITOOLG, ITWO INTEGER*2 ITMP LOGICAL L2, L3, L4 C C Find smallest INTEGER*2 number. C ISMALL=0 10 I0 = ISMALL-1 IF ((I0 .GE. ISMALL) .OR. (I0+1 .NE. ISMALL)) GOTO 20 ISMALL = I0 GOTO 10 20 CONTINUE C C Find largest INTEGER*2 number. C ILARGE=0 30 I0 = ILARGE+1 IF ((I0 .LE. ILARGE) .OR. (I0-1 .NE. ILARGE)) GOTO 40 ILARGE = I0 GOTO 30 40 CONTINUE C C Multiplying by two adds stress to the situation. C ITWO = 2 C C Need a number that, added to -2, is too wide to fit in I*2. C ITOOLG = ISMALL C C Use IDIM the straightforward way. C I1 = IDIM (ILARGE, ISMALL) * ITWO + ITOOLG C C Calculate result for first interpretation. C I2 = (INT (ILARGE) - INT (ISMALL)) * ITWO + ITOOLG C C Calculate result for second interpretation. C ITMP = ILARGE - ISMALL I3 = (INT (ITMP)) * ITWO + ITOOLG C C Calculate result for third interpretation. C I4 = (ILARGE - ISMALL) * ITWO + ITOOLG C C Print results. C PRINT *, 'ILARGE=', ILARGE PRINT *, 'ITWO=', ITWO PRINT *, 'ITOOLG=', ITOOLG PRINT *, 'ISMALL=', ISMALL PRINT *, 'I1=', I1 PRINT *, 'I2=', I2 PRINT *, 'I3=', I3 PRINT *, 'I4=', I4 PRINT * L2 = (I1 .EQ. I2) L3 = (I1 .EQ. I3) L4 = (I1 .EQ. I4) IF (L2 .AND. .NOT.L3 .AND. .NOT.L4) THEN PRINT *, 'Interp 1: IDIM(I*2,I*2) => IDIM(INT(I*2),INT(I*2))' STOP END IF IF (L3 .AND. .NOT.L2 .AND. .NOT.L4) THEN PRINT *, 'Interp 2: IDIM(I*2,I*2) => INT(DIM(I*2,I*2))' STOP END IF IF (L4 .AND. .NOT.L2 .AND. .NOT.L3) THEN PRINT *, 'Interp 3: IDIM(I*2,I*2) => DIM(I*2,I*2)' STOP END IF PRINT *, 'Results need careful analysis.' END No future version of the GNU Fortran language will likely permit specific intrinsic invocations with wrong-typed arguments (such as `IDIM' in the above example), since it has been determined that disagreements exist among many production compilers on the interpretation of such invocations. These disagreements strongly suggest that Fortran programmers, and certainly existing Fortran programs, disagree about the meaning of such invocations. The first version of `JCB002' didn't accommodate some compilers' treatment of `INT(I1-I2)' where `I1' and `I2' are `INTEGER*2'. In such a case, these compilers apparently convert both operands to `INTEGER*4' and then do an `INTEGER*4' subtraction, instead of doing an `INTEGER*2' subtraction on the original values in `I1' and `I2'. However, the results of the careful analyses done on the outputs of programs compiled by these various compilers show that they all implement either `Interp 1' or `Interp 2' above. Specifically, it is believed that the new version of `JCB002' above will confirm that: * Digital Semiconductor ("DEC") Alpha OSF/1, HP-UX 10.0.1, AIX 3.2.5 `f77' compilers all implement `Interp 1'. * IRIX 5.3 `f77' compiler implements `Interp 2'. * Solaris 2.5, SunOS 4.1.3, DECstation ULTRIX 4.3, and IRIX 6.1 `f77' compilers all implement `Interp 3'. If you get different results than the above for the stated compilers, or have results for other compilers that might be worth adding to the above list, please let us know the details (compiler product, version, machine, results, and so on).  File: g77.info, Node: REAL() and AIMAG() of Complex, Next: CMPLX() of DOUBLE PRECISION, Prev: Generics and Specifics, Up: Functions and Subroutines `REAL()' and `AIMAG()' of Complex --------------------------------- The GNU Fortran language disallows `REAL(EXPR)' and `AIMAG(EXPR)', where EXPR is any `COMPLEX' type other than `COMPLEX(KIND=1)', except when they are used in the following way: REAL(REAL(EXPR)) REAL(AIMAG(EXPR)) The above forms explicitly specify that the desired effect is to convert the real or imaginary part of EXPR, which might be some `REAL' type other than `REAL(KIND=1)', to type `REAL(KIND=1)', and have that serve as the value of the expression. The GNU Fortran language offers clearly named intrinsics to extract the real and imaginary parts of a complex entity without any conversion: REALPART(EXPR) IMAGPART(EXPR) To express the above using typical extended FORTRAN 77, use the following constructs (when EXPR is `COMPLEX(KIND=2)'): DBLE(EXPR) DIMAG(EXPR) The FORTRAN 77 language offers no way to explicitly specify the real and imaginary parts of a complex expression of arbitrary type, apparently as a result of requiring support for only one `COMPLEX' type (`COMPLEX(KIND=1)'). The concepts of converting an expression to type `REAL(KIND=1)' and of extracting the real part of a complex expression were thus "smooshed" by FORTRAN 77 into a single intrinsic, since they happened to have the exact same effect in that language (due to having only one `COMPLEX' type). _Note:_ When `-ff90' is in effect, `g77' treats `REAL(EXPR)', where EXPR is of type `COMPLEX', as `REALPART(EXPR)', whereas with `-fugly-complex -fno-f90' in effect, it is treated as `REAL(REALPART(EXPR))'. *Note Ugly Complex Part Extraction::, for more information.  File: g77.info, Node: CMPLX() of DOUBLE PRECISION, Next: MIL-STD 1753, Prev: REAL() and AIMAG() of Complex, Up: Functions and Subroutines `CMPLX()' of `DOUBLE PRECISION' ------------------------------- In accordance with Fortran 90 and at least some (perhaps all) other compilers, the GNU Fortran language defines `CMPLX()' as always returning a result that is type `COMPLEX(KIND=1)'. This means `CMPLX(D1,D2)', where `D1' and `D2' are `REAL(KIND=2)' (`DOUBLE PRECISION'), is treated as: CMPLX(SNGL(D1), SNGL(D2)) (It was necessary for Fortran 90 to specify this behavior for `DOUBLE PRECISION' arguments, since that is the behavior mandated by FORTRAN 77.) The GNU Fortran language also provides the `DCMPLX()' intrinsic, which is provided by some FORTRAN 77 compilers to construct a `DOUBLE COMPLEX' entity from of `DOUBLE PRECISION' operands. However, this solution does not scale well when more `COMPLEX' types (having various precisions and ranges) are offered by Fortran implementations. Fortran 90 extends the `CMPLX()' intrinsic by adding an extra argument used to specify the desired kind of complex result. However, this solution is somewhat awkward to use, and `g77' currently does not support it. The GNU Fortran language provides a simple way to build a complex value out of two numbers, with the precise type of the value determined by the types of the two numbers (via the usual type-promotion mechanism): COMPLEX(REAL, IMAG) When REAL and IMAG are the same `REAL' types, `COMPLEX()' performs no conversion other than to put them together to form a complex result of the same (complex version of real) type. *Note Complex Intrinsic::, for more information.  File: g77.info, Node: MIL-STD 1753, Next: f77/f2c Intrinsics, Prev: CMPLX() of DOUBLE PRECISION, Up: Functions and Subroutines MIL-STD 1753 Support -------------------- The GNU Fortran language includes the MIL-STD 1753 intrinsics `BTEST', `IAND', `IBCLR', `IBITS', `IBSET', `IEOR', `IOR', `ISHFT', `ISHFTC', `MVBITS', and `NOT'.  File: g77.info, Node: f77/f2c Intrinsics, Next: Table of Intrinsic Functions, Prev: MIL-STD 1753, Up: Functions and Subroutines `f77'/`f2c' Intrinsics ---------------------- The bit-manipulation intrinsics supported by traditional `f77' and by `f2c' are available in the GNU Fortran language. These include `AND', `LSHIFT', `OR', `RSHIFT', and `XOR'. Also supported are the intrinsics `CDABS', `CDCOS', `CDEXP', `CDLOG', `CDSIN', `CDSQRT', `DCMPLX', `DCONJG', `DFLOAT', `DIMAG', `DREAL', and `IMAG', `ZABS', `ZCOS', `ZEXP', `ZLOG', `ZSIN', and `ZSQRT'.  File: g77.info, Node: Table of Intrinsic Functions, Prev: f77/f2c Intrinsics, Up: Functions and Subroutines Table of Intrinsic Functions ---------------------------- (Corresponds to Section 15.10 of ANSI X3.9-1978 FORTRAN 77.) The GNU Fortran language adds various functions, subroutines, types, and arguments to the set of intrinsic functions in ANSI FORTRAN 77. The complete set of intrinsics supported by the GNU Fortran language is described below. Note that a name is not treated as that of an intrinsic if it is specified in an `EXTERNAL' statement in the same program unit; if a command-line option is used to disable the groups to which the intrinsic belongs; or if the intrinsic is not named in an `INTRINSIC' statement and a command-line option is used to hide the groups to which the intrinsic belongs. So, it is recommended that any reference in a program unit to an intrinsic procedure that is not a standard FORTRAN 77 intrinsic be accompanied by an appropriate `INTRINSIC' statement in that program unit. This sort of defensive programming makes it more likely that an implementation will issue a diagnostic rather than generate incorrect code for such a reference. The terminology used below is based on that of the Fortran 90 standard, so that the text may be more concise and accurate: * `OPTIONAL' means the argument may be omitted. * `A-1, A-2, ..., A-n' means more than one argument (generally named `A') may be specified. * `scalar' means the argument must not be an array (must be a variable or array element, or perhaps a constant if expressions are permitted). * `DIMENSION(4)' means the argument must be an array having 4 elements. * `INTENT(IN)' means the argument must be an expression (such as a constant or a variable that is defined upon invocation of the intrinsic). * `INTENT(OUT)' means the argument must be definable by the invocation of the intrinsic (that is, must not be a constant nor an expression involving operators other than array reference and substring reference). * `INTENT(INOUT)' means the argument must be defined prior to, and definable by, invocation of the intrinsic (a combination of the requirements of `INTENT(IN)' and `INTENT(OUT)'. * *Note Kind Notation::, for an explanation of `KIND'. (Note that the empty lines appearing in the menu below are not intentional--they result from a bug in the GNU `makeinfo' program...a program that, if it did not exist, would leave this document in far worse shape!) * Menu: * Abort Intrinsic:: Abort the program. * Abs Intrinsic:: Absolute value. * Access Intrinsic:: Check file accessibility. * AChar Intrinsic:: ASCII character from code. * ACos Intrinsic:: Arc cosine. * AdjustL Intrinsic:: (Reserved for future use.) * AdjustR Intrinsic:: (Reserved for future use.) * AImag Intrinsic:: Convert/extract imaginary part of complex. * AInt Intrinsic:: Truncate to whole number. * Alarm Intrinsic:: Execute a routine after a given delay. * All Intrinsic:: (Reserved for future use.) * Allocated Intrinsic:: (Reserved for future use.) * ALog Intrinsic:: Natural logarithm (archaic). * ALog10 Intrinsic:: Common logarithm (archaic). * AMax0 Intrinsic:: Maximum value (archaic). * AMax1 Intrinsic:: Maximum value (archaic). * AMin0 Intrinsic:: Minimum value (archaic). * AMin1 Intrinsic:: Minimum value (archaic). * AMod Intrinsic:: Remainder (archaic). * And Intrinsic:: Boolean AND. * ANInt Intrinsic:: Round to nearest whole number. * Any Intrinsic:: (Reserved for future use.) * ASin Intrinsic:: Arc sine. * Associated Intrinsic:: (Reserved for future use.) * ATan Intrinsic:: Arc tangent. * ATan2 Intrinsic:: Arc tangent. * BesJ0 Intrinsic:: Bessel function. * BesJ1 Intrinsic:: Bessel function. * BesJN Intrinsic:: Bessel function. * BesY0 Intrinsic:: Bessel function. * BesY1 Intrinsic:: Bessel function. * BesYN Intrinsic:: Bessel function. * Bit_Size Intrinsic:: Number of bits in argument's type. * BTest Intrinsic:: Test bit. * CAbs Intrinsic:: Absolute value (archaic). * CCos Intrinsic:: Cosine (archaic). * Ceiling Intrinsic:: (Reserved for future use.) * CExp Intrinsic:: Exponential (archaic). * Char Intrinsic:: Character from code. * ChDir Intrinsic (subroutine):: Change directory. * ChMod Intrinsic (subroutine):: Change file modes. * CLog Intrinsic:: Natural logarithm (archaic). * Cmplx Intrinsic:: Construct `COMPLEX(KIND=1)' value. * Complex Intrinsic:: Build complex value from real and imaginary parts. * Conjg Intrinsic:: Complex conjugate. * Cos Intrinsic:: Cosine. * CosH Intrinsic:: Hyperbolic cosine. * Count Intrinsic:: (Reserved for future use.) * CPU_Time Intrinsic:: Get current CPU time. * CShift Intrinsic:: (Reserved for future use.) * CSin Intrinsic:: Sine (archaic). * CSqRt Intrinsic:: Square root (archaic). * CTime Intrinsic (subroutine):: Convert time to Day Mon dd hh:mm:ss yyyy. * CTime Intrinsic (function):: Convert time to Day Mon dd hh:mm:ss yyyy. * DAbs Intrinsic:: Absolute value (archaic). * DACos Intrinsic:: Arc cosine (archaic). * DASin Intrinsic:: Arc sine (archaic). * DATan Intrinsic:: Arc tangent (archaic). * DATan2 Intrinsic:: Arc tangent (archaic). * Date_and_Time Intrinsic:: Get the current date and time. * DbesJ0 Intrinsic:: Bessel function (archaic). * DbesJ1 Intrinsic:: Bessel function (archaic). * DbesJN Intrinsic:: Bessel function (archaic). * DbesY0 Intrinsic:: Bessel function (archaic). * DbesY1 Intrinsic:: Bessel function (archaic). * DbesYN Intrinsic:: Bessel function (archaic). * Dble Intrinsic:: Convert to double precision. * DCos Intrinsic:: Cosine (archaic). * DCosH Intrinsic:: Hyperbolic cosine (archaic). * DDiM Intrinsic:: Difference magnitude (archaic). * DErF Intrinsic:: Error function (archaic). * DErFC Intrinsic:: Complementary error function (archaic). * DExp Intrinsic:: Exponential (archaic). * Digits Intrinsic:: (Reserved for future use.) * DiM Intrinsic:: Difference magnitude (non-negative subtract). * DInt Intrinsic:: Truncate to whole number (archaic). * DLog Intrinsic:: Natural logarithm (archaic). * DLog10 Intrinsic:: Common logarithm (archaic). * DMax1 Intrinsic:: Maximum value (archaic). * DMin1 Intrinsic:: Minimum value (archaic). * DMod Intrinsic:: Remainder (archaic). * DNInt Intrinsic:: Round to nearest whole number (archaic). * Dot_Product Intrinsic:: (Reserved for future use.) * DProd Intrinsic:: Double-precision product. * DSign Intrinsic:: Apply sign to magnitude (archaic). * DSin Intrinsic:: Sine (archaic). * DSinH Intrinsic:: Hyperbolic sine (archaic). * DSqRt Intrinsic:: Square root (archaic). * DTan Intrinsic:: Tangent (archaic). * DTanH Intrinsic:: Hyperbolic tangent (archaic). * DTime Intrinsic (subroutine):: Get elapsed time since last time. * EOShift Intrinsic:: (Reserved for future use.) * Epsilon Intrinsic:: (Reserved for future use.) * ErF Intrinsic:: Error function. * ErFC Intrinsic:: Complementary error function. * ETime Intrinsic (subroutine):: Get elapsed time for process. * ETime Intrinsic (function):: Get elapsed time for process. * Exit Intrinsic:: Terminate the program. * Exp Intrinsic:: Exponential. * Exponent Intrinsic:: (Reserved for future use.) * FDate Intrinsic (subroutine):: Get current time as Day Mon dd hh:mm:ss yyyy. * FDate Intrinsic (function):: Get current time as Day Mon dd hh:mm:ss yyyy. * FGet Intrinsic (subroutine):: Read a character from unit 5 stream-wise. * FGetC Intrinsic (subroutine):: Read a character stream-wise. * Float Intrinsic:: Conversion (archaic). * Floor Intrinsic:: (Reserved for future use.) * Flush Intrinsic:: Flush buffered output. * FNum Intrinsic:: Get file descriptor from Fortran unit number. * FPut Intrinsic (subroutine):: Write a character to unit 6 stream-wise. * FPutC Intrinsic (subroutine):: Write a character stream-wise. * Fraction Intrinsic:: (Reserved for future use.) * FSeek Intrinsic:: Position file (low-level). * FStat Intrinsic (subroutine):: Get file information. * FStat Intrinsic (function):: Get file information. * FTell Intrinsic (subroutine):: Get file position (low-level). * FTell Intrinsic (function):: Get file position (low-level). * GError Intrinsic:: Get error message for last error. * GetArg Intrinsic:: Obtain command-line argument. * GetCWD Intrinsic (subroutine):: Get current working directory. * GetCWD Intrinsic (function):: Get current working directory. * GetEnv Intrinsic:: Get environment variable. * GetGId Intrinsic:: Get process group id. * GetLog Intrinsic:: Get login name. * GetPId Intrinsic:: Get process id. * GetUId Intrinsic:: Get process user id. * GMTime Intrinsic:: Convert time to GMT time info. * HostNm Intrinsic (subroutine):: Get host name. * HostNm Intrinsic (function):: Get host name. * Huge Intrinsic:: (Reserved for future use.) * IAbs Intrinsic:: Absolute value (archaic). * IAChar Intrinsic:: ASCII code for character. * IAnd Intrinsic:: Boolean AND. * IArgC Intrinsic:: Obtain count of command-line arguments. * IBClr Intrinsic:: Clear a bit. * IBits Intrinsic:: Extract a bit subfield of a variable. * IBSet Intrinsic:: Set a bit. * IChar Intrinsic:: Code for character. * IDate Intrinsic (UNIX):: Get local time info. * IDiM Intrinsic:: Difference magnitude (archaic). * IDInt Intrinsic:: Convert to `INTEGER' value truncated to whole number (archaic). * IDNInt Intrinsic:: Convert to `INTEGER' value rounded to nearest whole number (archaic). * IEOr Intrinsic:: Boolean XOR. * IErrNo Intrinsic:: Get error number for last error. * IFix Intrinsic:: Conversion (archaic). * Imag Intrinsic:: Extract imaginary part of complex. * ImagPart Intrinsic:: Extract imaginary part of complex. * Index Intrinsic:: Locate a CHARACTER substring. * Int Intrinsic:: Convert to `INTEGER' value truncated to whole number. * Int2 Intrinsic:: Convert to `INTEGER(KIND=6)' value truncated to whole number. * Int8 Intrinsic:: Convert to `INTEGER(KIND=2)' value truncated to whole number. * IOr Intrinsic:: Boolean OR. * IRand Intrinsic:: Random number. * IsaTty Intrinsic:: Is unit connected to a terminal? * IShft Intrinsic:: Logical bit shift. * IShftC Intrinsic:: Circular bit shift. * ISign Intrinsic:: Apply sign to magnitude (archaic). * ITime Intrinsic:: Get local time of day. * Kill Intrinsic (subroutine):: Signal a process. * Kind Intrinsic:: (Reserved for future use.) * LBound Intrinsic:: (Reserved for future use.) * Len Intrinsic:: Length of character entity. * Len_Trim Intrinsic:: Get last non-blank character in string. * LGe Intrinsic:: Lexically greater than or equal. * LGt Intrinsic:: Lexically greater than. * Link Intrinsic (subroutine):: Make hard link in file system. * LLe Intrinsic:: Lexically less than or equal. * LLt Intrinsic:: Lexically less than. * LnBlnk Intrinsic:: Get last non-blank character in string. * Loc Intrinsic:: Address of entity in core. * Log Intrinsic:: Natural logarithm. * Log10 Intrinsic:: Common logarithm. * Logical Intrinsic:: (Reserved for future use.) * Long Intrinsic:: Conversion to `INTEGER(KIND=1)' (archaic). * LShift Intrinsic:: Left-shift bits. * LStat Intrinsic (subroutine):: Get file information. * LStat Intrinsic (function):: Get file information. * LTime Intrinsic:: Convert time to local time info. * MatMul Intrinsic:: (Reserved for future use.) * Max Intrinsic:: Maximum value. * Max0 Intrinsic:: Maximum value (archaic). * Max1 Intrinsic:: Maximum value (archaic). * MaxExponent Intrinsic:: (Reserved for future use.) * MaxLoc Intrinsic:: (Reserved for future use.) * MaxVal Intrinsic:: (Reserved for future use.) * MClock Intrinsic:: Get number of clock ticks for process. * MClock8 Intrinsic:: Get number of clock ticks for process. * Merge Intrinsic:: (Reserved for future use.) * Min Intrinsic:: Minimum value. * Min0 Intrinsic:: Minimum value (archaic). * Min1 Intrinsic:: Minimum value (archaic). * MinExponent Intrinsic:: (Reserved for future use.) * MinLoc Intrinsic:: (Reserved for future use.) * MinVal Intrinsic:: (Reserved for future use.) * Mod Intrinsic:: Remainder. * Modulo Intrinsic:: (Reserved for future use.) * MvBits Intrinsic:: Moving a bit field. * Nearest Intrinsic:: (Reserved for future use.) * NInt Intrinsic:: Convert to `INTEGER' value rounded to nearest whole number. * Not Intrinsic:: Boolean NOT. * Or Intrinsic:: Boolean OR. * Pack Intrinsic:: (Reserved for future use.) * PError Intrinsic:: Print error message for last error. * Precision Intrinsic:: (Reserved for future use.) * Present Intrinsic:: (Reserved for future use.) * Product Intrinsic:: (Reserved for future use.) * Radix Intrinsic:: (Reserved for future use.) * Rand Intrinsic:: Random number. * Random_Number Intrinsic:: (Reserved for future use.) * Random_Seed Intrinsic:: (Reserved for future use.) * Range Intrinsic:: (Reserved for future use.) * Real Intrinsic:: Convert value to type `REAL(KIND=1)'. * RealPart Intrinsic:: Extract real part of complex. * Rename Intrinsic (subroutine):: Rename file. * Repeat Intrinsic:: (Reserved for future use.) * Reshape Intrinsic:: (Reserved for future use.) * RRSpacing Intrinsic:: (Reserved for future use.) * RShift Intrinsic:: Right-shift bits. * Scale Intrinsic:: (Reserved for future use.) * Scan Intrinsic:: (Reserved for future use.) * Second Intrinsic (function):: Get CPU time for process in seconds. * Second Intrinsic (subroutine):: Get CPU time for process in seconds. * Selected_Int_Kind Intrinsic:: (Reserved for future use.) * Selected_Real_Kind Intrinsic:: (Reserved for future use.) * Set_Exponent Intrinsic:: (Reserved for future use.) * Shape Intrinsic:: (Reserved for future use.) * Short Intrinsic:: Convert to `INTEGER(KIND=6)' value truncated to whole number. * Sign Intrinsic:: Apply sign to magnitude. * Signal Intrinsic (subroutine):: Muck with signal handling. * Sin Intrinsic:: Sine. * SinH Intrinsic:: Hyperbolic sine. * Sleep Intrinsic:: Sleep for a specified time. * Sngl Intrinsic:: Convert (archaic). * Spacing Intrinsic:: (Reserved for future use.) * Spread Intrinsic:: (Reserved for future use.) * SqRt Intrinsic:: Square root. * SRand Intrinsic:: Random seed. * Stat Intrinsic (subroutine):: Get file information. * Stat Intrinsic (function):: Get file information. * Sum Intrinsic:: (Reserved for future use.) * SymLnk Intrinsic (subroutine):: Make symbolic link in file system. * System Intrinsic (subroutine):: Invoke shell (system) command. * System_Clock Intrinsic:: Get current system clock value. * Tan Intrinsic:: Tangent. * TanH Intrinsic:: Hyperbolic tangent. * Time Intrinsic (UNIX):: Get current time as time value. * Time8 Intrinsic:: Get current time as time value. * Tiny Intrinsic:: (Reserved for future use.) * Transfer Intrinsic:: (Reserved for future use.) * Transpose Intrinsic:: (Reserved for future use.) * Trim Intrinsic:: (Reserved for future use.) * TtyNam Intrinsic (subroutine):: Get name of terminal device for unit. * TtyNam Intrinsic (function):: Get name of terminal device for unit. * UBound Intrinsic:: (Reserved for future use.) * UMask Intrinsic (subroutine):: Set file creation permissions mask. * Unlink Intrinsic (subroutine):: Unlink file. * Unpack Intrinsic:: (Reserved for future use.) * Verify Intrinsic:: (Reserved for future use.) * XOr Intrinsic:: Boolean XOR. * ZAbs Intrinsic:: Absolute value (archaic). * ZCos Intrinsic:: Cosine (archaic). * ZExp Intrinsic:: Exponential (archaic). * ZLog Intrinsic:: Natural logarithm (archaic). * ZSin Intrinsic:: Sine (archaic). * ZSqRt Intrinsic:: Square root (archaic).  File: g77.info, Node: Abort Intrinsic, Next: Abs Intrinsic, Up: Table of Intrinsic Functions Abort Intrinsic ............... CALL Abort() Intrinsic groups: `unix'. Description: Prints a message and potentially causes a core dump via `abort(3)'.  File: g77.info, Node: Abs Intrinsic, Next: Access Intrinsic, Prev: Abort Intrinsic, Up: Table of Intrinsic Functions Abs Intrinsic ............. Abs(A) Abs: `INTEGER' or `REAL' function. The exact type depends on that of argument A--if A is `COMPLEX', this function's type is `REAL' with the same `KIND=' value as the type of A. Otherwise, this function's type is the same as that of A. A: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the absolute value of A. If A is type `COMPLEX', the absolute value is computed as: SQRT(REALPART(A)**2+IMAGPART(A)**2) Otherwise, it is computed by negating A if it is negative, or returning A. *Note Sign Intrinsic::, for how to explicitly compute the positive or negative form of the absolute value of an expression.  File: g77.info, Node: Access Intrinsic, Next: AChar Intrinsic, Prev: Abs Intrinsic, Up: Table of Intrinsic Functions Access Intrinsic ................ Access(NAME, MODE) Access: `INTEGER(KIND=1)' function. NAME: `CHARACTER'; scalar; INTENT(IN). MODE: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Checks file NAME for accessibility in the mode specified by MODE and returns 0 if the file is accessible in that mode, otherwise an error code if the file is inaccessible or MODE is invalid. See `access(2)'. A null character (`CHAR(0)') marks the end of the name in NAME--otherwise, trailing blanks in NAME are ignored. MODE may be a concatenation of any of the following characters: `r' Read permission `w' Write permission `x' Execute permission `SPC' Existence  File: g77.info, Node: AChar Intrinsic, Next: ACos Intrinsic, Prev: Access Intrinsic, Up: Table of Intrinsic Functions AChar Intrinsic ............... AChar(I) AChar: `CHARACTER*1' function. I: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `f2c', `f90'. Description: Returns the ASCII character corresponding to the code specified by I. *Note IAChar Intrinsic::, for the inverse of this function. *Note Char Intrinsic::, for the function corresponding to the system's native character set.  File: g77.info, Node: ACos Intrinsic, Next: AdjustL Intrinsic, Prev: AChar Intrinsic, Up: Table of Intrinsic Functions ACos Intrinsic .............. ACos(X) ACos: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the arc-cosine (inverse cosine) of X in radians. *Note Cos Intrinsic::, for the inverse of this function.  File: g77.info, Node: AdjustL Intrinsic, Next: AdjustR Intrinsic, Prev: ACos Intrinsic, Up: Table of Intrinsic Functions AdjustL Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL AdjustL' to use this name for an external procedure.  File: g77.info, Node: AdjustR Intrinsic, Next: AImag Intrinsic, Prev: AdjustL Intrinsic, Up: Table of Intrinsic Functions AdjustR Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL AdjustR' to use this name for an external procedure.  File: g77.info, Node: AImag Intrinsic, Next: AInt Intrinsic, Prev: AdjustR Intrinsic, Up: Table of Intrinsic Functions AImag Intrinsic ............... AImag(Z) AImag: `REAL' function. This intrinsic is valid when argument Z is `COMPLEX(KIND=1)'. When Z is any other `COMPLEX' type, this intrinsic is valid only when used as the argument to `REAL()', as explained below. Z: `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the (possibly converted) imaginary part of Z. Use of `AIMAG()' with an argument of a type other than `COMPLEX(KIND=1)' is restricted to the following case: REAL(AIMAG(Z)) This expression converts the imaginary part of Z to `REAL(KIND=1)'. *Note REAL() and AIMAG() of Complex::, for more information.  File: g77.info, Node: AInt Intrinsic, Next: Alarm Intrinsic, Prev: AImag Intrinsic, Up: Table of Intrinsic Functions AInt Intrinsic .............. AInt(A) AInt: `REAL' function, the `KIND=' value of the type being that of argument A. A: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns A with the fractional portion of its magnitude truncated and its sign preserved. (Also called "truncation towards zero".) *Note ANInt Intrinsic::, for how to round to nearest whole number. *Note Int Intrinsic::, for how to truncate and then convert number to `INTEGER'.  File: g77.info, Node: Alarm Intrinsic, Next: All Intrinsic, Prev: AInt Intrinsic, Up: Table of Intrinsic Functions Alarm Intrinsic ............... CALL Alarm(SECONDS, HANDLER, STATUS) SECONDS: `INTEGER'; scalar; INTENT(IN). HANDLER: Signal handler (`INTEGER FUNCTION' or `SUBROUTINE') or dummy/global `INTEGER(KIND=1)' scalar. STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Causes external subroutine HANDLER to be executed after a delay of SECONDS seconds by using `alarm(1)' to set up a signal and `signal(2)' to catch it. If STATUS is supplied, it will be returned with the number of seconds remaining until any previously scheduled alarm was due to be delivered, or zero if there was no previously scheduled alarm. *Note Signal Intrinsic (subroutine)::.  File: g77.info, Node: All Intrinsic, Next: Allocated Intrinsic, Prev: Alarm Intrinsic, Up: Table of Intrinsic Functions All Intrinsic ............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL All' to use this name for an external procedure.  File: g77.info, Node: Allocated Intrinsic, Next: ALog Intrinsic, Prev: All Intrinsic, Up: Table of Intrinsic Functions Allocated Intrinsic ................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Allocated' to use this name for an external procedure.  File: g77.info, Node: ALog Intrinsic, Next: ALog10 Intrinsic, Prev: Allocated Intrinsic, Up: Table of Intrinsic Functions ALog Intrinsic .............. ALog(X) ALog: `REAL(KIND=1)' function. X: `REAL(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `LOG()' that is specific to one type for X. *Note Log Intrinsic::.  File: g77.info, Node: ALog10 Intrinsic, Next: AMax0 Intrinsic, Prev: ALog Intrinsic, Up: Table of Intrinsic Functions ALog10 Intrinsic ................ ALog10(X) ALog10: `REAL(KIND=1)' function. X: `REAL(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `LOG10()' that is specific to one type for X. *Note Log10 Intrinsic::.  File: g77.info, Node: AMax0 Intrinsic, Next: AMax1 Intrinsic, Prev: ALog10 Intrinsic, Up: Table of Intrinsic Functions AMax0 Intrinsic ............... AMax0(A-1, A-2, ..., A-n) AMax0: `REAL(KIND=1)' function. A: `INTEGER(KIND=1)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MAX()' that is specific to one type for A and a different return type. *Note Max Intrinsic::.  File: g77.info, Node: AMax1 Intrinsic, Next: AMin0 Intrinsic, Prev: AMax0 Intrinsic, Up: Table of Intrinsic Functions AMax1 Intrinsic ............... AMax1(A-1, A-2, ..., A-n) AMax1: `REAL(KIND=1)' function. A: `REAL(KIND=1)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MAX()' that is specific to one type for A. *Note Max Intrinsic::.  File: g77.info, Node: AMin0 Intrinsic, Next: AMin1 Intrinsic, Prev: AMax1 Intrinsic, Up: Table of Intrinsic Functions AMin0 Intrinsic ............... AMin0(A-1, A-2, ..., A-n) AMin0: `REAL(KIND=1)' function. A: `INTEGER(KIND=1)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MIN()' that is specific to one type for A and a different return type. *Note Min Intrinsic::.  File: g77.info, Node: AMin1 Intrinsic, Next: AMod Intrinsic, Prev: AMin0 Intrinsic, Up: Table of Intrinsic Functions AMin1 Intrinsic ............... AMin1(A-1, A-2, ..., A-n) AMin1: `REAL(KIND=1)' function. A: `REAL(KIND=1)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MIN()' that is specific to one type for A. *Note Min Intrinsic::.  File: g77.info, Node: AMod Intrinsic, Next: And Intrinsic, Prev: AMin1 Intrinsic, Up: Table of Intrinsic Functions AMod Intrinsic .............. AMod(A, P) AMod: `REAL(KIND=1)' function. A: `REAL(KIND=1)'; scalar; INTENT(IN). P: `REAL(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MOD()' that is specific to one type for A. *Note Mod Intrinsic::.  File: g77.info, Node: And Intrinsic, Next: ANInt Intrinsic, Prev: AMod Intrinsic, Up: Table of Intrinsic Functions And Intrinsic ............. And(I, J) And: `INTEGER' or `LOGICAL' function, the exact type being the result of cross-promoting the types of all the arguments. I: `INTEGER' or `LOGICAL'; scalar; INTENT(IN). J: `INTEGER' or `LOGICAL'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Returns value resulting from boolean AND of pair of bits in each of I and J.  File: g77.info, Node: ANInt Intrinsic, Next: Any Intrinsic, Prev: And Intrinsic, Up: Table of Intrinsic Functions ANInt Intrinsic ............... ANInt(A) ANInt: `REAL' function, the `KIND=' value of the type being that of argument A. A: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns A with the fractional portion of its magnitude eliminated by rounding to the nearest whole number and with its sign preserved. A fractional portion exactly equal to `.5' is rounded to the whole number that is larger in magnitude. (Also called "Fortran round".) *Note AInt Intrinsic::, for how to truncate to whole number. *Note NInt Intrinsic::, for how to round and then convert number to `INTEGER'.  File: g77.info, Node: Any Intrinsic, Next: ASin Intrinsic, Prev: ANInt Intrinsic, Up: Table of Intrinsic Functions Any Intrinsic ............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Any' to use this name for an external procedure.  File: g77.info, Node: ASin Intrinsic, Next: Associated Intrinsic, Prev: Any Intrinsic, Up: Table of Intrinsic Functions ASin Intrinsic .............. ASin(X) ASin: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the arc-sine (inverse sine) of X in radians. *Note Sin Intrinsic::, for the inverse of this function.  File: g77.info, Node: Associated Intrinsic, Next: ATan Intrinsic, Prev: ASin Intrinsic, Up: Table of Intrinsic Functions Associated Intrinsic .................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Associated' to use this name for an external procedure.  File: g77.info, Node: ATan Intrinsic, Next: ATan2 Intrinsic, Prev: Associated Intrinsic, Up: Table of Intrinsic Functions ATan Intrinsic .............. ATan(X) ATan: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the arc-tangent (inverse tangent) of X in radians. *Note Tan Intrinsic::, for the inverse of this function.  File: g77.info, Node: ATan2 Intrinsic, Next: BesJ0 Intrinsic, Prev: ATan Intrinsic, Up: Table of Intrinsic Functions ATan2 Intrinsic ............... ATan2(Y, X) ATan2: `REAL' function, the exact type being the result of cross-promoting the types of all the arguments. Y: `REAL'; scalar; INTENT(IN). X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the arc-tangent (inverse tangent) of the complex number (Y, X) in radians. *Note Tan Intrinsic::, for the inverse of this function.  File: g77.info, Node: BesJ0 Intrinsic, Next: BesJ1 Intrinsic, Prev: ATan2 Intrinsic, Up: Table of Intrinsic Functions BesJ0 Intrinsic ............... BesJ0(X) BesJ0: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Calculates the Bessel function of the first kind of order 0 of X. See `bessel(3m)', on whose implementation the function depends.  File: g77.info, Node: BesJ1 Intrinsic, Next: BesJN Intrinsic, Prev: BesJ0 Intrinsic, Up: Table of Intrinsic Functions BesJ1 Intrinsic ............... BesJ1(X) BesJ1: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Calculates the Bessel function of the first kind of order 1 of X. See `bessel(3m)', on whose implementation the function depends.  File: g77.info, Node: BesJN Intrinsic, Next: BesY0 Intrinsic, Prev: BesJ1 Intrinsic, Up: Table of Intrinsic Functions BesJN Intrinsic ............... BesJN(N, X) BesJN: `REAL' function, the `KIND=' value of the type being that of argument X. N: `INTEGER' not wider than the default kind; scalar; INTENT(IN). X: `REAL'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Calculates the Bessel function of the first kind of order N of X. See `bessel(3m)', on whose implementation the function depends.  File: g77.info, Node: BesY0 Intrinsic, Next: BesY1 Intrinsic, Prev: BesJN Intrinsic, Up: Table of Intrinsic Functions BesY0 Intrinsic ............... BesY0(X) BesY0: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Calculates the Bessel function of the second kind of order 0 of X. See `bessel(3m)', on whose implementation the function depends.  File: g77.info, Node: BesY1 Intrinsic, Next: BesYN Intrinsic, Prev: BesY0 Intrinsic, Up: Table of Intrinsic Functions BesY1 Intrinsic ............... BesY1(X) BesY1: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Calculates the Bessel function of the second kind of order 1 of X. See `bessel(3m)', on whose implementation the function depends.  File: g77.info, Node: BesYN Intrinsic, Next: Bit_Size Intrinsic, Prev: BesY1 Intrinsic, Up: Table of Intrinsic Functions BesYN Intrinsic ............... BesYN(N, X) BesYN: `REAL' function, the `KIND=' value of the type being that of argument X. N: `INTEGER' not wider than the default kind; scalar; INTENT(IN). X: `REAL'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Calculates the Bessel function of the second kind of order N of X. See `bessel(3m)', on whose implementation the function depends.  File: g77.info, Node: Bit_Size Intrinsic, Next: BTest Intrinsic, Prev: BesYN Intrinsic, Up: Table of Intrinsic Functions Bit_Size Intrinsic .................. Bit_Size(I) Bit_Size: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar. Intrinsic groups: `f90'. Description: Returns the number of bits (integer precision plus sign bit) represented by the type for I. *Note BTest Intrinsic::, for how to test the value of a bit in a variable or array. *Note IBSet Intrinsic::, for how to set a bit in a variable to 1. *Note IBClr Intrinsic::, for how to set a bit in a variable to 0.  File: g77.info, Node: BTest Intrinsic, Next: CAbs Intrinsic, Prev: Bit_Size Intrinsic, Up: Table of Intrinsic Functions BTest Intrinsic ............... BTest(I, POS) BTest: `LOGICAL(KIND=1)' function. I: `INTEGER'; scalar; INTENT(IN). POS: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Returns `.TRUE.' if bit POS in I is 1, `.FALSE.' otherwise. (Bit 0 is the low-order (rightmost) bit, adding the value 2**0, or 1, to the number if set to 1; bit 1 is the next-higher-order bit, adding 2**1, or 2; bit 2 adds 2**2, or 4; and so on.) *Note Bit_Size Intrinsic::, for how to obtain the number of bits in a type. The leftmost bit of I is `BIT_SIZE(I-1)'.  File: g77.info, Node: CAbs Intrinsic, Next: CCos Intrinsic, Prev: BTest Intrinsic, Up: Table of Intrinsic Functions CAbs Intrinsic .............. CAbs(A) CAbs: `REAL(KIND=1)' function. A: `COMPLEX(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `ABS()' that is specific to one type for A. *Note Abs Intrinsic::.  File: g77.info, Node: CCos Intrinsic, Next: Ceiling Intrinsic, Prev: CAbs Intrinsic, Up: Table of Intrinsic Functions CCos Intrinsic .............. CCos(X) CCos: `COMPLEX(KIND=1)' function. X: `COMPLEX(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `COS()' that is specific to one type for X. *Note Cos Intrinsic::.  File: g77.info, Node: Ceiling Intrinsic, Next: CExp Intrinsic, Prev: CCos Intrinsic, Up: Table of Intrinsic Functions Ceiling Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Ceiling' to use this name for an external procedure.  File: g77.info, Node: CExp Intrinsic, Next: Char Intrinsic, Prev: Ceiling Intrinsic, Up: Table of Intrinsic Functions CExp Intrinsic .............. CExp(X) CExp: `COMPLEX(KIND=1)' function. X: `COMPLEX(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `EXP()' that is specific to one type for X. *Note Exp Intrinsic::.  File: g77.info, Node: Char Intrinsic, Next: ChDir Intrinsic (subroutine), Prev: CExp Intrinsic, Up: Table of Intrinsic Functions Char Intrinsic .............. Char(I) Char: `CHARACTER*1' function. I: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the character corresponding to the code specified by I, using the system's native character set. Because the system's native character set is used, the correspondence between character and their codes is not necessarily the same between GNU Fortran implementations. Note that no intrinsic exists to convert a numerical value to a printable character string. For example, there is no intrinsic that, given an `INTEGER' or `REAL' argument with the value `154', returns the `CHARACTER' result `'154''. Instead, you can use internal-file I/O to do this kind of conversion. For example: INTEGER VALUE CHARACTER*10 STRING VALUE = 154 WRITE (STRING, '(I10)'), VALUE PRINT *, STRING END The above program, when run, prints: 154 *Note IChar Intrinsic::, for the inverse of the `CHAR' function. *Note AChar Intrinsic::, for the function corresponding to the ASCII character set.  File: g77.info, Node: ChDir Intrinsic (subroutine), Next: ChMod Intrinsic (subroutine), Prev: Char Intrinsic, Up: Table of Intrinsic Functions ChDir Intrinsic (subroutine) ............................ CALL ChDir(DIR, STATUS) DIR: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Sets the current working directory to be DIR. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code otherwise upon return. See `chdir(3)'. _Caution:_ Using this routine during I/O to a unit connected with a non-absolute file name can cause subsequent I/O on such a unit to fail because the I/O library might reopen files by name. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note ChDir Intrinsic (function)::.  File: g77.info, Node: ChMod Intrinsic (subroutine), Next: CLog Intrinsic, Prev: ChDir Intrinsic (subroutine), Up: Table of Intrinsic Functions ChMod Intrinsic (subroutine) ............................ CALL ChMod(NAME, MODE, STATUS) NAME: `CHARACTER'; scalar; INTENT(IN). MODE: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Changes the access mode of file NAME according to the specification MODE, which is given in the format of `chmod(1)'. A null character (`CHAR(0)') marks the end of the name in NAME--otherwise, trailing blanks in NAME are ignored. Currently, NAME must not contain the single quote character. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return. Note that this currently works by actually invoking `/bin/chmod' (or the `chmod' found when the library was configured) and so might fail in some circumstances and will, anyway, be slow. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note ChMod Intrinsic (function)::.  File: g77.info, Node: CLog Intrinsic, Next: Cmplx Intrinsic, Prev: ChMod Intrinsic (subroutine), Up: Table of Intrinsic Functions CLog Intrinsic .............. CLog(X) CLog: `COMPLEX(KIND=1)' function. X: `COMPLEX(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `LOG()' that is specific to one type for X. *Note Log Intrinsic::.  File: g77.info, Node: Cmplx Intrinsic, Next: Complex Intrinsic, Prev: CLog Intrinsic, Up: Table of Intrinsic Functions Cmplx Intrinsic ............... Cmplx(X, Y) Cmplx: `COMPLEX(KIND=1)' function. X: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Y: `INTEGER' or `REAL'; OPTIONAL (must be omitted if X is `COMPLEX'); scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: If X is not type `COMPLEX', constructs a value of type `COMPLEX(KIND=1)' from the real and imaginary values specified by X and Y, respectively. If Y is omitted, `0.' is assumed. If X is type `COMPLEX', converts it to type `COMPLEX(KIND=1)'. *Note Complex Intrinsic::, for information on easily constructing a `COMPLEX' value of arbitrary precision from `REAL' arguments.  File: g77.info, Node: Complex Intrinsic, Next: Conjg Intrinsic, Prev: Cmplx Intrinsic, Up: Table of Intrinsic Functions Complex Intrinsic ................. Complex(REAL, IMAG) Complex: `COMPLEX' function, the exact type being the result of cross-promoting the types of all the arguments. REAL: `INTEGER' or `REAL'; scalar; INTENT(IN). IMAG: `INTEGER' or `REAL'; scalar; INTENT(IN). Intrinsic groups: `gnu'. Description: Returns a `COMPLEX' value that has `Real' and `Imag' as its real and imaginary parts, respectively. If REAL and IMAG are the same type, and that type is not `INTEGER', no data conversion is performed, and the type of the resulting value has the same kind value as the types of REAL and IMAG. If REAL and IMAG are not the same type, the usual type-promotion rules are applied to both, converting either or both to the appropriate `REAL' type. The type of the resulting value has the same kind value as the type to which both REAL and IMAG were converted, in this case. If REAL and IMAG are both `INTEGER', they are both converted to `REAL(KIND=1)', and the result of the `COMPLEX()' invocation is type `COMPLEX(KIND=1)'. _Note:_ The way to do this in standard Fortran 90 is too hairy to describe here, but it is important to note that `CMPLX(D1,D2)' returns a `COMPLEX(KIND=1)' result even if `D1' and `D2' are type `REAL(KIND=2)'. Hence the availability of `COMPLEX()' in GNU Fortran.  File: g77.info, Node: Conjg Intrinsic, Next: Cos Intrinsic, Prev: Complex Intrinsic, Up: Table of Intrinsic Functions Conjg Intrinsic ............... Conjg(Z) Conjg: `COMPLEX' function, the `KIND=' value of the type being that of argument Z. Z: `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the complex conjugate: COMPLEX(REALPART(Z), -IMAGPART(Z))  File: g77.info, Node: Cos Intrinsic, Next: CosH Intrinsic, Prev: Conjg Intrinsic, Up: Table of Intrinsic Functions Cos Intrinsic ............. Cos(X) Cos: `REAL' or `COMPLEX' function, the exact type being that of argument X. X: `REAL' or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the cosine of X, an angle measured in radians. *Note ACos Intrinsic::, for the inverse of this function.  File: g77.info, Node: CosH Intrinsic, Next: Count Intrinsic, Prev: Cos Intrinsic, Up: Table of Intrinsic Functions CosH Intrinsic .............. CosH(X) CosH: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the hyperbolic cosine of X.  File: g77.info, Node: Count Intrinsic, Next: CPU_Time Intrinsic, Prev: CosH Intrinsic, Up: Table of Intrinsic Functions Count Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Count' to use this name for an external procedure.  File: g77.info, Node: CPU_Time Intrinsic, Next: CShift Intrinsic, Prev: Count Intrinsic, Up: Table of Intrinsic Functions CPU_Time Intrinsic .................. CALL CPU_Time(SECONDS) SECONDS: `REAL'; scalar; INTENT(OUT). Intrinsic groups: `f90'. Description: Returns in SECONDS the current value of the system time. This implementation of the Fortran 95 intrinsic is just an alias for `second' *Note Second Intrinsic (subroutine)::. On some systems, the underlying timings are represented using types with sufficiently small limits that overflows (wraparounds) are possible, such as 32-bit types. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program.  File: g77.info, Node: CShift Intrinsic, Next: CSin Intrinsic, Prev: CPU_Time Intrinsic, Up: Table of Intrinsic Functions CShift Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL CShift' to use this name for an external procedure.  File: g77.info, Node: CSin Intrinsic, Next: CSqRt Intrinsic, Prev: CShift Intrinsic, Up: Table of Intrinsic Functions CSin Intrinsic .............. CSin(X) CSin: `COMPLEX(KIND=1)' function. X: `COMPLEX(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `SIN()' that is specific to one type for X. *Note Sin Intrinsic::.  File: g77.info, Node: CSqRt Intrinsic, Next: CTime Intrinsic (subroutine), Prev: CSin Intrinsic, Up: Table of Intrinsic Functions CSqRt Intrinsic ............... CSqRt(X) CSqRt: `COMPLEX(KIND=1)' function. X: `COMPLEX(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `SQRT()' that is specific to one type for X. *Note SqRt Intrinsic::.  File: g77.info, Node: CTime Intrinsic (subroutine), Next: CTime Intrinsic (function), Prev: CSqRt Intrinsic, Up: Table of Intrinsic Functions CTime Intrinsic (subroutine) ............................ CALL CTime(STIME, RESULT) STIME: `INTEGER'; scalar; INTENT(IN). RESULT: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Converts STIME, a system time value, such as returned by `TIME8()', to a string of the form `Sat Aug 19 18:13:14 1995', and returns that string in RESULT. *Note Time8 Intrinsic::. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine. For information on other intrinsics with the same name: *Note CTime Intrinsic (function)::.  File: g77.info, Node: CTime Intrinsic (function), Next: DAbs Intrinsic, Prev: CTime Intrinsic (subroutine), Up: Table of Intrinsic Functions CTime Intrinsic (function) .......................... CTime(STIME) CTime: `CHARACTER*(*)' function. STIME: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Converts STIME, a system time value, such as returned by `TIME8()', to a string of the form `Sat Aug 19 18:13:14 1995', and returns that string as the function value. *Note Time8 Intrinsic::. For information on other intrinsics with the same name: *Note CTime Intrinsic (subroutine)::.  File: g77.info, Node: DAbs Intrinsic, Next: DACos Intrinsic, Prev: CTime Intrinsic (function), Up: Table of Intrinsic Functions DAbs Intrinsic .............. DAbs(A) DAbs: `REAL(KIND=2)' function. A: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `ABS()' that is specific to one type for A. *Note Abs Intrinsic::.  File: g77.info, Node: DACos Intrinsic, Next: DASin Intrinsic, Prev: DAbs Intrinsic, Up: Table of Intrinsic Functions DACos Intrinsic ............... DACos(X) DACos: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `ACOS()' that is specific to one type for X. *Note ACos Intrinsic::.  File: g77.info, Node: DASin Intrinsic, Next: DATan Intrinsic, Prev: DACos Intrinsic, Up: Table of Intrinsic Functions DASin Intrinsic ............... DASin(X) DASin: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `ASIN()' that is specific to one type for X. *Note ASin Intrinsic::.  File: g77.info, Node: DATan Intrinsic, Next: DATan2 Intrinsic, Prev: DASin Intrinsic, Up: Table of Intrinsic Functions DATan Intrinsic ............... DATan(X) DATan: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `ATAN()' that is specific to one type for X. *Note ATan Intrinsic::.  File: g77.info, Node: DATan2 Intrinsic, Next: Date_and_Time Intrinsic, Prev: DATan Intrinsic, Up: Table of Intrinsic Functions DATan2 Intrinsic ................ DATan2(Y, X) DATan2: `REAL(KIND=2)' function. Y: `REAL(KIND=2)'; scalar; INTENT(IN). X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `ATAN2()' that is specific to one type for Y and X. *Note ATan2 Intrinsic::.  File: g77.info, Node: Date_and_Time Intrinsic, Next: DbesJ0 Intrinsic, Prev: DATan2 Intrinsic, Up: Table of Intrinsic Functions Date_and_Time Intrinsic ....................... CALL Date_and_Time(DATE, TIME, ZONE, VALUES) DATE: `CHARACTER'; scalar; INTENT(OUT). TIME: `CHARACTER'; OPTIONAL; scalar; INTENT(OUT). ZONE: `CHARACTER'; OPTIONAL; scalar; INTENT(OUT). VALUES: `INTEGER(KIND=1)'; OPTIONAL; DIMENSION(8); INTENT(OUT). Intrinsic groups: `f90'. Description: Returns: DATE The date in the form CCYYMMDD: century, year, month and day; TIME The time in the form `HHMMSS.SS': hours, minutes, seconds and milliseconds; ZONE The difference between local time and UTC (GMT) in the form SHHMM: sign, hours and minutes, e.g. `-0500' (winter in New York); VALUES The year, month of the year, day of the month, time difference in minutes from UTC, hour of the day, minutes of the hour, seconds of the minute, and milliseconds of the second in successive values of the array. Programs making use of this intrinsic might not be Year 10000 (Y10K) compliant. For example, the date might appear, to such programs, to wrap around (change from a larger value to a smaller one) as of the Year 10000. On systems where a millisecond timer isn't available, the millisecond value is returned as zero.  File: g77.info, Node: DbesJ0 Intrinsic, Next: DbesJ1 Intrinsic, Prev: Date_and_Time Intrinsic, Up: Table of Intrinsic Functions DbesJ0 Intrinsic ................ DbesJ0(X) DbesJ0: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `BESJ0()' that is specific to one type for X. *Note BesJ0 Intrinsic::.  File: g77.info, Node: DbesJ1 Intrinsic, Next: DbesJN Intrinsic, Prev: DbesJ0 Intrinsic, Up: Table of Intrinsic Functions DbesJ1 Intrinsic ................ DbesJ1(X) DbesJ1: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `BESJ1()' that is specific to one type for X. *Note BesJ1 Intrinsic::.  File: g77.info, Node: DbesJN Intrinsic, Next: DbesY0 Intrinsic, Prev: DbesJ1 Intrinsic, Up: Table of Intrinsic Functions DbesJN Intrinsic ................ DbesJN(N, X) DbesJN: `REAL(KIND=2)' function. N: `INTEGER' not wider than the default kind; scalar; INTENT(IN). X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `BESJN()' that is specific to one type for X. *Note BesJN Intrinsic::.  File: g77.info, Node: DbesY0 Intrinsic, Next: DbesY1 Intrinsic, Prev: DbesJN Intrinsic, Up: Table of Intrinsic Functions DbesY0 Intrinsic ................ DbesY0(X) DbesY0: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `BESY0()' that is specific to one type for X. *Note BesY0 Intrinsic::.  File: g77.info, Node: DbesY1 Intrinsic, Next: DbesYN Intrinsic, Prev: DbesY0 Intrinsic, Up: Table of Intrinsic Functions DbesY1 Intrinsic ................ DbesY1(X) DbesY1: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `BESY1()' that is specific to one type for X. *Note BesY1 Intrinsic::.  File: g77.info, Node: DbesYN Intrinsic, Next: Dble Intrinsic, Prev: DbesY1 Intrinsic, Up: Table of Intrinsic Functions DbesYN Intrinsic ................ DbesYN(N, X) DbesYN: `REAL(KIND=2)' function. N: `INTEGER' not wider than the default kind; scalar; INTENT(IN). X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `BESYN()' that is specific to one type for X. *Note BesYN Intrinsic::.  File: g77.info, Node: Dble Intrinsic, Next: DCos Intrinsic, Prev: DbesYN Intrinsic, Up: Table of Intrinsic Functions Dble Intrinsic .............. Dble(A) Dble: `REAL(KIND=2)' function. A: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns A converted to double precision (`REAL(KIND=2)'). If A is `COMPLEX', the real part of A is used for the conversion and the imaginary part disregarded. *Note Sngl Intrinsic::, for the function that converts to single precision. *Note Int Intrinsic::, for the function that converts to `INTEGER'. *Note Complex Intrinsic::, for the function that converts to `COMPLEX'.  File: g77.info, Node: DCos Intrinsic, Next: DCosH Intrinsic, Prev: Dble Intrinsic, Up: Table of Intrinsic Functions DCos Intrinsic .............. DCos(X) DCos: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `COS()' that is specific to one type for X. *Note Cos Intrinsic::.  File: g77.info, Node: DCosH Intrinsic, Next: DDiM Intrinsic, Prev: DCos Intrinsic, Up: Table of Intrinsic Functions DCosH Intrinsic ............... DCosH(X) DCosH: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `COSH()' that is specific to one type for X. *Note CosH Intrinsic::.  File: g77.info, Node: DDiM Intrinsic, Next: DErF Intrinsic, Prev: DCosH Intrinsic, Up: Table of Intrinsic Functions DDiM Intrinsic .............. DDiM(X, Y) DDiM: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Y: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `DIM()' that is specific to one type for X and Y. *Note DiM Intrinsic::.  File: g77.info, Node: DErF Intrinsic, Next: DErFC Intrinsic, Prev: DDiM Intrinsic, Up: Table of Intrinsic Functions DErF Intrinsic .............. DErF(X) DErF: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `ERF()' that is specific to one type for X. *Note ErF Intrinsic::.  File: g77.info, Node: DErFC Intrinsic, Next: DExp Intrinsic, Prev: DErF Intrinsic, Up: Table of Intrinsic Functions DErFC Intrinsic ............... DErFC(X) DErFC: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `ERFC()' that is specific to one type for X. *Note ErFC Intrinsic::.  File: g77.info, Node: DExp Intrinsic, Next: Digits Intrinsic, Prev: DErFC Intrinsic, Up: Table of Intrinsic Functions DExp Intrinsic .............. DExp(X) DExp: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `EXP()' that is specific to one type for X. *Note Exp Intrinsic::.  File: g77.info, Node: Digits Intrinsic, Next: DiM Intrinsic, Prev: DExp Intrinsic, Up: Table of Intrinsic Functions Digits Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Digits' to use this name for an external procedure.  File: g77.info, Node: DiM Intrinsic, Next: DInt Intrinsic, Prev: Digits Intrinsic, Up: Table of Intrinsic Functions DiM Intrinsic ............. DiM(X, Y) DiM: `INTEGER' or `REAL' function, the exact type being the result of cross-promoting the types of all the arguments. X: `INTEGER' or `REAL'; scalar; INTENT(IN). Y: `INTEGER' or `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns `X-Y' if X is greater than Y; otherwise returns zero.  File: g77.info, Node: DInt Intrinsic, Next: DLog Intrinsic, Prev: DiM Intrinsic, Up: Table of Intrinsic Functions DInt Intrinsic .............. DInt(A) DInt: `REAL(KIND=2)' function. A: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `AINT()' that is specific to one type for A. *Note AInt Intrinsic::.  File: g77.info, Node: DLog Intrinsic, Next: DLog10 Intrinsic, Prev: DInt Intrinsic, Up: Table of Intrinsic Functions DLog Intrinsic .............. DLog(X) DLog: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `LOG()' that is specific to one type for X. *Note Log Intrinsic::.  File: g77.info, Node: DLog10 Intrinsic, Next: DMax1 Intrinsic, Prev: DLog Intrinsic, Up: Table of Intrinsic Functions DLog10 Intrinsic ................ DLog10(X) DLog10: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `LOG10()' that is specific to one type for X. *Note Log10 Intrinsic::.  File: g77.info, Node: DMax1 Intrinsic, Next: DMin1 Intrinsic, Prev: DLog10 Intrinsic, Up: Table of Intrinsic Functions DMax1 Intrinsic ............... DMax1(A-1, A-2, ..., A-n) DMax1: `REAL(KIND=2)' function. A: `REAL(KIND=2)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MAX()' that is specific to one type for A. *Note Max Intrinsic::.  File: g77.info, Node: DMin1 Intrinsic, Next: DMod Intrinsic, Prev: DMax1 Intrinsic, Up: Table of Intrinsic Functions DMin1 Intrinsic ............... DMin1(A-1, A-2, ..., A-n) DMin1: `REAL(KIND=2)' function. A: `REAL(KIND=2)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MIN()' that is specific to one type for A. *Note Min Intrinsic::.  File: g77.info, Node: DMod Intrinsic, Next: DNInt Intrinsic, Prev: DMin1 Intrinsic, Up: Table of Intrinsic Functions DMod Intrinsic .............. DMod(A, P) DMod: `REAL(KIND=2)' function. A: `REAL(KIND=2)'; scalar; INTENT(IN). P: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MOD()' that is specific to one type for A. *Note Mod Intrinsic::.  File: g77.info, Node: DNInt Intrinsic, Next: Dot_Product Intrinsic, Prev: DMod Intrinsic, Up: Table of Intrinsic Functions DNInt Intrinsic ............... DNInt(A) DNInt: `REAL(KIND=2)' function. A: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `ANINT()' that is specific to one type for A. *Note ANInt Intrinsic::.  File: g77.info, Node: Dot_Product Intrinsic, Next: DProd Intrinsic, Prev: DNInt Intrinsic, Up: Table of Intrinsic Functions Dot_Product Intrinsic ..................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Dot_Product' to use this name for an external procedure.  File: g77.info, Node: DProd Intrinsic, Next: DSign Intrinsic, Prev: Dot_Product Intrinsic, Up: Table of Intrinsic Functions DProd Intrinsic ............... DProd(X, Y) DProd: `REAL(KIND=2)' function. X: `REAL(KIND=1)'; scalar; INTENT(IN). Y: `REAL(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns `DBLE(X)*DBLE(Y)'.  File: g77.info, Node: DSign Intrinsic, Next: DSin Intrinsic, Prev: DProd Intrinsic, Up: Table of Intrinsic Functions DSign Intrinsic ............... DSign(A, B) DSign: `REAL(KIND=2)' function. A: `REAL(KIND=2)'; scalar; INTENT(IN). B: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `SIGN()' that is specific to one type for A and B. *Note Sign Intrinsic::.  File: g77.info, Node: DSin Intrinsic, Next: DSinH Intrinsic, Prev: DSign Intrinsic, Up: Table of Intrinsic Functions DSin Intrinsic .............. DSin(X) DSin: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `SIN()' that is specific to one type for X. *Note Sin Intrinsic::.  File: g77.info, Node: DSinH Intrinsic, Next: DSqRt Intrinsic, Prev: DSin Intrinsic, Up: Table of Intrinsic Functions DSinH Intrinsic ............... DSinH(X) DSinH: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `SINH()' that is specific to one type for X. *Note SinH Intrinsic::.  File: g77.info, Node: DSqRt Intrinsic, Next: DTan Intrinsic, Prev: DSinH Intrinsic, Up: Table of Intrinsic Functions DSqRt Intrinsic ............... DSqRt(X) DSqRt: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `SQRT()' that is specific to one type for X. *Note SqRt Intrinsic::.  File: g77.info, Node: DTan Intrinsic, Next: DTanH Intrinsic, Prev: DSqRt Intrinsic, Up: Table of Intrinsic Functions DTan Intrinsic .............. DTan(X) DTan: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `TAN()' that is specific to one type for X. *Note Tan Intrinsic::.  File: g77.info, Node: DTanH Intrinsic, Next: DTime Intrinsic (subroutine), Prev: DTan Intrinsic, Up: Table of Intrinsic Functions DTanH Intrinsic ............... DTanH(X) DTanH: `REAL(KIND=2)' function. X: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `TANH()' that is specific to one type for X. *Note TanH Intrinsic::.  File: g77.info, Node: DTime Intrinsic (subroutine), Next: EOShift Intrinsic, Prev: DTanH Intrinsic, Up: Table of Intrinsic Functions DTime Intrinsic (subroutine) ............................ CALL DTime(TARRAY, RESULT) TARRAY: `REAL(KIND=1)'; DIMENSION(2); INTENT(OUT). RESULT: `REAL(KIND=1)'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Initially, return the number of seconds of runtime since the start of the process's execution in RESULT, and the user and system components of this in `TARRAY(1)' and `TARRAY(2)' respectively. The value of RESULT is equal to `TARRAY(1) + TARRAY(2)'. Subsequent invocations of `DTIME()' set values based on accumulations since the previous invocation. On some systems, the underlying timings are represented using types with sufficiently small limits that overflows (wraparounds) are possible, such as 32-bit types. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine. For information on other intrinsics with the same name: *Note DTime Intrinsic (function)::.  File: g77.info, Node: EOShift Intrinsic, Next: Epsilon Intrinsic, Prev: DTime Intrinsic (subroutine), Up: Table of Intrinsic Functions EOShift Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL EOShift' to use this name for an external procedure.  File: g77.info, Node: Epsilon Intrinsic, Next: ErF Intrinsic, Prev: EOShift Intrinsic, Up: Table of Intrinsic Functions Epsilon Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Epsilon' to use this name for an external procedure.  File: g77.info, Node: ErF Intrinsic, Next: ErFC Intrinsic, Prev: Epsilon Intrinsic, Up: Table of Intrinsic Functions ErF Intrinsic ............. ErF(X) ErF: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns the error function of X. See `erf(3m)', which provides the implementation.  File: g77.info, Node: ErFC Intrinsic, Next: ETime Intrinsic (subroutine), Prev: ErF Intrinsic, Up: Table of Intrinsic Functions ErFC Intrinsic .............. ErFC(X) ErFC: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns the complementary error function of X: `ERFC(R) = 1 - ERF(R)' (except that the result might be more accurate than explicitly evaluating that formulae would give). See `erfc(3m)', which provides the implementation.  File: g77.info, Node: ETime Intrinsic (subroutine), Next: ETime Intrinsic (function), Prev: ErFC Intrinsic, Up: Table of Intrinsic Functions ETime Intrinsic (subroutine) ............................ CALL ETime(TARRAY, RESULT) TARRAY: `REAL(KIND=1)'; DIMENSION(2); INTENT(OUT). RESULT: `REAL(KIND=1)'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Return the number of seconds of runtime since the start of the process's execution in RESULT, and the user and system components of this in `TARRAY(1)' and `TARRAY(2)' respectively. The value of RESULT is equal to `TARRAY(1) + TARRAY(2)'. On some systems, the underlying timings are represented using types with sufficiently small limits that overflows (wraparounds) are possible, such as 32-bit types. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine. For information on other intrinsics with the same name: *Note ETime Intrinsic (function)::.  File: g77.info, Node: ETime Intrinsic (function), Next: Exit Intrinsic, Prev: ETime Intrinsic (subroutine), Up: Table of Intrinsic Functions ETime Intrinsic (function) .......................... ETime(TARRAY) ETime: `REAL(KIND=1)' function. TARRAY: `REAL(KIND=1)'; DIMENSION(2); INTENT(OUT). Intrinsic groups: `unix'. Description: Return the number of seconds of runtime since the start of the process's execution as the function value, and the user and system components of this in `TARRAY(1)' and `TARRAY(2)' respectively. The functions' value is equal to `TARRAY(1) + TARRAY(2)'. On some systems, the underlying timings are represented using types with sufficiently small limits that overflows (wraparounds) are possible, such as 32-bit types. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. For information on other intrinsics with the same name: *Note ETime Intrinsic (subroutine)::.  File: g77.info, Node: Exit Intrinsic, Next: Exp Intrinsic, Prev: ETime Intrinsic (function), Up: Table of Intrinsic Functions Exit Intrinsic .............. CALL Exit(STATUS) STATUS: `INTEGER' not wider than the default kind; OPTIONAL; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Exit the program with status STATUS after closing open Fortran I/O units and otherwise behaving as `exit(2)'. If STATUS is omitted the canonical `success' value will be returned to the system.  File: g77.info, Node: Exp Intrinsic, Next: Exponent Intrinsic, Prev: Exit Intrinsic, Up: Table of Intrinsic Functions Exp Intrinsic ............. Exp(X) Exp: `REAL' or `COMPLEX' function, the exact type being that of argument X. X: `REAL' or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns `E**X', where E is approximately 2.7182818. *Note Log Intrinsic::, for the inverse of this function.  File: g77.info, Node: Exponent Intrinsic, Next: FDate Intrinsic (subroutine), Prev: Exp Intrinsic, Up: Table of Intrinsic Functions Exponent Intrinsic .................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Exponent' to use this name for an external procedure.  File: g77.info, Node: FDate Intrinsic (subroutine), Next: FDate Intrinsic (function), Prev: Exponent Intrinsic, Up: Table of Intrinsic Functions FDate Intrinsic (subroutine) ............................ CALL FDate(DATE) DATE: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Returns the current date (using the same format as `CTIME()') in DATE. Equivalent to: CALL CTIME(DATE, TIME8()) Programs making use of this intrinsic might not be Year 10000 (Y10K) compliant. For example, the date might appear, to such programs, to wrap around (change from a larger value to a smaller one) as of the Year 10000. *Note CTime Intrinsic (subroutine)::. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine. For information on other intrinsics with the same name: *Note FDate Intrinsic (function)::.  File: g77.info, Node: FDate Intrinsic (function), Next: FGet Intrinsic (subroutine), Prev: FDate Intrinsic (subroutine), Up: Table of Intrinsic Functions FDate Intrinsic (function) .......................... FDate() FDate: `CHARACTER*(*)' function. Intrinsic groups: `unix'. Description: Returns the current date (using the same format as `CTIME()'). Equivalent to: CTIME(TIME8()) Programs making use of this intrinsic might not be Year 10000 (Y10K) compliant. For example, the date might appear, to such programs, to wrap around (change from a larger value to a smaller one) as of the Year 10000. *Note CTime Intrinsic (function)::. For information on other intrinsics with the same name: *Note FDate Intrinsic (subroutine)::.  File: g77.info, Node: FGet Intrinsic (subroutine), Next: FGetC Intrinsic (subroutine), Prev: FDate Intrinsic (function), Up: Table of Intrinsic Functions FGet Intrinsic (subroutine) ........................... CALL FGet(C, STATUS) C: `CHARACTER'; scalar; INTENT(OUT). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Reads a single character into C in stream mode from unit 5 (by-passing normal formatted output) using `getc(3)'. Returns in STATUS 0 on success, -1 on end-of-file, and the error code from `ferror(3)' otherwise. Stream I/O should not be mixed with normal record-oriented (formatted or unformatted) I/O on the same unit; the results are unpredictable. For information on other intrinsics with the same name: *Note FGet Intrinsic (function)::.  File: g77.info, Node: FGetC Intrinsic (subroutine), Next: Float Intrinsic, Prev: FGet Intrinsic (subroutine), Up: Table of Intrinsic Functions FGetC Intrinsic (subroutine) ............................ CALL FGetC(UNIT, C, STATUS) UNIT: `INTEGER'; scalar; INTENT(IN). C: `CHARACTER'; scalar; INTENT(OUT). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Reads a single character into C in stream mode from unit UNIT (by-passing normal formatted output) using `getc(3)'. Returns in STATUS 0 on success, -1 on end-of-file, and the error code from `ferror(3)' otherwise. Stream I/O should not be mixed with normal record-oriented (formatted or unformatted) I/O on the same unit; the results are unpredictable. For information on other intrinsics with the same name: *Note FGetC Intrinsic (function)::.  File: g77.info, Node: Float Intrinsic, Next: Floor Intrinsic, Prev: FGetC Intrinsic (subroutine), Up: Table of Intrinsic Functions Float Intrinsic ............... Float(A) Float: `REAL(KIND=1)' function. A: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `REAL()' that is specific to one type for A. *Note Real Intrinsic::.  File: g77.info, Node: Floor Intrinsic, Next: Flush Intrinsic, Prev: Float Intrinsic, Up: Table of Intrinsic Functions Floor Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Floor' to use this name for an external procedure.  File: g77.info, Node: Flush Intrinsic, Next: FNum Intrinsic, Prev: Floor Intrinsic, Up: Table of Intrinsic Functions Flush Intrinsic ............... CALL Flush(UNIT) UNIT: `INTEGER'; OPTIONAL; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Flushes Fortran unit(s) currently open for output. Without the optional argument, all such units are flushed, otherwise just the unit specified by UNIT. Some non-GNU implementations of Fortran provide this intrinsic as a library procedure that might or might not support the (optional) UNIT argument.  File: g77.info, Node: FNum Intrinsic, Next: FPut Intrinsic (subroutine), Prev: Flush Intrinsic, Up: Table of Intrinsic Functions FNum Intrinsic .............. FNum(UNIT) FNum: `INTEGER(KIND=1)' function. UNIT: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns the Unix file descriptor number corresponding to the open Fortran I/O unit UNIT. This could be passed to an interface to C I/O routines.  File: g77.info, Node: FPut Intrinsic (subroutine), Next: FPutC Intrinsic (subroutine), Prev: FNum Intrinsic, Up: Table of Intrinsic Functions FPut Intrinsic (subroutine) ........................... CALL FPut(C, STATUS) C: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Writes the single character C in stream mode to unit 6 (by-passing normal formatted output) using `putc(3)'. Returns in STATUS 0 on success, the error code from `ferror(3)' otherwise. Stream I/O should not be mixed with normal record-oriented (formatted or unformatted) I/O on the same unit; the results are unpredictable. For information on other intrinsics with the same name: *Note FPut Intrinsic (function)::.  File: g77.info, Node: FPutC Intrinsic (subroutine), Next: Fraction Intrinsic, Prev: FPut Intrinsic (subroutine), Up: Table of Intrinsic Functions FPutC Intrinsic (subroutine) ............................ CALL FPutC(UNIT, C, STATUS) UNIT: `INTEGER'; scalar; INTENT(IN). C: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Writes the single character UNIT in stream mode to unit 6 (by-passing normal formatted output) using `putc(3)'. Returns in C 0 on success, the error code from `ferror(3)' otherwise. Stream I/O should not be mixed with normal record-oriented (formatted or unformatted) I/O on the same unit; the results are unpredictable. For information on other intrinsics with the same name: *Note FPutC Intrinsic (function)::.  File: g77.info, Node: Fraction Intrinsic, Next: FSeek Intrinsic, Prev: FPutC Intrinsic (subroutine), Up: Table of Intrinsic Functions Fraction Intrinsic .................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Fraction' to use this name for an external procedure.  File: g77.info, Node: FSeek Intrinsic, Next: FStat Intrinsic (subroutine), Prev: Fraction Intrinsic, Up: Table of Intrinsic Functions FSeek Intrinsic ............... CALL FSeek(UNIT, OFFSET, WHENCE, ERRLAB) UNIT: `INTEGER'; scalar; INTENT(IN). OFFSET: `INTEGER'; scalar; INTENT(IN). WHENCE: `INTEGER'; scalar; INTENT(IN). ERRLAB: `*LABEL', where LABEL is the label of an executable statement; OPTIONAL. Intrinsic groups: `unix'. Description: Attempts to move Fortran unit UNIT to the specified OFFSET: absolute offset if WHENCE=0; relative to the current offset if WHENCE=1; relative to the end of the file if WHENCE=2. It branches to label ERRLAB if UNIT is not open or if the call otherwise fails.  File: g77.info, Node: FStat Intrinsic (subroutine), Next: FStat Intrinsic (function), Prev: FSeek Intrinsic, Up: Table of Intrinsic Functions FStat Intrinsic (subroutine) ............................ CALL FStat(UNIT, SARRAY, STATUS) UNIT: `INTEGER'; scalar; INTENT(IN). SARRAY: `INTEGER(KIND=1)'; DIMENSION(13); INTENT(OUT). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Obtains data about the file open on Fortran I/O unit UNIT and places them in the array SARRAY. The values in this array are extracted from the `stat' structure as returned by `fstat(2)' q.v., as follows: 1. Device ID 2. Inode number 3. File mode 4. Number of links 5. Owner's uid 6. Owner's gid 7. ID of device containing directory entry for file (0 if not available) 8. File size (bytes) 9. Last access time 10. Last modification time 11. Last file status change time 12. Preferred I/O block size (-1 if not available) 13. Number of blocks allocated (-1 if not available) Not all these elements are relevant on all systems. If an element is not relevant, it is returned as 0. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note FStat Intrinsic (function)::.  File: g77.info, Node: FStat Intrinsic (function), Next: FTell Intrinsic (subroutine), Prev: FStat Intrinsic (subroutine), Up: Table of Intrinsic Functions FStat Intrinsic (function) .......................... FStat(UNIT, SARRAY) FStat: `INTEGER(KIND=1)' function. UNIT: `INTEGER'; scalar; INTENT(IN). SARRAY: `INTEGER(KIND=1)'; DIMENSION(13); INTENT(OUT). Intrinsic groups: `unix'. Description: Obtains data about the file open on Fortran I/O unit UNIT and places them in the array SARRAY. The values in this array are extracted from the `stat' structure as returned by `fstat(2)' q.v., as follows: 1. Device ID 2. Inode number 3. File mode 4. Number of links 5. Owner's uid 6. Owner's gid 7. ID of device containing directory entry for file (0 if not available) 8. File size (bytes) 9. Last access time 10. Last modification time 11. Last file status change time 12. Preferred I/O block size (-1 if not available) 13. Number of blocks allocated (-1 if not available) Not all these elements are relevant on all systems. If an element is not relevant, it is returned as 0. Returns 0 on success or a nonzero error code. For information on other intrinsics with the same name: *Note FStat Intrinsic (subroutine)::.  File: g77.info, Node: FTell Intrinsic (subroutine), Next: FTell Intrinsic (function), Prev: FStat Intrinsic (function), Up: Table of Intrinsic Functions FTell Intrinsic (subroutine) ............................ CALL FTell(UNIT, OFFSET) UNIT: `INTEGER'; scalar; INTENT(IN). OFFSET: `INTEGER(KIND=1)'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Sets OFFSET to the current offset of Fortran unit UNIT (or to -1 if UNIT is not open). Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine. For information on other intrinsics with the same name: *Note FTell Intrinsic (function)::.  File: g77.info, Node: FTell Intrinsic (function), Next: GError Intrinsic, Prev: FTell Intrinsic (subroutine), Up: Table of Intrinsic Functions FTell Intrinsic (function) .......................... FTell(UNIT) FTell: `INTEGER(KIND=1)' function. UNIT: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns the current offset of Fortran unit UNIT (or -1 if UNIT is not open). For information on other intrinsics with the same name: *Note FTell Intrinsic (subroutine)::.  File: g77.info, Node: GError Intrinsic, Next: GetArg Intrinsic, Prev: FTell Intrinsic (function), Up: Table of Intrinsic Functions GError Intrinsic ................ CALL GError(MESSAGE) MESSAGE: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Returns the system error message corresponding to the last system error (C `errno').  File: g77.info, Node: GetArg Intrinsic, Next: GetCWD Intrinsic (subroutine), Prev: GError Intrinsic, Up: Table of Intrinsic Functions GetArg Intrinsic ................ CALL GetArg(POS, VALUE) POS: `INTEGER' not wider than the default kind; scalar; INTENT(IN). VALUE: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Sets VALUE to the POS-th command-line argument (or to all blanks if there are fewer than VALUE command-line arguments); `CALL GETARG(0, VALUE)' sets VALUE to the name of the program (on systems that support this feature). *Note IArgC Intrinsic::, for information on how to get the number of arguments.  File: g77.info, Node: GetCWD Intrinsic (subroutine), Next: GetCWD Intrinsic (function), Prev: GetArg Intrinsic, Up: Table of Intrinsic Functions GetCWD Intrinsic (subroutine) ............................. CALL GetCWD(NAME, STATUS) NAME: `CHARACTER'; scalar; INTENT(OUT). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Places the current working directory in NAME. If the STATUS argument is supplied, it contains 0 success or a nonzero error code upon return (`ENOSYS' if the system does not provide `getcwd(3)' or `getwd(3)'). Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note GetCWD Intrinsic (function)::.  File: g77.info, Node: GetCWD Intrinsic (function), Next: GetEnv Intrinsic, Prev: GetCWD Intrinsic (subroutine), Up: Table of Intrinsic Functions GetCWD Intrinsic (function) ........................... GetCWD(NAME) GetCWD: `INTEGER(KIND=1)' function. NAME: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Places the current working directory in NAME. Returns 0 on success, otherwise a nonzero error code (`ENOSYS' if the system does not provide `getcwd(3)' or `getwd(3)'). For information on other intrinsics with the same name: *Note GetCWD Intrinsic (subroutine)::.  File: g77.info, Node: GetEnv Intrinsic, Next: GetGId Intrinsic, Prev: GetCWD Intrinsic (function), Up: Table of Intrinsic Functions GetEnv Intrinsic ................ CALL GetEnv(NAME, VALUE) NAME: `CHARACTER'; scalar; INTENT(IN). VALUE: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Sets VALUE to the value of environment variable given by the value of NAME (`$name' in shell terms) or to blanks if `$name' has not been set. A null character (`CHAR(0)') marks the end of the name in NAME--otherwise, trailing blanks in NAME are ignored.  File: g77.info, Node: GetGId Intrinsic, Next: GetLog Intrinsic, Prev: GetEnv Intrinsic, Up: Table of Intrinsic Functions GetGId Intrinsic ................ GetGId() GetGId: `INTEGER(KIND=1)' function. Intrinsic groups: `unix'. Description: Returns the group id for the current process.  File: g77.info, Node: GetLog Intrinsic, Next: GetPId Intrinsic, Prev: GetGId Intrinsic, Up: Table of Intrinsic Functions GetLog Intrinsic ................ CALL GetLog(LOGIN) LOGIN: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Returns the login name for the process in LOGIN. _Caution:_ On some systems, the `getlogin(3)' function, which this intrinsic calls at run time, is either not implemented or returns a null pointer. In the latter case, this intrinsic returns blanks in LOGIN.  File: g77.info, Node: GetPId Intrinsic, Next: GetUId Intrinsic, Prev: GetLog Intrinsic, Up: Table of Intrinsic Functions GetPId Intrinsic ................ GetPId() GetPId: `INTEGER(KIND=1)' function. Intrinsic groups: `unix'. Description: Returns the process id for the current process.  File: g77.info, Node: GetUId Intrinsic, Next: GMTime Intrinsic, Prev: GetPId Intrinsic, Up: Table of Intrinsic Functions GetUId Intrinsic ................ GetUId() GetUId: `INTEGER(KIND=1)' function. Intrinsic groups: `unix'. Description: Returns the user id for the current process.  File: g77.info, Node: GMTime Intrinsic, Next: HostNm Intrinsic (subroutine), Prev: GetUId Intrinsic, Up: Table of Intrinsic Functions GMTime Intrinsic ................ CALL GMTime(STIME, TARRAY) STIME: `INTEGER(KIND=1)'; scalar; INTENT(IN). TARRAY: `INTEGER(KIND=1)'; DIMENSION(9); INTENT(OUT). Intrinsic groups: `unix'. Description: Given a system time value STIME, fills TARRAY with values extracted from it appropriate to the GMT time zone using `gmtime(3)'. The array elements are as follows: 1. Seconds after the minute, range 0-59 or 0-61 to allow for leap seconds 2. Minutes after the hour, range 0-59 3. Hours past midnight, range 0-23 4. Day of month, range 0-31 5. Number of months since January, range 0-12 6. Years since 1900 7. Number of days since Sunday, range 0-6 8. Days since January 1 9. Daylight savings indicator: positive if daylight savings is in effect, zero if not, and negative if the information isn't available.  File: g77.info, Node: HostNm Intrinsic (subroutine), Next: HostNm Intrinsic (function), Prev: GMTime Intrinsic, Up: Table of Intrinsic Functions HostNm Intrinsic (subroutine) ............................. CALL HostNm(NAME, STATUS) NAME: `CHARACTER'; scalar; INTENT(OUT). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Fills NAME with the system's host name returned by `gethostname(2)'. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return (`ENOSYS' if the system does not provide `gethostname(2)'). Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. On some systems (specifically SCO) it might be necessary to link the "socket" library if you call this routine. Typically this means adding `-lg2c -lsocket -lm' to the `g77' command line when linking the program. For information on other intrinsics with the same name: *Note HostNm Intrinsic (function)::.  File: g77.info, Node: HostNm Intrinsic (function), Next: Huge Intrinsic, Prev: HostNm Intrinsic (subroutine), Up: Table of Intrinsic Functions HostNm Intrinsic (function) ........................... HostNm(NAME) HostNm: `INTEGER(KIND=1)' function. NAME: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Fills NAME with the system's host name returned by `gethostname(2)', returning 0 on success or a nonzero error code (`ENOSYS' if the system does not provide `gethostname(2)'). On some systems (specifically SCO) it might be necessary to link the "socket" library if you call this routine. Typically this means adding `-lg2c -lsocket -lm' to the `g77' command line when linking the program. For information on other intrinsics with the same name: *Note HostNm Intrinsic (subroutine)::.  File: g77.info, Node: Huge Intrinsic, Next: IAbs Intrinsic, Prev: HostNm Intrinsic (function), Up: Table of Intrinsic Functions Huge Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Huge' to use this name for an external procedure.  File: g77.info, Node: IAbs Intrinsic, Next: IAChar Intrinsic, Prev: Huge Intrinsic, Up: Table of Intrinsic Functions IAbs Intrinsic .............. IAbs(A) IAbs: `INTEGER(KIND=1)' function. A: `INTEGER(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `ABS()' that is specific to one type for A. *Note Abs Intrinsic::.  File: g77.info, Node: IAChar Intrinsic, Next: IAnd Intrinsic, Prev: IAbs Intrinsic, Up: Table of Intrinsic Functions IAChar Intrinsic ................ IAChar(C) IAChar: `INTEGER(KIND=1)' function. C: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `f2c', `f90'. Description: Returns the code for the ASCII character in the first character position of C. *Note AChar Intrinsic::, for the inverse of this function. *Note IChar Intrinsic::, for the function corresponding to the system's native character set.  File: g77.info, Node: IAnd Intrinsic, Next: IArgC Intrinsic, Prev: IAChar Intrinsic, Up: Table of Intrinsic Functions IAnd Intrinsic .............. IAnd(I, J) IAnd: `INTEGER' function, the exact type being the result of cross-promoting the types of all the arguments. I: `INTEGER'; scalar; INTENT(IN). J: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Returns value resulting from boolean AND of pair of bits in each of I and J.  