This file contains installation information for the GNU Fortran compiler. Copyright (C) 1995, 1996 Free Software Foundation, Inc. You may copy, distribute, and modify it freely as long as you preserve this copyright notice and permission notice. Note most of this information is out of date and superceded by the EGCS install procedures. It is provided for historical reference only. Installing GNU Fortran ********************** The following information describes how to install `g77'. The information in this file generally pertains to dealing with *source* distributions of `g77' and `gcc'. It is possible that some of this information will be applicable to some *binary* distributions of these products--however, since these distributions are not made by the maintainers of `g77', responsibility for binary distributions rests with whoever built and first distributed them. Nevertheless, efforts to make `g77' easier to both build and install from source and package up as a binary distribution are ongoing. Prerequisites ============= The procedures described to unpack, configure, build, and install `g77' assume your system has certain programs already installed. The following prerequisites should be met by your system before you follow the `g77' installation instructions: `gzip' To unpack the `gcc' and `g77' distributions, you'll need the `gunzip' utility in the `gzip' distribution. Most UNIX systems already have `gzip' installed. If yours doesn't, you can get it from the FSF. Note that you'll need `tar' and other utilities as well, but all UNIX systems have these. There are GNU versions of all these available--in fact, a complete GNU UNIX system can be put together on most systems, if desired. The version of GNU `gzip' used to package this release is 1.24. (The version of GNU `tar' used to package this release is 1.11.2.) `gcc-2.7.2.3.tar.gz' You need to have this, or some other applicable, version of `gcc' on your system. The version should be an exact copy of a distribution from the FSF. Its size is approximately 7.1MB. If you've already unpacked `gcc-2.7.2.3.tar.gz' into a directory (named `gcc-2.7.2.3') called the "source tree" for `gcc', you can delete the distribution itself, but you'll need to remember to skip any instructions to unpack this distribution. Without an applicable `gcc' source tree, you cannot build `g77'. You can obtain an FSF distribution of `gcc' from the FSF. `g77-0.5.21.tar.gz' You probably have already unpacked this package, or you are reading an advance copy of these installation instructions, which are contained in this distribution. The size of this package is approximately 1.5MB. You can obtain an FSF distribution of `g77' from the FSF, the same way you obtained `gcc'. Enough disk space The amount of disk space needed to unpack, build, install, and use `g77' depends on the type of system you're using, how you build `g77', and how much of it you install (primarily, which languages you install). The sizes shown below assume all languages distributed in `gcc-2.7.2.3', plus `g77', will be built and installed. These sizes are indicative of GNU/Linux systems on Intel x86 running COFF and on Digital Alpha (AXP) systems running ELF. These should be fairly representative of 32-bit and 64-bit systems, respectively. Note that all sizes are approximate and subject to change without notice! They are based on preliminary releases of g77 made shortly before the public beta release. -- `gcc' and `g77' distributions occupy 8.6MB packed, 35MB unpacked. These consist of the source code and documentation, plus some derived files (mostly documentation), for `gcc' and `g77'. Any deviations from these numbers for different kinds of systems are likely to be very minor. -- A "bootstrap" build requires an additional 67.3MB for a total of 102MB on an ix86, and an additional 98MB for a total of 165MB on an Alpha. -- Removing `gcc/stage1' after the build recovers 10.7MB for a total of 91MB on an ix86, and recovers ??MB for a total of ??MB on an Alpha. After doing this, the integrity of the build can still be verified via `make compare', and the `gcc' compiler modified and used to build itself for testing fairly quickly, using the copy of the compiler kept in `gcc/stage2'. -- Removing `gcc/stage2' after the build further recovers 27.3MB for a total of 64.3MB, and recovers ??MB for a total of ??MB on an Alpha. After doing this, the compiler can still be installed, especially if GNU `make' is used to avoid gratuitous rebuilds (or, the installation can be done by hand). -- Installing `gcc' and `g77' copies 14.9MB onto the `--prefix' disk for a total of 79.2MB on an ix86, and copies ??MB onto the `--prefix' disk for a total of ??MB on an Alpha. After installation, if no further modifications and builds of `gcc' or `g77' are planned, the source and build directory may be removed, leaving the total impact on a system's disk storage as that of the amount copied during installation. Systems with the appropriate version of `gcc' installed don't require the complete bootstrap build. Doing a "straight build" requires about as much space as does a bootstrap build followed by removing both the `gcc/stage1' and `gcc/stage2' directories. Installing `gcc' and `g77' over existing versions might require less *new* disk space, but note that, unlike many products, `gcc' installs itself in a way that avoids overwriting other installed versions of itself, so that other versions may easily be invoked (via `gcc -V VERSION'). So, the amount of space saved as a result of having an existing version of `gcc' and `g77' already installed is not much--typically only the command drivers (`gcc', `g77', `g++', and so on, which are small) and the documentation is overwritten by the new installation. The rest of the new installation is done without replacing existing installed versions (assuming they have different version numbers). `patch' Although you can do everything `patch' does yourself, by hand, without much trouble, having `patch' installed makes installation of new versions of GNU utilities such as `g77' so much easier that it is worth getting. You can obtain `patch' the same way you obtained `gcc' and `g77'. In any case, you can apply patches by hand--patch files are designed for humans to read them. The version of GNU `patch' used to develop this release is 2.4. `make' Your system must have `make', and you will probably save yourself a lot of trouble if it is GNU `make' (sometimes referred to as `gmake'). The version of GNU `make' used to develop this release is 3.73. `cc' Your system must have a working C compiler. *Note Installing GNU CC: (gcc)Installation, for more information on prerequisites for installing `gcc'. `bison' If you do not have `bison' installed, you can usually work around any need for it, since `g77' itself does not use it, and `gcc' normally includes all files generated by running it in its distribution. You can obtain `bison' the same way you obtained `gcc' and `g77'. The version of GNU `bison' used to develop this release is 1.25. *Note Missing bison?::, for information on how to work around not having `bison'. `makeinfo' If you are missing `makeinfo', you can usually work around any need for it. You can obtain `makeinfo' the same way you obtained `gcc' and `g77'. The version of GNU `makeinfo' used to develop this release is 1.68, from GNU `texinfo' version 3.11. *Note Missing makeinfo?::, for information on getting around the lack of `makeinfo'. `sed' All UNIX systems have `sed', but some have a broken version that cannot handle configuring, building, or installing `gcc' or `g77'. The version of GNU `sed' used to develop this release is 2.05. (Note that GNU `sed' version 3.0 was withdrawn by the FSF--if you happen to have this version installed, replace it with version 2.05 immediately. See a GNU distribution