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Names: »INSTALL«
└─⟦a05ed705a⟧ Bits:30007078 DKUUG GNU 2/12/89
└─⟦d53cfc7b2⟧ »./gcc-1.35.tar.Z«
└─⟦90f628c1d⟧
└─⟦this⟧ »gcc-1.35/INSTALL«
This is a copy of one node from the Info file gcc.info-2.
For full information on installing and porting GCC, refer to the
GCC manual:
Info file gcc.info
TeX output gcc.dvi
TeX source gcc.texinfo
Installing GNU CC
*****************
Here is the procedure for installing GNU CC on a Unix system.
* Menu:
* VMS Install:: See below for installation on VMS.
1. Edit `Makefile'. If you are using HPUX, or any form of system
V, you must make a few changes described in comments at the
beginning of the file. Genix requires changes also.
2. On a Sequent system, go to the Berkeley universe.
3. Choose configuration files. The easy way to do this is to run
the command file `config.gcc' with a single argument, which is
the name of the machine (and operating system, in some cases).
Here is a list of the possible arguments:
`vax'
Vaxes running BSD.
`vms'
Vaxes running VMS.
`vax-sysv'
Vaxes running system V.
`i386-sysv'
Intel 386 PCs running system V.
`i386-sysv-gas'
Intel 386 PCs running system V, using the GNU assembler and
GNU linker.
`sequent-i386'
Sequent with Intel 386 processors.
`sun2'
Sun 2 running system version 2 or 3.
`sun3'
Sun 3 running system version 2 or 3, with 68881.
Note there we do not provide a configuration file to use an
FPA by default because programs that establish signal
handlers for floating point traps inherently cannot work
with the FPA.
`sun3-nfp'
Sun 3 running system version 2 or 3, without 68881.
`sun4'
Sun 4 running system version 2 or 3.
`sun2-os4'
Sun 2 running system version 4.
`sun3-os4'
Sun 3 running system version 4, with 68881.
`sun3-nfp-os4'
Sun 3 running system version 4, without 68881.
`sun4-os4'
Sun 4 running system version 4.
`sun386'
Sun 386 (``roadrunner'').
`alliant'
Alliant FX/8 computer. Currently, there are bugs in the
support for floating point. Also note that Alliant's
version of dbx does not manage to work with the output from
GNU CC.
`mips'
Some variant of MIPS computer (but not the one from DEC).
Note that this machine description was written for GNU CC
version 1.32 and may require some updating to work with the
current version.
`convex-c1'
Convex C1 computer.
`convex-c2'
Convex C2 computer.
`hp9k320'
HP 9000 series 300 using HPUX assembler. Note there is no
support in GNU CC for HP's debugger; thus, `-g' is not
available in this configuration.
`hp9k320g'
HP 9000 series 300 using GNU assembler, linker and debugger.
This requires the HP-adapt package, which is available
along with the GNU linker as part of the ``binutils''
distribution. This is on the GNU CC distribution tape.
`isi68'
ISI 68000 or 68020 system.
`news800'
Sony NEWS 68020 system.
`next'
NeXT system.
`altos'
Altos 3068. Note that you must use the GNU assembler,
linker and debugger, with COFF-encapsulation. Also, you
must fix a kernel bug. Details in the file `ALTOS-README'.
`3b1'
AT&T 3b1, a.k.a. 7300 PC. Note that the current version of
GNU CC cannot be compiled with the Unix compiler on this
machine, due to bugs in the Unix comiler. GNU CC does work
correctly, however, if you can compile it with older
version of GNU CC or cross-compile it.
`sequent-ns32k'
Sequent containing ns32000 processors.
`encore'
Encore ns32000 system.
`genix'
National Semiconductor ns32000 system.
`88000'
Motorola 88000 processor. This port is not finished.
Here we spell out what files need to be set up:
* Make a symbolic link named `config.h' to the top-level
config file for the machine you are using (*note
Config::.). This file is responsible for defining
information about the host machine. It includes `tm.h'.
The file is located in the subdirectory `config'. Its name
should be `xm-MACHINE.h', with these exceptions:
`xm-vms.h'
for vaxen running VMS.
`xm-vaxv.h'
for vaxen running system V.
`xm-i386v.h'
for Intel 80386's running system V.
`xm-sunos4.h'
for Suns (model 2, 3 or 4) running *operating system*
version 4. (Use `xm-m68k.h' or `xm-sparc.h' for
version 3.)
`xm-sun386i.h'
for Sun roadrunner running any version of the
operating system.
`xm-hp9k320.h'
for the HP 9000 series 300.
`xm-genix.h'
for the ns32000 running Genix
If your system does not support symbolic links, you might
want to set up `config.h' to contain a `#include' command
which refers to the appropriate file.
