mirror of https://github.com/python/cpython
320 lines
12 KiB
TeX
320 lines
12 KiB
TeX
\chapter{Embedding Python in Another Application
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\label{embedding}}
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The previous chapters discussed how to extend Python, that is, how to
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extend the functionality of Python by attaching a library of C
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functions to it. It is also possible to do it the other way around:
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enrich your C/\Cpp{} application by embedding Python in it. Embedding
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provides your application with the ability to implement some of the
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functionality of your application in Python rather than C or \Cpp.
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This can be used for many purposes; one example would be to allow
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users to tailor the application to their needs by writing some scripts
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in Python. You can also use it yourself if some of the functionality
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can be written in Python more easily.
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Embedding Python is similar to extending it, but not quite. The
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difference is that when you extend Python, the main program of the
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application is still the Python interpreter, while if you embed
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Python, the main program may have nothing to do with Python ---
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instead, some parts of the application occasionally call the Python
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interpreter to run some Python code.
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So if you are embedding Python, you are providing your own main
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program. One of the things this main program has to do is initialize
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the Python interpreter. At the very least, you have to call the
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function \cfunction{Py_Initialize()} (on Mac OS, call
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\cfunction{PyMac_Initialize()} instead). There are optional calls to
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pass command line arguments to Python. Then later you can call the
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interpreter from any part of the application.
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There are several different ways to call the interpreter: you can pass
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a string containing Python statements to
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\cfunction{PyRun_SimpleString()}, or you can pass a stdio file pointer
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and a file name (for identification in error messages only) to
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\cfunction{PyRun_SimpleFile()}. You can also call the lower-level
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operations described in the previous chapters to construct and use
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Python objects.
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A simple demo of embedding Python can be found in the directory
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\file{Demo/embed/} of the source distribution.
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\begin{seealso}
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\seetitle[../api/api.html]{Python/C API Reference Manual}{The
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details of Python's C interface are given in this manual.
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A great deal of necessary information can be found here.}
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\end{seealso}
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\section{Very High Level Embedding
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\label{high-level-embedding}}
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The simplest form of embedding Python is the use of the very
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high level interface. This interface is intended to execute a
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Python script without needing to interact with the application
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directly. This can for example be used to perform some operation
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on a file.
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\begin{verbatim}
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#include <Python.h>
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int
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main(int argc, char *argv[])
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{
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Py_Initialize();
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PyRun_SimpleString("from time import time,ctime\n"
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"print 'Today is',ctime(time())\n");
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Py_Finalize();
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return 0;
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}
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\end{verbatim}
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The above code first initializes the Python interpreter with
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\cfunction{Py_Initialize()}, followed by the execution of a hard-coded
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Python script that print the date and time. Afterwards, the
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\cfunction{Py_Finalize()} call shuts the interpreter down, followed by
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the end of the program. In a real program, you may want to get the
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Python script from another source, perhaps a text-editor routine, a
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file, or a database. Getting the Python code from a file can better
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be done by using the \cfunction{PyRun_SimpleFile()} function, which
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saves you the trouble of allocating memory space and loading the file
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contents.
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\section{Beyond Very High Level Embedding: An overview
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\label{lower-level-embedding}}
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The high level interface gives you the ability to execute
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arbitrary pieces of Python code from your application, but
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exchanging data values is quite cumbersome to say the least. If
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you want that, you should use lower level calls. At the cost of
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having to write more C code, you can achieve almost anything.
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It should be noted that extending Python and embedding Python
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is quite the same activity, despite the different intent. Most
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topics discussed in the previous chapters are still valid. To
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show this, consider what the extension code from Python to C
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really does:
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\begin{enumerate}
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\item Convert data values from Python to C,
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\item Perform a function call to a C routine using the
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converted values, and
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\item Convert the data values from the call from C to Python.
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\end{enumerate}
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When embedding Python, the interface code does:
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\begin{enumerate}
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\item Convert data values from C to Python,
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\item Perform a function call to a Python interface routine
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using the converted values, and
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\item Convert the data values from the call from Python to C.
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\end{enumerate}
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As you can see, the data conversion steps are simply swapped to
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accomodate the different direction of the cross-language transfer.
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The only difference is the routine that you call between both
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data conversions. When extending, you call a C routine, when
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embedding, you call a Python routine.
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This chapter will not discuss how to convert data from Python
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to C and vice versa. Also, proper use of references and dealing
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with errors is assumed to be understood. Since these aspects do not
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differ from extending the interpreter, you can refer to earlier
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chapters for the required information.
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\section{Pure Embedding
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\label{pure-embedding}}
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The first program aims to execute a function in a Python
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script. Like in the section about the very high level interface,
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the Python interpreter does not directly interact with the
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application (but that will change in th next section).
