cpython/Mac/Demo/building.html

<HTML>
<HEAD>
<TITLE>Building Mac Python from source</TITLE>
</HEAD>
<BODY>
<H1>Building Mac Python from source</H1>
<HR>

This document explains how to build MacPython from source. This is
necessary if you want to write extension modules for 68K Python, and
currently also probably the easiest way to build PPC extension
modules. Building Python is not something to be undertaken lightly,
the process is not very streamlined so you need a reasonable working
knowledge of the CodeWarrior development environment, a good net
connection and probably quite some time too. <p>

The information density in this file is high, so you should probably
print it and read it at your leasure. Most things are explained only
once (and probably in the wrong place:-). <p>

I am very interested in feedback on this document, contact me at <A
HREF="mailto:jack@cwi.nl">&lt;jack@cwi.nl&gt;</A> or send your
comments to the <A
HREF="http://www.python.org/sigs/pythonmac-sig/">Mac Python Special
Interest Group</A>.

<H2>What you need.</H2>

The following things you definitely need:

<UL>

<LI> You need a MacPython source distribution, of course. You can
obtain one from <A
HREF="ftp://ftp.cwi.nl/pub/jack/python/mac">ftp://ftp.cwi.nl/pub/jack/python/mac</A>,
and possibly also from the standard <A
HREF="ftp://ftp.python.org/pub/python/mac">python.org ftp
site</A>. Everything you need is also included in the standard Python
source distribution, but the organization is different. Look in
directory <code>Mac/mwerks/projects</code> for the project files and
related stuff.

<LI> You need MetroWerks CodeWarrior. The current distribution has
been built with version 10 of CodeWarrior. Ordering information is
available on the <A HREF="http://www.metrowerks.com/">MetroWerks
homepage</A>. You might still be able to build Python with MPW or
Think/Symantec C but you are basically on your own.

<LI> You need GUSI, the Grand Unified Socket Interface, by Matthias
Neeracher. The current distribution has been built with a modified version of
CWGUSI 1.8.0. CWGUSI is
obtainable from <A
HREF="ftp://sunsite.cnlab-switch.ch/software/platform/macos/src">
ftp://sunsite.cnlab-switch.ch/software/platform/macos/src</A>.
It is possible to build a non-GUSI Python, see below.

</UL>

<A NAME="optional">The MacPython project files are configured to
include a plethora of optional modules</A>, and these modules need a
number extra packages. To use the project files as-is you have to
download these packages too. PPC and CFM68K Python have all such modules as
dynamically loaded modules, so if you don't need a certain package it
suffices to just refrain from builing the extension module. For static 68K
Python things are a bit more complicated: you have to edit the
interpreter project file to remove the reference to the module (and
the libraries it uses), and edit the <code>Mac:mwerks:mwerks_nonshared_config.h</code>
file to remove the <code>USE_...</code> line.  Here are the locations for the various things
you need:

<UL>

<LI> Tcl and Tk can be obtained from <A
HREF="ftp://ftp.smli.com/pub/tcl/mac/">ftp://ftp.smli.com/pub/tcl/mac/</A>.
The current distributions, Tcl 7.6 and Tk 4.2 need a bit of work,
see the section on <A HREF="#tcltk">building Tcl/Tk Python</A>
below. Get the "full source" distribution, which includes MoreFiles.

<LI> Waste, a TextEdit replacement written by Marco Piovanelli, <A
HREF="mailto:piovanel@kagi.com">&lt;piovanel@kagi.com&gt;</A>.  Python
was built using version 1.2, which you can obtain from <A
HREF="ftp://rhino.harvard.edu/pub/dan/WASTE">&lt;ftp://rhino.harvard.edu/pub/dan/WASTE&gt;</A>
and various other places.