site for further explanation.) `root' access or equivalent To perform the complete installation procedures on a system, you need to have `root' access to that system, or equivalent access to the `--prefix' directory tree specified on the `configure' command line. Portions of the procedure (such as configuring and building `g77') can be performed by any user with enough disk space and virtual memory. However, these instructions are oriented towards less-experienced users who want to install `g77' on their own personal systems. System administrators with more experience will want to determine for themselves how they want to modify the procedures described below to suit the needs of their installation. Problems Installing =================== This is a list of problems (and some apparent problems which don't really mean anything is wrong) that show up when configuring, building, installing, or porting GNU Fortran. *Note Installation Problems: (gcc)Installation Problems, for more information on installation problems that can afflict either `gcc' or `g77'. General Problems ---------------- These problems can occur on most or all systems. GNU C Required .............. Compiling `g77' requires GNU C, not just ANSI C. Fixing this wouldn't be very hard (just tedious), but the code using GNU extensions to the C language is expected to be rewritten for 0.6 anyway, so there are no plans for an interim fix. This requirement does not mean you must already have `gcc' installed to build `g77'. As long as you have a working C compiler, you can use a bootstrap build to automate the process of first building `gcc' using the working C compiler you have, then building `g77' and rebuilding `gcc' using that just-built `gcc', and so on. Patching GNU CC Necessary ......................... `g77' currently requires application of a patch file to the gcc compiler tree. The necessary patches should be folded in to the mainline gcc distribution. Some combinations of versions of `g77' and `gcc' might actually *require* no patches, but the patch files will be provided anyway as long as there are more changes expected in subsequent releases. These patch files might contain unnecessary, but possibly helpful, patches. As a result, it is possible this issue might never be resolved, except by eliminating the need for the person configuring `g77' to apply a patch by hand, by going to a more automated approach (such as configure-time patching). Building GNU CC Necessary ......................... It should be possible to build the runtime without building `cc1' and other non-Fortran items, but, for now, an easy way to do that is not yet established. Missing strtoul ............... On SunOS4 systems, linking the `f771' program produces an error message concerning an undefined symbol named `_strtoul'. This is not a `g77' bug. *Note Patching GNU Fortran::, for information on a workaround provided by `g77'. The proper fix is either to upgrade your system to one that provides a complete ANSI C environment, or improve `gcc' so that it provides one for all the languages and configurations it supports. *Note:* In earlier versions of `g77', an automated workaround for this problem was attempted. It worked for systems without `_strtoul', substituting the incomplete-yet-sufficient version supplied with `g77' for those systems. However, the automated workaround failed mysteriously for systems that appeared to have conforming ANSI C environments, and it was decided that, lacking resources to more fully investigate the problem, it was better to not punish users of those systems either by requiring them to work around the problem by hand or by always substituting an incomplete `strtoul()' implementation when their systems had a complete, working one. Unfortunately, this meant inconveniencing users of systems not having `strtoul()', but they're using obsolete (and generally unsupported) systems anyway. Cleanup Kills Stage Directories ............................... It'd be helpful if `g77''s `Makefile.in' or `Make-lang.in' would create the various `stageN' directories and their subdirectories, so developers and expert installers wouldn't have to reconfigure after cleaning up. Missing `gperf'? ................ If a build aborts trying to invoke `gperf', that strongly suggests an improper method was used to create the `gcc' source directory, such as the UNIX `cp -r' command instead of `cp -pr', since this problem very likely indicates that the date-time-modified information on the `gcc' source files is incorrect. The proper solution is to recreate the `gcc' source directory from a `gcc' distribution known to be provided by the FSF. It is possible you might be able to temporarily work around the problem, however, by trying these commands: sh# cd gcc sh# touch c-gperf.h sh# These commands update the date-time-modified information for the file produced by the invocation of `gperf' in the current versions of `gcc', so that `make' no longer believes it needs to update it. This file should already exist in a `gcc' distribution, but mistakes made when copying the `gcc' directory can leave the modification information set such that the `gperf' input files look more "recent" than the corresponding output files. If the above does not work, definitely start from scratch and avoid copying the `gcc' using any method that does not reliably preserve date-time-modified information, such as the UNIX `cp -r' command. Cross-compiler Problems ----------------------- `g77' has been in alpha testing since September of 1992, and in public beta testing since February of 1995. Alpha testing was done by a small number of people worldwide on a fairly wide variety of machines, involving self-compilation in most or all cases. Beta testing has been done primarily via self-compilation, but in more and more cases, cross-compilation (and "criss-cross compilation", where a version of a compiler is built on one machine to run on a second and generate code that runs on a third) has been tried and has succeeded, to varying extents. Generally, `g77' can be ported to any configuration to which `gcc', `f2c', and `libf2c' can be ported and made to work together, aside from the known problems described in this manual. If you want to port `g77' to a particular configuration, you should first make sure `gcc' and `libf2c' can be ported to that configuration before focusing on `g77', because `g77' is so dependent on them. Even for cases where `gcc' and `libf2c' work, you might run into problems with cross-compilation on certain machines, for several reasons. * There is one known bug (a design bug to be fixed in 0.6) that prevents configuration of `g77' as a cross-compiler in some cases, though there are assumptions made during configuration that probably make doing non-self-hosting builds a hassle, requiring manual intervention. * `gcc' might still have some trouble being configured for certain combinations of machines. For example, it might not know how to handle floating-point constants. * Improvements to the way `libf2c' is built could make building `g77' as a cross-compiler easier--for example, passing and using `$(LD)' and `$(AR)' in the appropriate ways. * There are still some challenges putting together the right run-time libraries (needed by `libf2c') for a target system, depending on the systems involved in the configuration. (This is a general problem with cross-compilation, and with `gcc' in particular.) Changing Settings Before Building ================================= Here are some internal `g77' settings that can be changed by editing source files in `gcc/f/' before building. This information, and perhaps even these settings, represent stop-gap solutions to problems people doing various ports of `g77' have encountered. As such, none of the following information is expected to be pertinent in