469 lines
16 KiB
C
469 lines
16 KiB
C
#ifndef Py_OBJECT_H
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#define Py_OBJECT_H
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#ifdef __cplusplus
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extern "C" {
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#endif
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/***********************************************************
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Copyright 1991-1995 by Stichting Mathematisch Centrum, Amsterdam,
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The Netherlands.
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All Rights Reserved
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Permission to use, copy, modify, and distribute this software and its
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documentation for any purpose and without fee is hereby granted,
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provided that the above copyright notice appear in all copies and that
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both that copyright notice and this permission notice appear in
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supporting documentation, and that the names of Stichting Mathematisch
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Centrum or CWI or Corporation for National Research Initiatives or
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CNRI not be used in advertising or publicity pertaining to
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distribution of the software without specific, written prior
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permission.
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While CWI is the initial source for this software, a modified version
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is made available by the Corporation for National Research Initiatives
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(CNRI) at the Internet address ftp://ftp.python.org.
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STICHTING MATHEMATISCH CENTRUM AND CNRI DISCLAIM ALL WARRANTIES WITH
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REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF
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MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL STICHTING MATHEMATISCH
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CENTRUM OR CNRI BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL
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DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR
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PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
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TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR
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PERFORMANCE OF THIS SOFTWARE.
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******************************************************************/
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/* Object and type object interface */
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/*
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123456789-123456789-123456789-123456789-123456789-123456789-123456789-12
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Objects are structures allocated on the heap. Special rules apply to
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the use of objects to ensure they are properly garbage-collected.
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Objects are never allocated statically or on the stack; they must be
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accessed through special macros and functions only. (Type objects are
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exceptions to the first rule; the standard types are represented by
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statically initialized type objects.)
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An object has a 'reference count' that is increased or decreased when a
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pointer to the object is copied or deleted; when the reference count
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reaches zero there are no references to the object left and it can be
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removed from the heap.
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An object has a 'type' that determines what it represents and what kind
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of data it contains. An object's type is fixed when it is created.
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Types themselves are represented as objects; an object contains a
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pointer to the corresponding type object. The type itself has a type
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pointer pointing to the object representing the type 'type', which
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contains a pointer to itself!).
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Objects do not float around in memory; once allocated an object keeps
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the same size and address. Objects that must hold variable-size data
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can contain pointers to variable-size parts of the object. Not all
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objects of the same type have the same size; but the size cannot change
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after allocation. (These restrictions are made so a reference to an
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object can be simply a pointer -- moving an object would require
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updating all the pointers, and changing an object's size would require
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moving it if there was another object right next to it.)
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Objects are always accessed through pointers of the type 'PyObject *'.
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The type 'PyObject' is a structure that only contains the reference count
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and the type pointer. The actual memory allocated for an object
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contains other data that can only be accessed after casting the pointer
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to a pointer to a longer structure type. This longer type must start
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with the reference count and type fields; the macro PyObject_HEAD should be
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used for this (to accomodate for future changes). The implementation
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of a particular object type can cast the object pointer to the proper
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type and back.
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A standard interface exists for objects that contain an array of items
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whose size is determined when the object is allocated.
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123456789-123456789-123456789-123456789-123456789-123456789-123456789-12
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*/
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#ifdef Py_DEBUG
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/* Turn on heavy reference debugging */
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#define Py_TRACE_REFS
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/* Turn on reference counting */
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#define Py_REF_DEBUG
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#endif /* Py_DEBUG */
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#ifdef Py_TRACE_REFS
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#define PyObject_HEAD \
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struct _object *_ob_next, *_ob_prev; \
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int ob_refcnt; \
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struct _typeobject *ob_type;
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#define PyObject_HEAD_INIT(type) 0, 0, 1, type,
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#else /* !Py_TRACE_REFS */
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#define PyObject_HEAD \
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int ob_refcnt; \
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struct _typeobject *ob_type;
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#define PyObject_HEAD_INIT(type) 1, type,
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#endif /* !Py_TRACE_REFS */
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#define PyObject_VAR_HEAD \
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PyObject_HEAD \
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int ob_size; /* Number of items in variable part */
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typedef struct _object {
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PyObject_HEAD
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} PyObject;
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typedef struct {
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PyObject_VAR_HEAD
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} varobject;
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/*
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Type objects contain a string containing the type name (to help somewhat
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in debugging), the allocation parameters (see newobj() and newvarobj()),
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and methods for accessing objects of the type. Methods are optional,a
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nil pointer meaning that particular kind of access is not available for
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this type. The Py_DECREF() macro uses the tp_dealloc method without
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checking for a nil pointer; it should always be implemented except if
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the implementation can guarantee that the reference count will never
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reach zero (e.g., for type objects).