<LI> JPEG library by the Independent JPEG Group. Python is still built
using an archaic version of the library, version 4. It can be obtained
from the <A HREF="ftp://ftp.cwi.nl/pub/jack/python/mac">
ftp://ftp.cwi.nl/pub/jack/python/mac</A> directory, complete with CW8
projects. If someone manages to build Python with the version 6
library I would be grateful if they sent me the changes needed.  The
most recent JPEG library can always be obtained from <A
HREF="ftp://ftp.uu.net/graphics/jpeg/">ftp://ftp.uu.net/graphics/jpeg/</A>.

<LI> The netpbm/pbmplus and libtiff libraries. The netpbm distribution
(which includes libtiff) is generally available on Internet ftp
servers. For Python pbmplus, an older incarnation of netpbm, is
functionally identical to netpbm, since Python only uses the library
and not the complete applications. A distribution with correct
projects and library source only is available from, you guessed it, <A
HREF="ftp://ftp.cwi.nl/pub/jack/python/mac">ftp://ftp.cwi.nl/pub/jack/python/mac</A>.

</UL>

<H2>Setting Up</H2>

Now that you have collected everything you should start with building
the various parts. Everything is independent, with the single
exception that Tcl and Tk depend on CWGUSI. If you don't want to fix
access paths try to set things up as follows:

<PRE>
Top-level-folder:
	CWGUSI
	imglibs
		libjpeg
		pbmplus
			libtiff
	MoreFiles 1.4.3 (not needed by Python, only by tcl/tk)
	Python
	Tcl 7.6
	Tk 4.2
	Waste 1.2 distribution (if you want waste)
</PRE>

First build GUSI. Move the files from the "CWGUSI-mods" to the right
place in the CWGUSI distribution folder, and build the
projects <code>GUSI.68K.<2E></code>, <code>GUSI.CFM68K.<2E></code> and
<code>GUSI.PPC.<2E></code>.
Two notes:
<ul>
<li> The projects as distributed have a slightly incorrect access path, due
to which they cannot find their <code>GUSICWFile.???</code> files. Change
the access path to <code>{project folder}::</code> to fix this.
<li> The Gusi CFM68K project is
distributed without "far data": you should set this option before building.
</ul> 
If you have a CWGUSI version more recent than
1.8 it could be that the fixes are already included, check it. Alternatively,
you can forget about the fixes and remove the one reference to GUSILoadPreferences
in the Python sources. This will disable the "default file creator/type" and
"Delay Sioux window" preferences in Python.

Next, in
<code>MoreFiles</code>, <code>libjpeg</code>, <code>pbmplus</code>
and<code>libtiff</code> you build all projects. Tcl/tk is a special
case, see below. Of course, if you are only interested in one of
static 68K, CFM68K or PPC you can skip building the other libraries.

<H2><A NAME="tcltk">Building Tcl/Tk</H2>

You need to make a minor organizational change to the Tcl/Tk
distribution. The current instructions are for the
<code>tcl7.6</code> and <code>tk4.2</code> distribution:

<UL>

<LI> Rename the <code>compat</code> folders to <code>(compat)</code>
in both the Tcl and Tk folders.

<LI> In the Tcl folder, move <code>strncasecmp.c</code> and
<code>tclErrno.h</code> from <code>(compat)</code> to the main Tcl
folder.

<LI> Fix <code>dnr.c</code> as provided by MetroWerks by inserting
<pre><code> #pragma ANSI_strict off </code></pre> at the
beginning. The tcl library is built with strict ANSI on, and this file
uses C++ style comments.

<LI> If you want to build <code>SimpleTcl</code> and
<code>SimpleTk</code> you may  have to remove the references
to <code>libmoto</code> from the project, not everyone has this library.