File: g77.info, Node: IArgC Intrinsic, Next: IBClr Intrinsic, Prev: IAnd Intrinsic, Up: Table of Intrinsic Functions IArgC Intrinsic ............... IArgC() IArgC: `INTEGER(KIND=1)' function. Intrinsic groups: `unix'. Description: Returns the number of command-line arguments. This count does not include the specification of the program name itself.  File: g77.info, Node: IBClr Intrinsic, Next: IBits Intrinsic, Prev: IArgC Intrinsic, Up: Table of Intrinsic Functions IBClr Intrinsic ............... IBClr(I, POS) IBClr: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar; INTENT(IN). POS: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Returns the value of I with bit POS cleared (set to zero). *Note BTest Intrinsic::, for information on bit positions.  File: g77.info, Node: IBits Intrinsic, Next: IBSet Intrinsic, Prev: IBClr Intrinsic, Up: Table of Intrinsic Functions IBits Intrinsic ............... IBits(I, POS, LEN) IBits: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar; INTENT(IN). POS: `INTEGER'; scalar; INTENT(IN). LEN: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Extracts a subfield of length LEN from I, starting from bit position POS and extending left for LEN bits. The result is right-justified and the remaining bits are zeroed. The value of `POS+LEN' must be less than or equal to the value `BIT_SIZE(I)'. *Note Bit_Size Intrinsic::.  File: g77.info, Node: IBSet Intrinsic, Next: IChar Intrinsic, Prev: IBits Intrinsic, Up: Table of Intrinsic Functions IBSet Intrinsic ............... IBSet(I, POS) IBSet: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar; INTENT(IN). POS: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Returns the value of I with bit POS set (to one). *Note BTest Intrinsic::, for information on bit positions.  File: g77.info, Node: IChar Intrinsic, Next: IDate Intrinsic (UNIX), Prev: IBSet Intrinsic, Up: Table of Intrinsic Functions IChar Intrinsic ............... IChar(C) IChar: `INTEGER(KIND=1)' function. C: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the code for the character in the first character position of C. Because the system's native character set is used, the correspondence between character and their codes is not necessarily the same between GNU Fortran implementations. Note that no intrinsic exists to convert a printable character string to a numerical value. For example, there is no intrinsic that, given the `CHARACTER' value `'154'', returns an `INTEGER' or `REAL' value with the value `154'. Instead, you can use internal-file I/O to do this kind of conversion. For example: INTEGER VALUE CHARACTER*10 STRING STRING = '154' READ (STRING, '(I10)'), VALUE PRINT *, VALUE END The above program, when run, prints: 154 *Note Char Intrinsic::, for the inverse of the `ICHAR' function. *Note IAChar Intrinsic::, for the function corresponding to the ASCII character set.  File: g77.info, Node: IDate Intrinsic (UNIX), Next: IDiM Intrinsic, Prev: IChar Intrinsic, Up: Table of Intrinsic Functions IDate Intrinsic (UNIX) ...................... CALL IDate(TARRAY) TARRAY: `INTEGER(KIND=1)'; DIMENSION(3); INTENT(OUT). Intrinsic groups: `unix'. Description: Fills TARRAY with the numerical values at the current local time. The day (in the range 1-31), month (in the range 1-12), and year appear in elements 1, 2, and 3 of TARRAY, respectively. The year has four significant digits. Programs making use of this intrinsic might not be Year 10000 (Y10K) compliant. For example, the date might appear, to such programs, to wrap around (change from a larger value to a smaller one) as of the Year 10000. For information on other intrinsics with the same name: *Note IDate Intrinsic (VXT)::.  File: g77.info, Node: IDiM Intrinsic, Next: IDInt Intrinsic, Prev: IDate Intrinsic (UNIX), Up: Table of Intrinsic Functions IDiM Intrinsic .............. IDiM(X, Y) IDiM: `INTEGER(KIND=1)' function. X: `INTEGER(KIND=1)'; scalar; INTENT(IN). Y: `INTEGER(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `DIM()' that is specific to one type for X and Y. *Note DiM Intrinsic::.  File: g77.info, Node: IDInt Intrinsic, Next: IDNInt Intrinsic, Prev: IDiM Intrinsic, Up: Table of Intrinsic Functions IDInt Intrinsic ............... IDInt(A) IDInt: `INTEGER(KIND=1)' function. A: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `INT()' that is specific to one type for A. *Note Int Intrinsic::.  File: g77.info, Node: IDNInt Intrinsic, Next: IEOr Intrinsic, Prev: IDInt Intrinsic, Up: Table of Intrinsic Functions IDNInt Intrinsic ................ IDNInt(A) IDNInt: `INTEGER(KIND=1)' function. A: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `NINT()' that is specific to one type for A. *Note NInt Intrinsic::.  File: g77.info, Node: IEOr Intrinsic, Next: IErrNo Intrinsic, Prev: IDNInt Intrinsic, Up: Table of Intrinsic Functions IEOr Intrinsic .............. IEOr(I, J) IEOr: `INTEGER' function, the exact type being the result of cross-promoting the types of all the arguments. I: `INTEGER'; scalar; INTENT(IN). J: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Returns value resulting from boolean exclusive-OR of pair of bits in each of I and J.  File: g77.info, Node: IErrNo Intrinsic, Next: IFix Intrinsic, Prev: IEOr Intrinsic, Up: Table of Intrinsic Functions IErrNo Intrinsic ................ IErrNo() IErrNo: `INTEGER(KIND=1)' function. Intrinsic groups: `unix'. Description: Returns the last system error number (corresponding to the C `errno').  File: g77.info, Node: IFix Intrinsic, Next: Imag Intrinsic, Prev: IErrNo Intrinsic, Up: Table of Intrinsic Functions IFix Intrinsic .............. IFix(A) IFix: `INTEGER(KIND=1)' function. A: `REAL(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `INT()' that is specific to one type for A. *Note Int Intrinsic::.  File: g77.info, Node: Imag Intrinsic, Next: ImagPart Intrinsic, Prev: IFix Intrinsic, Up: Table of Intrinsic Functions Imag Intrinsic .............. Imag(Z) Imag: `REAL' function, the `KIND=' value of the type being that of argument Z. Z: `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: The imaginary part of Z is returned, without conversion. _Note:_ The way to do this in standard Fortran 90 is `AIMAG(Z)'. However, when, for example, Z is `DOUBLE COMPLEX', `AIMAG(Z)' means something different for some compilers that are not true Fortran 90 compilers but offer some extensions standardized by Fortran 90 (such as the `DOUBLE COMPLEX' type, also known as `COMPLEX(KIND=2)'). The advantage of `IMAG()' is that, while not necessarily more or less portable than `AIMAG()', it is more likely to cause a compiler that doesn't support it to produce a diagnostic than generate incorrect code. *Note REAL() and AIMAG() of Complex::, for more information.  File: g77.info, Node: ImagPart Intrinsic, Next: Index Intrinsic, Prev: Imag Intrinsic, Up: Table of Intrinsic Functions ImagPart Intrinsic .................. ImagPart(Z) ImagPart: `REAL' function, the `KIND=' value of the type being that of argument Z. Z: `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: `gnu'. Description: The imaginary part of Z is returned, without conversion. _Note:_ The way to do this in standard Fortran 90 is `AIMAG(Z)'. However, when, for example, Z is `DOUBLE COMPLEX', `AIMAG(Z)' means something different for some compilers that are not true Fortran 90 compilers but offer some extensions standardized by Fortran 90 (such as the `DOUBLE COMPLEX' type, also known as `COMPLEX(KIND=2)'). The advantage of `IMAGPART()' is that, while not necessarily more or less portable than `AIMAG()', it is more likely to cause a compiler that doesn't support it to produce a diagnostic than generate incorrect code. *Note REAL() and AIMAG() of Complex::, for more information.  File: g77.info, Node: Index Intrinsic, Next: Int Intrinsic, Prev: ImagPart Intrinsic, Up: Table of Intrinsic Functions Index Intrinsic ............... Index(STRING, SUBSTRING) Index: `INTEGER(KIND=1)' function. STRING: `CHARACTER'; scalar; INTENT(IN). SUBSTRING: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the position of the start of the first occurrence of string SUBSTRING as a substring in STRING, counting from one. If SUBSTRING doesn't occur in STRING, zero is returned.  File: g77.info, Node: Int Intrinsic, Next: Int2 Intrinsic, Prev: Index Intrinsic, Up: Table of Intrinsic Functions Int Intrinsic ............. Int(A) Int: `INTEGER(KIND=1)' function. A: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns A with the fractional portion of its magnitude truncated and its sign preserved, converted to type `INTEGER(KIND=1)'. If A is type `COMPLEX', its real part is truncated and converted, and its imaginary part is disregarded. *Note NInt Intrinsic::, for how to convert, rounded to nearest whole number. *Note AInt Intrinsic::, for how to truncate to whole number without converting.  File: g77.info, Node: Int2 Intrinsic, Next: Int8 Intrinsic, Prev: Int Intrinsic, Up: Table of Intrinsic Functions Int2 Intrinsic .............. Int2(A) Int2: `INTEGER(KIND=6)' function. A: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: `gnu'. Description: Returns A with the fractional portion of its magnitude truncated and its sign preserved, converted to type `INTEGER(KIND=6)'. If A is type `COMPLEX', its real part is truncated and converted, and its imaginary part is disregarded. *Note Int Intrinsic::. The precise meaning of this intrinsic might change in a future version of the GNU Fortran language, as more is learned about how it is used.  File: g77.info, Node: Int8 Intrinsic, Next: IOr Intrinsic, Prev: Int2 Intrinsic, Up: Table of Intrinsic Functions Int8 Intrinsic .............. Int8(A) Int8: `INTEGER(KIND=2)' function. A: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: `gnu'. Description: Returns A with the fractional portion of its magnitude truncated and its sign preserved, converted to type `INTEGER(KIND=2)'. If A is type `COMPLEX', its real part is truncated and converted, and its imaginary part is disregarded. *Note Int Intrinsic::. The precise meaning of this intrinsic might change in a future version of the GNU Fortran language, as more is learned about how it is used.  File: g77.info, Node: IOr Intrinsic, Next: IRand Intrinsic, Prev: Int8 Intrinsic, Up: Table of Intrinsic Functions IOr Intrinsic ............. IOr(I, J) IOr: `INTEGER' function, the exact type being the result of cross-promoting the types of all the arguments. I: `INTEGER'; scalar; INTENT(IN). J: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Returns value resulting from boolean OR of pair of bits in each of I and J.  File: g77.info, Node: IRand Intrinsic, Next: IsaTty Intrinsic, Prev: IOr Intrinsic, Up: Table of Intrinsic Functions IRand Intrinsic ............... IRand(FLAG) IRand: `INTEGER(KIND=1)' function. FLAG: `INTEGER'; OPTIONAL; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns a uniform quasi-random number up to a system-dependent limit. If FLAG is 0, the next number in sequence is returned; if FLAG is 1, the generator is restarted by calling the UNIX function `srand(0)'; if FLAG has any other value, it is used as a new seed with `srand()'. *Note SRand Intrinsic::. _Note:_ As typically implemented (by the routine of the same name in the C library), this random number generator is a very poor one, though the BSD and GNU libraries provide a much better implementation than the `traditional' one. On a different system you almost certainly want to use something better.  File: g77.info, Node: IsaTty Intrinsic, Next: IShft Intrinsic, Prev: IRand Intrinsic, Up: Table of Intrinsic Functions IsaTty Intrinsic ................ IsaTty(UNIT) IsaTty: `LOGICAL(KIND=1)' function. UNIT: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns `.TRUE.' if and only if the Fortran I/O unit specified by UNIT is connected to a terminal device. See `isatty(3)'.  File: g77.info, Node: IShft Intrinsic, Next: IShftC Intrinsic, Prev: IsaTty Intrinsic, Up: Table of Intrinsic Functions IShft Intrinsic ............... IShft(I, SHIFT) IShft: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar; INTENT(IN). SHIFT: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: All bits representing I are shifted SHIFT places. `SHIFT.GT.0' indicates a left shift, `SHIFT.EQ.0' indicates no shift and `SHIFT.LT.0' indicates a right shift. If the absolute value of the shift count is greater than `BIT_SIZE(I)', the result is undefined. Bits shifted out from the left end or the right end are lost. Zeros are shifted in from the opposite end. *Note IShftC Intrinsic::, for the circular-shift equivalent.  File: g77.info, Node: IShftC Intrinsic, Next: ISign Intrinsic, Prev: IShft Intrinsic, Up: Table of Intrinsic Functions IShftC Intrinsic ................ IShftC(I, SHIFT, SIZE) IShftC: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar; INTENT(IN). SHIFT: `INTEGER'; scalar; INTENT(IN). SIZE: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: The rightmost SIZE bits of the argument I are shifted circularly SHIFT places, i.e. the bits shifted out of one end are shifted into the opposite end. No bits are lost. The unshifted bits of the result are the same as the unshifted bits of I. The absolute value of the argument SHIFT must be less than or equal to SIZE. The value of SIZE must be greater than or equal to one and less than or equal to `BIT_SIZE(I)'. *Note IShft Intrinsic::, for the logical shift equivalent.  File: g77.info, Node: ISign Intrinsic, Next: ITime Intrinsic, Prev: IShftC Intrinsic, Up: Table of Intrinsic Functions ISign Intrinsic ............... ISign(A, B) ISign: `INTEGER(KIND=1)' function. A: `INTEGER(KIND=1)'; scalar; INTENT(IN). B: `INTEGER(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `SIGN()' that is specific to one type for A and B. *Note Sign Intrinsic::.  File: g77.info, Node: ITime Intrinsic, Next: Kill Intrinsic (subroutine), Prev: ISign Intrinsic, Up: Table of Intrinsic Functions ITime Intrinsic ............... CALL ITime(TARRAY) TARRAY: `INTEGER(KIND=1)'; DIMENSION(3); INTENT(OUT). Intrinsic groups: `unix'. Description: Returns the current local time hour, minutes, and seconds in elements 1, 2, and 3 of TARRAY, respectively.  File: g77.info, Node: Kill Intrinsic (subroutine), Next: Kind Intrinsic, Prev: ITime Intrinsic, Up: Table of Intrinsic Functions Kill Intrinsic (subroutine) ........................... CALL Kill(PID, SIGNAL, STATUS) PID: `INTEGER'; scalar; INTENT(IN). SIGNAL: `INTEGER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Sends the signal specified by SIGNAL to the process PID. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return. See `kill(2)'. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note Kill Intrinsic (function)::.  File: g77.info, Node: Kind Intrinsic, Next: LBound Intrinsic, Prev: Kill Intrinsic (subroutine), Up: Table of Intrinsic Functions Kind Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Kind' to use this name for an external procedure.  File: g77.info, Node: LBound Intrinsic, Next: Len Intrinsic, Prev: Kind Intrinsic, Up: Table of Intrinsic Functions LBound Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL LBound' to use this name for an external procedure.  File: g77.info, Node: Len Intrinsic, Next: Len_Trim Intrinsic, Prev: LBound Intrinsic, Up: Table of Intrinsic Functions Len Intrinsic ............. Len(STRING) Len: `INTEGER(KIND=1)' function. STRING: `CHARACTER'; scalar. Intrinsic groups: (standard FORTRAN 77). Description: Returns the length of STRING. If STRING is an array, the length of an element of STRING is returned. Note that STRING need not be defined when this intrinsic is invoked, since only the length, not the content, of STRING is needed. *Note Bit_Size Intrinsic::, for the function that determines the size of its argument in bits.  File: g77.info, Node: Len_Trim Intrinsic, Next: LGe Intrinsic, Prev: Len Intrinsic, Up: Table of Intrinsic Functions Len_Trim Intrinsic .................. Len_Trim(STRING) Len_Trim: `INTEGER(KIND=1)' function. STRING: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `f90'. Description: Returns the index of the last non-blank character in STRING. `LNBLNK' and `LEN_TRIM' are equivalent.  File: g77.info, Node: LGe Intrinsic, Next: LGt Intrinsic, Prev: Len_Trim Intrinsic, Up: Table of Intrinsic Functions LGe Intrinsic ............. LGe(STRING_A, STRING_B) LGe: `LOGICAL(KIND=1)' function. STRING_A: `CHARACTER'; scalar; INTENT(IN). STRING_B: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns `.TRUE.' if `STRING_A.GE.STRING_B', `.FALSE.' otherwise. STRING_A and STRING_B are interpreted as containing ASCII character codes. If either value contains a character not in the ASCII character set, the result is processor dependent. If the STRING_A and STRING_B are not the same length, the shorter is compared as if spaces were appended to it to form a value that has the same length as the longer. The lexical comparison intrinsics `LGe', `LGt', `LLe', and `LLt' differ from the corresponding intrinsic operators `.GE.', `.GT.', `.LE.', `.LT.'. Because the ASCII collating sequence is assumed, the following expressions always return `.TRUE.': LGE ('0', ' ') LGE ('A', '0') LGE ('a', 'A') The following related expressions do _not_ always return `.TRUE.', as they are not necessarily evaluated assuming the arguments use ASCII encoding: '0' .GE. ' ' 'A' .GE. '0' 'a' .GE. 'A' The same difference exists between `LGt' and `.GT.'; between `LLe' and `.LE.'; and between `LLt' and `.LT.'.  File: g77.info, Node: LGt Intrinsic, Next: Link Intrinsic (subroutine), Prev: LGe Intrinsic, Up: Table of Intrinsic Functions LGt Intrinsic ............. LGt(STRING_A, STRING_B) LGt: `LOGICAL(KIND=1)' function. STRING_A: `CHARACTER'; scalar; INTENT(IN). STRING_B: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns `.TRUE.' if `STRING_A.GT.STRING_B', `.FALSE.' otherwise. STRING_A and STRING_B are interpreted as containing ASCII character codes. If either value contains a character not in the ASCII character set, the result is processor dependent. If the STRING_A and STRING_B are not the same length, the shorter is compared as if spaces were appended to it to form a value that has the same length as the longer. *Note LGe Intrinsic::, for information on the distinction between the `LGT' intrinsic and the `.GT.' operator.  File: g77.info, Node: Link Intrinsic (subroutine), Next: LLe Intrinsic, Prev: LGt Intrinsic, Up: Table of Intrinsic Functions Link Intrinsic (subroutine) ........................... CALL Link(PATH1, PATH2, STATUS) PATH1: `CHARACTER'; scalar; INTENT(IN). PATH2: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Makes a (hard) link from file PATH1 to PATH2. A null character (`CHAR(0)') marks the end of the names in PATH1 and PATH2--otherwise, trailing blanks in PATH1 and PATH2 are ignored. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return. See `link(2)'. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note Link Intrinsic (function)::.  File: g77.info, Node: LLe Intrinsic, Next: LLt Intrinsic, Prev: Link Intrinsic (subroutine), Up: Table of Intrinsic Functions LLe Intrinsic ............. LLe(STRING_A, STRING_B) LLe: `LOGICAL(KIND=1)' function. STRING_A: `CHARACTER'; scalar; INTENT(IN). STRING_B: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns `.TRUE.' if `STRING_A.LE.STRING_B', `.FALSE.' otherwise. STRING_A and STRING_B are interpreted as containing ASCII character codes. If either value contains a character not in the ASCII character set, the result is processor dependent. If the STRING_A and STRING_B are not the same length, the shorter is compared as if spaces were appended to it to form a value that has the same length as the longer. *Note LGe Intrinsic::, for information on the distinction between the `LLE' intrinsic and the `.LE.' operator.  File: g77.info, Node: LLt Intrinsic, Next: LnBlnk Intrinsic, Prev: LLe Intrinsic, Up: Table of Intrinsic Functions LLt Intrinsic ............. LLt(STRING_A, STRING_B) LLt: `LOGICAL(KIND=1)' function. STRING_A: `CHARACTER'; scalar; INTENT(IN). STRING_B: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns `.TRUE.' if `STRING_A.LT.STRING_B', `.FALSE.' otherwise. STRING_A and STRING_B are interpreted as containing ASCII character codes. If either value contains a character not in the ASCII character set, the result is processor dependent. If the STRING_A and STRING_B are not the same length, the shorter is compared as if spaces were appended to it to form a value that has the same length as the longer. *Note LGe Intrinsic::, for information on the distinction between the `LLT' intrinsic and the `.LT.' operator.  File: g77.info, Node: LnBlnk Intrinsic, Next: Loc Intrinsic, Prev: LLt Intrinsic, Up: Table of Intrinsic Functions LnBlnk Intrinsic ................ LnBlnk(STRING) LnBlnk: `INTEGER(KIND=1)' function. STRING: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns the index of the last non-blank character in STRING. `LNBLNK' and `LEN_TRIM' are equivalent.  File: g77.info, Node: Loc Intrinsic, Next: Log Intrinsic, Prev: LnBlnk Intrinsic, Up: Table of Intrinsic Functions Loc Intrinsic ............. Loc(ENTITY) Loc: `INTEGER(KIND=7)' function. ENTITY: Any type; cannot be a constant or expression. Intrinsic groups: `unix'. Description: The `LOC()' intrinsic works the same way as the `%LOC()' construct. *Note The `%LOC()' Construct: %LOC(), for more information.  File: g77.info, Node: Log Intrinsic, Next: Log10 Intrinsic, Prev: Loc Intrinsic, Up: Table of Intrinsic Functions Log Intrinsic ............. Log(X) Log: `REAL' or `COMPLEX' function, the exact type being that of argument X. X: `REAL' or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the natural logarithm of X, which must be greater than zero or, if type `COMPLEX', must not be zero. *Note Exp Intrinsic::, for the inverse of this function. *Note Log10 Intrinsic::, for the `common' (base-10) logarithm function.  File: g77.info, Node: Log10 Intrinsic, Next: Logical Intrinsic, Prev: Log Intrinsic, Up: Table of Intrinsic Functions Log10 Intrinsic ............... Log10(X) Log10: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the common logarithm (base 10) of X, which must be greater than zero. The inverse of this function is `10. ** LOG10(X)'. *Note Log Intrinsic::, for the natural logarithm function.  File: g77.info, Node: Logical Intrinsic, Next: Long Intrinsic, Prev: Log10 Intrinsic, Up: Table of Intrinsic Functions Logical Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Logical' to use this name for an external procedure.  File: g77.info, Node: Long Intrinsic, Next: LShift Intrinsic, Prev: Logical Intrinsic, Up: Table of Intrinsic Functions Long Intrinsic .............. Long(A) Long: `INTEGER(KIND=1)' function. A: `INTEGER(KIND=6)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Archaic form of `INT()' that is specific to one type for A. *Note Int Intrinsic::. The precise meaning of this intrinsic might change in a future version of the GNU Fortran language, as more is learned about how it is used.  File: g77.info, Node: LShift Intrinsic, Next: LStat Intrinsic (subroutine), Prev: Long Intrinsic, Up: Table of Intrinsic Functions LShift Intrinsic ................ LShift(I, SHIFT) LShift: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar; INTENT(IN). SHIFT: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Returns I shifted to the left SHIFT bits. Although similar to the expression `I*(2**SHIFT)', there are important differences. For example, the sign of the result is not necessarily the same as the sign of I. Currently this intrinsic is defined assuming the underlying representation of I is as a two's-complement integer. It is unclear at this point whether that definition will apply when a different representation is involved. *Note LShift Intrinsic::, for the inverse of this function. *Note IShft Intrinsic::, for information on a more widely available left-shifting intrinsic that is also more precisely defined.  File: g77.info, Node: LStat Intrinsic (subroutine), Next: LStat Intrinsic (function), Prev: LShift Intrinsic, Up: Table of Intrinsic Functions LStat Intrinsic (subroutine) ............................ CALL LStat(FILE, SARRAY, STATUS) FILE: `CHARACTER'; scalar; INTENT(IN). SARRAY: `INTEGER(KIND=1)'; DIMENSION(13); INTENT(OUT). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Obtains data about the given file FILE and places them in the array SARRAY. A null character (`CHAR(0)') marks the end of the name in FILE--otherwise, trailing blanks in FILE are ignored. If FILE is a symbolic link it returns data on the link itself, so the routine is available only on systems that support symbolic links. The values in this array are extracted from the `stat' structure as returned by `fstat(2)' q.v., as follows: 1. Device ID 2. Inode number 3. File mode 4. Number of links 5. Owner's uid 6. Owner's gid 7. ID of device containing directory entry for file (0 if not available) 8. File size (bytes) 9. Last access time 10. Last modification time 11. Last file status change time 12. Preferred I/O block size (-1 if not available) 13. Number of blocks allocated (-1 if not available) Not all these elements are relevant on all systems. If an element is not relevant, it is returned as 0. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return (`ENOSYS' if the system does not provide `lstat(2)'). Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note LStat Intrinsic (function)::.  File: g77.info, Node: LStat Intrinsic (function), Next: LTime Intrinsic, Prev: LStat Intrinsic (subroutine), Up: Table of Intrinsic Functions LStat Intrinsic (function) .......................... LStat(FILE, SARRAY) LStat: `INTEGER(KIND=1)' function. FILE: `CHARACTER'; scalar; INTENT(IN). SARRAY: `INTEGER(KIND=1)'; DIMENSION(13); INTENT(OUT). Intrinsic groups: `unix'. Description: Obtains data about the given file FILE and places them in the array SARRAY. A null character (`CHAR(0)') marks the end of the name in FILE--otherwise, trailing blanks in FILE are ignored. If FILE is a symbolic link it returns data on the link itself, so the routine is available only on systems that support symbolic links. The values in this array are extracted from the `stat' structure as returned by `fstat(2)' q.v., as follows: 1. Device ID 2. Inode number 3. File mode 4. Number of links 5. Owner's uid 6. Owner's gid 7. ID of device containing directory entry for file (0 if not available) 8. File size (bytes) 9. Last access time 10. Last modification time 11. Last file status change time 12. Preferred I/O block size (-1 if not available) 13. Number of blocks allocated (-1 if not available) Not all these elements are relevant on all systems. If an element is not relevant, it is returned as 0. Returns 0 on success or a nonzero error code (`ENOSYS' if the system does not provide `lstat(2)'). For information on other intrinsics with the same name: *Note LStat Intrinsic (subroutine)::.  File: g77.info, Node: LTime Intrinsic, Next: MatMul Intrinsic, Prev: LStat Intrinsic (function), Up: Table of Intrinsic Functions LTime Intrinsic ............... CALL LTime(STIME, TARRAY) STIME: `INTEGER(KIND=1)'; scalar; INTENT(IN). TARRAY: `INTEGER(KIND=1)'; DIMENSION(9); INTENT(OUT). Intrinsic groups: `unix'. Description: Given a system time value STIME, fills TARRAY with values extracted from it appropriate to the GMT time zone using `localtime(3)'. The array elements are as follows: 1. Seconds after the minute, range 0-59 or 0-61 to allow for leap seconds 2. Minutes after the hour, range 0-59 3. Hours past midnight, range 0-23 4. Day of month, range 0-31 5. Number of months since January, range 0-12 6. Years since 1900 7. Number of days since Sunday, range 0-6 8. Days since January 1 9. Daylight savings indicator: positive if daylight savings is in effect, zero if not, and negative if the information isn't available.  File: g77.info, Node: MatMul Intrinsic, Next: Max Intrinsic, Prev: LTime Intrinsic, Up: Table of Intrinsic Functions MatMul Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL MatMul' to use this name for an external procedure.  File: g77.info, Node: Max Intrinsic, Next: Max0 Intrinsic, Prev: MatMul Intrinsic, Up: Table of Intrinsic Functions Max Intrinsic ............. Max(A-1, A-2, ..., A-n) Max: `INTEGER' or `REAL' function, the exact type being the result of cross-promoting the types of all the arguments. A: `INTEGER' or `REAL'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the argument with the largest value. *Note Min Intrinsic::, for the opposite function.  File: g77.info, Node: Max0 Intrinsic, Next: Max1 Intrinsic, Prev: Max Intrinsic, Up: Table of Intrinsic Functions Max0 Intrinsic .............. Max0(A-1, A-2, ..., A-n) Max0: `INTEGER(KIND=1)' function. A: `INTEGER(KIND=1)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MAX()' that is specific to one type for A. *Note Max Intrinsic::.  File: g77.info, Node: Max1 Intrinsic, Next: MaxExponent Intrinsic, Prev: Max0 Intrinsic, Up: Table of Intrinsic Functions Max1 Intrinsic .............. Max1(A-1, A-2, ..., A-n) Max1: `INTEGER(KIND=1)' function. A: `REAL(KIND=1)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MAX()' that is specific to one type for A and a different return type. *Note Max Intrinsic::.  File: g77.info, Node: MaxExponent Intrinsic, Next: MaxLoc Intrinsic, Prev: Max1 Intrinsic, Up: Table of Intrinsic Functions MaxExponent Intrinsic ..................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL MaxExponent' to use this name for an external procedure.  File: g77.info, Node: MaxLoc Intrinsic, Next: MaxVal Intrinsic, Prev: MaxExponent Intrinsic, Up: Table of Intrinsic Functions MaxLoc Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL MaxLoc' to use this name for an external procedure.  File: g77.info, Node: MaxVal Intrinsic, Next: MClock Intrinsic, Prev: MaxLoc Intrinsic, Up: Table of Intrinsic Functions MaxVal Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL MaxVal' to use this name for an external procedure.  File: g77.info, Node: MClock Intrinsic, Next: MClock8 Intrinsic, Prev: MaxVal Intrinsic, Up: Table of Intrinsic Functions MClock Intrinsic ................ MClock() MClock: `INTEGER(KIND=1)' function. Intrinsic groups: `unix'. Description: Returns the number of clock ticks since the start of the process. Supported on systems with `clock(3)' (q.v.). This intrinsic is not fully portable, such as to systems with 32-bit `INTEGER' types but supporting times wider than 32 bits. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. *Note MClock8 Intrinsic::, for information on a similar intrinsic that might be portable to more GNU Fortran implementations, though to fewer Fortran compilers. If the system does not support `clock(3)', -1 is returned.  File: g77.info, Node: MClock8 Intrinsic, Next: Merge Intrinsic, Prev: MClock Intrinsic, Up: Table of Intrinsic Functions MClock8 Intrinsic ................. MClock8() MClock8: `INTEGER(KIND=2)' function. Intrinsic groups: `unix'. Description: Returns the number of clock ticks since the start of the process. Supported on systems with `clock(3)' (q.v.). _Warning:_ this intrinsic does not increase the range of the timing values over that returned by `clock(3)'. On a system with a 32-bit `clock(3)', `MCLOCK8' will return a 32-bit value, even though converted to an `INTEGER(KIND=2)' value. That means overflows of the 32-bit value can still occur. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. No Fortran implementations other than GNU Fortran are known to support this intrinsic at the time of this writing. *Note MClock Intrinsic::, for information on a similar intrinsic that might be portable to more Fortran compilers, though to fewer GNU Fortran implementations. If the system does not support `clock(3)', -1 is returned.  File: g77.info, Node: Merge Intrinsic, Next: Min Intrinsic, Prev: MClock8 Intrinsic, Up: Table of Intrinsic Functions Merge Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Merge' to use this name for an external procedure.  File: g77.info, Node: Min Intrinsic, Next: Min0 Intrinsic, Prev: Merge Intrinsic, Up: Table of Intrinsic Functions Min Intrinsic ............. Min(A-1, A-2, ..., A-n) Min: `INTEGER' or `REAL' function, the exact type being the result of cross-promoting the types of all the arguments. A: `INTEGER' or `REAL'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the argument with the smallest value. *Note Max Intrinsic::, for the opposite function.  File: g77.info, Node: Min0 Intrinsic, Next: Min1 Intrinsic, Prev: Min Intrinsic, Up: Table of Intrinsic Functions Min0 Intrinsic .............. Min0(A-1, A-2, ..., A-n) Min0: `INTEGER(KIND=1)' function. A: `INTEGER(KIND=1)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MIN()' that is specific to one type for A. *Note Min Intrinsic::.  File: g77.info, Node: Min1 Intrinsic, Next: MinExponent Intrinsic, Prev: Min0 Intrinsic, Up: Table of Intrinsic Functions Min1 Intrinsic .............. Min1(A-1, A-2, ..., A-n) Min1: `INTEGER(KIND=1)' function. A: `REAL(KIND=1)'; at least two such arguments must be provided; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `MIN()' that is specific to one type for A and a different return type. *Note Min Intrinsic::.  File: g77.info, Node: MinExponent Intrinsic, Next: MinLoc Intrinsic, Prev: Min1 Intrinsic, Up: Table of Intrinsic Functions MinExponent Intrinsic ..................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL MinExponent' to use this name for an external procedure.  File: g77.info, Node: MinLoc Intrinsic, Next: MinVal Intrinsic, Prev: MinExponent Intrinsic, Up: Table of Intrinsic Functions MinLoc Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL MinLoc' to use this name for an external procedure.  File: g77.info, Node: MinVal Intrinsic, Next: Mod Intrinsic, Prev: MinLoc Intrinsic, Up: Table of Intrinsic Functions MinVal Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL MinVal' to use this name for an external procedure.  File: g77.info, Node: Mod Intrinsic, Next: Modulo Intrinsic, Prev: MinVal Intrinsic, Up: Table of Intrinsic Functions Mod Intrinsic ............. Mod(A, P) Mod: `INTEGER' or `REAL' function, the exact type being the result of cross-promoting the types of all the arguments. A: `INTEGER' or `REAL'; scalar; INTENT(IN). P: `INTEGER' or `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns remainder calculated as: A - (INT(A / P) * P) P must not be zero.  File: g77.info, Node: Modulo Intrinsic, Next: MvBits Intrinsic, Prev: Mod Intrinsic, Up: Table of Intrinsic Functions Modulo Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Modulo' to use this name for an external procedure.  File: g77.info, Node: MvBits Intrinsic, Next: Nearest Intrinsic, Prev: Modulo Intrinsic, Up: Table of Intrinsic Functions MvBits Intrinsic ................ CALL MvBits(FROM, FROMPOS, LEN, TO, TOPOS) FROM: `INTEGER'; scalar; INTENT(IN). FROMPOS: `INTEGER'; scalar; INTENT(IN). LEN: `INTEGER'; scalar; INTENT(IN). TO: `INTEGER' with same `KIND=' value as for FROM; scalar; INTENT(INOUT). TOPOS: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Moves LEN bits from positions FROMPOS through `FROMPOS+LEN-1' of FROM to positions TOPOS through `FROMPOS+LEN-1' of TO. The portion of argument TO not affected by the movement of bits is unchanged. Arguments FROM and TO are permitted to be the same numeric storage unit. The values of `FROMPOS+LEN' and `TOPOS+LEN' must be less than or equal to `BIT_SIZE(FROM)'.  File: g77.info, Node: Nearest Intrinsic, Next: NInt Intrinsic, Prev: MvBits Intrinsic, Up: Table of Intrinsic Functions Nearest Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Nearest' to use this name for an external procedure.  File: g77.info, Node: NInt Intrinsic, Next: Not Intrinsic, Prev: Nearest Intrinsic, Up: Table of Intrinsic Functions NInt Intrinsic .............. NInt(A) NInt: `INTEGER(KIND=1)' function. A: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns A with the fractional portion of its magnitude eliminated by rounding to the nearest whole number and with its sign preserved, converted to type `INTEGER(KIND=1)'. If A is type `COMPLEX', its real part is rounded and converted. A fractional portion exactly equal to `.5' is rounded to the whole number that is larger in magnitude. (Also called "Fortran round".) *Note Int Intrinsic::, for how to convert, truncate to whole number. *Note ANInt Intrinsic::, for how to round to nearest whole number without converting.  File: g77.info, Node: Not Intrinsic, Next: Or Intrinsic, Prev: NInt Intrinsic, Up: Table of Intrinsic Functions Not Intrinsic ............. Not(I) Not: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `mil', `f90', `vxt'. Description: Returns value resulting from boolean NOT of each bit in I.  File: g77.info, Node: Or Intrinsic, Next: Pack Intrinsic, Prev: Not Intrinsic, Up: Table of Intrinsic Functions Or Intrinsic ............ Or(I, J) Or: `INTEGER' or `LOGICAL' function, the exact type being the result of cross-promoting the types of all the arguments. I: `INTEGER' or `LOGICAL'; scalar; INTENT(IN). J: `INTEGER' or `LOGICAL'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Returns value resulting from boolean OR of pair of bits in each of I and J.  File: g77.info, Node: Pack Intrinsic, Next: PError Intrinsic, Prev: Or Intrinsic, Up: Table of Intrinsic Functions Pack Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Pack' to use this name for an external procedure.  File: g77.info, Node: PError Intrinsic, Next: Precision Intrinsic, Prev: Pack Intrinsic, Up: Table of Intrinsic Functions PError Intrinsic ................ CALL PError(STRING) STRING: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Prints (on the C `stderr' stream) a newline-terminated error message corresponding to the last system error. This is prefixed by STRING, a colon and a space. See `perror(3)'.  File: g77.info, Node: Precision Intrinsic, Next: Present Intrinsic, Prev: PError Intrinsic, Up: Table of Intrinsic Functions Precision Intrinsic ................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Precision' to use this name for an external procedure.  File: g77.info, Node: Present Intrinsic, Next: Product Intrinsic, Prev: Precision Intrinsic, Up: Table of Intrinsic Functions Present Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Present' to use this name for an external procedure.  File: g77.info, Node: Product Intrinsic, Next: Radix Intrinsic, Prev: Present Intrinsic, Up: Table of Intrinsic Functions Product Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Product' to use this name for an external procedure.  File: g77.info, Node: Radix Intrinsic, Next: Rand Intrinsic, Prev: Product Intrinsic, Up: Table of Intrinsic Functions Radix Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Radix' to use this name for an external procedure.  File: g77.info, Node: Rand Intrinsic, Next: Random_Number Intrinsic, Prev: Radix Intrinsic, Up: Table of Intrinsic Functions Rand Intrinsic .............. Rand(FLAG) Rand: `REAL(KIND=1)' function. FLAG: `INTEGER'; OPTIONAL; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns a uniform quasi-random number between 0 and 1. If FLAG is 0, the next number in sequence is returned; if FLAG is 1, the generator is restarted by calling `srand(0)'; if FLAG has any other value, it is used as a new seed with `srand'. *Note SRand Intrinsic::. _Note:_ As typically implemented (by the routine of the same name in the C library), this random number generator is a very poor one, though the BSD and GNU libraries provide a much better implementation than the `traditional' one. On a different system you almost certainly want to use something better.  File: g77.info, Node: Random_Number Intrinsic, Next: Random_Seed Intrinsic, Prev: Rand Intrinsic, Up: Table of Intrinsic Functions Random_Number Intrinsic ....................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Random_Number' to use this name for an external procedure.  File: g77.info, Node: Random_Seed Intrinsic, Next: Range Intrinsic, Prev: Random_Number Intrinsic, Up: Table of Intrinsic Functions Random_Seed Intrinsic ..................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Random_Seed' to use this name for an external procedure.  File: g77.info, Node: Range Intrinsic, Next: Real Intrinsic, Prev: Random_Seed Intrinsic, Up: Table of Intrinsic Functions Range Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Range' to use this name for an external procedure.  File: g77.info, Node: Real Intrinsic, Next: RealPart Intrinsic, Prev: Range Intrinsic, Up: Table of Intrinsic Functions Real Intrinsic .............. Real(A) Real: `REAL' function. The exact type is `REAL(KIND=1)' when argument A is any type other than `COMPLEX', or when it is `COMPLEX(KIND=1)'. When A is any `COMPLEX' type other than `COMPLEX(KIND=1)', this intrinsic is valid only when used as the argument to `REAL()', as explained below. A: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Converts A to `REAL(KIND=1)'. Use of `REAL()' with a `COMPLEX' argument (other than `COMPLEX(KIND=1)') is restricted to the following case: REAL(REAL(A)) This expression converts the real part of A to `REAL(KIND=1)'. *Note RealPart Intrinsic::, for information on a GNU Fortran intrinsic that extracts the real part of an arbitrary `COMPLEX' value. *Note REAL() and AIMAG() of Complex::, for more information.  File: g77.info, Node: RealPart Intrinsic, Next: Rename Intrinsic (subroutine), Prev: Real Intrinsic, Up: Table of Intrinsic Functions RealPart Intrinsic .................. RealPart(Z) RealPart: `REAL' function, the `KIND=' value of the type being that of argument Z. Z: `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: `gnu'. Description: The real part of Z is returned, without conversion. _Note:_ The way to do this in standard Fortran 90 is `REAL(Z)'. However, when, for example, Z is `COMPLEX(KIND=2)', `REAL(Z)' means something different for some compilers that are not true Fortran 90 compilers but offer some extensions standardized by Fortran 90 (such as the `DOUBLE COMPLEX' type, also known as `COMPLEX(KIND=2)'). The advantage of `REALPART()' is that, while not necessarily more or less portable than `REAL()', it is more likely to cause a compiler that doesn't support it to produce a diagnostic than generate incorrect code. *Note REAL() and AIMAG() of Complex::, for more information.  File: g77.info, Node: Rename Intrinsic (subroutine), Next: Repeat Intrinsic, Prev: RealPart Intrinsic, Up: Table of Intrinsic Functions Rename Intrinsic (subroutine) ............................. CALL Rename(PATH1, PATH2, STATUS) PATH1: `CHARACTER'; scalar; INTENT(IN). PATH2: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Renames the file PATH1 to PATH2. A null character (`CHAR(0)') marks the end of the names in PATH1 and PATH2--otherwise, trailing blanks in PATH1 and PATH2 are ignored. See `rename(2)'. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note Rename Intrinsic (function)::.  File: g77.info, Node: Repeat Intrinsic, Next: Reshape Intrinsic, Prev: Rename Intrinsic (subroutine), Up: Table of Intrinsic Functions Repeat Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Repeat' to use this name for an external procedure.  File: g77.info, Node: Reshape Intrinsic, Next: RRSpacing Intrinsic, Prev: Repeat Intrinsic, Up: Table of Intrinsic Functions Reshape Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Reshape' to use this name for an external procedure.  File: g77.info, Node: RRSpacing Intrinsic, Next: RShift Intrinsic, Prev: Reshape Intrinsic, Up: Table of Intrinsic Functions RRSpacing Intrinsic ................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL RRSpacing' to use this name for an external procedure.  File: g77.info, Node: RShift Intrinsic, Next: Scale Intrinsic, Prev: RRSpacing Intrinsic, Up: Table of Intrinsic Functions RShift Intrinsic ................ RShift(I, SHIFT) RShift: `INTEGER' function, the `KIND=' value of the type being that of argument I. I: `INTEGER'; scalar; INTENT(IN). SHIFT: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Returns I shifted to the right SHIFT bits. Although similar to the expression `I/(2**SHIFT)', there are important differences. For example, the sign of the result is undefined. Currently this intrinsic is defined assuming the underlying representation of I is as a two's-complement integer. It is unclear at this point whether that definition will apply when a different representation is involved. *Note RShift Intrinsic::, for the inverse of this function. *Note IShft Intrinsic::, for information on a more widely available right-shifting intrinsic that is also more precisely defined.  File: g77.info, Node: Scale Intrinsic, Next: Scan Intrinsic, Prev: RShift Intrinsic, Up: Table of Intrinsic Functions Scale Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Scale' to use this name for an external procedure.  File: g77.info, Node: Scan Intrinsic, Next: Second Intrinsic (function), Prev: Scale Intrinsic, Up: Table of Intrinsic Functions Scan Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Scan' to use this name for an external procedure.  File: g77.info, Node: Second Intrinsic (function), Next: Second Intrinsic (subroutine), Prev: Scan Intrinsic, Up: Table of Intrinsic Functions Second Intrinsic (function) ........................... Second() Second: `REAL(KIND=1)' function. Intrinsic groups: `unix'. Description: Returns the process's runtime in seconds--the same value as the UNIX function `etime' returns. On some systems, the underlying timings are represented using types with sufficiently small limits that overflows (wraparounds) are possible, such as 32-bit types. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. For information on other intrinsics with the same name: *Note Second Intrinsic (subroutine)::.  File: g77.info, Node: Second Intrinsic (subroutine), Next: Selected_Int_Kind Intrinsic, Prev: Second Intrinsic (function), Up: Table of Intrinsic Functions Second Intrinsic (subroutine) ............................. CALL Second(SECONDS) SECONDS: `REAL'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Returns the process's runtime in seconds in SECONDS--the same value as the UNIX function `etime' returns. On some systems, the underlying timings are represented using types with sufficiently small limits that overflows (wraparounds) are possible, such as 32-bit types. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. This routine is known from Cray Fortran. *Note CPU_Time Intrinsic::, for a standard equivalent. For information on other intrinsics with the same name: *Note Second Intrinsic (function)::.  File: g77.info, Node: Selected_Int_Kind Intrinsic, Next: Selected_Real_Kind Intrinsic, Prev: Second Intrinsic (subroutine), Up: Table of Intrinsic Functions Selected_Int_Kind Intrinsic ........................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Selected_Int_Kind' to use this name for an external procedure.  File: g77.info, Node: Selected_Real_Kind Intrinsic, Next: Set_Exponent Intrinsic, Prev: Selected_Int_Kind Intrinsic, Up: Table of Intrinsic Functions Selected_Real_Kind Intrinsic ............................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Selected_Real_Kind' to use this name for an external procedure.  File: g77.info, Node: Set_Exponent Intrinsic, Next: Shape Intrinsic, Prev: Selected_Real_Kind Intrinsic, Up: Table of Intrinsic Functions Set_Exponent Intrinsic ...................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Set_Exponent' to use this name for an external procedure.  File: g77.info, Node: Shape Intrinsic, Next: Short Intrinsic, Prev: Set_Exponent Intrinsic, Up: Table of Intrinsic Functions Shape Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Shape' to use this name for an external procedure.  File: g77.info, Node: Short Intrinsic, Next: Sign Intrinsic, Prev: Shape Intrinsic, Up: Table of Intrinsic Functions Short Intrinsic ............... Short(A) Short: `INTEGER(KIND=6)' function. A: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns A with the fractional portion of its magnitude truncated and its sign preserved, converted to type `INTEGER(KIND=6)'. If A is type `COMPLEX', its real part is truncated and converted, and its imaginary part is disregarded. *Note Int Intrinsic::. The precise meaning of this intrinsic might change in a future version of the GNU Fortran language, as more is learned about how it is used.  File: g77.info, Node: Sign Intrinsic, Next: Signal Intrinsic (subroutine), Prev: Short Intrinsic, Up: Table of Intrinsic Functions Sign Intrinsic .............. Sign(A, B) Sign: `INTEGER' or `REAL' function, the exact type being the result of cross-promoting the types of all the arguments. A: `INTEGER' or `REAL'; scalar; INTENT(IN). B: `INTEGER' or `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns `ABS(A)*S', where S is +1 if `B.GE.0', -1 otherwise. *Note Abs Intrinsic::, for the function that returns the magnitude of a value.  File: g77.info, Node: Signal Intrinsic (subroutine), Next: Sin Intrinsic, Prev: Sign Intrinsic, Up: Table of Intrinsic Functions Signal Intrinsic (subroutine) ............................. CALL Signal(NUMBER, HANDLER, STATUS) NUMBER: `INTEGER'; scalar; INTENT(IN). HANDLER: Signal handler (`INTEGER FUNCTION' or `SUBROUTINE') or dummy/global `INTEGER(KIND=1)' scalar. STATUS: `INTEGER(KIND=7)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: If HANDLER is a an `EXTERNAL' routine, arranges for it to be invoked with a single integer argument (of system-dependent length) when signal NUMBER occurs. If HANDLER is an integer, it can be used to turn off handling of signal NUMBER or revert to its default action. See `signal(2)'. Note that HANDLER will be called using C conventions, so the value of its argument in Fortran terms Fortran terms is obtained by applying `%LOC()' (or `LOC()') to it. The value returned by `signal(2)' is written to STATUS, if that argument is supplied. Otherwise the return value is ignored. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. _Warning:_ Use of the `libf2c' run-time library function `signal_' directly (such as via `EXTERNAL SIGNAL') requires use of the `%VAL()' construct to pass an `INTEGER' value (such as `SIG_IGN' or `SIG_DFL') for the HANDLER argument. However, while `CALL SIGNAL(SIGNUM, %VAL(SIG_IGN))' works when `SIGNAL' is treated as an external procedure (and resolves, at link time, to `libf2c''s `signal_' routine), this construct is not valid when `SIGNAL' is recognized as the intrinsic of that name. Therefore, for maximum portability and reliability, code such references to the `SIGNAL' facility as follows: INTRINSIC SIGNAL ... CALL SIGNAL(SIGNUM, SIG_IGN) `g77' will compile such a call correctly, while other compilers will generally either do so as well or reject the `INTRINSIC SIGNAL' statement via a diagnostic, allowing you to take appropriate action. For information on other intrinsics with the same name: *Note Signal Intrinsic (function)::.  File: g77.info, Node: Sin Intrinsic, Next: SinH Intrinsic, Prev: Signal Intrinsic (subroutine), Up: Table of Intrinsic Functions Sin Intrinsic ............. Sin(X) Sin: `REAL' or `COMPLEX' function, the exact type being that of argument X. X: `REAL' or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the sine of X, an angle measured in radians. *Note ASin Intrinsic::, for the inverse of this function.  File: g77.info, Node: SinH Intrinsic, Next: Sleep Intrinsic, Prev: Sin Intrinsic, Up: Table of Intrinsic Functions SinH Intrinsic .............. SinH(X) SinH: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the hyperbolic sine of X.  File: g77.info, Node: Sleep Intrinsic, Next: Sngl Intrinsic, Prev: SinH Intrinsic, Up: Table of Intrinsic Functions Sleep Intrinsic ............... CALL Sleep(SECONDS) SECONDS: `INTEGER(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Causes the process to pause for SECONDS seconds. See `sleep(2)'.  File: g77.info, Node: Sngl Intrinsic, Next: Spacing Intrinsic, Prev: Sleep Intrinsic, Up: Table of Intrinsic Functions Sngl Intrinsic .............. Sngl(A) Sngl: `REAL(KIND=1)' function. A: `REAL(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Archaic form of `REAL()' that is specific to one type for A. *Note Real Intrinsic::.  File: g77.info, Node: Spacing Intrinsic, Next: Spread Intrinsic, Prev: Sngl Intrinsic, Up: Table of Intrinsic Functions Spacing Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Spacing' to use this name for an external procedure.  File: g77.info, Node: Spread Intrinsic, Next: SqRt Intrinsic, Prev: Spacing Intrinsic, Up: Table of Intrinsic Functions Spread Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Spread' to use this name for an external procedure.  File: g77.info, Node: SqRt Intrinsic, Next: SRand Intrinsic, Prev: Spread Intrinsic, Up: Table of Intrinsic Functions SqRt Intrinsic .............. SqRt(X) SqRt: `REAL' or `COMPLEX' function, the exact type being that of argument X. X: `REAL' or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the square root of X, which must not be negative. To calculate and represent the square root of a negative number, complex arithmetic must be used. For example, `SQRT(COMPLEX(X))'. The inverse of this function is `SQRT(X) * SQRT(X)'.  File: g77.info, Node: SRand Intrinsic, Next: Stat Intrinsic (subroutine), Prev: SqRt Intrinsic, Up: Table of Intrinsic Functions SRand Intrinsic ............... CALL SRand(SEED) SEED: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Reinitializes the generator with the seed in SEED. *Note IRand Intrinsic::. *Note Rand Intrinsic::.  File: g77.info, Node: Stat Intrinsic (subroutine), Next: Stat Intrinsic (function), Prev: SRand Intrinsic, Up: Table of Intrinsic Functions Stat Intrinsic (subroutine) ........................... CALL Stat(FILE, SARRAY, STATUS) FILE: `CHARACTER'; scalar; INTENT(IN). SARRAY: `INTEGER(KIND=1)'; DIMENSION(13); INTENT(OUT). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Obtains data about the given file FILE and places them in the array SARRAY. A null character (`CHAR(0)') marks the end of the name in FILE--otherwise, trailing blanks in FILE are ignored. The values in this array are extracted from the `stat' structure as returned by `fstat(2)' q.v., as follows: 1. Device ID 2. Inode number 3. File mode 4. Number of links 5. Owner's uid 6. Owner's gid 7. ID of device containing directory entry for file (0 if not available) 8. File size (bytes) 9. Last access time 10. Last modification time 11. Last file status change time 12. Preferred I/O block size (-1 if not available) 13. Number of blocks allocated (-1 if not available) Not all these elements are relevant on all systems. If an element is not relevant, it is returned as 0. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note Stat Intrinsic (function)::.  File: g77.info, Node: Stat Intrinsic (function), Next: Sum Intrinsic, Prev: Stat Intrinsic (subroutine), Up: Table of Intrinsic Functions Stat Intrinsic (function) ......................... Stat(FILE, SARRAY) Stat: `INTEGER(KIND=1)' function. FILE: `CHARACTER'; scalar; INTENT(IN). SARRAY: `INTEGER(KIND=1)'; DIMENSION(13); INTENT(OUT). Intrinsic groups: `unix'. Description: Obtains data about the given file FILE and places them in the array SARRAY. A null character (`CHAR(0)') marks the end of the name in FILE--otherwise, trailing blanks in FILE are ignored. The values in this array are extracted from the `stat' structure as returned by `fstat(2)' q.v., as follows: 1. Device ID 2. Inode number 3. File mode 4. Number of links 5. Owner's uid 6. Owner's gid 7. ID of device containing directory entry for file (0 if not available) 8. File size (bytes) 9. Last access time 10. Last modification time 11. Last file status change time 12. Preferred I/O block size (-1 if not available) 13. Number of blocks allocated (-1 if not available) Not all these elements are relevant on all systems. If an element is not relevant, it is returned as 0. Returns 0 on success or a nonzero error code. For information on other intrinsics with the same name: *Note Stat Intrinsic (subroutine)::.  File: g77.info, Node: Sum Intrinsic, Next: SymLnk Intrinsic (subroutine), Prev: Stat Intrinsic (function), Up: Table of Intrinsic Functions Sum Intrinsic ............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Sum' to use this name for an external procedure.  File: g77.info, Node: SymLnk Intrinsic (subroutine), Next: System Intrinsic (subroutine), Prev: Sum Intrinsic, Up: Table of Intrinsic Functions SymLnk Intrinsic (subroutine) ............................. CALL SymLnk(PATH1, PATH2, STATUS) PATH1: `CHARACTER'; scalar; INTENT(IN). PATH2: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Makes a symbolic link from file PATH1 to PATH2. A null character (`CHAR(0)') marks the end of the names in PATH1 and PATH2--otherwise, trailing blanks in PATH1 and PATH2 are ignored. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return (`ENOSYS' if the system does not provide `symlink(2)'). Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note SymLnk Intrinsic (function)::.  File: g77.info, Node: System Intrinsic (subroutine), Next: System_Clock Intrinsic, Prev: SymLnk Intrinsic (subroutine), Up: Table of Intrinsic Functions System Intrinsic (subroutine) ............................. CALL System(COMMAND, STATUS) COMMAND: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Passes the command COMMAND to a shell (see `system(3)'). If argument STATUS is present, it contains the value returned by `system(3)', presumably 0 if the shell command succeeded. Note that which shell is used to invoke the command is system-dependent and environment-dependent. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note System Intrinsic (function)::.  File: g77.info, Node: System_Clock Intrinsic, Next: Tan Intrinsic, Prev: System Intrinsic (subroutine), Up: Table of Intrinsic Functions System_Clock Intrinsic ...................... CALL System_Clock(COUNT, RATE, MAX) COUNT: `INTEGER(KIND=1)'; scalar; INTENT(OUT). RATE: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). MAX: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `f90'. Description: Returns in COUNT the current value of the system clock; this is the value returned by the UNIX function `times(2)' in this implementation, but isn't in general. RATE is the number of clock ticks per second and MAX is the maximum value this can take, which isn't very useful in this implementation since it's just the maximum C `unsigned int' value. On some systems, the underlying timings are represented using types with sufficiently small limits that overflows (wraparounds) are possible, such as 32-bit types. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program.  File: g77.info, Node: Tan Intrinsic, Next: TanH Intrinsic, Prev: System_Clock Intrinsic, Up: Table of Intrinsic Functions Tan Intrinsic ............. Tan(X) Tan: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the tangent of X, an angle measured in radians. *Note ATan Intrinsic::, for the inverse of this function.  File: g77.info, Node: TanH Intrinsic, Next: Time Intrinsic (UNIX), Prev: Tan Intrinsic, Up: Table of Intrinsic Functions TanH Intrinsic .............. TanH(X) TanH: `REAL' function, the `KIND=' value of the type being that of argument X. X: `REAL'; scalar; INTENT(IN). Intrinsic groups: (standard FORTRAN 77). Description: Returns the hyperbolic tangent of X.  File: g77.info, Node: Time Intrinsic (UNIX), Next: Time8 Intrinsic, Prev: TanH Intrinsic, Up: Table of Intrinsic Functions Time Intrinsic (UNIX) ..................... Time() Time: `INTEGER(KIND=1)' function. Intrinsic groups: `unix'. Description: Returns the current time encoded as an integer (in the manner of the UNIX function `time(3)'). This value is suitable for passing to `CTIME', `GMTIME', and `LTIME'. This intrinsic is not fully portable, such as to systems with 32-bit `INTEGER' types but supporting times wider than 32 bits. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. *Note Time8 Intrinsic::, for information on a similar intrinsic that might be portable to more GNU Fortran implementations, though to fewer Fortran compilers. For information on other intrinsics with the same name: *Note Time Intrinsic (VXT)::.  File: g77.info, Node: Time8 Intrinsic, Next: Tiny Intrinsic, Prev: Time Intrinsic (UNIX), Up: Table of Intrinsic Functions Time8 Intrinsic ............... Time8() Time8: `INTEGER(KIND=2)' function. Intrinsic groups: `unix'. Description: Returns the current time encoded as a long integer (in the manner of the UNIX function `time(3)'). This value is suitable for passing to `CTIME', `GMTIME', and `LTIME'. _Warning:_ this intrinsic does not increase the range of the timing values over that returned by `time(3)'. On a system with a 32-bit `time(3)', `TIME8' will return a 32-bit value, even though converted to an `INTEGER(KIND=2)' value. That means overflows of the 32-bit value can still occur. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. No Fortran implementations other than GNU Fortran are known to support this intrinsic at the time of this writing. *Note Time Intrinsic (UNIX)::, for information on a similar intrinsic that might be portable to more Fortran compilers, though to fewer GNU Fortran implementations.  File: g77.info, Node: Tiny Intrinsic, Next: Transfer Intrinsic, Prev: Time8 Intrinsic, Up: Table of Intrinsic Functions Tiny Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Tiny' to use this name for an external procedure.  File: g77.info, Node: Transfer Intrinsic, Next: Transpose Intrinsic, Prev: Tiny Intrinsic, Up: Table of Intrinsic Functions Transfer Intrinsic .................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Transfer' to use this name for an external procedure.  File: g77.info, Node: Transpose Intrinsic, Next: Trim Intrinsic, Prev: Transfer Intrinsic, Up: Table of Intrinsic Functions Transpose Intrinsic ................... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Transpose' to use this name for an external procedure.  File: g77.info, Node: Trim Intrinsic, Next: TtyNam Intrinsic (subroutine), Prev: Transpose Intrinsic, Up: Table of Intrinsic Functions Trim Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Trim' to use this name for an external procedure.  File: g77.info, Node: TtyNam Intrinsic (subroutine), Next: TtyNam Intrinsic (function), Prev: Trim Intrinsic, Up: Table of Intrinsic Functions TtyNam Intrinsic (subroutine) ............................. CALL TtyNam(UNIT, NAME) UNIT: `INTEGER'; scalar; INTENT(IN). NAME: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Sets NAME to the name of the terminal device open on logical unit UNIT or to a blank string if UNIT is not connected to a terminal. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine. For information on other intrinsics with the same name: *Note TtyNam Intrinsic (function)::.  File: g77.info, Node: TtyNam Intrinsic (function), Next: UBound Intrinsic, Prev: TtyNam Intrinsic (subroutine), Up: Table of Intrinsic Functions TtyNam Intrinsic (function) ........................... TtyNam(UNIT) TtyNam: `CHARACTER*(*)' function. UNIT: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `unix'. Description: Returns the name of the terminal device open on logical unit UNIT or a blank string if UNIT is not connected to a terminal. For information on other intrinsics with the same name: *Note TtyNam Intrinsic (subroutine)::.  File: g77.info, Node: UBound Intrinsic, Next: UMask Intrinsic (subroutine), Prev: TtyNam Intrinsic (function), Up: Table of Intrinsic Functions UBound Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL UBound' to use this name for an external procedure.  File: g77.info, Node: UMask Intrinsic (subroutine), Next: Unlink Intrinsic (subroutine), Prev: UBound Intrinsic, Up: Table of Intrinsic Functions UMask Intrinsic (subroutine) ............................ CALL UMask(MASK, OLD) MASK: `INTEGER'; scalar; INTENT(IN). OLD: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Sets the file creation mask to MASK and returns the old value in argument OLD if it is supplied. See `umask(2)'. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine. For information on other intrinsics with the same name: *Note UMask Intrinsic (function)::.  File: g77.info, Node: Unlink Intrinsic (subroutine), Next: Unpack Intrinsic, Prev: UMask Intrinsic (subroutine), Up: Table of Intrinsic Functions Unlink Intrinsic (subroutine) ............................. CALL Unlink(FILE, STATUS) FILE: `CHARACTER'; scalar; INTENT(IN). STATUS: `INTEGER(KIND=1)'; OPTIONAL; scalar; INTENT(OUT). Intrinsic groups: `unix'. Description: Unlink the file FILE. A null character (`CHAR(0)') marks the end of the name in FILE--otherwise, trailing blanks in FILE are ignored. If the STATUS argument is supplied, it contains 0 on success or a nonzero error code upon return. See `unlink(2)'. Some non-GNU implementations of Fortran provide this intrinsic as only a function, not as a subroutine, or do not support the (optional) STATUS argument. For information on other intrinsics with the same name: *Note Unlink Intrinsic (function)::.  File: g77.info, Node: Unpack Intrinsic, Next: Verify Intrinsic, Prev: Unlink Intrinsic (subroutine), Up: Table of Intrinsic Functions Unpack Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Unpack' to use this name for an external procedure.  File: g77.info, Node: Verify Intrinsic, Next: XOr Intrinsic, Prev: Unpack Intrinsic, Up: Table of Intrinsic Functions Verify Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL Verify' to use this name for an external procedure.  File: g77.info, Node: XOr Intrinsic, Next: ZAbs Intrinsic, Prev: Verify Intrinsic, Up: Table of Intrinsic Functions XOr Intrinsic ............. XOr(I, J) XOr: `INTEGER' or `LOGICAL' function, the exact type being the result of cross-promoting the types of all the arguments. I: `INTEGER' or `LOGICAL'; scalar; INTENT(IN). J: `INTEGER' or `LOGICAL'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Returns value resulting from boolean exclusive-OR of pair of bits in each of I and J.  File: g77.info, Node: ZAbs Intrinsic, Next: ZCos Intrinsic, Prev: XOr Intrinsic, Up: Table of Intrinsic Functions ZAbs Intrinsic .............. ZAbs(A) ZAbs: `REAL(KIND=2)' function. A: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Archaic form of `ABS()' that is specific to one type for A. *Note Abs Intrinsic::.  File: g77.info, Node: ZCos Intrinsic, Next: ZExp Intrinsic, Prev: ZAbs Intrinsic, Up: Table of Intrinsic Functions ZCos Intrinsic .............. ZCos(X) ZCos: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Archaic form of `COS()' that is specific to one type for X. *Note Cos Intrinsic::.  File: g77.info, Node: ZExp Intrinsic, Next: ZLog Intrinsic, Prev: ZCos Intrinsic, Up: Table of Intrinsic Functions ZExp Intrinsic .............. ZExp(X) ZExp: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Archaic form of `EXP()' that is specific to one type for X. *Note Exp Intrinsic::.  File: g77.info, Node: ZLog Intrinsic, Next: ZSin Intrinsic, Prev: ZExp Intrinsic, Up: Table of Intrinsic Functions ZLog Intrinsic .............. ZLog(X) ZLog: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Archaic form of `LOG()' that is specific to one type for X. *Note Log Intrinsic::.  File: g77.info, Node: ZSin Intrinsic, Next: ZSqRt Intrinsic, Prev: ZLog Intrinsic, Up: Table of Intrinsic Functions ZSin Intrinsic .............. ZSin(X) ZSin: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Archaic form of `SIN()' that is specific to one type for X. *Note Sin Intrinsic::.  File: g77.info, Node: ZSqRt Intrinsic, Prev: ZSin Intrinsic, Up: Table of Intrinsic Functions ZSqRt Intrinsic ............... ZSqRt(X) ZSqRt: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c'. Description: Archaic form of `SQRT()' that is specific to one type for X. *Note SqRt Intrinsic::.  File: g77.info, Node: Scope and Classes of Names, Next: I/O, Prev: Functions and Subroutines, Up: Language Scope and Classes of Symbolic Names =================================== (The following information augments or overrides the information in Chapter 18 of ANSI X3.9-1978 FORTRAN 77 in specifying the GNU Fortran language. Chapter 18 of that document otherwise serves as the basis for the relevant aspects of GNU Fortran.) * Menu: * Underscores in Symbol Names::  File: g77.info, Node: Underscores in Symbol Names, Up: Scope and Classes of Names Underscores in Symbol Names --------------------------- Underscores (`_') are accepted in symbol names after the first character (which must be a letter).  File: g77.info, Node: I/O, Next: Fortran 90 Features, Prev: Scope and Classes of Names, Up: Language I/O === A dollar sign at the end of an output format specification suppresses the newline at the end of the output. Edit descriptors in `FORMAT' statements may contain compile-time `INTEGER' constant expressions in angle brackets, such as 10 FORMAT (I) The `OPEN' specifier `NAME=' is equivalent to `FILE='. These Fortran 90 features are supported: * The `O' and `Z' edit descriptors are supported for I/O of integers in octal and hexadecimal formats, respectively. * The `FILE=' specifier may be omitted in an `OPEN' statement if `STATUS='SCRATCH'' is supplied. The `STATUS='REPLACE'' specifier is supported.  File: g77.info, Node: Fortran 90 Features, Prev: I/O, Up: Language Fortran 90 Features =================== For convenience this section collects a list (probably incomplete) of the Fortran 90 features supported by the GNU Fortran language, even if they are documented elsewhere. *Note Characters, Lines, and Execution Sequence: Characters Lines Sequence, for information on additional fixed source form lexical issues. Further, the free source form is supported through the `-ffree-form' option. Other Fortran 90 features can be turned on by the `-ff90' option; see *Note Fortran 90::. For information on the Fortran 90 intrinsics available, see *Note Table of Intrinsic Functions::. Automatic arrays in procedures Character assignments In character assignments, the variable being assigned may occur on the right hand side of the assignment. Character strings Strings may have zero length and substrings of character constants are permitted. Character constants may be enclosed in double quotes (`"') as well as single quotes. *Note Character Type::. Construct names (Symbolic tags on blocks.) *Note Construct Names::. `CYCLE' and `EXIT' *Note The `CYCLE' and `EXIT' Statements: CYCLE and EXIT. `DOUBLE COMPLEX' *Note `DOUBLE COMPLEX' Statement: DOUBLE COMPLEX. `DO WHILE' *Note DO WHILE::. `END' decoration *Note Statements::. `END DO' *Note END DO::. `KIND' `IMPLICIT NONE' `INCLUDE' statements *Note INCLUDE::. List-directed and namelist I/O on internal files Binary, octal and hexadecimal constants These are supported more generally than required by Fortran 90. *Note Integer Type::. `O' and `Z' edit descriptors `NAMELIST' *Note NAMELIST::. `OPEN' specifiers `STATUS='REPLACE'' is supported. The `FILE=' specifier may be omitted in an `OPEN' statement if `STATUS='SCRATCH'' is supplied. `FORMAT' edit descriptors The `Z' edit descriptor is supported. Relational operators The operators `<', `<=', `==', `/=', `>' and `>=' may be used instead of `.LT.', `.LE.', `.EQ.', `.NE.', `.GT.' and `.GE.' respectively. `SELECT CASE' Not fully implemented. *Note `SELECT CASE' on `CHARACTER' Type: SELECT CASE on CHARACTER Type. Specification statements A limited subset of the Fortran 90 syntax and semantics for variable declarations is supported, including `KIND'. *Note Kind Notation::. (`KIND' is of limited usefulness in the absence of the `KIND'-related intrinsics, since these intrinsics permit writing more widely portable code.) An example of supported `KIND' usage is: INTEGER (KIND=1) :: FOO=1, BAR=2 CHARACTER (LEN=3) FOO `PARAMETER' and `DIMENSION' attributes aren't supported.  File: g77.info, Node: Other Dialects, Next: Other Compilers, Prev: Compiler, Up: Top Other Dialects ************** GNU Fortran supports a variety of features that are not considered part of the GNU Fortran language itself, but are representative of various dialects of Fortran that `g77' supports in whole or in part. Any of the features listed below might be disallowed by `g77' unless some command-line option is specified. Currently, some of the features are accepted using the default invocation of `g77', but that might change in the future. _Note: This portion of the documentation definitely needs a lot of work!_ * Menu: * Source Form:: Details of fixed-form and free-form source. * Trailing Comment:: Use of `/*' to start a comment. * Debug Line:: Use of `D' in column 1. * Dollar Signs:: Use of `$' in symbolic names. * Case Sensitivity:: Uppercase and lowercase in source files. * VXT Fortran:: ...versus the GNU Fortran language. * Fortran 90:: ...versus the GNU Fortran language. * Pedantic Compilation:: Enforcing the standard. * Distensions:: Misfeatures supported by GNU Fortran.  File: g77.info, Node: Source Form, Next: Trailing Comment, Up: Other Dialects Source Form =========== GNU Fortran accepts programs written in either fixed form or free form. Fixed form corresponds to ANSI FORTRAN 77 (plus popular extensions, such as allowing tabs) and Fortran 90's fixed form. Free form corresponds to Fortran 90's free form (though possibly not entirely up-to-date, and without complaining about some things that for which Fortran 90 requires diagnostics, such as the spaces in the constant in `R = 3 . 1'). The way a Fortran compiler views source files depends entirely on the implementation choices made for the compiler, since those choices are explicitly left to the implementation by the published Fortran standards. GNU Fortran currently tries to be somewhat like a few popular compilers (`f2c', Digital ("DEC") Fortran, and so on). This section describes how `g77' interprets source lines. * Menu: * Carriage Returns:: Carriage returns ignored. * Tabs:: Tabs converted to spaces. * Short Lines:: Short lines padded with spaces (fixed-form only). * Long Lines:: Long lines truncated. * Ampersands:: Special Continuation Lines.  File: g77.info, Node: Carriage Returns, Next: Tabs, Up: Source Form Carriage Returns ---------------- Carriage returns (`\r') in source lines are ignored. This is somewhat different from `f2c', which seems to treat them as spaces outside character/Hollerith constants, and encodes them as `\r' inside such constants.  File: g77.info, Node: Tabs, Next: Short Lines, Prev: Carriage Returns, Up: Source Form Tabs ---- A source line with a character anywhere in it is treated as entirely significant--however long it is--instead of ending in column 72 (for fixed-form source) or 132 (for free-form source). This also is different from `f2c', which encodes tabs as `\t' (the ASCII character) inside character and Hollerith constants, but nevertheless seems to treat the column position as if it had been affected by the canonical tab positioning. `g77' effectively translates tabs to the appropriate number of spaces (a la the default for the UNIX `expand' command) before doing any other processing, other than (currently) noting whether a tab was found on a line and using this information to decide how to interpret the length of the line and continued constants.  File: g77.info, Node: Short Lines, Next: Long Lines, Prev: Tabs, Up: Source Form Short Lines ----------- Source lines shorter than the applicable fixed-form length are treated as if they were padded with spaces to that length. (None of this is relevant to source files written in free form.) This affects only continued character and Hollerith constants, and is a different interpretation than provided by some other popular compilers (although a bit more consistent with the traditional punched-card basis of Fortran and the way the Fortran standard expressed fixed source form). `g77' might someday offer an option to warn about cases where differences might be seen as a result of this treatment, and perhaps an option to specify the alternate behavior as well. Note that this padding cannot apply to lines that are effectively of infinite length--such lines are specified using command-line options like `-ffixed-line-length-none', for example.  File: g77.info, Node: Long Lines, Next: Ampersands, Prev: Short Lines, Up: Source Form Long Lines ---------- Source lines longer than the applicable length are truncated to that length. Currently, `g77' does not warn if the truncated characters are not spaces, to accommodate existing code written for systems that treated truncated text as commentary (especially in columns 73 through 80). *Note Options Controlling Fortran Dialect: Fortran Dialect Options, for information on the `-ffixed-line-length-N' option, which can be used to set the line length applicable to fixed-form source files.  File: g77.info, Node: Ampersands, Prev: Long Lines, Up: Source Form Ampersand Continuation Line --------------------------- A `&' in column 1 of fixed-form source denotes an arbitrary-length continuation line, imitating the behavior of `f2c'.  File: g77.info, Node: Trailing Comment, Next: Debug Line, Prev: Source Form, Up: Other Dialects Trailing Comment ================ `g77' supports use of `/*' to start a trailing comment. In the GNU Fortran language, `!' is used for this purpose. `/*' is not in the GNU Fortran language because the use of `/*' in a program might suggest to some readers that a block, not trailing, comment is started (and thus ended by `*/', not end of line), since that is the meaning of `/*' in C. Also, such readers might think they can use `//' to start a trailing comment as an alternative to `/*', but `//' already denotes concatenation, and such a "comment" might actually result in a program that compiles without error (though it would likely behave incorrectly).  File: g77.info, Node: Debug Line, Next: Dollar Signs, Prev: Trailing Comment, Up: Other Dialects Debug Line ========== Use of `D' or `d' as the first character (column 1) of a source line denotes a debug line. In turn, a debug line is treated as either a comment line or a normal line, depending on whether debug lines are enabled. When treated as a comment line, a line beginning with `D' or `d' is treated as if it the first character was `C' or `c', respectively. When treated as a normal line, such a line is treated as if the first character was (space). (Currently, `g77' provides no means for treating debug lines as normal lines.)  File: g77.info, Node: Dollar Signs, Next: Case Sensitivity, Prev: Debug Line, Up: Other Dialects Dollar Signs in Symbol Names ============================ Dollar signs (`$') are allowed in symbol names (after the first character) when the `-fdollar-ok' option is specified.  File: g77.info, Node: Case Sensitivity, Next: VXT Fortran, Prev: Dollar Signs, Up: Other Dialects Case Sensitivity ================ GNU Fortran offers the programmer way too much flexibility in deciding how source files are to be treated vis-a-vis uppercase and lowercase characters. There are 66 useful settings that affect case sensitivity, plus 10 settings that are nearly useless, with the remaining 116 settings being either redundant or useless. None of these settings have any effect on the contents of comments (the text after a `c' or `C' in Column 1, for example) or of character or Hollerith constants. Note that things like the `E' in the statement `CALL FOO(3.2E10)' and the `TO' in `ASSIGN 10 TO LAB' are considered built-in keywords, and so are affected by these settings. Low-level switches are identified in this section as follows: A Source Case Conversion: 0 Preserve (see Note 1) 1 Convert to Upper Case 2 Convert to Lower Case B Built-in Keyword Matching: 0 Match Any Case (per-character basis) 1 Match Upper Case Only 2 Match Lower Case Only 3 Match InitialCaps Only (see tables for spellings) C Built-in Intrinsic Matching: 0 Match Any Case (per-character basis) 1 Match Upper Case Only 2 Match Lower Case Only 3 Match InitialCaps Only (see tables for spellings) D User-defined Symbol Possibilities (warnings only): 0 Allow Any Case (per-character basis) 1 Allow Upper Case Only 2 Allow Lower Case Only 3 Allow InitialCaps Only (see Note 2) Note 1: `g77' eventually will support `NAMELIST' in a manner that is consistent with these source switches--in the sense that input will be expected to meet the same requirements as source code in terms of matching symbol names and keywords (for the exponent letters). Currently, however, `NAMELIST' is supported by `libg2c', which uppercases `NAMELIST' input and symbol names for matching. This means not only that `NAMELIST' output currently shows symbol (and keyword) names in uppercase even if lower-case source conversion (option A2) is selected, but that `NAMELIST' cannot be adequately supported when source case preservation (option A0) is selected. If A0 is selected, a warning message will be output for each `NAMELIST' statement to this effect. The behavior of the program is undefined at run time if two or more symbol names appear in a given `NAMELIST' such that the names are identical when converted to upper case (e.g. `NAMELIST /X/ VAR, Var, var'). For complete and total elegance, perhaps there should be a warning when option A2 is selected, since the output of NAMELIST is currently in uppercase but will someday be lowercase (when a `libg77' is written), but that seems to be overkill for a product in beta test. Note 2: Rules for InitialCaps names are: - Must be a single uppercase letter, *or* - Must start with an uppercase letter and contain at least one lowercase letter. So `A', `Ab', `ABc', `AbC', and `Abc' are valid InitialCaps names, but `AB', `A2', and `ABC' are not. Note that most, but not all, built-in names meet these requirements--the exceptions are some of the two-letter format specifiers, such as `BN' and `BZ'. Here are the names of the corresponding command-line options: A0: -fsource-case-preserve A1: -fsource-case-upper A2: -fsource-case-lower B0: -fmatch-case-any B1: -fmatch-case-upper B2: -fmatch-case-lower B3: -fmatch-case-initcap C0: -fintrin-case-any C1: -fintrin-case-upper C2: -fintrin-case-lower C3: -fintrin-case-initcap D0: -fsymbol-case-any D1: -fsymbol-case-upper D2: -fsymbol-case-lower D3: -fsymbol-case-initcap Useful combinations of the above settings, along with abbreviated option names that set some of these combinations all at once: 1: A0-- B0--- C0--- D0--- -fcase-preserve 2: A0-- B0--- C0--- D-1-- 3: A0-- B0--- C0--- D--2- 4: A0-- B0--- C0--- D---3 5: A0-- B0--- C-1-- D0--- 6: A0-- B0--- C-1-- D-1-- 7: A0-- B0--- C-1-- D--2- 8: A0-- B0--- C-1-- D---3 9: A0-- B0--- C--2- D0--- 10: A0-- B0--- C--2- D-1-- 11: A0-- B0--- C--2- D--2- 12: A0-- B0--- C--2- D---3 13: A0-- B0--- C---3 D0--- 14: A0-- B0--- C---3 D-1-- 15: A0-- B0--- C---3 D--2- 16: A0-- B0--- C---3 D---3 17: A0-- B-1-- C0--- D0--- 18: A0-- B-1-- C0--- D-1-- 19: A0-- B-1-- C0--- D--2- 20: A0-- B-1-- C0--- D---3 21: A0-- B-1-- C-1-- D0--- 22: A0-- B-1-- C-1-- D-1-- -fcase-strict-upper 23: A0-- B-1-- C-1-- D--2- 24: A0-- B-1-- C-1-- D---3 25: A0-- B-1-- C--2- D0--- 26: A0-- B-1-- C--2- D-1-- 27: A0-- B-1-- C--2- D--2- 28: A0-- B-1-- C--2- D---3 29: A0-- B-1-- C---3 D0--- 30: A0-- B-1-- C---3 D-1-- 31: A0-- B-1-- C---3 D--2- 32: A0-- B-1-- C---3 D---3 33: A0-- B--2- C0--- D0--- 34: A0-- B--2- C0--- D-1-- 35: A0-- B--2- C0--- D--2- 36: A0-- B--2- C0--- D---3 37: A0-- B--2- C-1-- D0--- 38: A0-- B--2- C-1-- D-1-- 39: A0-- B--2- C-1-- D--2- 40: A0-- B--2- C-1-- D---3 41: A0-- B--2- C--2- D0--- 42: A0-- B--2- C--2- D-1-- 43: A0-- B--2- C--2- D--2- -fcase-strict-lower 44: A0-- B--2- C--2- D---3 45: A0-- B--2- C---3 D0--- 46: A0-- B--2- C---3 D-1-- 47: A0-- B--2- C---3 D--2- 48: A0-- B--2- C---3 D---3 49: A0-- B---3 C0--- D0--- 50: A0-- B---3 C0--- D-1-- 51: A0-- B---3 C0--- D--2- 52: A0-- B---3 C0--- D---3 53: A0-- B---3 C-1-- D0--- 54: A0-- B---3 C-1-- D-1-- 55: A0-- B---3 C-1-- D--2- 56: A0-- B---3 C-1-- D---3 57: A0-- B---3 C--2- D0--- 58: A0-- B---3 C--2- D-1-- 59: A0-- B---3 C--2- D--2- 60: A0-- B---3 C--2- D---3 61: A0-- B---3 C---3 D0--- 62: A0-- B---3 C---3 D-1-- 63: A0-- B---3 C---3 D--2- 64: A0-- B---3 C---3 D---3 -fcase-initcap 65: A-1- B01-- C01-- D01-- -fcase-upper 66: A--2 B0-2- C0-2- D0-2- -fcase-lower Number 22 is the "strict" ANSI FORTRAN 77 model wherein all input (except comments, character constants, and Hollerith strings) must be entered in uppercase. Use `-fcase-strict-upper' to specify this combination. Number 43 is like Number 22 except all input must be lowercase. Use `-fcase-strict-lower' to specify this combination. Number 65 is the "classic" ANSI FORTRAN 77 model as implemented on many non-UNIX machines whereby all the source is translated to uppercase. Use `-fcase-upper' to specify this combination. Number 66 is the "canonical" UNIX model whereby all the source is translated to lowercase. Use `-fcase-lower' to specify this combination. There are a few nearly useless combinations: 67: A-1- B01-- C01-- D--2- 68: A-1- B01-- C01-- D---3 69: A-1- B01-- C--23 D01-- 70: A-1- B01-- C--23 D--2- 71: A-1- B01-- C--23 D---3 72: A--2 B01-- C0-2- D-1-- 73: A--2 B01-- C0-2- D---3 74: A--2 B01-- C-1-3 D0-2- 75: A--2 B01-- C-1-3 D-1-- 76: A--2 B01-- C-1-3 D---3 The above allow some programs to be compiled but with restrictions that make most useful programs impossible: Numbers 67 and 72 warn about _any_ user-defined symbol names (such as `SUBROUTINE FOO'); Numbers 68 and 73 warn about any user-defined symbol names longer than one character that don't have at least one non-alphabetic character after the first; Numbers 69 and 74 disallow any references to intrinsics; and Numbers 70, 71, 75, and 76 are combinations of the restrictions in 67+69, 68+69, 72+74, and 73+74, respectively. All redundant combinations are shown in the above tables anyplace where more than one setting is shown for a low-level switch. For example, `B0-2-' means either setting 0 or 2 is valid for switch B. The "proper" setting in such a case is the one that copies the setting of switch A--any other setting might slightly reduce the speed of the compiler, though possibly to an unmeasurable extent. All remaining combinations are useless in that they prevent successful compilation of non-null source files (source files with something other than comments).  