Misc/SpecialBuilds.txt - platform/external/python/cpython3 - Gitiles

 This file describes some special Python build types enabled via
 compile-time preprocessor defines.

 ---------------------------------------------------------------------------
 Py_REF_DEBUG                                              introduced in 1.4
                                                  named REF_DEBUG before 1.4

 Turn on aggregate reference counting.  This arranges that extern
 _Py_RefTotal hold a count of all references, the sum of ob_refcnt across
 all objects.  In a debug-mode build, this is where the "8288" comes from
 in

     >>> 23
     23
     [8288 refs]
     >>>

 Note that if this count increases when you're not storing away new objects,
 there's probably a leak.  Remember, though, that in interactive mode the
 special name "_" holds a reference to the last result displayed!

 Py_REF_DEBUG also checks after every decref to verify that the refcount
 hasn't gone negative, and causes an immediate fatal error if it has.

 Special gimmicks:

 sys.gettotalrefcount()
     Return current total of all refcounts.
     Available under Py_REF_DEBUG in Python 2.3.
     Before 2.3, Py_TRACE_REFS was required to enable this function.
 ---------------------------------------------------------------------------
 Py_TRACE_REFS                                             introduced in 1.4
                                                 named TRACE_REFS before 1.4

 Turn on heavy reference debugging.  This is major surgery.  Every PyObject
 grows two more pointers, to maintain a doubly-linked list of all live
 heap-allocated objects (note that, e.g., most builtin type objects are not
 in this list, as they're statically allocated).  Note that because the
 fundamental PyObject layout changes, Python modules compiled with
 Py_TRACE_REFS are incompatible with modules compiled without it.

 Py_TRACE_REFS implies Py_REF_DEBUG.

 Special gimmicks:

 sys.getobjects(max[, type])
     Return list of the (no more than) max most-recently allocated objects,
     most recently allocated first in the list, least-recently allocated
     last in the list.  max=0 means no limit on list length.
     If an optional type object is passed, the list is also restricted to
     objects of that type.
     The return list itself, and some temp objects created just to call
     sys.getobjects(), are excluded from the return list.  Note that the
     list returned is just another object, though, so may appear in the
     return list the next time you call getobjects(); note that every
     object in the list is kept alive too, simply by virtue of being in
     the list.

 envar PYTHONDUMPREFS
     If this envar exists, Py_Finalize() arranges to print a list of
     all still-live heap objects.
 ---------------------------------------------------------------------------
 PYMALLOC_DEBUG                                            introduced in 2.3

 When pymalloc is enabled (WITH_PYMALLOC is defined), calls to the PyObject_
 memory routines are handled by Python's own small-object allocator, while
 calls to the PyMem_ memory routines are directed to the system malloc/
 realloc/free.  If PYMALLOC_DEBUG is also defined, calls to both PyObject_
 and PyMem_ memory routines are directed to a special debugging mode of
 Python's small-object allocator.

 This mode fills dynamically allocated memory blocks with special,
 recognizable bit patterns, and adds debugging info on each end of
 dynamically allocated memory blocks.  The special bit patterns are:

 #define CLEANBYTE     0xCB   /* clean (newly allocated) memory */
 #define DEADBYTE      0xDB   /* dead (newly freed) memory */
 #define FORBIDDENBYTE 0xFB   /* fordidden -- untouchable bytes */

 Strings of these bytes are unlikely to be valid addresses, floats, or 7-bit
 ASCII strings.

 8 bytes are added at each end of each block of N bytes requested.  The
 memory layout is like so, where p represents the address returned by a
 malloc-like or realloc-like function (p[i:j] means the slice of bytes
 from *(p+i) inclusive up to *(p+j) exclusive; note that the treatment
 of negative indices differs from a Python slice):