<LI> If you want to build for CFM68K you have to create the projects
for the libraries yourself. Take the 68K library projects, set the C++ header
file to "MW_TclHeaderCFM68K", the project type to "cfm68K library" and the
filename to "Tcl-CFM68K.Lib" (and similarly for Tk).
You may also have to modify <code>TclMacNotify.c</code>
because there is an error in the Apple Universal headers (sic!). Read the
comments at the beginning of <code>Mac:Python:macglue.c</code> and copy the
code to <code>TclMacNotify.c</code>. If you get linker errors on <code>GetEvQHdr</code>
you have not done this correctly. <em>XXXX Is this still needed?</em>

<LI> Note that if you use a different release of Tcl and Tk than the ones
I have used you may have to adapt the Python <code>tkresources.rsrc</code> file.
This is easiest done by building <code>SimpleTk</code> and copying the TEXT, ICON
and CRSR resources from it to <code>tkresources.rsrc</code>. This allows
the <code>_tkinter</code> module to work without an installed Tk/Tcl on your
machine.

</UL>

Build first the Tcl library, then
SimpleTcl (test it by typing <code>ls -l</code> in the window you get)
then the Tk library, then SimpleTk (which can again be tested with
<code>ls -l</code>). If this all worked you are all set to try
building Python.

<H2>Building Waste</H2>

You do not need to build the Waste libraries, as Python includes the
source modules themselves. You have to make one modification,
though. In file <code>ICCFMGlue.c</code> in folder <code>Minimal IC
APIs</code>, add the following lines:

<blockquote><pre><code>
#include <Gestalt.h>
#include <Errors.h>
</code></pre></blockquote>

<H2>The organization of the Python source tree</H2>

Time for a short break, while we have a look at the organization of
the Python source tree.  At the top level, we find the following
folders:

<DL>
<DT> build.mac68k.stand
<DD> This is where you will build static 68K interpreters.

<DT> build.mac68k.shared
<DD> This is where you build the CFM68K shared library, interpreter
and applet framework.

<DT> build.macppc.shared
<DD> This is where you build the PPC shared library, interpreter and
applet framework. You can also build the fat applet framework here.

<DT> build.macppc.stand
<DD> This is where you build a nonshared PPC interpreter (optional).

<DT> Demo
<DD> Demo programs that are not Mac-specific. Some of these may not
work, the file <code>README-Mac</code> has some details.

<DT> Extensions
<DD> Extensions to the interpreter that are not Mac-specific. Contains
only the <code>img</code> extension in this distribution. Extensions
are <em>not</em> built here, as they are on Unix, but incorporated in
the core interpreter or built as plugin modules.

<DT> Grammar
<DD> The Python grammar. Included for reference only, you cannot build
the parser on a Mac.

<DT> Include
<DD> Machine-independent header files.

<DT> Modules
<DD> Machine-independent optional modules. Not all of these will work
on the Mac.

<DT> Objects
<DD> Machine-independent code for various objects. Most of these are
not really optional: the interpreter will not function without them.

<DT> Parser
<DD> The Python parser (machine-independent).

<DT> PlugIns
<DD> This is where you build the PPC and CFM68K dynamically-loaded plugin modules.

<DT> Python
<DD> The core interpreter. Most files are machine-independent, some
are unix-specific and not used on the Mac.

<DT> Tools
<DD> Tools for python developers. Contains <code>modulator</code>
which builds skeleton C extension modules and <code>bgen</code> which
generates complete interface modules from information in C header
files. There are some readme files, but more documentation is sorely
needed.

</DL>

All the mac-specific stuff lives in the <code>Mac</code> folder:
<DL>

<DT> Compat
<DD> Unix-compatability routines. Some of these are not used anymore,
since CWGUSI provides a rather complete emulation, but you may need
these if you are trying to build a non-GUSI python.

<DT> Demo
<DD> Mac-specific demo programs, some of them annotated.

<DT> Include
<DD> Mac-specific but compiler-independent include files. 

<DT> Lib
<DD> Mac-specific standard modules. The <code>toolbox</code> folder
contains modules specifically needed with various MacOS toolbox
interface modules.

<DT> Modules
<DD> Mac-specific builtin modules. Theoretically these are all
optional, but some are rather essential (like
<code>macmodule</code>). A lot of these modules are generated with
<code>bgen</code>, in which case the bgen input files are included so
you can attempt to regenerate them or extend them.

