libcm/cmMem.h

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2012-10-30 03:52:39 +00:00
//{
//(
// The cmMem class implements a memory allocation manager interface.
//
//
// Using cmMem allows memory leaks and some instances of memory corruption
// to be be detected. It can also perform memory block alignment.
//
// The cmMm class acts as an interface for implementing functions designed to replace
// malloc() and free(). cmMm does not actually allocate memory itself but rather
// tracks and conditions block of memory provided by other sources. In this sense
// it acts as a backend for a memory allocation manager.
// cmMallocDebug.h gives an example of using cmMm to interface to malloc() and free().
// cmLinkedHeap.h gives an example of using cmMm to link to an alternate heap manager.
// See cmMdTest() and cmLHeapTest() for usage examples of cmMm.
//
// cmMm works as follows:
//
// 1. A client memory manager creates and configures a cmMm object via cmMmInitialize().
// As part of the configuration the client gives callback functions which implement
// actual memory allocation and release. In practice this means the callback probably
// call malloc() or free().
// 2. At some point later when the client needs to allocate a block of memory it calls
// cmMmAllocate() with the size of the requested block. cmMm translates this request
// into a call to the client provided memory allocation callback to get a block of raw
// memory which is slightly larger than the request block.
// 3. Given the raw memory block cmMm conditions it in the following ways and returns
// it to the client.
// * The base of the blocks data area is shifted such that it is has an arbitrary
// address aligned according to the value set by the alignByteCnt parameter to cmMmInitialize().
// Address aligment is sometimes required by routines which make use of the the SIMD
// unit on some CPUs.
// * 'Guard' bytes are prepended and appended to the blocks data area.
// These bytes are set to the known fixed value (0xaa). At some point later cmMm can
// then test for accidental writes just before or just after the legal data area by
// checking the value of these guard bytes.
// * The number of bytes allocated is written just prior to the leading guard bytes.
// This allows the memory manager to track the
// size of the memory and thereby makes reallocations() to smaller or equal data areas
// very fast. This also allows the size of the data area to be known just by having a
// pointer to the data area (see cmMmByteCount()). This basic information is not availabe
// via malloc().
// * A record is added to an internal database to track the allocation code location
// (file name, file line, function name) and the allocation status (active or released).
// * The client may request that a new block of memory be automatically filled with zeros.
// If automatic zeroing is not requested then the block is filled with 0x55 to indicate that
// it is not initialized. This can be useful when attempting to recognize uninitialized
// memory during debugging.
//
// When a client requests that a block of memory is released cmMm does the following:
//
// 1. If deferred release is enabled (kDeferFreeFl) then the block is filled with 0x33
// but the callback to freeFunc() is not actually made. This allows cmMm to track attempted
// writes to freed memory areas. When deferred release is enabled the freeFunc() is not called
// on any blocks until cmMmFinalize(). If the program continually allocates memory over the
// life of the program this may mean that the program will eventually exhaust physical memory.
// 2. If tracking is enabled (kTrackMmFl) then the block pointer is looked up in the internal database.
// If the pointer is not found then a kMissingRecdRC is returned indicating an attempt to release
// a non-allocated block.
// 3. If tracking is enabled (kTrackMmFl) then the block is marked as released in the
// internal tracking database. At the end of the program all blocks should be marked for release
// otherwise they are considered leaks.
//
//
// At any time during the life of the cmMm object the client can request a report of the
// allocated blocks cmMmReport(). This report examines each allocated block for corrupt guard bytes,
// double frees (attempts to release an allocated block that was already released), and
// leaked blocks (active blocks).
//
//)
#ifndef cmMem_h
#define cmMem_h
#ifdef __cplusplus
extern "C" {
#endif
//(
typedef cmHandle_t cmMmH_t; //< cmMm handle type.
typedef cmRC_t cmMmRC_t; //< cmMm result code types.