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NB: the methods for certain type groups are now contained in separate
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method blocks.
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*/
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typedef PyObject * (*unaryfunc) Py_PROTO((PyObject *));
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typedef PyObject * (*binaryfunc) Py_PROTO((PyObject *, PyObject *));
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typedef PyObject * (*ternaryfunc) Py_PROTO((PyObject *, PyObject *, PyObject *));
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typedef int (*inquiry) Py_PROTO((PyObject *));
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typedef int (*coercion) Py_PROTO((PyObject **, PyObject **));
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typedef PyObject *(*intargfunc) Py_PROTO((PyObject *, int));
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typedef PyObject *(*intintargfunc) Py_PROTO((PyObject *, int, int));
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typedef int(*intobjargproc) Py_PROTO((PyObject *, int, PyObject *));
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typedef int(*intintobjargproc) Py_PROTO((PyObject *, int, int, PyObject *));
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typedef int(*objobjargproc) Py_PROTO((PyObject *, PyObject *, PyObject *));
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typedef struct {
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binaryfunc nb_add;
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binaryfunc nb_subtract;
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binaryfunc nb_multiply;
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binaryfunc nb_divide;
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binaryfunc nb_remainder;
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binaryfunc nb_divmod;
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ternaryfunc nb_power;
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unaryfunc nb_negative;
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unaryfunc nb_positive;
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unaryfunc nb_absolute;
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inquiry nb_nonzero;
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unaryfunc nb_invert;
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binaryfunc nb_lshift;
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binaryfunc nb_rshift;
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binaryfunc nb_and;
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binaryfunc nb_xor;
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binaryfunc nb_or;
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coercion nb_coerce;
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unaryfunc nb_int;
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unaryfunc nb_long;
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unaryfunc nb_float;
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unaryfunc nb_oct;
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unaryfunc nb_hex;
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} PyNumberMethods;
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typedef struct {
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inquiry sq_length;
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binaryfunc sq_concat;
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intargfunc sq_repeat;
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intargfunc sq_item;
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intintargfunc sq_slice;
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intobjargproc sq_ass_item;
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intintobjargproc sq_ass_slice;
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} PySequenceMethods;
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typedef struct {
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inquiry mp_length;
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binaryfunc mp_subscript;
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objobjargproc mp_ass_subscript;
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} PyMappingMethods;
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typedef void (*destructor) Py_PROTO((PyObject *));
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typedef int (*printfunc) Py_PROTO((PyObject *, FILE *, int));
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typedef PyObject *(*getattrfunc) Py_PROTO((PyObject *, char *));
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typedef PyObject *(*getattrofunc) Py_PROTO((PyObject *, PyObject *));
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typedef int (*setattrfunc) Py_PROTO((PyObject *, char *, PyObject *));
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typedef int (*setattrofunc) Py_PROTO((PyObject *, PyObject *, PyObject *));
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typedef int (*cmpfunc) Py_PROTO((PyObject *, PyObject *));
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typedef PyObject *(*reprfunc) Py_PROTO((PyObject *));
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typedef long (*hashfunc) Py_PROTO((PyObject *));
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typedef struct _typeobject {
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PyObject_VAR_HEAD
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char *tp_name; /* For printing */
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int tp_basicsize, tp_itemsize; /* For allocation */
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/* Methods to implement standard operations */
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destructor tp_dealloc;
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printfunc tp_print;
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getattrfunc tp_getattr;
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setattrfunc tp_setattr;
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cmpfunc tp_compare;
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reprfunc tp_repr;
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/* Method suites for standard classes */
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PyNumberMethods *tp_as_number;
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PySequenceMethods *tp_as_sequence;
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PyMappingMethods *tp_as_mapping;
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/* More standard operations (at end for binary compatibility) */
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hashfunc tp_hash;
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ternaryfunc tp_call;
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reprfunc tp_str;
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getattrofunc tp_getattro;
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setattrofunc tp_setattro;
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/* Space for future expansion */
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long tp_xxx3;
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long tp_xxx4;
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char *tp_doc; /* Documentation string */
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#ifdef COUNT_ALLOCS
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/* these must be last */
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int tp_alloc;
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int tp_free;
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int tp_maxalloc;
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struct _typeobject *tp_next;
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#endif
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} PyTypeObject;
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extern DL_IMPORT(PyTypeObject) PyType_Type; /* The type of type objects */
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#define PyType_Check(op) ((op)->ob_type == &PyType_Type)
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/* Generic operations on objects */
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extern int PyObject_Print Py_PROTO((PyObject *, FILE *, int));
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extern PyObject * PyObject_Repr Py_PROTO((PyObject *));
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extern PyObject * PyObject_Str Py_PROTO((PyObject *));
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extern int PyObject_Compare Py_PROTO((PyObject *, PyObject *));
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extern PyObject *PyObject_GetAttrString Py_PROTO((PyObject *, char *));
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extern int PyObject_SetAttrString Py_PROTO((PyObject *, char *, PyObject *));