<DT> MPW
<DD> MPW-specific files. These have not been used or kept up-to-date
for a long time, so use at your own risk.

<DT> mwerks
<DD> Mwerks-specific sources and headers. Contains glue code for
Pythons shared-library architecture, a replacement for
<code>malloc</code> and a directory with various projects for building
variations on the Python interpreter. The <code>mwerks_*.h</code>
files here are the option-setting files for the various interpreters
and such, comparable to the unix command-line <code>-D</code> options
to the compiler. Each project uses the correct option file as its
"prefix file" in the "C/C++ language" settings. Disabling optional
modules (for the 68K interpreter), building non-GUSI interpreters and
various other things are accomplished by modifying these files (and
possibly changing the list of files included in the project window, of
course).

<DT> Python
<DD> Mac-specific parts of the core interpreter.

<DT> Resources
<DD> Resource files needed to build the interpreter.

<DT> Scripts
<DD> A collection of various mac-specific Python scripts. Some are
essential, some are useful but few are documented, so you will have to
use your imagination to work them out.

<DT> Unsupported
<DD> Modules that are not supported any longer but may still work with a little effort.
</DL>

<H2>Building the 68K interpreter</H2>

If you have all the optional libraries mentioned <A
HREF="#optional">above</A> loaded buildin Python for 68K macs is a
breeze: open the project in the folder <code>build.mac68k.stand</code>
and build it.  Do <em>not</em> run it yet, this will possibly result
in a garbled preferences file. <p>

First remove the <code>Python preferences</code> file from your
preference folder, only if you had an older version of Python
installed.  (this is also what you do if you did not heed the last
sentence of the preceeding paragraph). Next, move the interpreter to
the main Python folder (up one level) and run it there. This will
create a correct initial preferences file. You are now all set, and
your tree should be completely compatible with a binary-only
distribution. Read the release notes
(<code>Relnotes-somethingorother</code>) and
<code>ReadMeOrSuffer</code> in the <code>Mac</code> folder.

<H2>Building the CFM68K interpreter</H2>

Building the CFM68K interpreter is as almost exactly the same as building
the PPC interpreter, with the exception that you should read "CFM68K"
for "PPC" every time. Continue reading with the next section.

<H2>Building the PPC interpreter</H2>

First you build the interpreter, core library and applet skeleton in
folder <code>build.macppc.stand</code>.  The order to build things is
the following:

<DL>
<DT> MWRuntimeStaticLib
<DD> A modified version of the MetroWerks runtime library that is
suitable for Pythons' shared library architecture. The sources all
come from the MW distribution.

<DT> PythonCorePPC
<DD> The shared library that contains the bulk of the interpreter and
its resources. It is a good idea to immedeately put an alias to this
shared library in the <code>Extensions</code> folder of your system
folder.  Do exactly that: put an <em>alias</em> there, copying or
moving the file will cause you grief later.

<DT> PythonPPC
<DD> The interpreter. This is basically a routine to call out to the
shared library. Because of the organization of GUSI it also contains
the Gusi settings resource (together with a ResEdit template, so you
can change the gusi settings should you feel like doing so).  Do
<em>not</em> run it yet, this will possibly result in a garbled
preferences file. <p>

<DT> PythonAppletPPC
<DD> The applet skeleton application. Very similar to
<code>PythonPPC</code>, but it calls to a different entrypoint in the
core library. The <code>mkapplet</code> script will copy this complete
file, and add a <code>'PYC '</code> with the module to generate an
applet. <p>

</DL>

After creating the alias to <code>PythonCorePPC</code> you should move
<code>PythonPPC</code> to the main Python folder. Next you remove any old
<code>Python XXX Preferences</code> file from the <code>Preferences</code> folder
(if you had python installed on your system before) and run the interpreter once
to create the correct preferences file. You should also make an alias
<code>PythonApplet</code> pointing to <code>PythonAppletPPC</code> in the main
Python folder. (again: making an alias is preferrable to copying or moving the
file, since this will cause the correct file to be used if you ever rebuild
PythonAppletPPC). <p>