future versions of `g77'. Larger File Unit Numbers ------------------------ 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 `f/runtime/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. Always Flush Output ------------------- 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). `libf2c' supports flagging write errors immediately when it is built with the `ALWAYS_FLUSH' macro defined. This results in a `libf2c' 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 `libf2c' is built with the `ALWAYS_FLUSH' macro defined, enabling this behavior. To do this, find this line in `f/runtime/configure.in' in your `g77' source tree: dnl AC_DEFINE(ALWAYS_FLUSH) Remove the leading `dnl ', so the line begins with `AC_DEFINE(', and run `autoconf' in that file's directory. (Or, if you don't have `autoconf', you can modify `f2c.h.in' in the same directory to include the line `#define ALWAYS_FLUSH' after `#define F2C_INCLUDE'.) Then build or rebuild `g77' as appropriate. Maximum Stackable Size ---------------------- `g77', on most machines, puts many variables and arrays on the stack where possible, and can be configured (by changing `FFECOM_sizeMAXSTACKITEM' in `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. Floating-point Bit Patterns --------------------------- The `g77' build will crash if an attempt is made to build it as a cross-compiler for a target when `g77' cannot reliably determine the bit pattern of floating-point constants for the target. Planned improvements for g77-0.6 will give it the capabilities it needs to not have to crash the build but rather generate correct code for the target. (Currently, `g77' would generate bad code under such circumstances if it didn't crash during the build, e.g. when compiling a source file that does something like `EQUIVALENCE (I,R)' and `DATA R/9.43578/'.) Initialization of Large Aggregate Areas --------------------------------------- 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/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. Alpha Problems Fixed -------------------- `g77' used to warn when it was used to compile Fortran code for a target configuration that is not basically a 32-bit machine (such as an Alpha, which is a 64-bit machine, especially if it has a 64-bit operating system running on it). That was because `g77' was known to not work properly on such configurations. As of version 0.5.20, `g77' is believed to work well enough on such systems. So, the warning is no longer needed or provided. However, support for 64-bit systems, especially in areas such as cross-compilation and handling of intrinsics, is still incomplete. The symptoms are believed to be compile-time diagnostics rather than the generation of bad code. It is hoped that version 0.6 will completely support 64-bit systems. Quick Start =========== This procedure configures, builds, and installs `g77' "out of the box" and works on most UNIX systems. Each command is identified by a unique number, used in the explanatory text that follows. For the most part, the output of each command is not shown, though indications of the types of responses are given in a few cases. To perform this procedure, the installer must be logged in as user `root'. Much of it can be done while not logged in as `root', and users experienced with UNIX administration should be able to modify the procedure properly to do so. Following traditional UNIX conventions, it is assumed that the source trees for `g77' and `gcc' will be placed in `/usr/src'. It also is assumed that the source distributions themselves already reside in `/usr/FSF', a naming convention used by the author of `g77' on his own system: /usr/FSF/gcc-2.7.2.3.tar.gz /usr/FSF/g77-0.5.21.tar.gz Users of the following systems should not blindly follow these quick-start instructions, because of problems their systems have coping with straightforward installation of `g77': * SunOS4 Instead, see *Note Complete Installation::, for detailed information on how to configure, build, and install `g77' for your particular system. Also, see *Note Known Causes of Trouble with GNU Fortran: Trouble, for information on bugs and other problems known to afflict the installation process, and how to report newly discovered ones. If your system is *not* on the above list, and *is* a UNIX system or one of its variants, you should be able to follow the instructions below. If you vary *any* of the steps below, you might run into trouble, including possibly breaking existing programs for other users of your system. Before doing so, it is wise to review the explanations of some of the steps. These explanations follow this list of steps. sh[ 1]# cd /usr/src sh[ 2]# gunzip -c < /usr/FSF/gcc-2.7.2.3.tar.gz | tar xf - [Might say "Broken pipe"...that is normal on some systems.] sh[ 3]# gunzip -c < /usr/FSF/g77-0.5.21.tar.gz | tar xf - ["Broken pipe" again possible.] sh[ 4]# ln -s gcc-2.7.2.3 gcc sh[ 5]# ln -s g77-0.5.21 g77 sh[ 6]# mv -i g77/* gcc [No questions should be asked by mv here; or, you made a mistake.] sh[ 7]# patch -p1 -V t -d gcc < gcc/f/gbe/2.7.2.3.diff [Unless patch complains about rejected patches, this step worked.] sh[ 8]# cd gcc sh[ 9]# touch f77-install-ok [Do not do the above if your system already has an f77 command, unless you've checked that overwriting it is okay.] sh[10]# touch f2c-install-ok [Do not do the above if your system already has an f2c command, unless you've checked that overwriting it is okay. Else, touch f2c-exists-ok.] sh[11]# ./configure --prefix=/usr [Do not do the above if gcc is not installed in /usr/bin. You might need a different --prefix=..., as described below.] sh[12]# make bootstrap [This takes a long time, and is where most problems occur.] sh[13]# make compare [This verifies that the compiler is `sane'. Only the file `f/zzz.o' (aka `tmp-foo1' and `tmp-foo2') should be in the list of object files this command prints as having different contents. If other files are printed, you have likely found a g77 bug.] sh[14]# rm -fr stage1 sh[15]# make -k install [The actual installation.] sh[16]# g77 -v [Verify that g77 is installed, obtain version info.] sh[17]# *Note Updating Your Info Directory: Updating Documentation, for information on how to update your system's top-level `info' directory to contain a reference to this manual, so that users of `g77' can easily find documentation instead of having to ask you for it. Elaborations of many of the above steps follows: Step 1: `cd /usr/src' You can build `g77' pretty much anyplace. By convention, this manual assumes `/usr/src'. It might be helpful if other users on your system knew where to look for the source code for the installed version of `g77' and `gcc' in any case. Step 3: `gunzip -d < /usr/FSF/g77-0.5.21.tar.gz | tar xf -' It is not always necessary to obtain the latest version of `g77' as a complete `.tar.gz' file if you have a complete, earlier distribution of `g77'. If appropriate, you can unpack that earlier version of `g77', and then apply the appropriate patches to achieve the same result--a source tree containing version 0.5.21 of `g77'. Step 4: `ln -s gcc-2.7.2.3 gcc' Step 5: `ln -s g77-0.5.21 g77' These commands mainly help reduce typing, and help reduce visual clutter in examples in this manual showing what to type to install `g77'. *Note Unpacking::, for information on using distributions of `g77' made by organizations other than the FSF. Step 6: `mv -i g77/* gcc' After doing this, you can, if you like, type `rm g77' and `rmdir g77-0.5.21' to remove the empty directory and the symbol link to it. But, it might be helpful to leave them around as quick reminders of which version(s) of `g77' are installed on your system. *Note Unpacking::, for information on the contents of the `g77' directory (as merged into the `gcc' directory). Step 7: `patch -p1 ...' This can produce a wide variety of printed output, from `Hmm, I can't seem to find a patch in there anywhere...' to long lists of messages indicated that patches are being found, applied successfully, and so on. If messages about "fuzz", "offset", or especially "reject files" are printed, it might mean you applied the wrong patch file. If you believe this is the case, it is best to restart the sequence after deleting (or at least renaming to unused names) the top-level directories for `g77' and `gcc' and their symbolic links. After this command finishes, the `gcc' directory might have old versions of several files as saved by `patch'. To remove these, after `cd gcc', type `rm -i *.