//========= Copyright Valve Corporation, All rights reserved. ============// // // Purpose: // //===========================================================================// #include "mempool.h" #include #include #include #include "tier0/dbg.h" #include #include "tier1/strtools.h" // Should be last include #include "tier0/memdbgon.h" MemoryPoolReportFunc_t CUtlMemoryPool::g_ReportFunc = 0; //----------------------------------------------------------------------------- // Error reporting... (debug only) //----------------------------------------------------------------------------- void CUtlMemoryPool::SetErrorReportFunc( MemoryPoolReportFunc_t func ) { g_ReportFunc = func; } //----------------------------------------------------------------------------- // Purpose: Constructor //----------------------------------------------------------------------------- CUtlMemoryPool::CUtlMemoryPool( int blockSize, int numElements, int growMode, const char *pszAllocOwner, int nAlignment ) { #ifdef _X360 if( numElements > 0 && growMode != UTLMEMORYPOOL_GROW_NONE ) { numElements = 1; } #endif m_nAlignment = ( nAlignment != 0 ) ? nAlignment : 1; Assert( IsPowerOfTwo( m_nAlignment ) ); m_BlockSize = blockSize < sizeof(void*) ? sizeof(void*) : blockSize; m_BlockSize = AlignValue( m_BlockSize, m_nAlignment ); m_BlocksPerBlob = numElements; m_PeakAlloc = 0; m_GrowMode = growMode; if ( !pszAllocOwner ) { pszAllocOwner = __FILE__; } m_pszAllocOwner = pszAllocOwner; Init(); AddNewBlob(); } //----------------------------------------------------------------------------- // Purpose: Frees the memory contained in the mempool, and invalidates it for // any further use. // Input : *memPool - the mempool to shutdown //----------------------------------------------------------------------------- CUtlMemoryPool::~CUtlMemoryPool() { if (m_BlocksAllocated > 0) { ReportLeaks(); } Clear(); } //----------------------------------------------------------------------------- // Resets the pool //----------------------------------------------------------------------------- void CUtlMemoryPool::Init() { m_NumBlobs = 0; m_BlocksAllocated = 0; m_pHeadOfFreeList = 0; m_BlobHead.m_pNext = m_BlobHead.m_pPrev = &m_BlobHead; } //----------------------------------------------------------------------------- // Frees everything //----------------------------------------------------------------------------- void CUtlMemoryPool::Clear() { // Free everything.. CBlob *pNext; for( CBlob *pCur = m_BlobHead.m_pNext; pCur != &m_BlobHead; pCur = pNext ) { pNext = pCur->m_pNext; free( pCur ); } Init(); } //----------------------------------------------------------------------------- // Purpose: Reports memory leaks //----------------------------------------------------------------------------- void CUtlMemoryPool::ReportLeaks() { if (!g_ReportFunc) return; g_ReportFunc("Memory leak: mempool blocks left in memory: %d\n", m_BlocksAllocated); #ifdef _DEBUG // walk and destroy the free list so it doesn't intefere in the scan while (m_pHeadOfFreeList != NULL) { void *next = *((void**)m_pHeadOfFreeList); memset(m_pHeadOfFreeList, 0, m_BlockSize); m_pHeadOfFreeList = next; } g_ReportFunc("Dumping memory: \'"); for( CBlob *pCur=m_BlobHead.m_pNext; pCur != &m_BlobHead; pCur=pCur->m_pNext ) { // scan the memory block and dump the leaks char *scanPoint = (char *)pCur->m_Data; char *scanEnd = pCur->m_Data + pCur->m_NumBytes; bool needSpace = false; while (scanPoint < scanEnd) { // search for and dump any strings if ((unsigned)(*scanPoint + 1) <= 256 && isprint(*scanPoint)) { g_ReportFunc("%c", *scanPoint); needSpace = true; } else if (needSpace) { needSpace = false; g_ReportFunc(" "); } scanPoint++; } } g_ReportFunc("\'\n"); #endif // _DEBUG } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- void CUtlMemoryPool::AddNewBlob() { MEM_ALLOC_CREDIT_(m_pszAllocOwner); int sizeMultiplier; if( m_GrowMode == UTLMEMORYPOOL_GROW_SLOW ) { sizeMultiplier = 1; } else { if ( m_GrowMode == UTLMEMORYPOOL_GROW_NONE ) { // Can only have one allocation when we're in this mode if( m_NumBlobs != 0 ) { Assert( !"CUtlMemoryPool::AddNewBlob: mode == UTLMEMORYPOOL_GROW_NONE" ); return; } } // GROW_FAST and GROW_NONE use this. sizeMultiplier = m_NumBlobs + 1; } // maybe use something other than malloc? int nElements = m_BlocksPerBlob * sizeMultiplier; int blobSize = m_BlockSize * nElements; CBlob *pBlob = (CBlob*)malloc( sizeof(CBlob) - 1 + blobSize + ( m_nAlignment - 1 ) ); Assert( pBlob ); // Link it in at the end of the blob list. pBlob->m_NumBytes = blobSize; pBlob->m_pNext = &m_BlobHead; pBlob->m_pPrev = pBlob->m_pNext->m_pPrev; pBlob->m_pNext->m_pPrev = pBlob->m_pPrev->m_pNext = pBlob; // setup the free list m_pHeadOfFreeList = AlignValue( pBlob->m_Data, m_nAlignment ); Assert (m_pHeadOfFreeList); void **newBlob = (void**)m_pHeadOfFreeList; for (int j = 0; j < nElements-1; j++) { newBlob[0] = (char*)newBlob + m_BlockSize; newBlob = (void**)newBlob[0]; } // null terminate list newBlob[0] = NULL; m_NumBlobs++; } void* CUtlMemoryPool::Alloc() { return Alloc( m_BlockSize ); } void* CUtlMemoryPool::AllocZero() { return AllocZero( m_BlockSize ); } //----------------------------------------------------------------------------- // Purpose: Allocs a single block of memory from the pool. // Input : amount - //----------------------------------------------------------------------------- void *CUtlMemoryPool::Alloc( size_t amount ) { void *returnBlock; if ( amount > (unsigned int)m_BlockSize ) return NULL; if( !m_pHeadOfFreeList ) { // returning NULL is fine in UTLMEMORYPOOL_GROW_NONE if( m_GrowMode == UTLMEMORYPOOL_GROW_NONE ) { //Assert( !"CUtlMemoryPool::Alloc: tried to make new blob with UTLMEMORYPOOL_GROW_NONE" ); return NULL; } // overflow AddNewBlob(); // still failure, error out if( !m_pHeadOfFreeList ) { Assert( !"CUtlMemoryPool::Alloc: ran out of memory" ); return NULL; } } m_BlocksAllocated++; m_PeakAlloc = max(m_PeakAlloc, m_BlocksAllocated); returnBlock = m_pHeadOfFreeList; // move the pointer the next block m_pHeadOfFreeList = *((void**)m_pHeadOfFreeList); return returnBlock; } //----------------------------------------------------------------------------- // Purpose: Allocs a single block of memory from the pool, zeroes the memory before returning // Input : amount - //----------------------------------------------------------------------------- void *CUtlMemoryPool::AllocZero( size_t amount ) { void *mem = Alloc( amount ); if ( mem ) { V_memset( mem, 0x00, amount ); } return mem; } //----------------------------------------------------------------------------- // Purpose: Frees a block of memory // Input : *memBlock - the memory to free //----------------------------------------------------------------------------- void CUtlMemoryPool::Free( void *memBlock ) { if ( !memBlock ) return; // trying to delete NULL pointer, ignore #ifdef _DEBUG // check to see if the memory is from the allocated range bool bOK = false; for( CBlob *pCur=m_BlobHead.m_pNext; pCur != &m_BlobHead; pCur=pCur->m_pNext ) { if (memBlock >= pCur->m_Data && (char*)memBlock < (pCur->m_Data + pCur->m_NumBytes)) { bOK = true; } } Assert (bOK); #endif // _DEBUG #ifdef _DEBUG // invalidate the memory memset( memBlock, 0xDD, m_BlockSize ); #endif m_BlocksAllocated--; // make the block point to the first item in the list *((void**)memBlock) = m_pHeadOfFreeList; // the list head is now the new block m_pHeadOfFreeList = memBlock; }