 p[-8:-4]
     Number of bytes originally asked for.  4-byte unsigned integer,
     big-endian (easier to read in a memory dump).
 p[-4:0]
     Copies of FORBIDDENBYTE.  Used to catch under- writes and reads.
 p[0:N]
     The requested memory, filled with copies of CLEANBYTE, used to catch
     reference to uninitialized memory.
     When a realloc-like function is called requesting a larger memory
     block, the new excess bytes are also filled with CLEANBYTE.
     When a free-like function is called, these are overwritten with
     DEADBYTE, to catch reference to freed memory.  When a realloc-
     like function is called requesting a smaller memory block, the excess
     old bytes are also filled with DEADBYTE.
 p[N:N+4]
     Copies of FORBIDDENBYTE.  Used to catch over- writes and reads.
 p[N+4:N+8]
     A serial number, incremented by 1 on each call to a malloc-like or
     realloc-like function.
     4-byte unsigned integer, big-endian.
     If "bad memory" is detected later, the serial number gives an
     excellent way to set a breakpoint on the next run, to capture the
     instant at which this block was passed out.  The static function
     bumpserialno() in obmalloc.c is the only place the serial number
     is incremented, and exists so you can set such a breakpoint easily.

 A realloc-like or free-like function first checks that the FORBIDDENBYTEs
 at each end are intact.  If they've been altered, diagnostic output is
 written to stderr, and the program is aborted via Py_FatalError().  The
 other main failure mode is provoking a memory error when a program
 reads up one of the special bit patterns and tries to use it as an address.
 If you get in a debugger then and look at the object, you're likely
 to see that it's entirely filled with 0xDB (meaning freed memory is
 getting used) or 0xCB (meaning uninitialized memory is getting used).

 Note that PYMALLOC_DEBUG requires WITH_PYMALLOC.

 Special gimmicks:

 envar PYTHONMALLOCSTATS
     If this envar exists, a report of pymalloc summary statistics is
     printed to stderr whenever a new arena is allocated, and also
     by Py_Finalize().
 ---------------------------------------------------------------------------
 Py_DEBUG                                                  introduced in 1.5
                                                      named DEBUG before 1.5

 This is what is generally meant by "a debug build" of Python.

 Py_DEBUG implies LLTRACE, Py_REF_DEBUG, Py_TRACE_REFS, and
 PYMALLOC_DEBUG (if WITH_PYMALLOC is enabled).  In addition, C
 assert()s are enabled (via the C way: by not defining NDEBUG), and
 some routines do additional sanity checks inside "#ifdef Py_DEBUG"
 blocks.
 ---------------------------------------------------------------------------
 COUNT_ALLOCS                                            introduced in 0.9.9
                                              partly broken in 2.2 and 2.2.1

 Each type object grows three new members:

     /* Number of times an object of this type was allocated. */
     int tp_allocs;

     /* Number of times an object of this type was deallocated. */
     int tp_frees;

     /* Highwater mark:  the maximum value of tp_allocs - tp_frees so
      * far; or, IOW, the largest number of objects of this type alive at
      * the same time.
      */
     int tp_maxalloc;

 Allocation and deallocation code keeps these counts up to date.
 Py_Finalize() displays a summary of the info returned by sys.getcounts()
 (see below), along with assorted other special allocation counts (like
 the number of tuple allocations satisfied by a tuple free-list, the number
 of 1-character strings allocated, etc).

 Before Python 2.2, type objects were immortal, and the COUNT_ALLOCS
 implementation relies on that.  As of Python 2.2, heap-allocated type/
 class objects can go away.  COUNT_ALLOCS can blow up in 2.2 and 2.2.1
 because of this; this was fixed in 2.2.2.  Use of COUNT_ALLOCS makes
 all heap-allocated type objects immortal, except for those for which no
 object of that type is ever allocated.

 Special gimmicks:

 sys.getcounts()
     Return a list of 4-tuples, one entry for each type object for which
     at least one object of that type was allocated.  Each tuple is of
     the form:

         (tp_name, tp_allocs, tp_frees, tp_maxalloc)

     Each distinct type object gets a distinct entry in this list, even
     if two or more type objects have the same tp_name (in which case
     there's no way to distinguish them by looking at this list).  The
     list is ordered by time of first object allocation:  the type object
     for which the first allocation of an object of that type occurred
     most recently is at the front of the list.
 ---------------------------------------------------------------------------
 LLTRACE                                          introduced well before 1.0

 Compile in support of Low Level TRACE-ing of the main interpreter loop.

 When this preprocessor symbol is defined, before eval_frame
 (eval_code2 before 2.2) executes a frame's code it checks the frame's
 global namespace for a variable "__lltrace__".  If such a variable is
 found, mounds of information about what the interpreter is doing are
 sprayed to stdout, such as every opcode and opcode argument and values
 pushed onto and popped off the value stack.

