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357 lines
17 KiB
HTML
<HTML><HEAD><TITLE>Creating a C extension module on the Macintosh</TITLE></HEAD>
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<BODY>
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<H1>Creating a C extension module on the Macintosh</H1>
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<HR>
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This document gives a step-by-step example of how to create a new C
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extension module on the mac. For this example, we will create a module
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to interface to the programmers' API of InterSLIP, a package that
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allows you to use MacTCP (and, hence, all internet services) over a
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modem connection. <p>
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<H2>Prerequisites</H2>
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There are a few things you need to pull this off. First and foremost,
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you need a C development environment. Actually, you need a specific
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development environment, CodeWarrior by <A
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HREF="http://www.metrowerks.com/">MetroWerks</A>. You will probably
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need the latest version. You may be able to get by with an older
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version of CodeWarrior or with another development environment (Up to
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about 1994 python was developed with THINK C, and in the dim past it
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was compiled with MPW C) assuming you have managed to get Python to
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compile under your development environment, but the step-by-step
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character of this document will be lost. <p>
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Next, you need a <A
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HREF="http://www.python.org/python/Sources.html">python source
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distribution</A>. For PowerPC and cfm68k development you can actually
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get by without a full source distribution, using the Development
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distribution (if I have gotten around to putting it together by the time
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you read this). You'll also need a functional python interpreter, and
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the Modulator program (which lives in <CODE>Tools:Modulator</CODE> in
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the standard source distribution). You may also find that Guido's <A
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HREF="http://www.python.org/doc/ext/ext.html">Extending and embedding
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the Python interpreter</A> is a very handy piece of documentation. I
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will skip lots of details that are handled there, like complete
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descriptions of <CODE>Py_ParseTuple</CODE> and such utility routines, or
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the general structure of extension modules. <p>
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<H2>InterSLIP and the C API to it</H2>
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InterSLIP, the utility to which we are going to create a python
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interface, is a system extension that does all the work of connecting
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to the internet over a modem connection. InterSLIP is provided
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free-of-charge by <A
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HREF="http://www.intercon.com/">InterCon</A>. First it connects to
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your modem, then it goes through the whole process of dialling,
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logging in and possibly starting the SLIP software on the remote
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computer and finally it starts with the real work: packing up IP
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packets handed to it by MacTCP and sending them to the remote side
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(and, of course, the reverse action of receiving incoming packets,
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unpacking them and handing them to MacTCP). InterSLIP is a device
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driver, and you control it using a application supplied with it,
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InterSLIP Setup. The API that InterSLIP Setup uses to talk to the
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device driver is published in the documentation and, hence, also
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useable by other applications. <p>
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I happened to have a C interface to the API, which is all ugly
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low-level device-driver calls by itself. The C interface is in <A
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HREF="interslip/InterslipLib.c">InterslipLib.c</A> and <A
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HREF="interslip/InterslipLib.h">InterslipLib.h</A>, we'll
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concentrate here on how to build the Python wrapper module around
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it. Note that this is the "normal" situation when you are writing a
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Python extension module: you have some sort of functionality available
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to C programmers and want to make a Python interface to it. <p>
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<H2>Using Modulator</H2>
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The method we describe in this document, using Modulator, is the best
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method for small interfaces. For large interfaces there is another
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tool, Bgen, which actually generates the complete module without you
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lifting a single finger. Bgen, however, has the disadvantage of having
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a very steep learning curve, so an example using it will have to wait
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until another document, when I have more time. <p>
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First, let us look at the <A
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HREF="interslip/InterslipLib.h">InterslipLib.h</A> header file,
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and see that the whole interface consists of six routines:
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<CODE>is_open</CODE>, <CODE>is_connect</CODE>,
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<CODE>is_disconnect</CODE>, <CODE>is_status</CODE>,
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<CODE>is_getconfig</CODE> and <CODE>is_setconfig</CODE>. Our first
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step will be to create a skeleton file <A
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HREF="interslip/@interslipmodule.c">@interslipmodule.c</A>, a
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dummy module that will contain all the glue code that python expects
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of an extension module. Creating this glue code is a breeze with
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modulator, a tool that we only have to tell that we want to create a
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module with methods of the six names above and that will create the