// cmMm result codes
enum
{
kOkMmRC = cmOkRC,
kObjAllocFailMmRC,
kTrkAllocFailMmRC,
kAllocFailMmRC,
kFreeFailMmRC,
kMissingRecdMmRC,
kGuardCorruptMmRC,
kWriteAfterFreeMmRC,
kLeakDetectedMmRC,
kDblFreeDetectedMmRC,
kParamErrMmRC
};
// All cmMmH_t variables should be initialized with this value prior to calling cmMmInitialize().
extern cmMmH_t cmMmNullHandle;
// Function signature for data allocation routine client provided to cmMmInitialize().
// Return NULL if byteCnt == 0.
typedef void* (*cmAllocMmFunc_t)(void* funcArgPtr, unsigned byteCnt);
// Function signature for data release routine client provided to cmMmInitialize().
// Return true on success and false on failure. Return true if ptr==NULL.
typedef bool (*cmFreeMmFunc_t)( void* funcArgPtr, void* ptr);
// Flags for use with cmMmInitialize()
enum
{
kTrackMmFl = 0x01, //< Track alloc's and free's for use by cmMmReport().
kDeferFreeMmFl = 0x02, //< Defer memory release until cmMmFinalize() (ignored unless kTrackMmFl is set.) Allows checks for 'write after release'.
kFillUninitMmFl = 0x04, //< Fill uninitialized (non-zeroed) memory with a 0x55 upon allocation
kFillFreedMmFl = 0x08 //< Fill freed memory with 0x33. This allow checks for wite-after-free.
};
// Create a new cmMm object.
// If *hp was not initalized by an earlier call to cmMmInitialize() then it should
// be set to cmMmNullHandle prior to calling this function. If *hp is a valid handle
// then it is automatically finalized by an internal call to cmMmFinalize() prior to
// being re-iniitalized.
cmMmRC_t cmMmInitialize(
cmMmH_t* hp, //< Pointer to a client provided cmMmH_t handle to recieve the handle of the new object.
cmAllocMmFunc_t allocFunc, //< The memory allocation function equivalent to malloc().
cmFreeMmFunc_t freeFunc, //< The memory release function equivalent to free().
void* funcArgPtr, //< An application supplied data value sent with call backs to allocFunc() and freeFunc().
unsigned guardByteCnt, //< Count of guardBytes to precede and follow each allocated block.
unsigned alignByteCnt, //< Address alignment to provide for each allocated block.
unsigned flags, //< Configuration flags (See cmXXXMmFl).
cmRpt_t* rptPtr //< Pointer to an error reporting object.
);
// Release a cmMm object created by an earlier call to cmMmInitialize(). Upon successful completion *hp is set to cmMmNullHandle.
cmMmRC_t cmMmFinalize( cmMmH_t* hp );
unsigned cmMmGuardByteCount( cmMmH_t h ); //< Return the count of guard bytes this cmMm object is applying.
unsigned cmMmAlignByteCount( cmMmH_t h ); //< Return the byte alignment this cmMm object is applying.
unsigned cmMmInitializeFlags( cmMmH_t h ); //< Return the configuration flags this cmMm object was initialized with.
// Return true if 'h' is a valid handle for an existing cmMm object.
bool cmMmIsValid( cmMmH_t h );
// flags for use with cmMmAllocate()
enum cmMmAllocFlags_t
{
kZeroMmFl = 0x01, //< Initialize new memory area to zero.
kAlignMmFl = 0x02, //< Align the returned memory according to the alignByteCnt set in cmMmInitialize().
kPreserveMmFl = 0x04 //< Preserve existing memory contents during reallocation (orgDataPtr!=NULL).
};
// Allocate a block of memory.