File: g77.info, Node: VXT Fortran, Next: Fortran 90, Prev: Case Sensitivity, Up: Other Dialects VXT Fortran =========== `g77' supports certain constructs that have different meanings in VXT Fortran than they do in the GNU Fortran language. Generally, this manual uses the invented term VXT Fortran to refer VAX FORTRAN (circa v4). That compiler offered many popular features, though not necessarily those that are specific to the VAX processor architecture, the VMS operating system, or Digital Equipment Corporation's Fortran product line. (VAX and VMS probably are trademarks of Digital Equipment Corporation.) An extension offered by a Digital Fortran product that also is offered by several other Fortran products for different kinds of systems is probably going to be considered for inclusion in `g77' someday, and is considered a VXT Fortran feature. The `-fvxt' option generally specifies that, where the meaning of a construct is ambiguous (means one thing in GNU Fortran and another in VXT Fortran), the VXT Fortran meaning is to be assumed. * Menu: * Double Quote Meaning:: `"2000' as octal constant. * Exclamation Point:: `!' in column 6.  File: g77.info, Node: Double Quote Meaning, Next: Exclamation Point, Up: VXT Fortran Meaning of Double Quote ----------------------- `g77' treats double-quote (`"') as beginning an octal constant of `INTEGER(KIND=1)' type when the `-fvxt' option is specified. The form of this octal constant is "OCTAL-DIGITS where OCTAL-DIGITS is a nonempty string of characters in the set `01234567'. For example, the `-fvxt' option permits this: PRINT *, "20 END The above program would print the value `16'. *Note Integer Type::, for information on the preferred construct for integer constants specified using GNU Fortran's octal notation. (In the GNU Fortran language, the double-quote character (`"') delimits a character constant just as does apostrophe (`''). There is no way to allow both constructs in the general case, since statements like `PRINT *,"2000 !comment?"' would be ambiguous.)  File: g77.info, Node: Exclamation Point, Prev: Double Quote Meaning, Up: VXT Fortran Meaning of Exclamation Point in Column 6 ---------------------------------------- `g77' treats an exclamation point (`!') in column 6 of a fixed-form source file as a continuation character rather than as the beginning of a comment (as it does in any other column) when the `-fvxt' option is specified. The following program, when run, prints a message indicating whether it is interpreted according to GNU Fortran (and Fortran 90) rules or VXT Fortran rules: C234567 (This line begins in column 1.) I = 0 !1 IF (I.EQ.0) PRINT *, ' I am a VXT Fortran program' IF (I.EQ.1) PRINT *, ' I am a Fortran 90 program' IF (I.LT.0 .OR. I.GT.1) PRINT *, ' I am a HAL 9000 computer' END (In the GNU Fortran and Fortran 90 languages, exclamation point is a valid character and, unlike space () or zero (`0'), marks a line as a continuation line when it appears in column 6.)  File: g77.info, Node: Fortran 90, Next: Pedantic Compilation, Prev: VXT Fortran, Up: Other Dialects Fortran 90 ========== The GNU Fortran language includes a number of features that are part of Fortran 90, even when the `-ff90' option is not specified. The features enabled by `-ff90' are intended to be those that, when `-ff90' is not specified, would have another meaning to `g77'--usually meaning something invalid in the GNU Fortran language. So, the purpose of `-ff90' is not to specify whether `g77' is to gratuitously reject Fortran 90 constructs. The `-pedantic' option specified with `-fno-f90' is intended to do that, although its implementation is certainly incomplete at this point. When `-ff90' is specified: * The type of `REAL(EXPR)' and `AIMAG(EXPR)', where EXPR is `COMPLEX' type, is the same type as the real part of EXPR. For example, assuming `Z' is type `COMPLEX(KIND=2)', `REAL(Z)' would return a value of type `REAL(KIND=2)', not of type `REAL(KIND=1)', since `-ff90' is specified.  File: g77.info, Node: Pedantic Compilation, Next: Distensions, Prev: Fortran 90, Up: Other Dialects Pedantic Compilation ==================== The `-fpedantic' command-line option specifies that `g77' is to warn about code that is not standard-conforming. This is useful for finding some extensions `g77' accepts that other compilers might not accept. (Note that the `-pedantic' and `-pedantic-errors' options always imply `-fpedantic'.) With `-fno-f90' in force, ANSI FORTRAN 77 is used as the standard for conforming code. With `-ff90' in force, Fortran 90 is used. The constructs for which `g77' issues diagnostics when `-fpedantic' and `-fno-f90' are in force are: * Automatic arrays, as in SUBROUTINE X(N) REAL A(N) ... where `A' is not listed in any `ENTRY' statement, and thus is not a dummy argument. * The commas in `READ (5), I' and `WRITE (10), J'. These commas are disallowed by FORTRAN 77, but, while strictly superfluous, are syntactically elegant, especially given that commas are required in statements such as `READ 99, I' and `PRINT *, J'. Many compilers permit the superfluous commas for this reason. * `DOUBLE COMPLEX', either explicitly or implicitly. An explicit use of this type is via a `DOUBLE COMPLEX' or `IMPLICIT DOUBLE COMPLEX' statement, for examples. An example of an implicit use is the expression `C*D', where `C' is `COMPLEX(KIND=1)' and `D' is `DOUBLE PRECISION'. This expression is prohibited by ANSI FORTRAN 77 because the rules of promotion would suggest that it produce a `DOUBLE COMPLEX' result--a type not provided for by that standard. * Automatic conversion of numeric expressions to `INTEGER(KIND=1)' in contexts such as: - Array-reference indexes. - Alternate-return values. - Computed `GOTO'. - `FORMAT' run-time expressions (not yet supported). - Dimension lists in specification statements. - Numbers for I/O statements (such as `READ (UNIT=3.2), I') - Sizes of `CHARACTER' entities in specification statements. - Kind types in specification entities (a Fortran 90 feature). - Initial, terminal, and incrementation parameters for implied-`DO' constructs in `DATA' statements. * Automatic conversion of `LOGICAL' expressions to `INTEGER' in contexts such as arithmetic `IF' (where `COMPLEX' expressions are disallowed anyway). * Zero-size array dimensions, as in: INTEGER I(10,20,4:2) * Zero-length `CHARACTER' entities, as in: PRINT *, '' * Substring operators applied to character constants and named constants, as in: PRINT *, 'hello'(3:5) * Null arguments passed to statement function, as in: PRINT *, FOO(,3) * Disagreement among program units regarding whether a given `COMMON' area is `SAVE'd (for targets where program units in a single source file are "glued" together as they typically are for UNIX development environments). * Disagreement among program units regarding the size of a named `COMMON' block. * Specification statements following first `DATA' statement. (In the GNU Fortran language, `DATA I/1/' may be followed by `INTEGER J', but not `INTEGER I'. The `-fpedantic' option disallows both of these.) * Semicolon as statement separator, as in: CALL FOO; CALL BAR * Use of `&' in column 1 of fixed-form source (to indicate continuation). * Use of `CHARACTER' constants to initialize numeric entities, and vice versa. * Expressions having two arithmetic operators in a row, such as `X*-Y'. If `-fpedantic' is specified along with `-ff90', the following constructs result in diagnostics: * Use of semicolon as a statement separator on a line that has an `INCLUDE' directive.  File: g77.info, Node: Distensions, Prev: Pedantic Compilation, Up: Other Dialects Distensions =========== The `-fugly-*' command-line options determine whether certain features supported by VAX FORTRAN and other such compilers, but considered too ugly to be in code that can be changed to use safer and/or more portable constructs, are accepted. These are humorously referred to as "distensions", extensions that just plain look ugly in the harsh light of day. * Menu: * Ugly Implicit Argument Conversion:: Disabled via `-fno-ugly-args'. * Ugly Assumed-Size Arrays:: Enabled via `-fugly-assumed'. * Ugly Null Arguments:: Enabled via `-fugly-comma'. * Ugly Complex Part Extraction:: Enabled via `-fugly-complex'. * Ugly Conversion of Initializers:: Disabled via `-fno-ugly-init'. * Ugly Integer Conversions:: Enabled via `-fugly-logint'. * Ugly Assigned Labels:: Enabled via `-fugly-assign'.  File: g77.info, Node: Ugly Implicit Argument Conversion, Next: Ugly Assumed-Size Arrays, Up: Distensions Implicit Argument Conversion ---------------------------- The `-fno-ugly-args' option disables passing typeless and Hollerith constants as actual arguments in procedure invocations. For example: CALL FOO(4HABCD) CALL BAR('123'O) These constructs can be too easily used to create non-portable code, but are not considered as "ugly" as others. Further, they are widely used in existing Fortran source code in ways that often are quite portable. Therefore, they are enabled by default.  File: g77.info, Node: Ugly Assumed-Size Arrays, Next: Ugly Null Arguments, Prev: Ugly Implicit Argument Conversion, Up: Distensions Ugly Assumed-Size Arrays ------------------------ The `-fugly-assumed' option enables the treatment of any array with a final dimension specified as `1' as an assumed-size array, as if `*' had been specified instead. For example, `DIMENSION X(1)' is treated as if it had read `DIMENSION X(*)' if `X' is listed as a dummy argument in a preceding `SUBROUTINE', `FUNCTION', or `ENTRY' statement in the same program unit. Use an explicit lower bound to avoid this interpretation. For example, `DIMENSION X(1:1)' is never treated as if it had read `DIMENSION X(*)' or `DIMENSION X(1:*)'. Nor is `DIMENSION X(2-1)' affected by this option, since that kind of expression is unlikely to have been intended to designate an assumed-size array. This option is used to prevent warnings being issued about apparent out-of-bounds reference such as `X(2) = 99'. It also prevents the array from being used in contexts that disallow assumed-size arrays, such as `PRINT *,X'. In such cases, a diagnostic is generated and the source file is not compiled. The construct affected by this option is used only in old code that pre-exists the widespread acceptance of adjustable and assumed-size arrays in the Fortran community. _Note:_ This option does not affect how `DIMENSION X(1)' is treated if `X' is listed as a dummy argument only _after_ the `DIMENSION' statement (presumably in an `ENTRY' statement). For example, `-fugly-assumed' has no effect on the following program unit: SUBROUTINE X REAL A(1) RETURN ENTRY Y(A) PRINT *, A END  File: g77.info, Node: Ugly Complex Part Extraction, Next: Ugly Conversion of Initializers, Prev: Ugly Null Arguments, Up: Distensions Ugly Complex Part Extraction ---------------------------- The `-fugly-complex' option enables use of the `REAL()' and `AIMAG()' intrinsics with arguments that are `COMPLEX' types other than `COMPLEX(KIND=1)'. With `-ff90' in effect, these intrinsics return the unconverted real and imaginary parts (respectively) of their argument. With `-fno-f90' in effect, these intrinsics convert the real and imaginary parts to `REAL(KIND=1)', and return the result of that conversion. Due to this ambiguity, the GNU Fortran language defines these constructs as invalid, except in the specific case where they are entirely and solely passed as an argument to an invocation of the `REAL()' intrinsic. For example, REAL(REAL(Z)) is permitted even when `Z' is `COMPLEX(KIND=2)' and `-fno-ugly-complex' is in effect, because the meaning is clear. `g77' enforces this restriction, unless `-fugly-complex' is specified, in which case the appropriate interpretation is chosen and no diagnostic is issued. *Note CMPAMBIG::, for information on how to cope with existing code with unclear expectations of `REAL()' and `AIMAG()' with `COMPLEX(KIND=2)' arguments. *Note RealPart Intrinsic::, for information on the `REALPART()' intrinsic, used to extract the real part of a complex expression without conversion. *Note ImagPart Intrinsic::, for information on the `IMAGPART()' intrinsic, used to extract the imaginary part of a complex expression without conversion.  File: g77.info, Node: Ugly Null Arguments, Next: Ugly Complex Part Extraction, Prev: Ugly Assumed-Size Arrays, Up: Distensions Ugly Null Arguments ------------------- The `-fugly-comma' option enables use of a single trailing comma to mean "pass an extra trailing null argument" in a list of actual arguments to an external procedure, and use of an empty list of arguments to such a procedure to mean "pass a single null argument". (Null arguments often are used in some procedure-calling schemes to indicate omitted arguments.) For example, `CALL FOO(,)' means "pass two null arguments", rather than "pass one null argument". Also, `CALL BAR()' means "pass one null argument". This construct is considered "ugly" because it does not provide an elegant way to pass a single null argument that is syntactically distinct from passing no arguments. That is, this construct changes the meaning of code that makes no use of the construct. So, with `-fugly-comma' in force, `CALL FOO()' and `I = JFUNC()' pass a single null argument, instead of passing no arguments as required by the Fortran 77 and 90 standards. _Note:_ Many systems gracefully allow the case where a procedure call passes one extra argument that the called procedure does not expect. So, in practice, there might be no difference in the behavior of a program that does `CALL FOO()' or `I = JFUNC()' and is compiled with `-fugly-comma' in force as compared to its behavior when compiled with the default, `-fno-ugly-comma', in force, assuming `FOO' and `JFUNC' do not expect any arguments to be passed.  File: g77.info, Node: Ugly Conversion of Initializers, Next: Ugly Integer Conversions, Prev: Ugly Complex Part Extraction, Up: Distensions Ugly Conversion of Initializers ------------------------------- The constructs disabled by `-fno-ugly-init' are: * Use of Hollerith and typeless constants in contexts where they set initial (compile-time) values for variables, arrays, and named constants--that is, `DATA' and `PARAMETER' statements, plus type-declaration statements specifying initial values. Here are some sample initializations that are disabled by the `-fno-ugly-init' option: PARAMETER (VAL='9A304FFE'X) REAL*8 STRING/8HOUTPUT00/ DATA VAR/4HABCD/ * In the same contexts as above, use of character constants to initialize numeric items and vice versa (one constant per item). Here are more sample initializations that are disabled by the `-fno-ugly-init' option: INTEGER IA CHARACTER BELL PARAMETER (IA = 'A') PARAMETER (BELL = 7) * Use of Hollerith and typeless constants on the right-hand side of assignment statements to numeric types, and in other contexts (such as passing arguments in invocations of intrinsic procedures and statement functions) that are treated as assignments to known types (the dummy arguments, in these cases). Here are sample statements that are disabled by the `-fno-ugly-init' option: IVAR = 4HABCD PRINT *, IMAX0(2HAB, 2HBA) The above constructs, when used, can tend to result in non-portable code. But, they are widely used in existing Fortran code in ways that often are quite portable. Therefore, they are enabled by default.  File: g77.info, Node: Ugly Integer Conversions, Next: Ugly Assigned Labels, Prev: Ugly Conversion of Initializers, Up: Distensions Ugly Integer Conversions ------------------------ The constructs enabled via `-fugly-logint' are: * Automatic conversion between `INTEGER' and `LOGICAL' as dictated by context (typically implies nonportable dependencies on how a particular implementation encodes `.TRUE.' and `.FALSE.'). * Use of a `LOGICAL' variable in `ASSIGN' and assigned-`GOTO' statements. The above constructs are disabled by default because use of them tends to lead to non-portable code. Even existing Fortran code that uses that often turns out to be non-portable, if not outright buggy. Some of this is due to differences among implementations as far as how `.TRUE.' and `.FALSE.' are encoded as `INTEGER' values--Fortran code that assumes a particular coding is likely to use one of the above constructs, and is also likely to not work correctly on implementations using different encodings. *Note Equivalence Versus Equality::, for more information.  File: g77.info, Node: Ugly Assigned Labels, Prev: Ugly Integer Conversions, Up: Distensions Ugly Assigned Labels -------------------- The `-fugly-assign' option forces `g77' to use the same storage for assigned labels as it would for a normal assignment to the same variable. For example, consider the following code fragment: I = 3 ASSIGN 10 TO I Normally, for portability and improved diagnostics, `g77' reserves distinct storage for a "sibling" of `I', used only for `ASSIGN' statements to that variable (along with the corresponding assigned-`GOTO' and assigned-`FORMAT'-I/O statements that reference the variable). However, some code (that violates the ANSI FORTRAN 77 standard) attempts to copy assigned labels among variables involved with `ASSIGN' statements, as in: ASSIGN 10 TO I ISTATE(5) = I ... J = ISTATE(ICUR) GOTO J Such code doesn't work under `g77' unless `-fugly-assign' is specified on the command-line, ensuring that the value of `I' referenced in the second line is whatever value `g77' uses to designate statement label `10', so the value may be copied into the `ISTATE' array, later retrieved into a variable of the appropriate type (`J'), and used as the target of an assigned-`GOTO' statement. _Note:_ To avoid subtle program bugs, when `-fugly-assign' is specified, `g77' requires the type of variables specified in assigned-label contexts _must_ be the same type returned by `%LOC()'. On many systems, this type is effectively the same as `INTEGER(KIND=1)', while, on others, it is effectively the same as `INTEGER(KIND=2)'. Do _not_ depend on `g77' actually writing valid pointers to these variables, however. While `g77' currently chooses that implementation, it might be changed in the future. *Note Assigned Statement Labels (ASSIGN and GOTO): Assigned Statement Labels, for implementation details on assigned-statement labels.  File: g77.info, Node: Compiler, Next: Other Dialects, Prev: Language, Up: Top The GNU Fortran Compiler ************************ The GNU Fortran compiler, `g77', supports programs written in the GNU Fortran language and in some other dialects of Fortran. Some aspects of how `g77' works are universal regardless of dialect, and yet are not properly part of the GNU Fortran language itself. These are described below. _Note: This portion of the documentation definitely needs a lot of work!_ * Menu: * Compiler Limits:: * Run-time Environment Limits:: * Compiler Types:: * Compiler Constants:: * Compiler Intrinsics::  File: g77.info, Node: Compiler Limits, Next: Run-time Environment Limits, Up: Compiler Compiler Limits =============== `g77', as with GNU tools in general, imposes few arbitrary restrictions on lengths of identifiers, number of continuation lines, number of external symbols in a program, and so on. For example, some other Fortran compiler have an option (such as `-NlX') to increase the limit on the number of continuation lines. Also, some Fortran compilation systems have an option (such as `-NxX') to increase the limit on the number of external symbols. `g77', `gcc', and GNU `ld' (the GNU linker) have no equivalent options, since they do not impose arbitrary limits in these areas. `g77' does currently limit the number of dimensions in an array to the same degree as do the Fortran standards--seven (7). This restriction might be lifted in a future version.  File: g77.info, Node: Run-time Environment Limits, Next: Compiler Types, Prev: Compiler Limits, Up: Compiler Run-time Environment Limits =========================== As a portable Fortran implementation, `g77' offers its users direct access to, and otherwise depends upon, the underlying facilities of the system used to build `g77', the system on which `g77' itself is used to compile programs, and the system on which the `g77'-compiled program is actually run. (For most users, the three systems are of the same type--combination of operating environment and hardware--often the same physical system.) The run-time environment for a particular system inevitably imposes some limits on a program's use of various system facilities. These limits vary from system to system. Even when such limits might be well beyond the possibility of being encountered on a particular system, the `g77' run-time environment has certain built-in limits, usually, but not always, stemming from intrinsics with inherently limited interfaces. Currently, the `g77' run-time environment does not generally offer a less-limiting environment by augmenting the underlying system's own environment. Therefore, code written in the GNU Fortran language, while syntactically and semantically portable, might nevertheless make non-portable assumptions about the run-time environment--assumptions that prove to be false for some particular environments. The GNU Fortran language, the `g77' compiler and run-time environment, and the `g77' documentation do not yet offer comprehensive portable work-arounds for such limits, though programmers should be able to find their own in specific instances. Not all of the limitations are described in this document. Some of the known limitations include: * Menu: * Timer Wraparounds:: * Year 2000 (Y2K) Problems:: * Array Size:: * Character-variable Length:: * Year 10000 (Y10K) Problems::  File: g77.info, Node: Timer Wraparounds, Next: Year 2000 (Y2K) Problems, Up: Run-time Environment Limits Timer Wraparounds ----------------- Intrinsics that return values computed from system timers, whether elapsed (wall-clock) timers, process CPU timers, or other kinds of timers, are prone to experiencing wrap-around errors (or returning wrapped-around values from successive calls) due to insufficient ranges offered by the underlying system's timers. Some of the symptoms of such behaviors include apparently negative time being computed for a duration, an extremely short amount of time being computed for a long duration, and an extremely long amount of time being computed for a short duration. See the following for intrinsics known to have potential problems in these areas on at least some systems: *Note CPU_Time Intrinsic::, *Note DTime Intrinsic (function)::, *Note DTime Intrinsic (subroutine)::, *Note ETime Intrinsic (function)::, *Note ETime Intrinsic (subroutine)::, *Note MClock Intrinsic::, *Note MClock8 Intrinsic::, *Note Secnds Intrinsic::, *Note Second Intrinsic (function)::, *Note Second Intrinsic (subroutine)::, *Note System_Clock Intrinsic::, *Note Time Intrinsic (UNIX)::, *Note Time Intrinsic (VXT)::, *Note Time8 Intrinsic::.  File: g77.info, Node: Year 2000 (Y2K) Problems, Next: Array Size, Prev: Timer Wraparounds, Up: Run-time Environment Limits Year 2000 (Y2K) Problems ------------------------ While the `g77' compiler itself is believed to be Year-2000 (Y2K) compliant, some intrinsics are not, and, potentially, some underlying systems are not, perhaps rendering some Y2K-compliant intrinsics non-compliant when used on those particular systems. Fortran code that uses non-Y2K-compliant intrinsics (listed below) is, itself, almost certainly not compliant, and should be modified to use Y2K-compliant intrinsics instead. Fortran code that uses no non-Y2K-compliant intrinsics, but which currently is running on a non-Y2K-compliant system, can be made more Y2K compliant by compiling and linking it for use on a new Y2K-compliant system, such as a new version of an old, non-Y2K-compliant, system. Currently, information on Y2K and related issues is being maintained at `http://www.gnu.org/software/year2000-list.html'. See the following for intrinsics known to have potential problems in these areas on at least some systems: *Note Date Intrinsic::, *Note IDate Intrinsic (VXT)::. The `libg2c' library shipped with any `g77' that warns about invocation of a non-Y2K-compliant intrinsic has renamed the `EXTERNAL' procedure names of those intrinsics. This is done so that the `libg2c' implementations of these intrinsics cannot be directly linked to as `EXTERNAL' names (which normally would avoid the non-Y2K-intrinsic warning). The renamed forms of the `EXTERNAL' names of these renamed procedures may be linked to by appending the string `_y2kbug' to the name of the procedure in the source code. For example: CHARACTER*20 STR INTEGER YY, MM, DD EXTERNAL DATE_Y2KBUG, VXTIDATE_Y2KBUG CALL DATE_Y2KBUG (STR) CALL VXTIDATE_Y2KBUG (MM, DD, YY) (Note that the `EXTERNAL' statement is not actually required, since the modified names are not recognized as intrinsics by the current version of `g77'. But it is shown in this specific case, for purposes of illustration.) The renaming of `EXTERNAL' procedure names of these intrinsics causes unresolved references at link time. For example, `EXTERNAL DATE; CALL DATE(STR)' is normally compiled by `g77' as, in C, `date_(&str, 20);'. This, in turn, links to the `date_' procedure in the `libE77' portion of `libg2c', which purposely calls a nonexistent procedure named `G77_date_y2kbuggy_0'. The resulting link-time error is designed, via this name, to encourage the programmer to look up the index entries to this portion of the `g77' documentation. Generally, we recommend that the `EXTERNAL' method of invoking procedures in `libg2c' _not_ be used. When used, some of the correctness checking normally performed by `g77' is skipped. In particular, it is probably better to use the `INTRINSIC' method of invoking non-Y2K-compliant procedures, so anyone compiling the code can quickly notice the potential Y2K problems (via the warnings printing by `g77') without having to even look at the code itself. If there are problems linking `libg2c' to code compiled by `g77' that involve the string `y2kbug', and these are not explained above, that probably indicates that a version of `libg2c' older than `g77' is being linked to, or that the new library is being linked to code compiled by an older version of `g77'. That's because, as of the version that warns about non-Y2K-compliant intrinsic invocation, `g77' references the `libg2c' implementations of those intrinsics using new names, containing the string `y2kbug'. So, linking newly-compiled code (invoking one of the intrinsics in question) to an old library might yield an unresolved reference to `G77_date_y2kbug_0'. (The old library calls it `G77_date_0'.) Similarly, linking previously-compiled code to a new library might yield an unresolved reference to `G77_vxtidate_0'. (The new library calls it `G77_vxtidate_y2kbug_0'.) The proper fix for the above problems is to obtain the latest release of `g77' and related products (including `libg2c') and install them on all systems, then recompile, relink, and install (as appropriate) all existing Fortran programs. (Normally, this sort of renaming is steadfastly avoided. In this case, however, it seems more important to highlight potential Y2K problems than to ease the transition of potentially non-Y2K-compliant code to new versions of `g77' and `libg2c'.)  File: g77.info, Node: Array Size, Next: Character-variable Length, Prev: Year 2000 (Y2K) Problems, Up: Run-time Environment Limits Array Size ---------- Currently, `g77' uses the default `INTEGER' type for array indexes, which limits the sizes of single-dimension arrays on systems offering a larger address space than can be addressed by that type. (That `g77' puts all arrays in memory could be considered another limitation--it could use large temporary files--but that decision is left to the programmer as an implementation choice by most Fortran implementations.) It is not yet clear whether this limitation never, sometimes, or always applies to the sizes of multiple-dimension arrays as a whole. For example, on a system with 64-bit addresses and 32-bit default `INTEGER', an array with a size greater than can be addressed by a 32-bit offset can be declared using multiple dimensions. Such an array is therefore larger than a single-dimension array can be, on the same system. Whether large multiple-dimension arrays are reliably supported depends mostly on the `gcc' back end (code generator) used by `g77', and has not yet been fully investigated.  File: g77.info, Node: Character-variable Length, Next: Year 10000 (Y10K) Problems, Prev: Array Size, Up: Run-time Environment Limits Character-variable Length ------------------------- Currently, `g77' uses the default `INTEGER' type for the lengths of `CHARACTER' variables and array elements. This means that, for example, a system with a 64-bit address space and a 32-bit default `INTEGER' type does not, under `g77', support a `CHARACTER*N' declaration where N is greater than 2147483647.  File: g77.info, Node: Year 10000 (Y10K) Problems, Prev: Character-variable Length, Up: Run-time Environment Limits Year 10000 (Y10K) Problems -------------------------- Most intrinsics returning, or computing values based on, date information are prone to Year-10000 (Y10K) problems, due to supporting only 4 digits for the year. See the following for examples: *Note FDate Intrinsic (function)::, *Note FDate Intrinsic (subroutine)::, *Note IDate Intrinsic (UNIX)::, *Note Time Intrinsic (VXT)::, *Note Date_and_Time Intrinsic::.  File: g77.info, Node: Compiler Types, Next: Compiler Constants, Prev: Run-time Environment Limits, Up: Compiler Compiler Types ============== Fortran implementations have a fair amount of freedom given them by the standard as far as how much storage space is used and how much precision and range is offered by the various types such as `LOGICAL(KIND=1)', `INTEGER(KIND=1)', `REAL(KIND=1)', `REAL(KIND=2)', `COMPLEX(KIND=1)', and `CHARACTER'. Further, many compilers offer so-called `*N' notation, but the interpretation of N varies across compilers and target architectures. The standard requires that `LOGICAL(KIND=1)', `INTEGER(KIND=1)', and `REAL(KIND=1)' occupy the same amount of storage space, and that `COMPLEX(KIND=1)' and `REAL(KIND=2)' take twice as much storage space as `REAL(KIND=1)'. Further, it requires that `COMPLEX(KIND=1)' entities be ordered such that when a `COMPLEX(KIND=1)' variable is storage-associated (such as via `EQUIVALENCE') with a two-element `REAL(KIND=1)' array named `R', `R(1)' corresponds to the real element and `R(2)' to the imaginary element of the `COMPLEX(KIND=1)' variable. (Few requirements as to precision or ranges of any of these are placed on the implementation, nor is the relationship of storage sizes of these types to the `CHARACTER' type specified, by the standard.) `g77' follows the above requirements, warning when compiling a program requires placement of items in memory that contradict the requirements of the target architecture. (For example, a program can require placement of a `REAL(KIND=2)' on a boundary that is not an even multiple of its size, but still an even multiple of the size of a `REAL(KIND=1)' variable. On some target architectures, using the canonical mapping of Fortran types to underlying architectural types, such placement is prohibited by the machine definition or the Application Binary Interface (ABI) in force for the configuration defined for building `gcc' and `g77'. `g77' warns about such situations when it encounters them.) `g77' follows consistent rules for configuring the mapping between Fortran types, including the `*N' notation, and the underlying architectural types as accessed by a similarly-configured applicable version of the `gcc' compiler. These rules offer a widely portable, consistent Fortran/C environment, although they might well conflict with the expectations of users of Fortran compilers designed and written for particular architectures. These rules are based on the configuration that is in force for the version of `gcc' built in the same release as `g77' (and which was therefore used to build both the `g77' compiler components and the `libg2c' run-time library): `REAL(KIND=1)' Same as `float' type. `REAL(KIND=2)' Same as whatever floating-point type that is twice the size of a `float'--usually, this is a `double'. `INTEGER(KIND=1)' Same as an integral type that is occupies the same amount of memory storage as `float'--usually, this is either an `int' or a `long int'. `LOGICAL(KIND=1)' Same `gcc' type as `INTEGER(KIND=1)'. `INTEGER(KIND=2)' Twice the size, and usually nearly twice the range, as `INTEGER(KIND=1)'--usually, this is either a `long int' or a `long long int'. `LOGICAL(KIND=2)' Same `gcc' type as `INTEGER(KIND=2)'. `INTEGER(KIND=3)' Same `gcc' type as signed `char'. `LOGICAL(KIND=3)' Same `gcc' type as `INTEGER(KIND=3)'. `INTEGER(KIND=6)' Twice the size, and usually nearly twice the range, as `INTEGER(KIND=3)'--usually, this is a `short'. `LOGICAL(KIND=6)' Same `gcc' type as `INTEGER(KIND=6)'. `COMPLEX(KIND=1)' Two `REAL(KIND=1)' scalars (one for the real part followed by one for the imaginary part). `COMPLEX(KIND=2)' Two `REAL(KIND=2)' scalars. `NUMERIC-TYPE*N' (Where NUMERIC-TYPE is any type other than `CHARACTER'.) Same as whatever `gcc' type occupies N times the storage space of a `gcc' `char' item. `DOUBLE PRECISION' Same as `REAL(KIND=2)'. `DOUBLE COMPLEX' Same as `COMPLEX(KIND=2)'. Note that the above are proposed correspondences and might change in future versions of `g77'--avoid writing code depending on them. Other types supported by `g77' are derived from gcc types such as `char', `short', `int', `long int', `long long int', `long double', and so on. That is, whatever types `gcc' already supports, `g77' supports now or probably will support in a future version. The rules for the `NUMERIC-TYPE*N' notation apply to these types, and new values for `NUMERIC-TYPE(KIND=N)' will be assigned in a way that encourages clarity, consistency, and portability.  File: g77.info, Node: Compiler Constants, Next: Compiler Intrinsics, Prev: Compiler Types, Up: Compiler Compiler Constants ================== `g77' strictly assigns types to _all_ constants not documented as "typeless" (typeless constants including `'1'Z', for example). Many other Fortran compilers attempt to assign types to typed constants based on their context. This results in hard-to-find bugs, nonportable code, and is not in the spirit (though it strictly follows the letter) of the 77 and 90 standards. `g77' might offer, in a future release, explicit constructs by which a wider variety of typeless constants may be specified, and/or user-requested warnings indicating places where `g77' might differ from how other compilers assign types to constants. *Note Context-Sensitive Constants::, for more information on this issue.  File: g77.info, Node: Compiler Intrinsics, Prev: Compiler Constants, Up: Compiler Compiler Intrinsics =================== `g77' offers an ever-widening set of intrinsics. Currently these all are procedures (functions and subroutines). Some of these intrinsics are unimplemented, but their names reserved to reduce future problems with existing code as they are implemented. Others are implemented as part of the GNU Fortran language, while yet others are provided for compatibility with other dialects of Fortran but are not part of the GNU Fortran language. To manage these distinctions, `g77' provides intrinsic _groups_, a facility that is simply an extension of the intrinsic groups provided by the GNU Fortran language. * Menu: * Intrinsic Groups:: How intrinsics are grouped for easy management. * Other Intrinsics:: Intrinsics other than those in the GNU Fortran language.  File: g77.info, Node: Intrinsic Groups, Next: Other Intrinsics, Up: Compiler Intrinsics Intrinsic Groups ---------------- A given specific intrinsic belongs in one or more groups. Each group is deleted, disabled, hidden, or enabled by default or a command-line option. The meaning of each term follows. Deleted No intrinsics are recognized as belonging to that group. Disabled Intrinsics are recognized as belonging to the group, but references to them (other than via the `INTRINSIC' statement) are disallowed through that group. Hidden Intrinsics in that group are recognized and enabled (if implemented) _only_ if the first mention of the actual name of an intrinsic in a program unit is in an `INTRINSIC' statement. Enabled Intrinsics in that group are recognized and enabled (if implemented). The distinction between deleting and disabling a group is illustrated by the following example. Assume intrinsic `FOO' belongs only to group `FGR'. If group `FGR' is deleted, the following program unit will successfully compile, because `FOO()' will be seen as a reference to an external function named `FOO': PRINT *, FOO() END If group `FGR' is disabled, compiling the above program will produce diagnostics, either because the `FOO' intrinsic is improperly invoked or, if properly invoked, it is not enabled. To change the above program so it references an external function `FOO' instead of the disabled `FOO' intrinsic, add the following line to the top: EXTERNAL FOO So, deleting a group tells `g77' to pretend as though the intrinsics in that group do not exist at all, whereas disabling it tells `g77' to recognize them as (disabled) intrinsics in intrinsic-like contexts. Hiding a group is like enabling it, but the intrinsic must be first named in an `INTRINSIC' statement to be considered a reference to the intrinsic rather than to an external procedure. This might be the "safest" way to treat a new group of intrinsics when compiling old code, because it allows the old code to be generally written as if those new intrinsics never existed, but to be changed to use them by inserting `INTRINSIC' statements in the appropriate places. However, it should be the goal of development to use `EXTERNAL' for all names of external procedures that might be intrinsic names. If an intrinsic is in more than one group, it is enabled if any of its containing groups are enabled; if not so enabled, it is hidden if any of its containing groups are hidden; if not so hidden, it is disabled if any of its containing groups are disabled; if not so disabled, it is deleted. This extra complication is necessary because some intrinsics, such as `IBITS', belong to more than one group, and hence should be enabled if any of the groups to which they belong are enabled, and so on. The groups are: `badu77' UNIX intrinsics having inappropriate forms (usually functions that have intended side effects). `gnu' Intrinsics the GNU Fortran language supports that are extensions to the Fortran standards (77 and 90). `f2c' Intrinsics supported by AT&T's `f2c' converter and/or `libf2c'. `f90' Fortran 90 intrinsics. `mil' MIL-STD 1753 intrinsics (`MVBITS', `IAND', `BTEST', and so on). `unix' UNIX intrinsics (`IARGC', `EXIT', `ERF', and so on). `vxt' VAX/VMS FORTRAN (current as of v4) intrinsics.  File: g77.info, Node: Other Intrinsics, Prev: Intrinsic Groups, Up: Compiler Intrinsics Other Intrinsics ---------------- `g77' supports intrinsics other than those in the GNU Fortran language proper. This set of intrinsics is described below. (Note that the empty lines appearing in the menu below are not intentional--they result from a bug in the `makeinfo' program.) * Menu: * ACosD Intrinsic:: (Reserved for future use.) * AIMax0 Intrinsic:: (Reserved for future use.) * AIMin0 Intrinsic:: (Reserved for future use.) * AJMax0 Intrinsic:: (Reserved for future use.) * AJMin0 Intrinsic:: (Reserved for future use.) * ASinD Intrinsic:: (Reserved for future use.) * ATan2D Intrinsic:: (Reserved for future use.) * ATanD Intrinsic:: (Reserved for future use.) * BITest Intrinsic:: (Reserved for future use.) * BJTest Intrinsic:: (Reserved for future use.) * CDAbs Intrinsic:: Absolute value (archaic). * CDCos Intrinsic:: Cosine (archaic). * CDExp Intrinsic:: Exponential (archaic). * CDLog Intrinsic:: Natural logarithm (archaic). * CDSin Intrinsic:: Sine (archaic). * CDSqRt Intrinsic:: Square root (archaic). * ChDir Intrinsic (function):: Change directory. * ChMod Intrinsic (function):: Change file modes. * CosD Intrinsic:: (Reserved for future use.) * DACosD Intrinsic:: (Reserved for future use.) * DASinD Intrinsic:: (Reserved for future use.) * DATan2D Intrinsic:: (Reserved for future use.) * DATanD Intrinsic:: (Reserved for future use.) * Date Intrinsic:: Get current date as dd-Mon-yy. * DbleQ Intrinsic:: (Reserved for future use.) * DCmplx Intrinsic:: Construct `COMPLEX(KIND=2)' value. * DConjg Intrinsic:: Complex conjugate (archaic). * DCosD Intrinsic:: (Reserved for future use.) * DFloat Intrinsic:: Conversion (archaic). * DFlotI Intrinsic:: (Reserved for future use.) * DFlotJ Intrinsic:: (Reserved for future use.) * DImag Intrinsic:: Convert/extract imaginary part of complex (archaic). * DReal Intrinsic:: Convert value to type `REAL(KIND=2)'. * DSinD Intrinsic:: (Reserved for future use.) * DTanD Intrinsic:: (Reserved for future use.) * DTime Intrinsic (function):: Get elapsed time since last time. * FGet Intrinsic (function):: Read a character from unit 5 stream-wise. * FGetC Intrinsic (function):: Read a character stream-wise. * FloatI Intrinsic:: (Reserved for future use.) * FloatJ Intrinsic:: (Reserved for future use.) * FPut Intrinsic (function):: Write a character to unit 6 stream-wise. * FPutC Intrinsic (function):: Write a character stream-wise. * IDate Intrinsic (VXT):: Get local time info (VAX/VMS). * IIAbs Intrinsic:: (Reserved for future use.) * IIAnd Intrinsic:: (Reserved for future use.) * IIBClr Intrinsic:: (Reserved for future use.) * IIBits Intrinsic:: (Reserved for future use.) * IIBSet Intrinsic:: (Reserved for future use.) * IIDiM Intrinsic:: (Reserved for future use.) * IIDInt Intrinsic:: (Reserved for future use.) * IIDNnt Intrinsic:: (Reserved for future use.) * IIEOr Intrinsic:: (Reserved for future use.) * IIFix Intrinsic:: (Reserved for future use.) * IInt Intrinsic:: (Reserved for future use.) * IIOr Intrinsic:: (Reserved for future use.) * IIQint Intrinsic:: (Reserved for future use.) * IIQNnt Intrinsic:: (Reserved for future use.) * IIShftC Intrinsic:: (Reserved for future use.) * IISign Intrinsic:: (Reserved for future use.) * IMax0 Intrinsic:: (Reserved for future use.) * IMax1 Intrinsic:: (Reserved for future use.) * IMin0 Intrinsic:: (Reserved for future use.) * IMin1 Intrinsic:: (Reserved for future use.) * IMod Intrinsic:: (Reserved for future use.) * INInt Intrinsic:: (Reserved for future use.) * INot Intrinsic:: (Reserved for future use.) * IZExt Intrinsic:: (Reserved for future use.) * JIAbs Intrinsic:: (Reserved for future use.) * JIAnd Intrinsic:: (Reserved for future use.) * JIBClr Intrinsic:: (Reserved for future use.) * JIBits Intrinsic:: (Reserved for future use.) * JIBSet Intrinsic:: (Reserved for future use.) * JIDiM Intrinsic:: (Reserved for future use.) * JIDInt Intrinsic:: (Reserved for future use.) * JIDNnt Intrinsic:: (Reserved for future use.) * JIEOr Intrinsic:: (Reserved for future use.) * JIFix Intrinsic:: (Reserved for future use.) * JInt Intrinsic:: (Reserved for future use.) * JIOr Intrinsic:: (Reserved for future use.) * JIQint Intrinsic:: (Reserved for future use.) * JIQNnt Intrinsic:: (Reserved for future use.) * JIShft Intrinsic:: (Reserved for future use.) * JIShftC Intrinsic:: (Reserved for future use.) * JISign Intrinsic:: (Reserved for future use.) * JMax0 Intrinsic:: (Reserved for future use.) * JMax1 Intrinsic:: (Reserved for future use.) * JMin0 Intrinsic:: (Reserved for future use.) * JMin1 Intrinsic:: (Reserved for future use.) * JMod Intrinsic:: (Reserved for future use.) * JNInt Intrinsic:: (Reserved for future use.) * JNot Intrinsic:: (Reserved for future use.) * JZExt Intrinsic:: (Reserved for future use.) * Kill Intrinsic (function):: Signal a process. * Link Intrinsic (function):: Make hard link in file system. * QAbs Intrinsic:: (Reserved for future use.) * QACos Intrinsic:: (Reserved for future use.) * QACosD Intrinsic:: (Reserved for future use.) * QASin Intrinsic:: (Reserved for future use.) * QASinD Intrinsic:: (Reserved for future use.) * QATan Intrinsic:: (Reserved for future use.) * QATan2 Intrinsic:: (Reserved for future use.) * QATan2D Intrinsic:: (Reserved for future use.) * QATanD Intrinsic:: (Reserved for future use.) * QCos Intrinsic:: (Reserved for future use.) * QCosD Intrinsic:: (Reserved for future use.) * QCosH Intrinsic:: (Reserved for future use.) * QDiM Intrinsic:: (Reserved for future use.) * QExp Intrinsic:: (Reserved for future use.) * QExt Intrinsic:: (Reserved for future use.) * QExtD Intrinsic:: (Reserved for future use.) * QFloat Intrinsic:: (Reserved for future use.) * QInt Intrinsic:: (Reserved for future use.) * QLog Intrinsic:: (Reserved for future use.) * QLog10 Intrinsic:: (Reserved for future use.) * QMax1 Intrinsic:: (Reserved for future use.) * QMin1 Intrinsic:: (Reserved for future use.) * QMod Intrinsic:: (Reserved for future use.) * QNInt Intrinsic:: (Reserved for future use.) * QSin Intrinsic:: (Reserved for future use.) * QSinD Intrinsic:: (Reserved for future use.) * QSinH Intrinsic:: (Reserved for future use.) * QSqRt Intrinsic:: (Reserved for future use.) * QTan Intrinsic:: (Reserved for future use.) * QTanD Intrinsic:: (Reserved for future use.) * QTanH Intrinsic:: (Reserved for future use.) * Rename Intrinsic (function):: Rename file. * Secnds Intrinsic:: Get local time offset since midnight. * Signal Intrinsic (function):: Muck with signal handling. * SinD Intrinsic:: (Reserved for future use.) * SnglQ Intrinsic:: (Reserved for future use.) * SymLnk Intrinsic (function):: Make symbolic link in file system. * System Intrinsic (function):: Invoke shell (system) command. * TanD Intrinsic:: (Reserved for future use.) * Time Intrinsic (VXT):: Get the time as a character value. * UMask Intrinsic (function):: Set file creation permissions mask. * Unlink Intrinsic (function):: Unlink file. * ZExt Intrinsic:: (Reserved for future use.)  File: g77.info, Node: ACosD Intrinsic, Next: AIMax0 Intrinsic, Up: Other Intrinsics ACosD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL ACosD' to use this name for an external procedure.  File: g77.info, Node: AIMax0 Intrinsic, Next: AIMin0 Intrinsic, Prev: ACosD Intrinsic, Up: Other Intrinsics AIMax0 Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL AIMax0' to use this name for an external procedure.  File: g77.info, Node: AIMin0 Intrinsic, Next: AJMax0 Intrinsic, Prev: AIMax0 Intrinsic, Up: Other Intrinsics AIMin0 Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL AIMin0' to use this name for an external procedure.  File: g77.info, Node: AJMax0 Intrinsic, Next: AJMin0 Intrinsic, Prev: AIMin0 Intrinsic, Up: Other Intrinsics AJMax0 Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL AJMax0' to use this name for an external procedure.  File: g77.info, Node: AJMin0 Intrinsic, Next: ASinD Intrinsic, Prev: AJMax0 Intrinsic, Up: Other Intrinsics AJMin0 Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL AJMin0' to use this name for an external procedure.  File: g77.info, Node: ASinD Intrinsic, Next: ATan2D Intrinsic, Prev: AJMin0 Intrinsic, Up: Other Intrinsics ASinD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL ASinD' to use this name for an external procedure.  File: g77.info, Node: ATan2D Intrinsic, Next: ATanD Intrinsic, Prev: ASinD Intrinsic, Up: Other Intrinsics ATan2D Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL ATan2D' to use this name for an external procedure.  File: g77.info, Node: ATanD Intrinsic, Next: BITest Intrinsic, Prev: ATan2D Intrinsic, Up: Other Intrinsics ATanD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL ATanD' to use this name for an external procedure.  File: g77.info, Node: BITest Intrinsic, Next: BJTest Intrinsic, Prev: ATanD Intrinsic, Up: Other Intrinsics BITest Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL BITest' to use this name for an external procedure.  File: g77.info, Node: BJTest Intrinsic, Next: CDAbs Intrinsic, Prev: BITest Intrinsic, Up: Other Intrinsics BJTest Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL BJTest' to use this name for an external procedure.  File: g77.info, Node: CDAbs Intrinsic, Next: CDCos Intrinsic, Prev: BJTest Intrinsic, Up: Other Intrinsics CDAbs Intrinsic ............... CDAbs(A) CDAbs: `REAL(KIND=2)' function. A: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `ABS()' that is specific to one type for A. *Note Abs Intrinsic::.  File: g77.info, Node: CDCos Intrinsic, Next: CDExp Intrinsic, Prev: CDAbs Intrinsic, Up: Other Intrinsics CDCos Intrinsic ............... CDCos(X) CDCos: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `COS()' that is specific to one type for X. *Note Cos Intrinsic::.  File: g77.info, Node: CDExp Intrinsic, Next: CDLog Intrinsic, Prev: CDCos Intrinsic, Up: Other Intrinsics CDExp Intrinsic ............... CDExp(X) CDExp: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `EXP()' that is specific to one type for X. *Note Exp Intrinsic::.  File: g77.info, Node: CDLog Intrinsic, Next: CDSin Intrinsic, Prev: CDExp Intrinsic, Up: Other Intrinsics CDLog Intrinsic ............... CDLog(X) CDLog: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `LOG()' that is specific to one type for X. *Note Log Intrinsic::.  File: g77.info, Node: CDSin Intrinsic, Next: CDSqRt Intrinsic, Prev: CDLog Intrinsic, Up: Other Intrinsics CDSin Intrinsic ............... CDSin(X) CDSin: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `SIN()' that is specific to one type for X. *Note Sin Intrinsic::.  File: g77.info, Node: CDSqRt Intrinsic, Next: ChDir Intrinsic (function), Prev: CDSin Intrinsic, Up: Other Intrinsics CDSqRt Intrinsic ................ CDSqRt(X) CDSqRt: `COMPLEX(KIND=2)' function. X: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `SQRT()' that is specific to one type for X. *Note SqRt Intrinsic::.  File: g77.info, Node: ChDir Intrinsic (function), Next: ChMod Intrinsic (function), Prev: CDSqRt Intrinsic, Up: Other Intrinsics ChDir Intrinsic (function) .......................... ChDir(DIR) ChDir: `INTEGER(KIND=1)' function. DIR: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Sets the current working directory to be DIR. Returns 0 on success or a nonzero error code. See `chdir(3)'. _Caution:_ Using this routine during I/O to a unit connected with a non-absolute file name can cause subsequent I/O on such a unit to fail because the I/O library might reopen files by name. Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note ChDir Intrinsic (subroutine)::.  File: g77.info, Node: ChMod Intrinsic (function), Next: CosD Intrinsic, Prev: ChDir Intrinsic (function), Up: Other Intrinsics ChMod Intrinsic (function) .......................... ChMod(NAME, MODE) ChMod: `INTEGER(KIND=1)' function. NAME: `CHARACTER'; scalar; INTENT(IN). MODE: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Changes the access mode of file NAME according to the specification MODE, which is given in the format of `chmod(1)'. A null character (`CHAR(0)') marks the end of the name in NAME--otherwise, trailing blanks in NAME are ignored. Currently, NAME must not contain the single quote character. Returns 0 on success or a nonzero error code otherwise. Note that this currently works by actually invoking `/bin/chmod' (or the `chmod' found when the library was configured) and so might fail in some circumstances and will, anyway, be slow. Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note ChMod Intrinsic (subroutine)::.  File: g77.info, Node: CosD Intrinsic, Next: DACosD Intrinsic, Prev: ChMod Intrinsic (function), Up: Other Intrinsics CosD Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL CosD' to use this name for an external procedure.  File: g77.info, Node: DACosD Intrinsic, Next: DASinD Intrinsic, Prev: CosD Intrinsic, Up: Other Intrinsics DACosD Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DACosD' to use this name for an external procedure.  File: g77.info, Node: DASinD Intrinsic, Next: DATan2D Intrinsic, Prev: DACosD Intrinsic, Up: Other Intrinsics DASinD Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DASinD' to use this name for an external procedure.  File: g77.info, Node: DATan2D Intrinsic, Next: DATanD Intrinsic, Prev: DASinD Intrinsic, Up: Other Intrinsics DATan2D Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DATan2D' to use this name for an external procedure.  File: g77.info, Node: DATanD Intrinsic, Next: Date Intrinsic, Prev: DATan2D Intrinsic, Up: Other Intrinsics DATanD Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DATanD' to use this name for an external procedure.  File: g77.info, Node: Date Intrinsic, Next: DbleQ Intrinsic, Prev: DATanD Intrinsic, Up: Other Intrinsics Date Intrinsic .............. CALL Date(DATE) DATE: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `vxt'. Description: Returns DATE in the form `DD-MMM-YY', representing the numeric day of the month DD, a three-character abbreviation of the month name MMM and the last two digits of the year YY, e.g. `25-Nov-96'. This intrinsic is not recommended, due to the year 2000 approaching. Therefore, programs making use of this intrinsic might not be Year 2000 (Y2K) compliant. *Note CTime Intrinsic (subroutine)::, for information on obtaining more digits for the current (or any) date.  File: g77.info, Node: DbleQ Intrinsic, Next: DCmplx Intrinsic, Prev: Date Intrinsic, Up: Other Intrinsics DbleQ Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DbleQ' to use this name for an external procedure.  File: g77.info, Node: DCmplx Intrinsic, Next: DConjg Intrinsic, Prev: DbleQ Intrinsic, Up: Other Intrinsics DCmplx Intrinsic ................ DCmplx(X, Y) DCmplx: `COMPLEX(KIND=2)' function. X: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Y: `INTEGER' or `REAL'; OPTIONAL (must be omitted if X is `COMPLEX'); scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: If X is not type `COMPLEX', constructs a value of type `COMPLEX(KIND=2)' from the real and imaginary values specified by X and Y, respectively. If Y is omitted, `0D0' is assumed. If X is type `COMPLEX', converts it to type `COMPLEX(KIND=2)'. Although this intrinsic is not standard Fortran, it is a popular extension offered by many compilers that support `DOUBLE COMPLEX', since it offers the easiest way to convert to `DOUBLE COMPLEX' without using Fortran 90 features (such as the `KIND=' argument to the `CMPLX()' intrinsic). (`CMPLX(0D0, 0D0)' returns a single-precision `COMPLEX' result, as required by standard FORTRAN 77. That's why so many compilers provide `DCMPLX()', since `DCMPLX(0D0, 0D0)' returns a `DOUBLE COMPLEX' result. Still, `DCMPLX()' converts even `REAL*16' arguments to their `REAL*8' equivalents in most dialects of Fortran, so neither it nor `CMPLX()' allow easy construction of arbitrary-precision values without potentially forcing a conversion involving extending or reducing precision. GNU Fortran provides such an intrinsic, called `COMPLEX()'.) *Note Complex Intrinsic::, for information on easily constructing a `COMPLEX' value of arbitrary precision from `REAL' arguments.  File: g77.info, Node: DConjg Intrinsic, Next: DCosD Intrinsic, Prev: DCmplx Intrinsic, Up: Other Intrinsics DConjg Intrinsic ................ DConjg(Z) DConjg: `COMPLEX(KIND=2)' function. Z: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `CONJG()' that is specific to one type for Z. *Note Conjg Intrinsic::.  File: g77.info, Node: DCosD Intrinsic, Next: DFloat Intrinsic, Prev: DConjg Intrinsic, Up: Other Intrinsics DCosD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DCosD' to use this name for an external procedure.  File: g77.info, Node: DFloat Intrinsic, Next: DFlotI Intrinsic, Prev: DCosD Intrinsic, Up: Other Intrinsics DFloat Intrinsic ................ DFloat(A) DFloat: `REAL(KIND=2)' function. A: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `REAL()' that is specific to one type for A. *Note Real Intrinsic::.  File: g77.info, Node: DFlotI Intrinsic, Next: DFlotJ Intrinsic, Prev: DFloat Intrinsic, Up: Other Intrinsics DFlotI Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DFlotI' to use this name for an external procedure.  File: g77.info, Node: DFlotJ Intrinsic, Next: DImag Intrinsic, Prev: DFlotI Intrinsic, Up: Other Intrinsics DFlotJ Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DFlotJ' to use this name for an external procedure.  File: g77.info, Node: DImag Intrinsic, Next: DReal Intrinsic, Prev: DFlotJ Intrinsic, Up: Other Intrinsics DImag Intrinsic ............... DImag(Z) DImag: `REAL(KIND=2)' function. Z: `COMPLEX(KIND=2)'; scalar; INTENT(IN). Intrinsic groups: `f2c', `vxt'. Description: Archaic form of `AIMAG()' that is specific to one type for Z. *Note AImag Intrinsic::.  File: g77.info, Node: DReal Intrinsic, Next: DSinD Intrinsic, Prev: DImag Intrinsic, Up: Other Intrinsics DReal Intrinsic ............... DReal(A) DReal: `REAL(KIND=2)' function. A: `INTEGER', `REAL', or `COMPLEX'; scalar; INTENT(IN). Intrinsic groups: `vxt'. Description: Converts A to `REAL(KIND=2)'. If A is type `COMPLEX', its real part is converted (if necessary) to `REAL(KIND=2)', and its imaginary part is disregarded. Although this intrinsic is not standard Fortran, it is a popular extension offered by many compilers that support `DOUBLE COMPLEX', since it offers the easiest way to extract the real part of a `DOUBLE COMPLEX' value without using the Fortran 90 `REAL()' intrinsic in a way that produces a return value inconsistent with the way many FORTRAN 77 compilers handle `REAL()' of a `DOUBLE COMPLEX' value. *Note RealPart Intrinsic::, for information on a GNU Fortran intrinsic that avoids these areas of confusion. *Note Dble Intrinsic::, for information on the standard FORTRAN 77 replacement for `DREAL()'. *Note REAL() and AIMAG() of Complex::, for more information on this issue.  File: g77.info, Node: DSinD Intrinsic, Next: DTanD Intrinsic, Prev: DReal Intrinsic, Up: Other Intrinsics DSinD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DSinD' to use this name for an external procedure.  File: g77.info, Node: DTanD Intrinsic, Next: DTime Intrinsic (function), Prev: DSinD Intrinsic, Up: Other Intrinsics DTanD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL DTanD' to use this name for an external procedure.  File: g77.info, Node: DTime Intrinsic (function), Next: FGet Intrinsic (function), Prev: DTanD Intrinsic, Up: Other Intrinsics DTime Intrinsic (function) .......................... DTime(TARRAY) DTime: `REAL(KIND=1)' function. TARRAY: `REAL(KIND=1)'; DIMENSION(2); INTENT(OUT). Intrinsic groups: `badu77'. Description: Initially, return the number of seconds of runtime since the start of the process's execution as the function value, and the user and system components of this in `TARRAY(1)' and `TARRAY(2)' respectively. The functions' value is equal to `TARRAY(1) + TARRAY(2)'. Subsequent invocations of `DTIME()' return values accumulated since the previous invocation. On some systems, the underlying timings are represented using types with sufficiently small limits that overflows (wraparounds) are possible, such as 32-bit types. Therefore, the values returned by this intrinsic might be, or become, negative, or numerically less than previous values, during a single run of the compiled program. Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note DTime Intrinsic (subroutine)::.  File: g77.info, Node: FGet Intrinsic (function), Next: FGetC Intrinsic (function), Prev: DTime Intrinsic (function), Up: Other Intrinsics FGet Intrinsic (function) ......................... FGet(C) FGet: `INTEGER(KIND=1)' function. C: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `badu77'. Description: Reads a single character into C in stream mode from unit 5 (by-passing normal formatted input) using `getc(3)'. Returns 0 on success, -1 on end-of-file, and the error code from `ferror(3)' otherwise. Stream I/O should not be mixed with normal record-oriented (formatted or unformatted) I/O on the same unit; the results are unpredictable. For information on other intrinsics with the same name: *Note FGet Intrinsic (subroutine)::.  File: g77.info, Node: FGetC Intrinsic (function), Next: FloatI Intrinsic, Prev: FGet Intrinsic (function), Up: Other Intrinsics FGetC Intrinsic (function) .......................... FGetC(UNIT, C) FGetC: `INTEGER(KIND=1)' function. UNIT: `INTEGER'; scalar; INTENT(IN). C: `CHARACTER'; scalar; INTENT(OUT). Intrinsic groups: `badu77'. Description: Reads a single character into C in stream mode from unit UNIT (by-passing normal formatted output) using `getc(3)'. Returns 0 on success, -1 on end-of-file, and the error code from `ferror(3)' otherwise. Stream I/O should not be mixed with normal record-oriented (formatted or unformatted) I/O on the same unit; the results are unpredictable. For information on other intrinsics with the same name: *Note FGetC Intrinsic (subroutine)::.  File: g77.info, Node: FloatI Intrinsic, Next: FloatJ Intrinsic, Prev: FGetC Intrinsic (function), Up: Other Intrinsics FloatI Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL FloatI' to use this name for an external procedure.  File: g77.info, Node: FloatJ Intrinsic, Next: FPut Intrinsic (function), Prev: FloatI Intrinsic, Up: Other Intrinsics FloatJ Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL FloatJ' to use this name for an external procedure.  File: g77.info, Node: FPut Intrinsic (function), Next: FPutC Intrinsic (function), Prev: FloatJ Intrinsic, Up: Other Intrinsics FPut Intrinsic (function) ......................... FPut(C) FPut: `INTEGER(KIND=1)' function. C: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Writes the single character C in stream mode to unit 6 (by-passing normal formatted output) using `getc(3)'. Returns 0 on success, the error code from `ferror(3)' otherwise. Stream I/O should not be mixed with normal record-oriented (formatted or unformatted) I/O on the same unit; the results are unpredictable. For information on other intrinsics with the same name: *Note FPut Intrinsic (subroutine)::.  File: g77.info, Node: FPutC Intrinsic (function), Next: IDate Intrinsic (VXT), Prev: FPut Intrinsic (function), Up: Other Intrinsics FPutC Intrinsic (function) .......................... FPutC(UNIT, C) FPutC: `INTEGER(KIND=1)' function. UNIT: `INTEGER'; scalar; INTENT(IN). C: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Writes the single character C in stream mode to unit UNIT (by-passing normal formatted output) using `putc(3)'. Returns 0 on success, the error code from `ferror(3)' otherwise. Stream I/O should not be mixed with normal record-oriented (formatted or unformatted) I/O on the same unit; the results are unpredictable. For information on other intrinsics with the same name: *Note FPutC Intrinsic (subroutine)::.  File: g77.info, Node: IDate Intrinsic (VXT), Next: IIAbs Intrinsic, Prev: FPutC Intrinsic (function), Up: Other Intrinsics IDate Intrinsic (VXT) ..................... CALL IDate(M, D, Y) M: `INTEGER(KIND=1)'; scalar; INTENT(OUT). D: `INTEGER(KIND=1)'; scalar; INTENT(OUT). Y: `INTEGER(KIND=1)'; scalar; INTENT(OUT). Intrinsic groups: `vxt'. Description: Returns the numerical values of the current local time. The month (in the range 1-12) is returned in M, the day (in the range 1-31) in D, and the year in Y (in the range 0-99). This intrinsic is not recommended, due to the fact that its return value for year wraps around century boundaries (change from a larger value to a smaller one). Therefore, programs making use of this intrinsic, for instance, might not be Year 2000 (Y2K) compliant. For example, the date might appear, to such programs, to wrap around as of the Year 2000. *Note IDate Intrinsic (UNIX)::, for information on obtaining more digits for the current date. For information on other intrinsics with the same name: *Note IDate Intrinsic (UNIX)::.  File: g77.info, Node: IIAbs Intrinsic, Next: IIAnd Intrinsic, Prev: IDate Intrinsic (VXT), Up: Other Intrinsics IIAbs Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIAbs' to use this name for an external procedure.  File: g77.info, Node: IIAnd Intrinsic, Next: IIBClr Intrinsic, Prev: IIAbs Intrinsic, Up: Other Intrinsics IIAnd Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIAnd' to use this name for an external procedure.  File: g77.info, Node: IIBClr Intrinsic, Next: IIBits Intrinsic, Prev: IIAnd Intrinsic, Up: Other Intrinsics IIBClr Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIBClr' to use this name for an external procedure.  File: g77.info, Node: IIBits Intrinsic, Next: IIBSet Intrinsic, Prev: IIBClr Intrinsic, Up: Other Intrinsics IIBits Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIBits' to use this name for an external procedure.  File: g77.info, Node: IIBSet Intrinsic, Next: IIDiM Intrinsic, Prev: IIBits Intrinsic, Up: Other Intrinsics IIBSet Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIBSet' to use this name for an external procedure.  File: g77.info, Node: IIDiM Intrinsic, Next: IIDInt Intrinsic, Prev: IIBSet Intrinsic, Up: Other Intrinsics IIDiM Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIDiM' to use this name for an external procedure.  File: g77.info, Node: IIDInt Intrinsic, Next: IIDNnt Intrinsic, Prev: IIDiM Intrinsic, Up: Other Intrinsics IIDInt Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIDInt' to use this name for an external procedure.  File: g77.info, Node: IIDNnt Intrinsic, Next: IIEOr Intrinsic, Prev: IIDInt Intrinsic, Up: Other Intrinsics IIDNnt Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIDNnt' to use this name for an external procedure.  File: g77.info, Node: IIEOr Intrinsic, Next: IIFix Intrinsic, Prev: IIDNnt Intrinsic, Up: Other Intrinsics IIEOr Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIEOr' to use this name for an external procedure.  File: g77.info, Node: IIFix Intrinsic, Next: IInt Intrinsic, Prev: IIEOr Intrinsic, Up: Other Intrinsics IIFix Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIFix' to use this name for an external procedure.  File: g77.info, Node: IInt Intrinsic, Next: IIOr Intrinsic, Prev: IIFix Intrinsic, Up: Other Intrinsics IInt Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IInt' to use this name for an external procedure.  File: g77.info, Node: IIOr Intrinsic, Next: IIQint Intrinsic, Prev: IInt Intrinsic, Up: Other Intrinsics IIOr Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIOr' to use this name for an external procedure.  File: g77.info, Node: IIQint Intrinsic, Next: IIQNnt Intrinsic, Prev: IIOr Intrinsic, Up: Other Intrinsics IIQint Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIQint' to use this name for an external procedure.  File: g77.info, Node: IIQNnt Intrinsic, Next: IIShftC Intrinsic, Prev: IIQint Intrinsic, Up: Other Intrinsics IIQNnt Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIQNnt' to use this name for an external procedure.  File: g77.info, Node: IIShftC Intrinsic, Next: IISign Intrinsic, Prev: IIQNnt Intrinsic, Up: Other Intrinsics IIShftC Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IIShftC' to use this name for an external procedure.  File: g77.info, Node: IISign Intrinsic, Next: IMax0 Intrinsic, Prev: IIShftC Intrinsic, Up: Other Intrinsics IISign Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IISign' to use this name for an external procedure.  File: g77.info, Node: IMax0 Intrinsic, Next: IMax1 Intrinsic, Prev: IISign Intrinsic, Up: Other Intrinsics IMax0 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IMax0' to use this name for an external procedure.  File: g77.info, Node: IMax1 Intrinsic, Next: IMin0 Intrinsic, Prev: IMax0 Intrinsic, Up: Other Intrinsics IMax1 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IMax1' to use this name for an external procedure.  File: g77.info, Node: IMin0 Intrinsic, Next: IMin1 Intrinsic, Prev: IMax1 Intrinsic, Up: Other Intrinsics IMin0 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IMin0' to use this name for an external procedure.  File: g77.info, Node: IMin1 Intrinsic, Next: IMod Intrinsic, Prev: IMin0 Intrinsic, Up: Other Intrinsics IMin1 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IMin1' to use this name for an external procedure.  File: g77.info, Node: IMod Intrinsic, Next: INInt Intrinsic, Prev: IMin1 Intrinsic, Up: Other Intrinsics IMod Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IMod' to use this name for an external procedure.  File: g77.info, Node: INInt Intrinsic, Next: INot Intrinsic, Prev: IMod Intrinsic, Up: Other Intrinsics INInt Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL INInt' to use this name for an external procedure.  File: g77.info, Node: INot Intrinsic, Next: IZExt Intrinsic, Prev: INInt Intrinsic, Up: Other Intrinsics INot Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL INot' to use this name for an external procedure.  File: g77.info, Node: IZExt Intrinsic, Next: JIAbs Intrinsic, Prev: INot Intrinsic, Up: Other Intrinsics IZExt Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL IZExt' to use this name for an external procedure.  File: g77.info, Node: JIAbs Intrinsic, Next: JIAnd Intrinsic, Prev: IZExt Intrinsic, Up: Other Intrinsics JIAbs Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIAbs' to use this name for an external procedure.  File: g77.info, Node: JIAnd Intrinsic, Next: JIBClr Intrinsic, Prev: JIAbs Intrinsic, Up: Other Intrinsics JIAnd Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIAnd' to use this name for an external procedure.  File: g77.info, Node: JIBClr Intrinsic, Next: JIBits Intrinsic, Prev: JIAnd Intrinsic, Up: Other Intrinsics JIBClr Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIBClr' to use this name for an external procedure.  File: g77.info, Node: JIBits Intrinsic, Next: JIBSet Intrinsic, Prev: JIBClr Intrinsic, Up: Other Intrinsics JIBits Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIBits' to use this name for an external procedure.  File: g77.info, Node: JIBSet Intrinsic, Next: JIDiM Intrinsic, Prev: JIBits Intrinsic, Up: Other Intrinsics JIBSet Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIBSet' to use this name for an external procedure.  File: g77.info, Node: JIDiM Intrinsic, Next: JIDInt Intrinsic, Prev: JIBSet Intrinsic, Up: Other Intrinsics JIDiM Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIDiM' to use this name for an external procedure.  File: g77.info, Node: JIDInt Intrinsic, Next: JIDNnt Intrinsic, Prev: JIDiM Intrinsic, Up: Other Intrinsics JIDInt Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIDInt' to use this name for an external procedure.  File: g77.info, Node: JIDNnt Intrinsic, Next: JIEOr Intrinsic, Prev: JIDInt Intrinsic, Up: Other Intrinsics JIDNnt Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIDNnt' to use this name for an external procedure.  File: g77.info, Node: JIEOr Intrinsic, Next: JIFix Intrinsic, Prev: JIDNnt Intrinsic, Up: Other Intrinsics JIEOr Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIEOr' to use this name for an external procedure.  File: g77.info, Node: JIFix Intrinsic, Next: JInt Intrinsic, Prev: JIEOr Intrinsic, Up: Other Intrinsics JIFix Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIFix' to use this name for an external procedure.  File: g77.info, Node: JInt Intrinsic, Next: JIOr Intrinsic, Prev: JIFix Intrinsic, Up: Other Intrinsics JInt Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JInt' to use this name for an external procedure.  File: g77.info, Node: JIOr Intrinsic, Next: JIQint Intrinsic, Prev: JInt Intrinsic, Up: Other Intrinsics JIOr Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIOr' to use this name for an external procedure.  File: g77.info, Node: JIQint Intrinsic, Next: JIQNnt Intrinsic, Prev: JIOr Intrinsic, Up: Other Intrinsics JIQint Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIQint' to use this name for an external procedure.  File: g77.info, Node: JIQNnt Intrinsic, Next: JIShft Intrinsic, Prev: JIQint Intrinsic, Up: Other Intrinsics JIQNnt Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIQNnt' to use this name for an external procedure.  File: g77.info, Node: JIShft Intrinsic, Next: JIShftC Intrinsic, Prev: JIQNnt Intrinsic, Up: Other Intrinsics JIShft Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIShft' to use this name for an external procedure.  File: g77.info, Node: JIShftC Intrinsic, Next: JISign Intrinsic, Prev: JIShft Intrinsic, Up: Other Intrinsics JIShftC Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JIShftC' to use this name for an external procedure.  File: g77.info, Node: JISign Intrinsic, Next: JMax0 Intrinsic, Prev: JIShftC Intrinsic, Up: Other Intrinsics JISign Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JISign' to use this name for an external procedure.  File: g77.info, Node: JMax0 Intrinsic, Next: JMax1 Intrinsic, Prev: JISign Intrinsic, Up: Other Intrinsics JMax0 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JMax0' to use this name for an external procedure.  File: g77.info, Node: JMax1 Intrinsic, Next: JMin0 Intrinsic, Prev: JMax0 Intrinsic, Up: Other Intrinsics JMax1 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JMax1' to use this name for an external procedure.  File: g77.info, Node: JMin0 Intrinsic, Next: JMin1 Intrinsic, Prev: JMax1 Intrinsic, Up: Other Intrinsics JMin0 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JMin0' to use this name for an external procedure.  File: g77.info, Node: JMin1 Intrinsic, Next: JMod Intrinsic, Prev: JMin0 Intrinsic, Up: Other Intrinsics JMin1 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JMin1' to use this name for an external procedure.  File: g77.info, Node: JMod Intrinsic, Next: JNInt Intrinsic, Prev: JMin1 Intrinsic, Up: Other Intrinsics JMod Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JMod' to use this name for an external procedure.  File: g77.info, Node: JNInt Intrinsic, Next: JNot Intrinsic, Prev: JMod Intrinsic, Up: Other Intrinsics JNInt Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JNInt' to use this name for an external procedure.  File: g77.info, Node: JNot Intrinsic, Next: JZExt Intrinsic, Prev: JNInt Intrinsic, Up: Other Intrinsics JNot Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JNot' to use this name for an external procedure.  File: g77.info, Node: JZExt Intrinsic, Next: Kill Intrinsic (function), Prev: JNot Intrinsic, Up: Other Intrinsics JZExt Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL JZExt' to use this name for an external procedure.  File: g77.info, Node: Kill Intrinsic (function), Next: Link Intrinsic (function), Prev: JZExt Intrinsic, Up: Other Intrinsics Kill Intrinsic (function) ......................... Kill(PID, SIGNAL) Kill: `INTEGER(KIND=1)' function. PID: `INTEGER'; scalar; INTENT(IN). SIGNAL: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Sends the signal specified by SIGNAL to the process PID. Returns 0 on success or a nonzero error code. See `kill(2)'. Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note Kill Intrinsic (subroutine)::.  File: g77.info, Node: Link Intrinsic (function), Next: QAbs Intrinsic, Prev: Kill Intrinsic (function), Up: Other Intrinsics Link Intrinsic (function) ......................... Link(PATH1, PATH2) Link: `INTEGER(KIND=1)' function. PATH1: `CHARACTER'; scalar; INTENT(IN). PATH2: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Makes a (hard) link from file PATH1 to PATH2. A null character (`CHAR(0)') marks the end of the names in PATH1 and PATH2--otherwise, trailing blanks in PATH1 and PATH2 are ignored. Returns 0 on success or a nonzero error code. See `link(2)'. Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note Link Intrinsic (subroutine)::.  File: g77.info, Node: QAbs Intrinsic, Next: QACos Intrinsic, Prev: Link Intrinsic (function), Up: Other Intrinsics QAbs Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QAbs' to use this name for an external procedure.  File: g77.info, Node: QACos Intrinsic, Next: QACosD Intrinsic, Prev: QAbs Intrinsic, Up: Other Intrinsics QACos Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QACos' to use this name for an external procedure.  File: g77.info, Node: QACosD Intrinsic, Next: QASin Intrinsic, Prev: QACos Intrinsic, Up: Other Intrinsics QACosD Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QACosD' to use this name for an external procedure.  File: g77.info, Node: QASin Intrinsic, Next: QASinD Intrinsic, Prev: QACosD Intrinsic, Up: Other Intrinsics QASin Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QASin' to use this name for an external procedure.  File: g77.info, Node: QASinD Intrinsic, Next: QATan Intrinsic, Prev: QASin Intrinsic, Up: Other Intrinsics QASinD Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QASinD' to use this name for an external procedure.  File: g77.info, Node: QATan Intrinsic, Next: QATan2 Intrinsic, Prev: QASinD Intrinsic, Up: Other Intrinsics QATan Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QATan' to use this name for an external procedure.  File: g77.info, Node: QATan2 Intrinsic, Next: QATan2D Intrinsic, Prev: QATan Intrinsic, Up: Other Intrinsics QATan2 Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QATan2' to use this name for an external procedure.  File: g77.info, Node: QATan2D Intrinsic, Next: QATanD Intrinsic, Prev: QATan2 Intrinsic, Up: Other Intrinsics QATan2D Intrinsic ................. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QATan2D' to use this name for an external procedure.  File: g77.info, Node: QATanD Intrinsic, Next: QCos Intrinsic, Prev: QATan2D Intrinsic, Up: Other Intrinsics QATanD Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QATanD' to use this name for an external procedure.  File: g77.info, Node: QCos Intrinsic, Next: QCosD Intrinsic, Prev: QATanD Intrinsic, Up: Other Intrinsics QCos Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QCos' to use this name for an external procedure.  File: g77.info, Node: QCosD Intrinsic, Next: QCosH Intrinsic, Prev: QCos Intrinsic, Up: Other Intrinsics QCosD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QCosD' to use this name for an external procedure.  File: g77.info, Node: QCosH Intrinsic, Next: QDiM Intrinsic, Prev: QCosD Intrinsic, Up: Other Intrinsics QCosH Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QCosH' to use this name for an external procedure.  File: g77.info, Node: QDiM Intrinsic, Next: QExp Intrinsic, Prev: QCosH Intrinsic, Up: Other Intrinsics QDiM Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QDiM' to use this name for an external procedure.  File: g77.info, Node: QExp Intrinsic, Next: QExt Intrinsic, Prev: QDiM Intrinsic, Up: Other Intrinsics QExp Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QExp' to use this name for an external procedure.  File: g77.info, Node: QExt Intrinsic, Next: QExtD Intrinsic, Prev: QExp Intrinsic, Up: Other Intrinsics QExt Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QExt' to use this name for an external procedure.  File: g77.info, Node: QExtD Intrinsic, Next: QFloat Intrinsic, Prev: QExt Intrinsic, Up: Other Intrinsics QExtD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QExtD' to use this name for an external procedure.  File: g77.info, Node: QFloat Intrinsic, Next: QInt Intrinsic, Prev: QExtD Intrinsic, Up: Other Intrinsics QFloat Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QFloat' to use this name for an external procedure.  File: g77.info, Node: QInt Intrinsic, Next: QLog Intrinsic, Prev: QFloat Intrinsic, Up: Other Intrinsics QInt Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QInt' to use this name for an external procedure.  File: g77.info, Node: QLog Intrinsic, Next: QLog10 Intrinsic, Prev: QInt Intrinsic, Up: Other Intrinsics QLog Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QLog' to use this name for an external procedure.  File: g77.info, Node: QLog10 Intrinsic, Next: QMax1 Intrinsic, Prev: QLog Intrinsic, Up: Other Intrinsics QLog10 Intrinsic ................ This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QLog10' to use this name for an external procedure.  File: g77.info, Node: QMax1 Intrinsic, Next: QMin1 Intrinsic, Prev: QLog10 Intrinsic, Up: Other Intrinsics QMax1 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QMax1' to use this name for an external procedure.  File: g77.info, Node: QMin1 Intrinsic, Next: QMod Intrinsic, Prev: QMax1 Intrinsic, Up: Other Intrinsics QMin1 Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QMin1' to use this name for an external procedure.  File: g77.info, Node: QMod Intrinsic, Next: QNInt Intrinsic, Prev: QMin1 Intrinsic, Up: Other Intrinsics QMod Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QMod' to use this name for an external procedure.  File: g77.info, Node: QNInt Intrinsic, Next: QSin Intrinsic, Prev: QMod Intrinsic, Up: Other Intrinsics QNInt Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QNInt' to use this name for an external procedure.  File: g77.info, Node: QSin Intrinsic, Next: QSinD Intrinsic, Prev: QNInt Intrinsic, Up: Other Intrinsics QSin Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QSin' to use this name for an external procedure.  File: g77.info, Node: QSinD Intrinsic, Next: QSinH Intrinsic, Prev: QSin Intrinsic, Up: Other Intrinsics QSinD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QSinD' to use this name for an external procedure.  File: g77.info, Node: QSinH Intrinsic, Next: QSqRt Intrinsic, Prev: QSinD Intrinsic, Up: Other Intrinsics QSinH Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QSinH' to use this name for an external procedure.  