~*~'. *Note Merging Distributions::, for more information. Step 9: `touch f77-install-ok' Don't do this if you don't want to overwrite an existing version of `f77' (such as a native compiler, or a script that invokes `f2c'). Otherwise, installation will overwrite the `f77' command and the `f77' man pages with copies of the corresponding `g77' material. *Note Installing `f77': Installing f77, for more information. Step 10: `touch f2c-install-ok' Don't do this if you don't want to overwrite an existing installation of `libf2c' (though, chances are, you do). Instead, `touch f2c-exists-ok' to allow the installation to continue without any error messages about `/usr/lib/libf2c.a' already existing. *Note Installing `f2c': Installing f2c, for more information. Step 11: `./configure --prefix=/usr' This is where you specify that the `g77' executable is to be installed in `/usr/bin/', the `libf2c.a' library is to be installed in `/usr/lib/', and so on. You should ensure that any existing installation of the `gcc' executable is in `/usr/bin/'. Otherwise, installing `g77' so that it does not fully replace the existing installation of `gcc' is likely to result in the inability to compile Fortran programs. *Note Where in the World Does Fortran (and GNU CC) Go?: Where to Install, for more information on determining where to install `g77'. *Note Configuring gcc::, for more information on the configuration process triggered by invoking the `./configure' script. Step 12: `make bootstrap' *Note Installing GNU CC: (gcc)Installation, for information on the kinds of diagnostics you should expect during this procedure. *Note Building gcc::, for complete `g77'-specific information on this step. Step 13: `make compare' *Note Where to Port Bugs: Bug Lists, for information on where to report that you observed more than `f/zzz.o' having different contents during this phase. *Note How to Report Bugs: Bug Reporting, for information on *how* to report bugs like this. Step 14: `rm -fr stage1' You don't need to do this, but it frees up disk space. Step 15: `make -k install' If this doesn't seem to work, try: make -k install install-libf77 install-f2c-all *Note Installation of Binaries::, for more information. *Note Updating Your Info Directory: Updating Documentation, for information on entering this manual into your system's list of texinfo manuals. Step 16: `g77 -v' If this command prints approximately 25 lines of output, including the GNU Fortran Front End version number (which should be the same as the version number for the version of `g77' you just built and installed) and the version numbers for the three parts of the `libf2c' library (`libF77', `libI77', `libU77'), and those version numbers are all in agreement, then there is a high likelihood that the installation has been successfully completed. You might consider doing further testing. For example, log in as a non-privileged user, then create a small Fortran program, such as: PROGRAM SMTEST DO 10 I=1, 10 PRINT *, 'Hello World #', I 10 CONTINUE END Compile, link, and run the above program, and, assuming you named the source file `smtest.f', the session should look like this: sh# g77 -o smtest smtest.f sh# ./smtest Hello World # 1 Hello World # 2 Hello World # 3 Hello World # 4 Hello World # 5 Hello World # 6 Hello World # 7 Hello World # 8 Hello World # 9 Hello World # 10 sh# After proper installation, you don't need to keep your gcc and g77 source and build directories around anymore. Removing them can free up a lot of disk space. Complete Installation ===================== Here is the complete `g77'-specific information on how to configure, build, and install `g77'. Unpacking --------- The `gcc' source distribution is a stand-alone distribution. It is designed to be unpacked (producing the `gcc' source tree) and built as is, assuming certain prerequisites are met (including the availability of compatible UNIX programs such as `make', `cc', and so on). However, before building `gcc', you will want to unpack and merge the `g77' distribution in with it, so that you build a Fortran-capable version of `gcc', which includes the `g77' command, the necessary run-time libraries, and this manual. Unlike `gcc', the `g77' source distribution is *not* a stand-alone distribution. It is designed to be unpacked and, afterwards, immediately merged into an applicable `gcc' source tree. That is, the `g77' distribution *augments* a `gcc' distribution--without `gcc', generally only the documentation is immediately usable. A sequence of commands typically used to unpack `gcc' and `g77' is: sh# cd /usr/src sh# gunzip -c /usr/FSF/gcc-2.7.2.3.tar.gz | tar xf - sh# gunzip -c /usr/FSF/g77-0.5.21.tar.gz | tar xf - sh# ln -s gcc-2.7.2.3 gcc sh# ln -s g77-0.5.21 g77 sh# mv -i g77/* gcc *Notes:* The commands beginning with `gunzip...' might print `Broken pipe...' as they complete. That is nothing to worry about, unless you actually *hear* a pipe breaking. The `ln' commands are helpful in reducing typing and clutter in installation examples in this manual. Hereafter, the top level of `gcc' source tree is referred to as `gcc', and the top level of just the `g77' source tree (prior to issuing the `mv' command, above) is referred to as `g77'. There are three top-level names in a `g77' distribution: g77/COPYING.g77 g77/README.g77 g77/f All three entries should be moved (or copied) into a `gcc' source tree (typically named after its version number and as it appears in the FSF distributions--e.g. `gcc-2.7.2.3'). `g77/f' is the subdirectory containing all of the code, documentation, and other information that is specific to `g77'. The other two files exist to provide information on `g77' to someone encountering a `gcc' source tree with `g77' already present, who has not yet read these installation instructions and thus needs help understanding that the source tree they are looking at does not come from a single FSF distribution. They also help people encountering an unmerged `g77' source tree for the first time. *Note:* Please use *only* `gcc' and `g77' source trees as distributed by the FSF. Use of modified versions, such as the Pentium-specific-optimization port of `gcc', is likely to result in problems that appear to be in the `g77' code but, in fact, are not. Do not use such modified versions unless you understand all the differences between them and the versions the FSF distributes--in which case you should be able to modify the `g77' (or `gcc') source trees appropriately so `g77' and `gcc' can coexist as they do in the stock FSF distributions. Merging Distributions --------------------- After merging the `g77' source tree into the `gcc' source tree, the final merge step is done by applying the pertinent patches the `g77' distribution provides for the `gcc' source tree. Read the file `gcc/f/gbe/README', and apply the appropriate patch file for the version of the GNU CC compiler you have, if that exists. If the directory exists but the appropriate file does not exist, you are using either an old, unsupported version, or a release one that is newer than the newest `gcc' version supported by the version of `g77' you have. As of version 