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complete skeleton C code for us. <p>
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Why call this dummy module <CODE>@interslipmodule.c</CODE> and not
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<CODE>interslipmodule.c</CODE>? Self-preservation: if ever you happen
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to repeat the whole process after you have actually turned the
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skeleton module into a real module you would overwrite your
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hand-written code. By calling the dummy module a different name you
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have to make <EM>two</EM> mistakes in a row before you do this. <p>
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If you installed Tk support when you installed Python this is extremely
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simple. You start modulator and are provided with a form in which you
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fill out the details of the module you are creating. <p>
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<IMG SRC="html.icons/modulator.gif" ALIGN=CENTER><p>
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You'll need to supply a module name (<CODE>interslip</CODE>, in our
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case), a module abbreviation (<CODE>pyis</CODE>, which is used as a
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prefix to all the routines and data structures modulator will create
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for you) and you enter the names of all the methods your module will
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export (the list above, with <CODE>is_</CODE> stripped off). Note that
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we use <CODE>pyis</CODE> as the prefix instead of the more logical
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<CODE>is</CODE>, since the latter would cause our routine names to
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collide with those in the API we are interfacing to! The method names
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are the names as seen by the python program, and the C routine names
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will have the prefix and an underscore prepended. Modulator can do
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much more, like generating code for objects and such, but that is a
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topic for a later example. <p>
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Once you have told modulator all about the module you want to create
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you press "check", which checks that you haven't omitted any
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information and "Generate code". This will prompt you for a C output
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file and generate your module for you. <p>
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<H2>Using Modulator without Tk</H2>
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Modulator actually uses a two-stage process to create your code: first
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the information you provided is turned into a number of python
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statements and then these statements are executed to generate your
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code. This is done so that you can even use modulator if you don't
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have Tk support in Python: you'll just have to write the modulator
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python statements by hand (about 10 lines, in our example) and
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modulator will generate the C code (about 150 lines, in our
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example). Here is the Python code you'll want to execute to generate
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our skeleton module: <p>
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<CODE><PRE>
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import addpack
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addpack.addpack('Tools')
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addpack.addpack('modulator')
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import genmodule
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m = genmodule.module()
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m.name = 'interslip'
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m.abbrev = 'pyis'
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m.methodlist = ['open', 'connect', 'disconnect', 'status', \
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'getconfig', 'setconfig']
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m.objects = []
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fp = open('@interslipmodule.c', 'w')
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genmodule.write(fp, m)
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</PRE></CODE>
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Drop this program on the python interpreter and out will come your
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skeleton module. <p>
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Now, rename the file to interslipmodule.c and you're all set to start
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developing. The module is complete in the sense that it should
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compile, and that if you import it in a python program you will see
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all the methods. It is, of course, not yet complete in a functional
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way... <p>
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<H2>Adding a module to Classic 68K Python</H2>
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What you do now depends on whether you're developing for PowerPC (or
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for CFM68K) or for "traditional" mac. For a traditional 68K Python,
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you will have to add your new module to the project file of the Python
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interpreter, and you have to edit "config.c" to add the module to the
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set of builtin modules. In config.c you will add the module at two
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places: near the start of the file there is a list of external
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declarations for all init() routines. Add a line of the form
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<CODE><PRE>
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extern void initinterslip();
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</PRE></CODE>
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here. Further down the file there is an array that is initialized with
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modulename/initfunction pairs. Add a line of the form
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<CODE><PRE>
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{"interslip", initinterslip},
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</PRE></CODE>
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here. You may want to bracket these two lines with
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<CODE><PRE>
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#ifdef USE_INTERSLIP
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#endif
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</PRE></CODE>
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lines, that way you can easily control whether the module is
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incorporated into python at compile time. If you decide to do the
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latter edit your config file (you can find the name in the "C/C++
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language" section of the MW preferences dialog, it will probably be