// Calling this function results in a call to the function named in allocFunc() in cmMmInitialize().
void* cmMmAllocate(
cmMmH_t h, //< Handle for this cmMm object returned from an earlier successful call to cmMmInitialize().
void* orgDataPtr, //< If this is a re-allocation then this pointer should point to the original allocation otherwise it should be NULL.
unsigned newEleCnt, //< Count of elmements in this allocation.
unsigned newEleByteCnt, //< Bytes per element in this allocation. The total memory request is newEleCnt*newEleByteCnt.
enum cmMmAllocFlags_t flags, //< See cmMmAllocFlags_t.
const char* fileName, //< Name of the C file from which the allocation request is being made.
const char* funcName, //< Name of the C function from which the allocation request is being made.
unsigned fileLine //< Line in the C file on which the allocation request is being made.
);
// Free memory pointed to by dataPtr.
// If dataPtr==NULL then the functon does nothing and returns.
// Calling this function results in a call to the function named in freeFunc() in cmMmInitialize().
// This is the release mode memory free routine. See cmMmFreeDebug() for the debug mode memory release routine.
// See \ref debug_mode for more about debug vs. release mode.
cmMmRC_t cmMmFree( cmMmH_t h, void* dataPtr );
// Debug mode version of cmMmFree(). See cmMmFree() for the release mode memory free routine.
// See debug_mode for more about debug vs. release mode.
// This routine is functionally identical to the cmMmFree() but takes the calling
// location information for use in tracking the block of memory.
cmMmRC_t cmMmFreeDebug( cmMmH_t h, void* dataPtr, const char* fileName, const char* funcName, unsigned fileLine );
// This function is identical to cmMmFree() but takes the address of the pointer
// to the block of memory to free. Upon successful completion *dataPtrPtr is
// set to NULL. In general this should be the preferred version of the free routine
// because it helps to eliminate problems of reusing deallocated memory blocks.
// Note that although dataPtrPtr must point to a valid address *dataPtrPtr may be NULL.
// This routine is generally only used in the release compile mode.
// See cmMmFreePtrDebug() for the debug mode version. See \ref debug_mode for more
// about compile vs. release mode.
cmMmRC_t cmMmFreePtr( cmMmH_t h, void** dataPtrPtr );
// Debug compile mode version of cmMmFreePtr().
// This function is functionally identical to cmMmFreePtr() but accepts information
// on the location of the call to aid in debuging.
cmMmRC_t cmMmFreePtrDebug( cmMmH_t h, void* dataPtr, const char* fileName, const char* funcName, unsigned fileLine );
// Return the size of a memory block returned from cmMmAllocate().
unsigned cmMmByteCount( cmMmH_t h, const void* dataPtr );
// Return the unique id associated with an address returned from cmMmAllocate().
unsigned cmMmDebugId( cmMmH_t h, const void* dataPtr);
// Flags for use with cmMmReport().
enum
{
kSuppressSummaryMmFl = 0x01, //< Do not print a memory use summary report.
kIgnoreNormalMmFl = 0x02, //< Do not print information for non-leaked,non-corrupt memory blocks.
kIgnoreLeaksMmFl = 0x04 //< Do not print information for leaked blocks.
};
// Report on the memory tracking data.
// Returns kMmOkRC if no errors were found otherwise returns the error of the
// last anomoly reported.
cmMmRC_t cmMmReport( cmMmH_t h, unsigned flags );
// Analyze the memory assoc'd with a specific tracking record for corruption.
// Returns: kOkMmRC,kGuardCorruptMmRC,kWriteAfterFreeMmRc, or kMissingRecdMmRC.
// This function is only useful if kTrackMmFl was set in cmMmInitialize().
// Write-after-free errors are only detectable if kDeferFreeMmFl was set in cmMmInitialize().
cmMmRC_t cmMmIsGuardCorrupt( cmMmH_t h, unsigned id );
// Check all tracking records by calling cmMmmIsGuardCorrupt() on each record.
cmMmRC_t cmMmCheckAllGuards( cmMmH_t h );
//)
//}
#ifdef __cplusplus
}
#endif
#endif