0.5.18, `g77' modifies the version number of `gcc' via the pertinent patches. This is done because the resulting version of `gcc' is deemed sufficiently different from the vanilla distribution to make it worthwhile to present, to the user, information signaling the fact that there are some differences. GNU version numbers make it easy to figure out whether a particular version of a distribution is newer or older than some other version of that distribution. The format is, generally, MAJOR.MINOR.PATCH, with each field being a decimal number. (You can safely ignore leading zeros; for example, 1.5.3 is the same as 1.5.03.) The MAJOR field only increases with time. The other two fields are reset to 0 when the field to their left is incremented; otherwise, they, too, only increase with time. So, version 2.6.2 is newer than version 2.5.8, and version 3.0 is newer than both. (Trailing `.0' fields often are omitted in announcements and in names for distributions and the directories they create.) If your version of `gcc' is older than the oldest version supported by `g77' (as casually determined by listing the contents of `gcc/f/gbe/'), you should obtain a newer, supported version of `gcc'. (You could instead obtain an older version of `g77', or try and get your `g77' to work with the old `gcc', but neither approach is recommended, and you shouldn't bother reporting any bugs you find if you take either approach, because they're probably already fixed in the newer versions you're not using.) If your version of `gcc' is newer than the newest version supported by `g77', it is possible that your `g77' will work with it anyway. If the version number for `gcc' differs only in the PATCH field, you might as well try applying the `g77' patch that is for the newest version of `gcc' having the same MAJOR and MINOR fields, as this is likely to work. So, for example, if a particular version of `g77' has support for `gcc' versions 2.7.0 and 2.7.1, it is likely that `gcc-2.7.2' would work well with `g77' by using the `2.7.1.diff' patch file provided with `g77' (aside from some offsets reported by `patch', which usually are harmless). However, `gcc-2.8.0' would almost certainly not work with that version of `g77' no matter which patch file was used, so a new version of `g77' would be needed (and you should wait for it rather than bothering the maintainers--*note User-Visible Changes: Changes.). This complexity is the result of `gcc' and `g77' being separate distributions. By keeping them separate, each product is able to be independently improved and distributed to its user base more frequently. However, `g77' often requires changes to contemporary versions of `gcc'. Also, the GBE interface defined by `gcc' typically undergoes some incompatible changes at least every time the MINOR field of the version number is incremented, and such changes require corresponding changes to the `g77' front end (FFE). It is hoped that the GBE interface, and the `gcc' and `g77' products in general, will stabilize sufficiently for the need for hand-patching to disappear. Invoking `patch' as described in `gcc/f/gbe/README' can produce a wide variety of printed output, from `Hmm, I can't seem to find a patch in there anywhere...' to long lists of messages indicated that patches are being found, applied successfully, and so on. If messages about "fuzz", "offset", or especially "reject files" are printed, it might mean you applied the wrong patch file. If you believe this is the case, it is best to restart the sequence after deleting (or at least renaming to unused names) the top-level directories for `g77' and `gcc' and their symbolic links. That is because `patch' might have partially patched some `gcc' source files, so reapplying the correct patch file might result in the correct patches being applied incorrectly (due to the way `patch' necessarily works). After `patch' finishes, the `gcc' directory might have old versions of several files as saved by `patch'. To remove these, after `cd gcc', type `rm -i *.~*~'. *Note:* `g77''s configuration file `gcc/f/config-lang.in' ensures that the source code for the version of `gcc' being configured has at least one indication of being patched as required specifically by `g77'. This configuration-time checking should catch failure to apply the correct patch and, if so caught, should abort the configuration with an explanation. *Please* do not try to disable the check, otherwise `g77' might well appear to build and install correctly, and even appear to compile correctly, but could easily produce broken code. `diff -rcp2N' is used to create the patch files in `gcc/f/gbe/'. Installing `f77' ---------------- You should decide whether you want installation of `g77' to also install an `f77' command. On systems with a native `f77', this is not normally desired, so `g77' does not do this by default. If you want `f77' installed, create the file `f77-install-ok' (e.g. via the UNIX command `touch f77-install-ok') in the source or build top-level directory (the same directory in which the `g77' `f' directory resides, not the `f' directory itself), or edit `gcc/f/Make-lang.in' and change the definition of the `F77_INSTALL_FLAG' macro appropriately. Usually, this means that, after typing `cd gcc', you would type `touch f77-install-ok'. When you enable installation of `f77', either a link to or a direct copy of the `g77' command is made. Similarly, `f77.1' is installed as a man page. (The `uninstall' target in the `gcc/Makefile' also tests this macro and file, when invoked, to determine whether to delete the installed copies of `f77' and `f77.1'.) *Note:* No attempt is yet made to install a program (like a shell script) that provides compatibility with any other `f77' programs. Only the most rudimentary invocations of `f77' will work the same way with `g77'. Installing `f2c' ---------------- Currently, `g77' does not include `f2c' itself in its distribution. However, it does include a modified version of the `libf2c'. This version is normally compatible with `f2c', but has been modified to meet the needs of `g77' in ways that might possibly be incompatible with some versions or configurations of `f2c'. Decide how installation of `g77' should affect any existing installation of `f2c' on your system. If you do not have `f2c' on your system (e.g. no `/usr/bin/f2c', no `/usr/include/f2c.h', and no `/usr/lib/libf2c.a', `/usr/lib/libF77.a', or `/usr/lib/libI77.a'), you don't need to be concerned with this item. If you do have `f2c' on your system, you need to decide how users of `f2c' will be affected by your installing `g77'. Since `g77' is currently designed to be object-code-compatible with `f2c' (with very few, clear exceptions), users of `f2c' might want to combine `f2c'-compiled object files with `g77'-compiled object files in a single executable. To do this, users of `f2c' should use the same copies of `f2c.h' and `libf2c.a' that `g77' uses (and that get built as part of `g77'). If you do nothing here, the `g77' installation process will not overwrite the `include/f2c.h' and `lib/libf2c.a' files with its own versions, and in fact will not even install `libf2c.a' for use with the newly installed versions of `gcc' and `g77' if it sees that `lib/libf2c.a' exists--instead, it will print an explanatory message and skip this part of the installation. To install `g77''s versions of `f2c.h' and `libf2c.a' in the appropriate places, create the file `f2c-install-ok' (e.g. via the UNIX command `touch f2c-install-ok') in the source or build top-level directory (the same directory in which the `g77' `f' directory resides, not the `f' directory itself), or edit `gcc/f/Make-lang.in' and change the definition of the `F2C_INSTALL_FLAG' macro appropriately. Usually, this means that, after typing `cd gcc', you would type `touch f2c-install-ok'. Make