File: g77.info, Node: QSqRt Intrinsic, Next: QTan Intrinsic, Prev: QSinH Intrinsic, Up: Other Intrinsics QSqRt Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QSqRt' to use this name for an external procedure.  File: g77.info, Node: QTan Intrinsic, Next: QTanD Intrinsic, Prev: QSqRt Intrinsic, Up: Other Intrinsics QTan Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QTan' to use this name for an external procedure.  File: g77.info, Node: QTanD Intrinsic, Next: QTanH Intrinsic, Prev: QTan Intrinsic, Up: Other Intrinsics QTanD Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QTanD' to use this name for an external procedure.  File: g77.info, Node: QTanH Intrinsic, Next: Rename Intrinsic (function), Prev: QTanD Intrinsic, Up: Other Intrinsics QTanH Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL QTanH' to use this name for an external procedure.  File: g77.info, Node: Rename Intrinsic (function), Next: Secnds Intrinsic, Prev: QTanH Intrinsic, Up: Other Intrinsics Rename Intrinsic (function) ........................... Rename(PATH1, PATH2) Rename: `INTEGER(KIND=1)' function. PATH1: `CHARACTER'; scalar; INTENT(IN). PATH2: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Renames the file PATH1 to PATH2. A null character (`CHAR(0)') marks the end of the names in PATH1 and PATH2--otherwise, trailing blanks in PATH1 and PATH2 are ignored. See `rename(2)'. Returns 0 on success or a nonzero error code. Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note Rename Intrinsic (subroutine)::.  File: g77.info, Node: Secnds Intrinsic, Next: Signal Intrinsic (function), Prev: Rename Intrinsic (function), Up: Other Intrinsics Secnds Intrinsic ................ Secnds(T) Secnds: `REAL(KIND=1)' function. T: `REAL(KIND=1)'; scalar; INTENT(IN). Intrinsic groups: `vxt'. Description: Returns the local time in seconds since midnight minus the value T. This values returned by this intrinsic become numerically less than previous values (they wrap around) during a single run of the compiler program, under normal circumstances (such as running through the midnight hour).  File: g77.info, Node: Signal Intrinsic (function), Next: SinD Intrinsic, Prev: Secnds Intrinsic, Up: Other Intrinsics Signal Intrinsic (function) ........................... Signal(NUMBER, HANDLER) Signal: `INTEGER(KIND=7)' function. NUMBER: `INTEGER'; scalar; INTENT(IN). HANDLER: Signal handler (`INTEGER FUNCTION' or `SUBROUTINE') or dummy/global `INTEGER(KIND=1)' scalar. Intrinsic groups: `badu77'. Description: If HANDLER is a an `EXTERNAL' routine, arranges for it to be invoked with a single integer argument (of system-dependent length) when signal NUMBER occurs. If HANDLER is an integer, it can be used to turn off handling of signal NUMBER or revert to its default action. See `signal(2)'. Note that HANDLER will be called using C conventions, so the value of its argument in Fortran terms is obtained by applying `%LOC()' (or `LOC()') to it. The value returned by `signal(2)' is returned. Due to the side effects performed by this intrinsic, the function form is not recommended. _Warning:_ If the returned value is stored in an `INTEGER(KIND=1)' (default `INTEGER') argument, truncation of the original return value occurs on some systems (such as Alphas, which have 64-bit pointers but 32-bit default integers), with no warning issued by `g77' under normal circumstances. Therefore, the following code fragment might silently fail on some systems: INTEGER RTN EXTERNAL MYHNDL RTN = SIGNAL(SIGNUM, MYHNDL) ... ! Restore original handler: RTN = SIGNAL(SIGNUM, RTN) The reason for the failure is that `RTN' might not hold all the information on the original handler for the signal, thus restoring an invalid handler. This bug could manifest itself as a spurious run-time failure at an arbitrary point later during the program's execution, for example. _Warning:_ Use of the `libf2c' run-time library function `signal_' directly (such as via `EXTERNAL SIGNAL') requires use of the `%VAL()' construct to pass an `INTEGER' value (such as `SIG_IGN' or `SIG_DFL') for the HANDLER argument. However, while `RTN = SIGNAL(SIGNUM, %VAL(SIG_IGN))' works when `SIGNAL' is treated as an external procedure (and resolves, at link time, to `libf2c''s `signal_' routine), this construct is not valid when `SIGNAL' is recognized as the intrinsic of that name. Therefore, for maximum portability and reliability, code such references to the `SIGNAL' facility as follows: INTRINSIC SIGNAL ... RTN = SIGNAL(SIGNUM, SIG_IGN) `g77' will compile such a call correctly, while other compilers will generally either do so as well or reject the `INTRINSIC SIGNAL' statement via a diagnostic, allowing you to take appropriate action. For information on other intrinsics with the same name: *Note Signal Intrinsic (subroutine)::.  File: g77.info, Node: SinD Intrinsic, Next: SnglQ Intrinsic, Prev: Signal Intrinsic (function), Up: Other Intrinsics SinD Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL SinD' to use this name for an external procedure.  File: g77.info, Node: SnglQ Intrinsic, Next: SymLnk Intrinsic (function), Prev: SinD Intrinsic, Up: Other Intrinsics SnglQ Intrinsic ............... This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL SnglQ' to use this name for an external procedure.  File: g77.info, Node: SymLnk Intrinsic (function), Next: System Intrinsic (function), Prev: SnglQ Intrinsic, Up: Other Intrinsics SymLnk Intrinsic (function) ........................... SymLnk(PATH1, PATH2) SymLnk: `INTEGER(KIND=1)' function. PATH1: `CHARACTER'; scalar; INTENT(IN). PATH2: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Makes a symbolic link from file PATH1 to PATH2. A null character (`CHAR(0)') marks the end of the names in PATH1 and PATH2--otherwise, trailing blanks in PATH1 and PATH2 are ignored. Returns 0 on success or a nonzero error code (`ENOSYS' if the system does not provide `symlink(2)'). Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note SymLnk Intrinsic (subroutine)::.  File: g77.info, Node: System Intrinsic (function), Next: TanD Intrinsic, Prev: SymLnk Intrinsic (function), Up: Other Intrinsics System Intrinsic (function) ........................... System(COMMAND) System: `INTEGER(KIND=1)' function. COMMAND: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Passes the command COMMAND to a shell (see `system(3)'). Returns the value returned by `system(3)', presumably 0 if the shell command succeeded. Note that which shell is used to invoke the command is system-dependent and environment-dependent. Due to the side effects performed by this intrinsic, the function form is not recommended. However, the function form can be valid in cases where the actual side effects performed by the call are unimportant to the application. For example, on a UNIX system, `SAME = SYSTEM('cmp a b')' does not perform any side effects likely to be important to the program, so the programmer would not care if the actual system call (and invocation of `cmp') was optimized away in a situation where the return value could be determined otherwise, or was not actually needed (`SAME' not actually referenced after the sample assignment statement). For information on other intrinsics with the same name: *Note System Intrinsic (subroutine)::.  File: g77.info, Node: TanD Intrinsic, Next: Time Intrinsic (VXT), Prev: System Intrinsic (function), Up: Other Intrinsics TanD Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL TanD' to use this name for an external procedure.  File: g77.info, Node: Time Intrinsic (VXT), Next: UMask Intrinsic (function), Prev: TanD Intrinsic, Up: Other Intrinsics Time Intrinsic (VXT) .................... CALL Time(TIME) TIME: `CHARACTER*8'; scalar; INTENT(OUT). Intrinsic groups: `vxt'. Description: Returns in TIME a character representation of the current time as obtained from `ctime(3)'. Programs making use of this intrinsic might not be Year 10000 (Y10K) compliant. For example, the date might appear, to such programs, to wrap around (change from a larger value to a smaller one) as of the Year 10000. *Note FDate Intrinsic (subroutine)::, for an equivalent routine. For information on other intrinsics with the same name: *Note Time Intrinsic (UNIX)::.  File: g77.info, Node: UMask Intrinsic (function), Next: Unlink Intrinsic (function), Prev: Time Intrinsic (VXT), Up: Other Intrinsics UMask Intrinsic (function) .......................... UMask(MASK) UMask: `INTEGER(KIND=1)' function. MASK: `INTEGER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Sets the file creation mask to MASK and returns the old value. See `umask(2)'. Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note UMask Intrinsic (subroutine)::.  File: g77.info, Node: Unlink Intrinsic (function), Next: ZExt Intrinsic, Prev: UMask Intrinsic (function), Up: Other Intrinsics Unlink Intrinsic (function) ........................... Unlink(FILE) Unlink: `INTEGER(KIND=1)' function. FILE: `CHARACTER'; scalar; INTENT(IN). Intrinsic groups: `badu77'. Description: Unlink the file FILE. A null character (`CHAR(0)') marks the end of the name in FILE--otherwise, trailing blanks in FILE are ignored. Returns 0 on success or a nonzero error code. See `unlink(2)'. Due to the side effects performed by this intrinsic, the function form is not recommended. For information on other intrinsics with the same name: *Note Unlink Intrinsic (subroutine)::.  File: g77.info, Node: ZExt Intrinsic, Prev: Unlink Intrinsic (function), Up: Other Intrinsics ZExt Intrinsic .............. This intrinsic is not yet implemented. The name is, however, reserved as an intrinsic. Use `EXTERNAL ZExt' to use this name for an external procedure.  File: g77.info, Node: Other Compilers, Next: Other Languages, Prev: Other Dialects, Up: Top Other Compilers *************** An individual Fortran source file can be compiled to an object (`*.o') file instead of to the final program executable. This allows several portions of a program to be compiled at different times and linked together whenever a new version of the program is needed. However, it introduces the issue of "object compatibility" across the various object files (and libraries, or `*.a' files) that are linked together to produce any particular executable file. Object compatibility is an issue when combining, in one program, Fortran code compiled by more than one compiler (or more than one configuration of a compiler). If the compilers disagree on how to transform the names of procedures, there will normally be errors when linking such programs. Worse, if the compilers agree on naming, but disagree on issues like how to pass parameters, return arguments, and lay out `COMMON' areas, the earliest detected errors might be the incorrect results produced by the program (and that assumes these errors are detected, which is not always the case). Normally, `g77' generates code that is object-compatible with code generated by a version of `f2c' configured (with, for example, `f2c.h' definitions) to be generally compatible with `g77' as built by `gcc'. (Normally, `f2c' will, by default, conform to the appropriate configuration, but it is possible that older or perhaps even newer versions of `f2c', or versions having certain configuration changes to `f2c' internals, will produce object files that are incompatible with `g77'.) For example, a Fortran string subroutine argument will become two arguments on the C side: a `char *' and an `int' length. Much of this compatibility results from the fact that `g77' uses the same run-time library, `libf2c', used by `f2c', though `g77' gives its version the name `libg2c' so as to avoid conflicts when linking, installing them in the same directories, and so on. Other compilers might or might not generate code that is object-compatible with `libg2c' and current `g77', and some might offer such compatibility only when explicitly selected via a command-line option to the compiler. _Note: This portion of the documentation definitely needs a lot of work!_ * Menu: * Dropping f2c Compatibility:: When speed is more important. * Compilers Other Than f2c:: Interoperation with code from other compilers.  File: g77.info, Node: Dropping f2c Compatibility, Next: Compilers Other Than f2c, Up: Other Compilers Dropping `f2c' Compatibility ============================ Specifying `-fno-f2c' allows `g77' to generate, in some cases, faster code, by not needing to allow to the possibility of linking with code compiled by `f2c'. For example, this affects how `REAL(KIND=1)', `COMPLEX(KIND=1)', and `COMPLEX(KIND=2)' functions are called. With `-fno-f2c', they are compiled as returning the appropriate `gcc' type (`float', `__complex__ float', `__complex__ double', in many configurations). With `-ff2c' in force, they are compiled differently (with perhaps slower run-time performance) to accommodate the restrictions inherent in `f2c''s use of K&R C as an intermediate language--`REAL(KIND=1)' functions return C's `double' type, while `COMPLEX' functions return `void' and use an extra argument pointing to a place for the functions to return their values. It is possible that, in some cases, leaving `-ff2c' in force might produce faster code than using `-fno-f2c'. Feel free to experiment, but remember to experiment with changing the way _entire programs and their Fortran libraries are compiled_ at a time, since this sort of experimentation affects the interface of code generated for a Fortran source file--that is, it affects object compatibility. Note that `f2c' compatibility is a fairly static target to achieve, though not necessarily perfectly so, since, like `g77', it is still being improved. However, specifying `-fno-f2c' causes `g77' to generate code that will probably be incompatible with code generated by future versions of `g77' when the same option is in force. You should make sure you are always able to recompile complete programs from source code when upgrading to new versions of `g77' or `f2c', especially when using options such as `-fno-f2c'. Therefore, if you are using `g77' to compile libraries and other object files for possible future use and you don't want to require recompilation for future use with subsequent versions of `g77', you might want to stick with `f2c' compatibility for now, and carefully watch for any announcements about changes to the `f2c'/`libf2c' interface that might affect existing programs (thus requiring recompilation). It is probable that a future version of `g77' will not, by default, generate object files compatible with `f2c', and that version probably would no longer use `libf2c'. If you expect to depend on this compatibility in the long term, use the options `-ff2c -ff2c-library' when compiling all of the applicable code. This should cause future versions of `g77' either to produce compatible code (at the expense of the availability of some features and performance), or at the very least, to produce diagnostics. (The library `g77' produces will no longer be named `libg2c' when it is no longer generally compatible with `libf2c'. It will likely be referred to, and, if installed as a distinct library, named `libg77', or some other as-yet-unused name.)  File: g77.info, Node: Compilers Other Than f2c, Prev: Dropping f2c Compatibility, Up: Other Compilers Compilers Other Than `f2c' ========================== On systems with Fortran compilers other than `f2c' and `g77', code compiled by `g77' is not expected to work well with code compiled by the native compiler. (This is true for `f2c'-compiled objects as well.) Libraries compiled with the native compiler probably will have to be recompiled with `g77' to be used with `g77'-compiled code. Reasons for such incompatibilities include: * There might be differences in the way names of Fortran procedures are translated for use in the system's object-file format. For example, the statement `CALL FOO' might be compiled by `g77' to call a procedure the linker `ld' sees given the name `_foo_', while the apparently corresponding statement `SUBROUTINE FOO' might be compiled by the native compiler to define the linker-visible name `_foo', or `_FOO_', and so on. * There might be subtle type mismatches which cause subroutine arguments and function return values to get corrupted. This is why simply getting `g77' to transform procedure names the same way a native compiler does is not usually a good idea--unless some effort has been made to ensure that, aside from the way the two compilers transform procedure names, everything else about the way they generate code for procedure interfaces is identical. * Native compilers use libraries of private I/O routines which will not be available at link time unless you have the native compiler--and you would have to explicitly ask for them. For example, on the Sun you would have to add `-L/usr/lang/SCx.x -lF77 -lV77' to the link command.  File: g77.info, Node: Other Languages, Next: Debugging and Interfacing, Prev: Other Compilers, Up: Top Other Languages *************** _Note: This portion of the documentation definitely needs a lot of work!_ * Menu: * Interoperating with C and C++::  File: g77.info, Node: Interoperating with C and C++, Up: Other Languages Tools and advice for interoperating with C and C++ ================================================== The following discussion assumes that you are running `g77' in `f2c' compatibility mode, i.e. not using `-fno-f2c'. It provides some advice about quick and simple techniques for linking Fortran and C (or C++), the most common requirement. For the full story consult the description of code generation. *Note Debugging and Interfacing::. When linking Fortran and C, it's usually best to use `g77' to do the linking so that the correct libraries are included (including the maths one). If you're linking with C++ you will want to add `-lstdc++', `-lg++' or whatever. If you need to use another driver program (or `ld' directly), you can find out what linkage options `g77' passes by running `g77 -v'. * Menu: * C Interfacing Tools:: * C Access to Type Information:: * f2c Skeletons and Prototypes:: * C++ Considerations:: * Startup Code::  File: g77.info, Node: C Interfacing Tools, Next: C Access to Type Information, Up: Interoperating with C and C++ C Interfacing Tools ------------------- Even if you don't actually use it as a compiler, `f2c' from `ftp://ftp.netlib.org/f2c/src', can be a useful tool when you're interfacing (linking) Fortran and C. *Note Generating Skeletons and Prototypes with `f2c': f2c Skeletons and Prototypes. To use `f2c' for this purpose you only need retrieve and build the `src' directory from the distribution, consult the `README' instructions there for machine-specifics, and install the `f2c' program on your path. Something else that might be useful is `cfortran.h' from `ftp://zebra.desy.de/cfortran'. This is a fairly general tool which can be used to generate interfaces for calling in both directions between Fortran and C. It can be used in `f2c' mode with `g77'--consult its documentation for details.  File: g77.info, Node: C Access to Type Information, Next: f2c Skeletons and Prototypes, Prev: C Interfacing Tools, Up: Interoperating with C and C++ Accessing Type Information in C ------------------------------- Generally, C code written to link with `g77' code--calling and/or being called from Fortran--should `#include ' to define the C versions of the Fortran types. Don't assume Fortran `INTEGER' types correspond to C `int's, for instance; instead, declare them as `integer', a type defined by `g2c.h'. `g2c.h' is installed where `gcc' will find it by default, assuming you use a copy of `gcc' compatible with `g77', probably built at the same time as `g77'.  File: g77.info, Node: f2c Skeletons and Prototypes, Next: C++ Considerations, Prev: C Access to Type Information, Up: Interoperating with C and C++ Generating Skeletons and Prototypes with `f2c' ---------------------------------------------- A simple and foolproof way to write `g77'-callable C routines--e.g. to interface with an existing library--is to write a file (named, for example, `fred.f') of dummy Fortran skeletons comprising just the declaration of the routine(s) and dummy arguments plus `END' statements. Then run `f2c' on file `fred.f' to produce `fred.c' into which you can edit useful code, confident the calling sequence is correct, at least. (There are some errors otherwise commonly made in generating C interfaces with `f2c' conventions, such as not using `doublereal' as the return type of a `REAL' `FUNCTION'.) `f2c' also can help with calling Fortran from C, using its `-P' option to generate C prototypes appropriate for calling the Fortran.(1) If the Fortran code containing any routines to be called from C is in file `joe.f', use the command `f2c -P joe.f' to generate the file `joe.P' containing prototype information. `#include' this in the C which has to call the Fortran routines to make sure you get it right. *Note Arrays (DIMENSION): Arrays, for information on the differences between the way Fortran (including compilers like `g77') and C handle arrays. ---------- Footnotes ---------- (1) The files generated like this can also be used for inter-unit consistency checking of dummy and actual arguments, although the `ftnchek' tool from `ftp://ftp.netlib.org/fortran' or `ftp://ftp.dsm.fordham.edu' is probably better for this purpose.  File: g77.info, Node: C++ Considerations, Next: Startup Code, Prev: f2c Skeletons and Prototypes, Up: Interoperating with C and C++ C++ Considerations ------------------ `f2c' can be used to generate suitable code for compilation with a C++ system using the `-C++' option. The important thing about linking `g77'-compiled code with C++ is that the prototypes for the `g77' routines must specify C linkage to avoid name mangling. So, use an `extern "C"' declaration. `f2c''s `-C++' option will not take care of this when generating skeletons or prototype files as above, however, it will avoid clashes with C++ reserved words in addition to those in C.  File: g77.info, Node: Startup Code, Prev: C++ Considerations, Up: Interoperating with C and C++ Startup Code ------------ Unlike with some runtime systems, it shouldn't be necessary (unless there are bugs) to use a Fortran main program unit to ensure the runtime--specifically the I/O system--is initialized. However, to use the `g77' intrinsics `GETARG' and `IARGC', either the `main' routine from the `libg2c' library must be used, or the `f_setarg' routine (new as of `egcs' version 1.1 and `g77' version 0.5.23) must be called with the appropriate `argc' and `argv' arguments prior to the program calling `GETARG' or `IARGC'. To provide more flexibility for mixed-language programming involving `g77' while allowing for shared libraries, as of `egcs' version 1.1 and `g77' version 0.5.23, `g77''s `main' routine in `libg2c' does the following, in order: 1. Calls `f_setarg' with the incoming `argc' and `argv' arguments, in the same order as for `main' itself. This sets up the command-line environment for `GETARG' and `IARGC'. 2. Calls `f_setsig' (with no arguments). This sets up the signaling and exception environment. 3. Calls `f_init' (with no arguments). This initializes the I/O environment, though that should not be necessary, as all I/O functions in `libf2c' are believed to call `f_init' automatically, if necessary. (A future version of `g77' might skip this explicit step, to speed up normal exit of a program.) 4. Arranges for `f_exit' to be called (with no arguments) when the program exits. This ensures that the I/O environment is properly shut down before the program exits normally. Otherwise, output buffers might not be fully flushed, scratch files might not be deleted, and so on. The simple way `main' does this is to call `f_exit' itself after calling `MAIN__' (in the next step). However, this does not catch the cases where the program might call `exit' directly, instead of using the `EXIT' intrinsic (implemented as `exit_' in `libf2c'). So, `main' attempts to use the operating environment's `onexit' or `atexit' facility, if available, to cause `f_exit' to be called automatically upon any invocation of `exit'. 5. Calls `MAIN__' (with no arguments). This starts executing the Fortran main program unit for the application. (Both `g77' and `f2c' currently compile a main program unit so that its global name is `MAIN__'.) 6. If no `onexit' or `atexit' is provided by the system, calls `f_exit'. 7. Calls `exit' with a zero argument, to signal a successful program termination. 8. Returns a zero value to the caller, to signal a successful program termination, in case `exit' doesn't exit on the system. All of the above names are C `extern' names, i.e. not mangled. When using the `main' procedure provided by `g77' without a Fortran main program unit, you need to provide `MAIN__' as the entry point for your C code. (Make sure you link the object file that defines that entry point with the rest of your program.) To provide your own `main' procedure in place of `g77''s, make sure you specify the object file defining that procedure _before_ `-lg2c' on the `g77' command line. Since the `-lg2c' option is implicitly provided, this is usually straightforward. (Use the `--verbose' option to see how and where `g77' implicitly adds `-lg2c' in a command line that will link the program. Feel free to specify `-lg2c' explicitly, as appropriate.) However, when providing your own `main', make sure you perform the appropriate tasks in the appropriate order. For example, if your `main' does not call `f_setarg', make sure the rest of your application does not call `GETARG' or `IARGC'. And, if your `main' fails to ensure that `f_exit' is called upon program exit, some files might end up incompletely written, some scratch files might be left lying around, and some existing files being written might be left with old data not properly truncated at the end. Note that, generally, the `g77' operating environment does not depend on a procedure named `MAIN__' actually being called prior to any other `g77'-compiled code. That is, `MAIN__' does not, itself, set up any important operating-environment characteristics upon which other code might depend. This might change in future versions of `g77', with appropriate notification in the release notes. For more information, consult the source code for the above routines. These are in `gcc/libf2c/libF77/', named `main.c', `setarg.c', `setsig.c', `getarg_.c', and `iargc_.c'. Also, the file `gcc/gcc/f/com.c' contains the code `g77' uses to open-code (inline) references to `IARGC'.  File: g77.info, Node: Debugging and Interfacing, Next: Collected Fortran Wisdom, Prev: Other Languages, Up: Top Debugging and Interfacing ************************* GNU Fortran currently generates code that is object-compatible with the `f2c' converter. Also, it avoids limitations in the current GBE, such as the inability to generate a procedure with multiple entry points, by generating code that is structured differently (in terms of procedure names, scopes, arguments, and so on) than might be expected. As a result, writing code in other languages that calls on, is called by, or shares in-memory data with `g77'-compiled code generally requires some understanding of the way `g77' compiles code for various constructs. Similarly, using a debugger to debug `g77'-compiled code, even if that debugger supports native Fortran debugging, generally requires this sort of information. This section describes some of the basic information on how `g77' compiles code for constructs involving interfaces to other languages and to debuggers. _Caution:_ Much or all of this information pertains to only the current release of `g77', sometimes even to using certain compiler options with `g77' (such as `-fno-f2c'). Do not write code that depends on this information without clearly marking said code as nonportable and subject to review for every new release of `g77'. This information is provided primarily to make debugging of code generated by this particular release of `g77' easier for the user, and partly to make writing (generally nonportable) interface code easier. Both of these activities require tracking changes in new version of `g77' as they are installed, because new versions can change the behaviors described in this section. * Menu: * Main Program Unit:: How `g77' compiles a main program unit. * Procedures:: How `g77' constructs parameter lists for procedures. * Functions:: Functions returning floating-point or character data. * Names:: Naming of user-defined variables, procedures, etc. * Common Blocks:: Accessing common variables while debugging. * Local Equivalence Areas:: Accessing `EQUIVALENCE' while debugging. * Complex Variables:: How `g77' performs complex arithmetic. * Arrays:: Dealing with (possibly multi-dimensional) arrays. * Adjustable Arrays:: Special consideration for adjustable arrays. * Alternate Entry Points:: How `g77' implements alternate `ENTRY'. * Alternate Returns:: How `g77' handles alternate returns. * Assigned Statement Labels:: How `g77' handles `ASSIGN'. * Run-time Library Errors:: Meanings of some `IOSTAT=' values.  File: g77.info, Node: Main Program Unit, Next: Procedures, Up: Debugging and Interfacing Main Program Unit (PROGRAM) =========================== When `g77' compiles a main program unit, it gives it the public procedure name `MAIN__'. The `libg2c' library has the actual `main()' procedure as is typical of C-based environments, and it is this procedure that performs some initial start-up activity and then calls `MAIN__'. Generally, `g77' and `libg2c' are designed so that you need not include a main program unit written in Fortran in your program--it can be written in C or some other language. Especially for I/O handling, this is the case, although `g77' version 0.5.16 includes a bug fix for `libg2c' that solved a problem with using the `OPEN' statement as the first Fortran I/O activity in a program without a Fortran main program unit. However, if you don't intend to use `g77' (or `f2c') to compile your main program unit--that is, if you intend to compile a `main()' procedure using some other language--you should carefully examine the code for `main()' in `libg2c', found in the source file `gcc/libf2c/libF77/main.c', to see what kinds of things might need to be done by your `main()' in order to provide the Fortran environment your Fortran code is expecting. For example, `libg2c''s `main()' sets up the information used by the `IARGC' and `GETARG' intrinsics. Bypassing `libg2c''s `main()' without providing a substitute for this activity would mean that invoking `IARGC' and `GETARG' would produce undefined results. When debugging, one implication of the fact that `main()', which is the place where the debugged program "starts" from the debugger's point of view, is in `libg2c' is that you won't be starting your Fortran program at a point you recognize as your Fortran code. The standard way to get around this problem is to set a break point (a one-time, or temporary, break point will do) at the entrance to `MAIN__', and then run the program. A convenient way to do so is to add the `gdb' command tbreak MAIN__ to the file `.gdbinit' in the directory in which you're debugging (using `gdb'). After doing this, the debugger will see the current execution point of the program as at the beginning of the main program unit of your program. Of course, if you really want to set a break point at some other place in your program and just start the program running, without first breaking at `MAIN__', that should work fine.  File: g77.info, Node: Procedures, Next: Functions, Prev: Main Program Unit, Up: Debugging and Interfacing Procedures (SUBROUTINE and FUNCTION) ==================================== Currently, `g77' passes arguments via reference--specifically, by passing a pointer to the location in memory of a variable, array, array element, a temporary location that holds the result of evaluating an expression, or a temporary or permanent location that holds the value of a constant. Procedures that accept `CHARACTER' arguments are implemented by `g77' so that each `CHARACTER' argument has two actual arguments. The first argument occupies the expected position in the argument list and has the user-specified name. This argument is a pointer to an array of characters, passed by the caller. The second argument is appended to the end of the user-specified calling sequence and is named `__g77_length_X', where X is the user-specified name. This argument is of the C type `ftnlen' (see `gcc/libf2c/g2c.h.in' for information on that type) and is the number of characters the caller has allocated in the array pointed to by the first argument. A procedure will ignore the length argument if `X' is not declared `CHARACTER*(*)', because for other declarations, it knows the length. Not all callers necessarily "know" this, however, which is why they all pass the extra argument. The contents of the `CHARACTER' argument are specified by the address passed in the first argument (named after it). The procedure can read or write these contents as appropriate. When more than one `CHARACTER' argument is present in the argument list, the length arguments are appended in the order the original arguments appear. So `CALL FOO('HI','THERE')' is implemented in C as `foo("hi","there",2,5);', ignoring the fact that `g77' does not provide the trailing null bytes on the constant strings (`f2c' does provide them, but they are unnecessary in a Fortran environment, and you should not expect them to be there). Note that the above information applies to `CHARACTER' variables and arrays *only*. It does *not* apply to external `CHARACTER' functions or to intrinsic `CHARACTER' functions. That is, no second length argument is passed to `FOO' in this case: CHARACTER X EXTERNAL X CALL FOO(X) Nor does `FOO' expect such an argument in this case: SUBROUTINE FOO(X) CHARACTER X EXTERNAL X Because of this implementation detail, if a program has a bug such that there is disagreement as to whether an argument is a procedure, and the type of the argument is `CHARACTER', subtle symptoms might appear.  File: g77.info, Node: Functions, Next: Names, Prev: Procedures, Up: Debugging and Interfacing Functions (FUNCTION and RETURN) =============================== `g77' handles in a special way functions that return the following types: * `CHARACTER' * `COMPLEX' * `REAL(KIND=1)' For `CHARACTER', `g77' implements a subroutine (a C function returning `void') with two arguments prepended: `__g77_result', which the caller passes as a pointer to a `char' array expected to hold the return value, and `__g77_length', which the caller passes as an `ftnlen' value specifying the length of the return value as declared in the calling program. For `CHARACTER*(*)', the called function uses `__g77_length' to determine the size of the array that `__g77_result' points to; otherwise, it ignores that argument. For `COMPLEX', when `-ff2c' is in force, `g77' implements a subroutine with one argument prepended: `__g77_result', which the caller passes as a pointer to a variable of the type of the function. The called function writes the return value into this variable instead of returning it as a function value. When `-fno-f2c' is in force, `g77' implements a `COMPLEX' function as `gcc''s `__complex__ float' or `__complex__ double' function (or an emulation thereof, when `-femulate-complex' is in effect), returning the result of the function in the same way as `gcc' would. For `REAL(KIND=1)', when `-ff2c' is in force, `g77' implements a function that actually returns `REAL(KIND=2)' (typically C's `double' type). When `-fno-f2c' is in force, `REAL(KIND=1)' functions return `float'.  File: g77.info, Node: Names, Next: Common Blocks, Prev: Functions, Up: Debugging and Interfacing Names ===== Fortran permits each implementation to decide how to represent names as far as how they're seen in other contexts, such as debuggers and when interfacing to other languages, and especially as far as how casing is handled. External names--names of entities that are public, or "accessible", to all modules in a program--normally have an underscore (`_') appended by `g77', to generate code that is compatible with `f2c'. External names include names of Fortran things like common blocks, external procedures (subroutines and functions, but not including statement functions, which are internal procedures), and entry point names. However, use of the `-fno-underscoring' option disables this kind of transformation of external names (though inhibiting the transformation certainly improves the chances of colliding with incompatible externals written in other languages--but that might be intentional. When `-funderscoring' is in force, any name (external or local) that already has at least one underscore in it is implemented by `g77' by appending two underscores. (This second underscore can be disabled via the `-fno-second-underscore' option.) External names are changed this way for `f2c' compatibility. Local names are changed this way to avoid collisions with external names that are different in the source code--`f2c' does the same thing, but there's no compatibility issue there except for user expectations while debugging. For example: Max_Cost = 0 Here, a user would, in the debugger, refer to this variable using the name `max_cost__' (or `MAX_COST__' or `Max_Cost__', as described below). (We hope to improve `g77' in this regard in the future--don't write scripts depending on this behavior! Also, consider experimenting with the `-fno-underscoring' option to try out debugging without having to massage names by hand like this.) `g77' provides a number of command-line options that allow the user to control how case mapping is handled for source files. The default is the traditional UNIX model for Fortran compilers--names are mapped to lower case. Other command-line options can be specified to map names to upper case, or to leave them exactly as written in the source file. For example: Foo = 9.436 Here, it is normally the case that the variable assigned will be named `foo'. This would be the name to enter when using a debugger to access the variable. However, depending on the command-line options specified, the name implemented by `g77' might instead be `FOO' or even `Foo', thus affecting how debugging is done. Also: Call Foo This would normally call a procedure that, if it were in a separate C program, be defined starting with the line: void foo_() However, `g77' command-line options could be used to change the casing of names, resulting in the name `FOO_' or `Foo_' being given to the procedure instead of `foo_', and the `-fno-underscoring' option could be used to inhibit the appending of the underscore to the name.  File: g77.info, Node: Common Blocks, Next: Local Equivalence Areas, Prev: Names, Up: Debugging and Interfacing Common Blocks (COMMON) ====================== `g77' names and lays out `COMMON' areas the same way `f2c' does, for compatibility with `f2c'.  File: g77.info, Node: Local Equivalence Areas, Next: Complex Variables, Prev: Common Blocks, Up: Debugging and Interfacing Local Equivalence Areas (EQUIVALENCE) ===================================== `g77' treats storage-associated areas involving a `COMMON' block as explained in the section on common blocks. A local `EQUIVALENCE' area is a collection of variables and arrays connected to each other in any way via `EQUIVALENCE', none of which are listed in a `COMMON' statement. (_Note:_ `g77' version 0.5.18 and earlier chose the name for X using a different method when more than one name was in the list of names of entities placed at the beginning of the array. Though the documentation specified that the first name listed in the `EQUIVALENCE' statements was chosen for X, `g77' in fact chose the name using a method that was so complicated, it seemed easier to change it to an alphabetical sort than to describe the previous method in the documentation.)  File: g77.info, Node: Complex Variables, Next: Arrays, Prev: Local Equivalence Areas, Up: Debugging and Interfacing Complex Variables (COMPLEX) =========================== As of 0.5.20, `g77' defaults to handling `COMPLEX' types (and related intrinsics, constants, functions, and so on) in a manner that makes direct debugging involving these types in Fortran language mode difficult. Essentially, `g77' implements these types using an internal construct similar to C's `struct', at least as seen by the `gcc' back end. Currently, the back end, when outputting debugging info with the compiled code for the assembler to digest, does not detect these `struct' types as being substitutes for Fortran complex. As a result, the Fortran language modes of debuggers such as `gdb' see these types as C `struct' types, which they might or might not support. Until this is fixed, switch to C language mode to work with entities of `COMPLEX' type and then switch back to Fortran language mode afterward. (In `gdb', this is accomplished via `set lang c' and either `set lang fortran' or `set lang auto'.)  File: g77.info, Node: Arrays, Next: Adjustable Arrays, Prev: Complex Variables, Up: Debugging and Interfacing Arrays (DIMENSION) ================== Fortran uses "column-major ordering" in its arrays. This differs from other languages, such as C, which use "row-major ordering". The difference is that, with Fortran, array elements adjacent to each other in memory differ in the _first_ subscript instead of the last; `A(5,10,20)' immediately follows `A(4,10,20)', whereas with row-major ordering it would follow `A(5,10,19)'. This consideration affects not only interfacing with and debugging Fortran code, it can greatly affect how code is designed and written, especially when code speed and size is a concern. Fortran also differs from C, a popular language for interfacing and to support directly in debuggers, in the way arrays are treated. In C, arrays are single-dimensional and have interesting relationships to pointers, neither of which is true for Fortran. As a result, dealing with Fortran arrays from within an environment limited to C concepts can be challenging. For example, accessing the array element `A(5,10,20)' is easy enough in Fortran (use `A(5,10,20)'), but in C some difficult machinations are needed. First, C would treat the A array as a single-dimension array. Second, C does not understand low bounds for arrays as does Fortran. Third, C assumes a low bound of zero (0), while Fortran defaults to a low bound of one (1) and can supports an arbitrary low bound. Therefore, calculations must be done to determine what the C equivalent of `A(5,10,20)' would be, and these calculations require knowing the dimensions of `A'. For `DIMENSION A(2:11,21,0:29)', the calculation of the offset of `A(5,10,20)' would be: (5-2) + (10-1)*(11-2+1) + (20-0)*(11-2+1)*(21-1+1) = 4293 So the C equivalent in this case would be `a[4293]'. When using a debugger directly on Fortran code, the C equivalent might not work, because some debuggers cannot understand the notion of low bounds other than zero. However, unlike `f2c', `g77' does inform the GBE that a multi-dimensional array (like `A' in the above example) is really multi-dimensional, rather than a single-dimensional array, so at least the dimensionality of the array is preserved. Debuggers that understand Fortran should have no trouble with nonzero low bounds, but for non-Fortran debuggers, especially C debuggers, the above example might have a C equivalent of `a[4305]'. This calculation is arrived at by eliminating the subtraction of the lower bound in the first parenthesized expression on each line--that is, for `(5-2)' substitute `(5)', for `(10-1)' substitute `(10)', and for `(20-0)' substitute `(20)'. Actually, the implication of this can be that the expression `*(&a[2][1][0] + 4293)' works fine, but that `a[20][10][5]' produces the equivalent of `*(&a[0][0][0] + 4305)' because of the missing lower bounds. Come to think of it, perhaps the behavior is due to the debugger internally compensating for the lower bounds by offsetting the base address of `a', leaving `&a' set lower, in this case, than `&a[2][1][0]' (the address of its first element as identified by subscripts equal to the corresponding lower bounds). You know, maybe nobody really needs to use arrays.  File: g77.info, Node: Adjustable Arrays, Next: Alternate Entry Points, Prev: Arrays, Up: Debugging and Interfacing Adjustable Arrays (DIMENSION) ============================= Adjustable and automatic arrays in Fortran require the implementation (in this case, the `g77' compiler) to "memorize" the expressions that dimension the arrays each time the procedure is invoked. This is so that subsequent changes to variables used in those expressions, made during execution of the procedure, do not have any effect on the dimensions of those arrays. For example: REAL ARRAY(5) DATA ARRAY/5*2/ CALL X(ARRAY, 5) END SUBROUTINE X(A, N) DIMENSION A(N) N = 20 PRINT *, N, A END Here, the implementation should, when running the program, print something like: 20 2. 2. 2. 2. 2. Note that this shows that while the value of `N' was successfully changed, the size of the `A' array remained at 5 elements. To support this, `g77' generates code that executes before any user code (and before the internally generated computed `GOTO' to handle alternate entry points, as described below) that evaluates each (nonconstant) expression in the list of subscripts for an array, and saves the result of each such evaluation to be used when determining the size of the array (instead of re-evaluating the expressions). So, in the above example, when `X' is first invoked, code is executed that copies the value of `N' to a temporary. And that same temporary serves as the actual high bound for the single dimension of the `A' array (the low bound being the constant 1). Since the user program cannot (legitimately) change the value of the temporary during execution of the procedure, the size of the array remains constant during each invocation. For alternate entry points, the code `g77' generates takes into account the possibility that a dummy adjustable array is not actually passed to the actual entry point being invoked at that time. In that case, the public procedure implementing the entry point passes to the master private procedure implementing all the code for the entry points a `NULL' pointer where a pointer to that adjustable array would be expected. The `g77'-generated code doesn't attempt to evaluate any of the expressions in the subscripts for an array if the pointer to that array is `NULL' at run time in such cases. (Don't depend on this particular implementation by writing code that purposely passes `NULL' pointers where the callee expects adjustable arrays, even if you know the callee won't reference the arrays--nor should you pass `NULL' pointers for any dummy arguments used in calculating the bounds of such arrays or leave undefined any values used for that purpose in COMMON--because the way `g77' implements these things might change in the future!)  File: g77.info, Node: Alternate Entry Points, Next: Alternate Returns, Prev: Adjustable Arrays, Up: Debugging and Interfacing Alternate Entry Points (ENTRY) ============================== The GBE does not understand the general concept of alternate entry points as Fortran provides via the ENTRY statement. `g77' gets around this by using an approach to compiling procedures having at least one `ENTRY' statement that is almost identical to the approach used by `f2c'. (An alternate approach could be used that would probably generate faster, but larger, code that would also be a bit easier to debug.) Information on how `g77' implements `ENTRY' is provided for those trying to debug such code. The choice of implementation seems unlikely to affect code (compiled in other languages) that interfaces to such code. `g77' compiles exactly one public procedure for the primary entry point of a procedure plus each `ENTRY' point it specifies, as usual. That is, in terms of the public interface, there is no difference between SUBROUTINE X END SUBROUTINE Y END and: SUBROUTINE X ENTRY Y END The difference between the above two cases lies in the code compiled for the `X' and `Y' procedures themselves, plus the fact that, for the second case, an extra internal procedure is compiled. For every Fortran procedure with at least one `ENTRY' statement, `g77' compiles an extra procedure named `__g77_masterfun_X', where X is the name of the primary entry point (which, in the above case, using the standard compiler options, would be `x_' in C). This extra procedure is compiled as a private procedure--that is, a procedure not accessible by name to separately compiled modules. It contains all the code in the program unit, including the code for the primary entry point plus for every entry point. (The code for each public procedure is quite short, and explained later.) The extra procedure has some other interesting characteristics. The argument list for this procedure is invented by `g77'. It contains a single integer argument named `__g77_which_entrypoint', passed by value (as in Fortran's `%VAL()' intrinsic), specifying the entry point index--0 for the primary entry point, 1 for the first entry point (the first `ENTRY' statement encountered), 2 for the second entry point, and so on. It also contains, for functions returning `CHARACTER' and (when `-ff2c' is in effect) `COMPLEX' functions, and for functions returning different types among the `ENTRY' statements (e.g. `REAL FUNCTION R()' containing `ENTRY I()'), an argument named `__g77_result' that is expected at run time to contain a pointer to where to store the result of the entry point. For `CHARACTER' functions, this storage area is an array of the appropriate number of characters; for `COMPLEX' functions, it is the appropriate area for the return type; for multiple-return-type functions, it is a union of all the supported return types (which cannot include `CHARACTER', since combining `CHARACTER' and non-`CHARACTER' return types via `ENTRY' in a single function is not supported by `g77'). For `CHARACTER' functions, the `__g77_result' argument is followed by yet another argument named `__g77_length' that, at run time, specifies the caller's expected length of the returned value. Note that only `CHARACTER*(*)' functions and entry points actually make use of this argument, even though it is always passed by all callers of public `CHARACTER' functions (since the caller does not generally know whether such a function is `CHARACTER*(*)' or whether there are any other callers that don't have that information). The rest of the argument list is the union of all the arguments specified for all the entry points (in their usual forms, e.g. `CHARACTER' arguments have extra length arguments, all appended at the end of this list). This is considered the "master list" of arguments. The code for this procedure has, before the code for the first executable statement, code much like that for the following Fortran statement: GOTO (100000,100001,100002), __g77_which_entrypoint 100000 ...code for primary entry point... 100001 ...code immediately following first ENTRY statement... 100002 ...code immediately following second ENTRY statement... (Note that invalid Fortran statement labels and variable names are used in the above example to highlight the fact that it represents code generated by the `g77' internals, not code to be written by the user.) It is this code that, when the procedure is called, picks which entry point to start executing. Getting back to the public procedures (`x' and `Y' in the original example), those procedures are fairly simple. Their interfaces are just like they would be if they were self-contained procedures (without `ENTRY'), of course, since that is what the callers expect. Their code consists of simply calling the private procedure, described above, with the appropriate extra arguments (the entry point index, and perhaps a pointer to a multiple-type- return variable, local to the public procedure, that contains all the supported returnable non-character types). For arguments that are not listed for a given entry point that are listed for other entry points, and therefore that are in the "master list" for the private procedure, null pointers (in C, the `NULL' macro) are passed. Also, for entry points that are part of a multiple-type- returning function, code is compiled after the call of the private procedure to extract from the multi-type union the appropriate result, depending on the type of the entry point in question, returning that result to the original caller. When debugging a procedure containing alternate entry points, you can either set a break point on the public procedure itself (e.g. a break point on `X' or `Y') or on the private procedure that contains most of the pertinent code (e.g. `__g77_masterfun_X'). If you do the former, you should use the debugger's command to "step into" the called procedure to get to the actual code; with the latter approach, the break point leaves you right at the actual code, skipping over the public entry point and its call to the private procedure (unless you have set a break point there as well, of course). Further, the list of dummy arguments that is visible when the private procedure is active is going to be the expanded version of the list for whichever particular entry point is active, as explained above, and the way in which return values are handled might well be different from how they would be handled for an equivalent single-entry function.  File: g77.info, Node: Alternate Returns, Next: Assigned Statement Labels, Prev: Alternate Entry Points, Up: Debugging and Interfacing Alternate Returns (SUBROUTINE and RETURN) ========================================= Subroutines with alternate returns (e.g. `SUBROUTINE X(*)' and `CALL X(*50)') are implemented by `g77' as functions returning the C `int' type. The actual alternate-return arguments are omitted from the calling sequence. Instead, the caller uses the return value to do a rough equivalent of the Fortran computed-`GOTO' statement, as in `GOTO (50), X()' in the example above (where `X' is quietly declared as an `INTEGER(KIND=1)' function), and the callee just returns whatever integer is specified in the `RETURN' statement for the subroutine For example, `RETURN 1' is implemented as `X = 1' followed by `RETURN' in C, and `RETURN' by itself is `X = 0' and `RETURN').  File: g77.info, Node: Assigned Statement Labels, Next: Run-time Library Errors, Prev: Alternate Returns, Up: Debugging and Interfacing Assigned Statement Labels (ASSIGN and GOTO) =========================================== For portability to machines where a pointer (such as to a label, which is how `g77' implements `ASSIGN' and its relatives, the assigned-`GOTO' and assigned-`FORMAT'-I/O statements) is wider (bitwise) than an `INTEGER(KIND=1)', `g77' uses a different memory location to hold the `ASSIGN'ed value of a variable than it does the numerical value in that variable, unless the variable is wide enough (can hold enough bits). In particular, while `g77' implements I = 10 as, in C notation, `i = 10;', it implements ASSIGN 10 TO I as, in GNU's extended C notation (for the label syntax), `__g77_ASSIGN_I = &&L10;' (where `L10' is just a massaging of the Fortran label `10' to make the syntax C-like; `g77' doesn't actually generate the name `L10' or any other name like that, since debuggers cannot access labels anyway). While this currently means that an `ASSIGN' statement does not overwrite the numeric contents of its target variable, _do not_ write any code depending on this feature. `g77' has already changed this implementation across versions and might do so in the future. This information is provided only to make debugging Fortran programs compiled with the current version of `g77' somewhat easier. If there's no debugger-visible variable named `__g77_ASSIGN_I' in a program unit that does `ASSIGN 10 TO I', that probably means `g77' has decided it can store the pointer to the label directly into `I' itself. *Note Ugly Assigned Labels::, for information on a command-line option to force `g77' to use the same storage for both normal and assigned-label uses of a variable.  File: g77.info, Node: Run-time Library Errors, Prev: Assigned Statement Labels, Up: Debugging and Interfacing Run-time Library Errors ======================= The `libg2c' library currently has the following table to relate error code numbers, returned in `IOSTAT=' variables, to messages. This information should, in future versions of this document, be expanded upon to include detailed descriptions of each message. In line with good coding practices, any of the numbers in the list below should _not_ be directly written into Fortran code you write. Instead, make a separate `INCLUDE' file that defines `PARAMETER' names for them, and use those in your code, so you can more easily change the actual numbers in the future. The information below is culled from the definition of `F_err' in `f/runtime/libI77/err.c' in the `g77' source tree. 100: "error in format" 101: "illegal unit number" 102: "formatted io not allowed" 103: "unformatted io not allowed" 104: "direct io not allowed" 105: "sequential io not allowed" 106: "can't backspace file" 107: "null file name" 108: "can't stat file" 109: "unit not connected" 110: "off end of record" 111: "truncation failed in endfile" 112: "incomprehensible list input" 113: "out of free space" 114: "unit not connected" 115: "read unexpected character" 116: "bad logical input field" 117: "bad variable type" 118: "bad namelist name" 119: "variable not in namelist" 120: "no end record" 121: "variable count incorrect" 122: "subscript for scalar variable" 123: "invalid array section" 124: "substring out of bounds" 125: "subscript out of bounds" 126: "can't read file" 127: "can't write file" 128: "'new' file exists" 129: "can't append to file" 130: "non-positive record number" 131: "I/O started while already doing I/O"  File: g77.info, Node: Collected Fortran Wisdom, Next: Trouble, Prev: Debugging and Interfacing, Up: Top Collected Fortran Wisdom ************************ Most users of `g77' can be divided into two camps: * Those writing new Fortran code to be compiled by `g77'. * Those using `g77' to compile existing, "legacy" code. Users writing new code generally understand most of the necessary aspects of Fortran to write "mainstream" code, but often need help deciding how to handle problems, such as the construction of libraries containing `BLOCK DATA'. Users dealing with "legacy" code sometimes don't have much experience with Fortran, but believe that the code they're compiling already works when compiled by other compilers (and might not understand why, as is sometimes the case, it doesn't work when compiled by `g77'). The following information is designed to help users do a better job coping with existing, "legacy" Fortran code, and with writing new code as well. * Menu: * Advantages Over f2c:: If `f2c' is so great, why `g77'? * Block Data and Libraries:: How `g77' solves a common problem. * Loops:: Fortran `DO' loops surprise many people. * Working Programs:: Getting programs to work should be done first. * Overly Convenient Options:: Temptations to avoid, habits to not form. * Faster Programs:: Everybody wants these, but at what cost?  File: g77.info, Node: Advantages Over f2c, Next: Block Data and Libraries, Up: Collected Fortran Wisdom Advantages Over f2c =================== Without `f2c', `g77' would have taken much longer to do and probably not been as good for quite a while. Sometimes people who notice how much `g77' depends on, and documents encouragement to use, `f2c' ask why `g77' was created if `f2c' already existed. This section gives some basic answers to these questions, though it is not intended to be comprehensive. * Menu: * Language Extensions:: Features used by Fortran code. * Diagnostic Abilities:: Abilities to spot problems early. * Compiler Options:: Features helpful to accommodate legacy code, etc. * Compiler Speed:: Speed of the compilation process. * Program Speed:: Speed of the generated, optimized code. * Ease of Debugging:: Debugging ease-of-use at the source level. * Character and Hollerith Constants:: A byte saved is a byte earned.  File: g77.info, Node: Language Extensions, Next: Diagnostic Abilities, Up: Advantages Over f2c Language Extensions ------------------- `g77' offers several extensions to FORTRAN 77 language that `f2c' doesn't: * Automatic arrays * `CYCLE' and `EXIT' * Construct names * `SELECT CASE' * `KIND=' and `LEN=' notation * Semicolon as statement separator * Constant expressions in `FORMAT' statements (such as `FORMAT(I)', where `J' is a `PARAMETER' named constant) * `MvBits' intrinsic * `libU77' (Unix-compatibility) library, with routines known to compiler as intrinsics (so they work even when compiler options are used to change the interfaces used by Fortran routines) `g77' also implements iterative `DO' loops so that they work even in the presence of certain "extreme" inputs, unlike `f2c'. *Note Loops::. However, `f2c' offers a few that `g77' doesn't, such as: * Intrinsics in `PARAMETER' statements * Array bounds expressions (such as `REAL M(N(2))') * `AUTOMATIC' statement It is expected that `g77' will offer some or all of these missing features at some time in the future.  File: g77.info, Node: Diagnostic Abilities, Next: Compiler Options, Prev: Language Extensions, Up: Advantages Over f2c Diagnostic Abilities -------------------- `g77' offers better diagnosis of problems in `FORMAT' statements. `f2c' doesn't, for example, emit any diagnostic for `FORMAT(XZFAJG10324)', leaving that to be diagnosed, at run time, by the `libf2c' run-time library.  File: g77.info, Node: Compiler Options, Next: Compiler Speed, Prev: Diagnostic Abilities, Up: Advantages Over f2c Compiler Options ---------------- `g77' offers compiler options that `f2c' doesn't, most of which are designed to more easily accommodate legacy code: * Two that control the automatic appending of extra underscores to external names * One that allows dollar signs (`$') in symbol names * A variety that control acceptance of various "ugly" constructs * Several that specify acceptable use of upper and lower case in the source code * Many that enable, disable, delete, or hide groups of intrinsics * One to specify the length of fixed-form source lines (normally 72) * One to specify the the source code is written in Fortran-90-style free-form However, `f2c' offers a few that `g77' doesn't, like an option to have `REAL' default to `REAL*8'. It is expected that `g77' will offer all of the missing options pertinent to being a Fortran compiler at some time in the future.  File: g77.info, Node: Compiler Speed, Next: Program Speed, Prev: Compiler Options, Up: Advantages Over f2c Compiler Speed -------------- Saving the steps of writing and then rereading C code is a big reason why `g77' should be able to compile code much faster than using `f2c' in conjunction with the equivalent invocation of `gcc'. However, due to `g77''s youth, lots of self-checking is still being performed. As a result, this improvement is as yet unrealized (though the potential seems to be there for quite a big speedup in the future). It is possible that, as of version 0.5.18, `g77' is noticeably faster compiling many Fortran source files than using `f2c' in conjunction with `gcc'.  File: g77.info, Node: Program Speed, Next: Ease of Debugging, Prev: Compiler Speed, Up: Advantages Over f2c Program Speed ------------- `g77' has the potential to better optimize code than `f2c', even when `gcc' is used to compile the output of `f2c', because `f2c' must necessarily translate Fortran into a somewhat lower-level language (C) that cannot preserve all the information that is potentially useful for optimization, while `g77' can gather, preserve, and transmit that information directly to the GBE. For example, `g77' implements `ASSIGN' and assigned `GOTO' using direct assignment of pointers to labels and direct jumps to labels, whereas `f2c' maps the assigned labels to integer values and then uses a C `switch' statement to encode the assigned `GOTO' statements. However, as is typical, theory and reality don't quite match, at least not in all cases, so it is still the case that `f2c' plus `gcc' can generate code that is faster than `g77'. Version 0.5.18 of `g77' offered default settings and options, via patches to the `gcc' back end, that allow for better program speed, though some of these improvements also affected the performance of programs translated by `f2c' and then compiled by `g77''s version of `gcc'. Version 0.5.20 of `g77' offers further performance improvements, at least one of which (alias analysis) is not generally applicable to `f2c' (though `f2c' could presumably be changed to also take advantage of this new capability of the `gcc' back end, assuming this is made available in an upcoming release of `gcc').  File: g77.info, Node: Ease of Debugging, Next: Character and Hollerith Constants, Prev: Program Speed, Up: Advantages Over f2c Ease of Debugging ----------------- Because `g77' compiles directly to assembler code like `gcc', instead of translating to an intermediate language (C) as does `f2c', support for debugging can be better for `g77' than `f2c'. However, although `g77' might be somewhat more "native" in terms of debugging support than `f2c' plus `gcc', there still are a lot of things "not quite right". Many of the important ones should be resolved in the near future. For example, `g77' doesn't have to worry about reserved names like `f2c' does. Given `FOR = WHILE', `f2c' must necessarily translate this to something _other_ than `for = while;', because C reserves those words. However, `g77' does still uses things like an extra level of indirection for `ENTRY'-laden procedures--in this case, because the back end doesn't yet support multiple entry points. Another example is that, given COMMON A, B EQUIVALENCE (B, C) the `g77' user should be able to access the variables directly, by name, without having to traverse C-like structures and unions, while `f2c' is unlikely to ever offer this ability (due to limitations in the C language). Yet another example is arrays. `g77' represents them to the debugger using the same "dimensionality" as in the source code, while `f2c' must necessarily convert them all to one-dimensional arrays to fit into the confines of the C language. However, the level of support offered by debuggers for interactive Fortran-style access to arrays as compiled by `g77' can vary widely. In some cases, it can actually be an advantage that `f2c' converts everything to widely supported C semantics. In fairness, `g77' could do many of the things `f2c' does to get things working at least as well as `f2c'--for now, the developers prefer making `g77' work the way they think it is supposed to, and finding help improving the other products (the back end of `gcc'; `gdb'; and so on) to get things working properly.  File: g77.info, Node: Character and Hollerith Constants, Prev: Ease of Debugging, Up: Advantages Over f2c Character and Hollerith Constants --------------------------------- To avoid the extensive hassle that would be needed to avoid this, `f2c' uses C character constants to encode character and Hollerith constants. That means a constant like `'HELLO'' is translated to `"hello"' in C, which further means that an extra null byte is present at the end of the constant. This null byte is superfluous. `g77' does not generate such null bytes. This represents significant savings of resources, such as on systems where `/dev/null' or `/dev/zero' represent bottlenecks in the systems' performance, because `g77' simply asks for fewer zeros from the operating system than `f2c'. (Avoiding spurious use of zero bytes, each byte typically have eight zero bits, also reduces the liabilities in case Microsoft's rumored patent on the digits 0 and 1 is upheld.)  File: g77.info, Node: Block Data and Libraries, Next: Loops, Prev: Advantages Over f2c, Up: Collected Fortran Wisdom Block Data and Libraries ======================== To ensure that block data program units are linked, especially a concern when they are put into libraries, give each one a name (as in `BLOCK DATA FOO') and make sure there is an `EXTERNAL FOO' statement in every program unit that uses any common block initialized by the corresponding `BLOCK DATA'. `g77' currently compiles a `BLOCK DATA' as if it were a `SUBROUTINE', that is, it generates an actual procedure having the appropriate name. The procedure does nothing but return immediately if it happens to be called. For `EXTERNAL FOO', where `FOO' is not otherwise referenced in the same program unit, `g77' assumes there exists a `BLOCK DATA FOO' in the program and ensures that by generating a reference to it so the linker will make sure it is present. (Specifically, `g77' outputs in the data section a static pointer to the external name `FOO'.) The implementation `g77' currently uses to make this work is one of the few things not compatible with `f2c' as currently shipped. `f2c' currently does nothing with `EXTERNAL FOO' except issue a warning that `FOO' is not otherwise referenced, and, for `BLOCK DATA FOO', `f2c' doesn't generate a dummy procedure with the name `FOO'. The upshot is that you shouldn't mix `f2c' and `g77' in this particular case. If you use `f2c' to compile `BLOCK DATA FOO', then any `g77'-compiled program unit that says `EXTERNAL FOO' will result in an unresolved reference when linked. If you do the opposite, then `FOO' might not be linked in under various circumstances (such as when `FOO' is in a library, or you're using a "clever" linker--so clever, it produces a broken program with little or no warning by omitting initializations of global data because they are contained in unreferenced procedures). The changes you make to your code to make `g77' handle this situation, however, appear to be a widely portable way to handle it. That is, many systems permit it (as they should, since the FORTRAN 77 standard permits `EXTERNAL FOO' when `FOO' is a block data program unit), and of the ones that might not link `BLOCK DATA FOO' under some circumstances, most of them appear to do so once `EXTERNAL FOO' is present in the appropriate program units. Here is the recommended approach to modifying a program containing a program unit such as the following: BLOCK DATA FOO COMMON /VARS/ X, Y, Z DATA X, Y, Z / 3., 4., 5. / END If the above program unit might be placed in a library module, then ensure that every program unit in every program that references that particular `COMMON' area uses the `EXTERNAL' statement to force the area to be initialized. For example, change a program unit that starts with INTEGER FUNCTION CURX() COMMON /VARS/ X, Y, Z CURX = X END so that it uses the `EXTERNAL' statement, as in: INTEGER FUNCTION CURX() COMMON /VARS/ X, Y, Z EXTERNAL FOO CURX = X END That way, `CURX' is compiled by `g77' (and many other compilers) so that the linker knows it must include `FOO', the `BLOCK DATA' program unit that sets the initial values for the variables in `VAR', in the executable program.  File: g77.info, Node: Loops, Next: Working Programs, Prev: Block Data and Libraries, Up: Collected Fortran Wisdom Loops ===== The meaning of a `DO' loop in Fortran is precisely specified in the Fortran standard...and is quite different from what many programmers might expect. In particular, Fortran iterative `DO' loops are implemented as if the number of trips through the loop is calculated _before_ the loop is entered. The number of trips for a loop is calculated from the START, END, and INCREMENT values specified in a statement such as: DO ITER = START, END, INCREMENT The trip count is evaluated using a fairly simple formula based on the three values following the `=' in the statement, and it is that trip count that is effectively decremented during each iteration of the loop. If, at the beginning of an iteration of the loop, the trip count is zero or negative, the loop terminates. The per-loop-iteration modifications to ITER are not related to determining whether to terminate the loop. There are two important things to remember about the trip count: * It can be _negative_, in which case it is treated as if it was zero--meaning the loop is not executed at all. * The type used to _calculate_ the trip count is the same type as ITER, but the final calculation, and thus the type of the trip count itself, always is `INTEGER(KIND=1)'. These two items mean that there are loops that cannot be written in straightforward fashion using the Fortran `DO'. For example, on a system with the canonical 32-bit two's-complement implementation of `INTEGER(KIND=1)', the following loop will not work: DO I = -2000000000, 2000000000 Although the START and END values are well within the range of `INTEGER(KIND=1)', the _trip count_ is not. The expected trip count is 40000000001, which is outside the range of `INTEGER(KIND=1)' on many systems. Instead, the above loop should be constructed this way: I = -2000000000 DO IF (I .GT. 2000000000) EXIT ... I = I + 1 END DO The simple `DO' construct and the `EXIT' statement (used to leave the innermost loop) are F90 features that `g77' supports. Some Fortran compilers have buggy implementations of `DO', in that they don't follow the standard. They implement `DO' as a straightforward translation to what, in C, would be a `for' statement. Instead of creating a temporary variable to hold the trip count as calculated at run time, these compilers use the iteration variable ITER to control whether the loop continues at each iteration. The bug in such an implementation shows up when the trip count is within the range of the type of ITER, but the magnitude of `ABS(END) + ABS(INCR)' exceeds that range. For example: DO I = 2147483600, 2147483647 A loop started by the above statement will work as implemented by `g77', but the use, by some compilers, of a more C-like implementation akin to for (i = 2147483600; i <= 2147483647; ++i) produces a loop that does not terminate, because `i' can never be greater than 2147483647, since incrementing it beyond that value overflows `i', setting it to -2147483648. This is a large, negative number that still is less than 2147483647. Another example of unexpected behavior of `DO' involves using a nonintegral iteration variable ITER, that is, a `REAL' variable. Consider the following program: DATA BEGIN, END, STEP /.1, .31, .007/ DO 10 R = BEGIN, END, STEP IF (R .GT. END) PRINT *, R, ' .GT. ', END, '!!' PRINT *,R 10 CONTINUE PRINT *,'LAST = ',R IF (R .LE. END) PRINT *, R, ' .LE. ', END, '!!' END A C-like view of `DO' would hold that the two "exclamatory" `PRINT' statements are never executed. However, this is the output of running the above program as compiled by `g77' on a GNU/Linux ix86 system: .100000001 .107000001 .114 .120999999 ... .289000005 .296000004 .303000003 LAST = .310000002 .310000002 .LE. .310000002!! Note that one of the two checks in the program turned up an apparent violation of the programmer's expectation--yet, the loop is correctly implemented by `g77', in that it has 30 iterations. This trip count of 30 is correct when evaluated using the floating-point representations for the BEGIN, END, and INCR values (.1, .31, .007) on GNU/Linux ix86 are used. On other systems, an apparently more accurate trip count of 31 might result, but, nevertheless, `g77' is faithfully following the Fortran standard, and the result is not what the author of the sample program above apparently expected. (Such other systems might, for different values in the `DATA' statement, violate the other programmer's expectation, for example.) Due to this combination of imprecise representation of floating-point values and the often-misunderstood interpretation of `DO' by standard-conforming compilers such as `g77', use of `DO' loops with `REAL' iteration variables is not recommended. Such use can be caught by specifying `-Wsurprising'. *Note Warning Options::, for more information on this option.  File: g77.info, Node: Working Programs, Next: Overly Convenient Options, Prev: Loops, Up: Collected Fortran Wisdom Working Programs ================ Getting Fortran programs to work in the first place can be quite a challenge--even when the programs already work on other systems, or when using other compilers. `g77' offers some facilities that might be useful for tracking down bugs in such programs. * Menu: * Not My Type:: * Variables Assumed To Be Zero:: * Variables Assumed To Be Saved:: * Unwanted Variables:: * Unused Arguments:: * Surprising Interpretations of Code:: * Aliasing Assumed To Work:: * Output Assumed To Flush:: * Large File Unit Numbers:: * Floating-point precision:: * Inconsistent Calling Sequences::  File: g77.info, Node: Not My Type, Next: Variables Assumed To Be Zero, Up: Working Programs Not My Type ----------- A fruitful source of bugs in Fortran source code is use, or mis-use, of Fortran's implicit-typing feature, whereby the type of a variable, array, or function is determined by the first character of its name. Simple cases of this include statements like `LOGX=9.227', without a statement such as `REAL LOGX'. In this case, `LOGX' is implicitly given `INTEGER(KIND=1)' type, with the result of the assignment being that it is given the value `9'. More involved cases include a function that is defined starting with a statement like `DOUBLE PRECISION FUNCTION IPS(...)'. Any caller of this function that does not also declare `IPS' as type `DOUBLE PRECISION' (or, in GNU Fortran, `REAL(KIND=2)') is likely to assume it returns `INTEGER', or some other type, leading to invalid results or even program crashes. The `-Wimplicit' option might catch failures to properly specify the types of variables, arrays, and functions in the code. However, in code that makes heavy use of Fortran's implicit-typing facility, this option might produce so many warnings about cases that are working, it would be hard to find the one or two that represent bugs. This is why so many experienced Fortran programmers strongly recommend widespread use of the `IMPLICIT NONE' statement, despite it not being standard FORTRAN 77, to completely turn off implicit typing. (`g77' supports `IMPLICIT NONE', as do almost all FORTRAN 77 compilers.) Note that `-Wimplicit' catches only implicit typing of _names_. It does not catch implicit typing of expressions such as `X**(2/3)'. Such expressions can be buggy as well--in fact, `X**(2/3)' is equivalent to `X**0', due to the way Fortran expressions are given types and then evaluated. (In this particular case, the programmer probably wanted `X**(2./3.)'.)  File: g77.info, Node: Variables Assumed To Be Zero, Next: Variables Assumed To Be Saved, Prev: Not My Type, Up: Working Programs Variables Assumed To Be Zero ---------------------------- Many Fortran programs were developed on systems that provided automatic initialization of all, or some, variables and arrays to zero. As a result, many of these programs depend, sometimes inadvertently, on this behavior, though to do so violates the Fortran standards. You can ask `g77' for this behavior by specifying the `-finit-local-zero' option when compiling Fortran code. (You might want to specify `-fno-automatic' as well, to avoid code-size inflation for non-optimized compilations.) Note that a program that works better when compiled with the `-finit-local-zero' option is almost certainly depending on a particular system's, or compiler's, tendency to initialize some variables to zero. It might be worthwhile finding such cases and fixing them, using techniques such as compiling with the `-O -Wuninitialized' options using `g77'.  File: g77.info, Node: Variables Assumed To Be Saved, Next: Unwanted Variables, Prev: Variables Assumed To Be Zero, Up: Working Programs Variables Assumed To Be Saved ----------------------------- Many Fortran programs were developed on systems that saved the values of all, or some, variables and arrays across procedure calls. As a result, many of these programs depend, sometimes inadvertently, on being able to assign a value to a variable, perform a `RETURN' to a calling procedure, and, upon subsequent invocation, reference the previously assigned variable to obtain the value. They expect this despite not using the `SAVE' statement to specify that the value in a variable is expected to survive procedure returns and calls. Depending on variables and arrays to retain values across procedure calls without using `SAVE' to require it violates the Fortran standards. You can ask `g77' to assume `SAVE' is specified for all relevant (local) variables and arrays by using the `-fno-automatic' option. Note that a program that works better when compiled with the `-fno-automatic' option is almost certainly depending on not having to use the `SAVE' statement as required by the Fortran standard. It might be worthwhile finding such cases and fixing them, using techniques such as compiling with the `-O -Wuninitialized' options using `g77'.  File: g77.info, Node: Unwanted Variables, Next: Unused Arguments, Prev: Variables Assumed To Be Saved, Up: Working Programs Unwanted Variables ------------------ The `-Wunused' option can find bugs involving implicit typing, sometimes more easily than using `-Wimplicit' in code that makes heavy use of implicit typing. An unused variable or array might indicate that the spelling for its declaration is different from that of its intended uses. Other than cases involving typos, unused variables rarely indicate actual bugs in a program. However, investigating such cases thoroughly has, on occasion, led to the discovery of code that had not been completely written--where the programmer wrote declarations as needed for the whole algorithm, wrote some or even most of the code for that algorithm, then got distracted and forgot that the job was not complete.  File: g77.info, Node: Unused Arguments, Next: Surprising Interpretations of Code, Prev: Unwanted Variables, Up: Working Programs Unused Arguments ---------------- As with unused variables, It is possible that unused arguments to a procedure might indicate a bug. Compile with `-W -Wunused' option to catch cases of unused arguments. Note that `-W' also enables warnings regarding overflow of floating-point constants under certain circumstances.  File: g77.info, Node: Surprising Interpretations of Code, Next: Aliasing Assumed To Work, Prev: Unused Arguments, Up: Working Programs Surprising Interpretations of Code ---------------------------------- The `-Wsurprising' option can help find bugs involving expression evaluation or in the way `DO' loops with non-integral iteration variables are handled. Cases found by this option might indicate a difference of interpretation between the author of the code involved, and a standard-conforming compiler such as `g77'. Such a difference might produce actual bugs. In any case, changing the code to explicitly do what the programmer might have expected it to do, so `g77' and other compilers are more likely to follow the programmer's expectations, might be worthwhile, especially if such changes make the program work better.  