628 lines
28 KiB
TeX
628 lines
28 KiB
TeX
\chapter{Introduction \label{intro}}
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The Application Programmer's Interface to Python gives C and
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\Cpp{} programmers access to the Python interpreter at a variety of
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levels. The API is equally usable from \Cpp, but for brevity it is
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generally referred to as the Python/C API. There are two
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fundamentally different reasons for using the Python/C API. The first
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reason is to write \emph{extension modules} for specific purposes;
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these are C modules that extend the Python interpreter. This is
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probably the most common use. The second reason is to use Python as a
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component in a larger application; this technique is generally
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referred to as \dfn{embedding} Python in an application.
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Writing an extension module is a relatively well-understood process,
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where a ``cookbook'' approach works well. There are several tools
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that automate the process to some extent. While people have embedded
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Python in other applications since its early existence, the process of
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embedding Python is less straightforward than writing an extension.
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Many API functions are useful independent of whether you're embedding
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or extending Python; moreover, most applications that embed Python
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will need to provide a custom extension as well, so it's probably a
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good idea to become familiar with writing an extension before
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attempting to embed Python in a real application.
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\section{Include Files \label{includes}}
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All function, type and macro definitions needed to use the Python/C
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API are included in your code by the following line:
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\begin{verbatim}
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#include "Python.h"
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\end{verbatim}
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This implies inclusion of the following standard headers:
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\code{<stdio.h>}, \code{<string.h>}, \code{<errno.h>},
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\code{<limits.h>}, and \code{<stdlib.h>} (if available).
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\begin{notice}[warning]
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Since Python may define some pre-processor definitions which affect
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the standard headers on some systems, you \emph{must} include
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\file{Python.h} before any standard headers are included.
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\end{notice}
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All user visible names defined by Python.h (except those defined by
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the included standard headers) have one of the prefixes \samp{Py} or
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\samp{_Py}. Names beginning with \samp{_Py} are for internal use by
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the Python implementation and should not be used by extension writers.
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Structure member names do not have a reserved prefix.
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\strong{Important:} user code should never define names that begin
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with \samp{Py} or \samp{_Py}. This confuses the reader, and
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jeopardizes the portability of the user code to future Python
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versions, which may define additional names beginning with one of
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these prefixes.
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The header files are typically installed with Python. On \UNIX, these
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are located in the directories
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\file{\envvar{prefix}/include/python\var{version}/} and
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\file{\envvar{exec_prefix}/include/python\var{version}/}, where
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\envvar{prefix} and \envvar{exec_prefix} are defined by the
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corresponding parameters to Python's \program{configure} script and
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\var{version} is \code{sys.version[:3]}. On Windows, the headers are
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installed in \file{\envvar{prefix}/include}, where \envvar{prefix} is
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the installation directory specified to the installer.
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To include the headers, place both directories (if different) on your
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compiler's search path for includes. Do \emph{not} place the parent
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directories on the search path and then use
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\samp{\#include <python\shortversion/Python.h>}; this will break on
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multi-platform builds since the platform independent headers under
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\envvar{prefix} include the platform specific headers from
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\envvar{exec_prefix}.
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\Cpp{} users should note that though the API is defined entirely using
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C, the header files do properly declare the entry points to be
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\code{extern "C"}, so there is no need to do anything special to use
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the API from \Cpp.
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\section{Objects, Types and Reference Counts \label{objects}}
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Most Python/C API functions have one or more arguments as well as a
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return value of type \ctype{PyObject*}. This type is a pointer
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to an opaque data type representing an arbitrary Python
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object. Since all Python object types are treated the same way by the
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Python language in most situations (e.g., assignments, scope rules,
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and argument passing), it is only fitting that they should be
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represented by a single C type. Almost all Python objects live on the
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heap: you never declare an automatic or static variable of type
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\ctype{PyObject}, only pointer variables of type \ctype{PyObject*} can
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be declared. The sole exception are the type objects\obindex{type};
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since these must never be deallocated, they are typically static
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\ctype{PyTypeObject} objects.