sure that when you enable the overwriting of `f2c.h' and `libf2c.a' as used by `f2c', you have a recent and properly configured version of `bin/f2c' so that it generates code that is compatible with `g77'. If you don't want installation of `g77' to overwrite `f2c''s existing installation, but you do want `g77' installation to proceed with installation of its own versions of `f2c.h' and `libf2c.a' in places where `g77' will pick them up (even when linking `f2c'-compiled object files--which might lead to incompatibilities), create the file `f2c-exists-ok' (e.g. via the UNIX command `touch f2c-exists-ok') in the source or build top-level directory, or edit `gcc/f/Make-lang.in' and change the definition of the `F2CLIBOK' macro appropriately. Patching GNU Fortran -------------------- If you're using a SunOS4 system, you'll need to make the following change to `gcc/f/proj.h': edit the line reading #define FFEPROJ_STRTOUL 1 ... by replacing the `1' with `0'. Or, you can avoid editing the source by adding CFLAGS='-DFFEPROJ_STRTOUL=0 -g -O' to the command line for `make' when you invoke it. (`-g' is the default for `CFLAGS'.) This causes a minimal version of `strtoul()' provided as part of the `g77' distribution to be compiled and linked into whatever `g77' programs need it, since some systems (like SunOS4 with only the bundled compiler and its runtime) do not provide this function in their system libraries. Similarly, a minimal version of `bsearch()' is available and can be enabled by editing a line similar to the one for `strtoul()' above in `gcc/f/proj.h', if your system libraries lack `bsearch()'. The method of overriding `X_CFLAGS' may also be used. These are not problems with `g77', which requires an ANSI C environment. You should upgrade your system to one that provides a full ANSI C environment, or encourage the maintainers of `gcc' to provide one to all `gcc'-based compilers in future `gcc' distributions. *Note Problems Installing::, for more information on why `strtoul()' comes up missing and on approaches to dealing with this problem that have already been tried. Where in the World Does Fortran (and GNU CC) Go? ------------------------------------------------ Before configuring, you should make sure you know where you want the `g77' and `gcc' binaries to be installed after they're built, because this information is given to the configuration tool and used during the build itself. A `g77' installation necessarily requires installation of a `g77'-aware version of `gcc', so that the `gcc' command recognizes Fortran source files and knows how to compile them. For this to work, the version of `gcc' that you will be building as part of `g77' *must* be installed as the "active" version of `gcc' on the system. Sometimes people make the mistake of installing `gcc' as `/usr/local/bin/gcc', leaving an older, non-Fortran-aware version in `/usr/bin/gcc'. (Or, the opposite happens.) This can result in `g77' being unable to compile Fortran source files, because when it calls on `gcc' to do the actual compilation, `gcc' complains that it does not recognize the language, or the file name suffix. So, determine whether `gcc' already is installed on your system, and, if so, *where* it is installed, and prepare to configure the new version of `gcc' you'll be building so that it installs over the existing version of `gcc'. You might want to back up your existing copy of `bin/gcc', and the entire `lib/' directory, before you perform the actual installation (as described in this manual). Existing `gcc' installations typically are found in `/usr' or `/usr/local'. If you aren't certain where the currently installed version of `gcc' and its related programs reside, look at the output of this command: gcc -v -o /tmp/delete-me -xc /dev/null -xnone All sorts of interesting information on the locations of various `gcc'-related programs and data files should be visible in the output of the above command. (The output also is likely to include a diagnostic from the linker, since there's no `main_()' function.) However, you do have to sift through it yourself; `gcc' currently provides no easy way to ask it where it is installed and where it looks for the various programs and data files it calls on to do its work. Just *building* `g77' should not overwrite any installed programs--but, usually, after you build `g77', you will want to install it, so backing up anything it might overwrite is a good idea. (This is true for any package, not just `g77', though in this case it is intentional that `g77' overwrites `gcc' if it is already installed--it is unusual that the installation process for one distribution intentionally overwrites a program or file installed by another distribution.) Another reason to back up the existing version first, or make sure you can restore it easily, is that it might be an older version on which other users have come to depend for certain behaviors. However, even the new version of `gcc' you install will offer users the ability to specify an older version of the actual compilation programs if desired, and these older versions need not include any `g77' components. *Note Specifying Target Machine and Compiler Version: (gcc)Target Options, for information on the `-V' option of `gcc'. Configuring GNU CC ------------------ `g77' is configured automatically when you configure `gcc'. There are two parts of `g77' that are configured in two different ways--`g77', which "camps on" to the `gcc' configuration mechanism, and `libf2c', which uses a variation of the GNU `autoconf' configuration system. Generally, you shouldn't have to be concerned with either `g77' or `libf2c' configuration, unless you're configuring `g77' as a cross-compiler. In this case, the `libf2c' configuration, and possibly the `g77' and `gcc' configurations as well, might need special attention. (This also might be the case if you're porting `gcc' to a whole new system--even if it is just a new operating system on an existing, supported CPU.) To configure the system, see *Note Installing GNU CC: (gcc)Installation, following the instructions for running `./configure'. Pay special attention to the `--prefix=' option, which you almost certainly will need to specify. (Note that `gcc' installation information is provided as a straight text file in `gcc/INSTALL'.) The information printed by the invocation of `./configure' should show that the `f' directory (the Fortran language) has been configured. If it does not, there is a problem. *Note:* Configuring with the `--srcdir' argument is known to work with GNU `make', but it is not known to work with other variants of `make'. Irix5.2 and SunOS4.1 versions of `make' definitely won't work outside the source directory at present. `g77''s portion of the `configure' script issues a warning message about this when you configure for building binaries outside the source directory. Building GNU CC --------------- Building `g77' requires building enough of `gcc' that these instructions assume you're going to build all of `gcc', including `g++', `protoize', and so on. You can save a little time and disk space by changes the `LANGUAGES' macro definition in `gcc/Makefile.in' or `gcc/Makefile', but if you do that, you're on your own. One change is almost *certainly* going to cause failures: removing `c' or `f77' from the definition of the `LANGUAGES' macro. After configuring `gcc', which configures `g77' and `libf2c' automatically, you're ready to start the actual build by invoking `make'. *Note:* You *must* have run `./configure' before you run `make', even if you're using an already existing `gcc' development directory, because `./configure' does the work to recognize that you've added `g77' to the configuration. There are two general approaches to building GNU CC from scratch: "bootstrap" This method uses minimal