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"mwerks_nonshared_config.h") and add a
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<CODE><PRE>
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#define USE_INTERSLIP
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</PRE></CODE>
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Make the new interpreter and check that you can import the module, see
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the methods (with "dir(interslip)") and call them. <p>
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<H2>Creating a PowerPC plugin module</H2>
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For PowerPC development you could follow the same path, but it is
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actually a better idea to use a dynamically loadable module. The
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advantage of dynamically loadable modules is that they are not loaded
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until a python program actually uses them (resulting in less memory
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usage by the interpreter) and that development is a lot simpler (since
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your projects will all be smaller). Moreover, you can distribute a
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plugin module by itself without haveing to distribute a complete
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python interpreter. <p>
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Go to the "PlugIns" folder and copy the files xx.prj,
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and xx.prj.exp to interslipmodule.prj and
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interslipmodule.prj.exp, respectively. Edit
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interslipmodule.prj.exp and change the name of the exported routine
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"initxx" to "initinterslip". Open interslipmodule.prj with CodeWarrior,
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remove the file xxmodule.c and add interslipmodule.c and make a number
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of adjustments to the preferences:
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<UL>
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<LI> in PPC target, set the output file name to "interslipmodule.pcc.slb",
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<LI> in cfm68k target set the output file name to "interslipmodule.cfm68k.slb".
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</UL>
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Next, compile and link your module, fire up python and do the same
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tests as for 68K python. <p>
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<H2>Getting the module to do real work</H2>
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So far, so good. In half an hour or so we have created a complete new
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extension module for Python. The downside, however, is that the module
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does not do anything useful. So, in the next half hour we will turn
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our beautiful skeleton module into something that is at least as
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beautiful but also gets some serious work done. For this once,
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<EM>I</EM> have spent that half hour for you, and you can see the
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results in <A
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HREF="interslip/interslipmodule.c">interslipmodule.c</A>. <p>
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We add
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<CODE><PRE>
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#include "InterslipLib.h"
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#include "macglue.h"
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</PRE></CODE>
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to the top of the file, and work our way through each of the methods
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to add the functionality needed. Starting with open, we fill in the
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template docstring, the value accessible from Python by looking at
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<CODE>interslip.open.__doc__</CODE>. There are not many tools using
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this information at the moment, but as soon as class browsers for
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python become available having this minimal documentation available is
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a good idea. We put "Load the interslip driver" as the comment
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here. <p>
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Next, we tackle the body of <CODE>pyis_open()</CODE>. Since it has no
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arguments and no return value we don't need to mess with that, we just
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have to add a call to <CODE>is_open()</CODE> and check the return for
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an error code, in which case we raise an error:
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<CODE><PRE>
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err = is_open();
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if ( err ) {
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PyErr_Mac(ErrorObject, err);
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return NULL;
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}
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</PRE></CODE>
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The routine <CODE><A NAME="PyErr_Mac">PyErr_Mac()</A></CODE> is a
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useful routine that raises the exception passed as its first
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argument. The data passed with the exception is based on the standard
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MacOS error code given, and PyErr_Mac() attempts to locate a textual
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description of the error code (which sure beats the "error -14021"
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messages that so many macintosh applications tell their poor
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users). <p>
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We will skip pyis_connect and pyis_disconnect here, which are pretty
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much identical to pyis_open: no arguments, no return value, just a
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call and an error check. With pyis_status() things get interesting
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again: this call still takes 3 arguments, and all happen to be values
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returned (a numeric connection status indicator, a message sequence
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number and a pointer to the message itself, in MacOS pascal-style
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string form). We declare variables to receive the returned values, do
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the call, check the error and format the return value. <p>
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Building the return value is done using <CODE><A
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NAME="Py_BuildValue">Py_BuildValue</A></CODE>:
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<CODE><PRE>
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return Py_BuildValue("iiO&", (int)status, (int)seqnum, PyMac_BuildStr255, message);
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</PRE></CODE>
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Py_BuildValue() is a very handy routine that builds tuples according