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All Python objects (even Python integers) have a \dfn{type} and a
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\dfn{reference count}. An object's type determines what kind of object
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it is (e.g., an integer, a list, or a user-defined function; there are
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many more as explained in the \citetitle[../ref/ref.html]{Python
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Reference Manual}). For each of the well-known types there is a macro
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to check whether an object is of that type; for instance,
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\samp{PyList_Check(\var{a})} is true if (and only if) the object
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pointed to by \var{a} is a Python list.
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\subsection{Reference Counts \label{refcounts}}
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The reference count is important because today's computers have a
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finite (and often severely limited) memory size; it counts how many
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different places there are that have a reference to an object. Such a
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place could be another object, or a global (or static) C variable, or
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a local variable in some C function. When an object's reference count
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becomes zero, the object is deallocated. If it contains references to
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other objects, their reference count is decremented. Those other
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objects may be deallocated in turn, if this decrement makes their
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reference count become zero, and so on. (There's an obvious problem
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with objects that reference each other here; for now, the solution is
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``don't do that.'')
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Reference counts are always manipulated explicitly. The normal way is
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to use the macro \cfunction{Py_INCREF()}\ttindex{Py_INCREF()} to
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increment an object's reference count by one, and
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\cfunction{Py_DECREF()}\ttindex{Py_DECREF()} to decrement it by
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one. The \cfunction{Py_DECREF()} macro is considerably more complex
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than the incref one, since it must check whether the reference count
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becomes zero and then cause the object's deallocator to be called.
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The deallocator is a function pointer contained in the object's type
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structure. The type-specific deallocator takes care of decrementing
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the reference counts for other objects contained in the object if this
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is a compound object type, such as a list, as well as performing any
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additional finalization that's needed. There's no chance that the
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reference count can overflow; at least as many bits are used to hold
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the reference count as there are distinct memory locations in virtual
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memory (assuming \code{sizeof(long) >= sizeof(char*)}). Thus, the
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reference count increment is a simple operation.
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It is not necessary to increment an object's reference count for every
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local variable that contains a pointer to an object. In theory, the
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object's reference count goes up by one when the variable is made to
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point to it and it goes down by one when the variable goes out of
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scope. However, these two cancel each other out, so at the end the
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reference count hasn't changed. The only real reason to use the
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reference count is to prevent the object from being deallocated as
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long as our variable is pointing to it. If we know that there is at
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least one other reference to the object that lives at least as long as
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our variable, there is no need to increment the reference count
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temporarily. An important situation where this arises is in objects
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that are passed as arguments to C functions in an extension module
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that are called from Python; the call mechanism guarantees to hold a
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reference to every argument for the duration of the call.
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However, a common pitfall is to extract an object from a list and
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hold on to it for a while without incrementing its reference count.
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Some other operation might conceivably remove the object from the
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list, decrementing its reference count and possible deallocating it.
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The real danger is that innocent-looking operations may invoke
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arbitrary Python code which could do this; there is a code path which
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allows control to flow back to the user from a \cfunction{Py_DECREF()},
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so almost any operation is potentially dangerous.
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A safe approach is to always use the generic operations (functions
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whose name begins with \samp{PyObject_}, \samp{PyNumber_},
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\samp{PySequence_} or \samp{PyMapping_}). These operations always
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increment the reference count of the object they return. This leaves
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the caller with the responsibility to call
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\cfunction{Py_DECREF()} when they are done with the result; this soon
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becomes second nature.
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\subsubsection{Reference Count Details \label{refcountDetails}}
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The reference count behavior of functions in the Python/C API is best
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explained in terms of \emph{ownership of references}. Ownership
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pertains to references, never to objects (objects are not owned: they
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are always shared). "Owning a reference" means being responsible for
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calling Py_DECREF on it when the reference is no longer needed.