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The code to run a function defined in a Python script is:
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\verbatiminput{run-func.c}
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This code loads a Python script using \code{argv[1]}, and calls the
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function named in \code{argv[2]}. Its integer arguments are the other
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values of the \code{argv} array. If you compile and link this
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program (let's call the finished executable \program{call}), and use
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it to execute a Python script, such as:
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\begin{verbatim}
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def multiply(a,b):
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print "Thy shall add", a, "times", b
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c = 0
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for i in range(0, a):
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c = c + b
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return c
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\end{verbatim}
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then the result should be:
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\begin{verbatim}
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$ call multiply 3 2
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Thy shall add 3 times 2
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Result of call: 6
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\end{verbatim} % $
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Although the program is quite large for its functionality, most of the
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code is for data conversion between Python and C, and for error
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reporting. The interesting part with respect to embedding Python
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starts with
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\begin{verbatim}
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Py_Initialize();
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pName = PyString_FromString(argv[1]);
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/* Error checking of pName left out */
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pModule = PyImport_Import(pName);
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\end{verbatim}
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After initializing the interpreter, the script is loaded using
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\cfunction{PyImport_Import()}. This routine needs a Python string
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as its argument, which is constructed using the
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\cfunction{PyString_FromString()} data conversion routine.
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\begin{verbatim}
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pDict = PyModule_GetDict(pModule);
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/* pDict is a borrowed reference */
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pFunc = PyDict_GetItemString(pDict, argv[2]);
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/* pFun is a borrowed reference */
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if (pFunc && PyCallable_Check(pFunc)) {
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...
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}
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\end{verbatim}
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Once the script is loaded, its dictionary is retrieved with
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\cfunction{PyModule_GetDict()}. The dictionary is then searched using
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the normal dictionary access routines for the function name. If the
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name exists, and the object retunred is callable, you can safely
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assume that it is a function. The program then proceeds by
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constructing a tuple of arguments as normal. The call to the python
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function is then made with:
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\begin{verbatim}
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pValue = PyObject_CallObject(pFunc, pArgs);
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\end{verbatim}
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Upon return of the function, \code{pValue} is either \NULL{} or it
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contains a reference to the return value of the function. Be sure to
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release the reference after examining the value.
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\section{Extending Embedded Python
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\label{extending-with-embedding}}
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Until now, the embedded Python interpreter had no access to
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functionality from the application itself. The Python API allows this
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by extending the embedded interpreter. That is, the embedded
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interpreter gets extended with routines provided by the application.
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While it sounds complex, it is not so bad. Simply forget for a while
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that the application starts the Python interpreter. Instead, consider
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the application to be a set of subroutines, and write some glue code
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that gives Python access to those routines, just like you would write
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a normal Python extension. For example:
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\begin{verbatim}
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static int numargs=0;
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/* Return the number of arguments of the application command line */
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static PyObject*
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emb_numargs(PyObject *self, PyObject *args)
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{
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if(!PyArg_ParseTuple(args, ":numargs"))
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return NULL;
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return Py_BuildValue("i", numargs);
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}
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static PyMethodDef EmbMethods[] = {
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{"numargs", emb_numargs, METH_VARARGS,
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"Return the number of arguments received by the process."},
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{NULL, NULL, 0, NULL}
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};
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\end{verbatim}
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Insert the above code just above the \cfunction{main()} function.
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Also, insert the following two statements directly after
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\cfunction{Py_Initialize()}:
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\begin{verbatim}
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numargs = argc;
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Py_InitModule("emb", EmbMethods);
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\end{verbatim}
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These two lines initialize the \code{numargs} variable, and make the
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\function{emb.numargs()} function accessible to the embedded Python
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interpreter. With these extensions, the Python script can do things
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like
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\begin{verbatim}
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import emb
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print "Number of arguments", emb.numargs()
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\end{verbatim}
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In a real application, the methods will expose an API of the
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application to Python.
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%\section{For the future}
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%
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%You don't happen to have a nice library to get textual
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%equivalents of numeric values do you :-) ?
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%Callbacks here ? (I may be using information from that section
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%?!)
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%threads
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%code examples do not really behave well if errors happen
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% (what to watch out for)
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\section{Embedding Python in \Cpp
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\label{embeddingInCplusplus}}
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It is also possible to embed Python in a \Cpp{} program; precisely how this
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is done will depend on the details of the \Cpp{} system used; in general you
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will need to write the main program in \Cpp, and use the \Cpp{} compiler
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to compile and link your program. There is no need to recompile Python
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itself using \Cpp.
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\section{Linking Requirements
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\label{link-reqs}}
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While the \program{configure} script shipped with the Python sources
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will correctly build Python to export the symbols needed by
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dynamically linked extensions, this is not automatically inherited by
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applications which embed the Python library statically, at least on
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\UNIX. This is an issue when the application is linked to the static
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runtime library (\file{libpython.a}) and needs to load dynamic
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extensions (implemented as \file{.so} files).
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The problem is that some entry points are defined by the Python
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runtime solely for extension modules to use. If the embedding
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application does not use any of these entry points, some linkers will
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not include those entries in the symbol table of the finished
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executable. Some additional options are needed to inform the linker
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not to remove these symbols.
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Determining the right options to use for any given platform can be
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quite difficult, but fortunately the Python configuration already has
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those values. To retrieve them from an installed Python interpreter,
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start an interactive interpreter and have a short session like this:
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\begin{verbatim}
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>>> import distutils.sysconfig
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>>> distutils.sysconfig.get_config_var('LINKFORSHARED')
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'-Xlinker -export-dynamic'
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\end{verbatim}
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\refstmodindex{distutils.sysconfig}
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The contents of the string presented will be the options that should
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be used. If the string is empty, there's no need to add any
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additional options. The \constant{LINKFORSHARED} definition
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corresponds to the variable of the same name in Python's top-level
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\file{Makefile}.
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