* Make a symbolic link named `tm.h' to the
machine-description macro file for your machine. It should
be in the subdirectory `config' and its name should be
`tm-MACHINE.h'.
If your system is a 68000, don't use the file `tm-m68k.h'
directly. Instead, use one of these files:
`tm-sun3.h'
for Sun 3 machines with 68881.
`tm-sun3-nfp.h'
for Sun 3 machines with no hardware floating point.
`tm-sun2.h'
for Sun 2 machines.
`tm-3b1.h'
for AT&T 3b1 (aka 7300 Unix PC).
`tm-isi68.h'
for Integrated Solutions systems. This file assumes
you use the GNU assembler.
`tm-news800.h'
for SONY News systems.
`tm-hp9k320.h'
for HPUX systems, if you are using GNU CC with the
system's assembler and linker.
`tm-hp9k320g.h'
for HPUX systems, if you are using the GNU assembler,
linker and other utilities. Not all of the pieces of
GNU software needed for this mode of operation are as
yet in distribution; full instructions will appear
here in the future.
For the vax, use `tm-vax.h' on BSD Unix, `tm-vaxv.h' on
system V, or `tm-vms.h' on VMS.
For the Motorola 88000, use `tm-m88k.h'. The support for
the 88000 has a few unfinished spots because there was no
way to run the output. Bugs are suspected in handling of
branch-tables and in the function prologue and epilogue.
For the 80386, don't use `tm-i386.h' directly. Use
`tm-i386v.h' if the target machine is running system V,
`tm-i386gas.h' if it is running system V but you are using
the GNU assembler and linker, `tm-seq386.h' for a Sequent
386 system, or `tm-compaq.h' for a Compaq, or
`tm-sun386i.h' for a Sun 386 system.
For the 32000, use `tm-sequent.h' if you are using a
Sequent machine, or `tm-encore.h' for an Encore machine, or
`tm-genix.h' if you are using Genix version 3; otherwise,
perhaps `tm-ns32k.h' will work for you.
Note that Genix has bugs in `alloca' and `malloc'; you must
get the compiled versions of these from GNU Emacs and edit
GNU CC's `Makefile' to use them.
Note that Encore systems are supported only under BSD.
For Sparc (Sun 4) machines, use `tm-sparc.h' with operating
system version 4, and `tm-sun4os3.h' with system version 3.
* Make a symbolic link named `md' to the machine description
pattern file. It should be in the `config' subdirectory
and its name should be `MACHINE.md'; but MACHINE is often
not the same as the name used in the `tm.h' file because
the `md' files are more general.
* Make a symbolic link named `aux-output.c' to the output
subroutine file for your machine. It should be in the
`config' subdirectory and its name should be `out-MACHINE.c'.
4. Make sure the Bison parser generator is installed. (This is
unnecessary if the Bison output files `c-parse.tab.c' and
`cexp.c' are more recent than `c-parse.y' and `cexp.y' and you
do not plan to change the `.y' files.)
Bison versions older that Sept 8, 1988 will produce incorrect
output for `c-parse.tab.c'.
5. If you are using a Sun, make sure the environment variable
`FLOAT_OPTION' is not set. If this option were set to `f68881'
when `gnulib' is compiled, the resulting code would demand to be
linked with a special startup file and will not link properly
without special pains.
6. Build the compiler. Just type `make' in the compiler directory.
Ignore any warnings you may see about ``statement not reached''
in the `insn-emit.c'; they are normal. Any other compilation
errors may represent bugs in the port to your machine or
operating system, and should be investigated and reported (*note
Bugs::.).
7. Optionally, install the library functions for 64-bit integer
arithmetic. You do this with the command `make gnulib2'. In
the future this will happen automatically; for now, it is
optional, until we are sure it works on all machines.
8. If you are using COFF-encapsulation, you must convert `gnulib'
to a GNU-format library at this point. See the file
`README-ENCAP' in the directory containing the GNU binary file
utilities, for directions.
9. Move the first-stage object files and executables into a
subdirectory with this command:
make stage1
The files are moved into a subdirectory named `stage1'. Once
installation is complete, you may wish to delete these files
with `rm -r stage1'.
10. Recompile the compiler with itself, with this command:
make CC=stage1/gcc CFLAGS="-g -O -Bstage1/"
On a 68000 or 68020 system lacking floating point hardware,
unless you have selected a `tm.h' file that expects by default
that there is no such hardware, do this instead:
make CC=stage1/gcc CFLAGS="-g -O -Bstage1/ -msoft-float"
11. If you wish to test the compiler by compiling it with itself one
more time, do this (in C shell):
make stage2
make CC=stage2/gcc CFLAGS="-g -O -Bstage2/"
foreach file (*.o)
cmp $file stage2/$file
end
Aside from the `-B' option, the options should be the same as
when you made stage 2.
The `foreach' command (written in C shell) will notify you if
any of these stage 3 object files differs from those of stage 2.