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Ownership can also be transferred, meaning that the code that receives
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ownership of the reference then becomes responsible for eventually
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decref'ing it by calling \cfunction{Py_DECREF()} or
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\cfunction{Py_XDECREF()} when it's no longer needed---or passing on
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this responsibility (usually to its caller).
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When a function passes ownership of a reference on to its caller, the
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caller is said to receive a \emph{new} reference. When no ownership
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is transferred, the caller is said to \emph{borrow} the reference.
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Nothing needs to be done for a borrowed reference.
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Conversely, when a calling function passes it a reference to an
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object, there are two possibilities: the function \emph{steals} a
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reference to the object, or it does not. \emph{Stealing a reference}
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means that when you pass a reference to a function, that function
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assumes that it now owns that reference, and you are not responsible
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for it any longer.
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Few functions steal references; the two notable exceptions are
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\cfunction{PyList_SetItem()}\ttindex{PyList_SetItem()} and
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\cfunction{PyTuple_SetItem()}\ttindex{PyTuple_SetItem()}, which
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steal a reference to the item (but not to the tuple or list into which
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the item is put!). These functions were designed to steal a reference
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because of a common idiom for populating a tuple or list with newly
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created objects; for example, the code to create the tuple \code{(1,
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2, "three")} could look like this (forgetting about error handling for
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the moment; a better way to code this is shown below):
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\begin{verbatim}
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PyObject *t;
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t = PyTuple_New(3);
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PyTuple_SetItem(t, 0, PyInt_FromLong(1L));
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PyTuple_SetItem(t, 1, PyInt_FromLong(2L));
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PyTuple_SetItem(t, 2, PyString_FromString("three"));
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\end{verbatim}
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Here, \cfunction{PyInt_FromLong()} returns a new reference which is
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immediately stolen by \cfunction{PyTuple_SetItem()}. When you want to
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keep using an object although the reference to it will be stolen,
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use \cfunction{Py_INCREF()} to grab another reference before calling the
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reference-stealing function.
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Incidentally, \cfunction{PyTuple_SetItem()} is the \emph{only} way to
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set tuple items; \cfunction{PySequence_SetItem()} and
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\cfunction{PyObject_SetItem()} refuse to do this since tuples are an
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immutable data type. You should only use
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\cfunction{PyTuple_SetItem()} for tuples that you are creating
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yourself.
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Equivalent code for populating a list can be written using
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\cfunction{PyList_New()} and \cfunction{PyList_SetItem()}.
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However, in practice, you will rarely use these ways of
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creating and populating a tuple or list. There's a generic function,
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\cfunction{Py_BuildValue()}, that can create most common objects from
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C values, directed by a \dfn{format string}. For example, the
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above two blocks of code could be replaced by the following (which
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also takes care of the error checking):
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\begin{verbatim}
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PyObject *tuple, *list;
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tuple = Py_BuildValue("(iis)", 1, 2, "three");
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list = Py_BuildValue("[iis]", 1, 2, "three");
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\end{verbatim}
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It is much more common to use \cfunction{PyObject_SetItem()} and
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friends with items whose references you are only borrowing, like
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arguments that were passed in to the function you are writing. In
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that case, their behaviour regarding reference counts is much saner,
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since you don't have to increment a reference count so you can give a
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reference away (``have it be stolen''). For example, this function
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sets all items of a list (actually, any mutable sequence) to a given
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item:
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\begin{verbatim}
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int
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set_all(PyObject *target, PyObject *item)
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{
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int i, n;
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n = PyObject_Length(target);
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if (n < 0)
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return -1;
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for (i = 0; i < n; i++) {
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PyObject *index = PyInt_FromLong(i);
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if (!index)
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return -1;
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if (PyObject_SetItem(target, index, item) < 0)
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return -1;
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Py_DECREF(index);
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}
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return 0;
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}
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\end{verbatim}
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\ttindex{set_all()}
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The situation is slightly different for function return values.
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While passing a reference to most functions does not change your
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ownership responsibilities for that reference, many functions that
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return a reference to an object give you ownership of the reference.
