ocaml/INSTALL

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Installing Objective Caml on a Unix machine
-------------------------------------------
PREREQUISITES
* The GNU C compiler gcc is recommended, as the bytecode
interpreter takes advantage of gcc-specific features to enhance
performance. Versions 2.5.8, 2.6.3, 2.7.2, 2.7.2.3, 2.95
as well as egcs versions 1.0 and 2.91 have all been tested at some point
and work well.
2.7.2.1 for Intel as found in Linux/RedHat 4.1 and 4.2 has known problems;
upgrade to something more recent.
* Under HP/UX, the GNU C compiler gcc, the GNU assembler gas, and GNU make
are all *required*. The vendor-provided compiler, assembler and make
have major problems.
* Under MacOS X, before you begin, you must raise the limit on the
stack size with one of the following commands:
limit stacksize 64M # if your shell is zsh or tcsh
ulimit -s 65536 # if your shell is bash
INSTALLATION INSTRUCTIONS
1- Configure the system. From the top directory, do:
./configure
This generates the three configuration files "Makefile", "m.h" and "s.h"
in the config/ subdirectory.
The "configure" script accepts the following options:
-bindir <dir> (default: /usr/local/bin)
Directory where the binaries will be installed
-libdir <dir> (default: /usr/local/lib/ocaml)
Directory where the Caml library will be installed
-mandir <dir> (default: /usr/local/man/man1)
Directory where the manual pages will be installed
-prefix <dir> (default: /usr/local)
Set bindir, libdir and mandir to
<dir>/bin, <dir>/lib/ocaml, <dir>/man/man1 respectively.
-cc <C compiler and options> (default: gcc if available, cc otherwise)
C compiler to use for building the system
-libs <extra libraries> (default: none)
Extra libraries to link with the system
-no-curses
Do not use the curses library.
-host <hosttype> (default: determined automatically)
The type of the host machine, in GNU's "configuration name"
format (CPU-COMPANY-SYSTEM). This info is generally determined
automatically by the "configure" script, and rarely ever
needs to be provided by hand. The installation instructions
for gcc or emacs contain a complete list of configuration names.
-x11include <include_dir> (default: determined automatically)
-x11lib <lib_dir> (default: determined automatically)
Location of the X11 include directory (e.g. /usr/X11R6/include)
and the X11 library directory (e.g. /usr/X11R6/lib).
-with-pthread
Use POSIX threads for the OCaml thread library instead of
the default bytecode-level threading. POSIX threads
support threading with native-code programs (ocamlopt)
as well as bytecode (ocamlc), and also allow more flexibility
in interfacing with C. However, you need a strictly
conformant POSIX 1003.1c implementation on your system.
For instance, this option works under Solaris 2.5 and later,
Digital Unix 4.0, and recent Linux distributions (using glibc 2).
-tkdefs <cpp flags> (default: none)
-tklibs <flags and libraries> (default: determined automatically)
These options specify where to find the Tcl/Tk libraries for
LablTk. "-tkdefs" helps to find the headers, and "-tklibs"
the C libraries. "-tklibs" may contain either only -L/path and
-Wl,... flags, in which case the library names are determined
automatically, or the actual libraries, which are used as given.
Example: for a Japanese tcl/tk whose headers are in specific
directories and libraries in /usr/local/lib, you can use
./configure -tklibs "-L/usr/local/lib -ltk8.0jp -ltcl8.0jp"
-tkdefs "-I/usr/local/include/tcl8.0jp -I/usr/local/include/tk8.0jp"
-tk-no-x11
Build LablTk without using X11. This option is needed on Cygwin.
-no-tk
Do not attempt to build LablTk.
-verbose
Verbose output of the configuration tests. Use it if the outcome
of configure is not what you were expecting.
Examples:
./configure -prefix /usr/bin
./configure -bindir /usr/bin -libdir /usr/lib/ocaml -mandir /usr/man/manl
./configure -cc "acc -fast" -libs "-lucb"
# For Sun Solaris with the acc compiler
./configure -cc "xlc_r -D_AIX43 -Wl,-bexpall,-brtl -qmaxmem=8192"
# For AIX 4.3 with the IBM compiler
If something goes wrong during the automatic configuration, or if the
generated files cause errors later on, then look at the template files
config/Makefile-templ
config/m-templ.h
config/s-templ.h
for guidance on how to edit the generated files by hand.
2- From the top directory, do:
make world
This builds the Objective Caml bytecode compiler for the first time.