native system facilities to build a barebones, unoptimized `gcc', that is then used to compile ("bootstrap") the entire system. "straight" This method assumes a more complete native system exists, and uses that just once to build the entire system. On all systems without a recent version of `gcc' already installed, the bootstrap method must be used. In particular, `g77' uses extensions to the C language offered, apparently, only by `gcc'. On most systems with a recent version of `gcc' already installed, the straight method can be used. This is an advantage, because it takes less CPU time and disk space for the build. However, it does require that the system have fairly recent versions of many GNU programs and other programs, which are not enumerated here. Bootstrap Build ............... A complete bootstrap build is done by issuing a command beginning with `make bootstrap ...', as described in *Note Installing GNU CC: (gcc)Installation. This is the most reliable form of build, but it does require the most disk space and CPU time, since the complete system is built twice (in Stages 2 and 3), after an initial build (during Stage 1) of a minimal `gcc' compiler using the native compiler and libraries. You might have to, or want to, control the way a bootstrap build is done by entering the `make' commands to build each stage one at a time, as described in the `gcc' manual. For example, to save time or disk space, you might want to not bother doing the Stage 3 build, in which case you are assuming that the `gcc' compiler you have built is basically sound (because you are giving up the opportunity to compare a large number of object files to ensure they're identical). To save some disk space during installation, after Stage 2 is built, you can type `rm -fr stage1' to remove the binaries built during Stage 1. *Note:* *Note Object File Differences::, for information on expected differences in object files produced during Stage 2 and Stage 3 of a bootstrap build. These differences will be encountered as a result of using the `make compare' or similar command sequence recommended by the GNU CC installation documentation. Also, *Note Installing GNU CC: (gcc)Installation, for important information on building `gcc' that is not described in this `g77' manual. For example, explanations of diagnostic messages and whether they're expected, or indicate trouble, are found there. Straight Build .............. If you have a recent version of `gcc' already installed on your system, and if you're reasonably certain it produces code that is object-compatible with the version of `gcc' you want to build as part of building `g77', you can save time and disk space by doing a straight build. To build just the C and Fortran compilers and the necessary run-time libraries, issue the following command: make -k CC=gcc LANGUAGES=f77 all g77 (The `g77' target is necessary because the `gcc' build procedures apparently do not automatically build command drivers for languages in subdirectories. It's the `all' target that triggers building everything except, apparently, the `g77' command itself.) If you run into problems using this method, you have two options: * Abandon this approach and do a bootstrap build. * Try to make this approach work by diagnosing the problems you're running into and retrying. Especially if you do the latter, you might consider submitting any solutions as bug/fix reports. *Note Known Causes of Trouble with GNU Fortran: Trouble. However, understand that many problems preventing a straight build from working are not `g77' problems, and, in such cases, are not likely to be addressed in future versions of `g77'. Pre-installation Checks ----------------------- Before installing the system, which includes installing `gcc', you might want to do some minimum checking to ensure that some basic things work. Here are some commands you can try, and output typically printed by them when they work: sh# cd /usr/src/gcc sh# ./g77 --driver=./xgcc -B./ -v g77 version 0.5.21 ./xgcc -B./ -v -fnull-version -o /tmp/gfa18047 ... Reading specs from ./specs gcc version 2.7.2.3.f.1 ./cpp -lang-c -v -isystem ./include -undef ... GNU CPP version 2.7.2.3.f.1 (Linux/Alpha) #include "..." search starts here: #include <...> search starts here: ./include /usr/local/include /usr/alpha-unknown-linux/include /usr/lib/gcc-lib/alpha-unknown-linux/2.7.2.3.f.1/include /usr/include End of search list. ./f771 /tmp/cca18048.i -fset-g77-defaults -quiet -dumpbase ... GNU F77 version 2.7.2.3.f.1 (Linux/Alpha) compiled ... GNU Fortran Front End version 0.5.21 compiled: ... as -nocpp -o /tmp/cca180481.o /tmp/cca18048.s ld -G 8 -O1 -o /tmp/gfa18047 /usr/lib/crt0.o -L. ... __G77_LIBF77_VERSION__: 0.5.21 @(#)LIBF77 VERSION 19970404 __G77_LIBI77_VERSION__: 0.5.21 @(#) LIBI77 VERSION pjw,dmg-mods 19970816 __G77_LIBU77_VERSION__: 0.5.21 @(#) LIBU77 VERSION 19970609 sh# ./xgcc -B./ -v -o /tmp/delete-me -xc /dev/null -xnone Reading specs from ./specs gcc version 2.7.2.3.f.1 ./cpp -lang-c -v -isystem ./include -undef ... GNU CPP version 2.7.2.3.f.1 (Linux/Alpha) #include "..." search starts here: #include <...> search starts here: ./include /usr/local/include /usr/alpha-unknown-linux/include /usr/lib/gcc-lib/alpha-unknown-linux/2.7.2.3.f.1/include /usr/include End of search list. ./cc1 /tmp/cca18063.i -quiet -dumpbase null.c -version ... GNU C version 2.7.2.3.f.1 (Linux/Alpha) compiled ... as -nocpp -o /tmp/cca180631.o /tmp/cca18063.s ld -G 8 -O1 -o /tmp/delete-me /usr/lib/crt0.o -L. ... /usr/lib/crt0.o: In function `__start': crt0.S:110: undefined reference to `main' /usr/lib/crt0.o(.lita+0x28): undefined reference to `main' sh# (Note that long lines have been truncated, and `...' used to indicate such truncations.) The above two commands test whether `g77' and `gcc', respectively, are able to compile empty (null) source files, whether invocation of the C preprocessor works, whether libraries can be linked, and so on. If the output you get from either of the above two commands is noticeably different, especially if it is shorter or longer in ways that do not look consistent with the above sample output, you probably should not install `gcc' and `g77' until you have investigated further. For example, you could try compiling actual applications and seeing how that works. (You might want to do that anyway, even if the above tests work.) To compile using the not-yet-installed versions of `gcc' and `g77', use the following commands to invoke them. To invoke `g77', type: /usr/src/gcc/g77 --driver=/usr/src/gcc/xgcc -B/usr/src/gcc/ ... To invoke `gcc', type: /usr/src/gcc/xgcc -B/usr/src/gcc/ ... Installation of Binaries ------------------------ After configuring, building, and testing `g77' and `gcc', when you are ready to install them on your system, type: make -k CC=gcc LANGUAGES=f77 install As described in *Note Installing GNU CC: (gcc)Installation, the values for the `CC' and `LANGUAGES' macros should be the same as those you supplied for the build itself. So, the details of the above command might vary if you used a bootstrap build (where you might be able to omit both definitions, or might have to supply the same definitions you used when building the final stage) or if you deviated from the instructions for a straight build. If the above command does not install `libf2c.a' as expected, try this: make -k ... install install-libf77 install-f2c-all We don't know why some non-GNU versions of `make' sometimes require this alternate command, but they do. (Remember to supply the appropriate definitions for `CC' and `LANGUAGES' where you see `...' in the above command.) Note that using the `-k' option tells `make' to continue after some installation problems, like not having `makeinfo' installed on your system. It might not be necessary for your system. Updating Your Info Directory ---------------------------- As part of installing `g77', you should make sure users of `info' can easily access this manual on-line. Do this by making sure a line such as the following exists in `/usr/info/dir', or in whatever file is the top-level file in the `info' directory on your system (perhaps `/usr/local/info/dir': * g77: (g77). The GNU Fortran programming language. If the menu in `dir' is organized into sections, `g77' probably belongs in a section with a name such as one of the following: * Fortran Programming * Writing Programs * Programming Languages * Languages Other Than C * Scientific/Engineering Tools * GNU Compilers Missing `bison'? ---------------- If you cannot install `bison', make sure you have started with a *fresh* distribution of `gcc', do *not* do `make maintainer-clean' (in other versions of `gcc', this was called `make realclean'), and, to ensure that `bison' is not invoked by `make' during the build, type these commands: sh# cd gcc sh# touch bi-parser.c bi-parser.h c-parse.c c-parse.h cexp.c sh# touch cp/parse.c cp/parse.h objc-parse.c sh# These commands update the date-time-modified information for all the files produced by the various invocations of `bison' in the current versions of `gcc', so that `make' no longer believes it needs to update them. All of these files should already exist in a `gcc' distribution, but the application of patches to upgrade to a newer version can leave the modification information set such that the `bison' input files look more "recent" than the corresponding output files. *Note:* New versions of `gcc' might change the set of files it generates by invoking `bison'--if you cannot figure out for yourself how to handle such a situation, try an older version of `gcc' until you find someone who can (or until you obtain and install `bison'). Missing `makeinfo'? ------------------- If you cannot install `makeinfo', either use the `-k' option when invoking make to specify any of the `install' or related targets, or specify `MAKEINFO=echo' on the `make' command line. If you fail to do one of these things, some files, like `libf2c.a', might not be installed, because the failed attempt by `make' to invoke `makeinfo' causes it to cancel any further processing. Distributing Binaries ===================== If you are building `g77' for distribution to others in binary form, first make sure you are aware of your legal responsibilities (read the file `gcc/COPYING' thoroughly). Then, consider your target audience and decide where `g77' should be installed. For systems like GNU/Linux that have no native Fortran compiler (or where `g77' could be considered the native compiler for Fortran and `gcc' for C, etc.), you should definitely configure `g77' for installation in `/usr/bin' instead of `/usr/local/bin'. Specify the `--prefix=/usr' option when running `./configure'. You might also want to set up the distribution so the `f77' command is a link to `g77'--just make an empty file named `f77-install-ok' in the source or build directory (the one in which the `f' directory resides, not the `f' directory itself) when you specify one of the `install' or `uninstall' targets in a `make' command. For a system that might already have `f2c' installed, you definitely will want to make another empty file (in the same directory) named either `f2c-exists-ok' or `f2c-install-ok'. Use the former if you don't want your distribution to overwrite `f2c'-related files in existing systems; use the latter if you want to improve the likelihood that users will be able to use both `f2c' and `g77' to compile code for a single program without encountering link-time or run-time incompatibilities. (Make sure you clearly document, in the "advertising" for your distribution, how installation of your distribution will affect existing installations of `gcc', `f2c', `f77', `libf2c.a', and so on. Similarly, you should clearly document any requirements you assume are met by users of your distribution.) For other systems with native `f77' (and `cc') compilers, configure `g77' as you (or most of your audience) would configure `gcc' for their installations. Typically this is for installation in `/usr/local', and would not include a copy of `g77' named `f77', so users could still use the native `f77'. In any case, for `g77' to work properly, you *must* ensure that the binaries you distribute include: `bin/g77' This is the command most users use to compile Fortran. `bin/gcc' This is the command all users use to compile Fortran, either directly or indirectly via the `g77' command. The `bin/gcc' executable file must have been built from a `gcc' source tree into which a `g77' source tree was merged and configured, or it will not know how to compile Fortran programs. `bin/f77' In installations with no non-GNU native Fortran compiler, this is the same as `bin/g77'. Otherwise, it should be omitted from the distribution, so the one on already on a particular system does not get overwritten. `info/g77.info*' This is the documentation for `g77'. If it is not included, users will have trouble understanding diagnostics messages and other such things, and will send you a lot of email asking questions. Please edit this documentation (by editing `gcc/f/*.texi' and doing `make doc' from the `/usr/src/gcc' directory) to reflect any changes you've made to `g77', or at least to encourage users of your binary distribution to report bugs to you first. Also, whether you distribute binaries or install `g77' on your own system, it might be helpful for everyone to add a line listing this manual by name and topic to the top-level `info' node in `/usr/info/dir'. That way, users can find `g77' documentation more easily. *Note Updating Your Info Directory: Updating Documentation. `man/man1/g77.1' This is the short man page for `g77'. It is out of date, but you might as well include it for people who really like man pages. `man/man1/f77.1' In installations where `f77' is the same as `g77', this is the same as `man/man1/g77.1'. Otherwise, it should be omitted from the distribution, so the one already on a particular system does not get overwritten. `lib/gcc-lib/.../f771' This is the actual Fortran compiler. `lib/gcc-lib/.../libf2c.a' This is the run-time library for `g77'-compiled programs. Whether you want to include the slightly updated (and possibly improved) versions of `cc1', `cc1plus', and whatever other binaries get rebuilt with the changes the GNU Fortran distribution makes to the GNU back end, is up to you. These changes are highly unlikely to break any compilers, and it is possible they'll fix back-end bugs that can be demonstrated using front ends other than GNU Fortran's. Please assure users that unless they have a specific need for their existing, older versions of `gcc' command, they are unlikely to experience any problems by overwriting it with your version--though they could certainly protect themselves by making backup copies first! Otherwise, users might try and install your binaries in a "safe" place, find they cannot compile Fortran programs with your distribution (because, perhaps, they're picking up their old version of the `gcc' command, which does not recognize Fortran programs), and assume that your binaries (or, more generally, GNU Fortran distributions in general) are broken, at least for their system. Finally, *please* ask for bug reports to go to you first, at least until you're sure your distribution is widely used and has been well tested. This especially goes for those of you making any changes to the `g77' sources to port `g77', e.g. to OS/2. has received a fair number of bug reports that turned out to be problems with other peoples' ports and distributions, about which nothing could be done for the user. Once you are quite certain a bug report does not involve your efforts, you can forward it to us.