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The reason is simple: in many cases, the returned object is created
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on the fly, and the reference you get is the only reference to the
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object. Therefore, the generic functions that return object
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references, like \cfunction{PyObject_GetItem()} and
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\cfunction{PySequence_GetItem()}, always return a new reference (the
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caller becomes the owner of the reference).
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It is important to realize that whether you own a reference returned
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by a function depends on which function you call only --- \emph{the
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plumage} (the type of the object passed as an
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argument to the function) \emph{doesn't enter into it!} Thus, if you
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extract an item from a list using \cfunction{PyList_GetItem()}, you
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don't own the reference --- but if you obtain the same item from the
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same list using \cfunction{PySequence_GetItem()} (which happens to
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take exactly the same arguments), you do own a reference to the
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returned object.
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Here is an example of how you could write a function that computes the
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sum of the items in a list of integers; once using
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\cfunction{PyList_GetItem()}\ttindex{PyList_GetItem()}, and once using
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\cfunction{PySequence_GetItem()}\ttindex{PySequence_GetItem()}.
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\begin{verbatim}
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long
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sum_list(PyObject *list)
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{
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int i, n;
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long total = 0;
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PyObject *item;
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n = PyList_Size(list);
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if (n < 0)
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return -1; /* Not a list */
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for (i = 0; i < n; i++) {
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item = PyList_GetItem(list, i); /* Can't fail */
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if (!PyInt_Check(item)) continue; /* Skip non-integers */
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total += PyInt_AsLong(item);
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}
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return total;
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}
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\end{verbatim}
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\ttindex{sum_list()}
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\begin{verbatim}
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long
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sum_sequence(PyObject *sequence)
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{
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int i, n;
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long total = 0;
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PyObject *item;
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n = PySequence_Length(sequence);
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if (n < 0)
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return -1; /* Has no length */
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for (i = 0; i < n; i++) {
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item = PySequence_GetItem(sequence, i);
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if (item == NULL)
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return -1; /* Not a sequence, or other failure */
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if (PyInt_Check(item))
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total += PyInt_AsLong(item);
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Py_DECREF(item); /* Discard reference ownership */
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}
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return total;
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}
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\end{verbatim}
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\ttindex{sum_sequence()}
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\subsection{Types \label{types}}
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There are few other data types that play a significant role in
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the Python/C API; most are simple C types such as \ctype{int},
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\ctype{long}, \ctype{double} and \ctype{char*}. A few structure types
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are used to describe static tables used to list the functions exported
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by a module or the data attributes of a new object type, and another
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is used to describe the value of a complex number. These will
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be discussed together with the functions that use them.
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\section{Exceptions \label{exceptions}}
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The Python programmer only needs to deal with exceptions if specific
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error handling is required; unhandled exceptions are automatically
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propagated to the caller, then to the caller's caller, and so on, until
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they reach the top-level interpreter, where they are reported to the
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user accompanied by a stack traceback.
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For C programmers, however, error checking always has to be explicit.
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All functions in the Python/C API can raise exceptions, unless an
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explicit claim is made otherwise in a function's documentation. In
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general, when a function encounters an error, it sets an exception,
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discards any object references that it owns, and returns an
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error indicator --- usually \NULL{} or \code{-1}. A few functions
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return a Boolean true/false result, with false indicating an error.
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Very few functions return no explicit error indicator or have an
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ambiguous return value, and require explicit testing for errors with
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\cfunction{PyErr_Occurred()}\ttindex{PyErr_Occurred()}.
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Exception state is maintained in per-thread storage (this is
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equivalent to using global storage in an unthreaded application). A
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thread can be in one of two states: an exception has occurred, or not.
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The function \cfunction{PyErr_Occurred()} can be used to check for
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this: it returns a borrowed reference to the exception type object
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when an exception has occurred, and \NULL{} otherwise. There are a
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number of functions to set the exception state:
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\cfunction{PyErr_SetString()}\ttindex{PyErr_SetString()} is the most
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common (though not the most general) function to set the exception
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state, and \cfunction{PyErr_Clear()}\ttindex{PyErr_Clear()} clears the
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exception state.
