1. Armin Rigo
  2. cpython-withatomic


cpython-withatomic / Misc / README.valgrind

The branch 'legacy-trunk' does not exist.
This document describes some caveats about the use of Valgrind with
Python.  Valgrind is used periodically by Python developers to try
to ensure there are no memory leaks or invalid memory reads/writes.

If you don't want to read about the details of using Valgrind, there
are still two things you must do to suppress the warnings.  First,
you must use a suppressions file.  One is supplied in
Misc/valgrind-python.supp.  Second, you must do one of the following:

  * Uncomment Py_USING_MEMORY_DEBUGGER in Objects/obmalloc.c,
    then rebuild Python
  * Uncomment the lines in Misc/valgrind-python.supp that
    suppress the warnings for PyObject_Free and PyObject_Realloc

Python uses its own small-object allocation scheme on top of malloc,
called PyMalloc.

Valgrind may show some unexpected results when PyMalloc is used.
Starting with Python 2.3, PyMalloc is used by default.  You can disable
PyMalloc when configuring python by adding the --without-pymalloc option.
If you disable PyMalloc, most of the information in this document and
the supplied suppressions file will not be useful.

If you use valgrind on a default build of Python,  you will see
many errors like:

        ==6399== Use of uninitialised value of size 4
        ==6399== at 0x4A9BDE7E: PyObject_Free (obmalloc.c:711)
        ==6399== by 0x4A9B8198: dictresize (dictobject.c:477)

These are expected and not a problem.  Tim Peters explains
the situation:

        PyMalloc needs to know whether an arbitrary address is one
	that's managed by it, or is managed by the system malloc.
	The current scheme allows this to be determined in constant
	time, regardless of how many memory areas are under pymalloc's

        The memory pymalloc manages itself is in one or more "arenas",
	each a large contiguous memory area obtained from malloc.
	The base address of each arena is saved by pymalloc
	in a vector.  Each arena is carved into "pools", and a field at
	the start of each pool contains the index of that pool's arena's
	base address in that vector.

        Given an arbitrary address, pymalloc computes the pool base
	address corresponding to it, then looks at "the index" stored
	near there.  If the index read up is out of bounds for the
	vector of arena base addresses pymalloc maintains, then
	pymalloc knows for certain that this address is not under
	pymalloc's control.  Otherwise the index is in bounds, and
	pymalloc compares

            the arena base address stored at that index in the vector


            the arbitrary address pymalloc is investigating

        pymalloc controls this arbitrary address if and only if it lies
        in the arena the address's pool's index claims it lies in.

        It doesn't matter whether the memory pymalloc reads up ("the
	index") is initialized.  If it's not initialized, then
	whatever trash gets read up will lead pymalloc to conclude
	(correctly) that the address isn't controlled by it, either
	because the index is out of bounds, or the index is in bounds
	but the arena it represents doesn't contain the address.

        This determination has to be made on every call to one of
	pymalloc's free/realloc entry points, so its speed is critical
	(Python allocates and frees dynamic memory at a ferocious rate
	-- everything in Python, from integers to "stack frames",
	lives in the heap).