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extern int PyObject_HasAttrString Py_PROTO((PyObject *, char *));
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extern PyObject *PyObject_GetAttr Py_PROTO((PyObject *, PyObject *));
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extern int PyObject_SetAttr Py_PROTO((PyObject *, PyObject *, PyObject *));
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extern long PyObject_Hash Py_PROTO((PyObject *));
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extern int PyObject_IsTrue Py_PROTO((PyObject *));
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extern int PyCallable_Check Py_PROTO((PyObject *));
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extern int PyNumber_Coerce Py_PROTO((PyObject **, PyObject **));
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/* Flag bits for printing: */
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#define Py_PRINT_RAW 1 /* No string quotes etc. */
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/*
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123456789-123456789-123456789-123456789-123456789-123456789-123456789-12
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The macros Py_INCREF(op) and Py_DECREF(op) are used to increment or decrement
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reference counts. Py_DECREF calls the object's deallocator function; for
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objects that don't contain references to other objects or heap memory
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this can be the standard function free(). Both macros can be used
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whereever a void expression is allowed. The argument shouldn't be a
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NIL pointer. The macro _Py_NewReference(op) is used only to initialize
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reference counts to 1; it is defined here for convenience.
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We assume that the reference count field can never overflow; this can
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be proven when the size of the field is the same as the pointer size
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but even with a 16-bit reference count field it is pretty unlikely so
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we ignore the possibility. (If you are paranoid, make it a long.)
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Type objects should never be deallocated; the type pointer in an object
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is not considered to be a reference to the type object, to save
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complications in the deallocation function. (This is actually a
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decision that's up to the implementer of each new type so if you want,
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you can count such references to the type object.)
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*** WARNING*** The Py_DECREF macro must have a side-effect-free argument
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since it may evaluate its argument multiple times. (The alternative
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would be to mace it a proper function or assign it to a global temporary
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variable first, both of which are slower; and in a multi-threaded
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environment the global variable trick is not safe.)
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*/
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#ifdef Py_TRACE_REFS
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#ifndef Py_REF_DEBUG
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#define Py_REF_DEBUG
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#endif
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#endif
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#ifdef Py_TRACE_REFS
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extern void _Py_Dealloc Py_PROTO((PyObject *));
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extern void _Py_NewReference Py_PROTO((PyObject *));
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extern void _Py_ForgetReference Py_PROTO((PyObject *));
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extern void _Py_PrintReferences Py_PROTO((FILE *));
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#endif
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#ifndef Py_TRACE_REFS
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#ifdef COUNT_ALLOCS
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#define _Py_Dealloc(op) ((op)->ob_type->tp_free++, (*(op)->ob_type->tp_dealloc)((PyObject *)(op)))
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#define _Py_ForgetReference(op) ((op)->ob_type->tp_free++)
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#else /* !COUNT_ALLOCS */
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#define _Py_Dealloc(op) (*(op)->ob_type->tp_dealloc)((PyObject *)(op))
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#define _Py_ForgetReference(op) /*empty*/
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#endif /* !COUNT_ALLOCS */
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#endif /* !Py_TRACE_REFS */
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#ifdef COUNT_ALLOCS
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extern void inc_count Py_PROTO((PyTypeObject *));
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#endif
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#ifdef Py_REF_DEBUG
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extern long _Py_RefTotal;
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#ifndef Py_TRACE_REFS
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#ifdef COUNT_ALLOCS
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#define _Py_NewReference(op) (inc_count((op)->ob_type), _Py_RefTotal++, (op)->ob_refcnt = 1)
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#else
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#define _Py_NewReference(op) (_Py_RefTotal++, (op)->ob_refcnt = 1)
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#endif
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#endif /* !Py_TRACE_REFS */
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#define Py_INCREF(op) (_Py_RefTotal++, (op)->ob_refcnt++)
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#define Py_DECREF(op) \
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if (--_Py_RefTotal, --(op)->ob_refcnt != 0) \
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; \
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else \
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_Py_Dealloc(op)
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#else /* !Py_REF_DEBUG */
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#ifdef COUNT_ALLOCS
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#define _Py_NewReference(op) (inc_count((op)->ob_type), (op)->ob_refcnt = 1)
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#else
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#define _Py_NewReference(op) ((op)->ob_refcnt = 1)
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#endif
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#define Py_INCREF(op) ((op)->ob_refcnt++)
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#define Py_DECREF(op) \
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if (--(op)->ob_refcnt != 0) \
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; \
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else \
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_Py_Dealloc(op)
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#endif /* !Py_REF_DEBUG */
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/* Macros to use in case the object pointer may be NULL: */
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#define Py_XINCREF(op) if ((op) == NULL) ; else Py_INCREF(op)
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#define Py_XDECREF(op) if ((op) == NULL) ; else Py_DECREF(op)
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/* Definition of NULL, so you don't have to include <stdio.h> */
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#ifndef NULL
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#define NULL 0
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#endif
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/*
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_Py_NoneStruct is an object of undefined type which can be used in contexts
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where NULL (nil) is not suitable (since NULL often means 'error').