File: g77.info, Node: Aliasing Assumed To Work, Next: Output Assumed To Flush, Prev: Surprising Interpretations of Code, Up: Working Programs Aliasing Assumed To Work ------------------------ The `-falias-check', `-fargument-alias', `-fargument-noalias', and `-fno-argument-noalias-global' options, introduced in version 0.5.20 and `g77''s version 2.7.2.2.f.2 of `gcc', were withdrawn as of `g77' version 0.5.23 due to their not being supported by `gcc' version 2.8. These options control the assumptions regarding aliasing (overlapping) of writes and reads to main memory (core) made by the `gcc' back end. The information below still is useful, but applies to only those versions of `g77' that support the alias analysis implied by support for these options. These options are effective only when compiling with `-O' (specifying any level other than `-O0') or with `-falias-check'. The default for Fortran code is `-fargument-noalias-global'. (The default for C code and code written in other C-based languages is `-fargument-alias'. These defaults apply regardless of whether you use `g77' or `gcc' to compile your code.) Note that, on some systems, compiling with `-fforce-addr' in effect can produce more optimal code when the default aliasing options are in effect (and when optimization is enabled). If your program is not working when compiled with optimization, it is possible it is violating the Fortran standards (77 and 90) by relying on the ability to "safely" modify variables and arrays that are aliased, via procedure calls, to other variables and arrays, without using `EQUIVALENCE' to explicitly set up this kind of aliasing. (The FORTRAN 77 standard's prohibition of this sort of overlap, generally referred to therein as "storage association", appears in Sections 15.9.3.6. This prohibition allows implementations, such as `g77', to, for example, implement the passing of procedures and even values in `COMMON' via copy operations into local, perhaps more efficiently accessed temporaries at entry to a procedure, and, where appropriate, via copy operations back out to their original locations in memory at exit from that procedure, without having to take into consideration the order in which the local copies are updated by the code, among other things.) To test this hypothesis, try compiling your program with the `-fargument-alias' option, which causes the compiler to revert to assumptions essentially the same as made by versions of `g77' prior to 0.5.20. If the program works using this option, that strongly suggests that the bug is in your program. Finding and fixing the bug(s) should result in a program that is more standard-conforming and that can be compiled by `g77' in a way that results in a faster executable. (You might want to try compiling with `-fargument-noalias', a kind of half-way point, to see if the problem is limited to aliasing between dummy arguments and `COMMON' variables--this option assumes that such aliasing is not done, while still allowing aliasing among dummy arguments.) An example of aliasing that is invalid according to the standards is shown in the following program, which might _not_ produce the expected results when executed: I = 1 CALL FOO(I, I) PRINT *, I END SUBROUTINE FOO(J, K) J = J + K K = J * K PRINT *, J, K END The above program attempts to use the temporary aliasing of the `J' and `K' arguments in `FOO' to effect a pathological behavior--the simultaneous changing of the values of _both_ `J' and `K' when either one of them is written. The programmer likely expects the program to print these values: 2 4 4 However, since the program is not standard-conforming, an implementation's behavior when running it is undefined, because subroutine `FOO' modifies at least one of the arguments, and they are aliased with each other. (Even if one of the assignment statements was deleted, the program would still violate these rules. This kind of on-the-fly aliasing is permitted by the standard only when none of the aliased items are defined, or written, while the aliasing is in effect.) As a practical example, an optimizing compiler might schedule the `J =' part of the second line of `FOO' _after_ the reading of `J' and `K' for the `J * K' expression, resulting in the following output: 2 2 2 Essentially, compilers are promised (by the standard and, therefore, by programmers who write code they claim to be standard-conforming) that if they cannot detect aliasing via static analysis of a single program unit's `EQUIVALENCE' and `COMMON' statements, no such aliasing exists. In such cases, compilers are free to assume that an assignment to one variable will not change the value of another variable, allowing it to avoid generating code to re-read the value of the other variable, to re-schedule reads and writes, and so on, to produce a faster executable. The same promise holds true for arrays (as seen by the called procedure)--an element of one dummy array cannot be aliased with, or overlap, any element of another dummy array or be in a `COMMON' area known to the procedure. (These restrictions apply only when the procedure defines, or writes to, one of the aliased variables or arrays.) Unfortunately, there is no way to find _all_ possible cases of violations of the prohibitions against aliasing in Fortran code. Static analysis is certainly imperfect, as is run-time analysis, since neither can catch all violations. (Static analysis can catch all likely violations, and some that might never actually happen, while run-time analysis can catch only those violations that actually happen during a particular run. Neither approach can cope with programs mixing Fortran code with routines written in other languages, however.) Currently, `g77' provides neither static nor run-time facilities to detect any cases of this problem, although other products might. Run-time facilities are more likely to be offered by future versions of `g77', though patches improving `g77' so that it provides either form of detection are welcome.  File: g77.info, Node: Output Assumed To Flush, Next: Large File Unit Numbers, Prev: Aliasing Assumed To Work, Up: Working Programs Output Assumed To Flush ----------------------- For several versions prior to 0.5.20, `g77' configured its version of the `libf2c' run-time library so that one of its configuration macros, `ALWAYS_FLUSH', was defined. This was done as a result of a belief that many programs expected output to be flushed to the operating system (under UNIX, via the `fflush()' library call) with the result that errors, such as disk full, would be immediately flagged via the relevant `ERR=' and `IOSTAT=' mechanism. Because of the adverse effects this approach had on the performance of many programs, `g77' no longer configures `libf2c' (now named `libg2c' in its `g77' incarnation) to always flush output. If your program depends on this behavior, either insert the appropriate `CALL FLUSH' statements, or modify the sources to the `libg2c', rebuild and reinstall `g77', and relink your programs with the modified library. (Ideally, `libg2c' would offer the choice at run-time, so that a compile-time option to `g77' or `f2c' could result in generating the appropriate calls to flushing or non-flushing library routines.) Some Fortran programs require output (writes) to be flushed to the operating system (under UNIX, via the `fflush()' library call) so that errors, such as disk full, are immediately flagged via the relevant `ERR=' and `IOSTAT=' mechanism, instead of such errors being flagged later as subsequent writes occur, forcing the previously written data to disk, or when the file is closed. Essentially, the difference can be viewed as synchronous error reporting (immediate flagging of errors during writes) versus asynchronous, or, more precisely, buffered error reporting (detection of errors might be delayed). `libg2c' supports flagging write errors immediately when it is built with the `ALWAYS_FLUSH' macro defined. This results in a `libg2c' that runs slower, sometimes quite a bit slower, under certain circumstances--for example, accessing files via the networked file system NFS--but the effect can be more reliable, robust file I/O. If you know that Fortran programs requiring this level of precision of error reporting are to be compiled using the version of `g77' you are building, you might wish to modify the `g77' source tree so that the version of `libg2c' is built with the `ALWAYS_FLUSH' macro defined, enabling this behavior. To do this, find this line in `gcc/libf2c/f2c.h' in your `g77' source tree: /* #define ALWAYS_FLUSH */ Remove the leading `/* ', so the line begins with `#define', and the trailing ` */'. Then build or rebuild `g77' as appropriate.  File: g77.info, Node: Large File Unit Numbers, Next: Floating-point precision, Prev: Output Assumed To Flush, Up: Working Programs Large File Unit Numbers ----------------------- If your program crashes at run time with a message including the text `illegal unit number', that probably is a message from the run-time library, `libg2c'. The message means that your program has attempted to use a file unit number that is out of the range accepted by `libg2c'. Normally, this range is 0 through 99, and the high end of the range is controlled by a `libg2c' source-file macro named `MXUNIT'. If you can easily change your program to use unit numbers in the range 0 through 99, you should do so. As distributed, whether as part of `f2c' or `g77', `libf2c' accepts file unit numbers only in the range 0 through 99. For example, a statement such as `WRITE (UNIT=100)' causes a run-time crash in `libf2c', because the unit number, 100, is out of range. If you know that Fortran programs at your installation require the use of unit numbers higher than 99, you can change the value of the `MXUNIT' macro, which represents the maximum unit number, to an appropriately higher value. To do this, edit the file `gcc/libf2c/libI77/fio.h' in your `g77' source tree, changing the following line: #define MXUNIT 100 Change the line so that the value of `MXUNIT' is defined to be at least one _greater_ than the maximum unit number used by the Fortran programs on your system. (For example, a program that does `WRITE (UNIT=255)' would require `MXUNIT' set to at least 256 to avoid crashing.) Then build or rebuild `g77' as appropriate. _Note:_ Changing this macro has _no_ effect on other limits your system might place on the number of files open at the same time. That is, the macro might allow a program to do `WRITE (UNIT=100)', but the library and operating system underlying `libf2c' might disallow it if many other files have already been opened (via `OPEN' or implicitly via `READ', `WRITE', and so on). Information on how to increase these other limits should be found in your system's documentation.  File: g77.info, Node: Floating-point precision, Next: Inconsistent Calling Sequences, Prev: Large File Unit Numbers, Up: Working Programs Floating-point precision ------------------------ If your program depends on exact IEEE 754 floating-point handling it may help on some systems--specifically x86 or m68k hardware--to use the `-ffloat-store' option or to reset the precision flag on the floating-point unit. *Note Optimize Options::. However, it might be better simply to put the FPU into double precision mode and not take the performance hit of `-ffloat-store'. On x86 and m68k GNU systems you can do this with a technique similar to that for turning on floating-point exceptions (*note Floating-point Exception Handling::). The control word could be set to double precision by some code like this one: #include { fpu_control_t cw = (_FPU_DEFAULT & ~_FPU_EXTENDED) | _FPU_DOUBLE; _FPU_SETCW(cw); } (It is not clear whether this has any effect on the operation of the GNU maths library, but we have no evidence of it causing trouble.) Some targets (such as the Alpha) may need special options for full IEEE conformance. *Note Hardware Models and Configurations: (gcc)Submodel Options.  File: g77.info, Node: Inconsistent Calling Sequences, Prev: Floating-point precision, Up: Working Programs Inconsistent Calling Sequences ------------------------------ Code containing inconsistent calling sequences in the same file is normally rejected--see *Note GLOBALS::. (Use, say, `ftnchek' to ensure consistency across source files. *Note Generating Skeletons and Prototypes with `f2c': f2c Skeletons and Prototypes.) Mysterious errors, which may appear to be code generation problems, can appear specifically on the x86 architecture with some such inconsistencies. On x86 hardware, floating-point return values of functions are placed on the floating-point unit's register stack, not the normal stack. Thus calling a `REAL' or `DOUBLE PRECISION' `FUNCTION' as some other sort of procedure, or vice versa, scrambles the floating-point stack. This may break unrelated code executed later. Similarly if, say, external C routines are written incorrectly.  File: g77.info, Node: Overly Convenient Options, Next: Faster Programs, Prev: Working Programs, Up: Collected Fortran Wisdom Overly Convenient Command-line Options ====================================== These options should be used only as a quick-and-dirty way to determine how well your program will run under different compilation models without having to change the source. Some are more problematic than others, depending on how portable and maintainable you want the program to be (and, of course, whether you are allowed to change it at all is crucial). You should not continue to use these command-line options to compile a given program, but rather should make changes to the source code: `-finit-local-zero' (This option specifies that any uninitialized local variables and arrays have default initialization to binary zeros.) Many other compilers do this automatically, which means lots of Fortran code developed with those compilers depends on it. It is safer (and probably would produce a faster program) to find the variables and arrays that need such initialization and provide it explicitly via `DATA', so that `-finit-local-zero' is not needed. Consider using `-Wuninitialized' (which requires `-O') to find likely candidates, but do not specify `-finit-local-zero' or `-fno-automatic', or this technique won't work. `-fno-automatic' (This option specifies that all local variables and arrays are to be treated as if they were named in `SAVE' statements.) Many other compilers do this automatically, which means lots of Fortran code developed with those compilers depends on it. The effect of this is that all non-automatic variables and arrays are made static, that is, not placed on the stack or in heap storage. This might cause a buggy program to appear to work better. If so, rather than relying on this command-line option (and hoping all compilers provide the equivalent one), add `SAVE' statements to some or all program unit sources, as appropriate. Consider using `-Wuninitialized' (which requires `-O') to find likely candidates, but do not specify `-finit-local-zero' or `-fno-automatic', or this technique won't work. The default is `-fautomatic', which tells `g77' to try and put variables and arrays on the stack (or in fast registers) where possible and reasonable. This tends to make programs faster. _Note:_ Automatic variables and arrays are not affected by this option. These are variables and arrays that are _necessarily_ automatic, either due to explicit statements, or due to the way they are declared. Examples include local variables and arrays not given the `SAVE' attribute in procedures declared `RECURSIVE', and local arrays declared with non-constant bounds (automatic arrays). Currently, `g77' supports only automatic arrays, not `RECURSIVE' procedures or other means of explicitly specifying that variables or arrays are automatic. `-fGROUP-intrinsics-hide' Change the source code to use `EXTERNAL' for any external procedure that might be the name of an intrinsic. It is easy to find these using `-fGROUP-intrinsics-disable'.  File: g77.info, Node: Faster Programs, Prev: Overly Convenient Options, Up: Collected Fortran Wisdom Faster Programs =============== Aside from the usual `gcc' options, such as `-O', `-ffast-math', and so on, consider trying some of the following approaches to speed up your program (once you get it working). * Menu: * Aligned Data:: * Prefer Automatic Uninitialized Variables:: * Avoid f2c Compatibility:: * Use Submodel Options::  File: g77.info, Node: Aligned Data, Next: Prefer Automatic Uninitialized Variables, Up: Faster Programs Aligned Data ------------ On some systems, such as those with Pentium Pro CPUs, programs that make heavy use of `REAL(KIND=2)' (`DOUBLE PRECISION') might run much slower than possible due to the compiler not aligning these 64-bit values to 64-bit boundaries in memory. (The effect also is present, though to a lesser extent, on the 586 (Pentium) architecture.) The Intel x86 architecture generally ensures that these programs will work on all its implementations, but particular implementations (such as Pentium Pro) perform better with more strict alignment. (Such behavior isn't unique to the Intel x86 architecture.) Other architectures might _demand_ 64-bit alignment of 64-bit data. There are a variety of approaches to use to address this problem: * Order your `COMMON' and `EQUIVALENCE' areas such that the variables and arrays with the widest alignment guidelines come first. For example, on most systems, this would mean placing `COMPLEX(KIND=2)', `REAL(KIND=2)', and `INTEGER(KIND=2)' entities first, followed by `REAL(KIND=1)', `INTEGER(KIND=1)', and `LOGICAL(KIND=1)' entities, then `INTEGER(KIND=6)' entities, and finally `CHARACTER' and `INTEGER(KIND=3)' entities. The reason to use such placement is it makes it more likely that your data will be aligned properly, without requiring you to do detailed analysis of each aggregate (`COMMON' and `EQUIVALENCE') area. Specifically, on systems where the above guidelines are appropriate, placing `CHARACTER' entities before `REAL(KIND=2)' entities can work just as well, but only if the number of bytes occupied by the `CHARACTER' entities is divisible by the recommended alignment for `REAL(KIND=2)'. By ordering the placement of entities in aggregate areas according to the simple guidelines above, you avoid having to carefully count the number of bytes occupied by each entity to determine whether the actual alignment of each subsequent entity meets the alignment guidelines for the type of that entity. If you don't ensure correct alignment of `COMMON' elements, the compiler may be forced by some systems to violate the Fortran semantics by adding padding to get `DOUBLE PRECISION' data properly aligned. If the unfortunate practice is employed of overlaying different types of data in the `COMMON' block, the different variants of this block may become misaligned with respect to each other. Even if your platform doesn't require strict alignment, `COMMON' should be laid out as above for portability. (Unfortunately the FORTRAN 77 standard didn't anticipate this possible requirement, which is compiler-independent on a given platform.) * Use the (x86-specific) `-malign-double' option when compiling programs for the Pentium and Pentium Pro architectures (called 586 and 686 in the `gcc' configuration subsystem). The warning about this in the `gcc' manual isn't generally relevant to Fortran, but using it will force `COMMON' to be padded if necessary to align `DOUBLE PRECISION' data. When `DOUBLE PRECISION' data is forcibly aligned in `COMMON' by `g77' due to specifying `-malign-double', `g77' issues a warning about the need to insert padding. In this case, each and every program unit that uses the same `COMMON' area must specify the same layout of variables and their types for that area and be compiled with `-malign-double' as well. `g77' will issue warnings in each case, but as long as every program unit using that area is compiled with the same warnings, the resulting object files should work when linked together unless the program makes additional assumptions about `COMMON' area layouts that are outside the scope of the FORTRAN 77 standard, or uses `EQUIVALENCE' or different layouts in ways that assume no padding is ever inserted by the compiler. * Ensure that `crt0.o' or `crt1.o' on your system guarantees a 64-bit aligned stack for `main()'. The recent one from GNU (`glibc2') will do this on x86 systems, but we don't know of any other x86 setups where it will be right. Read your system's documentation to determine if it is appropriate to upgrade to a more recent version to obtain the optimal alignment. Progress is being made on making this work "out of the box" on future versions of `g77', `gcc', and some of the relevant operating systems (such as GNU/Linux).  File: g77.info, Node: Prefer Automatic Uninitialized Variables, Next: Avoid f2c Compatibility, Prev: Aligned Data, Up: Faster Programs Prefer Automatic Uninitialized Variables ---------------------------------------- If you're using `-fno-automatic' already, you probably should change your code to allow compilation with `-fautomatic' (the default), to allow the program to run faster. Similarly, you should be able to use `-fno-init-local-zero' (the default) instead of `-finit-local-zero'. This is because it is rare that every variable affected by these options in a given program actually needs to be so affected. For example, `-fno-automatic', which effectively `SAVE's every local non-automatic variable and array, affects even things like `DO' iteration variables, which rarely need to be `SAVE'd, and this often reduces run-time performances. Similarly, `-fno-init-local-zero' forces such variables to be initialized to zero--when `SAVE'd (such as when `-fno-automatic'), this by itself generally affects only startup time for a program, but when not `SAVE'd, it can slow down the procedure every time it is called. *Note Overly Convenient Command-Line Options: Overly Convenient Options, for information on the `-fno-automatic' and `-finit-local-zero' options and how to convert their use into selective changes in your own code.  File: g77.info, Node: Avoid f2c Compatibility, Next: Use Submodel Options, Prev: Prefer Automatic Uninitialized Variables, Up: Faster Programs Avoid f2c Compatibility ----------------------- If you aren't linking with any code compiled using `f2c', try using the `-fno-f2c' option when compiling _all_ the code in your program. (Note that `libf2c' is _not_ an example of code that is compiled using `f2c'--it is compiled by a C compiler, typically `gcc'.)  File: g77.info, Node: Use Submodel Options, Prev: Avoid f2c Compatibility, Up: Faster Programs Use Submodel Options -------------------- Using an appropriate `-m' option to generate specific code for your CPU may be worthwhile, though it may mean the executable won't run on other versions of the CPU that don't support the same instruction set. *Note Hardware Models and Configurations: (gcc)Submodel Options. For instance on an x86 system the compiler might have been built--as shown by `g77 -v'--for the target `i386-pc-linux-gnu', i.e. an `i386' CPU. In that case to generate code best optimized for a Pentium you could use the option `-march=pentium'. For recent CPUs that don't have explicit support in the released version of `gcc', it _might_ still be possible to get improvements with certain `-m' options. `-fomit-frame-pointer' can help performance on x86 systems and others. It will, however, inhibit debugging on the systems on which it is not turned on anyway by `-O'.  File: g77.info, Node: Trouble, Next: Open Questions, Prev: Collected Fortran Wisdom, Up: Top Known Causes of Trouble with GNU Fortran **************************************** This section describes known problems that affect users of GNU Fortran. Most of these are not GNU Fortran bugs per se--if they were, we would fix them. But the result for a user might be like the result of a bug. Some of these problems are due to bugs in other software, some are missing features that are too much work to add, and some are places where people's opinions differ as to what is best. (Note that some of this portion of the manual is lifted directly from the `gcc' manual, with minor modifications to tailor it to users of `g77'. Anytime a bug seems to have more to do with the `gcc' portion of `g77', see *Note Known Causes of Trouble with GCC: (gcc)Trouble.) * Menu: * But-bugs:: Bugs really in other programs or elsewhere. * Known Bugs:: Bugs known to be in this version of `g77'. * Missing Features:: Features we already know we want to add later. * Disappointments:: Regrettable things we can't change. * Non-bugs:: Things we think are right, but some others disagree. * Warnings and Errors:: Which problems in your code get warnings, and which get errors.  File: g77.info, Node: But-bugs, Next: Known Bugs, Up: Trouble Bugs Not In GNU Fortran ======================= These are bugs to which the maintainers often have to reply, "but that isn't a bug in `g77'...". Some of these already are fixed in new versions of other software; some still need to be fixed; some are problems with how `g77' is installed or is being used; some are the result of bad hardware that causes software to misbehave in sometimes bizarre ways; some just cannot be addressed at this time until more is known about the problem. Please don't re-report these bugs to the `g77' maintainers--if you must remind someone how important it is to you that the problem be fixed, talk to the people responsible for the other products identified below, but preferably only after you've tried the latest versions of those products. The `g77' maintainers have their hands full working on just fixing and improving `g77', without serving as a clearinghouse for all bugs that happen to affect `g77' users. *Note Collected Fortran Wisdom::, for information on behavior of Fortran programs, and the programs that compile them, that might be _thought_ to indicate bugs. * Menu: * Signal 11 and Friends:: Strange behavior by any software. * Cannot Link Fortran Programs:: Unresolved references. * Large Common Blocks:: Problems on older GNU/Linux systems. * Debugger Problems:: When the debugger crashes. * NeXTStep Problems:: Misbehaving executables. * Stack Overflow:: More misbehaving executables. * Nothing Happens:: Less behaving executables. * Strange Behavior at Run Time:: Executables misbehaving due to bugs in your program. * Floating-point Errors:: The results look wrong, but....  File: g77.info, Node: Signal 11 and Friends, Next: Cannot Link Fortran Programs, Up: But-bugs Signal 11 and Friends --------------------- A whole variety of strange behaviors can occur when the software, or the way you are using the software, stresses the hardware in a way that triggers hardware bugs. This might seem hard to believe, but it happens frequently enough that there exist documents explaining in detail what the various causes of the problems are, what typical symptoms look like, and so on. Generally these problems are referred to in this document as "signal 11" crashes, because the Linux kernel, running on the most popular hardware (the Intel x86 line), often stresses the hardware more than other popular operating systems. When hardware problems do occur under GNU/Linux on x86 systems, these often manifest themselves as "signal 11" problems, as illustrated by the following diagnostic: sh# g77 myprog.f gcc: Internal compiler error: program f771 got fatal signal 11 sh# It is _very_ important to remember that the above message is _not_ the only one that indicates a hardware problem, nor does it always indicate a hardware problem. In particular, on systems other than those running the Linux kernel, the message might appear somewhat or very different, as it will if the error manifests itself while running a program other than the `g77' compiler. For example, it will appear somewhat different when running your program, when running Emacs, and so on. How to cope with such problems is well beyond the scope of this manual. However, users of Linux-based systems (such as GNU/Linux) should review `http://www.bitwizard.nl/sig11/', a source of detailed information on diagnosing hardware problems, by recognizing their common symptoms. Users of other operating systems and hardware might find this reference useful as well. If you know of similar material for another hardware/software combination, please let us know so we can consider including a reference to it in future versions of this manual.  File: g77.info, Node: Cannot Link Fortran Programs, Next: Large Common Blocks, Prev: Signal 11 and Friends, Up: But-bugs Cannot Link Fortran Programs ---------------------------- On some systems, perhaps just those with out-of-date (shared?) libraries, unresolved-reference errors happen when linking `g77'-compiled programs (which should be done using `g77'). If this happens to you, try appending `-lc' to the command you use to link the program, e.g. `g77 foo.f -lc'. `g77' already specifies `-lg2c -lm' when it calls the linker, but it cannot also specify `-lc' because not all systems have a file named `libc.a'. It is unclear at this point whether there are legitimately installed systems where `-lg2c -lm' is insufficient to resolve code produced by `g77'. If your program doesn't link due to unresolved references to names like `_main', make sure you're using the `g77' command to do the link, since this command ensures that the necessary libraries are loaded by specifying `-lg2c -lm' when it invokes the `gcc' command to do the actual link. (Use the `-v' option to discover more about what actually happens when you use the `g77' and `gcc' commands.) Also, try specifying `-lc' as the last item on the `g77' command line, in case that helps.  File: g77.info, Node: Large Common Blocks, Next: Debugger Problems, Prev: Cannot Link Fortran Programs, Up: But-bugs Large Common Blocks ------------------- On some older GNU/Linux systems, programs with common blocks larger than 16MB cannot be linked without some kind of error message being produced. This is a bug in older versions of `ld', fixed in more recent versions of `binutils', such as version 2.6.  File: g77.info, Node: Debugger Problems, Next: NeXTStep Problems, Prev: Large Common Blocks, Up: But-bugs Debugger Problems ----------------- There are some known problems when using `gdb' on code compiled by `g77'. Inadequate investigation as of the release of 0.5.16 results in not knowing which products are the culprit, but `gdb-4.14' definitely crashes when, for example, an attempt is made to print the contents of a `COMPLEX(KIND=2)' dummy array, on at least some GNU/Linux machines, plus some others. Attempts to access assumed-size arrays are also known to crash recent versions of `gdb'. (`gdb''s Fortran support was done for a different compiler and isn't properly compatible with `g77'.)  File: g77.info, Node: NeXTStep Problems, Next: Stack Overflow, Prev: Debugger Problems, Up: But-bugs NeXTStep Problems ----------------- Developers of Fortran code on NeXTStep (all architectures) have to watch out for the following problem when writing programs with large, statically allocated (i.e. non-stack based) data structures (common blocks, saved arrays). Due to the way the native loader (`/bin/ld') lays out data structures in virtual memory, it is very easy to create an executable wherein the `__DATA' segment overlaps (has addresses in common) with the `UNIX STACK' segment. This leads to all sorts of trouble, from the executable simply not executing, to bus errors. The NeXTStep command line tool `ebadexec' points to the problem as follows: % /bin/ebadexec a.out /bin/ebadexec: __LINKEDIT segment (truncated address = 0x3de000 rounded size = 0x2a000) of executable file: a.out overlaps with UNIX STACK segment (truncated address = 0x400000 rounded size = 0x3c00000) of executable file: a.out (In the above case, it is the `__LINKEDIT' segment that overlaps the stack segment.) This can be cured by assigning the `__DATA' segment (virtual) addresses beyond the stack segment. A conservative estimate for this is from address 6000000 (hexadecimal) onwards--this has always worked for me [Toon Moene]: % g77 -segaddr __DATA 6000000 test.f % ebadexec a.out ebadexec: file: a.out appears to be executable % Browsing through `gcc/gcc/f/Makefile.in', you will find that the `f771' program itself also has to be linked with these flags--it has large statically allocated data structures. (Version 0.5.18 reduces this somewhat, but probably not enough.) (The above item was contributed by Toon Moene ().)  File: g77.info, Node: Stack Overflow, Next: Nothing Happens, Prev: NeXTStep Problems, Up: But-bugs Stack Overflow -------------- `g77' code might fail at runtime (probably with a "segmentation violation") due to overflowing the stack. This happens most often on systems with an environment that provides substantially more heap space (for use when arbitrarily allocating and freeing memory) than stack space. Often this can be cured by increasing or removing your shell's limit on stack usage, typically using `limit stacksize' (in `csh' and derivatives) or `ulimit -s' (in `sh' and derivatives). Increasing the allowed stack size might, however, require changing some operating system or system configuration parameters. You might be able to work around the problem by compiling with the `-fno-automatic' option to reduce stack usage, probably at the expense of speed. `g77', on most machines, puts many variables and arrays on the stack where possible, and can be configured (by changing `FFECOM_sizeMAXSTACKITEM' in `gcc/gcc/f/com.c') to force smaller-sized entities into static storage (saving on stack space) or permit larger-sized entities to be put on the stack (which can improve run-time performance, as it presents more opportunities for the GBE to optimize the generated code). _Note:_ Putting more variables and arrays on the stack might cause problems due to system-dependent limits on stack size. Also, the value of `FFECOM_sizeMAXSTACKITEM' has no effect on automatic variables and arrays. *Note But-bugs::, for more information. _Note:_ While `libg2c' places a limit on the range of Fortran file-unit numbers, the underlying library and operating system might impose different kinds of limits. For example, some systems limit the number of files simultaneously open by a running program. Information on how to increase these limits should be found in your system's documentation. However, if your program uses large automatic arrays (for example, has declarations like `REAL A(N)' where `A' is a local array and `N' is a dummy or `COMMON' variable that can have a large value), neither use of `-fno-automatic', nor changing the cut-off point for `g77' for using the stack, will solve the problem by changing the placement of these large arrays, as they are _necessarily_ automatic. `g77' currently provides no means to specify that automatic arrays are to be allocated on the heap instead of the stack. So, other than increasing the stack size, your best bet is to change your source code to avoid large automatic arrays. Methods for doing this currently are outside the scope of this document. (_Note:_ If your system puts stack and heap space in the same memory area, such that they are effectively combined, then a stack overflow probably indicates a program that is either simply too large for the system, or buggy.)  File: g77.info, Node: Nothing Happens, Next: Strange Behavior at Run Time, Prev: Stack Overflow, Up: But-bugs Nothing Happens --------------- It is occasionally reported that a "simple" program, such as a "Hello, World!" program, does nothing when it is run, even though the compiler reported no errors, despite the program containing nothing other than a simple `PRINT' statement. This most often happens because the program has been compiled and linked on a UNIX system and named `test', though other names can lead to similarly unexpected run-time behavior on various systems. Essentially this problem boils down to giving your program a name that is already known to the shell you are using to identify some other program, which the shell continues to execute instead of your program when you invoke it via, for example: sh# test sh# Under UNIX and many other system, a simple command name invokes a searching mechanism that might well not choose the program located in the current working directory if there is another alternative (such as the `test' command commonly installed on UNIX systems). The reliable way to invoke a program you just linked in the current directory under UNIX is to specify it using an explicit pathname, as in: sh# ./test Hello, World! sh# Users who encounter this problem should take the time to read up on how their shell searches for commands, how to set their search path, and so on. The relevant UNIX commands to learn about include `man', `info' (on GNU systems), `setenv' (or `set' and `env'), `which', and `find'.  File: g77.info, Node: Strange Behavior at Run Time, Next: Floating-point Errors, Prev: Nothing Happens, Up: But-bugs Strange Behavior at Run Time ---------------------------- `g77' code might fail at runtime with "segmentation violation", "bus error", or even something as subtle as a procedure call overwriting a variable or array element that it is not supposed to touch. These can be symptoms of a wide variety of actual bugs that occurred earlier during the program's run, but manifested themselves as _visible_ problems some time later. Overflowing the bounds of an array--usually by writing beyond the end of it--is one of two kinds of bug that often occurs in Fortran code. (Compile your code with the `-fbounds-check' option to catch many of these kinds of errors at program run time.) The other kind of bug is a mismatch between the actual arguments passed to a procedure and the dummy arguments as declared by that procedure. Both of these kinds of bugs, and some others as well, can be difficult to track down, because the bug can change its behavior, or even appear to not occur, when using a debugger. That is, these bugs can be quite sensitive to data, including data representing the placement of other data in memory (that is, pointers, such as the placement of stack frames in memory). `g77' now offers the ability to catch and report some of these problems at compile, link, or run time, such as by generating code to detect references to beyond the bounds of most arrays (except assumed-size arrays), and checking for agreement between calling and called procedures. Future improvements are likely to be made in the procedure-mismatch area, at least. In the meantime, finding and fixing the programming bugs that lead to these behaviors is, ultimately, the user's responsibility, as difficult as that task can sometimes be. One runtime problem that has been observed might have a simple solution. If a formatted `WRITE' produces an endless stream of spaces, check that your program is linked against the correct version of the C library. The configuration process takes care to account for your system's normal `libc' not being ANSI-standard, which will otherwise cause this behavior. If your system's default library is ANSI-standard and you subsequently link against a non-ANSI one, there might be problems such as this one. Specifically, on Solaris2 systems, avoid picking up the `BSD' library from `/usr/ucblib'.  File: g77.info, Node: Floating-point Errors, Prev: Strange Behavior at Run Time, Up: But-bugs Floating-point Errors --------------------- Some programs appear to produce inconsistent floating-point results compiled by `g77' versus by other compilers. Often the reason for this behavior is the fact that floating-point values are represented on almost all Fortran systems by _approximations_, and these approximations are inexact even for apparently simple values like 0.1, 0.2, 0.3, 0.4, 0.6, 0.7, 0.8, 0.9, 1.1, and so on. Most Fortran systems, including all current ports of `g77', use binary arithmetic to represent these approximations. Therefore, the exact value of any floating-point approximation as manipulated by `g77'-compiled code is representable by adding some combination of the values 1.0, 0.5, 0.25, 0.125, and so on (just keep dividing by two) through the precision of the fraction (typically around 23 bits for `REAL(KIND=1)', 52 for `REAL(KIND=2)'), then multiplying the sum by a integral power of two (in Fortran, by `2**N') that typically is between -127 and +128 for `REAL(KIND=1)' and -1023 and +1024 for `REAL(KIND=2)', then multiplying by -1 if the number is negative. So, a value like 0.2 is exactly represented in decimal--since it is a fraction, `2/10', with a denominator that is compatible with the base of the number system (base 10). However, `2/10' cannot be represented by any finite number of sums of any of 1.0, 0.5, 0.25, and so on, so 0.2 cannot be exactly represented in binary notation. (On the other hand, decimal notation can represent any binary number in a finite number of digits. Decimal notation cannot do so with ternary, or base-3, notation, which would represent floating-point numbers as sums of any of `1/1', `1/3', `1/9', and so on. After all, no finite number of decimal digits can exactly represent `1/3'. Fortunately, few systems use ternary notation.) Moreover, differences in the way run-time I/O libraries convert between these approximations and the decimal representation often used by programmers and the programs they write can result in apparent differences between results that do not actually exist, or exist to such a small degree that they usually are not worth worrying about. For example, consider the following program: PRINT *, 0.2 END When compiled by `g77', the above program might output `0.20000003', while another compiler might produce a executable that outputs `0.2'. This particular difference is due to the fact that, currently, conversion of floating-point values by the `libg2c' library, used by `g77', handles only double-precision values. Since `0.2' in the program is a single-precision value, it is converted to double precision (still in binary notation) before being converted back to decimal. The conversion to binary appends _binary_ zero digits to the original value--which, again, is an inexact approximation of 0.2--resulting in an approximation that is much less exact than is connoted by the use of double precision. (The appending of binary zero digits has essentially the same effect as taking a particular decimal approximation of `1/3', such as `0.3333333', and appending decimal zeros to it, producing `0.33333330000000000'. Treating the resulting decimal approximation as if it really had 18 or so digits of valid precision would make it seem a very poor approximation of `1/3'.) As a result of converting the single-precision approximation to double precision by appending binary zeros, the conversion of the resulting double-precision value to decimal produces what looks like an incorrect result, when in fact the result is _inexact_, and is probably no less inaccurate or imprecise an approximation of 0.2 than is produced by other compilers that happen to output the converted value as "exactly" `0.2'. (Some compilers behave in a way that can make them appear to retain more accuracy across a conversion of a single-precision constant to double precision. *Note Context-Sensitive Constants::, to see why this practice is illusory and even dangerous.) Note that a more exact approximation of the constant is computed when the program is changed to specify a double-precision constant: PRINT *, 0.2D0 END Future versions of `g77' and/or `libg2c' might convert single-precision values directly to decimal, instead of converting them to double precision first. This would tend to result in output that is more consistent with that produced by some other Fortran implementations. A useful source of information on floating-point computation is David Goldberg, `What Every Computer Scientist Should Know About Floating-Point Arithmetic', Computing Surveys, 23, March 1991, pp. 5-48. An online version is available at `http://docs.sun.com/'. Information related to the IEEE 754 floating-point standard can be found at `http://grouper.ieee.org/groups/754/' and `http://http.cs.berkeley.edu/%7Ewkahan/ieee754status/'; see also slides from the short course referenced from `http://http.cs.berkeley.edu/%7Efateman/'. The supplement to the PostScript-formatted Goldberg document, referenced above, is available in HTML format. See `Differences Among IEEE 754 Implementations' by Doug Priest. This document explores some of the issues surrounding computing of extended (80-bit) results on processors such as the x86, especially when those results are arbitrarily truncated to 32-bit or 64-bit values by the compiler as "spills". (_Note:_ `g77' specifically, and `gcc' generally, does arbitrarily truncate 80-bit results during spills as of this writing. It is not yet clear whether a future version of the GNU compiler suite will offer 80-bit spills as an option, or perhaps even as the default behavior.) The GNU C library provides routines for controlling the FPU, and other documentation about this. *Note Floating-point precision::, regarding IEEE 754 conformance.  File: g77.info, Node: Known Bugs, Next: Missing Features, Prev: But-bugs, Up: Trouble Known Bugs In GNU Fortran ========================= This section identifies bugs that `g77' _users_ might run into in the GCC-3.4.2 version of `g77'. This includes bugs that are actually in the `gcc' back end (GBE) or in `libf2c', because those sets of code are at least somewhat under the control of (and necessarily intertwined with) `g77', so it isn't worth separating them out. For information on bugs in _other_ versions of `g77', see *Note News About GNU Fortran: News. There, lists of bugs fixed in various versions of `g77' can help determine what bugs existed in prior versions. The following information was last updated on 2004-05-18: * `g77' fails to warn about use of a "live" iterative-DO variable as an implied-DO variable in a `WRITE' or `PRINT' statement (although it does warn about this in a `READ' statement). * Something about `g77''s straightforward handling of label references and definitions sometimes prevents the GBE from unrolling loops. Until this is solved, try inserting or removing `CONTINUE' statements as the terminal statement, using the `END DO' form instead, and so on. * Some confusion in diagnostics concerning failing `INCLUDE' statements from within `INCLUDE''d or `#include''d files. * `g77' assumes that `INTEGER(KIND=1)' constants range from `-2**31' to `2**31-1' (the range for two's-complement 32-bit values), instead of determining their range from the actual range of the type for the configuration (and, someday, for the constant). Further, it generally doesn't implement the handling of constants very well in that it makes assumptions about the configuration that it no longer makes regarding variables (types). Included with this item is the fact that `g77' doesn't recognize that, on IEEE-754/854-compliant systems, `0./0.' should produce a NaN and no warning instead of the value `0.' and a warning. * `g77' uses way too much memory and CPU time to process large aggregate areas having any initialized elements. For example, `REAL A(1000000)' followed by `DATA A(1)/1/' takes up way too much time and space, including the size of the generated assembler file. Version 0.5.18 improves cases like this--specifically, cases of _sparse_ initialization that leave large, contiguous areas uninitialized--significantly. However, even with the improvements, these cases still require too much memory and CPU time. (Version 0.5.18 also improves cases where the initial values are zero to a much greater degree, so if the above example ends with `DATA A(1)/0/', the compile-time performance will be about as good as it will ever get, aside from unrelated improvements to the compiler.) Note that `g77' does display a warning message to notify the user before the compiler appears to hang. A warning message is issued when `g77' sees code that provides initial values (e.g. via `DATA') to an aggregate area (`COMMON' or `EQUIVALENCE', or even a large enough array or `CHARACTER' variable) that is large enough to increase `g77''s compile time by roughly a factor of 10. This size currently is quite small, since `g77' currently has a known bug requiring too much memory and time to handle such cases. In `gcc/gcc/f/data.c', the macro `FFEDATA_sizeTOO_BIG_INIT_' is defined to the minimum size for the warning to appear. The size is specified in storage units, which can be bytes, words, or whatever, on a case-by-case basis. After changing this macro definition, you must (of course) rebuild and reinstall `g77' for the change to take effect. Note that, as of version 0.5.18, improvements have reduced the scope of the problem for _sparse_ initialization of large arrays, especially those with large, contiguous uninitialized areas. However, the warning is issued at a point prior to when `g77' knows whether the initialization is sparse, and delaying the warning could mean it is produced too late to be helpful. Therefore, the macro definition should not be adjusted to reflect sparse cases. Instead, adjust it to generate the warning when densely initialized arrays begin to cause responses noticeably slower than linear performance would suggest. * When debugging, after starting up the debugger but before being able to see the source code for the main program unit, the user must currently set a breakpoint at `MAIN__' (or `MAIN___' or `MAIN_' if `MAIN__' doesn't exist) and run the program until it hits the breakpoint. At that point, the main program unit is activated and about to execute its first executable statement, but that's the state in which the debugger should start up, as is the case for languages like C. * Debugging `g77'-compiled code using debuggers other than `gdb' is likely not to work. Getting `g77' and `gdb' to work together is a known problem--getting `g77' to work properly with other debuggers, for which source code often is unavailable to `g77' developers, seems like a much larger, unknown problem, and is a lower priority than making `g77' and `gdb' work together properly. On the other hand, information about problems other debuggers have with `g77' output might make it easier to properly fix `g77', and perhaps even improve `gdb', so it is definitely welcome. Such information might even lead to all relevant products working together properly sooner. * `g77' doesn't work perfectly on 64-bit configurations such as the Digital Semiconductor ("DEC") Alpha. This problem is largely resolved as of version 0.5.23. * `g77' currently inserts needless padding for things like `COMMON A,IPAD' where `A' is `CHARACTER*1' and `IPAD' is `INTEGER(KIND=1)' on machines like x86, because the back end insists that `IPAD' be aligned to a 4-byte boundary, but the processor has no such requirement (though it is usually good for performance). The `gcc' back end needs to provide a wider array of specifications of alignment requirements and preferences for targets, and front ends like `g77' should take advantage of this when it becomes available. * The `libf2c' routines that perform some run-time arithmetic on `COMPLEX' operands were modified circa version 0.5.20 of `g77' to work properly even in the presence of aliased operands. While the `g77' and `netlib' versions of `libf2c' differ on how this is accomplished, the main differences are that we believe the `g77' version works properly even in the presence of _partially_ aliased operands. However, these modifications have reduced performance on targets such as x86, due to the extra copies of operands involved.  File: g77.info, Node: Missing Features, Next: Disappointments, Prev: Known Bugs, Up: Trouble Missing Features ================ This section lists features we know are missing from `g77', and which we want to add someday. (There is no priority implied in the ordering below.) * Menu: GNU Fortran language: * Better Source Model:: * Fortran 90 Support:: * Intrinsics in PARAMETER Statements:: * Arbitrary Concatenation:: * SELECT CASE on CHARACTER Type:: * RECURSIVE Keyword:: * Popular Non-standard Types:: * Full Support for Compiler Types:: * Array Bounds Expressions:: * POINTER Statements:: * Sensible Non-standard Constructs:: * READONLY Keyword:: * FLUSH Statement:: * Expressions in FORMAT Statements:: * Explicit Assembler Code:: * Q Edit Descriptor:: GNU Fortran dialects: * Old-style PARAMETER Statements:: * TYPE and ACCEPT I/O Statements:: * STRUCTURE UNION RECORD MAP:: * OPEN CLOSE and INQUIRE Keywords:: * ENCODE and DECODE:: * AUTOMATIC Statement:: * Suppressing Space Padding:: * Fortran Preprocessor:: * Bit Operations on Floating-point Data:: * Really Ugly Character Assignments:: New facilities: * POSIX Standard:: * Floating-point Exception Handling:: * Nonportable Conversions:: * Large Automatic Arrays:: * Support for Threads:: * Increasing Precision/Range:: * Enabling Debug Lines:: Better diagnostics: * Better Warnings:: * Gracefully Handle Sensible Bad Code:: * Non-standard Conversions:: * Non-standard Intrinsics:: * Modifying DO Variable:: * Better Pedantic Compilation:: * Warn About Implicit Conversions:: * Invalid Use of Hollerith Constant:: * Dummy Array Without Dimensioning Dummy:: * Invalid FORMAT Specifiers:: * Ambiguous Dialects:: * Unused Labels:: * Informational Messages:: Run-time facilities: * Uninitialized Variables at Run Time:: * Portable Unformatted Files:: * Better List-directed I/O:: * Default to Console I/O:: Debugging: * Labels Visible to Debugger::  File: g77.info, Node: Better Source Model, Next: Fortran 90 Support, Up: Missing Features Better Source Model ------------------- `g77' needs to provide, as the default source-line model, a "pure visual" mode, where the interpretation of a source program in this mode can be accurately determined by a user looking at a traditionally displayed rendition of the program (assuming the user knows whether the program is fixed or free form). The design should assume the user cannot tell tabs from spaces and cannot see trailing spaces on lines, but has canonical tab stops and, for fixed-form source, has the ability to always know exactly where column 72 is (since the Fortran standard itself requires this for fixed-form source). This would change the default treatment of fixed-form source to not treat lines with tabs as if they were infinitely long--instead, they would end at column 72 just as if the tabs were replaced by spaces in the canonical way. As part of this, provide common alternate models (Digital, `f2c', and so on) via command-line options. This includes allowing arbitrarily long lines for free-form source as well as fixed-form source and providing various limits and diagnostics as appropriate. Also, `g77' should offer, perhaps even default to, warnings when characters beyond the last valid column are anything other than spaces. This would mean code with "sequence numbers" in columns 73 through 80 would be rejected, and there's a lot of that kind of code around, but one of the most frequent bugs encountered by new users is accidentally writing fixed-form source code into and beyond column 73. So, maybe the users of old code would be able to more easily handle having to specify, say, a `-Wno-col73to80' option.  File: g77.info, Node: Fortran 90 Support, Next: Intrinsics in PARAMETER Statements, Prev: Better Source Model, Up: Missing Features Fortran 90 Support ------------------ `g77' does not support many of the features that distinguish Fortran 90 (and, now, Fortran 95) from ANSI FORTRAN 77. Some Fortran 90 features are supported, because they make sense to offer even to die-hard users of F77. For example, many of them codify various ways F77 has been extended to meet users' needs during its tenure, so `g77' might as well offer them as the primary way to meet those same needs, even if it offers compatibility with one or more of the ways those needs were met by other F77 compilers in the industry. Still, many important F90 features are not supported, because no attempt has been made to research each and every feature and assess its viability in `g77'. In the meantime, users who need those features must use Fortran 90 compilers anyway, and the best approach to adding some F90 features to GNU Fortran might well be to fund a comprehensive project to create GNU Fortran 95.  File: g77.info, Node: Intrinsics in PARAMETER Statements, Next: Arbitrary Concatenation, Prev: Fortran 90 Support, Up: Missing Features Intrinsics in `PARAMETER' Statements ------------------------------------ `g77' doesn't allow intrinsics in `PARAMETER' statements. Related to this, `g77' doesn't allow non-integral exponentiation in `PARAMETER' statements, such as `PARAMETER (R=2**.25)'. It is unlikely `g77' will ever support this feature, as doing it properly requires complete emulation of a target computer's floating-point facilities when building `g77' as a cross-compiler. But, if the `gcc' back end is enhanced to provide such a facility, `g77' will likely use that facility in implementing this feature soon afterwards.  File: g77.info, Node: Arbitrary Concatenation, Next: SELECT CASE on CHARACTER Type, Prev: Intrinsics in PARAMETER Statements, Up: Missing Features Arbitrary Concatenation ----------------------- `g77' doesn't support arbitrary operands for concatenation in contexts where run-time allocation is required. For example: SUBROUTINE X(A) CHARACTER*(*) A CALL FOO(A // 'suffix')  File: g77.info, Node: SELECT CASE on CHARACTER Type, Next: RECURSIVE Keyword, Prev: Arbitrary Concatenation, Up: Missing Features `SELECT CASE' on `CHARACTER' Type --------------------------------- Character-type selector/cases for `SELECT CASE' currently are not supported.  File: g77.info, Node: RECURSIVE Keyword, Next: Popular Non-standard Types, Prev: SELECT CASE on CHARACTER Type, Up: Missing Features `RECURSIVE' Keyword ------------------- `g77' doesn't support the `RECURSIVE' keyword that F90 compilers do. Nor does it provide any means for compiling procedures designed to do recursion. All recursive code can be rewritten to not use recursion, but the result is not pretty.  File: g77.info, Node: Increasing Precision/Range, Next: Enabling Debug Lines, Prev: Support for Threads, Up: Missing Features Increasing Precision/Range -------------------------- Some compilers, such as `f2c', have an option (`-r8', `-qrealsize=8' or similar) that provides automatic treatment of `REAL' entities such that they have twice the storage size, and a corresponding increase in the range and precision, of what would normally be the `REAL(KIND=1)' (default `REAL') type. (This affects `COMPLEX' the same way.) They also typically offer another option (`-i8') to increase `INTEGER' entities so they are twice as large (with roughly twice as much range). (There are potential pitfalls in using these options.) `g77' does not yet offer any option that performs these kinds of transformations. Part of the problem is the lack of detailed specifications regarding exactly how these options affect the interpretation of constants, intrinsics, and so on. Until `g77' addresses this need, programmers could improve the portability of their code by modifying it to not require compile-time options to produce correct results. Some free tools are available which may help, specifically in Toolpack (which one would expect to be sound) and the `fortran' section of the Netlib repository. Use of preprocessors can provide a fairly portable means to work around the lack of widely portable methods in the Fortran language itself (though increasing acceptance of Fortran 90 would alleviate this problem).  File: g77.info, Node: Popular Non-standard Types, Next: Full Support for Compiler Types, Prev: RECURSIVE Keyword, Up: Missing Features Popular Non-standard Types -------------------------- `g77' doesn't fully support `INTEGER*2', `LOGICAL*1', and similar. In the meantime, version 0.5.18 provides rudimentary support for them.  File: g77.info, Node: Full Support for Compiler Types, Next: Array Bounds Expressions, Prev: Popular Non-standard Types, Up: Missing Features Full Support for Compiler Types ------------------------------- `g77' doesn't support `INTEGER', `REAL', and `COMPLEX' equivalents for _all_ applicable back-end-supported types (`char', `short int', `int', `long int', `long long int', and `long double'). This means providing intrinsic support, and maybe constant support (using F90 syntax) as well, and, for most machines will result in automatic support of `INTEGER*1', `INTEGER*2', `INTEGER*8', maybe even `REAL*16', and so on.  File: g77.info, Node: Array Bounds Expressions, Next: POINTER Statements, Prev: Full Support for Compiler Types, Up: Missing Features Array Bounds Expressions ------------------------ `g77' doesn't support more general expressions to dimension arrays, such as array element references, function references, etc. For example, `g77' currently does not accept the following: SUBROUTINE X(M, N) INTEGER N(10), M(N(2), N(1))  File: g77.info, Node: POINTER Statements, Next: Sensible Non-standard Constructs, Prev: Array Bounds Expressions, Up: Missing Features POINTER Statements ------------------ `g77' doesn't support pointers or allocatable objects (other than automatic arrays). This set of features is probably considered just behind intrinsics in `PARAMETER' statements on the list of large, important things to add to `g77'. In the meantime, consider using the `INTEGER(KIND=7)' declaration to specify that a variable must be able to hold a pointer. This construct is not portable to other non-GNU compilers, but it is portable to all machines GNU Fortran supports when `g77' is used. *Note Functions and Subroutines::, for information on `%VAL()', `%REF()', and `%DESCR()' constructs, which are useful for passing pointers to procedures written in languages other than Fortran.  File: g77.info, Node: Sensible Non-standard Constructs, Next: READONLY Keyword, Prev: POINTER Statements, Up: Missing Features Sensible Non-standard Constructs -------------------------------- `g77' rejects things other compilers accept, like `INTRINSIC SQRT,SQRT'. As time permits in the future, some of these things that are easy for humans to read and write and unlikely to be intended to mean something else will be accepted by `g77' (though `-fpedantic' should trigger warnings about such non-standard constructs). Until `g77' no longer gratuitously rejects sensible code, you might as well fix your code to be more standard-conforming and portable. The kind of case that is important to except from the recommendation to change your code is one where following good coding rules would force you to write non-standard code that nevertheless has a clear meaning. For example, when writing an `INCLUDE' file that defines a common block, it might be appropriate to include a `SAVE' statement for the common block (such as `SAVE /CBLOCK/'), so that variables defined in the common block retain their values even when all procedures declaring the common block become inactive (return to their callers). However, putting `SAVE' statements in an `INCLUDE' file would prevent otherwise standard-conforming code from also specifying the `SAVE' statement, by itself, to indicate that all local variables and arrays are to have the `SAVE' attribute. For this reason, `g77' already has been changed to allow this combination, because although the general problem of gratuitously rejecting unambiguous and "safe" constructs still exists in `g77', this particular construct was deemed useful enough that it was worth fixing `g77' for just this case. So, while there is no need to change your code to avoid using this particular construct, there might be other, equally appropriate but non-standard constructs, that you shouldn't have to stop using just because `g77' (or any other compiler) gratuitously rejects it. Until the general problem is solved, if you have any such construct you believe is worthwhile using (e.g. not just an arbitrary, redundant specification of an attribute), please submit a bug report with an explanation, so we can consider fixing `g77' just for cases like yours.  File: g77.info, Node: READONLY Keyword, Next: FLUSH Statement, Prev: Sensible Non-standard Constructs, Up: Missing Features `READONLY' Keyword ------------------ Support for `READONLY', in `OPEN' statements, requires `libg2c' support, to make sure that `CLOSE(...,STATUS='DELETE')' does not delete a file opened on a unit with the `READONLY' keyword, and perhaps to trigger a fatal diagnostic if a `WRITE' or `PRINT' to such a unit is attempted. _Note:_ It is not sufficient for `g77' and `libg2c' (its version of `libf2c') to assume that `READONLY' does not need some kind of explicit support at run time, due to UNIX systems not (generally) needing it. `g77' is not just a UNIX-based compiler! Further, mounting of non-UNIX filesystems on UNIX systems (such as via NFS) might require proper `READONLY' support. (Similar issues might be involved with supporting the `SHARED' keyword.)  File: g77.info, Node: FLUSH Statement, Next: Expressions in FORMAT Statements, Prev: READONLY Keyword, Up: Missing Features `FLUSH' Statement ----------------- `g77' could perhaps use a `FLUSH' statement that does what `CALL FLUSH' does, but that supports `*' as the unit designator (same unit as for `PRINT') and accepts `ERR=' and/or `IOSTAT=' specifiers.  File: g77.info, Node: Expressions in FORMAT Statements, Next: Explicit Assembler Code, Prev: FLUSH Statement, Up: Missing Features Expressions in `FORMAT' Statements ---------------------------------- `g77' doesn't support `FORMAT(I)' and the like. Supporting this requires a significant redesign or replacement of `libg2c'. However, `g77' does support this construct when the expression is constant (as of version 0.5.22). For example: PARAMETER (IWIDTH = 12) 10 FORMAT (I) Otherwise, at least for output (`PRINT' and `WRITE'), Fortran code making use of this feature can be rewritten to avoid it by constructing the `FORMAT' string in a `CHARACTER' variable or array, then using that variable or array in place of the `FORMAT' statement label to do the original `PRINT' or `WRITE'. Many uses of this feature on input can be rewritten this way as well, but not all can. For example, this can be rewritten: READ 20, I 20 FORMAT (I) However, this cannot, in general, be rewritten, especially when `ERR=' and `END=' constructs are employed: READ 30, J, I 30 FORMAT (I)  File: g77.info, Node: Explicit Assembler Code, Next: Q Edit Descriptor, Prev: Expressions in FORMAT Statements, Up: Missing Features Explicit Assembler Code ----------------------- `g77' needs to provide some way, a la `gcc', for `g77' code to specify explicit assembler code.  File: g77.info, Node: Q Edit Descriptor, Next: Old-style PARAMETER Statements, Prev: Explicit Assembler Code, Up: Missing Features Q Edit Descriptor ----------------- The `Q' edit descriptor in `FORMAT's isn't supported. (This is meant to get the number of characters remaining in an input record.) Supporting this requires a significant redesign or replacement of `libg2c'. A workaround might be using internal I/O or the stream-based intrinsics. *Note FGetC Intrinsic (subroutine)::.  File: g77.info, Node: Old-style PARAMETER Statements, Next: TYPE and ACCEPT I/O Statements, Prev: Q Edit Descriptor, Up: Missing Features Old-style PARAMETER Statements ------------------------------ `g77' doesn't accept `PARAMETER I=1'. Supporting this obsolete form of the `PARAMETER' statement would not be particularly hard, as most of the parsing code is already in place and working. Until time/money is spent implementing it, you might as well fix your code to use the standard form, `PARAMETER (I=1)' (possibly needing `INTEGER I' preceding the `PARAMETER' statement as well, otherwise, in the obsolete form of `PARAMETER', the type of the variable is set from the type of the constant being assigned to it).  File: g77.info, Node: TYPE and ACCEPT I/O Statements, Next: STRUCTURE UNION RECORD MAP, Prev: Old-style PARAMETER Statements, Up: Missing Features `TYPE' and `ACCEPT' I/O Statements ---------------------------------- `g77' doesn't support the I/O statements `TYPE' and `ACCEPT'. These are common extensions that should be easy to support, but also are fairly easy to work around in user code. Generally, any `TYPE fmt,list' I/O statement can be replaced by `PRINT fmt,list'. And, any `ACCEPT fmt,list' statement can be replaced by `READ fmt,list'.  File: g77.info, Node: STRUCTURE UNION RECORD MAP, Next: OPEN CLOSE and INQUIRE Keywords, Prev: TYPE and ACCEPT I/O Statements, Up: Missing Features `STRUCTURE', `UNION', `RECORD', `MAP' ------------------------------------- `g77' doesn't support `STRUCTURE', `UNION', `RECORD', `MAP'. This set of extensions is quite a bit lower on the list of large, important things to add to `g77', partly because it requires a great deal of work either upgrading or replacing `libg2c'.  File: g77.info, Node: OPEN CLOSE and INQUIRE Keywords, Next: ENCODE and DECODE, Prev: STRUCTURE UNION RECORD MAP, Up: Missing Features `OPEN', `CLOSE', and `INQUIRE' Keywords --------------------------------------- `g77' doesn't have support for keywords such as `DISP='DELETE'' in the `OPEN', `CLOSE', and `INQUIRE' statements. These extensions are easy to add to `g77' itself, but require much more work on `libg2c'. `g77' doesn't support `FORM='PRINT'' or an equivalent to translate the traditional `carriage control' characters in column 1 of output to use backspaces, carriage returns and the like. However programs exist to translate them in output files (or standard output). These are typically called either `fpr' or `asa'. You can get a version of `asa' from `ftp://sunsite.unc.edu/pub/Linux/devel/lang/fortran' for GNU systems which will probably build easily on other systems. Alternatively, `fpr' is in BSD distributions in various archive sites.  File: g77.info, Node: ENCODE and DECODE, Next: AUTOMATIC Statement, Prev: OPEN CLOSE and INQUIRE Keywords, Up: Missing Features `ENCODE' and `DECODE' --------------------- `g77' doesn't support `ENCODE' or `DECODE'. These statements are best replaced by READ and WRITE statements involving internal files (CHARACTER variables and arrays). For example, replace a code fragment like INTEGER*1 LINE(80) ... DECODE (80, 9000, LINE) A, B, C ... 9000 FORMAT (1X, 3(F10.5)) with: CHARACTER*80 LINE ... READ (UNIT=LINE, FMT=9000) A, B, C ... 9000 FORMAT (1X, 3(F10.5)) Similarly, replace a code fragment like INTEGER*1 LINE(80) ... ENCODE (80, 9000, LINE) A, B, C ... 9000 FORMAT (1X, 'OUTPUT IS ', 3(F10.5)) with: CHARACTER*80 LINE ... WRITE (UNIT=LINE, FMT=9000) A, B, C ... 9000 FORMAT (1X, 'OUTPUT IS ', 3(F10.5)) It is entirely possible that `ENCODE' and `DECODE' will be supported by a future version of `g77'.  File: g77.info, Node: AUTOMATIC Statement, Next: Suppressing Space Padding, Prev: ENCODE and DECODE, Up: Missing Features `AUTOMATIC' Statement --------------------- `g77' doesn't support the `AUTOMATIC' statement that `f2c' does. `AUTOMATIC' would identify a variable or array as not being `SAVE''d, which is normally the default, but which would be especially useful for code that, _generally_, needed to be compiled with the `-fno-automatic' option. `AUTOMATIC' also would serve as a hint to the compiler that placing the variable or array--even a very large array-on the stack is acceptable. `AUTOMATIC' would not, by itself, designate the containing procedure as recursive. `AUTOMATIC' should work syntactically like `SAVE', in that `AUTOMATIC' with no variables listed should apply to all pertinent variables and arrays (which would not include common blocks or their members). Variables and arrays denoted as `AUTOMATIC' would not be permitted to be initialized via `DATA' or other specification of any initial values, requiring explicit initialization, such as via assignment statements. Perhaps `UNSAVE' and `STATIC', as strict semantic opposites to `SAVE' and `AUTOMATIC', should be provided as well.  File: g77.info, Node: Suppressing Space Padding, Next: Fortran Preprocessor, Prev: AUTOMATIC Statement, Up: Missing Features Suppressing Space Padding of Source Lines ----------------------------------------- `g77' should offer VXT-Fortran-style suppression of virtual spaces at the end of a source line if an appropriate command-line option is specified. This affects cases where a character constant is continued onto the next line in a fixed-form source file, as in the following example: 10 PRINT *,'HOW MANY 1 SPACES?' `g77', and many other compilers, virtually extend the continued line through column 72 with spaces that become part of the character constant, but Digital Fortran normally didn't, leaving only one space between `MANY' and `SPACES?' in the output of the above statement. Fairly recently, at least one version of Digital Fortran was enhanced to provide the other behavior when a command-line option is specified, apparently due to demand from readers of the USENET group `comp.lang.fortran' to offer conformance to this widespread practice in the industry. `g77' should return the favor by offering conformance to Digital's approach to handling the above example.  File: g77.info, Node: Fortran Preprocessor, Next: Bit Operations on Floating-point Data, Prev: Suppressing Space Padding, Up: Missing Features Fortran Preprocessor -------------------- `g77' should offer a preprocessor designed specifically for Fortran to replace `cpp -traditional'. There are several out there worth evaluating, at least. Such a preprocessor would recognize Hollerith constants, properly parse comments and character constants, and so on. It might also recognize, process, and thus preprocess files included via the `INCLUDE' directive.  File: g77.info, Node: Bit Operations on Floating-point Data, Next: Really Ugly Character Assignments, Prev: Fortran Preprocessor, Up: Missing Features Bit Operations on Floating-point Data ------------------------------------- `g77' does not allow `REAL' and other non-integral types for arguments to intrinsics like `And', `Or', and `Shift'. For example, this program is rejected by `g77', because the intrinsic `Iand' does not accept `REAL' arguments: DATA A/7.54/, B/9.112/ PRINT *, IAND(A, B) END  File: g77.info, Node: Really Ugly Character Assignments, Next: POSIX Standard, Prev: Bit Operations on Floating-point Data, Up: Missing Features Really Ugly Character Assignments --------------------------------- An option such as `-fugly-char' should be provided to allow REAL*8 A1 DATA A1 / '12345678' / and: REAL*8 A1 A1 = 'ABCDEFGH'  File: g77.info, Node: POSIX Standard, Next: Floating-point Exception Handling, Prev: Really Ugly Character Assignments, Up: Missing Features `POSIX' Standard ---------------- `g77' should support the POSIX standard for Fortran.  File: g77.info, Node: Floating-point Exception Handling, Next: Nonportable Conversions, Prev: POSIX Standard, Up: Missing Features Floating-point Exception Handling --------------------------------- The `gcc' backend and, consequently, `g77', currently provides no general control over whether or not floating-point exceptions are trapped or ignored. (Ignoring them typically results in NaN values being propagated in systems that conform to IEEE 754.) The behavior is normally inherited from the system-dependent startup code, though some targets, such as the Alpha, have code generation options which change the behavior. Most systems provide some C-callable mechanism to change this; this can be invoked at startup using `gcc''s `constructor' attribute. For example, just compiling and linking the following C code with your program will turn on exception trapping for the "common" exceptions on a GNU system using glibc 2.2 or newer: #define _GNU_SOURCE 1 #include static void __attribute__ ((constructor)) trapfpe () { /* Enable some exceptions. At startup all exceptions are masked. */ feenableexcept (FE_INVALID|FE_DIVBYZERO|FE_OVERFLOW); } A convenient trick is to compile this something like: gcc -o libtrapfpe.a trapfpe.c and then use it by adding `-trapfpe' to the `g77' command line when linking.  File: g77.info, Node: Nonportable Conversions, Next: Large Automatic Arrays, Prev: Floating-point Exception Handling, Up: Missing Features Nonportable Conversions ----------------------- `g77' doesn't accept some particularly nonportable, silent data-type conversions such as `LOGICAL' to `REAL' (as in `A=.FALSE.', where `A' is type `REAL'), that other compilers might quietly accept. Some of these conversions are accepted by `g77' when the `-fugly-logint' option is specified. Perhaps it should accept more or all of them.  File: g77.info, Node: Large Automatic Arrays, Next: Support for Threads, Prev: Nonportable Conversions, Up: Missing Features Large Automatic Arrays ---------------------- Currently, automatic arrays always are allocated on the stack. For situations where the stack cannot be made large enough, `g77' should offer a compiler option that specifies allocation of automatic arrays in heap storage.  File: g77.info, Node: Support for Threads, Next: Increasing Precision/Range, Prev: Large Automatic Arrays, Up: Missing Features Support for Threads ------------------- Neither the code produced by `g77' nor the `libg2c' library are thread-safe, nor does `g77' have support for parallel processing (other than the instruction-level parallelism available on some processors). A package such as PVM might help here.  File: g77.info, Node: Enabling Debug Lines, Next: Better Warnings, Prev: Increasing Precision/Range, Up: Missing Features Enabling Debug Lines -------------------- An option such as `-fdebug-lines' should be provided to turn fixed-form lines beginning with `D' to be treated as if they began with a space, instead of as if they began with a `C' (as comment lines).  File: g77.info, Node: Better Warnings, Next: Gracefully Handle Sensible Bad Code, Prev: Enabling Debug Lines, Up: Missing Features Better Warnings --------------- Because of how `g77' generates code via the back end, it doesn't always provide warnings the user wants. Consider: PROGRAM X PRINT *, A END Currently, the above is not flagged as a case of using an uninitialized variable, because `g77' generates a run-time library call that looks, to the GBE, like it might actually _modify_ `A' at run time. (And, in fact, depending on the previous run-time library call, it would!) Fixing this requires one of the following: * Switch to new library, `libg77', that provides a more "clean" interface, vis-a-vis input, output, and modified arguments, so the GBE can tell what's going on. This would provide a pretty big performance improvement, at least theoretically, and, ultimately, in practice, for some types of code. * Have `g77' pass a pointer to a temporary containing a copy of `A', instead of to `A' itself. The GBE would then complain about the copy operation involving a potentially uninitialized variable. This might also provide a performance boost for some code, because `A' might then end up living in a register, which could help with inner loops. * Have `g77' use a GBE construct similar to `ADDR_EXPR' but with extra information on the fact that the item pointed to won't be modified (a la `const' in C). Probably the best solution for now, but not quite trivial to implement in the general case.  File: g77.info, Node: Gracefully Handle Sensible Bad Code, Next: Non-standard Conversions, Prev: Better Warnings, Up: Missing Features Gracefully Handle Sensible Bad Code ----------------------------------- `g77' generally should continue processing for warnings and recoverable (user) errors whenever possible--that is, it shouldn't gratuitously make bad or useless code. For example: INTRINSIC ZABS CALL FOO(ZABS) END When compiling the above with `-ff2c-intrinsics-disable', `g77' should indeed complain about passing `ZABS', but it still should compile, instead of rejecting the entire `CALL' statement. (Some of this is related to improving the compiler internals to improve how statements are analyzed.)  File: g77.info, Node: Non-standard Conversions, Next: Non-standard Intrinsics, Prev: Gracefully Handle Sensible Bad Code, Up: Missing Features Non-standard Conversions ------------------------ `-Wconversion' and related should flag places where non-standard conversions are found. Perhaps much of this would be part of `-Wugly*'.  File: g77.info, Node: Non-standard Intrinsics, Next: Modifying DO Variable, Prev: Non-standard Conversions, Up: Missing Features Non-standard Intrinsics ----------------------- `g77' needs a new option, like `-Wintrinsics', to warn about use of non-standard intrinsics without explicit `INTRINSIC' statements for them. This would help find code that might fail silently when ported to another compiler.  File: g77.info, Node: Modifying DO Variable, Next: Better Pedantic Compilation, Prev: Non-standard Intrinsics, Up: Missing Features Modifying `DO' Variable ----------------------- `g77' should warn about modifying `DO' variables via `EQUIVALENCE'. (The internal information gathered to produce this warning might also be useful in setting the internal "doiter" flag for a variable or even array reference within a loop, since that might produce faster code someday.) For example, this code is invalid, so `g77' should warn about the invalid assignment to `NOTHER': EQUIVALENCE (I, NOTHER) DO I = 1, 100 IF (I.EQ. 10) NOTHER = 20 END DO  File: g77.info, Node: Better Pedantic Compilation, Next: Warn About Implicit Conversions, Prev: Modifying DO Variable, Up: Missing Features Better Pedantic Compilation --------------------------- `g77' needs to support `-fpedantic' more thoroughly, and use it only to generate warnings instead of rejecting constructs outright. Have it warn: if a variable that dimensions an array is not a dummy or placed explicitly in `COMMON' (F77 does not allow it to be placed in `COMMON' via `EQUIVALENCE'); if specification statements follow statement-function-definition statements; about all sorts of syntactic extensions.  File: g77.info, Node: Warn About Implicit Conversions, Next: Invalid Use of Hollerith Constant, Prev: Better Pedantic Compilation, Up: Missing Features Warn About Implicit Conversions ------------------------------- `g77' needs a `-Wpromotions' option to warn if source code appears to expect automatic, silent, and somewhat dangerous compiler-assisted conversion of `REAL(KIND=1)' constants to `REAL(KIND=2)' based on context. For example, it would warn about cases like this: DOUBLE PRECISION FOO PARAMETER (TZPHI = 9.435784839284958) FOO = TZPHI * 3D0  File: g77.info, Node: Invalid Use of Hollerith Constant, Next: Dummy Array Without Dimensioning Dummy, Prev: Warn About Implicit Conversions, Up: Missing Features Invalid Use of Hollerith Constant --------------------------------- `g77' should disallow statements like `RETURN 2HAB', which are invalid in both source forms (unlike `RETURN (2HAB)', which probably still makes no sense but at least can be reliably parsed). Fixed-form processing rejects it, but not free-form, except in a way that is a bit difficult to understand.  File: g77.info, Node: Dummy Array Without Dimensioning Dummy, Next: Invalid FORMAT Specifiers, Prev: Invalid Use of Hollerith Constant, Up: Missing Features Dummy Array Without Dimensioning Dummy -------------------------------------- `g77' should complain when a list of dummy arguments containing an adjustable dummy array does not also contain every variable listed in the dimension list of the adjustable array. Currently, `g77' does complain about a variable that dimensions an array but doesn't appear in any dummy list or `COMMON' area, but this needs to be extended to catch cases where it doesn't appear in every dummy list that also lists any arrays it dimensions. For example, `g77' should warn about the entry point `ALT' below, since it includes `ARRAY' but not `ISIZE' in its list of arguments: SUBROUTINE PRIMARY(ARRAY, ISIZE) REAL ARRAY(ISIZE) ENTRY ALT(ARRAY)  File: g77.info, Node: Invalid FORMAT Specifiers, Next: Ambiguous Dialects, Prev: Dummy Array Without Dimensioning Dummy, Up: Missing Features Invalid FORMAT Specifiers ------------------------- `g77' should check `FORMAT' specifiers for validity as it does `FORMAT' statements. For example, a diagnostic would be produced for: PRINT 'HI THERE!' !User meant PRINT *, 'HI THERE!'  