On BSD systems, any difference, no matter how innocuous,
indicates that the stage 2 compiler has compiled GNU CC
incorrectly, and is therefore a potentially serious bug which
you should investigate and report (*note Bugs::.).
On systems that use COFF object files, bytes 5 to 8 will always
be different, since it is a timestamp. On these systems, you
can do the comparison as follows (in Bourne shell):
for file in *.o; do
echo $file
tail +10 $file > foo1
tail +10 stage2/$file > foo2
cmp foo1 foo2
done
12. Install the compiler driver, the compiler's passes and run-time
support. You can use the following command:
make install
This copies the files `cc1', `cpp' and `gnulib' to files
`gcc-cc1', `gcc-cpp' and `gcc-gnulib' in directory
`/usr/local/lib', which is where the compiler driver program
looks for them. It also copies the driver program `gcc' into
the directory `/usr/local/bin', so that it appears in typical
execution search paths.
*Warning: there is a bug in `alloca' in the Sun library. To
avoid this bug, install the binaries of GNU CC that were
compiled by GNU CC. They use `alloca' as a built-in function
and never the one in the library.*
*Warning: the GNU CPP may not work for `ioctl.h', `ttychars.h'
and other system header files unless the `-traditional' option
is used.* The bug is in the header files: at least on some
machines, they rely on behavior that is incompatible with ANSI
C. This behavior consists of substituting for macro argument
names when they appear inside of character constants. The
`-traditional' option tells GNU CC to behave the way these
headers expect.
Because of this problem, you might prefer to configure GNU CC to
use the system's own C preprocessor. To do so, make the file
`/usr/local/lib/gcc-cpp' a link to `/lib/cpp'.
Alternatively, on Sun systems and 4.3BSD at least, you can
correct the include files by running the shell script
`fixincludes'. This installs modified, corrected copies of the
files `ioctl.h', `ttychars.h' and many others, in a special
directory where only GNU CC will normally look for them. This
script will work on various systems because it chooses the files
by searching all the system headers for the problem cases that
we know about.
If you cannot install the compiler's passes and run-time support in
`/usr/local/lib', you can alternatively use the `-B' option to
specify a prefix by which they may be found. The compiler
concatenates the prefix with the names `cpp', `cc1' and `gnulib'.
Thus, you can put the files in a directory `/usr/foo/gcc' and specify
`-B/usr/foo/gcc/' when you run GNU CC.
Also, you can specify an alternative default directory for these
files by setting the Make variable `libdir' when you make GNU CC.
▶1f◀
File: gcc.info, Node: VMS Install, Prev: Installation, Up: Installation
Installing GNU CC on VMS
========================
The VMS version of GNU CC is distributed in a backup saveset
containing both source code and precompiled binaries.
Sometimes the binaries will be from an older version that the
sources, because we don't always have time to update them. In this
case, you should use the binaries you get to recompile the sources.
If you must recompile, here is how:
1. Copy the file `tm-vms.h' to `tm.h', `xm-vms.h' to `config.h',
`vax.md' to `md.' and `output-vax.c' to `aux-output.c'.
2. Type `@make' to do recompile everything.
If you are compiling with a version of GCC older than 1.33,
specify `/DEFINE=("inline=")' as an option in all the
compilations. This requires editing all the `gcc' commands in
`make-cc1.com'. (The older versions had problems supporting
`inline'.) Once you have a working 1.33 or newer GCC, you can
change this file back.
To install the `GCC' command so you can use the compiler easily, in
the same manner as you use the VMS C compiler, you must install the
VMS CLD file for GNU CC as follows:
1. Define the VMS logical names `GNU_CC' and `GNU_CC_INCLUDE' to
point to the directories where the GNU CC executables
(`gcc-cpp', `gcc-cc1', etc.) and the C include files are kept.
This should be done with the commands:
$ assign /super /system disk:[gcc] gnu_cc
$ assign /super /system disk:[gcc.include] gnu_cc_include
with the appropriate disk and directory names. These commands
can be placed in your system startup file so they will be
executed whenever the machine is rebooted.
2. Install the `GCC' command with the command line:
$ set command /table=sys$library:dcltables gnu_cc:gcc
3. To install the help file, do the following:
$ lib/help sys$library:helplib.hlb gcc.hlp
Now you can invoke the compiler with a command like `gcc
/verbose file.c', which is equivalent to the command `gcc -v -c
file.c' in Unix.
There is a known problem on VMS: `const' global variables don't work
compatibly with the VMS C compiler; we don't know a way to get them
to the linker properly.
Note that GNU CC on VMS does not generate debugging information to
describe the program's symbols. It is not straightforward to
implement this, and we have no time to spend on it, but we might
consent to install a very modular implementation if you write it.
You will probably have to modify GAS as well as GNU CC.