Next, you have to build the extension modules in the
<code>PlugIns</code> folder. Open each project with <code>.ppc</code> in the
name and build it. After all
the dynamically loaded modules are built you have to create a number
of aliases: some modules live together in a single dynamic
library. Run the <code>MkPluginAliases.py</code> script from
<code>Mac:scripts</code> to create the aliases. <p>

Finally, you must build the standard applets:
<code>EditPythonPrefs</code>, <code>mkapplet</code>, etc. This is
easiest done with the <code>fullbuild</code> script from
<code>Mac:scripts</code>. Answer <em>no</em> to all questions except
when it asks whether to build the applets. <p>

<BLOCKQUOTE>
Actually, the <code>fullbuild</code> script can be used to build
everything, but you need a fully-functional interpreter before you can
use it (and one that isn't rebuilt in the process: you cannot rebuild
a running program). You could copy the 68K interpreter to a different
place and use that to run fullbuild, or use the standalone PPC python
for this. I tend to keep a standalone interpreter in a safe place for
this use only.
</BLOCKQUOTE>

You are all set now, and should read the release notes and
<code>ReadMeOrSuffer</code> file from the <code>Mac</code> folder.

<H2>Rebuilding <code>.exp</code> files for PPC and CFM68K</H2>

Occasionally it may be necessary to rebuild your PythonCore <code>.exp</code>
file, a file that controls which symbols are exported by your PythonCore
shared library. Rebuild it if you get unexpected undefined symbols when you
are building a plugin module. <p>

Rebuilding the .exp file is done by first removing the file and removing the
reference to it in the project (in the "config" section). Next, build PythonCore.
This will create a new .exp file. Edit this file to remove the references to
the symbols <code>__initialize</code>, <code>__terminate</code>, <code>setjmp</code>,
<code>longjmp</code> and <code>__ptmf_null</code>. Next, add the .exp file to the project
again and rebuild PythonCore. <p>

This rather convoluted procedure is needed to ensure that plugin modules don't
accidentally link with those entrypoints from PythonCore, which will not work because
those routines have to be in the same code fragment as they are used from.

<H2>Odds and ends</H2>

Some remarks that I could not fit in elsewhere:

<UL>

<LI> It may be possible to use the <code>PythonCore</code> shared
library to embed Python in another program, if your program can live
with using GUSI for I/O. Use PythonCore in stead of your C library
(or, at the very least, link it before the normal C library). Let me
know whether this works.

<LI> It is possible to build PPC extension modules without building a
complete Python. Take the binary distribution, add folders
<code>Include</code>, <code>Mac:Include</code> and
<code>Mac:mwerks</code> from the source distribution and you should be
all set. A template for a dynamic module can be found in
<code>xx.ppc.<2E></code> or <code>xx.CFM68K.<2E></code>.

<LI> The Python shared library architecture is a variant of the architecture
described as "application with shared libraries and dropins" in the MetroWerks
"Targeting MacOS" documentation. The Python Application and applet-template use
the <code>AppRuntime.Lib</code> runtime library (with properly set CFM
initialization and termination routines). PythonCore uses <code>ShlibRuntime.Lib</code>
and <code>MWRuntimeStaticLib.Lib</code>, which is almost identical to the MW
standard <code>MWRuntimeLib</code>, but not dynamically loaded. This library contains
the part of the runtime that can (or must) be shared between all modules in the program.
It is linked statically into PythonCore (and exported to the applications and plugins)
so we do not have to distribute yet another shared library. Plugin modules use
<code>ShlibRuntime.Lib</code> and obtain the rest from PythonCore. PythonCore uses a
non-standard initialization entry point, <code>__initialize_with_resources</code>, to
be able to obtain resources from the library file lateron. Plugins can do the same or
use the standard <code>__initialize</code> entry point.


</UL>
</BODY>
</HTML>