File: g77.info, Node: Ambiguous Dialects, Next: Unused Labels, Prev: Invalid FORMAT Specifiers, Up: Missing Features Ambiguous Dialects ------------------ `g77' needs a set of options such as `-Wugly*', `-Wautomatic', `-Wvxt', `-Wf90', and so on. These would warn about places in the user's source where ambiguities are found, helpful in resolving ambiguities in the program's dialect or dialects.  File: g77.info, Node: Unused Labels, Next: Informational Messages, Prev: Ambiguous Dialects, Up: Missing Features Unused Labels ------------- `g77' should warn about unused labels when `-Wunused' is in effect.  File: g77.info, Node: Informational Messages, Next: Uninitialized Variables at Run Time, Prev: Unused Labels, Up: Missing Features Informational Messages ---------------------- `g77' needs an option to suppress information messages (notes). `-w' does this but also suppresses warnings. The default should be to suppress info messages. Perhaps info messages should simply be eliminated.  File: g77.info, Node: Uninitialized Variables at Run Time, Next: Portable Unformatted Files, Prev: Informational Messages, Up: Missing Features Uninitialized Variables at Run Time ----------------------------------- `g77' needs an option to initialize everything (not otherwise explicitly initialized) to "weird" (machine-dependent) values, e.g. NaNs, bad (non-`NULL') pointers, and largest-magnitude integers, would help track down references to some kinds of uninitialized variables at run time. Note that use of the options `-O -Wuninitialized' can catch many such bugs at compile time.  File: g77.info, Node: Portable Unformatted Files, Next: Better List-directed I/O, Prev: Uninitialized Variables at Run Time, Up: Missing Features Portable Unformatted Files -------------------------- `g77' has no facility for exchanging unformatted files with systems using different number formats--even differing only in endianness (byte order)--or written by other compilers. Some compilers provide facilities at least for doing byte-swapping during unformatted I/O. It is unrealistic to expect to cope with exchanging unformatted files with arbitrary other compiler runtimes, but the `g77' runtime should at least be able to read files written by `g77' on systems with different number formats, particularly if they differ only in byte order. In case you do need to write a program to translate to or from `g77' (`libf2c') unformatted files, they are written as follows: Sequential Unformatted sequential records consist of 1. A number giving the length of the record contents; 2. the length of record contents again (for backspace). The record length is of C type `long'; this means that it is 8 bytes on 64-bit systems such as Alpha GNU/Linux and 4 bytes on other systems, such as x86 GNU/Linux. Consequently such files cannot be exchanged between 64-bit and 32-bit systems, even with the same basic number format. Direct access Unformatted direct access files form a byte stream of length RECORDS*RECL bytes, where RECORDS is the maximum record number (`REC=RECORDS') written and RECL is the record length in bytes specified in the `OPEN' statement (`RECL=RECL'). Data appear in the records as determined by the relevant `WRITE' statement. Dummy records with arbitrary contents appear in the file in place of records which haven't been written. Thus for exchanging a sequential or direct access unformatted file between big- and little-endian 32-bit systems using IEEE 754 floating point it would be sufficient to reverse the bytes in consecutive words in the file if, and _only_ if, only `REAL*4', `COMPLEX', `INTEGER*4' and/or `LOGICAL*4' data have been written to it by `g77'. If necessary, it is possible to do byte-oriented i/o with `g77''s `FGETC' and `FPUTC' intrinsics. Byte-swapping can be done in Fortran by equivalencing larger sized variables to an `INTEGER*1' array or a set of scalars. If you need to exchange binary data between arbitrary system and compiler variations, we recommend using a portable binary format with Fortran bindings, such as NCSA's HDF (`http://hdf.ncsa.uiuc.edu/') or PACT's PDB(1) (`http://www.llnl.gov/def_sci/pact/pact_homepage.html'). (Unlike, say, CDF or XDR, HDF-like systems write in the native number formats and only incur overhead when they are read on a system with a different format.) A future `g77' runtime library should use such techniques. ---------- Footnotes ---------- (1) No, not _that_ one.  File: g77.info, Node: Better List-directed I/O, Next: Default to Console I/O, Prev: Portable Unformatted Files, Up: Missing Features Better List-directed I/O ------------------------ Values output using list-directed I/O (`PRINT *, R, D') should be written with a field width, precision, and so on appropriate for the type (precision) of each value. (Currently, no distinction is made between single-precision and double-precision values by `libf2c'.) It is likely this item will require the `libg77' project to be undertaken. In the meantime, use of formatted I/O is recommended. While it might be of little consolation, `g77' does support `FORMAT(F.4)', for example, as long as `WIDTH' is defined as a named constant (via `PARAMETER'). That at least allows some compile-time specification of the precision of a data type, perhaps controlled by preprocessing directives.  File: g77.info, Node: Default to Console I/O, Next: Labels Visible to Debugger, Prev: Better List-directed I/O, Up: Missing Features Default to Console I/O ---------------------- The default I/O units, specified by `READ FMT', `READ (UNIT=*)', `WRITE (UNIT=*)', and `PRINT FMT', should not be units 5 (input) and 6 (output), but, rather, unit numbers not normally available for use in statements such as `OPEN' and `CLOSE'. Changing this would allow a program to connect units 5 and 6 to files via `OPEN', but still use `READ (UNIT=*)' and `PRINT' to do I/O to the "console". This change probably requires the `libg77' project.  File: g77.info, Node: Labels Visible to Debugger, Prev: Default to Console I/O, Up: Missing Features Labels Visible to Debugger -------------------------- `g77' should output debugging information for statements labels, for use by debuggers that know how to support them. Same with weirder things like construct names. It is not yet known if any debug formats or debuggers support these.  File: g77.info, Node: Disappointments, Next: Non-bugs, Prev: Missing Features, Up: Trouble Disappointments and Misunderstandings ===================================== These problems are perhaps regrettable, but we don't know any practical way around them for now. * Menu: * Mangling of Names:: `SUBROUTINE FOO' is given external name `foo_'. * Multiple Definitions of External Names:: No doing both `COMMON /FOO/' and `SUBROUTINE FOO'. * Limitation on Implicit Declarations:: No `IMPLICIT CHARACTER*(*)'.  File: g77.info, Node: Mangling of Names, Next: Multiple Definitions of External Names, Up: Disappointments Mangling of Names in Source Code -------------------------------- The current external-interface design, which includes naming of external procedures, COMMON blocks, and the library interface, has various usability problems, including things like adding underscores where not really necessary (and preventing easier inter-language operability) and yet not providing complete namespace freedom for user C code linked with Fortran apps (due to the naming of functions in the library, among other things). Project GNU should at least get all this "right" for systems it fully controls, such as the Hurd, and provide defaults and options for compatibility with existing systems and interoperability with popular existing compilers.  File: g77.info, Node: Multiple Definitions of External Names, Next: Limitation on Implicit Declarations, Prev: Mangling of Names, Up: Disappointments Multiple Definitions of External Names -------------------------------------- `g77' doesn't allow a common block and an external procedure or `BLOCK DATA' to have the same name. Some systems allow this, but `g77' does not, to be compatible with `f2c'. `g77' could special-case the way it handles `BLOCK DATA', since it is not compatible with `f2c' in this particular area (necessarily, since `g77' offers an important feature here), but it is likely that such special-casing would be very annoying to people with programs that use `EXTERNAL FOO', with no other mention of `FOO' in the same program unit, to refer to external procedures, since the result would be that `g77' would treat these references as requests to force-load BLOCK DATA program units. In that case, if `g77' modified names of `BLOCK DATA' so they could have the same names as `COMMON', users would find that their programs wouldn't link because the `FOO' procedure didn't have its name translated the same way. (Strictly speaking, `g77' could emit a null-but-externally-satisfying definition of `FOO' with its name transformed as if it had been a `BLOCK DATA', but that probably invites more trouble than it's worth.)  File: g77.info, Node: Limitation on Implicit Declarations, Prev: Multiple Definitions of External Names, Up: Disappointments Limitation on Implicit Declarations ----------------------------------- `g77' disallows `IMPLICIT CHARACTER*(*)'. This is not standard-conforming.  File: g77.info, Node: Non-bugs, Next: Warnings and Errors, Prev: Disappointments, Up: Trouble Certain Changes We Don't Want to Make ===================================== This section lists changes that people frequently request, but which we do not make because we think GNU Fortran is better without them. * Menu: * Backslash in Constants:: Why `'\\'' is a constant that is one, not two, characters long. * Initializing Before Specifying:: Why `DATA VAR/1/' can't precede `COMMON VAR'. * Context-Sensitive Intrinsicness:: Why `CALL SQRT' won't work. * Context-Sensitive Constants:: Why `9.435784839284958' is a single-precision constant, and might be interpreted as `9.435785' or similar. * Equivalence Versus Equality:: Why `.TRUE. .EQ. .TRUE.' won't work. * Order of Side Effects:: Why `J = IFUNC() - IFUNC()' might not behave as expected.  File: g77.info, Node: Backslash in Constants, Next: Initializing Before Specifying, Up: Non-bugs Backslash in Constants ---------------------- In the opinion of many experienced Fortran users, `-fno-backslash' should be the default, not `-fbackslash', as currently set by `g77'. First of all, you can always specify `-fno-backslash' to turn off this processing. Despite not being within the spirit (though apparently within the letter) of the ANSI FORTRAN 77 standard, `g77' defaults to `-fbackslash' because that is what most UNIX `f77' commands default to, and apparently lots of code depends on this feature. This is a particularly troubling issue. The use of a C construct in the midst of Fortran code is bad enough, worse when it makes existing Fortran programs stop working (as happens when programs written for non-UNIX systems are ported to UNIX systems with compilers that provide the `-fbackslash' feature as the default--sometimes with no option to turn it off). The author of GNU Fortran wished, for reasons of linguistic purity, to make `-fno-backslash' the default for GNU Fortran and thus require users of UNIX `f77' and `f2c' to specify `-fbackslash' to get the UNIX behavior. However, the realization that `g77' is intended as a replacement for _UNIX_ `f77', caused the author to choose to make `g77' as compatible with `f77' as feasible, which meant making `-fbackslash' the default. The primary focus on compatibility is at the source-code level, and the question became "What will users expect a replacement for `f77' to do, by default?" Although at least one UNIX `f77' does not provide `-fbackslash' as a default, it appears that the majority of them do, which suggests that the majority of code that is compiled by UNIX `f77' compilers expects `-fbackslash' to be the default. It is probably the case that more code exists that would _not_ work with `-fbackslash' in force than code that requires it be in force. However, most of _that_ code is not being compiled with `f77', and when it is, new build procedures (shell scripts, makefiles, and so on) must be set up anyway so that they work under UNIX. That makes a much more natural and safe opportunity for non-UNIX users to adapt their build procedures for `g77''s default of `-fbackslash' than would exist for the majority of UNIX `f77' users who would have to modify existing, working build procedures to explicitly specify `-fbackslash' if that was not the default. One suggestion has been to configure the default for `-fbackslash' (and perhaps other options as well) based on the configuration of `g77'. This is technically quite straightforward, but will be avoided even in cases where not configuring defaults to be dependent on a particular configuration greatly inconveniences some users of legacy code. Many users appreciate the GNU compilers because they provide an environment that is uniform across machines. These users would be inconvenienced if the compiler treated things like the format of the source code differently on certain machines. Occasionally users write programs intended only for a particular machine type. On these occasions, the users would benefit if the GNU Fortran compiler were to support by default the same dialect as the other compilers on that machine. But such applications are rare. And users writing a program to run on more than one type of machine cannot possibly benefit from this kind of compatibility. (This is consistent with the design goals for `gcc'. To change them for `g77', you must first change them for `gcc'. Do not ask the maintainers of `g77' to do this for you, or to disassociate `g77' from the widely understood, if not widely agreed-upon, goals for GNU compilers in general.) This is why GNU Fortran does and will treat backslashes in the same fashion on all types of machines (by default). *Note Direction of Language Development::, for more information on this overall philosophy guiding the development of the GNU Fortran language. Of course, users strongly concerned about portability should indicate explicitly in their build procedures which options are expected by their source code, or write source code that has as few such expectations as possible. For example, avoid writing code that depends on backslash (`\') being interpreted either way in particular, such as by starting a program unit with: CHARACTER BACKSL PARAMETER (BACKSL = '\\') Then, use concatenation of `BACKSL' anyplace a backslash is desired. In this way, users can write programs which have the same meaning in many Fortran dialects. (However, this technique does not work for Hollerith constants--which is just as well, since the only generally portable uses for Hollerith constants are in places where character constants can and should be used instead, for readability.)  File: g77.info, Node: Initializing Before Specifying, Next: Context-Sensitive Intrinsicness, Prev: Backslash in Constants, Up: Non-bugs Initializing Before Specifying ------------------------------ `g77' does not allow `DATA VAR/1/' to appear in the source code before `COMMON VAR', `DIMENSION VAR(10)', `INTEGER VAR', and so on. In general, `g77' requires initialization of a variable or array to be specified _after_ all other specifications of attributes (type, size, placement, and so on) of that variable or array are specified (though _confirmation_ of data type is permitted). It is _possible_ `g77' will someday allow all of this, even though it is not allowed by the FORTRAN 77 standard. Then again, maybe it is better to have `g77' always require placement of `DATA' so that it can possibly immediately write constants to the output file, thus saving time and space. That is, `DATA A/1000000*1/' should perhaps always be immediately writable to canonical assembler, unless it's already known to be in a `COMMON' area following as-yet-uninitialized stuff, and to do this it cannot be followed by `COMMON A'.  File: g77.info, Node: Context-Sensitive Intrinsicness, Next: Context-Sensitive Constants, Prev: Initializing Before Specifying, Up: Non-bugs Context-Sensitive Intrinsicness ------------------------------- `g77' treats procedure references to _possible_ intrinsic names as always enabling their intrinsic nature, regardless of whether the _form_ of the reference is valid for that intrinsic. For example, `CALL SQRT' is interpreted by `g77' as an invalid reference to the `SQRT' intrinsic function, because the reference is a subroutine invocation. First, `g77' recognizes the statement `CALL SQRT' as a reference to a _procedure_ named `SQRT', not to a _variable_ with that name (as it would for a statement such as `V = SQRT'). Next, `g77' establishes that, in the program unit being compiled, `SQRT' is an intrinsic--not a subroutine that happens to have the same name as an intrinsic (as would be the case if, for example, `EXTERNAL SQRT' was present). Finally, `g77' recognizes that the _form_ of the reference is invalid for that particular intrinsic. That is, it recognizes that it is invalid for an intrinsic _function_, such as `SQRT', to be invoked as a _subroutine_. At that point, `g77' issues a diagnostic. Some users claim that it is "obvious" that `CALL SQRT' references an external subroutine of their own, not an intrinsic function. However, `g77' knows about intrinsic subroutines, not just functions, and is able to support both having the same names, for example. As a result of this, `g77' rejects calls to intrinsics that are not subroutines, and function invocations of intrinsics that are not functions, just as it (and most compilers) rejects invocations of intrinsics with the wrong number (or types) of arguments. So, use the `EXTERNAL SQRT' statement in a program unit that calls a user-written subroutine named `SQRT'.  File: g77.info, Node: Context-Sensitive Constants, Next: Equivalence Versus Equality, Prev: Context-Sensitive Intrinsicness, Up: Non-bugs Context-Sensitive Constants --------------------------- `g77' does not use context to determine the types of constants or named constants (`PARAMETER'), except for (non-standard) typeless constants such as `'123'O'. For example, consider the following statement: PRINT *, 9.435784839284958 * 2D0 `g77' will interpret the (truncated) constant `9.435784839284958' as a `REAL(KIND=1)', not `REAL(KIND=2)', constant, because the suffix `D0' is not specified. As a result, the output of the above statement when compiled by `g77' will appear to have "less precision" than when compiled by other compilers. In these and other cases, some compilers detect the fact that a single-precision constant is used in a double-precision context and therefore interpret the single-precision constant as if it was _explicitly_ specified as a double-precision constant. (This has the effect of appending _decimal_, not _binary_, zeros to the fractional part of the number--producing different computational results.) The reason this misfeature is dangerous is that a slight, apparently innocuous change to the source code can change the computational results. Consider: REAL ALMOST, CLOSE DOUBLE PRECISION FIVE PARAMETER (ALMOST = 5.000000000001) FIVE = 5 CLOSE = 5.000000000001 PRINT *, 5.000000000001 - FIVE PRINT *, ALMOST - FIVE PRINT *, CLOSE - FIVE END Running the above program should result in the same value being printed three times. With `g77' as the compiler, it does. However, compiled by many other compilers, running the above program would print two or three distinct values, because in two or three of the statements, the constant `5.000000000001', which on most systems is exactly equal to `5.' when interpreted as a single-precision constant, is instead interpreted as a double-precision constant, preserving the represented precision. However, this "clever" promotion of type does not extend to variables or, in some compilers, to named constants. Since programmers often are encouraged to replace manifest constants or permanently-assigned variables with named constants (`PARAMETER' in Fortran), and might need to replace some constants with variables having the same values for pertinent portions of code, it is important that compilers treat code so modified in the same way so that the results of such programs are the same. `g77' helps in this regard by treating constants just the same as variables in terms of determining their types in a context-independent way. Still, there is a lot of existing Fortran code that has been written to depend on the way other compilers freely interpret constants' types based on context, so anything `g77' can do to help flag cases of this in such code could be very helpful.  File: g77.info, Node: Equivalence Versus Equality, Next: Order of Side Effects, Prev: Context-Sensitive Constants, Up: Non-bugs Equivalence Versus Equality --------------------------- Use of `.EQ.' and `.NE.' on `LOGICAL' operands is not supported, except via `-fugly-logint', which is not recommended except for legacy code (where the behavior expected by the _code_ is assumed). Legacy code should be changed, as resources permit, to use `.EQV.' and `.NEQV.' instead, as these are permitted by the various Fortran standards. New code should never be written expecting `.EQ.' or `.NE.' to work if either of its operands is `LOGICAL'. The problem with supporting this "feature" is that there is unlikely to be consensus on how it works, as illustrated by the following sample program: LOGICAL L,M,N DATA L,M,N /3*.FALSE./ IF (L.AND.M.EQ.N) PRINT *,'L.AND.M.EQ.N' END The issue raised by the above sample program is: what is the precedence of `.EQ.' (and `.NE.') when applied to `LOGICAL' operands? Some programmers will argue that it is the same as the precedence for `.EQ.' when applied to numeric (such as `INTEGER') operands. By this interpretation, the subexpression `M.EQ.N' must be evaluated first in the above program, resulting in a program that, when run, does not execute the `PRINT' statement. Other programmers will argue that the precedence is the same as the precedence for `.EQV.', which is restricted by the standards to `LOGICAL' operands. By this interpretation, the subexpression `L.AND.M' must be evaluated first, resulting in a program that _does_ execute the `PRINT' statement. Assigning arbitrary semantic interpretations to syntactic expressions that might legitimately have more than one "obvious" interpretation is generally unwise. The creators of the various Fortran standards have done a good job in this case, requiring a distinct set of operators (which have their own distinct precedence) to compare `LOGICAL' operands. This requirement results in expression syntax with more certain precedence (without requiring substantial context), making it easier for programmers to read existing code. `g77' will avoid muddying up elements of the Fortran language that were well-designed in the first place. (Ask C programmers about the precedence of expressions such as `(a) & (b)' and `(a) - (b)'--they cannot even tell you, without knowing more context, whether the `&' and `-' operators are infix (binary) or unary!) Most dangerous of all is the fact that, even assuming consensus on its meaning, an expression like `L.AND.M.EQ.N', if it is the result of a typographical error, doesn't _look_ like it has such a typo. Even experienced Fortran programmers would not likely notice that `L.AND.M.EQV.N' was, in fact, intended. So, this is a prime example of a circumstance in which a quality compiler diagnoses the code, instead of leaving it up to someone debugging it to know to turn on special compiler options that might diagnose it.  File: g77.info, Node: Order of Side Effects, Prev: Equivalence Versus Equality, Up: Non-bugs Order of Side Effects --------------------- `g77' does not necessarily produce code that, when run, performs side effects (such as those performed by function invocations) in the same order as in some other compiler--or even in the same order as another version, port, or invocation (using different command-line options) of `g77'. It is never safe to depend on the order of evaluation of side effects. For example, an expression like this may very well behave differently from one compiler to another: J = IFUNC() - IFUNC() There is no guarantee that `IFUNC' will be evaluated in any particular order. Either invocation might happen first. If `IFUNC' returns 5 the first time it is invoked, and returns 12 the second time, `J' might end up with the value `7', or it might end up with `-7'. Generally, in Fortran, procedures with side-effects intended to be visible to the caller are best designed as _subroutines_, not functions. Examples of such side-effects include: * The generation of random numbers that are intended to influence return values. * Performing I/O (other than internal I/O to local variables). * Updating information in common blocks. An example of a side-effect that is not intended to be visible to the caller is a function that maintains a cache of recently calculated results, intended solely to speed repeated invocations of the function with identical arguments. Such a function can be safely used in expressions, because if the compiler optimizes away one or more calls to the function, operation of the program is unaffected (aside from being speeded up).  File: g77.info, Node: Warnings and Errors, Prev: Non-bugs, Up: Trouble Warning Messages and Error Messages =================================== The GNU compiler can produce two kinds of diagnostics: errors and warnings. Each kind has a different purpose: _Errors_ report problems that make it impossible to compile your program. GNU Fortran reports errors with the source file name, line number, and column within the line where the problem is apparent. _Warnings_ report other unusual conditions in your code that _might_ indicate a problem, although compilation can (and does) proceed. Warning messages also report the source file name, line number, and column information, but include the text `warning:' to distinguish them from error messages. Warnings might indicate danger points where you should check to make sure that your program really does what you intend; or the use of obsolete features; or the use of nonstandard features of GNU Fortran. Many warnings are issued only if you ask for them, with one of the `-W' options (for instance, `-Wall' requests a variety of useful warnings). _Note:_ Currently, the text of the line and a pointer to the column is printed in most `g77' diagnostics. *Note Options to Request or Suppress Warnings: Warning Options, for more detail on these and related command-line options.  File: g77.info, Node: Open Questions, Next: Bugs, Prev: Trouble, Up: Top Open Questions ************** Please consider offering useful answers to these questions! * `LOC()' and other intrinsics are probably somewhat misclassified. Is the a need for more precise classification of intrinsics, and if so, what are the appropriate groupings? Is there a need to individually enable/disable/delete/hide intrinsics from the command line?  File: g77.info, Node: Bugs, Next: Service, Prev: Open Questions, Up: Top Reporting Bugs ************** Your bug reports play an essential role in making GNU Fortran reliable. When you encounter a problem, the first thing to do is to see if it is already known. *Note Trouble::. If it isn't known, then you should report the problem. * Menu: * Criteria: Bug Criteria. Have you really found a bug? * Reporting: Bug Reporting. How to report a bug effectively. *Note Known Causes of Trouble with GNU Fortran: Trouble, for information on problems we already know about. *Note How To Get Help with GNU Fortran: Service, for information on where to ask for help.  File: g77.info, Node: Bug Criteria, Next: Bug Reporting, Up: Bugs Have You Found a Bug? ===================== If you are not sure whether you have found a bug, here are some guidelines: * If the compiler gets a fatal signal, for any input whatever, that is a compiler bug. Reliable compilers never crash--they just remain obsolete. * If the compiler produces invalid assembly code, for any input whatever, that is a compiler bug, unless the compiler reports errors (not just warnings) which would ordinarily prevent the assembler from being run. * If the compiler produces valid assembly code that does not correctly execute the input source code, that is a compiler bug. However, you must double-check to make sure, because you might have run into an incompatibility between GNU Fortran and traditional Fortran. These incompatibilities might be considered bugs, but they are inescapable consequences of valuable features. Or you might have a program whose behavior is undefined, which happened by chance to give the desired results with another Fortran compiler. It is best to check the relevant Fortran standard thoroughly if it is possible that the program indeed does something undefined. After you have localized the error to a single source line, it should be easy to check for these things. If your program is correct and well defined, you have found a compiler bug. It might help if, in your submission, you identified the specific language in the relevant Fortran standard that specifies the desired behavior, if it isn't likely to be obvious and agreed-upon by all Fortran users. * If the compiler produces an error message for valid input, that is a compiler bug. * If the compiler does not produce an error message for invalid input, that is a compiler bug. However, you should note that your idea of "invalid input" might be someone else's idea of "an extension" or "support for traditional practice". * If you are an experienced user of Fortran compilers, your suggestions for improvement of GNU Fortran are welcome in any case. Many, perhaps most, bug reports against `g77' turn out to be bugs in the user's code. While we find such bug reports educational, they sometimes take a considerable amount of time to track down or at least respond to--time we could be spending making `g77', not some user's code, better. Some steps you can take to verify that the bug is not certainly in the code you're compiling with `g77': * Compile your code using the `g77' options `-W -Wall -O'. These options enable many useful warning; the `-O' option enables flow analysis that enables the uninitialized-variable warning. If you investigate the warnings and find evidence of possible bugs in your code, fix them first and retry `g77'. * Compile your code using the `g77' options `-finit-local-zero', `-fno-automatic', `-ffloat-store', and various combinations thereof. If your code works with any of these combinations, that is not proof that the bug isn't in `g77'--a `g77' bug exposed by your code might simply be avoided, or have a different, more subtle effect, when different options are used--but it can be a strong indicator that your code is making unwarranted assumptions about the Fortran dialect and/or underlying machine it is being compiled and run on. *Note Overly Convenient Command-Line Options: Overly Convenient Options, for information on the `-fno-automatic' and `-finit-local-zero' options and how to convert their use into selective changes in your own code. * Validate your code with `ftnchek' or a similar code-checking tool. `ftnchek' can be found at `ftp://ftp.netlib.org/fortran' or `ftp://ftp.dsm.fordham.edu'. Here are some sample `Makefile' rules using `ftnchek' "project" files to do cross-file checking and `sfmakedepend' (from `ftp://ahab.rutgers.edu/pub/perl/sfmakedepend') to maintain dependencies automatically. These assume the use of GNU `make'. # Dummy suffix for ftnchek targets: .SUFFIXES: .chek .PHONY: chekall # How to compile .f files (for implicit rule): FC = g77 # Assume `include' directory: FFLAGS = -Iinclude -g -O -Wall # Flags for ftnchek: CHEK1 = -array=0 -include=includes -noarray CHEK2 = -nonovice -usage=1 -notruncation CHEKFLAGS = $(CHEK1) $(CHEK2) # Run ftnchek with all the .prj files except the one corresponding # to the target's root: %.chek : %.f ; \ ftnchek $(filter-out $*.prj,$(PRJS)) $(CHEKFLAGS) \ -noextern -library $< # Derive a project file from a source file: %.prj : %.f ; \ ftnchek $(CHEKFLAGS) -noextern -project -library $< # The list of objects is assumed to be in variable OBJS. # Sources corresponding to the objects: SRCS = $(OBJS:%.o=%.f) # ftnchek project files: PRJS = $(OBJS:%.o=%.prj) # Build the program prog: $(OBJS) ; \ $(FC) -o $ $(OBJS) chekall: $(PRJS) ; \ ftnchek $(CHEKFLAGS) $(PRJS) prjs: $(PRJS) # For Emacs M-x find-tag: TAGS: $(SRCS) ; \ etags $(SRCS) # Rebuild dependencies: depend: ; \ sfmakedepend -I $(PLTLIBDIR) -I includes -a prj $(SRCS1) * Try your code out using other Fortran compilers, such as `f2c'. If it does not work on at least one other compiler (assuming the compiler supports the features the code needs), that is a strong indicator of a bug in the code. However, even if your code works on many compilers _except_ `g77', that does _not_ mean the bug is in `g77'. It might mean the bug is in your code, and that `g77' simply exposes it more readily than other compilers.  File: g77.info, Node: Bug Reporting, Prev: Bug Criteria, Up: Bugs How to Report Bugs ================== Bugs should be reported to our bug database. Please refer to `http://gcc.gnu.org/bugs.html' for up-to-date instructions how to submit bug reports. Copies of this file in HTML (`bugs.html') and plain text (`BUGS') are also part of GCC releases.  File: g77.info, Node: Service, Next: Adding Options, Prev: Bugs, Up: Top How To Get Help with GNU Fortran ******************************** If you need help installing, using or changing GNU Fortran, there are two ways to find it: * Look in the service directory for someone who might help you for a fee. The service directory is found in the file named `SERVICE' in the GCC distribution. * Send a message to .  File: g77.info, Node: Adding Options, Next: Projects, Prev: Service, Up: Top Adding Options ************** To add a new command-line option to `g77', first decide what kind of option you wish to add. Search the `g77' and `gcc' documentation for one or more options that is most closely like the one you want to add (in terms of what kind of effect it has, and so on) to help clarify its nature. * _Fortran options_ are options that apply only when compiling Fortran programs. They are accepted by `g77' and `gcc', but they apply only when compiling Fortran programs. * _Compiler options_ are options that apply when compiling most any kind of program. _Fortran options_ are listed in the file `gcc/gcc/f/lang-options.h', which is used during the build of `gcc' to build a list of all options that are accepted by at least one language's compiler. This list goes into the `documented_lang_options' array in `gcc/toplev.c', which uses this array to determine whether a particular option should be offered to the linked-in front end for processing by calling `lang_option_decode', which, for `g77', is in `gcc/gcc/f/com.c' and just calls `ffe_decode_option'. If the linked-in front end "rejects" a particular option passed to it, `toplev.c' just ignores the option, because _some_ language's compiler is willing to accept it. This allows commands like `gcc -fno-asm foo.c bar.f' to work, even though Fortran compilation does not currently support the `-fno-asm' option; even though the `f771' version of `lang_decode_option' rejects `-fno-asm', `toplev.c' doesn't produce a diagnostic because some other language (C) does accept it. This also means that commands like `g77 -fno-asm foo.f' yield no diagnostics, despite the fact that no phase of the command was able to recognize and process `-fno-asm'--perhaps a warning about this would be helpful if it were possible. Code that processes Fortran options is found in `gcc/gcc/f/top.c', function `ffe_decode_option'. This code needs to check positive and negative forms of each option. The defaults for Fortran options are set in their global definitions, also found in `gcc/gcc/f/top.c'. Many of these defaults are actually macros defined in `gcc/gcc/f/target.h', since they might be machine-specific. However, since, in practice, GNU compilers should behave the same way on all configurations (especially when it comes to language constructs), the practice of setting defaults in `target.h' is likely to be deprecated and, ultimately, stopped in future versions of `g77'. Accessor macros for Fortran options, used by code in the `g77' FFE, are defined in `gcc/gcc/f/top.h'. _Compiler options_ are listed in `gcc/toplev.c' in the array `f_options'. An option not listed in `lang_options' is looked up in `f_options' and handled from there. The defaults for compiler options are set in the global definitions for the corresponding variables, some of which are in `gcc/toplev.c'. You can set different defaults for _Fortran-oriented_ or _Fortran-reticent_ compiler options by changing the source code of `g77' and rebuilding. How to do this depends on the version of `g77': `G77 0.5.24 (EGCS 1.1)' `G77 0.5.25 (EGCS 1.2 - which became GCC 2.95)' Change the `lang_init_options' routine in `gcc/gcc/f/com.c'. (Note that these versions of `g77' perform internal consistency checking automatically when the `-fversion' option is specified.) `G77 0.5.23' `G77 0.5.24 (EGCS 1.0)' Change the way `f771' handles the `-fset-g77-defaults' option, which is always provided as the first option when called by `g77' or `gcc'. This code is in `ffe_decode_options' in `gcc/gcc/f/top.c'. Have it change just the variables that you want to default to a different setting for Fortran compiles compared to compiles of other languages. The `-fset-g77-defaults' option is passed to `f771' automatically because of the specification information kept in `gcc/gcc/f/lang-specs.h'. This file tells the `gcc' command how to recognize, in this case, Fortran source files (those to be preprocessed, and those that are not), and further, how to invoke the appropriate programs (including `f771') to process those source files. It is in `gcc/gcc/f/lang-specs.h' that `-fset-g77-defaults', `-fversion', and other options are passed, as appropriate, even when the user has not explicitly specified them. Other "internal" options such as `-quiet' also are passed via this mechanism.  File: g77.info, Node: Projects, Next: Front End, Prev: Adding Options, Up: Top Projects ******** If you want to contribute to `g77' by doing research, design, specification, documentation, coding, or testing, the following information should give you some ideas. * Menu: * Efficiency:: Make `g77' itself compile code faster. * Better Optimization:: Teach `g77' to generate faster code. * Simplify Porting:: Make `g77' easier to configure, build, and install. * More Extensions:: Features many users won't know to ask for. * Machine Model:: `g77' should better leverage `gcc'. * Internals Documentation:: Make maintenance easier. * Internals Improvements:: Make internals more robust. * Better Diagnostics:: Make using `g77' on new code easier.  File: g77.info, Node: Efficiency, Next: Better Optimization, Up: Projects Improve Efficiency ================== Don't bother doing any performance analysis until most of the following items are taken care of, because there's no question they represent serious space/time problems, although some of them show up only given certain kinds of (popular) input. * Improve `malloc' package and its uses to specify more info about memory pools and, where feasible, use obstacks to implement them. * Skip over uninitialized portions of aggregate areas (arrays, `COMMON' areas, `EQUIVALENCE' areas) so zeros need not be output. This would reduce memory usage for large initialized aggregate areas, even ones with only one initialized element. As of version 0.5.18, a portion of this item has already been accomplished. * Prescan the statement (in `sta.c') so that the nature of the statement is determined as much as possible by looking entirely at its form, and not looking at any context (previous statements, including types of symbols). This would allow ripping out of the statement-confirmation, symbol retraction/confirmation, and diagnostic inhibition mechanisms. Plus, it would result in much-improved diagnostics. For example, `CALL some-intrinsic(...)', where the intrinsic is not a subroutine intrinsic, would result actual error instead of the unimplemented-statement catch-all. * Throughout `g77', don't pass line/column pairs where a simple `ffewhere' type, which points to the error as much as is desired by the configuration, will do, and don't pass `ffelexToken' types where a simple `ffewhere' type will do. Then, allow new default configuration of `ffewhere' such that the source line text is not preserved, and leave it to things like Emacs' next-error function to point to them (now that `next-error' supports column, or, perhaps, character-offset, numbers). The change in calling sequences should improve performance somewhat, as should not having to save source lines. (Whether this whole item will improve performance is questionable, but it should improve maintainability.) * Handle `DATA (A(I),I=1,1000000)/1000000*2/' more efficiently, especially as regards the assembly output. Some of this might require improving the back end, but lots of improvement in space/time required in `g77' itself can be fairly easily obtained without touching the back end. Maybe type-conversion, where necessary, can be speeded up as well in cases like the one shown (converting the `2' into `2.'). * If analysis shows it to be worthwhile, optimize `lex.c'. * Consider redesigning `lex.c' to not need any feedback during tokenization, by keeping track of enough parse state on its own.  File: g77.info, Node: Better Optimization, Next: Simplify Porting, Prev: Efficiency, Up: Projects Better Optimization =================== Much of this work should be put off until after `g77' has all the features necessary for its widespread acceptance as a useful F77 compiler. However, perhaps this work can be done in parallel during the feature-adding work. * Do the equivalent of the trick of putting `extern inline' in front of every function definition in `libg2c' and #include'ing the resulting file in `f2c'+`gcc'--that is, inline all run-time-library functions that are at all worth inlining. (Some of this has already been done, such as for integral exponentiation.) * When doing `CHAR_VAR = CHAR_FUNC(...)', and it's clear that types line up and `CHAR_VAR' is addressable or not a `VAR_DECL', make `CHAR_VAR', not a temporary, be the receiver for `CHAR_FUNC'. (This is now done for `COMPLEX' variables.) * Design and implement Fortran-specific optimizations that don't really belong in the back end, or where the front end needs to give the back end more info than it currently does. * Design and implement a new run-time library interface, with the code going into `libgcc' so no special linking is required to link Fortran programs using standard language features. This library would speed up lots of things, from I/O (using precompiled formats, doing just one, or, at most, very few, calls for arrays or array sections, and so on) to general computing (array/section implementations of various intrinsics, implementation of commonly performed loops that aren't likely to be optimally compiled otherwise, etc.). Among the important things the library would do are: * Be a one-stop-shop-type library, hence shareable and usable by all, in that what are now library-build-time options in `libg2c' would be moved at least to the `g77' compile phase, if not to finer grains (such as choosing how list-directed I/O formatting is done by default at `OPEN' time, for preconnected units via options or even statements in the main program unit, maybe even on a per-I/O basis with appropriate pragma-like devices). * Probably requiring the new library design, change interface to normally have `COMPLEX' functions return their values in the way `gcc' would if they were declared `__complex__ float', rather than using the mechanism currently used by `CHARACTER' functions (whereby the functions are compiled as returning void and their first arg is a pointer to where to store the result). (Don't append underscores to external names for `COMPLEX' functions in some cases once `g77' uses `gcc' rather than `f2c' calling conventions.) * Do something useful with `doiter' references where possible. For example, `CALL FOO(I)' cannot modify `I' if within a `DO' loop that uses `I' as the iteration variable, and the back end might find that info useful in determining whether it needs to read `I' back into a register after the call. (It normally has to do that, unless it knows `FOO' never modifies its passed-by-reference argument, which is rarely the case for Fortran-77 code.)  File: g77.info, Node: Simplify Porting, Next: More Extensions, Prev: Better Optimization, Up: Projects Simplify Porting ================ Making `g77' easier to configure, port, build, and install, either as a single-system compiler or as a cross-compiler, would be very useful. * A new library (replacing `libg2c') should improve portability as well as produce more optimal code. Further, `g77' and the new library should conspire to simplify naming of externals, such as by removing unnecessarily added underscores, and to reduce/eliminate the possibility of naming conflicts, while making debugger more straightforward. Also, it should make multi-language applications more feasible, such as by providing Fortran intrinsics that get Fortran unit numbers given C `FILE *' descriptors. * Possibly related to a new library, `g77' should produce the equivalent of a `gcc' `main(argc, argv)' function when it compiles a main program unit, instead of compiling something that must be called by a library implementation of `main()'. This would do many useful things such as provide more flexibility in terms of setting up exception handling, not requiring programmers to start their debugging sessions with `breakpoint MAIN__' followed by `run', and so on. * The GBE needs to understand the difference between alignment requirements and desires. For example, on Intel x86 machines, `g77' currently imposes overly strict alignment requirements, due to the back end, but it would be useful for Fortran and C programmers to be able to override these _recommendations_ as long as they don't violate the actual processor _requirements_.  File: g77.info, Node: More Extensions, Next: Machine Model, Prev: Simplify Porting, Up: Projects More Extensions =============== These extensions are not the sort of things users ask for "by name", but they might improve the usability of `g77', and Fortran in general, in the long run. Some of these items really pertain to improving `g77' internals so that some popular extensions can be more easily supported. * Look through all the documentation on the GNU Fortran language, dialects, compiler, missing features, bugs, and so on. Many mentions of incomplete or missing features are sprinkled throughout. It is not worth repeating them here. * Consider adding a `NUMERIC' type to designate typeless numeric constants, named and unnamed. The idea is to provide a forward-looking, effective replacement for things like the old-style `PARAMETER' statement when people really need typelessness in a maintainable, portable, clearly documented way. Maybe `TYPELESS' would include `CHARACTER', `POINTER', and whatever else might come along. (This is not really a call for polymorphism per se, just an ability to express limited, syntactic polymorphism.) * Support `OPEN(...,KEY=(...),...)'. * Support arbitrary file unit numbers, instead of limiting them to 0 through `MXUNIT-1'. (This is a `libg2c' issue.) * `OPEN(NOSPANBLOCKS,...)' is treated as `OPEN(UNIT=NOSPANBLOCKS,...)', so a later `UNIT=' in the first example is invalid. Make sure this is what users of this feature would expect. * Currently `g77' disallows `READ(1'10)' since it is an obnoxious syntax, but supporting it might be pretty easy if needed. More details are needed, such as whether general expressions separated by an apostrophe are supported, or maybe the record number can be a general expression, and so on. * Support `STRUCTURE', `UNION', `MAP', and `RECORD' fully. Currently there is no support at all for `%FILL' in `STRUCTURE' and related syntax, whereas the rest of the stuff has at least some parsing support. This requires either major changes to `libg2c' or its replacement. * F90 and `g77' probably disagree about label scoping relative to `INTERFACE' and `END INTERFACE', and their contained procedure interface bodies (blocks?). * `ENTRY' doesn't support F90 `RESULT()' yet, since that was added after S8.112. * Empty-statement handling (10 ;;CONTINUE;;) probably isn't consistent with the final form of the standard (it was vague at S8.112). * It seems to be an "open" question whether a file, immediately after being `OPEN'ed,is positioned at the beginning, the end, or wherever--it might be nice to offer an option of opening to "undefined" status, requiring an explicit absolute-positioning operation to be performed before any other (besides `CLOSE') to assist in making applications port to systems (some IBM?) that `OPEN' to the end of a file or some such thing.  File: g77.info, Node: Machine Model, Next: Internals Documentation, Prev: More Extensions, Up: Projects Machine Model ============= This items pertain to generalizing `g77''s view of the machine model to more fully accept whatever the GBE provides it via its configuration. * Switch to using `REAL_VALUE_TYPE' to represent floating-point constants exclusively so the target float format need not be required. This means changing the way `g77' handles initialization of aggregate areas having more than one type, such as `REAL' and `INTEGER', because currently it initializes them as if they were arrays of `char' and uses the bit patterns of the constants of the various types in them to determine what to stuff in elements of the arrays. * Rely more and more on back-end info and capabilities, especially in the area of constants (where having the `g77' front-end's IL just store the appropriate tree nodes containing constants might be best). * Suite of C and Fortran programs that a user/administrator can run on a machine to help determine the configuration for `g77' before building and help determine if the compiler works (especially with whatever libraries are installed) after building.  File: g77.info, Node: Internals Documentation, Next: Internals Improvements, Prev: Machine Model, Up: Projects Internals Documentation ======================= Better info on how `g77' works and how to port it is needed. *Note Front End::, which contains some information on `g77' internals.  File: g77.info, Node: Internals Improvements, Next: Better Diagnostics, Prev: Internals Documentation, Up: Projects Internals Improvements ====================== Some more items that would make `g77' more reliable and easier to maintain: * Generally make expression handling focus more on critical syntax stuff, leaving semantics to callers. For example, anything a caller can check, semantically, let it do so, rather than having `expr.c' do it. (Exceptions might include things like diagnosing `FOO(I--K:)=BAR' where `FOO' is a `PARAMETER'--if it seems important to preserve the left-to-right-in-source order of production of diagnostics.) * Come up with better naming conventions for `-D' to establish requirements to achieve desired implementation dialect via `proj.h'. * Clean up used tokens and `ffewhere's in `ffeglobal_terminate_1'. * Replace `sta.c' `outpooldisp' mechanism with `malloc_pool_use'. * Check for `opANY' in more places in `com.c', `std.c', and `ste.c', and get rid of the `opCONVERT(opANY)' kludge (after determining if there is indeed no real need for it). * Utility to read and check `bad.def' messages and their references in the code, to make sure calls are consistent with message templates. * Search and fix `&ffe...' and similar so that `ffe...ptr...' macros are available instead (a good argument for wishing this could have written all this stuff in C++, perhaps). On the other hand, it's questionable whether this sort of improvement is really necessary, given the availability of tools such as Emacs and Perl, which make finding any address-taking of structure members easy enough? * Some modules truly export the member names of their structures (and the structures themselves), maybe fix this, and fix other modules that just appear to as well (by appending `_', though it'd be ugly and probably not worth the time). * Implement C macros `RETURNS(value)' and `SETS(something,value)' in `proj.h' and use them throughout `g77' source code (especially in the definitions of access macros in `.h' files) so they can be tailored to catch code writing into a `RETURNS()' or reading from a `SETS()'. * Decorate throughout with `const' and other such stuff. * All F90 notational derivations in the source code are still based on the S8.112 version of the draft standard. Probably should update to the official standard, or put documentation of the rules as used in the code...uh...in the code. * Some `ffebld_new' calls (those outside of `ffeexpr.c' or inside but invoked via paths not involving `ffeexpr_lhs' or `ffeexpr_rhs') might be creating things in improper pools, leading to such things staying around too long or (doubtful, but possible and dangerous) not long enough. * Some `ffebld_list_new' (or whatever) calls might not be matched by `ffebld_list_bottom' (or whatever) calls, which might someday matter. (It definitely is not a problem just yet.) * Probably not doing clean things when we fail to `EQUIVALENCE' something due to alignment/mismatch or other problems--they end up without `ffestorag' objects, so maybe the backend (and other parts of the front end) can notice that and handle like an `opANY' (do what it wants, just don't complain or crash). Most of this seems to have been addressed by now, but a code review wouldn't hurt.  File: g77.info, Node: Better Diagnostics, Prev: Internals Improvements, Up: Projects Better Diagnostics ================== These are things users might not ask about, or that need to be looked into, before worrying about. Also here are items that involve reducing unnecessary diagnostic clutter. * When `FUNCTION' and `ENTRY' point types disagree (`CHARACTER' lengths, type classes, and so on), `ANY'-ize the offending `ENTRY' point and any _new_ dummies it specifies. * Speed up and improve error handling for data when repeat-count is specified. For example, don't output 20 unnecessary messages after the first necessary one for: INTEGER X(20) CONTINUE DATA (X(I), J= 1, 20) /20*5/ END (The `CONTINUE' statement ensures the `DATA' statement is processed in the context of executable, not specification, statements.)  File: g77.info, Node: Front End, Next: Diagnostics, Prev: Projects, Up: Top Front End ********* This chapter describes some aspects of the design and implementation of the `g77' front end. To find about things that are "To Be Determined" or "To Be Done", search for the string TBD. If you want to help by working on one or more of these items, email . If you're planning to do more than just research issues and offer comments, see `http://gcc.gnu.org/contribute.html' for steps you might need to take first. * Menu: * Overview of Sources:: * Overview of Translation Process:: * Philosophy of Code Generation:: * Two-pass Design:: * Challenges Posed:: * Transforming Statements:: * Transforming Expressions:: * Internal Naming Conventions::  File: g77.info, Node: Overview of Sources, Next: Overview of Translation Process, Up: Front End Overview of Sources =================== The current directory layout includes the following: `SRCDIR/gcc/' Non-g77 files in gcc `SRCDIR/gcc/f/' GNU Fortran front end sources `SRCDIR/libf2c/' `libg2c' configuration and `g2c.h' file generation `SRCDIR/libf2c/libF77/' General support and math portion of `libg2c' `SRCDIR/libf2c/libI77/' I/O portion of `libg2c' `SRCDIR/libf2c/libU77/' Additional interfaces to Unix `libc' for `libg2c' Components of note in `g77' are described below. `f/' as a whole contains the source for `g77', while `libf2c/' contains a portion of the separate program `f2c'. Note that the `libf2c' code is not part of the program `g77', just distributed with it. `f/' contains text files that document the Fortran compiler, source files for the GNU Fortran Front End (FFE), and some other stuff. The `g77' compiler code is placed in `f/' because it, along with its contents, is designed to be a subdirectory of a `gcc' source directory, `gcc/', which is structured so that language-specific front ends can be "dropped in" as subdirectories. The C++ front end (`g++'), is an example of this--it resides in the `cp/' subdirectory. Note that the C front end (also referred to as `gcc') is an exception to this, as its source files reside in the `gcc/' directory itself. `libf2c/' contains the run-time libraries for the `f2c' program, also used by `g77'. These libraries normally referred to collectively as `libf2c'. When built as part of `g77', `libf2c' is installed under the name `libg2c' to avoid conflict with any existing version of `libf2c', and thus is often referred to as `libg2c' when the `g77' version is specifically being referred to. The `netlib' version of `libf2c/' contains two distinct libraries, `libF77' and `libI77', each in their own subdirectories. In `g77', this distinction is not made, beyond maintaining the subdirectory structure in the source-code tree. `libf2c/' is not part of the program `g77', just distributed with it. It contains files not present in the official (`netlib') version of `libf2c', and also contains some minor changes made from `libf2c', to fix some bugs, and to facilitate automatic configuration, building, and installation of `libf2c' (as `libg2c') for use by `g77' users. See `libf2c/README' for more information, including licensing conditions governing distribution of programs containing code from `libg2c'. `libg2c', `g77''s version of `libf2c', adds Dave Love's implementation of `libU77', in the `libf2c/libU77/' directory. This library is distributed under the GNU Library General Public License (LGPL)--see the file `libf2c/libU77/COPYING.LIB' for more information, as this license governs distribution conditions for programs containing code from this portion of the library. Files of note in `f/' and `libf2c/' are described below: `f/BUGS' Lists some important bugs known to be in g77. Or use Info (or GNU Emacs Info mode) to read the "Actual Bugs" node of the `g77' documentation: info -f f/g77.info -n "Actual Bugs" `f/ChangeLog' Lists recent changes to `g77' internals. `libf2c/ChangeLog' Lists recent changes to `libg2c' internals. `f/NEWS' Contains the per-release changes. These include the user-visible changes described in the node "Changes" in the `g77' documentation, plus internal changes of import. Or use: info -f f/g77.info -n News `f/g77.info*' The `g77' documentation, in Info format, produced by building `g77'. All users of `g77' (not just installers) should read this, using the `more' command if neither the `info' command, nor GNU Emacs (with its Info mode), are available, or if users aren't yet accustomed to using these tools. All of these files are readable as "plain text" files, though they're easier to navigate using Info readers such as `info' and GNU Emacs Info mode. If you want to explore the FFE code, which lives entirely in `f/', here are a few clues. The file `g77spec.c' contains the `g77'-specific source code for the `g77' command only--this just forms a variant of the `gcc' command, so, just as the `gcc' command itself does not contain the C front end, the `g77' command does not contain the Fortran front end (FFE). The FFE code ends up in an executable named `f771', which does the actual compiling, so it contains the FFE plus the `gcc' back end (GBE), the latter to do most of the optimization, and the code generation. The file `parse.c' is the source file for `yyparse()', which is invoked by the GBE to start the compilation process, for `f771'. The file `top.c' contains the top-level FFE function `ffe_file' and it (along with top.h) define all `ffe_[a-z].*', `ffe[A-Z].*', and `FFE_[A-Za-z].*' symbols. The file `fini.c' is a `main()' program that is used when building the FFE to generate C header and source files for recognizing keywords. The files `malloc.c' and `malloc.h' comprise a memory manager that defines all `malloc_[a-z].*', `malloc[A-Z].*', and `MALLOC_[A-Za-z].*' symbols. All other modules named XYZ are comprised of all files named `XYZ*.EXT' and define all `ffeXYZ_[a-z].*', `ffeXYZ[A-Z].*', and `FFEXYZ_[A-Za-z].*' symbols. If you understand all this, congratulations--it's easier for me to remember how it works than to type in these regular expressions. But it does make it easy to find where a symbol is defined. For example, the symbol `ffexyz_set_something' would be defined in `xyz.h' and implemented there (if it's a macro) or in `xyz.c'. The "porting" files of note currently are: `proj.h' This defines the "language" used by all the other source files, the language being Standard C plus some useful things like `ARRAY_SIZE' and such. `target.c' `target.h' These describe the target machine in terms of what data types are supported, how they are denoted (to what C type does an `INTEGER*8' map, for example), how to convert between them, and so on. Over time, versions of `g77' rely less on this file and more on run-time configuration based on GBE info in `com.c'. `com.c' `com.h' These are the primary interface to the GBE. `ste.c' `ste.h' This contains code for implementing recognized executable statements in the GBE. `src.c' `src.h' These contain information on the format(s) of source files (such as whether they are never to be processed as case-insensitive with regard to Fortran keywords). If you want to debug the `f771' executable, for example if it crashes, note that the global variables `lineno' and `input_filename' are usually set to reflect the current line being read by the lexer during the first-pass analysis of a program unit and to reflect the current line being processed during the second-pass compilation of a program unit. If an invocation of the function `ffestd_exec_end' is on the stack, the compiler is in the second pass, otherwise it is in the first. (This information might help you reduce a test case and/or work around a bug in `g77' until a fix is available.)  File: g77.info, Node: Overview of Translation Process, Next: Philosophy of Code Generation, Prev: Overview of Sources, Up: Front End Overview of Translation Process =============================== The order of phases translating source code to the form accepted by the GBE is: 1. Stripping punched-card sources (`g77stripcard.c') 2. Lexing (`lex.c') 3. Stand-alone statement identification (`sta.c') 4. INCLUDE handling (`sti.c') 5. Order-dependent statement identification (`stq.c') 6. Parsing (`stb.c' and `expr.c') 7. Constructing (`stc.c') 8. Collecting (`std.c') 9. Expanding (`ste.c') To get a rough idea of how a particularly twisted Fortran statement gets treated by the passes, consider: FORMAT(I2 4H)=(J/ & I3) The job of `lex.c' is to know enough about Fortran syntax rules to break the statement up into distinct lexemes without requiring any feedback from subsequent phases: `FORMAT' `(' `I24H' `)' `=' `(' `J' `/' `I3' `)' The job of `sta.c' is to figure out the kind of statement, or, at least, statement form, that sequence of lexemes represent. The sooner it can do this (in terms of using the smallest number of lexemes, starting with the first for each statement), the better, because that leaves diagnostics for problems beyond the recognition of the statement form to subsequent phases, which can usually better describe the nature of the problem. In this case, the `=' at "level zero" (not nested within parentheses) tells `sta.c' that this is an _assignment-form_, not `FORMAT', statement. An assignment-form statement might be a statement-function definition or an executable assignment statement. To make that determination, `sta.c' looks at the first two lexemes. Since the second lexeme is `(', the first must represent an array for this to be an assignment statement, else it's a statement function. Either way, `sta.c' hands off the statement to `stq.c' (via `sti.c', which expands INCLUDE files). `stq.c' figures out what a statement that is, on its own, ambiguous, must actually be based on the context established by previous statements. So, `stq.c' watches the statement stream for executable statements, END statements, and so on, so it knows whether `A(B)=C' is (intended as) a statement-function definition or an assignment statement. After establishing the context-aware statement info, `stq.c' passes the original sample statement on to `stb.c' (either its statement-function parser or its assignment-statement parser). `stb.c' forms a statement-specific record containing the pertinent information. That information includes a source expression and, for an assignment statement, a destination expression. Expressions are parsed by `expr.c'. This record is passed to `stc.c', which copes with the implications of the statement within the context established by previous statements. For example, if it's the first statement in the file or after an `END' statement, `stc.c' recognizes that, first of all, a main program unit is now being lexed (and tells that to `std.c' before telling it about the current statement). `stc.c' attaches whatever information it can, usually derived from the context established by the preceding statements, and passes the information to `std.c'. `std.c' saves this information away, since the GBE cannot cope with information that might be incomplete at this stage. For example, `I3' might later be determined to be an argument to an alternate `ENTRY' point. When `std.c' is told about the end of an external (top-level) program unit, it passes all the information it has saved away on statements in that program unit to `ste.c'. `ste.c' "expands" each statement, in sequence, by constructing the appropriate GBE information and calling the appropriate GBE routines. Details on the transformational phases follow. Keep in mind that Fortran numbering is used, so the first character on a line is column 1, decimal numbering is used, and so on. * Menu: * g77stripcard:: * lex.c:: * sta.c:: * sti.c:: * stq.c:: * stb.c:: * expr.c:: * stc.c:: * std.c:: * ste.c:: * Gotchas (Transforming):: * TBD (Transforming)::  File: g77.info, Node: g77stripcard, Next: lex.c, Up: Overview of Translation Process g77stripcard ------------ The `g77stripcard' program handles removing content beyond column 72 (adjustable via a command-line option), optionally warning about that content being something other than trailing whitespace or Fortran commentary. This program is needed because `lex.c' doesn't pay attention to maximum line lengths at all, to make it easier to maintain, as well as faster (for sources that don't depend on the maximum column length vis-a-vis trailing non-blank non-commentary content). Just how this program will be run--whether automatically for old source (perhaps as the default for `.f' files?)--is not yet determined. In the meantime, it might as well be implemented as a typical UNIX pipe. It should accept a `-fline-length-N' option, with the default line length set to 72. When the text it strips off the end of a line is not blank (not spaces and tabs), it should insert an additional comment line (beginning with `!', so it works for both fixed-form and free-form files) containing the text, following the stripped line. The inserted comment should have a prefix of some kind, TBD, that distinguishes the comment as representing stripped text. Users could use that to `sed' out such lines, if they wished--it seems silly to provide a command-line option to delete information when it can be so easily filtered out by another program. (This inserted comment should be designed to "fit in" well with whatever the Fortran community is using these days for preprocessor, translator, and other such products, like OpenMP. What that's all about, and how `g77' can elegantly fit its special comment conventions into it all, is TBD as well. We don't want to reinvent the wheel here, but if there turn out to be too many conflicting conventions, we might have to invent one that looks nothing like the others, but which offers their host products a better infrastructure in which to fit and coexist peacefully.) `g77stripcard' probably shouldn't do any tab expansion or other fancy stuff. People can use `expand' or other pre-filtering if they like. The idea here is to keep each stage quite simple, while providing excellent performance for "normal" code. (Code with junk beyond column 73 is not really "normal", as it comes from a card-punch heritage, and will be increasingly hard for tomorrow's Fortran programmers to read.)  File: g77.info, Node: lex.c, Next: sta.c, Prev: g77stripcard, Up: Overview of Translation Process lex.c ----- To help make the lexer simple, fast, and easy to maintain, while also having `g77' generally encourage Fortran programmers to write simple, maintainable, portable code by maximizing the performance of compiling that kind of code: * There'll be just one lexer, for both fixed-form and free-form source. * It'll care about the form only when handling the first 7 columns of text, stuff like spaces between strings of alphanumerics, and how lines are continued. Some other distinctions will be handled by subsequent phases, so at least one of them will have to know which form is involved. For example, `I = 2 . 4' is acceptable in fixed form, and works in free form as well given the implementation `g77' presently uses. But the standard requires a diagnostic for it in free form, so the parser has to be able to recognize that the lexemes aren't contiguous (information the lexer _does_ have to provide) and that free-form source is being parsed, so it can provide the diagnostic. The `g77' lexer doesn't try to gather `2 . 4' into a single lexeme. Otherwise, it'd have to know a whole lot more about how to parse Fortran, or subsequent phases (mainly parsing) would have two paths through lots of critical code--one to handle the lexeme `2', `.', and `4' in sequence, another to handle the lexeme `2.4'. * It won't worry about line lengths (beyond the first 7 columns for fixed-form source). That is, once it starts parsing the "statement" part of a line (column 7 for fixed-form, column 1 for free-form), it'll keep going until it finds a newline, rather than ignoring everything past a particular column (72 or 132). The implication here is that there shouldn't _be_ anything past that last column, other than whitespace or commentary, because users using typical editors (or viewing output as typically printed) won't necessarily know just where the last column is. Code that has "garbage" beyond the last column (almost certainly only fixed-form code with a punched-card legacy, such as code using columns 73-80 for "sequence numbers") will have to be run through `g77stripcard' first. Also, keeping track of the maximum column position while also watching out for the end of a line _and_ while reading from a file just makes things slower. Since a file must be read, and watching for the end of the line is necessary (unless the typical input file was preprocessed to include the necessary number of trailing spaces), dropping the tracking of the maximum column position is the only way to reduce the complexity of the pertinent code while maintaining high performance. * ASCII encoding is assumed for the input file. Code written in other character sets will have to be converted first. * Tabs (ASCII code 9) will be converted to spaces via the straightforward approach. Specifically, a tab is converted to between one and eight spaces as necessary to reach column N, where dividing `(N - 1)' by eight results in a remainder of zero. That saves having to pass most source files through `expand'. * Linefeeds (ASCII code 10) mark the ends of lines. * A carriage return (ASCII code 13) is accept if it immediately precedes a linefeed, in which case it is ignored. Otherwise, it is rejected (with a diagnostic). * Any other characters other than the above that are not part of the GNU Fortran Character Set (*note Character Set::) are rejected with a diagnostic. This includes backspaces, form feeds, and the like. (It might make sense to allow a form feed in column 1 as long as that's the only character on a line. It certainly wouldn't seem to cost much in terms of performance.) * The end of the input stream (EOF) ends the current line. * The distinction between uppercase and lowercase letters will be preserved. It will be up to subsequent phases to decide to fold case. Current plans are to permit any casing for Fortran (reserved) keywords while preserving casing for user-defined names. (This might not be made the default for `.f' files, though.) Preserving case seems necessary to provide more direct access to facilities outside of `g77', such as to C or Pascal code. Names of intrinsics will probably be matchable in any case, (How `external SiN; r = sin(x)' would be handled is TBD. I think old `g77' might already handle that pretty elegantly, but whether we can cope with allowing the same fragment to reference a _different_ procedure, even with the same interface, via `s = SiN(r)', needs to be determined. If it can't, we need to make sure that when code introduces a user-defined name, any intrinsic matching that name using a case-insensitive comparison is "turned off".) * Backslashes in `CHARACTER' and Hollerith constants are not allowed. This avoids the confusion introduced by some Fortran compiler vendors providing C-like interpretation of backslashes, while others provide straight-through interpretation. Some kind of lexical construct (TBD) will be provided to allow flagging of a `CHARACTER' (but probably not a Hollerith) constant that permits backslashes. It'll necessarily be a prefix, such as: PRINT *, C'This line has a backspace \b here.' PRINT *, F'This line has a straight backslash \ here.' Further, command-line options might be provided to specify that one prefix or the other is to be assumed as the default for `CHARACTER' constants. However, it seems more helpful for `g77' to provide a program that converts prefix all constants (or just those containing backslashes) with the desired designation, so printouts of code can be read without knowing the compile-time options used when compiling it. If such a program is provided (let's name it `g77slash' for now), then a command-line option to `g77' should not be provided. (Though, given that it'll be easy to implement, it might be hard to resist user requests for it "to compile faster than if we have to invoke another filter".) This program would take a command-line option to specify the default interpretation of slashes, affecting which prefix it uses for constants. `g77slash' probably should automatically convert Hollerith constants that contain slashes to the appropriate `CHARACTER' constants. Then `g77' wouldn't have to define a prefix syntax for Hollerith constants specifying whether they want C-style or straight-through backslashes. * To allow for form-neutral INCLUDE files without requiring them to be preprocessed, the fixed-form lexer should offer an extension (if possible) allowing a trailing `&' to be ignored, especially if after column 72, as it would be using the traditional Unix Fortran source model (which ignores _everything_ after column 72). The above implements nearly exactly what is specified by *Note Character Set::, and *Note Lines::, except it also provides automatic conversion of tabs and ignoring of newline-related carriage returns, as well as accommodating form-neutral INCLUDE files. It also implements the "pure visual" model, by which is meant that a user viewing his code in a typical text editor (assuming it's not preprocessed via `g77stripcard' or similar) doesn't need any special knowledge of whether spaces on the screen are really tabs, whether lines end immediately after the last visible non-space character or after a number of spaces and tabs that follow it, or whether the last line in the file is ended by a newline. Most editors don't make these distinctions, the ANSI FORTRAN 77 standard doesn't require them to, and it permits a standard-conforming compiler to define a method for transforming source code to "standard form" however it wants. So, GNU Fortran defines it such that users have the best chance of having the code be interpreted the way it looks on the screen of the typical editor. (Fancy editors should _never_ be required to correctly read code written in classic two-dimensional-plaintext form. By correct reading I mean ability to read it, book-like, without mistaking text ignored by the compiler for program code and vice versa, and without having to count beyond the first several columns. The vague meaning of ASCII TAB, among other things, complicates this somewhat, but as long as "everyone", including the editor, other tools, and printer, agrees about the every-eighth-column convention, the GNU Fortran "pure visual" model meets these requirements. Any language or user-visible source form requiring special tagging of tabs, the ends of lines after spaces/tabs, and so on, fails to meet this fairly straightforward specification. Fortunately, Fortran _itself_ does not mandate such a failure, though most vendor-supplied defaults for their Fortran compilers _do_ fail to meet this specification for readability.) Further, this model provides a clean interface to whatever preprocessors or code-generators are used to produce input to this phase of `g77'. Mainly, they need not worry about long lines.  File: g77.info, Node: sta.c, Next: sti.c, Prev: lex.c, Up: Overview of Translation Process sta.c -----  File: g77.info, Node: sti.c, Next: stq.c, Prev: sta.c, Up: Overview of Translation Process sti.c -----  File: g77.info, Node: stq.c, Next: stb.c, Prev: sti.c, Up: Overview of Translation Process stq.c -----  File: g77.info, Node: stb.c, Next: expr.c, Prev: stq.c, Up: Overview of Translation Process stb.c -----  File: g77.info, Node: expr.c, Next: stc.c, Prev: stb.c, Up: Overview of Translation Process expr.c ------  File: g77.info, Node: stc.c, Next: std.c, Prev: expr.c, Up: Overview of Translation Process stc.c -----  File: g77.info, Node: std.c, Next: ste.c, Prev: stc.c, Up: Overview of Translation Process std.c -----  File: g77.info, Node: ste.c, Next: Gotchas (Transforming), Prev: std.c, Up: Overview of Translation Process ste.c -----  File: g77.info, Node: Gotchas (Transforming), Next: TBD (Transforming), Prev: ste.c, Up: Overview of Translation Process Gotchas (Transforming) ---------------------- This section is not about transforming "gotchas" into something else. It is about the weirder aspects of transforming Fortran, however that's defined, into a more modern, canonical form. Multi-character Lexemes ....................... Each lexeme carries with it a pointer to where it appears in the source. To provide the ability for diagnostics to point to column numbers, in addition to line numbers and names, lexemes that represent more than one (significant) character in the source code need, generally, to provide pointers to where each _character_ appears in the source. This provides the ability to properly identify the precise location of the problem in code like SUBROUTINE X END BLOCK DATA X END which, in fixed-form source, would result in single lexemes consisting of the strings `SUBROUTINEX' and `BLOCKDATAX'. (The problem is that `X' is defined twice, so a pointer to the `X' in the second definition, as well as a follow-up pointer to the corresponding pointer in the first, would be preferable to pointing to the beginnings of the statements.) This need also arises when parsing (and diagnosing) `FORMAT' statements. Further, it arises when diagnosing `FMT=' specifiers that contain constants (or partial constants, or even propagated constants!) in I/O statements, as in: PRINT '(I2, 3HAB)', J (A pointer to the beginning of the prematurely-terminated Hollerith constant, and/or to the close parenthese, is preferable to a pointer to the open-parenthese or the apostrophe that precedes it.) Multi-character lexemes, which would seem to naturally include at least digit strings, alphanumeric strings, `CHARACTER' constants, and Hollerith constants, therefore need to provide location information on each character. (Maybe Hollerith constants don't, but it's unnecessary to except them.) The question then arises, what about _other_ multi-character lexemes, such as `**' and `//', and Fortran 90's `(/', `/)', `::', and so on? Turns out there's a need to identify the location of the second character of these two-character lexemes. For example, in `I(/J) = K', the slash needs to be diagnosed as the problem, not the open parenthese. Similarly, it is preferable to diagnose the second slash in `I = J // K' rather than the first, given the implicit typing rules, which would result in the compiler disallowing the attempted concatenation of two integers. (Though, since that's more of a semantic issue, it's not _that_ much preferable.) Even sequences that could be parsed as digit strings could use location info, for example, to diagnose the `9' in the octal constant `O'129''. (This probably will be parsed as a character string, to be consistent with the parsing of `Z'129A''.) To avoid the hassle of recording the location of the second character, while also preserving the general rule that each significant character is distinctly pointed to by the lexeme that contains it, it's best to simply not have any fixed-size lexemes larger than one character. This new design is expected to make checking for two `*' lexemes in a row much easier than the old design, so this is not much of a sacrifice. It probably makes the lexer much easier to implement than it makes the parser harder. Space-padding Lexemes ..................... Certain lexemes need to be padded with virtual spaces when the end of the line (or file) is encountered. This is necessary in fixed form, to handle lines that don't extend to column 72, assuming that's the line length in effect. Bizarre Free-form Hollerith Constants ..................................... Last I checked, the Fortran 90 standard actually required the compiler to silently accept something like FORMAT ( 1 2 Htwelve chars ) as a valid `FORMAT' statement specifying a twelve-character Hollerith constant. The implication here is that, since the new lexer is a zero-feedback one, it won't know that the special case of a `FORMAT' statement being parsed requires apparently distinct lexemes `1' and `2' to be treated as a single lexeme. (This is a horrible misfeature of the Fortran 90 language. It's one of many such misfeatures that almost make me want to not support them, and forge ahead with designing a new "GNU Fortran" language that has the features, but not the misfeatures, of Fortran 90, and provide utility programs to do the conversion automatically.) So, the lexer must gather distinct chunks of decimal strings into a single lexeme in contexts where a single decimal lexeme might start a Hollerith constant. (Which probably means it might as well do that all the time for all multi-character lexemes, even in free-form mode, leaving it to subsequent phases to pull them apart as they see fit.) Compare the treatment of this to how CHARACTER * 4 5 HEY and CHARACTER * 12 HEY must be treated--the former must be diagnosed, due to the separation between lexemes, the latter must be accepted as a proper declaration. Hollerith Constants ................... Recognizing a Hollerith constant--specifically, that an `H' or `h' after a digit string begins such a constant--requires some knowledge of context. Hollerith constants (such as `2HAB') can appear after: * `(' * `,' * `=' * `+', `-', `/' * `*', except as noted below Hollerith constants don't appear after: * `CHARACTER*', which can be treated generally as any `*' that is the second lexeme of a statement Confusing Function Keyword .......................... While REAL FUNCTION FOO () must be a `FUNCTION' statement and REAL FUNCTION FOO (5) must be a type-definition statement, REAL FUNCTION FOO (NAMES) where NAMES is a comma-separated list of names, can be one or the other. The only way to disambiguate that statement (short of mandating free-form source or a short maximum length for name for external procedures) is based on the context of the statement. In particular, the statement is known to be within an already-started program unit (but not at the outer level of the `CONTAINS' block), it is a type-declaration statement. Otherwise, the statement is a `FUNCTION' statement, in that it begins a function program unit (external, or, within `CONTAINS', nested). Weird READ .......... The statement READ (N) is equivalent to either READ (UNIT=(N)) or READ (FMT=(N)) depending on which would be valid in context. Specifically, if `N' is type `INTEGER', `READ (FMT=(N))' would not be valid, because parentheses may not be used around `N', whereas they may around it in `READ (UNIT=(N))'. Further, if `N' is type `CHARACTER', the opposite is true--`READ (UNIT=(N))' is not valid, but `READ (FMT=(N))' is. Strictly speaking, if anything follows READ (N) in the statement, whether the first lexeme after the close parenthese is a comma could be used to disambiguate the two cases, without looking at the type of `N', because the comma is required for the `READ (FMT=(N))' interpretation and disallowed for the `READ (UNIT=(N))' interpretation. However, in practice, many Fortran compilers allow the comma for the `READ (UNIT=(N))' interpretation anyway (in that they generally allow a leading comma before an I/O list in an I/O statement), and much code takes advantage of this allowance. (This is quite a reasonable allowance, since the juxtaposition of a comma-separated list immediately after an I/O control-specification list, which is also comma-separated, without an intervening comma, looks sufficiently "wrong" to programmers that they can't resist the itch to insert the comma. `READ (I, J), K, L' simply looks cleaner than `READ (I, J) K, L'.) So, type-based disambiguation is needed unless strict adherence to the standard is always assumed, and we're not going to assume that.  