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The full exception state consists of three objects (all of which can
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be \NULL): the exception type, the corresponding exception
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value, and the traceback. These have the same meanings as the Python
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\withsubitem{(in module sys)}{
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\ttindex{exc_type}\ttindex{exc_value}\ttindex{exc_traceback}}
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objects \code{sys.exc_type}, \code{sys.exc_value}, and
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\code{sys.exc_traceback}; however, they are not the same: the Python
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objects represent the last exception being handled by a Python
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\keyword{try} \ldots\ \keyword{except} statement, while the C level
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exception state only exists while an exception is being passed on
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between C functions until it reaches the Python bytecode interpreter's
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main loop, which takes care of transferring it to \code{sys.exc_type}
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and friends.
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Note that starting with Python 1.5, the preferred, thread-safe way to
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access the exception state from Python code is to call the function
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\withsubitem{(in module sys)}{\ttindex{exc_info()}}
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\function{sys.exc_info()}, which returns the per-thread exception state
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for Python code. Also, the semantics of both ways to access the
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exception state have changed so that a function which catches an
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exception will save and restore its thread's exception state so as to
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preserve the exception state of its caller. This prevents common bugs
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in exception handling code caused by an innocent-looking function
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overwriting the exception being handled; it also reduces the often
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unwanted lifetime extension for objects that are referenced by the
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stack frames in the traceback.
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As a general principle, a function that calls another function to
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perform some task should check whether the called function raised an
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exception, and if so, pass the exception state on to its caller. It
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should discard any object references that it owns, and return an
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error indicator, but it should \emph{not} set another exception ---
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that would overwrite the exception that was just raised, and lose
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important information about the exact cause of the error.
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A simple example of detecting exceptions and passing them on is shown
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in the \cfunction{sum_sequence()}\ttindex{sum_sequence()} example
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above. It so happens that that example doesn't need to clean up any
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owned references when it detects an error. The following example
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function shows some error cleanup. First, to remind you why you like
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Python, we show the equivalent Python code:
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\begin{verbatim}
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def incr_item(dict, key):
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try:
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item = dict[key]
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except KeyError:
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item = 0
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dict[key] = item + 1
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\end{verbatim}
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\ttindex{incr_item()}
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Here is the corresponding C code, in all its glory:
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\begin{verbatim}
|
|
int
|
|
incr_item(PyObject *dict, PyObject *key)
|
|
{
|
|
/* Objects all initialized to NULL for Py_XDECREF */
|
|
PyObject *item = NULL, *const_one = NULL, *incremented_item = NULL;
|
|
int rv = -1; /* Return value initialized to -1 (failure) */
|
|
|
|
item = PyObject_GetItem(dict, key);
|
|
if (item == NULL) {
|
|
/* Handle KeyError only: */
|
|
if (!PyErr_ExceptionMatches(PyExc_KeyError))
|
|
goto error;
|
|
|
|
/* Clear the error and use zero: */
|
|
PyErr_Clear();
|
|
item = PyInt_FromLong(0L);
|
|
if (item == NULL)
|
|
goto error;
|
|
}
|
|
const_one = PyInt_FromLong(1L);
|
|
if (const_one == NULL)
|
|
goto error;
|
|
|
|
incremented_item = PyNumber_Add(item, const_one);
|
|
if (incremented_item == NULL)
|
|
goto error;
|
|
|
|
if (PyObject_SetItem(dict, key, incremented_item) < 0)
|
|
goto error;
|
|
rv = 0; /* Success */
|
|
/* Continue with cleanup code */
|
|
|
|
error:
|
|
/* Cleanup code, shared by success and failure path */
|
|
|
|
/* Use Py_XDECREF() to ignore NULL references */
|
|
Py_XDECREF(item);
|
|
Py_XDECREF(const_one);
|
|
Py_XDECREF(incremented_item);
|
|
|
|
return rv; /* -1 for error, 0 for success */
|
|
}
|
|
\end{verbatim}
|
|
\ttindex{incr_item()}
|
|
|
|
This example represents an endorsed use of the \keyword{goto} statement
|
|
in C! It illustrates the use of
|
|
\cfunction{PyErr_ExceptionMatches()}\ttindex{PyErr_ExceptionMatches()} and
|
|
\cfunction{PyErr_Clear()}\ttindex{PyErr_Clear()} to
|
|
handle specific exceptions, and the use of
|
|
\cfunction{Py_XDECREF()}\ttindex{Py_XDECREF()} to
|
|
dispose of owned references that may be \NULL{} (note the
|
|
\character{X} in the name; \cfunction{Py_DECREF()} would crash when
|
|
confronted with a \NULL{} reference). It is important that the
|
|
variables used to hold owned references are initialized to \NULL{} for
|
|
this to work; likewise, the proposed return value is initialized to
|
|
\code{-1} (failure) and only set to success after the final call made
|
|
is successful.