 Not useful very often, but very useful when needed.
	This file describes some special Python build types enabled via
	compile-time preprocessor defines.

	---------------------------------------------------------------------------
	Py_REF_DEBUG introduced in 1.4
	named REF_DEBUG before 1.4

	Turn on aggregate reference counting. This arranges that extern
	_Py_RefTotal hold a count of all references, the sum of ob_refcnt across
	all objects. In a debug-mode build, this is where the "8288" comes from
	in

	>>> 23
	23
	[8288 refs]
	>>>

	Note that if this count increases when you're not storing away new objects,
	there's probably a leak. Remember, though, that in interactive mode the
	special name "_" holds a reference to the last result displayed!

	Py_REF_DEBUG also checks after every decref to verify that the refcount
	hasn't gone negative, and causes an immediate fatal error if it has.

	Special gimmicks:

	sys.gettotalrefcount()
	Return current total of all refcounts.
	Available under Py_REF_DEBUG in Python 2.3.
	Before 2.3, Py_TRACE_REFS was required to enable this function.
	---------------------------------------------------------------------------
	Py_TRACE_REFS introduced in 1.4
	named TRACE_REFS before 1.4

	Turn on heavy reference debugging. This is major surgery. Every PyObject
	grows two more pointers, to maintain a doubly-linked list of all live
	heap-allocated objects (note that, e.g., most builtin type objects are not
	in this list, as they're statically allocated). Note that because the
	fundamental PyObject layout changes, Python modules compiled with
	Py_TRACE_REFS are incompatible with modules compiled without it.

	Py_TRACE_REFS implies Py_REF_DEBUG.

	Special gimmicks:

	sys.getobjects(max[, type])
	Return list of the (no more than) max most-recently allocated objects,
	most recently allocated first in the list, least-recently allocated
	last in the list. max=0 means no limit on list length.
	If an optional type object is passed, the list is also restricted to
	objects of that type.
	The return list itself, and some temp objects created just to call
	sys.getobjects(), are excluded from the return list. Note that the
	list returned is just another object, though, so may appear in the
	return list the next time you call getobjects(); note that every
	object in the list is kept alive too, simply by virtue of being in
	the list.

	envar PYTHONDUMPREFS
	If this envar exists, Py_Finalize() arranges to print a list of
	all still-live heap objects.
	---------------------------------------------------------------------------
	PYMALLOC_DEBUG introduced in 2.3

	When pymalloc is enabled (WITH_PYMALLOC is defined), calls to the PyObject_
	memory routines are handled by Python's own small-object allocator, while
	calls to the PyMem_ memory routines are directed to the system malloc/
	realloc/free. If PYMALLOC_DEBUG is also defined, calls to both PyObject_
	and PyMem_ memory routines are directed to a special debugging mode of
	Python's small-object allocator.

	This mode fills dynamically allocated memory blocks with special,
	recognizable bit patterns, and adds debugging info on each end of
	dynamically allocated memory blocks. The special bit patterns are:

	#define CLEANBYTE 0xCB /* clean (newly allocated) memory */
	#define DEADBYTE 0xDB /* dead (newly freed) memory */
	#define FORBIDDENBYTE 0xFB /* fordidden -- untouchable bytes */

	Strings of these bytes are unlikely to be valid addresses, floats, or 7-bit
	ASCII strings.

	8 bytes are added at each end of each block of N bytes requested. The
	memory layout is like so, where p represents the address returned by a
	malloc-like or realloc-like function (p[i:j] means the slice of bytes
	from (p+i) inclusive up to (p+j) exclusive; note that the treatment
	of negative indices differs from a Python slice):