File: g77.info, Node: TBD (Transforming), Prev: Gotchas (Transforming), Up: Overview of Translation Process TBD (Transforming) ------------------ Continue researching gotchas, designing the transformational process, and implementing it. Specific issues to resolve: * Just where should (if it was implemented) `USE' processing take place? This gets into the whole issue of how `g77' should handle the concept of modules. I think GNAT already takes on this issue, but don't know more than that. Jim Giles has written extensively on `comp.lang.fortran' about his opinions on module handling, as have others. Jim's views should be taken into account. Actually, Richard M. Stallman (RMS) also has written up some guidelines for implementing such things, but I'm not sure where I read them. Perhaps the old list. If someone could dig references to these up and get them to me, that would be much appreciated! Even though modules are not on the short-term list for implementation, it'd be helpful to know _now_ how to avoid making them harder to implement them _later_. * Should the `g77' command become just a script that invokes all the various preprocessing that might be needed, thus making it seem slower than necessary for legacy code that people are unwilling to convert, or should we provide a separate script for that, thus encouraging people to convert their code once and for all? At least, a separate script to behave as old `g77' did, perhaps named `g77old', might ease the transition, as might a corresponding one that converts source codes named `g77oldnew'. These scripts would take all the pertinent options `g77' used to take and run the appropriate filters, passing the results to `g77' or just making new sources out of them (in a subdirectory, leaving the user to do the dirty deed of moving or copying them over the old sources). * Do other Fortran compilers provide a prefix syntax to govern the treatment of backslashes in `CHARACTER' (or Hollerith) constants? Knowing what other compilers provide would help. * Is it okay to drop support for the `-fintrin-case-initcap', `-fmatch-case-initcap', `-fsymbol-case-initcap', and `-fcase-initcap' options? I've asked for input on this. Not having to support these makes it easier to write the new front end, and might also avoid complicated its design. The consensus to date (1999-11-17) has been to drop this support. Can't recall anybody saying they're using it, in fact.  File: g77.info, Node: Philosophy of Code Generation, Next: Two-pass Design, Prev: Overview of Translation Process, Up: Front End Philosophy of Code Generation ============================= Don't poke the bear. The `g77' front end generates code via the `gcc' back end. The `gcc' back end (GBE) is a large, complex labyrinth of intricate code written in a combination of the C language and specialized languages internal to `gcc'. While the _code_ that implements the GBE is written in a combination of languages, the GBE itself is, to the front end for a language like Fortran, best viewed as a _compiler_ that compiles its own, unique, language. The GBE's "source", then, is written in this language, which consists primarily of a combination of calls to GBE functions and "tree" nodes (which are, themselves, created by calling GBE functions). So, the `g77' generates code by, in effect, translating the Fortran code it reads into a form "written" in the "language" of the `gcc' back end. This language will heretofore be referred to as "GBEL", for GNU Back End Language. GBEL is an evolving language, not fully specified in any published form as of this writing. It offers many facilities, but its "core" facilities are those that corresponding most directly to those needed to support `gcc' (compiling code written in GNU C). The `g77' Fortran Front End (FFE) is designed and implemented to navigate the currents and eddies of ongoing GBEL and `gcc' development while also delivering on the potential of an integrated FFE (as compared to using a converter like `f2c' and feeding the output into `gcc'). Goals of the FFE's code-generation strategy include: * High likelihood of generation of correct code, or, failing that, producing a fatal diagnostic or crashing. * Generation of highly optimized code, as directed by the user via GBE-specific (versus `g77'-specific) constructs, such as command-line options. * Fast overall (FFE plus GBE) compilation. * Preservation of source-level debugging information. The strategies historically, and currently, used by the FFE to achieve these goals include: * Use of GBEL constructs that most faithfully encapsulate the semantics of Fortran. * Avoidance of GBEL constructs that are so rarely used, or limited to use in specialized situations not related to Fortran, that their reliability and performance has not yet been established as sufficient for use by the FFE. * Flexible design, to readily accommodate changes to specific code-generation strategies, perhaps governed by command-line options. "Don't poke the bear" somewhat summarizes the above strategies. The GBE is the bear. The FFE is designed and implemented to avoid poking it in ways that are likely to just annoy it. The FFE usually either tackles it head-on, or avoids treating it in ways dissimilar to how the `gcc' front end treats it. For example, the FFE uses the native array facility in the back end instead of the lower-level pointer-arithmetic facility used by `gcc' when compiling `f2c' output). Theoretically, this presents more opportunities for optimization, faster compile times, and the production of more faithful debugging information. These benefits were not, however, immediately realized, mainly because `gcc' itself makes little or no use of the native array facility. Complex arithmetic is a case study of the evolution of this strategy. When originally implemented, the GBEL had just evolved its own native complex-arithmetic facility, so the FFE took advantage of that. When porting `g77' to 64-bit systems, it was discovered that the GBE didn't really implement its native complex-arithmetic facility properly. The short-term solution was to rewrite the FFE to instead use the lower-level facilities that'd be used by `gcc'-compiled code (assuming that code, itself, didn't use the native complex type provided, as an extension, by `gcc'), since these were known to work, and, in any case, if shown to not work, would likely be rapidly fixed (since they'd likely not work for vanilla C code in similar circumstances). However, the rewrite accommodated the original, native approach as well by offering a command-line option to select it over the emulated approach. This allowed users, and especially GBE maintainers, to try out fixes to complex-arithmetic support in the GBE while `g77' continued to default to compiling more code correctly, albeit producing (typically) slower executables. As of April 1999, it appeared that the last few bugs in the GBE's support of its native complex-arithmetic facility were worked out. The FFE was changed back to default to using that native facility, leaving emulation as an option. Later during the release cycle (which was called EGCS 1.2, but soon became GCC 2.95), bugs in the native facility were found. Reactions among various people included "the last thing we should do is change the default back", "we must change the default back", and "let's figure out whether we can narrow down the bugs to few enough cases to allow the now-months-long-tested default to remain the same". The latter viewpoint won that particular time. The bugs exposed other concerns regarding ABI compliance when the ABI specified treatment of complex data as different from treatment of what Fortran and GNU C consider the equivalent aggregation (structure) of real (or float) pairs. Other Fortran constructs--arrays, character strings, complex division, `COMMON' and `EQUIVALENCE' aggregates, and so on--involve issues similar to those pertaining to complex arithmetic. So, it is possible that the history of how the FFE handled complex arithmetic will be repeated, probably in modified form (and hopefully over shorter timeframes), for some of these other facilities.  File: g77.info, Node: Two-pass Design, Next: Challenges Posed, Prev: Philosophy of Code Generation, Up: Front End Two-pass Design =============== The FFE does not tell the GBE anything about a program unit until after the last statement in that unit has been parsed. (A program unit is a Fortran concept that corresponds, in the C world, mostly closely to functions definitions in ISO C. That is, a program unit in Fortran is like a top-level function in C. Nested functions, found among the extensions offered by GNU C, correspond roughly to Fortran's statement functions.) So, while parsing the code in a program unit, the FFE saves up all the information on statements, expressions, names, and so on, until it has seen the last statement. At that point, the FFE revisits the saved information (in what amounts to a second "pass" over the program unit) to perform the actual translation of the program unit into GBEL, ultimating in the generation of assembly code for it. Some lookahead is performed during this second pass, so the FFE could be viewed as a "two-plus-pass" design. * Menu: * Two-pass Code:: * Why Two Passes::  File: g77.info, Node: Two-pass Code, Next: Why Two Passes, Up: Two-pass Design Two-pass Code ------------- Most of the code that turns the first pass (parsing) into a second pass for code generation is in `gcc/gcc/f/std.c'. It has external functions, called mainly by siblings in `gcc/gcc/f/stc.c', that record the information on statements and expressions in the order they are seen in the source code. These functions save that information. It also has an external function that revisits that information, calling the siblings in `gcc/gcc/f/ste.c', which handles the actual code generation (by generating GBEL code, that is, by calling GBE routines to represent and specify expressions, statements, and so on).  File: g77.info, Node: Why Two Passes, Prev: Two-pass Code, Up: Two-pass Design Why Two Passes -------------- The need for two passes was not immediately evident during the design and implementation of the code in the FFE that was to produce GBEL. Only after a few kludges, to handle things like incorrectly-guessed `ASSIGN' label nature, had been implemented, did enough evidence pile up to make it clear that `std.c' had to be introduced to intercept, save, then revisit as part of a second pass, the digested contents of a program unit. Other such missteps have occurred during the evolution of the FFE, because of the different goals of the FFE and the GBE. Because the GBE's original, and still primary, goal was to directly support the GNU C language, the GBEL, and the GBE itself, requires more complexity on the part of most front ends than it requires of `gcc''s. For example, the GBEL offers an interface that permits the `gcc' front end to implement most, or all, of the language features it supports, without the front end having to make use of non-user-defined variables. (It's almost certainly the case that all of K&R C, and probably ANSI C as well, is handled by the `gcc' front end without declaring such variables.) The FFE, on the other hand, must resort to a variety of "tricks" to achieve its goals. Consider the following C code: int foo (int a, int b) { int c = 0; if ((c = bar (c)) == 0) goto done; quux (c << 1); done: return c; } Note what kinds of objects are declared, or defined, before their use, and before any actual code generation involving them would normally take place: * Return type of function * Entry point(s) of function * Dummy arguments * Variables * Initial values for variables Whereas, the following items can, and do, suddenly appear "out of the blue" in C: * Label references * Function references Not surprisingly, the GBE faithfully permits the latter set of items to be "discovered" partway through GBEL "programs", just as they are permitted to in C. Yet, the GBE has tended, at least in the past, to be reticent to fully support similar "late" discovery of items in the former set. This makes Fortran a poor fit for the "safe" subset of GBEL. Consider: FUNCTION X (A, ARRAY, ID1) CHARACTER*(*) A DOUBLE PRECISION X, Y, Z, TMP, EE, PI REAL ARRAY(ID1*ID2) COMMON ID2 EXTERNAL FRED ASSIGN 100 TO J CALL FOO (I) IF (I .EQ. 0) PRINT *, A(0) GOTO 200 ENTRY Y (Z) ASSIGN 101 TO J 200 PRINT *, A(1) READ *, TMP GOTO J 100 X = TMP * EE RETURN 101 Y = TMP * PI CALL FRED DATA EE, PI /2.71D0, 3.14D0/ END Here are some observations about the above code, which, while somewhat contrived, conforms to the FORTRAN 77 and Fortran 90 standards: * The return type of function `X' is not known until the `DOUBLE PRECISION' line has been parsed. * Whether `A' is a function or a variable is not known until the `PRINT *, A(0)' statement has been parsed. * The bounds of the array of argument `ARRAY' depend on a computation involving the subsequent argument `ID1' and the blank-common member `ID2'. * Whether `Y' and `Z' are local variables, additional function entry points, or dummy arguments to additional entry points is not known until the `ENTRY' statement is parsed. * Similarly, whether `TMP' is a local variable is not known until the `READ *, TMP' statement is parsed. * The initial values for `EE' and `PI' are not known until after the `DATA' statement is parsed. * Whether `FRED' is a function returning type `REAL' or a subroutine (which can be thought of as returning type `void' _or_, to support alternate returns in a simple way, type `int') is not known until the `CALL FRED' statement is parsed. * Whether `100' is a `FORMAT' label or the label of an executable statement is not known until the `X =' statement is parsed. (These two types of labels get _very_ different treatment, especially when `ASSIGN''ed.) * That `J' is a local variable is not known until the first `ASSIGN' statement is parsed. (This happens _after_ executable code has been seen.) Very few of these "discoveries" can be accommodated by the GBE as it has evolved over the years. The GBEL doesn't support several of them, and those it might appear to support don't always work properly, especially in combination with other GBEL and GBE features, as implemented in the GBE. (Had the GBE and its GBEL originally evolved to support `g77', the shoe would be on the other foot, so to speak--most, if not all, of the above would be directly supported by the GBEL, and a few C constructs would probably not, as they are in reality, be supported. Both this mythical, and today's real, GBE caters to its GBEL by, sometimes, scrambling around, cleaning up after itself--after discovering that assumptions it made earlier during code generation are incorrect. That's not a great design, since it indicates significant code paths that might be rarely tested but used in some key production environments.) So, the FFE handles these discrepancies--between the order in which it discovers facts about the code it is compiling, and the order in which the GBEL and GBE support such discoveries--by performing what amounts to two passes over each program unit. (A few ambiguities can remain at that point, such as whether, given `EXTERNAL BAZ' and no other reference to `BAZ' in the program unit, it is a subroutine, a function, or a block-data--which, in C-speak, governs its declared return type. Fortunately, these distinctions are easily finessed for the procedure, library, and object-file interfaces supported by `g77'.)  File: g77.info, Node: Challenges Posed, Next: Transforming Statements, Prev: Two-pass Design, Up: Front End Challenges Posed ================ Consider the following Fortran code, which uses various extensions (including some to Fortran 90): SUBROUTINE X(A) CHARACTER*(*) A COMPLEX CFUNC INTEGER*2 CLOCKS(200) INTEGER IFUNC CALL SYSTEM_CLOCK (CLOCKS (IFUNC (CFUNC ('('//A//')')))) The above poses the following challenges to any Fortran compiler that uses run-time interfaces, and a run-time library, roughly similar to those used by `g77': * Assuming the library routine that supports `SYSTEM_CLOCK' expects to set an `INTEGER*4' variable via its `COUNT' argument, the compiler must make available to it a temporary variable of that type. * Further, after the `SYSTEM_CLOCK' library routine returns, the compiler must ensure that the temporary variable it wrote is copied into the appropriate element of the `CLOCKS' array. (This assumes the compiler doesn't just reject the code, which it should if it is compiling under some kind of a "strict" option.) * To determine the correct index into the `CLOCKS' array, (putting aside the fact that the index, in this particular case, need not be computed until after the `SYSTEM_CLOCK' library routine returns), the compiler must ensure that the `IFUNC' function is called. That requires evaluating its argument, which requires, for `g77' (assuming `-ff2c' is in force), reserving a temporary variable of type `COMPLEX' for use as a repository for the return value being computed by `CFUNC'. * Before invoking `CFUNC', is argument must be evaluated, which requires allocating, at run time, a temporary large enough to hold the result of the concatenation, as well as actually performing the concatenation. * The large temporary needed during invocation of `CFUNC' should, ideally, be deallocated (or, at least, left to the GBE to dispose of, as it sees fit) as soon as `CFUNC' returns, which means before `IFUNC' is called (as it might need a lot of dynamically allocated memory). `g77' currently doesn't support all of the above, but, so that it might someday, it has evolved to handle at least some of the above requirements. Meeting the above requirements is made more challenging by conforming to the requirements of the GBEL/GBE combination.  File: g77.info, Node: Transforming Statements, Next: Transforming Expressions, Prev: Challenges Posed, Up: Front End Transforming Statements ======================= Most Fortran statements are given their own block, and, for temporary variables they might need, their own scope. (A block is what distinguishes `{ foo (); }' from just `foo ();' in C. A scope is included with every such block, providing a distinct name space for local variables.) Label definitions for the statement precede this block, so `10 PRINT *, I' is handled more like `fl10: { ... }' than `{ fl10: ... }' (where `fl10' is just a notation meaning "Fortran Label 10" for the purposes of this document). * Menu: * Statements Needing Temporaries:: * Transforming DO WHILE:: * Transforming Iterative DO:: * Transforming Block IF:: * Transforming SELECT CASE::  File: g77.info, Node: Statements Needing Temporaries, Next: Transforming DO WHILE, Up: Transforming Statements Statements Needing Temporaries ------------------------------ Any temporaries needed during, but not beyond, execution of a Fortran statement, are made local to the scope of that statement's block. This allows the GBE to share storage for these temporaries among the various statements without the FFE having to manage that itself. (The GBE could, of course, decide to optimize management of these temporaries. For example, it could, theoretically, schedule some of the computations involving these temporaries to occur in parallel. More practically, it might leave the storage for some temporaries "live" beyond their scopes, to reduce the number of manipulations of the stack pointer at run time.) Temporaries needed across distinct statement boundaries usually are associated with Fortran blocks (such as `DO'/`END DO'). (Also, there might be temporaries not associated with blocks at all--these would be in the scope of the entire program unit.) Each Fortran block _should_ get its own block/scope in the GBE. This is best, because it allows temporaries to be more naturally handled. However, it might pose problems when handling labels (in particular, when they're the targets of `GOTO's outside the Fortran block), and generally just hassling with replicating parts of the `gcc' front end (because the FFE needs to support an arbitrary number of nested back-end blocks if each Fortran block gets one). So, there might still be a need for top-level temporaries, whose "owning" scope is that of the containing procedure. Also, there seems to be problems declaring new variables after generating code (within a block) in the back end, leading to, e.g., `label not defined before binding contour' or similar messages, when compiling with `-fstack-check' or when compiling for certain targets. Because of that, and because sometimes these temporaries are not discovered until in the middle of of generating code for an expression statement (as in the case of the optimization for `X**I'), it seems best to always pre-scan all the expressions that'll be expanded for a block before generating any of the code for that block. This pre-scan then handles discovering and declaring, to the back end, the temporaries needed for that block. It's also important to treat distinct items in an I/O list as distinct statements deserving their own blocks. That's because there's a requirement that each I/O item be fully processed before the next one, which matters in cases like `READ (*,*), I, A(I)'--the element of `A' read in the second item _must_ be determined from the value of `I' read in the first item.  File: g77.info, Node: Transforming DO WHILE, Next: Transforming Iterative DO, Prev: Statements Needing Temporaries, Up: Transforming Statements Transforming DO WHILE --------------------- `DO WHILE(expr)' _must_ be implemented so that temporaries needed to evaluate `expr' are generated just for the test, each time. Consider how `DO WHILE (A//B .NE. 'END'); ...; END DO' is transformed: for (;;) { int temp0; { char temp1[large]; libg77_catenate (temp1, a, b); temp0 = libg77_ne (temp1, 'END'); } if (! temp0) break; ... } In this case, it seems like a time/space tradeoff between allocating and deallocating `temp1' for each iteration and allocating it just once for the entire loop. However, if `temp1' is allocated just once for the entire loop, it could be the wrong size for subsequent iterations of that loop in cases like `DO WHILE (A(I:J)//B .NE. 'END')', because the body of the loop might modify `I' or `J'. So, the above implementation is used, though a more optimal one can be used in specific circumstances.  File: g77.info, Node: Transforming Iterative DO, Next: Transforming Block IF, Prev: Transforming DO WHILE, Up: Transforming Statements Transforming Iterative DO ------------------------- An iterative `DO' loop (one that specifies an iteration variable) is required by the Fortran standards to be implemented as though an iteration count is computed before entering the loop body, and that iteration count used to determine the number of times the loop body is to be performed (assuming the loop isn't cut short via `GOTO' or `EXIT'). The FFE handles this by allocating a temporary variable to contain the computed number of iterations. Since this variable must be in a scope that includes the entire loop, a GBEL block is created for that loop, and the variable declared as belonging to the scope of that block.  File: g77.info, Node: Transforming Block IF, Next: Transforming SELECT CASE, Prev: Transforming Iterative DO, Up: Transforming Statements Transforming Block IF --------------------- Consider: SUBROUTINE X(A,B,C) CHARACTER*(*) A, B, C LOGICAL LFUNC IF (LFUNC (A//B)) THEN CALL SUBR1 ELSE IF (LFUNC (A//C)) THEN CALL SUBR2 ELSE CALL SUBR3 END The arguments to the two calls to `LFUNC' require dynamic allocation (at run time), but are not required during execution of the `CALL' statements. So, the scopes of those temporaries must be within blocks inside the block corresponding to the Fortran `IF' block. This cannot be represented "naturally" in vanilla C, nor in GBEL. The `if', `elseif', `else', and `endif' constructs provided by both languages must, for a given `if' block, share the same C/GBE block. Therefore, any temporaries needed during evaluation of `expr' while executing `ELSE IF(expr)' must either have been predeclared at the top of the corresponding `IF' block, or declared within a new block for that `ELSE IF'--a block that, since it cannot contain the `else' or `else if' itself (due to the above requirement), actually implements the rest of the `IF' block's `ELSE IF' and `ELSE' statements within an inner block. The FFE takes the latter approach.  File: g77.info, Node: Transforming SELECT CASE, Prev: Transforming Block IF, Up: Transforming Statements Transforming SELECT CASE ------------------------ `SELECT CASE' poses a few interesting problems for code generation, if efficiency and frugal stack management are important. Consider `SELECT CASE (I('PREFIX'//A))', where `A' is `CHARACTER*(*)'. In a case like this--basically, in any case where largish temporaries are needed to evaluate the expression--those temporaries should not be "live" during execution of any of the `CASE' blocks. So, evaluation of the expression is best done within its own block, which in turn is within the `SELECT CASE' block itself (which contains the code for the CASE blocks as well, though each within their own block). Otherwise, we'd have the rough equivalent of this pseudo-code: { char temp[large]; libg77_catenate (temp, 'prefix', a); switch (i (temp)) { case 0: ... } } And that would leave temp[large] in scope during the CASE blocks (although a clever back end *could* see that it isn't referenced in them, and thus free that temp before executing the blocks). So this approach is used instead: { int temp0; { char temp1[large]; libg77_catenate (temp1, 'prefix', a); temp0 = i (temp1); } switch (temp0) { case 0: ... } } Note how `temp1' goes out of scope before starting the switch, thus making it easy for a back end to free it. The problem _that_ solution has, however, is with `SELECT CASE('prefix'//A)' (which is currently not supported). Unless the GBEL is extended to support arbitrarily long character strings in its `case' facility, the FFE has to implement `SELECT CASE' on `CHARACTER' (probably excepting `CHARACTER*1') using a cascade of `if', `elseif', `else', and `endif' constructs in GBEL. To prevent the (potentially large) temporary, needed to hold the selected expression itself (`'prefix'//A'), from being in scope during execution of the `CASE' blocks, two approaches are available: * Pre-evaluate all the `CASE' tests, producing an integer ordinal that is used, a la `temp0' in the earlier example, as if `SELECT CASE(temp0)' had been written. Each corresponding `CASE' is replaced with `CASE(I)', where I is the ordinal for that case, determined while, or before, generating the cascade of `if'-related constructs to cope with `CHARACTER' selection. * Make `temp0' above just large enough to hold the longest `CASE' string that'll actually be compared against the expression (in this case, `'prefix'//A'). Since that length must be constant (because `CASE' expressions are all constant), it won't be so large, and, further, `temp1' need not be dynamically allocated, since normal `CHARACTER' assignment can be used into the fixed-length `temp0'. Both of these solutions require `SELECT CASE' implementation to be changed so all the corresponding `CASE' statements are seen during the actual code generation for `SELECT CASE'.  File: g77.info, Node: Transforming Expressions, Next: Internal Naming Conventions, Prev: Transforming Statements, Up: Front End Transforming Expressions ======================== The interactions between statements, expressions, and subexpressions at program run time can be viewed as: ACTION(EXPR) Here, ACTION is the series of steps performed to effect the statement, and EXPR is the expression whose value is used by ACTION. Expanding the above shows a typical order of events at run time: Evaluate EXPR Perform ACTION, using result of evaluation of EXPR Clean up after evaluating EXPR So, if evaluating EXPR requires allocating memory, that memory can be freed before performing ACTION only if it is not needed to hold the result of evaluating EXPR. Otherwise, it must be freed no sooner than after ACTION has been performed. The above are recursive definitions, in the sense that they apply to subexpressions of EXPR. That is, evaluating EXPR involves evaluating all of its subexpressions, performing the ACTION that computes the result value of EXPR, then cleaning up after evaluating those subexpressions. The recursive nature of this evaluation is implemented via recursive-descent transformation of the top-level statements, their expressions, _their_ subexpressions, and so on. However, that recursive-descent transformation is, due to the nature of the GBEL, focused primarily on generating a _single_ stream of code to be executed at run time. Yet, from the above, it's clear that multiple streams of code must effectively be simultaneously generated during the recursive-descent analysis of statements. The primary stream implements the primary ACTION items, while at least two other streams implement the evaluation and clean-up items. Requirements imposed by expressions include: * Whether the caller needs to have a temporary ready to hold the value of the expression. * Other stuff???  File: g77.info, Node: Internal Naming Conventions, Prev: Transforming Expressions, Up: Front End Internal Naming Conventions =========================== Names exported by FFE modules have the following (regular-expression) forms. Note that all names beginning `ffeMOD' or `FFEMOD', where MOD is lowercase or uppercase alphanumerics, respectively, are exported by the module `ffeMOD', with the source code doing the exporting in `MOD.h'. (Usually, the source code for the implementation is in `MOD.c'.) Identifiers that don't fit the following forms are not considered exported, even if they are according to the C language. (For example, they might be made available to other modules solely for use within expansions of exported macros, not for use within any source code in those other modules.) `ffeMOD' The single typedef exported by the module. `FFEUMOD_[A-Z][A-Z0-9_]*' (Where UMOD is the uppercase for of MOD.) A `#define' or `enum' constant of the type `ffeMOD'. `ffeMOD[A-Z][A-Z][a-z0-9]*' A typedef exported by the module. The portion of the identifier after `ffeMOD' is referred to as `ctype', a capitalized (mixed-case) form of `type'. `FFEUMOD_TYPE[A-Z][A-Z0-9_]*[A-Z0-9]?' (Where UMOD is the uppercase for of MOD.) A `#define' or `enum' constant of the type `ffeMODTYPE', where TYPE is the lowercase form of CTYPE in an exported typedef. `ffeMOD_VALUE' A function that does or returns something, as described by VALUE (see below). `ffeMOD_VALUE_INPUT' A function that does or returns something based primarily on the thing described by INPUT (see below). Below are names used for VALUE and INPUT, along with their definitions. `col' A column number within a line (first column is number 1). `file' An encapsulation of a file's name. `find' Looks up an instance of some type that matches specified criteria, and returns that, even if it has to create a new instance or crash trying to find it (as appropriate). `initialize' Initializes, usually a module. No type. `int' A generic integer of type `int'. `is' A generic integer that contains a true (nonzero) or false (zero) value. `len' A generic integer that contains the length of something. `line' A line number within a source file, or a global line number. `lookup' Looks up an instance of some type that matches specified criteria, and returns that, or returns nil. `name' A `text' that points to a name of something. `new' Makes a new instance of the indicated type. Might return an existing one if appropriate--if so, similar to `find' without crashing. `pt' Pointer to a particular character (line, column pairs) in the input file (source code being compiled). `run' Performs some herculean task. No type. `terminate' Terminates, usually a module. No type. `text' A `char *' that points to generic text.  File: g77.info, Node: Diagnostics, Next: Keyword Index, Prev: Front End, Up: Top Diagnostics *********** Some diagnostics produced by `g77' require sufficient explanation that the explanations are given below, and the diagnostics themselves identify the appropriate explanation. Identification uses the GNU Info format--specifically, the `info' command that displays the explanation is given within square brackets in the diagnostic. For example: foo.f:5: Invalid statement [info -f g77 M FOOEY] More details about the above diagnostic is found in the `g77' Info documentation, menu item `M', submenu item `FOOEY', which is displayed by typing the UNIX command `info -f g77 M FOOEY'. Other Info readers, such as EMACS, may be just as easily used to display the pertinent node. In the above example, `g77' is the Info document name, `M' is the top-level menu item to select, and, in that node (named `Diagnostics', the name of this chapter, which is the very text you're reading now), `FOOEY' is the menu item to select. * Menu: * CMPAMBIG:: Ambiguous use of intrinsic. * EXPIMP:: Intrinsic used explicitly and implicitly. * INTGLOB:: Intrinsic also used as name of global. * LEX:: Various lexer messages * GLOBALS:: Disagreements about globals. * LINKFAIL:: When linking `f771' fails. * Y2KBAD:: Use of non-Y2K-compliant intrinsic.  File: g77.info, Node: CMPAMBIG, Next: EXPIMP, Up: Diagnostics `CMPAMBIG' ========== Ambiguous use of intrinsic INTRINSIC ... The type of the argument to the invocation of the INTRINSIC intrinsic is a `COMPLEX' type other than `COMPLEX(KIND=1)'. Typically, it is `COMPLEX(KIND=2)', also known as `DOUBLE COMPLEX'. The interpretation of this invocation depends on the particular dialect of Fortran for which the code was written. Some dialects convert the real part of the argument to `REAL(KIND=1)', thus losing precision; other dialects, and Fortran 90, do no such conversion. So, GNU Fortran rejects such invocations except under certain circumstances, to avoid making an incorrect assumption that results in generating the wrong code. To determine the dialect of the program unit, perhaps even whether that particular invocation is properly coded, determine how the result of the intrinsic is used. The result of INTRINSIC is expected (by the original programmer) to be `REAL(KIND=1)' (the non-Fortran-90 interpretation) if: * It is passed as an argument to a procedure that explicitly or implicitly declares that argument `REAL(KIND=1)'. For example, a procedure with no `DOUBLE PRECISION' or `IMPLICIT DOUBLE PRECISION' statement specifying the dummy argument corresponding to an actual argument of `REAL(Z)', where `Z' is declared `DOUBLE COMPLEX', strongly suggests that the programmer expected `REAL(Z)' to return `REAL(KIND=1)' instead of `REAL(KIND=2)'. * It is used in a context that would otherwise not include any `REAL(KIND=2)' but where treating the INTRINSIC invocation as `REAL(KIND=2)' would result in unnecessary promotions and (typically) more expensive operations on the wider type. For example: DOUBLE COMPLEX Z ... R(1) = T * REAL(Z) The above example suggests the programmer expected the real part of `Z' to be converted to `REAL(KIND=1)' before being multiplied by `T' (presumed, along with `R' above, to be type `REAL(KIND=1)'). Otherwise, the conversion would have to be delayed until after the multiplication, requiring not only an extra conversion (of `T' to `REAL(KIND=2)'), but a (typically) more expensive multiplication (a double-precision multiplication instead of a single-precision one). The result of INTRINSIC is expected (by the original programmer) to be `REAL(KIND=2)' (the Fortran 90 interpretation) if: * It is passed as an argument to a procedure that explicitly or implicitly declares that argument `REAL(KIND=2)'. For example, a procedure specifying a `DOUBLE PRECISION' dummy argument corresponding to an actual argument of `REAL(Z)', where `Z' is declared `DOUBLE COMPLEX', strongly suggests that the programmer expected `REAL(Z)' to return `REAL(KIND=2)' instead of `REAL(KIND=1)'. * It is used in an expression context that includes other `REAL(KIND=2)' operands, or is assigned to a `REAL(KIND=2)' variable or array element. For example: DOUBLE COMPLEX Z DOUBLE PRECISION R, T ... R(1) = T * REAL(Z) The above example suggests the programmer expected the real part of `Z' to _not_ be converted to `REAL(KIND=1)' by the `REAL()' intrinsic. Otherwise, the conversion would have to be immediately followed by a conversion back to `REAL(KIND=2)', losing the original, full precision of the real part of `Z', before being multiplied by `T'. Once you have determined whether a particular invocation of INTRINSIC expects the Fortran 90 interpretation, you can: * Change it to `DBLE(EXPR)' (if INTRINSIC is `REAL') or `DIMAG(EXPR)' (if INTRINSIC is `AIMAG') if it expected the Fortran 90 interpretation. This assumes EXPR is `COMPLEX(KIND=2)'--if it is some other type, such as `COMPLEX*32', you should use the appropriate intrinsic, such as the one to convert to `REAL*16' (perhaps `DBLEQ()' in place of `DBLE()', and `QIMAG()' in place of `DIMAG()'). * Change it to `REAL(INTRINSIC(EXPR))', otherwise. This converts to `REAL(KIND=1)' in all working Fortran compilers. If you don't want to change the code, and you are certain that all ambiguous invocations of INTRINSIC in the source file have the same expectation regarding interpretation, you can: * Compile with the `g77' option `-ff90', to enable the Fortran 90 interpretation. * Compile with the `g77' options `-fno-f90 -fugly-complex', to enable the non-Fortran-90 interpretations. *Note REAL() and AIMAG() of Complex::, for more information on this issue. Note: If the above suggestions don't produce enough evidence as to whether a particular program expects the Fortran 90 interpretation of this ambiguous invocation of INTRINSIC, there is one more thing you can try. If you have access to most or all the compilers used on the program to create successfully tested and deployed executables, read the documentation for, and _also_ test out, each compiler to determine how it treats the INTRINSIC intrinsic in this case. (If all the compilers don't agree on an interpretation, there might be lurking bugs in the deployed versions of the program.) The following sample program might help: PROGRAM JCB003 C C Written by James Craig Burley 1997-02-23. C C Determine how compilers handle non-standard REAL C and AIMAG on DOUBLE COMPLEX operands. C DOUBLE COMPLEX Z REAL R Z = (3.3D0, 4.4D0) R = Z CALL DUMDUM(Z, R) R = REAL(Z) - R IF (R .NE. 0.) PRINT *, 'REAL() is Fortran 90' IF (R .EQ. 0.) PRINT *, 'REAL() is not Fortran 90' R = 4.4D0 CALL DUMDUM(Z, R) R = AIMAG(Z) - R IF (R .NE. 0.) PRINT *, 'AIMAG() is Fortran 90' IF (R .EQ. 0.) PRINT *, 'AIMAG() is not Fortran 90' END C C Just to make sure compiler doesn't use naive flow C analysis to optimize away careful work above, C which might invalidate results.... C SUBROUTINE DUMDUM(Z, R) DOUBLE COMPLEX Z REAL R END If the above program prints contradictory results on a particular compiler, run away!  File: g77.info, Node: EXPIMP, Next: INTGLOB, Prev: CMPAMBIG, Up: Diagnostics `EXPIMP' ======== Intrinsic INTRINSIC referenced ... The INTRINSIC is explicitly declared in one program unit in the source file and implicitly used as an intrinsic in another program unit in the same source file. This diagnostic is designed to catch cases where a program might depend on using the name INTRINSIC as an intrinsic in one program unit and as a global name (such as the name of a subroutine or function) in another, but `g77' recognizes the name as an intrinsic in both cases. After verifying that the program unit making implicit use of the intrinsic is indeed written expecting the intrinsic, add an `INTRINSIC INTRINSIC' statement to that program unit to prevent this warning. This and related warnings are disabled by using the `-Wno-globals' option when compiling. Note that this warning is not issued for standard intrinsics. Standard intrinsics include those described in the FORTRAN 77 standard and, if `-ff90' is specified, those described in the Fortran 90 standard. Such intrinsics are not as likely to be confused with user procedures as intrinsics provided as extensions to the standard by `g77'.  File: g77.info, Node: INTGLOB, Next: LEX, Prev: EXPIMP, Up: Diagnostics `INTGLOB' ========= Same name `INTRINSIC' given ... The name INTRINSIC is used for a global entity (a common block or a program unit) in one program unit and implicitly used as an intrinsic in another program unit. This diagnostic is designed to catch cases where a program intends to use a name entirely as a global name, but `g77' recognizes the name as an intrinsic in the program unit that references the name, a situation that would likely produce incorrect code. For example: INTEGER FUNCTION TIME() ... END ... PROGRAM SAMP INTEGER TIME PRINT *, 'Time is ', TIME() END The above example defines a program unit named `TIME', but the reference to `TIME' in the main program unit `SAMP' is normally treated by `g77' as a reference to the intrinsic `TIME()' (unless a command-line option that prevents such treatment has been specified). As a result, the program `SAMP' will _not_ invoke the `TIME' function in the same source file. Since `g77' recognizes `libU77' procedures as intrinsics, and since some existing code uses the same names for its own procedures as used by some `libU77' procedures, this situation is expected to arise often enough to make this sort of warning worth issuing. After verifying that the program unit making implicit use of the intrinsic is indeed written expecting the intrinsic, add an `INTRINSIC INTRINSIC' statement to that program unit to prevent this warning. Or, if you believe the program unit is designed to invoke the program-defined procedure instead of the intrinsic (as recognized by `g77'), add an `EXTERNAL INTRINSIC' statement to the program unit that references the name to prevent this warning. This and related warnings are disabled by using the `-Wno-globals' option when compiling. Note that this warning is not issued for standard intrinsics. Standard intrinsics include those described in the FORTRAN 77 standard and, if `-ff90' is specified, those described in the Fortran 90 standard. Such intrinsics are not as likely to be confused with user procedures as intrinsics provided as extensions to the standard by `g77'.  File: g77.info, Node: LEX, Next: GLOBALS, Prev: INTGLOB, Up: Diagnostics `LEX' ===== Unrecognized character ... Invalid first character ... Line too long ... Non-numeric character ... Continuation indicator ... Label at ... invalid with continuation line indicator ... Character constant ... Continuation line ... Statement at ... begins with invalid token Although the diagnostics identify specific problems, they can be produced when general problems such as the following occur: * The source file contains something other than Fortran code. If the code in the file does not look like many of the examples elsewhere in this document, it might not be Fortran code. (Note that Fortran code often is written in lower case letters, while the examples in this document use upper case letters, for stylistic reasons.) For example, if the file contains lots of strange-looking characters, it might be APL source code; if it contains lots of parentheses, it might be Lisp source code; if it contains lots of bugs, it might be C++ source code. * The source file contains free-form Fortran code, but `-ffree-form' was not specified on the command line to compile it. Free form is a newer form for Fortran code. The older, classic form is called fixed form. Fixed-form code is visually fairly distinctive, because numerical labels and comments are all that appear in the first five columns of a line, the sixth column is reserved to denote continuation lines, and actual statements start at or beyond column 7. Spaces generally are not significant, so if you see statements such as `REALX,Y' and `DO10I=1,100', you are looking at fixed-form code. Comment lines are indicated by the letter `C' or the symbol `*' in column 1. (Some code uses `!' or `/*' to begin in-line comments, which many compilers support.) Free-form code is distinguished from fixed-form source primarily by the fact that statements may start anywhere. (If lots of statements start in columns 1 through 6, that's a strong indicator of free-form source.) Consecutive keywords must be separated by spaces, so `REALX,Y' is not valid, while `REAL X,Y' is. There are no comment lines per se, but `!' starts a comment anywhere in a line (other than within a character or Hollerith constant). *Note Source Form::, for more information. * The source file is in fixed form and has been edited without sensitivity to the column requirements. Statements in fixed-form code must be entirely contained within columns 7 through 72 on a given line. Starting them "early" is more likely to result in diagnostics than finishing them "late", though both kinds of errors are often caught at compile time. For example, if the following code fragment is edited by following the commented instructions literally, the result, shown afterward, would produce a diagnostic when compiled: C On XYZZY systems, remove "C" on next line: C CALL XYZZY_RESET The result of editing the above line might be: C On XYZZY systems, remove "C" on next line: CALL XYZZY_RESET However, that leaves the first `C' in the `CALL' statement in column 6, making it a comment line, which is not really what the author intended, and which is likely to result in one of the above-listed diagnostics. _Replacing_ the `C' in column 1 with a space is the proper change to make, to ensure the `CALL' keyword starts in or after column 7. Another common mistake like this is to forget that fixed-form source lines are significant through only column 72, and that, normally, any text beyond column 72 is ignored or is diagnosed at compile time. *Note Source Form::, for more information. * The source file requires preprocessing, and the preprocessing is not being specified at compile time. A source file containing lines beginning with `#define', `#include', `#if', and so on is likely one that requires preprocessing. If the file's suffix is `.f', `.for', or `.FOR', the file normally will be compiled _without_ preprocessing by `g77'. Change the file's suffix from `.f' to `.F' (or, on systems with case-insensitive file names, to `.fpp' or `.FPP'), from `.for' to `.fpp', or from `.FOR' to `.FPP'. `g77' compiles files with such names _with_ preprocessing. Or, learn how to use `gcc''s `-x' option to specify the language `f77-cpp-input' for Fortran files that require preprocessing. *Note Options Controlling the Kind of Output: (gcc)Overall Options. * The source file is preprocessed, and the results of preprocessing result in syntactic errors that are not necessarily obvious to someone examining the source file itself. Examples of errors resulting from preprocessor macro expansion include exceeding the line-length limit, improperly starting, terminating, or incorporating the apostrophe or double-quote in a character constant, improperly forming a Hollerith constant, and so on. *Note Options Controlling the Kind of Output: Overall Options, for suggestions about how to use, and not use, preprocessing for Fortran code.  File: g77.info, Node: GLOBALS, Next: LINKFAIL, Prev: LEX, Up: Diagnostics `GLOBALS' ========= Global name NAME defined at ... already defined... Global name NAME at ... has different type... Too many arguments passed to NAME at ... Too few arguments passed to NAME at ... Argument #N of NAME is ... These messages all identify disagreements about the global procedure named NAME among different program units (usually including NAME itself). Whether a particular disagreement is reported as a warning or an error can depend on the relative order of the disagreeing portions of the source file. Disagreements between a procedure invocation and the _subsequent_ procedure itself are, usually, diagnosed as errors when the procedure itself _precedes_ the invocation. Other disagreements are diagnosed via warnings. This distinction, between warnings and errors, is due primarily to the present tendency of the `gcc' back end to inline only those procedure invocations that are _preceded_ by the corresponding procedure definitions. If the `gcc' back end is changed to inline "forward references", in which invocations precede definitions, the `g77' front end will be changed to treat both orderings as errors, accordingly. The sorts of disagreements that are diagnosed by `g77' include whether a procedure is a subroutine or function; if it is a function, the type of the return value of the procedure; the number of arguments the procedure accepts; and the type of each argument. Disagreements regarding global names among program units in a Fortran program _should_ be fixed in the code itself. However, if that is not immediately practical, and the code has been working for some time, it is possible it will work when compiled with the `-fno-globals' option. The `-fno-globals' option causes these diagnostics to all be warnings and disables all inlining of references to global procedures (to avoid subsequent compiler crashes and bad-code generation). Use of the `-Wno-globals' option as well as `-fno-globals' suppresses all of these diagnostics. (`-Wno-globals' by itself disables only the warnings, not the errors.) After using `-fno-globals' to work around these problems, it is wise to stop using that option and address them by fixing the Fortran code, because such problems, while they might not actually result in bugs on some systems, indicate that the code is not as portable as it could be. In particular, the code might appear to work on a particular system, but have bugs that affect the reliability of the data without exhibiting any other outward manifestations of the bugs.  File: g77.info, Node: LINKFAIL, Next: Y2KBAD, Prev: GLOBALS, Up: Diagnostics `LINKFAIL' ========== On AIX 4.1, `g77' might not build with the native (non-GNU) tools due to a linker bug in coping with the `-bbigtoc' option which leads to a `Relocation overflow' error. The GNU linker is not recommended on current AIX versions, though; it was developed under a now-unsupported version. This bug is said to be fixed by `update PTF U455193 for APAR IX75823'. Compiling with `-mminimal-toc' might solve this problem, e.g. by adding BOOT_CFLAGS='-mminimal-toc -O2 -g' to the `make bootstrap' command line.  File: g77.info, Node: Y2KBAD, Prev: LINKFAIL, Up: Diagnostics `Y2KBAD' ======== Intrinsic `NAME', invoked at (^), known to be non-Y2K-compliant... This diagnostic indicates that the specific intrinsic invoked by the name NAME is known to have an interface that is not Year-2000 (Y2K) compliant. *Note Year 2000 (Y2K) Problems::.  File: g77.info, Node: Keyword Index, Prev: Diagnostics, Up: Top Keyword Index ************* * Menu: * ! <1>: Trailing Comment. * ! <2>: Exclamation Point. * ! <3>: Statements Comments Lines. * ! <4>: LEX. * !: Character Set. * ": Character Set. * # <1>: Character Set. * #: Cpp-style directives. * #define: Overall Options. * #if: Overall Options. * #include: Overall Options. * $: Dollar Signs. * %: Character Set. * %DESCR() construct: %DESCR(). * %LOC() construct: %LOC(). * %REF() construct: %REF(). * %VAL() construct: %VAL(). * &: Character Set. * *: LEX. * *N notation <1>: Compiler Types. * *N notation: Star Notation. * --driver option <1>: News. * --driver option <2>: Changes. * --driver option: News. * -falias-check option <1>: Aliasing Assumed To Work. * -falias-check option: Code Gen Options. * -fargument-alias option <1>: Aliasing Assumed To Work. * -fargument-alias option: Code Gen Options. * -fargument-noalias option <1>: Code Gen Options. * -fargument-noalias option: Aliasing Assumed To Work. * -fbadu77-intrinsics-delete option: Fortran Dialect Options. * -fbadu77-intrinsics-disable option: Fortran Dialect Options. * -fbadu77-intrinsics-enable option: Fortran Dialect Options. * -fbadu77-intrinsics-hide option: Fortran Dialect Options. * -fbounds-check option: Code Gen Options. * -fcaller-saves option: Optimize Options. * -fcase-initcap option: Fortran Dialect Options. * -fcase-lower option: Fortran Dialect Options. * -fcase-preserve option: Fortran Dialect Options. * -fcase-strict-lower option: Fortran Dialect Options. * -fcase-strict-upper option: Fortran Dialect Options. * -fcase-upper option: Fortran Dialect Options. * -fdelayed-branch option: Optimize Options. * -fdollar-ok option: Fortran Dialect Options. * -femulate-complex option: Code Gen Options. * -fexpensive-optimizations option: Optimize Options. * -ff2c-intrinsics-delete option: Fortran Dialect Options. * -ff2c-intrinsics-disable option: Fortran Dialect Options. * -ff2c-intrinsics-enable option: Fortran Dialect Options. * -ff2c-intrinsics-hide option: Fortran Dialect Options. * -ff2c-library option: Code Gen Options. * -ff66 option: Shorthand Options. * -ff77 option: Shorthand Options. * -ff90: Fortran 90 Features. * -ff90 option: Fortran Dialect Options. * -ff90-intrinsics-delete option: Fortran Dialect Options. * -ff90-intrinsics-disable option: Fortran Dialect Options. * -ff90-intrinsics-enable option: Fortran Dialect Options. * -ff90-intrinsics-hide option: Fortran Dialect Options. * -ffast-math option: Optimize Options. * -ffinite-math-only option: Optimize Options. * -ffixed-line-length-N option: Fortran Dialect Options. * -fflatten-arrays option: Code Gen Options. * -ffloat-store option: Optimize Options. * -fforce-addr option: Optimize Options. * -fforce-mem option: Optimize Options. * -ffortran-bounds-check option: Code Gen Options. * -ffree-form: Fortran 90 Features. * -ffree-form option: Fortran Dialect Options. * -fgnu-intrinsics-delete option: Fortran Dialect Options. * -fgnu-intrinsics-disable option: Fortran Dialect Options. * -fgnu-intrinsics-enable option: Fortran Dialect Options. * -fgnu-intrinsics-hide option: Fortran Dialect Options. * -fGROUP-intrinsics-hide option: Overly Convenient Options. * -finit-local-zero option <1>: Overly Convenient Options. * -finit-local-zero option: Code Gen Options. * -fintrin-case-any option: Fortran Dialect Options. * -fintrin-case-initcap option: Fortran Dialect Options. * -fintrin-case-lower option: Fortran Dialect Options. * -fintrin-case-upper option: Fortran Dialect Options. * -fmatch-case-any option: Fortran Dialect Options. * -fmatch-case-initcap option: Fortran Dialect Options. * -fmatch-case-lower option: Fortran Dialect Options. * -fmatch-case-upper option: Fortran Dialect Options. * -fmil-intrinsics-delete option: Fortran Dialect Options. * -fmil-intrinsics-disable option: Fortran Dialect Options. * -fmil-intrinsics-enable option: Fortran Dialect Options. * -fmil-intrinsics-hide option: Fortran Dialect Options. * -fno-argument-noalias-global option <1>: Aliasing Assumed To Work. * -fno-argument-noalias-global option: Code Gen Options. * -fno-automatic option <1>: Code Gen Options. * -fno-automatic option: Overly Convenient Options. * -fno-backslash option: Fortran Dialect Options. * -fno-common option: Code Gen Options. * -fno-f2c option <1>: Avoid f2c Compatibility. * -fno-f2c option: Code Gen Options. * -fno-f77 option: Shorthand Options. * -fno-fixed-form option: Fortran Dialect Options. * -fno-globals option: Code Gen Options. * -fno-ident option: Code Gen Options. * -fno-inline option: Optimize Options. * -fno-move-all-movables option: Optimize Options. * -fno-reduce-all-givs option: Optimize Options. * -fno-rerun-loop-opt option: Optimize Options. * -fno-second-underscore: f2c Skeletons and Prototypes. * -fno-second-underscore option <1>: Names. * -fno-second-underscore option: Code Gen Options. * -fno-silent option: Overall Options. * -fno-trapping-math option: Optimize Options. * -fno-ugly option: Shorthand Options. * -fno-ugly-args option: Fortran Dialect Options. * -fno-ugly-init option: Fortran Dialect Options. * -fno-underscoring option <1>: Names. * -fno-underscoring option: Code Gen Options. * -fonetrip option: Fortran Dialect Options. * -fpack-struct option: Code Gen Options. * -fpcc-struct-return option: Code Gen Options. * -fpedantic option: Warning Options. * -fPIC option: News. * -freg-struct-return option: Code Gen Options. * -frerun-cse-after-loop option: Optimize Options. * -fschedule-insns option: Optimize Options. * -fschedule-insns2 option: Optimize Options. * -fset-g77-defaults option: Overall Options. * -fshort-double option: Code Gen Options. * -fsource-case-lower option: Fortran Dialect Options. * -fsource-case-preserve option: Fortran Dialect Options. * -fsource-case-upper option: Fortran Dialect Options. * -fstrength-reduce option: Optimize Options. * -fsymbol-case-any option: Fortran Dialect Options. * -fsymbol-case-initcap option: Fortran Dialect Options. * -fsymbol-case-lower option: Fortran Dialect Options. * -fsymbol-case-upper option: Fortran Dialect Options. * -fsyntax-only option: Warning Options. * -ftypeless-boz option: Fortran Dialect Options. * -fugly option: Shorthand Options. * -fugly-assign option: Fortran Dialect Options. * -fugly-assumed option: Fortran Dialect Options. * -fugly-comma option: Fortran Dialect Options. * -fugly-complex option: Fortran Dialect Options. * -fugly-logint option: Fortran Dialect Options. * -funix-intrinsics-delete option: Fortran Dialect Options. * -funix-intrinsics-disable option: Fortran Dialect Options. * -funix-intrinsics-enable option: Fortran Dialect Options. * -funix-intrinsics-hide option: Fortran Dialect Options. * -funroll-all-loops option: Optimize Options. * -funroll-loops option: Optimize Options. * -funsafe-math-optimizations option: Optimize Options. * -fversion option: Overall Options. * -fvxt option: Fortran Dialect Options. * -fvxt-intrinsics-delete option: Fortran Dialect Options. * -fvxt-intrinsics-disable option: Fortran Dialect Options. * -fvxt-intrinsics-enable option: Fortran Dialect Options. * -fvxt-intrinsics-hide option: Fortran Dialect Options. * -fzeros option: Code Gen Options. * -g option: Debugging Options. * -I- option: Directory Options. * -i8: Increasing Precision/Range. * -Idir option: Directory Options. * -malign-double <1>: Changes. * -malign-double <2>: News. * -malign-double: Changes. * -malign-double option <1>: Optimize Options. * -malign-double option: Aligned Data. * -Nl option: Compiler Limits. * -Nx option: Compiler Limits. * -O2: News. * -pedantic option: Warning Options. * -pedantic-errors option: Warning Options. * -qrealsize=8: Increasing Precision/Range. * -r8: Increasing Precision/Range. * -u option: Warning Options. * -v option: G77 and GCC. * -w option: Warning Options. * -W option: Warning Options. * -Waggregate-return option: Warning Options. * -Wall option: Warning Options. * -Wcomment option: Warning Options. * -Wconversion option: Warning Options. * -Werror option: Warning Options. * -Wformat option: Warning Options. * -Wid-clash-LEN option: Warning Options. * -Wimplicit option: Warning Options. * -Wlarger-than-LEN option: Warning Options. * -Wno-globals option: Warning Options. * -Wparentheses option: Warning Options. * -Wredundant-decls option: Warning Options. * -Wshadow option: Warning Options. * -Wsurprising option: Warning Options. * -Wswitch option: Warning Options. * -Wswitch-default option: Warning Options. * -Wswitch-enum option: Warning Options. * -Wtraditional option: Warning Options. * -Wuninitialized option: Warning Options. * -Wunused option: Warning Options. * -x f77-cpp-input option: LEX. * .EQV., with integer operands: Equivalence Versus Equality. * .f filename suffix: Overall Options. * .F filename suffix: Overall Options. * .for filename suffix: Overall Options. * .FOR filename suffix: Overall Options. * .fpp filename suffix: Overall Options. * .FPP filename suffix: Overall Options. * .gdbinit: Main Program Unit. * .r filename suffix: Overall Options. * /* <1>: Trailing Comment. * /*: Overall Options. * /WARNINGS=DECLARATIONS switch: Warning Options. * 80-bit spills: Floating-point Errors. * ; <1>: Statements Comments Lines. * ;: Character Set. * <: Character Set. * <> edit descriptor: I/O. * >: Character Set. * ?: Character Set. * \: Character Set. * _: Character Set. * Abort intrinsic: Abort Intrinsic. * Abs intrinsic: Abs Intrinsic. * ACCEPT statement: TYPE and ACCEPT I/O Statements. * Access intrinsic: Access Intrinsic. * AChar intrinsic: AChar Intrinsic. * ACos intrinsic: ACos Intrinsic. * ACosD intrinsic: ACosD Intrinsic. * adding options: Adding Options. * adjustable arrays: Adjustable Arrays. * AdjustL intrinsic: AdjustL Intrinsic. * AdjustR intrinsic: AdjustR Intrinsic. * AImag intrinsic <1>: AImag Intrinsic. * AImag intrinsic: REAL() and AIMAG() of Complex. * AIMax0 intrinsic: AIMax0 Intrinsic. * AIMin0 intrinsic: AIMin0 Intrinsic. * AInt intrinsic: AInt Intrinsic. * AJMax0 intrinsic: AJMax0 Intrinsic. * AJMin0 intrinsic: AJMin0 Intrinsic. * Alarm intrinsic: Alarm Intrinsic. * aliasing <1>: Known Bugs. * aliasing: Aliasing Assumed To Work. * aligned data: Aligned Data. * aligned stack: Aligned Data. * alignment <1>: News. * alignment <2>: Changes. * alignment <3>: Aligned Data. * alignment: Changes. * All intrinsic: All Intrinsic. * all warnings: Warning Options. * Allocated intrinsic: Allocated Intrinsic. * ALog intrinsic: ALog Intrinsic. * ALog10 intrinsic: ALog10 Intrinsic. * Alpha, support: Known Bugs. * alternate entry points: Alternate Entry Points. * alternate returns: Alternate Returns. * ALWAYS_FLUSH: Output Assumed To Flush. * AMax0 intrinsic: AMax0 Intrinsic. * AMax1 intrinsic: AMax1 Intrinsic. * AMin0 intrinsic: AMin0 Intrinsic. * AMin1 intrinsic: AMin1 Intrinsic. * AMod intrinsic: AMod Intrinsic. * ampersand: Character Set. * ampersand continuation line: Ampersands. * And intrinsic <1>: And Intrinsic. * And intrinsic: Bit Operations on Floating-point Data. * ANInt intrinsic: ANInt Intrinsic. * ANS carriage control: OPEN CLOSE and INQUIRE Keywords. * ANSI FORTRAN 77 standard: Language. * ANSI FORTRAN 77 support: Standard Support. * anti-aliasing: Aliasing Assumed To Work. * Any intrinsic: Any Intrinsic. * arguments, null: Ugly Null Arguments. * arguments, omitting: Ugly Null Arguments. * arguments, unused <1>: Unused Arguments. * arguments, unused: Warning Options. * array bounds checking: Code Gen Options. * array bounds, adjustable: Array Bounds Expressions. * array elements, in adjustable array bounds: Array Bounds Expressions. * array ordering: Arrays. * array performance: Code Gen Options. * array size: Array Size. * arrays: Arrays. * arrays, adjustable: Adjustable Arrays. * arrays, assumed-size: Ugly Assumed-Size Arrays. * arrays, automatic <1>: Stack Overflow. * arrays, automatic <2>: Overly Convenient Options. * arrays, automatic <3>: Large Automatic Arrays. * arrays, automatic: Adjustable Arrays. * arrays, dimensioning <1>: Adjustable Arrays. * arrays, dimensioning: Array Size. * arrays, flattening: Code Gen Options. * as command: What is GNU Fortran?. * ASin intrinsic: ASin Intrinsic. * ASinD intrinsic: ASinD Intrinsic. * assembler: What is GNU Fortran?. * assembly code: What is GNU Fortran?. * assembly code, invalid: Bug Criteria. * ASSIGN statement <1>: Assigned Statement Labels. * ASSIGN statement: Ugly Assigned Labels. * assigned labels: Ugly Assigned Labels. * assigned statement labels: Assigned Statement Labels. * Associated intrinsic: Associated Intrinsic. * association, storage: Aliasing Assumed To Work. * assumed-size arrays: Ugly Assumed-Size Arrays. * asterisk: LEX. * ATan intrinsic: ATan Intrinsic. * ATan2 intrinsic: ATan2 Intrinsic. * ATan2D intrinsic: ATan2D Intrinsic. * ATanD intrinsic: ATanD Intrinsic. * automatic arrays <1>: Adjustable Arrays. * automatic arrays <2>: Stack Overflow. * automatic arrays <3>: Overly Convenient Options. * automatic arrays: Large Automatic Arrays. * AUTOMATIC statement: AUTOMATIC Statement. * automatic variables: AUTOMATIC Statement. * back end, gcc <1>: What is GNU Fortran?. * back end, gcc: Philosophy of Code Generation. * backslash <1>: Fortran Dialect Options. * backslash <2>: Backslash in Constants. * backslash: Character Set. * badu77 intrinsics: Fortran Dialect Options. * badu77 intrinsics group: Intrinsic Groups. * basic concepts: What is GNU Fortran?. * Bear-poking: Philosophy of Code Generation. * beginners: Getting Started. * BesJ0 intrinsic: BesJ0 Intrinsic. * BesJ1 intrinsic: BesJ1 Intrinsic. * BesJN intrinsic: BesJN Intrinsic. * BesY0 intrinsic: BesY0 Intrinsic. * BesY1 intrinsic: BesY1 Intrinsic. * BesYN intrinsic: BesYN Intrinsic. * binary data: Portable Unformatted Files. * Bit_Size intrinsic: Bit_Size Intrinsic. * BITest intrinsic: BITest Intrinsic. * BJTest intrinsic: BJTest Intrinsic. * blank <1>: Lines. * blank: Character Set. * block data: Multiple Definitions of External Names. * block data and libraries: Block Data and Libraries. * BLOCK DATA statement <1>: Block Data and Libraries. * BLOCK DATA statement: Multiple Definitions of External Names. * bounds checking: Code Gen Options. * BTest intrinsic: BTest Intrinsic. * bug criteria: Bug Criteria. * bugs: Bugs. * bugs, finding: What is GNU Fortran?. * bugs, known: Trouble. * bus error <1>: Strange Behavior at Run Time. * bus error: NeXTStep Problems. * but-bugs: But-bugs. * byte ordering: Portable Unformatted Files. * C library: Strange Behavior at Run Time. * C preprocessor: Overall Options. * C routines calling Fortran: Debugging and Interfacing. * C++: C++ Considerations. * C++, linking with: Interoperating with C and C++. * C, linking with: Interoperating with C and C++. * CAbs intrinsic: CAbs Intrinsic. * calling C routines: Debugging and Interfacing. * card image: Fortran Dialect Options. * carriage control: OPEN CLOSE and INQUIRE Keywords. * carriage returns: Carriage Returns. * case sensitivity: Case Sensitivity. * cc1 program: What is GNU Fortran?. * cc1plus program: What is GNU Fortran?. * CCos intrinsic: CCos Intrinsic. * CDAbs intrinsic: CDAbs Intrinsic. * CDCos intrinsic: CDCos Intrinsic. * CDExp intrinsic: CDExp Intrinsic. * CDLog intrinsic: CDLog Intrinsic. * CDSin intrinsic: CDSin Intrinsic. * CDSqRt intrinsic: CDSqRt Intrinsic. * Ceiling intrinsic: Ceiling Intrinsic. * CExp intrinsic: CExp Intrinsic. * cfortran.h: C Interfacing Tools. * changes, user-visible: Changes. * Char intrinsic: Char Intrinsic. * character assignments: Fortran 90 Features. * character constants <1>: Character and Hollerith Constants. * character constants <2>: Ugly Conversion of Initializers. * character constants <3>: Double Quote Meaning. * character constants: Fortran Dialect Options. * character set: Fortran Dialect Options. * CHARACTER*(*): Arbitrary Concatenation. * CHARACTER, null: Character Type. * character-variable length: Character-variable Length. * characters: Character Set. * characters, comma: Ugly Null Arguments. * characters, comment <1>: Statements Comments Lines. * characters, comment <2>: Exclamation Point. * characters, comment <3>: LEX. * characters, comment: Trailing Comment. * characters, continuation <1>: Statements Comments Lines. * characters, continuation <2>: LEX. * characters, continuation: Exclamation Point. * ChDir intrinsic <1>: ChDir Intrinsic (function). * ChDir intrinsic: ChDir Intrinsic (subroutine). * checking subscripts: Code Gen Options. * checking substrings: Code Gen Options. * checks, of internal consistency: Overall Options. * ChMod intrinsic <1>: ChMod Intrinsic (function). * ChMod intrinsic: ChMod Intrinsic (subroutine). * CLog intrinsic: CLog Intrinsic. * close angle: Character Set. * close bracket: Character Set. * CLOSE statement: OPEN CLOSE and INQUIRE Keywords. * Cmplx intrinsic <1>: Cmplx Intrinsic. * Cmplx intrinsic: CMPLX() of DOUBLE PRECISION. * code generation, conventions: Code Gen Options. * code generation, improving: Better Optimization. * code generator <1>: What is GNU Fortran?. * code generator: Philosophy of Code Generation. * code, assembly: What is GNU Fortran?. * code, displaying main source: Known Bugs. * code, in-line: What is GNU Fortran?. * code, legacy: Collected Fortran Wisdom. * code, machine: What is GNU Fortran?. * code, source <1>: What is GNU Fortran?. * code, source <2>: Lines. * code, source <3>: Source Form. * code, source: Case Sensitivity. * code, user: Cannot Link Fortran Programs. * code, writing: Collected Fortran Wisdom. * column-major ordering: Arrays. * columns 73 through 80: Better Source Model. * comma, trailing: Ugly Null Arguments. * command options: Invoking G77. * commands, as: What is GNU Fortran?. * commands, g77 <1>: What is GNU Fortran?. * commands, g77: G77 and GCC. * commands, gcc <1>: G77 and GCC. * commands, gcc: What is GNU Fortran?. * commands, gdb: What is GNU Fortran?. * commands, ld: What is GNU Fortran?. * comment <1>: Statements Comments Lines. * comment <2>: Trailing Comment. * comment: LEX. * comment character: Exclamation Point. * comment line, debug <1>: Enabling Debug Lines. * comment line, debug: Debug Line. * common blocks <1>: Known Bugs. * common blocks <2>: Common Blocks. * common blocks: Mangling of Names. * common blocks, large: Large Common Blocks. * COMMON layout: Aligned Data. * COMMON statement <1>: Common Blocks. * COMMON statement: Multiple Definitions of External Names. * comparing logical expressions: Equivalence Versus Equality. * compatibility, f2c <1>: Avoid f2c Compatibility. * compatibility, f2c <2>: Block Data and Libraries. * compatibility, f2c <3>: Shorthand Options. * compatibility, f2c <4>: Code Gen Options. * compatibility, f2c: Overall Options. * compatibility, f77: Shorthand Options. * compatibility, FORTRAN 66 <1>: Shorthand Options. * compatibility, FORTRAN 66: Fortran Dialect Options. * compatibility, FORTRAN 77: Standard Support. * compatibility, Fortran 90: Fortran 90. * compilation, in-line <1>: Optimize Options. * compilation, in-line <2>: Code Gen Options. * compilation, in-line: GLOBALS. * compilation, pedantic: Pedantic Compilation. * compilation, status: Overall Options. * compiler bugs, reporting: Bug Reporting. * compiler limits: Compiler Limits. * compiler memory usage: Known Bugs. * compiler speed: Known Bugs. * compilers: What is GNU Fortran?. * compiling programs: G77 and GCC. * Complex intrinsic: Complex Intrinsic. * COMPLEX intrinsics: Fortran Dialect Options. * complex performance: Known Bugs. * COMPLEX statement: Complex Variables. * complex values: Ugly Complex Part Extraction. * complex variables: Complex Variables. * COMPLEX(KIND=1) type: Compiler Types. * COMPLEX(KIND=2) type: Compiler Types. * components of g77: What is GNU Fortran?. * concatenation: Arbitrary Concatenation. * concepts, basic: What is GNU Fortran?. * conformance, IEEE 754 <1>: Optimize Options. * conformance, IEEE 754 <2>: Floating-point precision. * conformance, IEEE 754: Optimize Options. * Conjg intrinsic: Conjg Intrinsic. * consistency checks: Overall Options. * constants <1>: Constants. * constants: Compiler Constants. * constants, character <1>: Character and Hollerith Constants. * constants, character <2>: Ugly Conversion of Initializers. * constants, character: Double Quote Meaning. * constants, context-sensitive: Context-Sensitive Constants. * constants, Hollerith <1>: Ugly Conversion of Initializers. * constants, Hollerith <2>: Ugly Implicit Argument Conversion. * constants, Hollerith: Character and Hollerith Constants. * constants, integer: Known Bugs. * constants, octal: Double Quote Meaning. * constants, prefix-radix: Fortran Dialect Options. * constants, types: Fortran Dialect Options. * construct names: Construct Names. * context-sensitive constants: Context-Sensitive Constants. * context-sensitive intrinsics: Context-Sensitive Intrinsicness. * continuation character <1>: Exclamation Point. * continuation character <2>: Statements Comments Lines. * continuation character: LEX. * continuation line, ampersand: Ampersands. * continuation line, number of: Continuation Line. * contributors: Contributors. * conversions, nonportable: Nonportable Conversions. * core dump: Bug Criteria. * Cos intrinsic: Cos Intrinsic. * CosD intrinsic: CosD Intrinsic. * CosH intrinsic: CosH Intrinsic. * Count intrinsic: Count Intrinsic. * cpp preprocessor: Overall Options. * cpp program <1>: Preprocessor Options. * cpp program <2>: LEX. * cpp program <3>: Overall Options. * cpp program: What is GNU Fortran?. * CPU_Time intrinsic: CPU_Time Intrinsic. * Cray pointers: POINTER Statements. * credits: Contributors. * CShift intrinsic: CShift Intrinsic. * CSin intrinsic: CSin Intrinsic. * CSqRt intrinsic: CSqRt Intrinsic. * CTime intrinsic <1>: CTime Intrinsic (subroutine). * CTime intrinsic: CTime Intrinsic (function). * CYCLE statement: CYCLE and EXIT. * DAbs intrinsic: DAbs Intrinsic. * DACos intrinsic: DACos Intrinsic. * DACosD intrinsic: DACosD Intrinsic. * DASin intrinsic: DASin Intrinsic. * DASinD intrinsic: DASinD Intrinsic. * DATA statement <1>: Code Gen Options. * DATA statement: Known Bugs. * data types: Compiler Types. * data, aligned: Aligned Data. * data, overwritten: Strange Behavior at Run Time. * DATan intrinsic: DATan Intrinsic. * DATan2 intrinsic: DATan2 Intrinsic. * DATan2D intrinsic: DATan2D Intrinsic. * DATanD intrinsic: DATanD Intrinsic. * Date intrinsic: Date Intrinsic. * Date_and_Time intrinsic: Date_and_Time Intrinsic. * date_y2kbuggy_0: Year 2000 (Y2K) Problems. * DbesJ0 intrinsic: DbesJ0 Intrinsic. * DbesJ1 intrinsic: DbesJ1 Intrinsic. * DbesJN intrinsic: DbesJN Intrinsic. * DbesY0 intrinsic: DbesY0 Intrinsic. * DbesY1 intrinsic: DbesY1 Intrinsic. * DbesYN intrinsic: DbesYN Intrinsic. * Dble intrinsic: Dble Intrinsic. * DbleQ intrinsic: DbleQ Intrinsic. * DCmplx intrinsic: DCmplx Intrinsic. * DConjg intrinsic: DConjg Intrinsic. * DCos intrinsic: DCos Intrinsic. * DCosD intrinsic: DCosD Intrinsic. * DCosH intrinsic: DCosH Intrinsic. * DDiM intrinsic: DDiM Intrinsic. * debug line <1>: Debug Line. * debug line: Enabling Debug Lines. * debugger <1>: Known Bugs. * debugger: What is GNU Fortran?. * debugging <1>: Names. * debugging <2>: Main Program Unit. * debugging: Debugging and Interfacing. * debugging information options: Debugging Options. * debugging main source code: Known Bugs. * DECODE statement: ENCODE and DECODE. * deleted intrinsics: Intrinsic Groups. * DErF intrinsic: DErF Intrinsic. * DErFC intrinsic: DErFC Intrinsic. * DExp intrinsic: DExp Intrinsic. * DFloat intrinsic: DFloat Intrinsic. * DFlotI intrinsic: DFlotI Intrinsic. * DFlotJ intrinsic: DFlotJ Intrinsic. * diagnostics: Diagnostics. * diagnostics, incorrect: What is GNU Fortran?. * dialect options: Fortran Dialect Options. * Digital Fortran features: Fortran Dialect Options. * Digits intrinsic: Digits Intrinsic. * DiM intrinsic: DiM Intrinsic. * DImag intrinsic: DImag Intrinsic. * DIMENSION statement <1>: Adjustable Arrays. * DIMENSION statement <2>: Array Bounds Expressions. * DIMENSION statement: Arrays. * DIMENSION X(1): Ugly Assumed-Size Arrays. * dimensioning arrays: Adjustable Arrays. * DInt intrinsic: DInt Intrinsic. * direction of language development: Direction of Language Development. * directive, INCLUDE <1>: Preprocessor Options. * directive, INCLUDE: Directory Options. * directory, options: Directory Options. * directory, search paths for inclusion: Directory Options. * disabled intrinsics: Intrinsic Groups. * disk full: Output Assumed To Flush. * displaying main source code: Known Bugs. * disposition of files: OPEN CLOSE and INQUIRE Keywords. * distensions: Distensions. * DLog intrinsic: DLog Intrinsic. * DLog10 intrinsic: DLog10 Intrinsic. * DMax1 intrinsic: DMax1 Intrinsic. * DMin1 intrinsic: DMin1 Intrinsic. * DMod intrinsic: DMod Intrinsic. * DNInt intrinsic: DNInt Intrinsic. * DNRM2: News. * DO: DO WHILE. * DO loops, one-trip: Fortran Dialect Options. * DO loops, zero-trip: Fortran Dialect Options. * DO statement <1>: Warning Options. * DO statement: Loops. * DO WHILE <1>: DO WHILE. * DO WHILE: Optimize Options. * dollar sign <1>: Dollar Signs. * dollar sign <2>: Fortran Dialect Options. * dollar sign: I/O. * Dot_Product intrinsic: Dot_Product Intrinsic. * DOUBLE COMPLEX: DOUBLE COMPLEX. * DOUBLE COMPLEX type: Compiler Types. * DOUBLE PRECISION type: Compiler Types. * double quote: Character Set. * double quoted character constants <1>: Fortran 90 Features. * double quoted character constants: Character Type. * double quotes: Double Quote Meaning. * double-precision performance <1>: Changes. * double-precision performance: News. * DProd intrinsic: DProd Intrinsic. * DReal intrinsic: DReal Intrinsic. * driver, gcc command as: What is GNU Fortran?. * DSign intrinsic: DSign Intrinsic. * DSin intrinsic: DSin Intrinsic. * DSinD intrinsic: DSinD Intrinsic. * DSinH intrinsic: DSinH Intrinsic. * DSqRt intrinsic: DSqRt Intrinsic. * DTan intrinsic: DTan Intrinsic. * DTanD intrinsic: DTanD Intrinsic. * DTanH intrinsic: DTanH Intrinsic. * DTime intrinsic <1>: DTime Intrinsic (subroutine). * DTime intrinsic: DTime Intrinsic (function). * dummies, unused: Warning Options. * edit descriptor, <>: I/O. * edit descriptor, O: I/O. * edit descriptor, Q: Q Edit Descriptor. * edit descriptor, Z <1>: Fortran 90 Features. * edit descriptor, Z: I/O. * effecting IMPLICIT NONE: Warning Options. * efficiency: Efficiency. * ELF support: News. * empty CHARACTER strings: Character Type. * enabled intrinsics: Intrinsic Groups. * ENCODE statement: ENCODE and DECODE. * END DO: END DO. * entry points: Alternate Entry Points. * ENTRY statement: Alternate Entry Points. * environment variables: Environment Variables. * EOShift intrinsic: EOShift Intrinsic. * Epsilon intrinsic: Epsilon Intrinsic. * equivalence areas <1>: Known Bugs. * equivalence areas: Local Equivalence Areas. * EQUIVALENCE statement: Local Equivalence Areas. * ErF intrinsic: ErF Intrinsic. * ErFC intrinsic: ErFC Intrinsic. * error messages <1>: Warnings and Errors. * error messages: Run-time Library Errors. * error messages, incorrect: What is GNU Fortran?. * error values: Run-time Library Errors. * errors, linker: Large Common Blocks. * ETime intrinsic <1>: ETime Intrinsic (function). * ETime intrinsic: ETime Intrinsic (subroutine). * exceptions, floating-point: Floating-point Exception Handling. * exclamation point <1>: Exclamation Point. * exclamation point <2>: Statements Comments Lines. * exclamation point <3>: LEX. * exclamation point <4>: Trailing Comment. * exclamation point: Character Set. * executable file: What is GNU Fortran?. * Exit intrinsic: Exit Intrinsic. * EXIT statement: CYCLE and EXIT. * Exp intrinsic: Exp Intrinsic. * Exponent intrinsic: Exponent Intrinsic. * extended-source option: Fortran Dialect Options. * extensions, file name: Overall Options. * extensions, from Fortran 90: Fortran 90 Features. * extensions, more: More Extensions. * extensions, VXT: VXT Fortran. * external names: Mangling of Names. * extra warnings: Warning Options. * f2c: Increasing Precision/Range. * f2c compatibility <1>: Avoid f2c Compatibility. * f2c compatibility <2>: Shorthand Options. * f2c compatibility <3>: Debugging and Interfacing. * f2c compatibility <4>: Overall Options. * f2c compatibility <5>: Code Gen Options. * f2c compatibility: Block Data and Libraries. * f2c intrinsics: Fortran Dialect Options. * f2c intrinsics group: Intrinsic Groups. * f77 compatibility: Shorthand Options. * f77 support: Backslash in Constants. * f771, program: What is GNU Fortran?. * f90 intrinsics group: Intrinsic Groups. * fatal signal: Bug Criteria. * FDate intrinsic <1>: FDate Intrinsic (function). * FDate intrinsic: FDate Intrinsic (subroutine). * FDL, GNU Free Documentation License: GNU Free Documentation License. * features, language: Direction of Language Development. * features, ugly <1>: Shorthand Options. * features, ugly: Distensions. * FFE <1>: What is GNU Fortran?. * FFE: Front End. * fflush(): Output Assumed To Flush. * FGet intrinsic <1>: FGet Intrinsic (subroutine). * FGet intrinsic: FGet Intrinsic (function). * FGetC intrinsic <1>: FGetC Intrinsic (function). * FGetC intrinsic: FGetC Intrinsic (subroutine). * file format not recognized: What is GNU Fortran?. * file formats: Portable Unformatted Files. * file name extension: Overall Options. * file name suffix: Overall Options. * file type: Overall Options. * file, source <1>: What is GNU Fortran?. * file, source <2>: Source Form. * file, source: Lines. * files, executable: What is GNU Fortran?. * fixed form <1>: Fortran Dialect Options. * fixed form <2>: Lines. * fixed form <3>: Source Form. * fixed form: Fortran Dialect Options. * Float intrinsic: Float Intrinsic. * FloatI intrinsic: FloatI Intrinsic. * floating-point errors: Floating-point Errors. * floating-point, errors: Inconsistent Calling Sequences. * floating-point, exceptions: Floating-point Exception Handling. * floating-point, precision <1>: Floating-point precision. * floating-point, precision: Optimize Options. * FloatJ intrinsic: FloatJ Intrinsic. * Floor intrinsic: Floor Intrinsic. * Flush intrinsic: Flush Intrinsic. * flushing output: Output Assumed To Flush. * FNum intrinsic: FNum Intrinsic. * FORM='PRINT': OPEN CLOSE and INQUIRE Keywords. * FORMAT descriptors <1>: I/O. * FORMAT descriptors: Fortran 90 Features. * FORMAT statement <1>: Expressions in FORMAT Statements. * FORMAT