|
|
|
|
|
|
\section{Embedding Python \label{embedding}}
|
|
|
|
The one important task that only embedders (as opposed to extension
|
|
writers) of the Python interpreter have to worry about is the
|
|
initialization, and possibly the finalization, of the Python
|
|
interpreter. Most functionality of the interpreter can only be used
|
|
after the interpreter has been initialized.
|
|
|
|
The basic initialization function is
|
|
\cfunction{Py_Initialize()}\ttindex{Py_Initialize()}.
|
|
This initializes the table of loaded modules, and creates the
|
|
fundamental modules \module{__builtin__}\refbimodindex{__builtin__},
|
|
\module{__main__}\refbimodindex{__main__}, \module{sys}\refbimodindex{sys},
|
|
and \module{exceptions}.\refbimodindex{exceptions} It also initializes
|
|
the module search path (\code{sys.path}).%
|
|
\indexiii{module}{search}{path}
|
|
\withsubitem{(in module sys)}{\ttindex{path}}
|
|
|
|
\cfunction{Py_Initialize()} does not set the ``script argument list''
|
|
(\code{sys.argv}). If this variable is needed by Python code that
|
|
will be executed later, it must be set explicitly with a call to
|
|
\code{PySys_SetArgv(\var{argc},
|
|
\var{argv})}\ttindex{PySys_SetArgv()} subsequent to the call to
|
|
\cfunction{Py_Initialize()}.
|
|
|
|
On most systems (in particular, on \UNIX{} and Windows, although the
|
|
details are slightly different),
|
|
\cfunction{Py_Initialize()} calculates the module search path based
|
|
upon its best guess for the location of the standard Python
|
|
interpreter executable, assuming that the Python library is found in a
|
|
fixed location relative to the Python interpreter executable. In
|
|
particular, it looks for a directory named
|
|
\file{lib/python\shortversion} relative to the parent directory where
|
|
the executable named \file{python} is found on the shell command
|
|
search path (the environment variable \envvar{PATH}).
|
|
|
|
For instance, if the Python executable is found in
|
|
\file{/usr/local/bin/python}, it will assume that the libraries are in
|
|
\file{/usr/local/lib/python\shortversion}. (In fact, this particular path
|
|
is also the ``fallback'' location, used when no executable file named
|
|
\file{python} is found along \envvar{PATH}.) The user can override
|
|
this behavior by setting the environment variable \envvar{PYTHONHOME},
|
|
or insert additional directories in front of the standard path by
|
|
setting \envvar{PYTHONPATH}.
|
|
|
|
The embedding application can steer the search by calling
|
|
\code{Py_SetProgramName(\var{file})}\ttindex{Py_SetProgramName()} \emph{before} calling
|
|
\cfunction{Py_Initialize()}. Note that \envvar{PYTHONHOME} still
|
|
overrides this and \envvar{PYTHONPATH} is still inserted in front of
|
|
the standard path. An application that requires total control has to
|
|
provide its own implementation of
|
|
\cfunction{Py_GetPath()}\ttindex{Py_GetPath()},
|
|
\cfunction{Py_GetPrefix()}\ttindex{Py_GetPrefix()},
|
|
\cfunction{Py_GetExecPrefix()}\ttindex{Py_GetExecPrefix()}, and
|
|
\cfunction{Py_GetProgramFullPath()}\ttindex{Py_GetProgramFullPath()} (all
|
|
defined in \file{Modules/getpath.c}).