	p[-8:-4]
	Number of bytes originally asked for. 4-byte unsigned integer,
	big-endian (easier to read in a memory dump).
	p[-4:0]
	Copies of FORBIDDENBYTE. Used to catch under- writes and reads.
	p[0:N]
	The requested memory, filled with copies of CLEANBYTE, used to catch
	reference to uninitialized memory.
	When a realloc-like function is called requesting a larger memory
	block, the new excess bytes are also filled with CLEANBYTE.
	When a free-like function is called, these are overwritten with
	DEADBYTE, to catch reference to freed memory. When a realloc-
	like function is called requesting a smaller memory block, the excess
	old bytes are also filled with DEADBYTE.
	p[N:N+4]
	Copies of FORBIDDENBYTE. Used to catch over- writes and reads.
	p[N+4:N+8]
	A serial number, incremented by 1 on each call to a malloc-like or
	realloc-like function.
	4-byte unsigned integer, big-endian.
	If "bad memory" is detected later, the serial number gives an
	excellent way to set a breakpoint on the next run, to capture the
	instant at which this block was passed out. The static function
	bumpserialno() in obmalloc.c is the only place the serial number
	is incremented, and exists so you can set such a breakpoint easily.

	A realloc-like or free-like function first checks that the FORBIDDENBYTEs
	at each end are intact. If they've been altered, diagnostic output is
	written to stderr, and the program is aborted via Py_FatalError(). The
	other main failure mode is provoking a memory error when a program
	reads up one of the special bit patterns and tries to use it as an address.
	If you get in a debugger then and look at the object, you're likely
	to see that it's entirely filled with 0xDB (meaning freed memory is
	getting used) or 0xCB (meaning uninitialized memory is getting used).

	Note that PYMALLOC_DEBUG requires WITH_PYMALLOC.

	Special gimmicks:

	envar PYTHONMALLOCSTATS
	If this envar exists, a report of pymalloc summary statistics is
	printed to stderr whenever a new arena is allocated, and also
	by Py_Finalize().
	---------------------------------------------------------------------------
	Py_DEBUG introduced in 1.5
	named DEBUG before 1.5

	This is what is generally meant by "a debug build" of Python.

	Py_DEBUG implies LLTRACE, Py_REF_DEBUG, Py_TRACE_REFS, and
	PYMALLOC_DEBUG (if WITH_PYMALLOC is enabled). In addition, C
	assert()s are enabled (via the C way: by not defining NDEBUG), and
	some routines do additional sanity checks inside "#ifdef Py_DEBUG"
	blocks.
	---------------------------------------------------------------------------
	COUNT_ALLOCS introduced in 0.9.9
	partly broken in 2.2 and 2.2.1

	Each type object grows three new members:

	/* Number of times an object of this type was allocated. */
	int tp_allocs;

	/* Number of times an object of this type was deallocated. */
	int tp_frees;

	/* Highwater mark: the maximum value of tp_allocs - tp_frees so
	* far; or, IOW, the largest number of objects of this type alive at
	* the same time.
	*/
	int tp_maxalloc;

	Allocation and deallocation code keeps these counts up to date.
	Py_Finalize() displays a summary of the info returned by sys.getcounts()
	(see below), along with assorted other special allocation counts (like
	the number of tuple allocations satisfied by a tuple free-list, the number
	of 1-character strings allocated, etc).

	Before Python 2.2, type objects were immortal, and the COUNT_ALLOCS
	implementation relies on that. As of Python 2.2, heap-allocated type/
	class objects can go away. COUNT_ALLOCS can blow up in 2.2 and 2.2.1
	because of this; this was fixed in 2.2.2. Use of COUNT_ALLOCS makes
	all heap-allocated type objects immortal, except for those for which no
	object of that type is ever allocated.

	Special gimmicks:

	sys.getcounts()
	Return a list of 4-tuples, one entry for each type object for which
	at least one object of that type was allocated. Each tuple is of
	the form:

	(tp_name, tp_allocs, tp_frees, tp_maxalloc)

	Each distinct type object gets a distinct entry in this list, even
	if two or more type objects have the same tp_name (in which case
	there's no way to distinguish them by looking at this list). The
	list is ordered by time of first object allocation: the type object
	for which the first allocation of an object of that type occurred
	most recently is at the front of the list.
	---------------------------------------------------------------------------
	LLTRACE introduced well before 1.0

	Compile in support of Low Level TRACE-ing of the main interpreter loop.

	When this preprocessor symbol is defined, before eval_frame
	(eval_code2 before 2.2) executes a frame's code it checks the frame's
	global namespace for a variable "__lltrace__". If such a variable is
	found, mounds of information about what the interpreter is doing are
	sprayed to stdout, such as every opcode and opcode argument and values
	pushed onto and popped off the value stack.

	Not useful very often, but very useful when needed.