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Don't forget to apply Py_INCREF() when returning this value!!!
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*/
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extern DL_IMPORT(PyObject) _Py_NoneStruct; /* Don't use this directly */
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#define Py_None (&_Py_NoneStruct)
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/*
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A common programming style in Python requires the forward declaration
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of static, initialized structures, e.g. for a type object that is used
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by the functions whose address must be used in the initializer.
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Some compilers (notably SCO ODT 3.0, I seem to remember early AIX as
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well) botch this if you use the static keyword for both declarations
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(they allocate two objects, and use the first, uninitialized one until
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the second declaration is encountered). Therefore, the forward
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declaration should use the 'forwardstatic' keyword. This expands to
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static on most systems, but to extern on a few. The actual storage
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and name will still be static because the second declaration is
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static, so no linker visible symbols will be generated. (Standard C
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compilers take offense to the extern forward declaration of a static
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object, so I can't just put extern in all cases. :-( )
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*/
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#ifdef BAD_STATIC_FORWARD
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#define staticforward extern
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#ifdef __SC__
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#define statichere
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#else
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#define statichere static
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#endif /* __SC__ */
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#else /* !BAD_STATIC_FORWARD */
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#define staticforward static
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#define statichere static
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#endif /* !BAD_STATIC_FORWARD */
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/*
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123456789-123456789-123456789-123456789-123456789-123456789-123456789-12
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More conventions
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================
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Argument Checking
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-----------------
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Functions that take objects as arguments normally don't check for nil
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arguments, but they do check the type of the argument, and return an
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error if the function doesn't apply to the type.
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Failure Modes
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-------------
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Functions may fail for a variety of reasons, including running out of
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memory. This is communicated to the caller in two ways: an error string
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is set (see errors.h), and the function result differs: functions that
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normally return a pointer return NULL for failure, functions returning
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an integer return -1 (which could be a legal return value too!), and
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other functions return 0 for success and -1 for failure.
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Callers should always check for errors before using the result.
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Reference Counts
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----------------
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It takes a while to get used to the proper usage of reference counts.
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Functions that create an object set the reference count to 1; such new
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objects must be stored somewhere or destroyed again with Py_DECREF().
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Functions that 'store' objects such as PyTuple_SetItem() and
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PyDict_SetItemString()
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don't increment the reference count of the object, since the most
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frequent use is to store a fresh object. Functions that 'retrieve'
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objects such as PyTuple_GetItem() and PyDict_GetItemString() also
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don't increment
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the reference count, since most frequently the object is only looked at
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quickly. Thus, to retrieve an object and store it again, the caller
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must call Py_INCREF() explicitly.
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NOTE: functions that 'consume' a reference count like
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PyDict_SetItemString() even
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consume the reference if the object wasn't stored, to simplify error
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handling.
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It seems attractive to make other functions that take an object as
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argument consume a reference count; however this may quickly get
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confusing (even the current practice is already confusing). Consider
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it carefully, it may save lots of calls to Py_INCREF() and Py_DECREF() at
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times.
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123456789-123456789-123456789-123456789-123456789-123456789-123456789-12
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*/
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#ifdef __cplusplus
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}
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#endif
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#endif /* !Py_OBJECT_H */
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