Table of Content:
- General overview
- Setting libxml set of memory routines
- Cleaning up after parsing
- Debugging routines
- General memory requirements
The module xmlmemory.h
provides the interfaces to the libxml memory system:
- libxml does not use the libc memory allocator directly but xmlFree(),
xmlMalloc() and xmlRealloc()
- those routines can be reallocated to a specific set of routine, by
default the libc ones i.e. free(), malloc() and realloc()
- the xmlmemory.c module includes a set of debugging routine
It is sometimes useful to not use the default memory allocator, either for
debugging, analysis or to implement a specific behaviour on memory management
(like on embedded systems). Two function calls are available to do so:
-
xmlMemGet ()
which return the current set of functions in use by the parser
-
xmlMemSetup()
which allow to set up a new set of memory allocation functions
Of course a call to xmlMemSetup() should probably be done before calling
any other libxml routines (unless you are sure your allocations routines are
compatibles).
Libxml is not stateless, there is a few set of memory structures needing
allocation before the parser is fully functionnal (some encoding structures
for example). This also mean that once parsing is finished there is a tiny
amount of memory (a few hundred bytes) which can be recollected if you don't
reuse the parser immediately:
-
xmlCleanupParser
()
is a centralized routine to free the parsing states. Note that it won't
deallocate any produced tree if any (use the xmlFreeDoc() and related
routines for this).
-
xmlInitParser
()
is the dual routine allowing to preallocate the parsing state which can
be useful for example to avoid initialization reentrancy problems when
using libxml in multithreaded applications
Generally xmlCleanupParser() is safe, if needed the state will be rebuild
at the next invocation of parser routines, but be careful of the consequences
in multithreaded applications.
When configured using --with-mem-debug flag (off by default), libxml uses
a set of memory allocation debugging routineskeeping track of all allocated
blocks and the location in the code where the routine was called. A couple of
other debugging routines allow to dump the memory allocated infos to a file
or call a specific routine when a given block number is allocated:
When developping libxml memory debug is enabled, the tests programs call
xmlMemoryDump () and the "make test" regression tests will check for any
memory leak during the full regression test sequence, this helps a lot
ensuring that libxml does not leak memory and bullet proof memory
allocations use (some libc implementations are known to be far too permissive
resulting in major portability problems!).
If the .memdump reports a leak, it displays the allocation function and
also tries to give some informations about the content and structure of the
allocated blocks left. This is sufficient in most cases to find the culprit,
but not always. Assuming the allocation problem is reproductible, it is
possible to find more easilly:
- write down the block number xxxx not allocated
- export the environement variable XML_MEM_BREAKPOINT=xxxx
- run the program under a debugger and set a breakpoint on
xmlMallocBreakpoint() a specific function called when this precise block
is allocated
- when the breakpoint is reached you can then do a fine analysis of the
allocation an step to see the condition resulting in the missing
deallocation.
I used to use a commercial tool to debug libxml memory problems but after
noticing that it was not detecting memory leaks that simple mechanism was
used and proved extremely efficient until now.
How much libxml memory require ? It's hard to tell in average it depends
of a number of things:
- the parser itself should work in a fixed amout of memory, except for
information maintained about the stacks of names and entities locations.
The I/O and encoding handlers will probably account for a few KBytes.
This is true for both the XML and HTML parser (though the HTML parser
need more state).
- If you are generating the DOM tree then memory requirements will grow
nearly lineary with the size of the data. In general for a balanced
textual document the internal memory requirement is about 4 times the
size of the UTF8 serialization of this document (exmple the XML-1.0
recommendation is a bit more of 150KBytes and takes 650KBytes of main
memory when parsed). Validation will add a amount of memory required for
maintaining the external Dtd state which should be linear with the
complexity of the content model defined by the Dtd
- If you don't care about the advanced features of libxml like
validation, DOM, XPath or XPointer, but really need to work fixed memory
requirements, then the SAX interface should be used.
Daniel Veillard
|