|
|
|
|
Sometimes, it is desirable to ``uninitialize'' Python. For instance,
|
|
the application may want to start over (make another call to
|
|
\cfunction{Py_Initialize()}) or the application is simply done with its
|
|
use of Python and wants to free memory allocated by Python. This
|
|
can be accomplished by calling \cfunction{Py_Finalize()}. The function
|
|
\cfunction{Py_IsInitialized()}\ttindex{Py_IsInitialized()} returns
|
|
true if Python is currently in the initialized state. More
|
|
information about these functions is given in a later chapter.
|
|
Notice that \cfunction{Py_Finalize} does \emph{not} free all memory
|
|
allocated by the Python interpreter, e.g. memory allocated by extension
|
|
modules currently cannot be released.
|
|
|
|
|
|
\section{Debugging Builds \label{debugging}}
|
|
|
|
Python can be built with several macros to enable extra checks of the
|
|
interpreter and extension modules. These checks tend to add a large
|
|
amount of overhead to the runtime so they are not enabled by default.
|
|
|
|
A full list of the various types of debugging builds is in the file
|
|
\file{Misc/SpecialBuilds.txt} in the Python source distribution.
|
|
Builds are available that support tracing of reference counts,
|
|
debugging the memory allocator, or low-level profiling of the main
|
|
interpreter loop. Only the most frequently-used builds will be
|
|
described in the remainder of this section.
|
|
|
|
Compiling the interpreter with the \csimplemacro{Py_DEBUG} macro
|
|
defined produces what is generally meant by "a debug build" of Python.
|
|
\csimplemacro{Py_DEBUG} is enabled in the \UNIX{} build by adding
|
|
\longprogramopt{with-pydebug} to the \file{configure} command. It is also
|
|
implied by the presence of the not-Python-specific
|
|
\csimplemacro{_DEBUG} macro. When \csimplemacro{Py_DEBUG} is enabled
|
|
in the \UNIX{} build, compiler optimization is disabled.
|
|
|
|
In addition to the reference count debugging described below, the
|
|
following extra checks are performed:
|
|
|
|
\begin{itemize}
|
|
\item Extra checks are added to the object allocator.
|
|
\item Extra checks are added to the parser and compiler.
|
|
\item Downcasts from wide types to narrow types are checked for
|
|
loss of information.
|
|
\item A number of assertions are added to the dictionary and set
|
|
implementations. In addition, the set object acquires a
|
|
\method{test_c_api} method.
|
|
\item Sanity checks of the input arguments are added to frame
|
|
creation.
|
|
\item The storage for long ints is initialized with a known
|
|
invalid pattern to catch reference to uninitialized
|
|
digits.
|
|
\item Low-level tracing and extra exception checking are added
|
|
to the runtime virtual machine.
|
|
\item Extra checks are added to the memory arena implementation.
|
|
\item Extra debugging is added to the thread module.
|
|
\end{itemize}
|
|
|
|
There may be additional checks not mentioned here.
|
|
|
|
Defining \csimplemacro{Py_TRACE_REFS} enables reference tracing. When
|
|
defined, a circular doubly linked list of active objects is maintained
|
|
by adding two extra fields to every \ctype{PyObject}. Total
|
|
allocations are tracked as well. Upon exit, all existing references
|
|
are printed. (In interactive mode this happens after every statement
|
|
run by the interpreter.) Implied by \csimplemacro{Py_DEBUG}.
|
|
|
|
Please refer to \file{Misc/SpecialBuilds.txt} in the Python source
|
|
distribution for more detailed information.
|