statement: Q Edit Descriptor. * FORTRAN 66 <1>: Fortran Dialect Options. * FORTRAN 66: Shorthand Options. * FORTRAN 77 compatibility: Standard Support. * Fortran 90: Fortran 90 Features. * Fortran 90, compatibility: Fortran 90. * Fortran 90, features: Fortran Dialect Options. * Fortran 90, intrinsics: Fortran Dialect Options. * Fortran 90, support: Fortran 90 Support. * Fortran preprocessor: Overall Options. * forward references: GLOBALS. * FPE handling: Floating-point Exception Handling. * FPut intrinsic <1>: FPut Intrinsic (subroutine). * FPut intrinsic: FPut Intrinsic (function). * FPutC intrinsic <1>: FPutC Intrinsic (subroutine). * FPutC intrinsic: FPutC Intrinsic (function). * Fraction intrinsic: Fraction Intrinsic. * free form <1>: Lines. * free form <2>: Fortran Dialect Options. * free form: Source Form. * front end, g77 <1>: What is GNU Fortran?. * front end, g77: Front End. * FSeek intrinsic: FSeek Intrinsic. * FSF, funding the: Funding GNU Fortran. * FStat intrinsic <1>: FStat Intrinsic (subroutine). * FStat intrinsic: FStat Intrinsic (function). * FTell intrinsic <1>: FTell Intrinsic (subroutine). * FTell intrinsic: FTell Intrinsic (function). * function references, in adjustable array bounds: Array Bounds Expressions. * FUNCTION statement <1>: Procedures. * FUNCTION statement: Functions. * functions: Functions. * functions, mistyped: Not My Type. * funding improvements: Funding GNU Fortran. * funding the FSF: Funding GNU Fortran. * g77 options, --driver <1>: Changes. * g77 options, --driver <2>: News. * g77 options, --driver: Changes. * g77 options, -v: G77 and GCC. * g77, command <1>: What is GNU Fortran?. * g77, command <2>: G77 and GCC. * g77, command: What is GNU Fortran?. * g77, components of: What is GNU Fortran?. * g77, front end <1>: What is GNU Fortran?. * g77, front end: Front End. * g77, modifying: Overall Options. * G77_date_y2kbuggy_0: Year 2000 (Y2K) Problems. * G77_vxtidate_y2kbuggy_0: Year 2000 (Y2K) Problems. * GBE <1>: Philosophy of Code Generation. * GBE: What is GNU Fortran?. * GBEL: Philosophy of Code Generation. * gcc, back end <1>: What is GNU Fortran?. * gcc, back end: Philosophy of Code Generation. * gcc, command <1>: What is GNU Fortran?. * gcc, command: G77 and GCC. * gcc, command as driver: What is GNU Fortran?. * gcc, not recognizing Fortran source: What is GNU Fortran?. * gdb, command: What is GNU Fortran?. * gdb, support: Debugger Problems. * generic intrinsics: Generics and Specifics. * GError intrinsic: GError Intrinsic. * GetArg intrinsic <1>: GetArg Intrinsic. * GetArg intrinsic: Main Program Unit. * GetCWD intrinsic <1>: GetCWD Intrinsic (subroutine). * GetCWD intrinsic: GetCWD Intrinsic (function). * GetEnv intrinsic: GetEnv Intrinsic. * GetGId intrinsic: GetGId Intrinsic. * GetLog intrinsic: GetLog Intrinsic. * GetPId intrinsic: GetPId Intrinsic. * getting started: Getting Started. * GetUId intrinsic: GetUId Intrinsic. * global names, warning <1>: Code Gen Options. * global names, warning: Warning Options. * GMTime intrinsic: GMTime Intrinsic. * GNU Back End (GBE) <1>: What is GNU Fortran?. * GNU Back End (GBE): Philosophy of Code Generation. * GNU Back End Language (GBEL): Philosophy of Code Generation. * GNU Fortran command options: Invoking G77. * GNU Fortran Front End (FFE) <1>: Front End. * GNU Fortran Front End (FFE): What is GNU Fortran?. * gnu intrinsics group: Intrinsic Groups. * GOTO statement: Assigned Statement Labels. * groups of intrinsics: Intrinsic Groups. * hardware errors: Signal 11 and Friends. * hash mark: Character Set. * HDF: Portable Unformatted Files. * hidden intrinsics: Intrinsic Groups. * Hollerith constants <1>: Fortran Dialect Options. * Hollerith constants <2>: Ugly Implicit Argument Conversion. * Hollerith constants <3>: Ugly Conversion of Initializers. * Hollerith constants: Character and Hollerith Constants. * horizontal tab: Tabs. * HostNm intrinsic <1>: HostNm Intrinsic (function). * HostNm intrinsic: HostNm Intrinsic (subroutine). * Huge intrinsic: Huge Intrinsic. * I/O, errors: Run-time Library Errors. * I/O, flushing: Output Assumed To Flush. * IAbs intrinsic: IAbs Intrinsic. * IAChar intrinsic: IAChar Intrinsic. * IAnd intrinsic: IAnd Intrinsic. * IArgC intrinsic <1>: IArgC Intrinsic. * IArgC intrinsic: Main Program Unit. * IBClr intrinsic: IBClr Intrinsic. * IBits intrinsic: IBits Intrinsic. * IBSet intrinsic: IBSet Intrinsic. * IChar intrinsic: IChar Intrinsic. * IDate intrinsic <1>: IDate Intrinsic (UNIX). * IDate intrinsic: IDate Intrinsic (VXT). * IDiM intrinsic: IDiM Intrinsic. * IDInt intrinsic: IDInt Intrinsic. * IDNInt intrinsic: IDNInt Intrinsic. * IEEE 754 conformance <1>: Floating-point precision. * IEEE 754 conformance: Optimize Options. * IEOr intrinsic: IEOr Intrinsic. * IErrNo intrinsic: IErrNo Intrinsic. * IFix intrinsic: IFix Intrinsic. * IIAbs intrinsic: IIAbs Intrinsic. * IIAnd intrinsic: IIAnd Intrinsic. * IIBClr intrinsic: IIBClr Intrinsic. * IIBits intrinsic: IIBits Intrinsic. * IIBSet intrinsic: IIBSet Intrinsic. * IIDiM intrinsic: IIDiM Intrinsic. * IIDInt intrinsic: IIDInt Intrinsic. * IIDNnt intrinsic: IIDNnt Intrinsic. * IIEOr intrinsic: IIEOr Intrinsic. * IIFix intrinsic: IIFix Intrinsic. * IInt intrinsic: IInt Intrinsic. * IIOr intrinsic: IIOr Intrinsic. * IIQint intrinsic: IIQint Intrinsic. * IIQNnt intrinsic: IIQNnt Intrinsic. * IIShftC intrinsic: IIShftC Intrinsic. * IISign intrinsic: IISign Intrinsic. * illegal unit number: Large File Unit Numbers. * Imag intrinsic: Imag Intrinsic. * imaginary part <1>: Complex Variables. * imaginary part: Ugly Complex Part Extraction. * ImagPart intrinsic: ImagPart Intrinsic. * IMax0 intrinsic: IMax0 Intrinsic. * IMax1 intrinsic: IMax1 Intrinsic. * IMin0 intrinsic: IMin0 Intrinsic. * IMin1 intrinsic: IMin1 Intrinsic. * IMod intrinsic: IMod Intrinsic. * IMPLICIT CHARACTER*(*) statement: Limitation on Implicit Declarations. * implicit declaration, warning: Warning Options. * IMPLICIT NONE, similar effect: Warning Options. * implicit typing: Not My Type. * improvements, funding: Funding GNU Fortran. * in-line code <1>: Optimize Options. * in-line code <2>: GLOBALS. * in-line code <3>: Code Gen Options. * in-line code: What is GNU Fortran?. * INCLUDE directive <1>: Preprocessor Options. * INCLUDE directive <2>: INCLUDE. * INCLUDE directive: Directory Options. * inclusion, directory search paths for: Directory Options. * inconsistent floating-point results: Floating-point Errors. * incorrect diagnostics: What is GNU Fortran?. * incorrect error messages: What is GNU Fortran?. * incorrect use of language: What is GNU Fortran?. * increasing maximum unit number: Large File Unit Numbers. * increasing precision: Increasing Precision/Range. * increasing range: Increasing Precision/Range. * Index intrinsic: Index Intrinsic. * indexed (iterative) DO: Optimize Options. * infinite spaces printed: Strange Behavior at Run Time. * INInt intrinsic: INInt Intrinsic. * initialization, bug: Known Bugs. * initialization, of local variables: Code Gen Options. * initialization, run-time: Startup Code. * initialization, statement placement: Initializing Before Specifying. * INot intrinsic: INot Intrinsic. * INQUIRE statement: OPEN CLOSE and INQUIRE Keywords. * installation trouble: Trouble. * Int intrinsic: Int Intrinsic. * Int2 intrinsic: Int2 Intrinsic. * Int8 intrinsic: Int8 Intrinsic. * integer constants: Known Bugs. * INTEGER(KIND=1) type: Compiler Types. * INTEGER(KIND=2) type: Compiler Types. * INTEGER(KIND=3) type: Compiler Types. * INTEGER(KIND=6) type: Compiler Types. * INTEGER*2 support: Popular Non-standard Types. * INTEGER*8 support: Full Support for Compiler Types. * Intel x86: News. * interfacing: Debugging and Interfacing. * internal consistency checks: Overall Options. * intrinsics, Abort: Abort Intrinsic. * intrinsics, Abs: Abs Intrinsic. * intrinsics, Access: Access Intrinsic. * intrinsics, AChar: AChar Intrinsic. * intrinsics, ACos: ACos Intrinsic. * intrinsics, ACosD: ACosD Intrinsic. * intrinsics, AdjustL: AdjustL Intrinsic. * intrinsics, AdjustR: AdjustR Intrinsic. * intrinsics, AImag <1>: AImag Intrinsic. * intrinsics, AImag: REAL() and AIMAG() of Complex. * intrinsics, AIMax0: AIMax0 Intrinsic. * intrinsics, AIMin0: AIMin0 Intrinsic. * intrinsics, AInt: AInt Intrinsic. * intrinsics, AJMax0: AJMax0 Intrinsic. * intrinsics, AJMin0: AJMin0 Intrinsic. * intrinsics, Alarm: Alarm Intrinsic. * intrinsics, All: All Intrinsic. * intrinsics, Allocated: Allocated Intrinsic. * intrinsics, ALog: ALog Intrinsic. * intrinsics, ALog10: ALog10 Intrinsic. * intrinsics, AMax0: AMax0 Intrinsic. * intrinsics, AMax1: AMax1 Intrinsic. * intrinsics, AMin0: AMin0 Intrinsic. * intrinsics, AMin1: AMin1 Intrinsic. * intrinsics, AMod: AMod Intrinsic. * intrinsics, And <1>: And Intrinsic. * intrinsics, And: Bit Operations on Floating-point Data. * intrinsics, ANInt: ANInt Intrinsic. * intrinsics, Any: Any Intrinsic. * intrinsics, ASin: ASin Intrinsic. * intrinsics, ASinD: ASinD Intrinsic. * intrinsics, Associated: Associated Intrinsic. * intrinsics, ATan: ATan Intrinsic. * intrinsics, ATan2: ATan2 Intrinsic. * intrinsics, ATan2D: ATan2D Intrinsic. * intrinsics, ATanD: ATanD Intrinsic. * intrinsics, badu77: Fortran Dialect Options. * intrinsics, BesJ0: BesJ0 Intrinsic. * intrinsics, BesJ1: BesJ1 Intrinsic. * intrinsics, BesJN: BesJN Intrinsic. * intrinsics, BesY0: BesY0 Intrinsic. * intrinsics, BesY1: BesY1 Intrinsic. * intrinsics, BesYN: BesYN Intrinsic. * intrinsics, Bit_Size: Bit_Size Intrinsic. * intrinsics, BITest: BITest Intrinsic. * intrinsics, BJTest: BJTest Intrinsic. * intrinsics, BTest: BTest Intrinsic. * intrinsics, CAbs: CAbs Intrinsic. * intrinsics, CCos: CCos Intrinsic. * intrinsics, CDAbs: CDAbs Intrinsic. * intrinsics, CDCos: CDCos Intrinsic. * intrinsics, CDExp: CDExp Intrinsic. * intrinsics, CDLog: CDLog Intrinsic. * intrinsics, CDSin: CDSin Intrinsic. * intrinsics, CDSqRt: CDSqRt Intrinsic. * intrinsics, Ceiling: Ceiling Intrinsic. * intrinsics, CExp: CExp Intrinsic. * intrinsics, Char: Char Intrinsic. * intrinsics, ChDir <1>: ChDir Intrinsic (subroutine). * intrinsics, ChDir: ChDir Intrinsic (function). * intrinsics, ChMod <1>: ChMod Intrinsic (subroutine). * intrinsics, ChMod: ChMod Intrinsic (function). * intrinsics, CLog: CLog Intrinsic. * intrinsics, Cmplx <1>: CMPLX() of DOUBLE PRECISION. * intrinsics, Cmplx: Cmplx Intrinsic. * intrinsics, Complex: Complex Intrinsic. * intrinsics, COMPLEX: Fortran Dialect Options. * intrinsics, Conjg: Conjg Intrinsic. * intrinsics, context-sensitive: Context-Sensitive Intrinsicness. * intrinsics, Cos: Cos Intrinsic. * intrinsics, CosD: CosD Intrinsic. * intrinsics, CosH: CosH Intrinsic. * intrinsics, Count: Count Intrinsic. * intrinsics, CPU_Time: CPU_Time Intrinsic. * intrinsics, CShift: CShift Intrinsic. * intrinsics, CSin: CSin Intrinsic. * intrinsics, CSqRt: CSqRt Intrinsic. * intrinsics, CTime <1>: CTime Intrinsic (function). * intrinsics, CTime: CTime Intrinsic (subroutine). * intrinsics, DAbs: DAbs Intrinsic. * intrinsics, DACos: DACos Intrinsic. * intrinsics, DACosD: DACosD Intrinsic. * intrinsics, DASin: DASin Intrinsic. * intrinsics, DASinD: DASinD Intrinsic. * intrinsics, DATan: DATan Intrinsic. * intrinsics, DATan2: DATan2 Intrinsic. * intrinsics, DATan2D: DATan2D Intrinsic. * intrinsics, DATanD: DATanD Intrinsic. * intrinsics, Date: Date Intrinsic. * intrinsics, Date_and_Time: Date_and_Time Intrinsic. * intrinsics, DbesJ0: DbesJ0 Intrinsic. * intrinsics, DbesJ1: DbesJ1 Intrinsic. * intrinsics, DbesJN: DbesJN Intrinsic. * intrinsics, DbesY0: DbesY0 Intrinsic. * intrinsics, DbesY1: DbesY1 Intrinsic. * intrinsics, DbesYN: DbesYN Intrinsic. * intrinsics, Dble: Dble Intrinsic. * intrinsics, DbleQ: DbleQ Intrinsic. * intrinsics, DCmplx: DCmplx Intrinsic. * intrinsics, DConjg: DConjg Intrinsic. * intrinsics, DCos: DCos Intrinsic. * intrinsics, DCosD: DCosD Intrinsic. * intrinsics, DCosH: DCosH Intrinsic. * intrinsics, DDiM: DDiM Intrinsic. * intrinsics, deleted: Intrinsic Groups. * intrinsics, DErF: DErF Intrinsic. * intrinsics, DErFC: DErFC Intrinsic. * intrinsics, DExp: DExp Intrinsic. * intrinsics, DFloat: DFloat Intrinsic. * intrinsics, DFlotI: DFlotI Intrinsic. * intrinsics, DFlotJ: DFlotJ Intrinsic. * intrinsics, Digits: Digits Intrinsic. * intrinsics, DiM: DiM Intrinsic. * intrinsics, DImag: DImag Intrinsic. * intrinsics, DInt: DInt Intrinsic. * intrinsics, disabled: Intrinsic Groups. * intrinsics, DLog: DLog Intrinsic. * intrinsics, DLog10: DLog10 Intrinsic. * intrinsics, DMax1: DMax1 Intrinsic. * intrinsics, DMin1: DMin1 Intrinsic. * intrinsics, DMod: DMod Intrinsic. * intrinsics, DNInt: DNInt Intrinsic. * intrinsics, Dot_Product: Dot_Product Intrinsic. * intrinsics, DProd: DProd Intrinsic. * intrinsics, DReal: DReal Intrinsic. * intrinsics, DSign: DSign Intrinsic. * intrinsics, DSin: DSin Intrinsic. * intrinsics, DSinD: DSinD Intrinsic. * intrinsics, DSinH: DSinH Intrinsic. * intrinsics, DSqRt: DSqRt Intrinsic. * intrinsics, DTan: DTan Intrinsic. * intrinsics, DTanD: DTanD Intrinsic. * intrinsics, DTanH: DTanH Intrinsic. * intrinsics, DTime <1>: DTime Intrinsic (subroutine). * intrinsics, DTime: DTime Intrinsic (function). * intrinsics, enabled: Intrinsic Groups. * intrinsics, EOShift: EOShift Intrinsic. * intrinsics, Epsilon: Epsilon Intrinsic. * intrinsics, ErF: ErF Intrinsic. * intrinsics, ErFC: ErFC Intrinsic. * intrinsics, ETime <1>: ETime Intrinsic (function). * intrinsics, ETime: ETime Intrinsic (subroutine). * intrinsics, Exit: Exit Intrinsic. * intrinsics, Exp: Exp Intrinsic. * intrinsics, Exponent: Exponent Intrinsic. * intrinsics, f2c: Fortran Dialect Options. * intrinsics, FDate <1>: FDate Intrinsic (subroutine). * intrinsics, FDate: FDate Intrinsic (function). * intrinsics, FGet <1>: FGet Intrinsic (subroutine). * intrinsics, FGet: FGet Intrinsic (function). * intrinsics, FGetC <1>: FGetC Intrinsic (function). * intrinsics, FGetC: FGetC Intrinsic (subroutine). * intrinsics, Float: Float Intrinsic. * intrinsics, FloatI: FloatI Intrinsic. * intrinsics, FloatJ: FloatJ Intrinsic. * intrinsics, Floor: Floor Intrinsic. * intrinsics, Flush: Flush Intrinsic. * intrinsics, FNum: FNum Intrinsic. * intrinsics, Fortran 90: Fortran Dialect Options. * intrinsics, FPut <1>: FPut Intrinsic (function). * intrinsics, FPut: FPut Intrinsic (subroutine). * intrinsics, FPutC <1>: FPutC Intrinsic (subroutine). * intrinsics, FPutC: FPutC Intrinsic (function). * intrinsics, Fraction: Fraction Intrinsic. * intrinsics, FSeek: FSeek Intrinsic. * intrinsics, FStat <1>: FStat Intrinsic (subroutine). * intrinsics, FStat: FStat Intrinsic (function). * intrinsics, FTell <1>: FTell Intrinsic (function). * intrinsics, FTell: FTell Intrinsic (subroutine). * intrinsics, generic: Generics and Specifics. * intrinsics, GError: GError Intrinsic. * intrinsics, GetArg <1>: GetArg Intrinsic. * intrinsics, GetArg: Main Program Unit. * intrinsics, GetCWD <1>: GetCWD Intrinsic (function). * intrinsics, GetCWD: GetCWD Intrinsic (subroutine). * intrinsics, GetEnv: GetEnv Intrinsic. * intrinsics, GetGId: GetGId Intrinsic. * intrinsics, GetLog: GetLog Intrinsic. * intrinsics, GetPId: GetPId Intrinsic. * intrinsics, GetUId: GetUId Intrinsic. * intrinsics, GMTime: GMTime Intrinsic. * intrinsics, groups: Intrinsic Groups. * intrinsics, groups of: Intrinsic Groups. * intrinsics, hidden: Intrinsic Groups. * intrinsics, HostNm <1>: HostNm Intrinsic (subroutine). * intrinsics, HostNm: HostNm Intrinsic (function). * intrinsics, Huge: Huge Intrinsic. * intrinsics, IAbs: IAbs Intrinsic. * intrinsics, IAChar: IAChar Intrinsic. * intrinsics, IAnd: IAnd Intrinsic. * intrinsics, IArgC <1>: IArgC Intrinsic. * intrinsics, IArgC: Main Program Unit. * intrinsics, IBClr: IBClr Intrinsic. * intrinsics, IBits: IBits Intrinsic. * intrinsics, IBSet: IBSet Intrinsic. * intrinsics, IChar: IChar Intrinsic. * intrinsics, IDate <1>: IDate Intrinsic (VXT). * intrinsics, IDate: IDate Intrinsic (UNIX). * intrinsics, IDiM: IDiM Intrinsic. * intrinsics, IDInt: IDInt Intrinsic. * intrinsics, IDNInt: IDNInt Intrinsic. * intrinsics, IEOr: IEOr Intrinsic. * intrinsics, IErrNo: IErrNo Intrinsic. * intrinsics, IFix: IFix Intrinsic. * intrinsics, IIAbs: IIAbs Intrinsic. * intrinsics, IIAnd: IIAnd Intrinsic. * intrinsics, IIBClr: IIBClr Intrinsic. * intrinsics, IIBits: IIBits Intrinsic. * intrinsics, IIBSet: IIBSet Intrinsic. * intrinsics, IIDiM: IIDiM Intrinsic. * intrinsics, IIDInt: IIDInt Intrinsic. * intrinsics, IIDNnt: IIDNnt Intrinsic. * intrinsics, IIEOr: IIEOr Intrinsic. * intrinsics, IIFix: IIFix Intrinsic. * intrinsics, IInt: IInt Intrinsic. * intrinsics, IIOr: IIOr Intrinsic. * intrinsics, IIQint: IIQint Intrinsic. * intrinsics, IIQNnt: IIQNnt Intrinsic. * intrinsics, IIShftC: IIShftC Intrinsic. * intrinsics, IISign: IISign Intrinsic. * intrinsics, Imag: Imag Intrinsic. * intrinsics, ImagPart: ImagPart Intrinsic. * intrinsics, IMax0: IMax0 Intrinsic. * intrinsics, IMax1: IMax1 Intrinsic. * intrinsics, IMin0: IMin0 Intrinsic. * intrinsics, IMin1: IMin1 Intrinsic. * intrinsics, IMod: IMod Intrinsic. * intrinsics, Index: Index Intrinsic. * intrinsics, INInt: INInt Intrinsic. * intrinsics, INot: INot Intrinsic. * intrinsics, Int: Int Intrinsic. * intrinsics, Int2: Int2 Intrinsic. * intrinsics, Int8: Int8 Intrinsic. * intrinsics, IOr: IOr Intrinsic. * intrinsics, IRand: IRand Intrinsic. * intrinsics, IsaTty: IsaTty Intrinsic. * intrinsics, IShft: IShft Intrinsic. * intrinsics, IShftC: IShftC Intrinsic. * intrinsics, ISign: ISign Intrinsic. * intrinsics, ITime: ITime Intrinsic. * intrinsics, IZExt: IZExt Intrinsic. * intrinsics, JIAbs: JIAbs Intrinsic. * intrinsics, JIAnd: JIAnd Intrinsic. * intrinsics, JIBClr: JIBClr Intrinsic. * intrinsics, JIBits: JIBits Intrinsic. * intrinsics, JIBSet: JIBSet Intrinsic. * intrinsics, JIDiM: JIDiM Intrinsic. * intrinsics, JIDInt: JIDInt Intrinsic. * intrinsics, JIDNnt: JIDNnt Intrinsic. * intrinsics, JIEOr: JIEOr Intrinsic. * intrinsics, JIFix: JIFix Intrinsic. * intrinsics, JInt: JInt Intrinsic. * intrinsics, JIOr: JIOr Intrinsic. * intrinsics, JIQint: JIQint Intrinsic. * intrinsics, JIQNnt: JIQNnt Intrinsic. * intrinsics, JIShft: JIShft Intrinsic. * intrinsics, JIShftC: JIShftC Intrinsic. * intrinsics, JISign: JISign Intrinsic. * intrinsics, JMax0: JMax0 Intrinsic. * intrinsics, JMax1: JMax1 Intrinsic. * intrinsics, JMin0: JMin0 Intrinsic. * intrinsics, JMin1: JMin1 Intrinsic. * intrinsics, JMod: JMod Intrinsic. * intrinsics, JNInt: JNInt Intrinsic. * intrinsics, JNot: JNot Intrinsic. * intrinsics, JZExt: JZExt Intrinsic. * intrinsics, Kill <1>: Kill Intrinsic (subroutine). * intrinsics, Kill: Kill Intrinsic (function). * intrinsics, Kind: Kind Intrinsic. * intrinsics, LBound: LBound Intrinsic. * intrinsics, Len: Len Intrinsic. * intrinsics, Len_Trim: Len_Trim Intrinsic. * intrinsics, LGe: LGe Intrinsic. * intrinsics, LGt: LGt Intrinsic. * intrinsics, Link <1>: Link Intrinsic (subroutine). * intrinsics, Link: Link Intrinsic (function). * intrinsics, LLe: LLe Intrinsic. * intrinsics, LLt: LLt Intrinsic. * intrinsics, LnBlnk: LnBlnk Intrinsic. * intrinsics, Loc: Loc Intrinsic. * intrinsics, Log: Log Intrinsic. * intrinsics, Log10: Log10 Intrinsic. * intrinsics, Logical: Logical Intrinsic. * intrinsics, Long: Long Intrinsic. * intrinsics, LShift: LShift Intrinsic. * intrinsics, LStat <1>: LStat Intrinsic (subroutine). * intrinsics, LStat: LStat Intrinsic (function). * intrinsics, LTime: LTime Intrinsic. * intrinsics, MatMul: MatMul Intrinsic. * intrinsics, Max: Max Intrinsic. * intrinsics, Max0: Max0 Intrinsic. * intrinsics, Max1: Max1 Intrinsic. * intrinsics, MaxExponent: MaxExponent Intrinsic. * intrinsics, MaxLoc: MaxLoc Intrinsic. * intrinsics, MaxVal: MaxVal Intrinsic. * intrinsics, MClock: MClock Intrinsic. * intrinsics, MClock8: MClock8 Intrinsic. * intrinsics, Merge: Merge Intrinsic. * intrinsics, MIL-STD 1753: Fortran Dialect Options. * intrinsics, Min: Min Intrinsic. * intrinsics, Min0: Min0 Intrinsic. * intrinsics, Min1: Min1 Intrinsic. * intrinsics, MinExponent: MinExponent Intrinsic. * intrinsics, MinLoc: MinLoc Intrinsic. * intrinsics, MinVal: MinVal Intrinsic. * intrinsics, Mod: Mod Intrinsic. * intrinsics, Modulo: Modulo Intrinsic. * intrinsics, MvBits: MvBits Intrinsic. * intrinsics, Nearest: Nearest Intrinsic. * intrinsics, NInt: NInt Intrinsic. * intrinsics, Not: Not Intrinsic. * intrinsics, Or <1>: Bit Operations on Floating-point Data. * intrinsics, Or: Or Intrinsic. * intrinsics, others: Other Intrinsics. * intrinsics, Pack: Pack Intrinsic. * intrinsics, PError: PError Intrinsic. * intrinsics, Precision: Precision Intrinsic. * intrinsics, Present: Present Intrinsic. * intrinsics, Product: Product Intrinsic. * intrinsics, QAbs: QAbs Intrinsic. * intrinsics, QACos: QACos Intrinsic. * intrinsics, QACosD: QACosD Intrinsic. * intrinsics, QASin: QASin Intrinsic. * intrinsics, QASinD: QASinD Intrinsic. * intrinsics, QATan: QATan Intrinsic. * intrinsics, QATan2: QATan2 Intrinsic. * intrinsics, QATan2D: QATan2D Intrinsic. * intrinsics, QATanD: QATanD Intrinsic. * intrinsics, QCos: QCos Intrinsic. * intrinsics, QCosD: QCosD Intrinsic. * intrinsics, QCosH: QCosH Intrinsic. * intrinsics, QDiM: QDiM Intrinsic. * intrinsics, QExp: QExp Intrinsic. * intrinsics, QExt: QExt Intrinsic. * intrinsics, QExtD: QExtD Intrinsic. * intrinsics, QFloat: QFloat Intrinsic. * intrinsics, QInt: QInt Intrinsic. * intrinsics, QLog: QLog Intrinsic. * intrinsics, QLog10: QLog10 Intrinsic. * intrinsics, QMax1: QMax1 Intrinsic. * intrinsics, QMin1: QMin1 Intrinsic. * intrinsics, QMod: QMod Intrinsic. * intrinsics, QNInt: QNInt Intrinsic. * intrinsics, QSin: QSin Intrinsic. * intrinsics, QSinD: QSinD Intrinsic. * intrinsics, QSinH: QSinH Intrinsic. * intrinsics, QSqRt: QSqRt Intrinsic. * intrinsics, QTan: QTan Intrinsic. * intrinsics, QTanD: QTanD Intrinsic. * intrinsics, QTanH: QTanH Intrinsic. * intrinsics, Radix: Radix Intrinsic. * intrinsics, Rand: Rand Intrinsic. * intrinsics, Random_Number: Random_Number Intrinsic. * intrinsics, Random_Seed: Random_Seed Intrinsic. * intrinsics, Range: Range Intrinsic. * intrinsics, Real <1>: REAL() and AIMAG() of Complex. * intrinsics, Real: Real Intrinsic. * intrinsics, RealPart: RealPart Intrinsic. * intrinsics, Rename <1>: Rename Intrinsic (function). * intrinsics, Rename: Rename Intrinsic (subroutine). * intrinsics, Repeat: Repeat Intrinsic. * intrinsics, Reshape: Reshape Intrinsic. * intrinsics, RRSpacing: RRSpacing Intrinsic. * intrinsics, RShift: RShift Intrinsic. * intrinsics, Scale: Scale Intrinsic. * intrinsics, Scan: Scan Intrinsic. * intrinsics, Secnds: Secnds Intrinsic. * intrinsics, Second <1>: Second Intrinsic (subroutine). * intrinsics, Second: Second Intrinsic (function). * intrinsics, Selected_Int_Kind: Selected_Int_Kind Intrinsic. * intrinsics, Selected_Real_Kind: Selected_Real_Kind Intrinsic. * intrinsics, Set_Exponent: Set_Exponent Intrinsic. * intrinsics, Shape: Shape Intrinsic. * intrinsics, Shift: Bit Operations on Floating-point Data. * intrinsics, Short: Short Intrinsic. * intrinsics, Sign: Sign Intrinsic. * intrinsics, Signal <1>: Signal Intrinsic (subroutine). * intrinsics, Signal: Signal Intrinsic (function). * intrinsics, Sin: Sin Intrinsic. * intrinsics, SinD: SinD Intrinsic. * intrinsics, SinH: SinH Intrinsic. * intrinsics, Sleep: Sleep Intrinsic. * intrinsics, Sngl: Sngl Intrinsic. * intrinsics, SnglQ: SnglQ Intrinsic. * intrinsics, Spacing: Spacing Intrinsic. * intrinsics, Spread: Spread Intrinsic. * intrinsics, SqRt: SqRt Intrinsic. * intrinsics, SRand: SRand Intrinsic. * intrinsics, Stat <1>: Stat Intrinsic (function). * intrinsics, Stat: Stat Intrinsic (subroutine). * intrinsics, Sum: Sum Intrinsic. * intrinsics, SymLnk <1>: SymLnk Intrinsic (function). * intrinsics, SymLnk: SymLnk Intrinsic (subroutine). * intrinsics, System <1>: System Intrinsic (function). * intrinsics, System: System Intrinsic (subroutine). * intrinsics, System_Clock: System_Clock Intrinsic. * intrinsics, table of: Table of Intrinsic Functions. * intrinsics, Tan: Tan Intrinsic. * intrinsics, TanD: TanD Intrinsic. * intrinsics, TanH: TanH Intrinsic. * intrinsics, Time <1>: Time Intrinsic (UNIX). * intrinsics, Time: Time Intrinsic (VXT). * intrinsics, Time8: Time8 Intrinsic. * intrinsics, Tiny: Tiny Intrinsic. * intrinsics, Transfer: Transfer Intrinsic. * intrinsics, Transpose: Transpose Intrinsic. * intrinsics, Trim: Trim Intrinsic. * intrinsics, TtyNam <1>: TtyNam Intrinsic (function). * intrinsics, TtyNam: TtyNam Intrinsic (subroutine). * intrinsics, UBound: UBound Intrinsic. * intrinsics, UMask <1>: UMask Intrinsic (subroutine). * intrinsics, UMask: UMask Intrinsic (function). * intrinsics, UNIX: Fortran Dialect Options. * intrinsics, Unlink <1>: Unlink Intrinsic (function). * intrinsics, Unlink: Unlink Intrinsic (subroutine). * intrinsics, Unpack: Unpack Intrinsic. * intrinsics, Verify: Verify Intrinsic. * intrinsics, VXT: Fortran Dialect Options. * intrinsics, XOr: XOr Intrinsic. * intrinsics, ZAbs: ZAbs Intrinsic. * intrinsics, ZCos: ZCos Intrinsic. * intrinsics, ZExp: ZExp Intrinsic. * intrinsics, ZExt: ZExt Intrinsic. * intrinsics, ZLog: ZLog Intrinsic. * intrinsics, ZSin: ZSin Intrinsic. * intrinsics, ZSqRt: ZSqRt Intrinsic. * Introduction: Top. * invalid assembly code: Bug Criteria. * invalid input: Bug Criteria. * IOr intrinsic: IOr Intrinsic. * IOSTAT=: Run-time Library Errors. * IRand intrinsic: IRand Intrinsic. * IsaTty intrinsic: IsaTty Intrinsic. * IShft intrinsic: IShft Intrinsic. * IShftC intrinsic: IShftC Intrinsic. * ISign intrinsic: ISign Intrinsic. * iterative DO: Optimize Options. * ITime intrinsic: ITime Intrinsic. * ix86 floating-point: Floating-point precision. * ix86 FPU stack: Inconsistent Calling Sequences. * IZExt intrinsic: IZExt Intrinsic. * JCB002 program: Generics and Specifics. * JCB003 program: CMPAMBIG. * JIAbs intrinsic: JIAbs Intrinsic. * JIAnd intrinsic: JIAnd Intrinsic. * JIBClr intrinsic: JIBClr Intrinsic. * JIBits intrinsic: JIBits Intrinsic. * JIBSet intrinsic: JIBSet Intrinsic. * JIDiM intrinsic: JIDiM Intrinsic. * JIDInt intrinsic: JIDInt Intrinsic. * JIDNnt intrinsic: JIDNnt Intrinsic. * JIEOr intrinsic: JIEOr Intrinsic. * JIFix intrinsic: JIFix Intrinsic. * JInt intrinsic: JInt Intrinsic. * JIOr intrinsic: JIOr Intrinsic. * JIQint intrinsic: JIQint Intrinsic. * JIQNnt intrinsic: JIQNnt Intrinsic. * JIShft intrinsic: JIShft Intrinsic. * JIShftC intrinsic: JIShftC Intrinsic. * JISign intrinsic: JISign Intrinsic. * JMax0 intrinsic: JMax0 Intrinsic. * JMax1 intrinsic: JMax1 Intrinsic. * JMin0 intrinsic: JMin0 Intrinsic. * JMin1 intrinsic: JMin1 Intrinsic. * JMod intrinsic: JMod Intrinsic. * JNInt intrinsic: JNInt Intrinsic. * JNot intrinsic: JNot Intrinsic. * JZExt intrinsic: JZExt Intrinsic. * keywords, RECURSIVE: RECURSIVE Keyword. * Kill intrinsic <1>: Kill Intrinsic (subroutine). * Kill intrinsic: Kill Intrinsic (function). * Kind intrinsic: Kind Intrinsic. * KIND= notation: Kind Notation. * known causes of trouble: Trouble. * lack of recursion: RECURSIVE Keyword. * language, dialect options: Fortran Dialect Options. * language, features: Direction of Language Development. * language, incorrect use of: What is GNU Fortran?. * large aggregate areas: Known Bugs. * large common blocks: Large Common Blocks. * layout of COMMON blocks: Aligned Data. * LBound intrinsic: LBound Intrinsic. * ld command: What is GNU Fortran?. * ld, can't find _main: Cannot Link Fortran Programs. * ld, can't find strange names: Cannot Link Fortran Programs. * ld, error linking user code: Cannot Link Fortran Programs. * ld, errors: Large Common Blocks. * left angle: Character Set. * left bracket: Character Set. * legacy code: Collected Fortran Wisdom. * Len intrinsic: Len Intrinsic. * Len_Trim intrinsic: Len_Trim Intrinsic. * length of source lines: Fortran Dialect Options. * letters, lowercase: Case Sensitivity. * letters, uppercase: Case Sensitivity. * LGe intrinsic: LGe Intrinsic. * LGt intrinsic: LGt Intrinsic. * libc, non-ANSI or non-default: Strange Behavior at Run Time. * libf2c library: What is GNU Fortran?. * libg2c library: What is GNU Fortran?. * libraries: What is GNU Fortran?. * libraries, containing BLOCK DATA: Block Data and Libraries. * libraries, libf2c: What is GNU Fortran?. * libraries, libg2c: What is GNU Fortran?. * limits, array dimensions: Compiler Limits. * limits, array size: Array Size. * limits, compiler: Compiler Limits. * limits, continuation lines <1>: Compiler Limits. * limits, continuation lines: Continuation Line. * limits, lengths of names <1>: Compiler Limits. * limits, lengths of names: Syntactic Items. * limits, lengths of source lines: Fortran Dialect Options. * limits, multi-dimension arrays: Array Size. * limits, on character-variable length: Character-variable Length. * limits, rank: Compiler Limits. * limits, run-time library: Run-time Environment Limits. * limits, timings <1>: ETime Intrinsic (function). * limits, timings <2>: CPU_Time Intrinsic. * limits, timings <3>: Second Intrinsic (function). * limits, timings <4>: MClock8 Intrinsic. * limits, timings <5>: System_Clock Intrinsic. * limits, timings <6>: ETime Intrinsic (subroutine). * limits, timings <7>: DTime Intrinsic (subroutine). * limits, timings <8>: MClock Intrinsic. * limits, timings <9>: Time8 Intrinsic. * limits, timings <10>: DTime Intrinsic (function). * limits, timings <11>: Second Intrinsic (subroutine). * limits, timings <12>: Time Intrinsic (UNIX). * limits, timings: Secnds Intrinsic. * limits, Y10K <1>: FDate Intrinsic (function). * limits, Y10K <2>: IDate Intrinsic (UNIX). * limits, Y10K <3>: Time Intrinsic (VXT). * limits, Y10K <4>: Date_and_Time Intrinsic. * limits, Y10K: FDate Intrinsic (subroutine). * limits, Y2K: IDate Intrinsic (VXT). * lines: Lines. * lines, continuation: Continuation Line. * lines, length: Fortran Dialect Options. * lines, long: Long Lines. * lines, short: Short Lines. * Link intrinsic <1>: Link Intrinsic (subroutine). * Link intrinsic: Link Intrinsic (function). * linking: What is GNU Fortran?. * linking against non-standard library: Strange Behavior at Run Time. * linking error for user code: Cannot Link Fortran Programs. * linking error, user code: Cannot Link Fortran Programs. * linking with C: Interoperating with C and C++. * linking, errors: Large Common Blocks. * LLe intrinsic: LLe Intrinsic. * LLt intrinsic: LLt Intrinsic. * LnBlnk intrinsic: LnBlnk Intrinsic. * Loc intrinsic: Loc Intrinsic. * local equivalence areas: Local Equivalence Areas. * Log intrinsic: Log Intrinsic. * Log10 intrinsic: Log10 Intrinsic. * logical expressions, comparing: Equivalence Versus Equality. * Logical intrinsic: Logical Intrinsic. * LOGICAL(KIND=1) type: Compiler Types. * LOGICAL(KIND=2) type: Compiler Types. * LOGICAL(KIND=3) type: Compiler Types. * LOGICAL(KIND=6) type: Compiler Types. * LOGICAL*1 support: Popular Non-standard Types. * Long intrinsic: Long Intrinsic. * long source lines: Long Lines. * long time: Timer Wraparounds. * loops, optimizing: Optimize Options. * loops, speeding up: Optimize Options. * loops, unrolling: Optimize Options. * lowercase letters: Case Sensitivity. * LShift intrinsic: LShift Intrinsic. * LStat intrinsic <1>: LStat Intrinsic (function). * LStat intrinsic: LStat Intrinsic (subroutine). * LTime intrinsic: LTime Intrinsic. * machine code: What is GNU Fortran?. * macro options: Shorthand Options. * main program unit, debugging: Main Program Unit. * main(): Main Program Unit. * MAIN__(): Main Program Unit. * Makefile example: Bug Criteria. * MAP statement: STRUCTURE UNION RECORD MAP. * MatMul intrinsic: MatMul Intrinsic. * Max intrinsic: Max Intrinsic. * Max0 intrinsic: Max0 Intrinsic. * Max1 intrinsic: Max1 Intrinsic. * MaxExponent intrinsic: MaxExponent Intrinsic. * maximum number of dimensions: Compiler Limits. * maximum rank: Compiler Limits. * maximum unit number: Large File Unit Numbers. * MaxLoc intrinsic: MaxLoc Intrinsic. * MaxVal intrinsic: MaxVal Intrinsic. * MClock intrinsic: MClock Intrinsic. * MClock8 intrinsic: MClock8 Intrinsic. * memory usage, of compiler: Known Bugs. * Merge intrinsic: Merge Intrinsic. * messages, run-time: Run-time Library Errors. * messages, warning: Warning Options. * messages, warning and error: Warnings and Errors. * mil intrinsics group: Intrinsic Groups. * MIL-STD 1753 <1>: END DO. * MIL-STD 1753 <2>: DO WHILE. * MIL-STD 1753 <3>: MIL-STD 1753. * MIL-STD 1753: Fortran Dialect Options. * Min intrinsic: Min Intrinsic. * Min0 intrinsic: Min0 Intrinsic. * Min1 intrinsic: Min1 Intrinsic. * MinExponent intrinsic: MinExponent Intrinsic. * MinLoc intrinsic: MinLoc Intrinsic. * MinVal intrinsic: MinVal Intrinsic. * mistakes: What is GNU Fortran?. * mistyped functions: Not My Type. * mistyped variables: Not My Type. * Mod intrinsic: Mod Intrinsic. * modifying g77: Overall Options. * Modulo intrinsic: Modulo Intrinsic. * multi-dimension arrays: Array Size. * MvBits intrinsic: MvBits Intrinsic. * MXUNIT: Large File Unit Numbers. * name space: Mangling of Names. * NAMELIST statement: NAMELIST. * naming conflicts: Multiple Definitions of External Names. * naming issues: Mangling of Names. * naming programs: Nothing Happens. * NaN values: Floating-point Exception Handling. * Nearest intrinsic: Nearest Intrinsic. * negative forms of options: Invoking G77. * negative time: Timer Wraparounds. * Netlib <1>: Increasing Precision/Range. * Netlib: C Interfacing Tools. * network file system: Output Assumed To Flush. * new users: Getting Started. * newbies: Getting Started. * NeXTStep problems: NeXTStep Problems. * NFS: Output Assumed To Flush. * NInt intrinsic: NInt Intrinsic. * nonportable conversions: Nonportable Conversions. * Not intrinsic: Not Intrinsic. * nothing happens: Nothing Happens. * null arguments: Ugly Null Arguments. * null byte, trailing: Character and Hollerith Constants. * null CHARACTER strings: Character Type. * number of continuation lines: Continuation Line. * number of dimensions, maximum: Compiler Limits. * number of trips: Loops. * O edit descriptor: I/O. * octal constants: Double Quote Meaning. * omitting arguments: Ugly Null Arguments. * one-trip DO loops: Fortran Dialect Options. * open angle: Character Set. * open bracket: Character Set. * OPEN statement: OPEN CLOSE and INQUIRE Keywords. * optimization, better: Better Optimization. * optimization, for Pentium: Aligned Data. * optimize options: Optimize Options. * options, --driver <1>: News. * options, --driver <2>: Changes. * options, --driver <3>: News. * options, --driver: Changes. * options, -falias-check <1>: Aliasing Assumed To Work. * options, -falias-check: Code Gen Options. * options, -fargument-alias <1>: Code Gen Options. * options, -fargument-alias: Aliasing Assumed To Work. * options, -fargument-noalias <1>: Aliasing Assumed To Work. * options, -fargument-noalias: Code Gen Options. * options, -fbadu77-intrinsics-delete: Fortran Dialect Options. * options, -fbadu77-intrinsics-disable: Fortran Dialect Options. * options, -fbadu77-intrinsics-enable: Fortran Dialect Options. * options, -fbadu77-intrinsics-hide: Fortran Dialect Options. * options, -fcaller-saves: Optimize Options. * options, -fcase-initcap: Fortran Dialect Options. * options, -fcase-lower: Fortran Dialect Options. * options, -fcase-preserve: Fortran Dialect Options. * options, -fcase-strict-lower: Fortran Dialect Options. * options, -fcase-strict-upper: Fortran Dialect Options. * options, -fcase-upper: Fortran Dialect Options. * options, -fdelayed-branch: Optimize Options. * options, -fdollar-ok: Fortran Dialect Options. * options, -femulate-complex: Code Gen Options. * options, -fexpensive-optimizations: Optimize Options. * options, -ff2c-intrinsics-delete: Fortran Dialect Options. * options, -ff2c-intrinsics-disable: Fortran Dialect Options. * options, -ff2c-intrinsics-enable: Fortran Dialect Options. * options, -ff2c-intrinsics-hide: Fortran Dialect Options. * options, -ff2c-library: Code Gen Options. * options, -ff66: Shorthand Options. * options, -ff77: Shorthand Options. * options, -ff90: Fortran Dialect Options. * options, -ff90-intrinsics-delete: Fortran Dialect Options. * options, -ff90-intrinsics-disable: Fortran Dialect Options. * options, -ff90-intrinsics-enable: Fortran Dialect Options. * options, -ff90-intrinsics-hide: Fortran Dialect Options. * options, -ffast-math: Optimize Options. * options, -ffinite-math-only: Optimize Options. * options, -ffixed-line-length-N: Fortran Dialect Options. * options, -ffloat-store: Optimize Options. * options, -fforce-addr: Optimize Options. * options, -fforce-mem: Optimize Options. * options, -ffree-form: Fortran Dialect Options. * options, -fgnu-intrinsics-delete: Fortran Dialect Options. * options, -fgnu-intrinsics-disable: Fortran Dialect Options. * options, -fgnu-intrinsics-enable: Fortran Dialect Options. * options, -fgnu-intrinsics-hide: Fortran Dialect Options. * options, -fGROUP-intrinsics-hide: Overly Convenient Options. * options, -finit-local-zero <1>: Code Gen Options. * options, -finit-local-zero: Overly Convenient Options. * options, -fintrin-case-any: Fortran Dialect Options. * options, -fintrin-case-initcap: Fortran Dialect Options. * options, -fintrin-case-lower: Fortran Dialect Options. * options, -fintrin-case-upper: Fortran Dialect Options. * options, -fmatch-case-any: Fortran Dialect Options. * options, -fmatch-case-initcap: Fortran Dialect Options. * options, -fmatch-case-lower: Fortran Dialect Options. * options, -fmatch-case-upper: Fortran Dialect Options. * options, -fmil-intrinsics-delete: Fortran Dialect Options. * options, -fmil-intrinsics-disable: Fortran Dialect Options. * options, -fmil-intrinsics-enable: Fortran Dialect Options. * options, -fmil-intrinsics-hide: Fortran Dialect Options. * options, -fno-argument-noalias-global <1>: Aliasing Assumed To Work. * options, -fno-argument-noalias-global: Code Gen Options. * options, -fno-automatic <1>: Code Gen Options. * options, -fno-automatic: Overly Convenient Options. * options, -fno-backslash: Fortran Dialect Options. * options, -fno-common: Code Gen Options. * options, -fno-f2c <1>: Avoid f2c Compatibility. * options, -fno-f2c: Code Gen Options. * options, -fno-f77: Shorthand Options. * options, -fno-fixed-form: Fortran Dialect Options. * options, -fno-globals: Code Gen Options. * options, -fno-ident: Code Gen Options. * options, -fno-inline: Optimize Options. * options, -fno-move-all-movables: Optimize Options. * options, -fno-reduce-all-givs: Optimize Options. * options, -fno-rerun-loop-opt: Optimize Options. * options, -fno-second-underscore: Code Gen Options. * options, -fno-silent: Overall Options. * options, -fno-trapping-math: Optimize Options. * options, -fno-ugly: Shorthand Options. * options, -fno-ugly-args: Fortran Dialect Options. * options, -fno-ugly-init: Fortran Dialect Options. * options, -fno-underscoring <1>: Names. * options, -fno-underscoring: Code Gen Options. * options, -fonetrip: Fortran Dialect Options. * options, -fpack-struct: Code Gen Options. * options, -fpcc-struct-return: Code Gen Options. * options, -fpedantic: Warning Options. * options, -fPIC: News. * options, -freg-struct-return: Code Gen Options. * options, -frerun-cse-after-loop: Optimize Options. * options, -fschedule-insns: Optimize Options. * options, -fschedule-insns2: Optimize Options. * options, -fset-g77-defaults: Overall Options. * options, -fshort-double: Code Gen Options. * options, -fsource-case-lower: Fortran Dialect Options. * options, -fsource-case-preserve: Fortran Dialect Options. * options, -fsource-case-upper: Fortran Dialect Options. * options, -fstrength-reduce: Optimize Options. * options, -fsymbol-case-any: Fortran Dialect Options. * options, -fsymbol-case-initcap: Fortran Dialect Options. * options, -fsymbol-case-lower: Fortran Dialect Options. * options, -fsymbol-case-upper: Fortran Dialect Options. * options, -fsyntax-only: Warning Options. * options, -ftypeless-boz: Fortran Dialect Options. * options, -fugly: Shorthand Options. * options, -fugly-assign: Fortran Dialect Options. * options, -fugly-assumed: Fortran Dialect Options. * options, -fugly-comma: Fortran Dialect Options. * options, -fugly-complex: Fortran Dialect Options. * options, -fugly-logint: Fortran Dialect Options. * options, -funix-intrinsics-delete: Fortran Dialect Options. * options, -funix-intrinsics-disable: Fortran Dialect Options. * options, -funix-intrinsics-enable: Fortran Dialect Options. * options, -funix-intrinsics-hide: Fortran Dialect Options. * options, -funroll-all-loops: Optimize Options. * options, -funroll-loops: Optimize Options. * options, -funsafe-math-optimizations: Optimize Options. * options, -fversion: Overall Options. * options, -fvxt: Fortran Dialect Options. * options, -fvxt-intrinsics-delete: Fortran Dialect Options. * options, -fvxt-intrinsics-disable: Fortran Dialect Options. * options, -fvxt-intrinsics-enable: Fortran Dialect Options. * options, -fvxt-intrinsics-hide: Fortran Dialect Options. * options, -fzeros: Code Gen Options. * options, -g: Debugging Options. * options, -I-: Directory Options. * options, -Idir: Directory Options. * options, -malign-double <1>: Optimize Options. * options, -malign-double: Aligned Data. * options, -Nl: Compiler Limits. * options, -Nx: Compiler Limits. * options, -pedantic: Warning Options. * options, -pedantic-errors: Warning Options. * options, -v: G77 and GCC. * options, -W: Warning Options. * options, -w: Warning Options. * options, -Waggregate-return: Warning Options. * options, -Wall: Warning Options. * options, -Wcomment: Warning Options. * options, -Wconversion: Warning Options. * options, -Werror: Warning Options. * options, -Wformat: Warning Options. * options, -Wid-clash-LEN: Warning Options. * options, -Wimplicit: Warning Options. * options, -Wlarger-than-LEN: Warning Options. * options, -Wno-globals: Warning Options. * options, -Wparentheses: Warning Options. * options, -Wredundant-decls: Warning Options. * options, -Wshadow: Warning Options. * options, -Wsurprising: Warning Options. * options, -Wswitch: Warning Options. * options, -Wswitch-default: Warning Options. * options, -Wswitch-enum: Warning Options. * options, -Wtraditional: Warning Options. * options, -Wuninitialized: Warning Options. * options, -Wunused: Warning Options. * options, -x f77-cpp-input: LEX. * options, adding: Adding Options. * options, code generation: Code Gen Options. * options, debugging: Debugging Options. * options, dialect: Fortran Dialect Options. * options, directory search: Directory Options. * options, GNU Fortran command: Invoking G77. * options, macro: Shorthand Options. * options, negative forms: Invoking G77. * options, optimization: Optimize Options. * options, overall: Overall Options. * options, overly convenient: Overly Convenient Options. * options, preprocessor: Preprocessor Options. * options, shorthand: Shorthand Options. * options, warnings: Warning Options. * Or intrinsic <1>: Bit Operations on Floating-point Data. * Or intrinsic: Or Intrinsic. * order of evaluation, side effects: Order of Side Effects. * ordering, array: Arrays. * other intrinsics: Other Intrinsics. * output, flushing: Output Assumed To Flush. * overall options: Overall Options. * overflow: Warning Options. * overlapping arguments: Aliasing Assumed To Work. * overlays: Aliasing Assumed To Work. * overly convenient options: Overly Convenient Options. * overwritten data: Strange Behavior at Run Time. * Pack intrinsic: Pack Intrinsic. * padding: Known Bugs. * parallel processing: Support for Threads. * PARAMETER statement <1>: Old-style PARAMETER Statements. * PARAMETER statement: Intrinsics in PARAMETER Statements. * parameters, unused: Warning Options. * paths, search: Directory Options. * PDB: Portable Unformatted Files. * pedantic compilation: Pedantic Compilation. * Pentium optimizations: Aligned Data. * percent sign: Character Set. * PError intrinsic: PError Intrinsic. * placing initialization statements: Initializing Before Specifying. * POINTER statement: POINTER Statements. * pointers <1>: Kind Notation. * pointers: Ugly Assigned Labels. * Poking the bear: Philosophy of Code Generation. * porting, simplify: Simplify Porting. * pound sign: Character Set. * Precision intrinsic: Precision Intrinsic. * precision, increasing: Increasing Precision/Range. * prefix-radix constants: Fortran Dialect Options. * preprocessor <1>: What is GNU Fortran?. * preprocessor <2>: LEX. * preprocessor <3>: Cpp-style directives. * preprocessor: Overall Options. * preprocessor options: Preprocessor Options. * Present intrinsic: Present Intrinsic. * printing compilation status: Overall Options. * printing main source: Known Bugs. * printing version information <1>: What is GNU Fortran?. * printing version information: Overall Options. * procedures: Procedures. * Product intrinsic: Product Intrinsic. * PROGRAM statement: Main Program Unit. * programs, cc1: What is GNU Fortran?. * programs, cc1plus: What is GNU Fortran?. * programs, compiling: G77 and GCC. * programs, cpp <1>: LEX. * programs, cpp <2>: Overall Options. * programs, cpp <3>: Preprocessor Options. * programs, cpp: What is GNU Fortran?. * programs, f771: What is GNU Fortran?. * programs, ratfor: Overall Options. * programs, speeding up: Faster Programs. * programs, test: Nothing Happens. * projects: Projects. * Q edit descriptor: Q Edit Descriptor. * QAbs intrinsic: QAbs Intrinsic. * QACos intrinsic: QACos Intrinsic. * QACosD intrinsic: QACosD Intrinsic. * QASin intrinsic: QASin Intrinsic. * QASinD intrinsic: QASinD Intrinsic. * QATan intrinsic: QATan Intrinsic. * QATan2 intrinsic: QATan2 Intrinsic. * QATan2D intrinsic: QATan2D Intrinsic. * QATanD intrinsic: QATanD Intrinsic. * QCos intrinsic: QCos Intrinsic. * QCosD intrinsic: QCosD Intrinsic. * QCosH intrinsic: QCosH Intrinsic. * QDiM intrinsic: QDiM Intrinsic. * QExp intrinsic: QExp Intrinsic. * QExt intrinsic: QExt Intrinsic. * QExtD intrinsic: QExtD Intrinsic. * QFloat intrinsic: QFloat Intrinsic. * QInt intrinsic: QInt Intrinsic. * QLog intrinsic: QLog Intrinsic. * QLog10 intrinsic: QLog10 Intrinsic. * QMax1 intrinsic: QMax1 Intrinsic. * QMin1 intrinsic: QMin1 Intrinsic. * QMod intrinsic: QMod Intrinsic. * QNInt intrinsic: QNInt Intrinsic. * QSin intrinsic: QSin Intrinsic. * QSinD intrinsic: QSinD Intrinsic. * QSinH intrinsic: QSinH Intrinsic. * QSqRt intrinsic: QSqRt Intrinsic. * QTan intrinsic: QTan Intrinsic. * QTanD intrinsic: QTanD Intrinsic. * QTanH intrinsic: QTanH Intrinsic. * question mark: Character Set. * questionable instructions: What is GNU Fortran?. * Radix intrinsic: Radix Intrinsic. * Rand intrinsic: Rand Intrinsic. * Random_Number intrinsic: Random_Number Intrinsic. * Random_Seed intrinsic: Random_Seed Intrinsic. * range checking: Code Gen Options. * Range intrinsic: Range Intrinsic. * range, increasing: Increasing Precision/Range. * rank, maximum: Compiler Limits. * ratfor: Overall Options. * Ratfor preprocessor: Overall Options. * READONLY: READONLY Keyword. * reads and writes, scheduling: Aliasing Assumed To Work. * Real intrinsic <1>: Real Intrinsic. * Real intrinsic: REAL() and AIMAG() of Complex. * real part: Ugly Complex Part Extraction. * REAL(KIND=1) type: Compiler Types. * REAL(KIND=2) type: Compiler Types. * REAL*16 support: Full Support for Compiler Types. * RealPart intrinsic: RealPart Intrinsic. * recent versions <1>: News. * recent versions: Changes. * RECORD statement: STRUCTURE UNION RECORD MAP. * recursion, lack of: RECURSIVE Keyword. * RECURSIVE keyword: RECURSIVE Keyword. * reference works: Language. * Rename intrinsic <1>: Rename Intrinsic (function). * Rename intrinsic: Rename Intrinsic (subroutine). * Repeat intrinsic: Repeat Intrinsic. * reporting bugs: Bugs. * reporting compilation status: Overall Options. * Reshape intrinsic: Reshape Intrinsic. * results, inconsistent: Floating-point Errors. * RETURN statement <1>: Alternate Returns. * RETURN statement: Functions. * return type of functions: Functions. * right angle: Character Set. * right bracket: Character Set. * rounding errors: Floating-point Errors. * row-major ordering: Arrays. * RRSpacing intrinsic: RRSpacing Intrinsic. * RShift intrinsic: RShift Intrinsic. * run-time, dynamic allocation: Arbitrary Concatenation. * run-time, initialization: Startup Code. * run-time, library: What is GNU Fortran?. * run-time, options: Code Gen Options. * SAVE statement: Code Gen Options. * saved variables: Variables Assumed To Be Saved. * Scale intrinsic: Scale Intrinsic. * Scan intrinsic: Scan Intrinsic. * scheduling of reads and writes: Aliasing Assumed To Work. * scope <1>: Scope and Classes of Names. * scope: Scope of Names and Labels. * search path: Directory Options. * search paths, for included files: Directory Options. * Secnds intrinsic: Secnds Intrinsic. * Second intrinsic <1>: Second Intrinsic (function). * Second intrinsic: Second Intrinsic (subroutine). * segmentation violation <1>: Strange Behavior at Run Time. * segmentation violation <2>: NeXTStep Problems. * segmentation violation: Stack Overflow. * Selected_Int_Kind intrinsic: Selected_Int_Kind Intrinsic. * Selected_Real_Kind intrinsic: Selected_Real_Kind Intrinsic. * semicolon <1>: Statements Comments Lines. * semicolon: Character Set. * sequence numbers: Better Source Model. * Set_Exponent intrinsic: Set_Exponent Intrinsic. * Shape intrinsic: Shape Intrinsic. * SHARED: READONLY Keyword. * Shift intrinsic: Bit Operations on Floating-point Data. * Short intrinsic: Short Intrinsic. * short source lines: Short Lines. * short time: Timer Wraparounds. * shorthand options: Shorthand Options. * side effects, order of evaluation: Order of Side Effects. * Sign intrinsic: Sign Intrinsic. * signal 11: Signal 11 and Friends. * Signal intrinsic <1>: Signal Intrinsic (subroutine). * Signal intrinsic: Signal Intrinsic (function). * signature of procedures: Procedures. * simplify porting: Simplify Porting. * Sin intrinsic: Sin Intrinsic. * SinD intrinsic: SinD Intrinsic. * SinH intrinsic: SinH Intrinsic. * Sleep intrinsic: Sleep Intrinsic. * Sngl intrinsic: Sngl Intrinsic. * SnglQ intrinsic: SnglQ Intrinsic. * Solaris: Strange Behavior at Run Time. * source code <1>: Case Sensitivity. * source code <2>: What is GNU Fortran?. * source code <3>: Lines. * source code: Source Form. * source file: What is GNU Fortran?. * source file format <1>: Fortran Dialect Options. * source file format <2>: Source Form. * source file format <3>: Lines. * source file format <4>: Case Sensitivity. * source file format: Fortran Dialect Options. * source format <1>: Source Form. * source format: Lines. * source lines, long: Long Lines. * source lines, short: Short Lines. * space <1>: Character Set. * space: Lines. * space, endless printing of: Strange Behavior at Run Time. * space, padding with: Short Lines. * Spacing intrinsic: Spacing Intrinsic. * SPC <1>: Character Set. * SPC: Lines. * speed, of compiler: Known Bugs. * speed, of loops: Optimize Options. * speed, of programs: Faster Programs. * spills of floating-point results: Floating-point Errors. * Spread intrinsic: Spread Intrinsic. * SqRt intrinsic: SqRt Intrinsic. * SRand intrinsic: SRand Intrinsic. * stack, 387 coprocessor: News. * stack, aligned: Aligned Data. * stack, overflow: Stack Overflow. * standard, ANSI FORTRAN 77: Language. * standard, support for: Standard Support. * startup code: Startup Code. * Stat intrinsic <1>: Stat Intrinsic (subroutine). * Stat intrinsic: Stat Intrinsic (function). * statement labels, assigned: Assigned Statement Labels. * statements, ACCEPT: TYPE and ACCEPT I/O Statements. * statements, ASSIGN <1>: Ugly Assigned Labels. * statements, ASSIGN: Assigned Statement Labels. * statements, AUTOMATIC: AUTOMATIC Statement. * statements, BLOCK DATA <1>: Block Data and Libraries. * statements, BLOCK DATA: Multiple Definitions of External Names. * statements, CLOSE: OPEN CLOSE and INQUIRE Keywords. * statements, COMMON <1>: Common Blocks. * statements, COMMON: Multiple Definitions of External Names. * statements, COMPLEX: Complex Variables. * statements, CYCLE: CYCLE and EXIT. * statements, DATA <1>: Code Gen Options. * statements, DATA: Known Bugs. * statements, DECODE: ENCODE and DECODE. * statements, DIMENSION <1>: Adjustable Arrays. * statements, DIMENSION <2>: Arrays. * statements, DIMENSION: Array Bounds Expressions. * statements, DO <1>: Warning Options. * statements, DO: Loops. * statements, ENCODE: ENCODE and DECODE. * statements, ENTRY: Alternate Entry Points. * statements, EQUIVALENCE: Local Equivalence Areas. * statements, EXIT: CYCLE and EXIT. * statements, FORMAT: Expressions in FORMAT Statements. * statements, FUNCTION <1>: Functions. * statements, FUNCTION: Procedures. * statements, GOTO: Assigned Statement Labels. * statements, IMPLICIT CHARACTER*(*): Limitation on Implicit Declarations. * statements, INQUIRE: OPEN CLOSE and INQUIRE Keywords. * statements, MAP: STRUCTURE UNION RECORD MAP. * statements, NAMELIST: NAMELIST. * statements, OPEN: OPEN CLOSE and INQUIRE Keywords. * statements, PARAMETER <1>: Intrinsics in PARAMETER Statements. * statements, PARAMETER: Old-style PARAMETER Statements. * statements, POINTER: POINTER Statements. * statements, PROGRAM: Main Program Unit. * statements, RECORD: STRUCTURE UNION RECORD MAP. * statements, RETURN <1>: Alternate Returns. * statements, RETURN: Functions. * statements, SAVE: Code Gen Options. * statements, separated by semicolon: Statements Comments Lines. * statements, STRUCTURE: STRUCTURE UNION RECORD MAP. * statements, SUBROUTINE <1>: Alternate Returns. * statements, SUBROUTINE: Procedures. * statements, TYPE: TYPE and ACCEPT I/O Statements. * statements, UNION: STRUCTURE UNION RECORD MAP. * STATIC: AUTOMATIC Statement. * static variables: Variables Assumed To Be Saved. * status, compilation: Overall Options. * storage association: Aliasing Assumed To Work. * strings, empty: Character Type. * STRUCTURE statement: STRUCTURE UNION RECORD MAP. * structures: Known Bugs. * submodels: Use Submodel Options. * SUBROUTINE statement <1>: Procedures. * SUBROUTINE statement: Alternate Returns. * subroutines: Alternate Returns. * subscript checking: Code Gen Options. * substring checking: Code Gen Options. * suffixes, file name: Overall Options. * Sum intrinsic: Sum Intrinsic. * support, Alpha: Known Bugs. * support, ELF: News. * support, f77: Backslash in Constants. * support, FORTRAN 77: Standard Support. * support, Fortran 90: Fortran 90 Support. * support, gdb: Debugger Problems. * suppressing warnings: Warning Options. * symbol names <1>: Names. * symbol names: Fortran Dialect Options. * symbol names, scope and classes: Scope and Classes of Names. * symbol names, transforming: Code Gen Options. * symbol names, underscores: Code Gen Options. * SymLnk intrinsic <1>: SymLnk Intrinsic (subroutine). * SymLnk intrinsic: SymLnk Intrinsic (function). * synchronous write errors: Output Assumed To Flush. * syntax checking: Warning Options. * System intrinsic <1>: System Intrinsic (subroutine). * System intrinsic: System Intrinsic (function). * System_Clock intrinsic: System_Clock Intrinsic. * tab character: Tabs. * table of intrinsics: Table of Intrinsic Functions. * Tan intrinsic: Tan Intrinsic. * TanD intrinsic: TanD Intrinsic. * TanH intrinsic: TanH Intrinsic. * test programs: Nothing Happens. * textbooks: Language. * threads: Support for Threads. * Time intrinsic <1>: Time Intrinsic (VXT). * Time intrinsic: Time Intrinsic (UNIX). * Time8 intrinsic: Time8 Intrinsic. * Tiny intrinsic: Tiny Intrinsic. * Toolpack: Increasing Precision/Range. * trailing comma: Ugly Null Arguments. * trailing comment <1>: Trailing Comment. * trailing comment <2>: LEX. * trailing comment: Statements Comments Lines. * trailing null byte: Character and Hollerith Constants. * Transfer intrinsic: Transfer Intrinsic. * transforming symbol names <1>: Names. * transforming symbol names: Code Gen Options. * translation of user programs: What is GNU Fortran?. * Transpose intrinsic: Transpose Intrinsic. * Trim intrinsic: Trim Intrinsic. * trips, number of: Loops. * truncation, of floating-point values: Floating-point Errors. * truncation, of long lines: Long Lines. * TtyNam intrinsic <1>: TtyNam Intrinsic (subroutine). * TtyNam intrinsic: TtyNam Intrinsic (function). * TYPE statement: TYPE and ACCEPT I/O Statements. * types, COMPLEX(KIND=1): Compiler Types. * types, COMPLEX(KIND=2): Compiler Types. * types, constants <1>: Constants. * types, constants <2>: Fortran Dialect Options. * types, constants: Compiler Constants. * types, DOUBLE COMPLEX: Compiler Types. * types, DOUBLE PRECISION: Compiler Types. * types, file: Overall Options. * types, Fortran/C: C Access to Type Information. * types, INTEGER(KIND=1): Compiler Types. * types, INTEGER(KIND=2): Compiler Types. * types, INTEGER(KIND=3): Compiler Types. * types, INTEGER(KIND=6): Compiler Types. * types, INTEGER*2: Popular Non-standard Types. * types, INTEGER*8: Full Support for Compiler Types. * types, LOGICAL(KIND=1): Compiler Types. * types, LOGICAL(KIND=2): Compiler Types. * types, LOGICAL(KIND=3): Compiler Types. * types, LOGICAL(KIND=6): Compiler Types. * types, LOGICAL*1: Popular Non-standard Types. * types, of data: Compiler Types. * types, REAL(KIND=1): Compiler Types. * types, REAL(KIND=2): Compiler Types. * types, REAL*16: Full Support for Compiler Types. * UBound intrinsic: UBound Intrinsic. * ugly features <1>: Shorthand Options. * ugly features: Distensions. * UMask intrinsic <1>: UMask Intrinsic (subroutine). * UMask intrinsic: UMask Intrinsic (function). * undefined behavior: Bug Criteria. * undefined function value: Bug Criteria. * undefined reference (_main): Cannot Link Fortran Programs. * underscore <1>: Character Set. * underscore <2>: Underscores in Symbol Names. * underscore <3>: Mangling of Names. * underscore: Code Gen Options. * unformatted files: Portable Unformatted Files. * uninitialized variables <1>: Variables Assumed To Be Zero. * uninitialized variables <2>: Warning Options. * uninitialized variables: Code Gen Options. * UNION statement: STRUCTURE UNION RECORD MAP. * unit numbers: Large File Unit Numbers. * UNIX f77: Shorthand Options. * UNIX intrinsics: Fortran Dialect Options. * Unlink intrinsic <1>: Unlink Intrinsic (subroutine). * Unlink intrinsic: Unlink Intrinsic (function). * Unpack intrinsic: Unpack Intrinsic. * unrecognized file format: What is GNU Fortran?. * unresolved reference (various): Cannot Link Fortran Programs. * unrolling loops: Optimize Options. * UNSAVE: AUTOMATIC Statement. * unsupported warnings: Warning Options. * unused arguments <1>: Unused Arguments. * unused arguments: Warning Options. * unused dummies: Warning Options. * unused parameters: Warning Options. * unused variables: Warning Options. * uppercase letters: Case Sensitivity. * user-visible changes: Changes. * variables, assumed to be zero: Variables Assumed To Be Zero. * variables, automatic: AUTOMATIC Statement. * variables, initialization of: Code Gen Options. * variables, mistyped: Not My Type. * variables, retaining values across calls: Variables Assumed To Be Saved. * variables, uninitialized <1>: Warning Options. * variables, uninitialized: Code Gen Options. * variables, unused: Warning Options. * Verify intrinsic: Verify Intrinsic. * version information, printing <1>: Overall Options. * version information, printing: What is GNU Fortran?. * versions, recent <1>: Changes. * versions, recent: News. * VXT extensions <1>: VXT Fortran. * VXT extensions: Fortran Dialect Options. * VXT intrinsics: Fortran Dialect Options. * vxtidate_y2kbuggy_0: Year 2000 (Y2K) Problems. * warnings: What is GNU Fortran?. * warnings vs errors: Warnings and Errors. * warnings, all: Warning Options. * warnings, extra: Warning Options. * warnings, global names <1>: Warning Options. * warnings, global names: Code Gen Options. * warnings, implicit declaration: Warning Options. * warnings, suppressing: Warning Options. * warnings, unsupported: Warning Options. * wisdom: Collected Fortran Wisdom. * wraparound: Run-time Environment Limits. * wraparound, timings <1>: Time8 Intrinsic. * wraparound, timings <2>: MClock Intrinsic. * wraparound, timings <3>: MClock8 Intrinsic. * wraparound, timings <4>: Secnds Intrinsic. * wraparound, timings <5>: ETime Intrinsic (function). * wraparound, timings <6>: ETime Intrinsic (subroutine). * wraparound, timings <7>: DTime Intrinsic (subroutine). * wraparound, timings <8>: DTime Intrinsic (function). * wraparound, timings <9>: Second Intrinsic (function). * wraparound, timings <10>: Second Intrinsic (subroutine). * wraparound, timings <11>: CPU_Time Intrinsic. * wraparound, timings <12>: System_Clock Intrinsic. * wraparound, timings: Time Intrinsic (UNIX). * wraparound, Y10K <1>: Date_and_Time Intrinsic. * wraparound, Y10K <2>: IDate Intrinsic (UNIX). * wraparound, Y10K <3>: Time Intrinsic (VXT). * wraparound, Y10K <4>: FDate Intrinsic (function). * wraparound, Y10K: FDate Intrinsic (subroutine). * wraparound, Y2K: IDate Intrinsic (VXT). * writes, flushing: Output Assumed To Flush. * writing code: Collected Fortran Wisdom. * x86 floating-point: Floating-point precision. * x86 FPU stack: Inconsistent Calling Sequences. * XOr intrinsic: XOr Intrinsic. * Y10K compliance <1>: Time Intrinsic (VXT). * Y10K compliance <2>: IDate Intrinsic (UNIX). * Y10K compliance <3>: Year 10000 (Y10K) Problems. * Y10K compliance <4>: Date_and_Time Intrinsic. * Y10K compliance <5>: FDate Intrinsic (subroutine). * Y10K compliance: FDate Intrinsic (function). * Y2K compliance <1>: Year 2000 (Y2K) Problems. * Y2K compliance <2>: Date Intrinsic. * Y2K compliance <3>: IDate Intrinsic (VXT). * Y2K compliance: Y2KBAD. * y2kbuggy: Year 2000 (Y2K) Problems. * Year 10000 compliance <1>: Date_and_Time Intrinsic. * Year 10000 compliance <2>: Year 10000 (Y10K) Problems. * Year 10000 compliance <3>: FDate Intrinsic (subroutine). * Year 10000 compliance <4>: IDate Intrinsic (UNIX). * Year 10000 compliance <5>: FDate Intrinsic (function). * Year 10000 compliance: Time Intrinsic (VXT). * Year 2000 compliance <1>: Year 2000 (Y2K) Problems. * Year 2000 compliance <2>: Date Intrinsic. * Year 2000 compliance <3>: IDate Intrinsic (VXT). * Year 2000 compliance: Y2KBAD. * Z edit descriptor <1>: Fortran 90 Features. * Z edit descriptor: I/O. * ZAbs intrinsic: ZAbs Intrinsic. * ZCos intrinsic: ZCos Intrinsic. * zero byte, trailing: Character and Hollerith Constants. * zero-initialized variables: Variables Assumed To Be Zero. * zero-length CHARACTER: Character Type. * zero-trip DO loops: Fortran Dialect Options. * ZExp intrinsic: ZExp Intrinsic. * ZExt intrinsic: ZExt Intrinsic. * ZLog intrinsic: ZLog Intrinsic. * ZSin intrinsic: ZSin Intrinsic. * ZSqRt intrinsic: ZSqRt Intrinsic.  Tag Table: Node: Top2322 Node: Copying4279 Node: GNU Free Documentation License23479 Node: Contributors45888 Node: Funding49279 Node: Funding GNU Fortran51791 Node: Getting Started53006 Node: What is GNU Fortran?55255 Node: G77 and GCC65143 Node: Invoking G7766346 Node: Option Summary68284 Node: Overall Options73142 Node: Shorthand Options79730 Node: Fortran Dialect Options82027 Node: Warning Options93284 Node: Debugging Options102201 Node: Optimize Options103791 Ref: Optimize Options-Footnote-1109809 Node: Preprocessor Options110502 Node: Directory Options111683 Node: Code Gen Options112995 Node: Environment Variables127902 Node: News128357 Node: Changes183228 Node: Language211627 Node: Direction of Language Development213828 Node: Standard Support220068 Node: No Passing External Assumed-length220789 Node: No Passing Dummy Assumed-length221266 Node: No Pathological Implied-DO221781 Node: No Useless Implied-DO222468 Node: Conformance223199 Node: Notation Used225222 Node: Terms and Concepts229428 Node: Syntactic Items229940 Node: Statements Comments Lines230622 Node: Scope of Names and Labels232487 Node: Characters Lines Sequence232917 Node: Character Set233523 Node: Lines234524 Node: Continuation Line237000 Node: Statements237955 Node: Statement Labels238911 Node: Order239603 Node: INCLUDE240488 Node: Cpp-style directives243260 Node: Data Types and Constants243715 Node: Types247236 Node: Double Notation248325 Node: Star Notation249397 Node: Kind Notation252342 Node: Constants260762 Node: Integer Type262278 Node: Character Type262876 Node: Expressions263640 Node: %LOC()264056 Node: Specification Statements266786 Node: NAMELIST267243 Node: DOUBLE COMPLEX267994 Node: Control Statements268248 Node: DO WHILE268740 Node: END DO269045 Node: Construct Names270052 Node: CYCLE and EXIT270792 Node: Functions and Subroutines273556 Node: %VAL()274202 Node: %REF()275566 Node: %DESCR()277394 Node: Generics and Specifics279527 Node: REAL() and AIMAG() of Complex286729 Node: CMPLX() of DOUBLE PRECISION288562 Node: MIL-STD 1753290288 Node: f77/f2c Intrinsics290630 Node: Table of Intrinsic Functions291200 Node: Abort Intrinsic307912 Node: Abs Intrinsic308176 Node: Access Intrinsic309039 Node: AChar Intrinsic309875 Node: ACos Intrinsic310397 Node: AdjustL Intrinsic310858 Node: AdjustR Intrinsic311183 Node: AImag Intrinsic311509 Node: AInt Intrinsic312314 Node: Alarm Intrinsic312942 Node: All Intrinsic313774 Node: Allocated Intrinsic314086 Node: ALog Intrinsic314415 Node: ALog10 Intrinsic314805 Node: AMax0 Intrinsic315203 Node: AMax1 Intrinsic315688 Node: AMin0 Intrinsic316141 Node: AMin1 Intrinsic316625 Node: AMod Intrinsic317077 Node: And Intrinsic317503 Node: ANInt Intrinsic318009 Node: Any Intrinsic318773 Node: ASin Intrinsic319080 Node: Associated Intrinsic319538 Node: ATan Intrinsic319872 Node: ATan2 Intrinsic320338 Node: BesJ0 Intrinsic320889 Node: BesJ1 Intrinsic321350 Node: BesJN Intrinsic321811 Node: BesY0 Intrinsic322342 Node: BesY1 Intrinsic322804 Node: BesYN Intrinsic323266 Node: Bit_Size Intrinsic323801 Node: BTest Intrinsic324460 Node: CAbs Intrinsic325180 Node: CCos Intrinsic325567 Node: Ceiling Intrinsic325959 Node: CExp Intrinsic326281 Node: Char Intrinsic326673 Node: ChDir Intrinsic (subroutine)327927 Node: ChMod Intrinsic (subroutine)328930 Node: CLog Intrinsic330200 Node: Cmplx Intrinsic330604 Node: Complex Intrinsic331405 Node: Conjg Intrinsic332851 Node: Cos Intrinsic333275 Node: CosH Intrinsic333738 Node: Count Intrinsic334113 Node: CPU_Time Intrinsic334431 Node: CShift Intrinsic335222 Node: CSin Intrinsic335544 Node: CSqRt Intrinsic335936 Node: CTime Intrinsic (subroutine)336346 Node: CTime Intrinsic (function)337101 Node: DAbs Intrinsic337735 Node: DACos Intrinsic338131 Node: DASin Intrinsic338522 Node: DATan Intrinsic338914 Node: DATan2 Intrinsic339307 Node: Date_and_Time Intrinsic339762 Node: DbesJ0 Intrinsic341126 Node: DbesJ1 Intrinsic341519 Node: DbesJN Intrinsic341905 Node: DbesY0 Intrinsic342361 Node: DbesY1 Intrinsic342747 Node: DbesYN Intrinsic343133 Node: Dble Intrinsic343587 Node: DCos Intrinsic344293 Node: DCosH Intrinsic344677 Node: DDiM Intrinsic345067 Node: DErF Intrinsic345499 Node: DErFC Intrinsic345868 Node: DExp Intrinsic346243 Node: Digits Intrinsic346629 Node: DiM Intrinsic346946 Node: DInt Intrinsic347445 Node: DLog Intrinsic347829 Node: DLog10 Intrinsic348214 Node: DMax1 Intrinsic348612 Node: DMin1 Intrinsic349066 Node: DMod Intrinsic349518 Node: DNInt Intrinsic349946 Node: Dot_Product Intrinsic350345 Node: DProd Intrinsic350685 Node: DSign Intrinsic351067 Node: DSin Intrinsic351506 Node: DSinH Intrinsic351891 Node: DSqRt Intrinsic352282 Node: DTan Intrinsic352673 Node: DTanH Intrinsic353058 Node: DTime Intrinsic (subroutine)353462 Node: EOShift Intrinsic354733 Node: Epsilon Intrinsic355072 Node: ErF Intrinsic355396 Node: ErFC Intrinsic355802 Node: ETime Intrinsic (subroutine)356362 Node: ETime Intrinsic (function)357525 Node: Exit Intrinsic358565 Node: Exp Intrinsic359074 Node: Exponent Intrinsic359536 Node: FDate Intrinsic (subroutine)359875 Node: FDate Intrinsic (function)360785 Node: FGet Intrinsic (subroutine)361557 Node: FGetC Intrinsic (subroutine)362394 Node: Float Intrinsic363271 Node: Floor Intrinsic363671 Node: Flush Intrinsic363987 Node: FNum Intrinsic364566 Node: FPut Intrinsic (subroutine)365014 Node: FPutC Intrinsic (subroutine)365811 Node: Fraction Intrinsic366658 Node: FSeek Intrinsic366999 Node: FStat Intrinsic (subroutine)367724 Node: FStat Intrinsic (function)369248 Node: FTell Intrinsic (subroutine)370537 Node: FTell Intrinsic (function)371210 Node: GError Intrinsic371727 Node: GetArg Intrinsic372101 Node: GetCWD Intrinsic (subroutine)372769 Node: GetCWD Intrinsic (function)373624 Node: GetEnv Intrinsic374243 Node: GetGId Intrinsic374830 Node: GetLog Intrinsic375136 Node: GetPId Intrinsic375674 Node: GetUId Intrinsic375982 Node: GMTime Intrinsic376287 Node: HostNm Intrinsic (subroutine)377295 Node: HostNm Intrinsic (function)378384 Node: Huge Intrinsic379226 Node: IAbs Intrinsic379549 Node: IAChar Intrinsic379940 Node: IAnd Intrinsic380480 Node: IArgC Intrinsic380968 Node: IBClr Intrinsic381344 Node: IBits Intrinsic381855 Node: IBSet Intrinsic382569 Node: IChar Intrinsic383071 Node: IDate Intrinsic (UNIX)384290 Node: IDiM Intrinsic385132 Node: IDInt Intrinsic385581 Node: IDNInt Intrinsic385974 Node: IEOr Intrinsic386373 Node: IErrNo Intrinsic386871 Node: IFix Intrinsic387198 Node: Imag Intrinsic387586 Node: ImagPart Intrinsic388591 Node: Index Intrinsic389617 Node: Int Intrinsic390170 Node: Int2 Intrinsic390885 Node: Int8 Intrinsic391594 Node: IOr Intrinsic392303 Node: IRand Intrinsic392783 Node: IsaTty Intrinsic393703 Node: IShft Intrinsic394127 Node: IShftC Intrinsic394957 Node: ISign Intrinsic395886 Node: ITime Intrinsic396336 Node: Kill Intrinsic (subroutine)396738 Node: Kind Intrinsic397574 Node: LBound Intrinsic397899 Node: Len Intrinsic398216 Node: Len_Trim Intrinsic398852 Node: LGe Intrinsic399264 Node: LGt Intrinsic400677 Node: Link Intrinsic (subroutine)401582 Node: LLe Intrinsic402546 Node: LLt Intrinsic403451 Node: LnBlnk Intrinsic404345 Node: Loc Intrinsic404748 Node: Log Intrinsic405179 Node: Log10 Intrinsic405770 Node: Logical Intrinsic406312 Node: Long Intrinsic406635 Node: LShift Intrinsic407159 Node: LStat Intrinsic (subroutine)408195 Node: LStat Intrinsic (function)410006 Node: LTime Intrinsic411568 Node: MatMul Intrinsic412572 Node: Max Intrinsic412890 Node: Max0 Intrinsic413441 Node: Max1 Intrinsic413892 Node: MaxExponent Intrinsic414376 Node: MaxLoc Intrinsic414716 Node: MaxVal Intrinsic415043 Node: MClock Intrinsic415365 Node: MClock8 Intrinsic416263 Node: Merge Intrinsic417451 Node: Min Intrinsic417767 Node: Min0 Intrinsic418318 Node: Min1 Intrinsic418769 Node: MinExponent Intrinsic419253 Node: MinLoc Intrinsic419593 Node: MinVal Intrinsic419920 Node: Mod Intrinsic420239 Node: Modulo Intrinsic420762 Node: MvBits Intrinsic421081 Node: Nearest Intrinsic421947 Node: NInt Intrinsic422271 Node: Not Intrinsic423109 Node: Or Intrinsic423504 Node: Pack Intrinsic424002 Node: PError Intrinsic424312 Node: Precision Intrinsic424766 Node: Present Intrinsic425101 Node: Product Intrinsic425431 Node: Radix Intrinsic425757 Node: Rand Intrinsic426074 Node: Random_Number Intrinsic426961 Node: Random_Seed Intrinsic427314 Node: Range Intrinsic427662 Node: Real Intrinsic427983 Node: RealPart Intrinsic428989 Node: Rename Intrinsic (subroutine)430022 Node: Repeat Intrinsic430993 Node: Reshape Intrinsic431329 Node: RRSpacing Intrinsic431658 Node: RShift Intrinsic431993 Node: Scale Intrinsic432991 Node: Scan Intrinsic433307 Node: Second Intrinsic (function)433631 Node: Second Intrinsic (subroutine)434462 Node: Selected_Int_Kind Intrinsic435437 Node: Selected_Real_Kind Intrinsic435828 Node: Set_Exponent Intrinsic436215 Node: Shape Intrinsic436572 Node: Short Intrinsic436895 Node: Sign Intrinsic437590 Node: Signal Intrinsic (subroutine)438190 Node: Sin Intrinsic440406 Node: SinH Intrinsic440881 Node: Sleep Intrinsic441254 Node: Sngl Intrinsic441596 Node: Spacing Intrinsic441985 Node: Spread Intrinsic442309 Node: SqRt Intrinsic442630 Node: SRand Intrinsic443234 Node: Stat Intrinsic (subroutine)443611 Node: Stat Intrinsic (function)445225 Node: Sum Intrinsic446588 Node: SymLnk Intrinsic (subroutine)446920 Node: System Intrinsic (subroutine)447951 Node: System_Clock Intrinsic448890 Node: Tan Intrinsic450014 Node: TanH Intrinsic450474 Node: Time Intrinsic (UNIX)450856 Node: Time8 Intrinsic451841 Node: Tiny Intrinsic453020 Node: Transfer Intrinsic453335 Node: Transpose Intrinsic453666 Node: Trim Intrinsic454000 Node: TtyNam Intrinsic (subroutine)454330 Node: TtyNam Intrinsic (function)455032 Node: UBound Intrinsic455601 Node: UMask Intrinsic (subroutine)455946 Node: Unlink Intrinsic (subroutine)456643 Node: Unpack Intrinsic457540 Node: Verify Intrinsic457875 Node: XOr Intrinsic458194 Node: ZAbs Intrinsic458710 Node: ZCos Intrinsic459079 Node: ZExp Intrinsic459452 Node: ZLog Intrinsic459825 Node: ZSin Intrinsic460198 Node: ZSqRt Intrinsic460572 Node: Scope and Classes of Names460929 Node: Underscores in Symbol Names461411 Node: I/O461658 Node: Fortran 90 Features462431 Node: Other Dialects465233 Node: Source Form466392 Node: Carriage Returns467607 Node: Tabs467936 Node: Short Lines468809 Node: Long Lines469783 Node: Ampersands470394 Node: Trailing Comment470648 Node: Debug Line471424 Node: Dollar Signs472093 Node: Case Sensitivity472379 Node: VXT Fortran480995 Node: Double Quote Meaning482178 Node: Exclamation Point483106 Node: Fortran 90484149 Node: Pedantic Compilation485201 Node: Distensions489165 Node: Ugly Implicit Argument Conversion490129 Node: Ugly Assumed-Size Arrays490743 Node: Ugly Complex Part Extraction492464 Node: Ugly Null Arguments494086 Node: Ugly Conversion of Initializers495689 Node: Ugly Integer Conversions497454 Node: Ugly Assigned Labels498562 Node: Compiler500493 Node: Compiler Limits501131 Node: Run-time Environment Limits502022 Node: Timer Wraparounds503964 Node: Year 2000 (Y2K) Problems505243 Node: Array Size509749 Node: Character-variable Length510934 Node: Year 10000 (Y10K) Problems511443 Node: Compiler Types511989 Node: Compiler Constants516700 Node: Compiler Intrinsics517559 Node: Intrinsic Groups518486 Node: Other Intrinsics521927 Node: ACosD Intrinsic529525 Node: AIMax0 Intrinsic529806 Node: AIMin0 Intrinsic530115 Node: AJMax0 Intrinsic530425 Node: AJMin0 Intrinsic530735 Node: ASinD Intrinsic531044 Node: ATan2D Intrinsic531350 Node: ATanD Intrinsic531658 Node: BITest Intrinsic531964 Node: BJTest Intrinsic532273 Node: CDAbs Intrinsic532582 Node: CDCos Intrinsic532955 Node: CDExp Intrinsic533330 Node: CDLog Intrinsic533705 Node: CDSin Intrinsic534080 Node: CDSqRt Intrinsic534456 Node: ChDir Intrinsic (function)534849 Node: ChMod Intrinsic (function)535677 Node: CosD Intrinsic536790 Node: DACosD Intrinsic537102 Node: DASinD Intrinsic537410 Node: DATan2D Intrinsic537721 Node: DATanD Intrinsic538035 Node: Date Intrinsic538344 Node: DbleQ Intrinsic539063 Node: DCmplx Intrinsic539367 Node: DConjg Intrinsic540998 Node: DCosD Intrinsic541383 Node: DFloat Intrinsic541689 Node: DFlotI Intrinsic542061 Node: DFlotJ Intrinsic542371 Node: DImag Intrinsic542680 Node: DReal Intrinsic543057 Node: DSinD Intrinsic544204 Node: DTanD Intrinsic544508 Node: DTime Intrinsic (function)544823 Node: FGet Intrinsic (function)546053 Node: FGetC Intrinsic (function)546826 Node: FloatI Intrinsic547642 Node: FloatJ Intrinsic547962 Node: FPut Intrinsic (function)548281 Node: FPutC Intrinsic (function)549017 Node: IDate Intrinsic (VXT)549810 Node: IIAbs Intrinsic550917 Node: IIAnd Intrinsic551227 Node: IIBClr Intrinsic551532 Node: IIBits Intrinsic551841 Node: IIBSet Intrinsic552151 Node: IIDiM Intrinsic552460 Node: IIDInt Intrinsic552766 Node: IIDNnt Intrinsic553075 Node: IIEOr Intrinsic553384 Node: IIFix Intrinsic553689 Node: IInt Intrinsic553992 Node: IIOr Intrinsic554291 Node: IIQint Intrinsic554591 Node: IIQNnt Intrinsic554899 Node: IIShftC Intrinsic555210 Node: IISign Intrinsic555524 Node: IMax0 Intrinsic555834 Node: IMax1 Intrinsic556139 Node: IMin0 Intrinsic556443 Node: IMin1 Intrinsic556747 Node: IMod Intrinsic557050 Node: INInt Intrinsic557350 Node: INot Intrinsic557652 Node: IZExt Intrinsic557952 Node: JIAbs Intrinsic558255 Node: JIAnd Intrinsic558559 Node: JIBClr Intrinsic558864 Node: JIBits Intrinsic559173 Node: JIBSet Intrinsic559483 Node: JIDiM Intrinsic559792 Node: JIDInt Intrinsic560098 Node: JIDNnt Intrinsic560407 Node: JIEOr Intrinsic560716 Node: JIFix Intrinsic561021 Node: JInt Intrinsic561324 Node: JIOr Intrinsic561623 Node: JIQint Intrinsic561923 Node: JIQNnt Intrinsic562231 Node: JIShft Intrinsic562541 Node: JIShftC Intrinsic562852 Node: JISign Intrinsic563166 Node: JMax0 Intrinsic563476 Node: JMax1 Intrinsic563781 Node: JMin0 Intrinsic564085 Node: JMin1 Intrinsic564389 Node: JMod Intrinsic564692 Node: JNInt Intrinsic564992 Node: JNot Intrinsic565294 Node: JZExt Intrinsic565594 Node: Kill Intrinsic (function)565907 Node: Link Intrinsic (function)566588 Node: QAbs Intrinsic567399 Node: QACos Intrinsic567709 Node: QACosD Intrinsic568013 Node: QASin Intrinsic568321 Node: QASinD Intrinsic568627 Node: QATan Intrinsic568935 Node: QATan2 Intrinsic569241 Node: QATan2D Intrinsic569551 Node: QATanD Intrinsic569865 Node: QCos Intrinsic570174 Node: QCosD Intrinsic570475 Node: QCosH Intrinsic570778 Node: QDiM Intrinsic571081 Node: QExp Intrinsic571380 Node: QExt Intrinsic571678 Node: QExtD Intrinsic571977 Node: QFloat Intrinsic572281 Node: QInt Intrinsic572588 Node: QLog Intrinsic572888 Node: QLog10 Intrinsic573188 Node: QMax1 Intrinsic573495 Node: QMin1 Intrinsic573800 Node: QMod Intrinsic574103 Node: QNInt Intrinsic574403 Node: QSin Intrinsic574705 Node: QSinD Intrinsic575005 Node: QSinH Intrinsic575308 Node: QSqRt Intrinsic575612 Node: QTan Intrinsic575915 Node: QTanD Intrinsic576215 Node: QTanH Intrinsic576518 Node: Rename Intrinsic (function)576834 Node: Secnds Intrinsic577638 Node: Signal Intrinsic (function)578237 Node: SinD Intrinsic581068 Node: SnglQ Intrinsic581380 Node: SymLnk Intrinsic (function)581695 Node: System Intrinsic (function)582562 Node: TanD Intrinsic583889 Node: Time Intrinsic (VXT)584206 Node: UMask Intrinsic (function)584960 Node: Unlink Intrinsic (function)585568 Node: ZExt Intrinsic586296 Node: Other Compilers586584 Node: Dropping f2c Compatibility589104 Node: Compilers Other Than f2c592176 Node: Other Languages593974 Node: Interoperating with C and C++594239 Node: C Interfacing Tools595272 Node: C Access to Type Information596200 Node: f2c Skeletons and Prototypes596887 Ref: f2c Skeletons and Prototypes-Footnote-1598334 Node: C++ Considerations598588 Node: Startup Code599255 Node: Debugging and Interfacing604044 Node: Main Program Unit606731 Node: Procedures609225 Node: Functions611883 Node: Names613501 Node: Common Blocks616644 Node: Local Equivalence Areas616908 Node: Complex Variables617892 Node: Arrays619012 Node: Adjustable Arrays622345 Node: Alternate Entry Points625204 Node: Alternate Returns631906 Node: Assigned Statement Labels632807 Node: Run-time Library Errors634652 Node: Collected Fortran Wisdom636604 Node: Advantages Over f2c638040 Node: Language Extensions639021 Node: Diagnostic Abilities640195 Node: Compiler Options640586 Node: Compiler Speed641634 Node: Program Speed642344 Node: Ease of Debugging643929 Node: Character and Hollerith Constants646038 Node: Block Data and Libraries647010 Node: Loops650339 Node: Working Programs655565 Node: Not My Type656309 Node: Variables Assumed To Be Zero658240 Node: Variables Assumed To Be Saved659294 Node: Unwanted Variables660664 Node: Unused Arguments661544 Node: Surprising Interpretations of Code662007 Node: Aliasing Assumed To Work662854 Node: Output Assumed To Flush669052 Node: Large File Unit Numbers671825 Node: Floating-point precision673977 Node: Inconsistent Calling Sequences675238 Node: Overly Convenient Options676218 Node: Faster Programs679524 Node: Aligned Data679970 Node: Prefer Automatic Uninitialized Variables684663 Node: Avoid f2c Compatibility686029 Node: Use Submodel Options686497 Node: Trouble687501 Node: But-bugs688825 Node: Signal 11 and Friends690598 Node: Cannot Link Fortran Programs692678 Node: Large Common Blocks693961 Node: Debugger Problems694387 Node: NeXTStep Problems695102 Node: Stack Overflow696928 Node: Nothing Happens699817 Node: Strange Behavior at Run Time701431 Node: Floating-point Errors703919 Node: Known Bugs709905 Node: Missing Features716971 Node: Better Source Model718898 Node: Fortran 90 Support720667 Node: Intrinsics in PARAMETER Statements721768 Node: Arbitrary Concatenation722519 Node: SELECT CASE on CHARACTER Type722922 Node: RECURSIVE Keyword723209 Node: Increasing Precision/Range723636 Node: Popular Non-standard Types725174 Node: Full Support for Compiler Types725513 Node: Array Bounds Expressions726149 Node: POINTER Statements726596 Node: Sensible Non-standard Constructs727479 Node: READONLY Keyword729805 Node: FLUSH Statement730715 Node: Expressions in FORMAT Statements731085 Node: Explicit Assembler Code732260 Node: Q Edit Descriptor732549 Node: Old-style PARAMETER Statements733053 Node: TYPE and ACCEPT I/O Statements733787 Node: STRUCTURE UNION RECORD MAP734353 Node: OPEN CLOSE and INQUIRE Keywords734839 Node: ENCODE and DECODE735819 Node: AUTOMATIC Statement736914 Node: Suppressing Space Padding738161 Node: Fortran Preprocessor739388 Node: Bit Operations on Floating-point Data739961 Node: Really Ugly Character Assignments740494 Node: POSIX Standard740869 Node: Floating-point Exception Handling741109 Node: Nonportable Conversions742511 Node: Large Automatic Arrays743054 Node: Support for Threads743461 Node: Enabling Debug Lines743886 Node: Better Warnings744263 Node: Gracefully Handle Sensible Bad Code745899 Node: Non-standard Conversions746643 Node: Non-standard Intrinsics746986 Node: Modifying DO Variable747402 Node: Better Pedantic Compilation748078 Node: Warn About Implicit Conversions748706 Node: Invalid Use of Hollerith Constant749293 Node: Dummy Array Without Dimensioning Dummy749836 Node: Invalid FORMAT Specifiers750749 Node: Ambiguous Dialects751150 Node: Unused Labels751561 Node: Informational Messages751783 Node: Uninitialized Variables at Run Time752186 Node: Portable Unformatted Files752792 Ref: Portable Unformatted Files-Footnote-1755748 Node: Better List-directed I/O755776 Node: Default to Console I/O756681 Node: Labels Visible to Debugger757329 Node: Disappointments757730 Node: Mangling of Names758368 Node: Multiple Definitions of External Names759218 Node: Limitation on Implicit Declarations760581 Node: Non-bugs760865 Node: Backslash in Constants761990 Node: Initializing Before Specifying766879 Node: Context-Sensitive Intrinsicness768021 Node: Context-Sensitive Constants769917 Node: Equivalence Versus Equality772873 Node: Order of Side Effects775916 Node: Warnings and Errors777644 Node: Open Questions779042 Node: Bugs779511 Node: Bug Criteria780199 Node: Bug Reporting786436 Node: Service786797 Node: Adding Options787260 Node: Projects791853 Node: Efficiency792696 Node: Better Optimization795593 Node: Simplify Porting798963 Node: More Extensions800718 Node: Machine Model803806 Node: Internals Documentation805092 Node: Internals Improvements805399 Node: Better Diagnostics808943 Node: Front End809860 Node: Overview of Sources810638 Node: Overview of Translation Process817916 Node: g77stripcard822194 Node: lex.c824671 Node: sta.c834211 Node: sti.c834322 Node: stq.c834433 Node: stb.c834544 Node: expr.c834656 Node: stc.c834770 Node: std.c834882 Node: ste.c834993 Node: Gotchas (Transforming)835121 Node: TBD (Transforming)843240 Node: Philosophy of Code Generation845936 Node: Two-pass Design851840 Node: Two-pass Code852997 Node: Why Two Passes853730 Node: Challenges Posed859798 Node: Transforming Statements862282 Node: Statements Needing Temporaries863132 Node: Transforming DO WHILE865896 Node: Transforming Iterative DO867079 Node: Transforming Block IF867908 Node: Transforming SELECT CASE869273 Node: Transforming Expressions872495 Node: Internal Naming Conventions874484 Node: Diagnostics877483 Node: CMPAMBIG878881 Node: EXPIMP885298 Node: INTGLOB886534 Node: LEX888778 Node: GLOBALS894233 Node: LINKFAIL896897 Node: Y2KBAD897521 Node: Keyword Index897871  End Tag Table