This phase is fairly verbose; consider redirecting the output to a file:
make world > log.world 2>&1 # in sh
make world >& log.world # in csh
3- (Optional) To be sure everything works well, you can try to
bootstrap the system --- that is, to recompile all Objective Caml
sources with the newly created compiler. From the top directory, do:
make bootstrap
or, better:
make bootstrap > log.bootstrap 2>&1 # in sh
make bootstrap >& log.bootstrap # in csh
The "make bootstrap" checks that the bytecode programs compiled with
the new compiler are identical to the bytecode programs compiled with
the old compiler. If this is the case, you can be pretty sure the
system has been correctly compiled. Otherwise, this does not
necessarily mean something went wrong. The best thing to do is to try
a second bootstrapping phase: just do "make bootstrap" again. It will
either crash almost immediately, or re-re-compile everything correctly
and reach the fixpoint.
4- If your platform is supported by the native-code compiler (as
reported during the autoconfiguration), you can now build the
native-code compiler. From the top directory, do:
make opt
or:
make opt > log.opt 2>&1 # in sh
make opt >& log.opt # in csh
5- (Optional) If you want to give the native-code compiler a serious
test, you can try to compile the Objective Caml compilers with the
native-code compiler (they are compiled to bytecode by default).
Just do:
make ocamlc.opt # to build a native-code version of ocamlc
make ocamlopt.opt # to build a native-code version of ocamlopt
make ocamllex.opt # to build a native-code version of ocamllex
or
make opt.opt # to build all of them
Later, you can compile your programs to bytecode using ocamlc.opt
instead of ocamlc, and to native-code using ocamlopt.opt instead of
ocamlopt. The ".opt" compilers should run faster than the normal
compilers, especially on large input files, but they may take longer
to start due to increased code size. If compilation times are an issue on
your programs, try the ".opt" compilers to see if they make a
significant difference.
6- You can now install the Objective Caml system. This will create the
following commands (in the binary directory selected during autoconfiguration):
ocamlc the batch bytecode compiler
ocamlopt the batch native-code compiler (if supported)
ocamlrun the runtime system for the bytecode compiler
ocamlyacc the parser generator
ocamllex the lexer generator
ocaml the interactive, toplevel-based system
ocamlmktop a tool to make toplevel systems that integrate
user-defined C primitives and Caml code
ocamldebug the source-level replay debugger
ocamldep generator of "make" dependencies for Caml sources
ocamlprof execution count profiler
ocamlcp the bytecode compiler in profiling mode
and also, if you built them during step 5,
ocamlc.opt the batch bytecode compiler compiled with ocamlopt
ocamlopt.opt the batch native-code compiler compiled with ocamlopt
ocamllex.opt the lexer generator compiled with ocamlopt
From the top directory, become superuser and do:
umask 022 # make sure to give read & execute permission to all
make install
7- Installation is complete. Time to clean up. From the toplevel
directory, do "make clean".
8- (Optional) The emacs/ subdirectory contains Emacs-Lisp files for an
Objective Caml editing mode and an interface for the debugger. To
install these files, change to the emacs/ subdirectory and do
make EMACSDIR=<directory where to install the files> install
or
make install
In the latter case, the destination directory defaults to the
"site-lisp" directory of your Emacs installation.
9- After installation, do *not* strip the ocamldebug and ocamlbrowser
executables. (These are mixed-mode executables, containing both
compiled C code and Caml bytecode; stripping erases the bytecode!)
Other executables such as ocamlrun can safely be stripped.
IF SOMETHING GOES WRONG:
Read the "common problems" and "machine-specific hints" section at the
end of this file.
Check the files m.h and s.h in config/. Wrong endianness or alignment
constraints in m.h will immediately crash the bytecode interpreter.
If you get a "segmentation violation" signal, check the limits on the
stack size and data segment size (type "limit" under csh or
"ulimit -a" under bash). Make sure the limit on the stack size is
at least 2M.
Try recompiling the runtime system with optimizations turned off
(change CFLAGS in byterun/Makefile and asmrun/Makefile).
The runtime system contains some complex, atypical pieces of C code
that can uncover bugs in optimizing compilers. Alternatively, try
another C compiler (e.g. gcc instead of the vendor-supplied cc).
You can also build a debug version of the runtime system. Go to the
byterun/ directory and do "make ocamlrund". Then, copy ocamlrund to
../boot/ocamlrun, and try again. This version of the runtime system
contains lots of assertions and sanity checks that could help you
pinpoint the problem.
COMMON PROBLEMS:
* The Makefiles use the "include" directive, which is not supported by
all versions of make. Use GNU make if this is a problem.
* The Makefiles assume that make execute commands by calling /bin/sh. They
won't work if /bin/csh is called instead. You may have to unset the SHELL
environment variable, or set it to /bin/sh.
* gcc 2.7.2.1 generates incorrect code for the runtime system in -O mode
on some Intel x86 platforms (e.g. Linux RedHat 4.1 and 4.2).
If this causes a problem, the solution is to upgrade to 2.7.2.3 or above.
* On HP 9000/700 machines under HP/UX 9. Some versions of cc are
unable to compile correctly the runtime system (wrong code is
generated for (x - y) where x is a pointer and y an integer).
Fix: use gcc.