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to a format string, somewhat similar to the way <CODE>printf()</CODE>
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works. The format string specifies the arguments expected after the
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string, and turns them from C objects into python objects. The
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resulting objects are put in a python tuple object and returned. The
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"i" format specifier signifies an "int" (hence the cast: status and
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seqnum are declared as "long", which is what the is_status() routine
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wants, and even though we use a 4-byte project there is really no
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reason not to put the cast here). Py_BuildValue and its counterpart
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Py_ParseTuple have format codes for all the common C types like ints,
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shorts, C-strings, floats, etc. Also, there is a nifty escape
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mechanism to format values about which is does not know. This is
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invoked by the "O&" format: it expects two arguments, a routine
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pointer and an int-sized data object. The routine is called with the
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object as a parameter and it should return a python objects
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representing the data. <CODE>Macglue.h</CODE> declares a number of
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such formatting routines for common MacOS objects like Str255, FSSpec,
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OSType, Rect, etc. See the comments in the include file for
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details. <p>
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<CODE>Pyis_getconfig()</CODE> is again similar to pyis_getstatus, only
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two minor points are worth noting here. First, the C API return the
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input and output baudrate squashed together into a single 4-byte
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long. We separate them out before returning the result to
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python. Second, whereas the status call returned us a pointer to a
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<CODE>Str255</CODE> it kept we are responsible for allocating the
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<CODE>Str255</CODE> for getconfig. This is something that would have
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been easy to get wrong had we not used prototypes everywhere. Morale:
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always try to include the header files for interfaces to libraries and
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other stuff, so that the compiler can catch any mistakes you make. <p>
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<CODE>Pyis_setconfig()</CODE> finally shows off
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<CODE>Py_ParseTuple</CODE>, the companion function to
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<CODE>Py_BuildValue</CODE>. You pass it the argument tuple "args"
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that your method gets as its second argument, a format string and
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pointers to where you want the arguments stored. Again, standard C
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types such as strings and integers Py_ParseTuple knows all about and
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through the "O&" format you can extend the functionality. For each
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"O&" you pass a function pointer and a pointer to a data area. The
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function will be called with a PyObject pointer and your data pointer
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and it should convert the python object to the correct C type. It
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should return 1 on success and 0 on failure. Again, a number of
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converters for standard MacOS types are provided, and declared in
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<CODE>macglue.h</CODE>. <p>
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Next in our source file comes the method table for our module, which
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has been generated by modulator (and it did a good job too!), but
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which is worth looking at for a moment. Entries are of the form
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<CODE><PRE>
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{"open", pyis_open, 1, pyis_open__doc__},
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</PRE></CODE>
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where the entries are python method name, C routine pointer, flags and
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docstring pointer. The value to note is the 1 for the flags: this
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signifies that you want to use "new-style" Py_ParseTuple behaviour. If
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you are writing a new module always use this, but if you are modifying
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old code which calls something like <CODE>getargs(args, "(ii)",
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...)</CODE> you will have to put zero here. See "extending and
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embedding" or possibly the getargs.c source file for details if you
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need them. <p>
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Finally, we add some code to the init module, to put some symbolic
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constants (codes that can by returned by the status method) in the
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module dictionary, so the python program can use "interslip.RUN"
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instead of the cryptic "4" when it wants to check that the interslip
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driver is in RUN state. Modulator has already generated code to get at
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the module dictionary using PyModule_GetDict() to store the exception
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object, so we simply call
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<CODE><PRE>
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PyDict_SetItemString(d, "IDLE", PyInt_FromLong(IS_IDLE));
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</PRE></CODE>
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for each of our items. Since the last bit of code in our init routine
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checks for previous errors with <CODE>PyErr_Occurred()</CODE> and
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since <CODE>PyDict_SetItemString()</CODE> gracefully handles the case
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of <CODE>NULL</CODE> parameters (if <CODE>PyInt_FromLong()</CODE>
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failed, for instance) we don't have to do error checking here. In some
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other cases you may have to do error checking yourself. <p>
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This concludes our crash-course on writing Python extensions in C on
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the Macintosh. If you are not done reading yet I suggest you look
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back at the <A HREF="index.html">MacPython Crashcourse index</A> to
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find another topic to study. <p>
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