// // Copyright (c) 2000 Microsoft Corporation // // Module Name // // heapwalk.c // // Abstract // // Contains functions that create/modify/update the datastructure // HEAP_ENTRY_LIST. HEAP_ENTRY_LIST maintains miminum amount of data // for a HEAP Object. // // Author // // Narayana Batchu (nbatchu) [May 11, 2001] // #include #include #include #include #include "heapwalk.h" // // Initialize // // Initializes and allocates memory for the private member // variables of the HEAP_ENTRY_LIST datastructure. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST whose member variables // to be initialized. // // Return Value // VOID Initialize(LPHEAP_ENTRY_LIST pList) { if (!pList) return; pList->HeapEntryCount = 0; pList->ListSorted = TRUE; pList->PresentCapacity = INITIAL_CAPACITY; pList->pHeapEntries = (LPHEAP_ENTRY_INFO)HeapAlloc( GetProcessHeap(), HEAP_ZERO_MEMORY, sizeof(HEAP_ENTRY_INFO) * pList->PresentCapacity ); if (!pList->pHeapEntries) pList->PresentCapacity = 0; } // // DestroyList // // Cleans up the datastructure HEAP_ENTRY_LIST and frees up the // memory associated with the pHeapEntries member. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST whose member variables // to be cleaned up. // // Return Value // VOID DestroyList(LPHEAP_ENTRY_LIST pList) { if (!pList) return; pList->HeapEntryCount = 0; pList->ListSorted = TRUE; pList->PresentCapacity = 0; HeapFree(GetProcessHeap(), 0, pList->pHeapEntries); } // // GetMaxBlockSize // // This function searches through the HEAP_ENTRY_LIST to find out // the maximum block size whose status is defined by 'State'. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // State Specifies the status to search for the maximum size. // State of any block can be 0 (FREE) and 1 (BUSY). // There are other valid status values also, // but we dont maintain those entries. // // Return Value // // DWORD Returns the maximum size of the block with status 'State'. // ULONG GetMaxBlockSize(LPHEAP_ENTRY_LIST pList, BLOCK_STATE State) { ULONG MaxBlockSize = 0; UINT Index; if (!pList) goto ERROR1; if (FALSE == pList->ListSorted) { SortHeapEntries(pList); } for (Index=0; Index < pList->HeapEntryCount; Index++) { if (State == pList->pHeapEntries[Index].BlockState) { MaxBlockSize = pList->pHeapEntries[Index].BlockSize; break; } } ERROR1: return MaxBlockSize; } // // GetMaxFreeBlockSize // // This function searches through the HEAP_ENTRY_LIST to find out // the maximum free block size. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // Return Value // // DWORD Returns the maximum size of the available block // ULONG GetMaxFreeBlockSize(LPHEAP_ENTRY_LIST pList) { return GetMaxBlockSize(pList, HEAP_BLOCK_FREE); } // // GetMaxAllocBlockSize // // This function searches through the HEAP_ENTRY_LIST to find out // the maximum allocated block size. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // Return Value // // DWORD Returns the maximum size of the allocated block. // ULONG GetMaxAllocBlockSize(LPHEAP_ENTRY_LIST pList) { return GetMaxBlockSize(pList, HEAP_BLOCK_BUSY); } // // GetTopNfreeEntries // // This function scans through the entry list to find the top // n free entries in the list. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // pArray Array of HEAP_ENTRY_INFO structures. This holds the // top n free block sizes available for the process. // // Entries Specifies the top number of entries to be read from // the list. // // Return Value // // BOOL Returns TRUE if successful. // BOOL GetTopNfreeEntries( LPHEAP_ENTRY_LIST pList, LPHEAP_ENTRY_INFO pArray, UINT EntriesToRead) { return GetTopNentries( HEAP_BLOCK_FREE, pList, pArray, EntriesToRead ); } // // GetTopNallocEntries // // This function scans through the entry list to find the top // n allocated entries in the list. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // pArray Array of HEAP_ENTRY_INFO structures. This holds the // top n allocated block sizes available for the process. // // Entries Specifies the top number of entries to be read from // the list. // // Return Value // // BOOL Returns TRUE if successful. // BOOL GetTopNallocEntries( LPHEAP_ENTRY_LIST pList, LPHEAP_ENTRY_INFO pArray, UINT EntriesToRead ) { return GetTopNentries( HEAP_BLOCK_BUSY, pList, pArray, EntriesToRead ); } // // GetTopNallocEntries // // This function scans through the entry list to find the top // n entries in the list, whose staus matches 'State'. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // pArray Array of HEAP_ENTRY_INFO structures. This holds the // top n block sizes available for the process, whose status // matches 'State'. // // Entries Specifies the top number of entries to be read from // the list. // // Return Value // // BOOL Returns TRUE if successful. // BOOL GetTopNentries( BLOCK_STATE State, LPHEAP_ENTRY_LIST pList, LPHEAP_ENTRY_INFO pArray, UINT EntriesToRead ) { BOOL fSuccess = FALSE; UINT EntriesRead = 0; UINT Index; if (!pArray || !pList) goto ERROR2; if (FALSE == pList->ListSorted) { SortHeapEntries(pList); } for (Index=0; Index < pList->HeapEntryCount; Index++) { if (EntriesRead == EntriesToRead) break; if (State == pList->pHeapEntries[Index].BlockState) { pArray[EntriesRead].BlockSize = pList->pHeapEntries[Index].BlockSize; pArray[EntriesRead].BlockCount = pList->pHeapEntries[Index].BlockCount; pArray[EntriesRead].BlockState = pList->pHeapEntries[Index].BlockState; EntriesRead++; } } if (EntriesRead == EntriesToRead) fSuccess = TRUE; ERROR2: return fSuccess; } // // IncreaseCapacity // // Increases the array capacity by double. This function is called // when tried to insert at the end of the array which is full. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // Return Value // // BOOL Returns TRUE if successful in increasing the capacity. // BOOL IncreaseCapacity(LPHEAP_ENTRY_LIST pList) { BOOL fSuccess = FALSE; UINT NewCapacity; if (!pList) goto ERROR3; NewCapacity = pList->PresentCapacity * 2; if (0 == NewCapacity) NewCapacity = INITIAL_CAPACITY; __try { pList->pHeapEntries = (LPHEAP_ENTRY_INFO)HeapReAlloc( GetProcessHeap(), HEAP_GENERATE_EXCEPTIONS | HEAP_ZERO_MEMORY, pList->pHeapEntries, sizeof(HEAP_ENTRY_INFO) * NewCapacity ); pList->PresentCapacity = NewCapacity; fSuccess = TRUE; } __except(GetExceptionCode() == STATUS_NO_MEMORY || GetExceptionCode() == STATUS_ACCESS_VIOLATION) { // // Ignoring the exceptions raised by HeapReAlloc(). // } ERROR3: return fSuccess; } // // FindMatch // // Finds an entry in the HEAP_ENTRY_LIST that matches the size and // status of pHeapEntry. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // pHeapEntry Pointer to HEAP_ENTRY_INFO to be serached for in 'pList'. // // Return Value // // DWORD Index of the heap entry that matched the input heap entry // 'pHeapEntry' // // UINT FindMatch(LPHEAP_ENTRY_LIST pList, LPHEAP_ENTRY_INFO pHeapEntry) { UINT MatchedEntry = NO_MATCH; UINT Index; if (!pList || !pHeapEntry) goto ERROR4; for (Index = 0; Index < pList->HeapEntryCount; Index++) { if (pList->pHeapEntries[Index].BlockSize == pHeapEntry->BlockSize && pList->pHeapEntries[Index].BlockState == pHeapEntry->BlockState) { MatchedEntry = Index; break; } } ERROR4: return MatchedEntry; } // // InsertHeapEntry // // Inserts a new heap entry to the list. It updates the block count if // a match is found else a new entry is made at the end of the HEAP_ // ENTRY_INFO array. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST. // // pHeapEntry Pointer to HEAP_ENTRY_INFO that is to be added to 'pList'. // // Return Value // // DWORD Returns the index at which it is added to the array. If // for any reason, it is not added to the list, then it // returns NO_MATCH value. // UINT InsertHeapEntry(LPHEAP_ENTRY_LIST pList, LPHEAP_ENTRY_INFO pHeapEntry) { UINT MatchedEntry = NO_MATCH; if (!pList || !pHeapEntry) goto ERROR5; MatchedEntry = FindMatch(pList, pHeapEntry); if (NO_MATCH != MatchedEntry) pList->pHeapEntries[MatchedEntry].BlockCount++; else { UINT Index = pList->HeapEntryCount; if (Index == pList->PresentCapacity && !IncreaseCapacity(pList)) goto ERROR5; pList->pHeapEntries[Index].BlockSize = pHeapEntry->BlockSize; pList->pHeapEntries[Index].BlockState = pHeapEntry->BlockState; pList->pHeapEntries[Index].BlockCount = 1; MatchedEntry = Index; pList->HeapEntryCount++; pList->ListSorted = FALSE; } ERROR5: return MatchedEntry; } // // DeleteHeapEntry // // Deletes a new heap entry to the list. It decrements the block count // if a match is found. // // Its possible that the block size is zero and still the heap entry // exits. In such cases we dont decrement the block count (which would // make it negative) and return a NO_MATCH. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST // // pHeapEntry Pointer to HEAP_ENTRY_INFO that is to be removed from 'pList'. // // Return Value // // DWORD Returns the index at which it is removed from the array. If for // any reason (Count==0), it is not removed to the list, then it // returns NO_MATCH value. // UINT DeleteHeapEntry(LPHEAP_ENTRY_LIST pList, LPHEAP_ENTRY_INFO pHeapEntry) { UINT MatchedEntry = NO_MATCH; if (!pList || !pHeapEntry) goto ERROR6; MatchedEntry = FindMatch(pList, pHeapEntry); if (NO_MATCH != MatchedEntry && 0 != pList->pHeapEntries[MatchedEntry].BlockCount) { pList->pHeapEntries[MatchedEntry].BlockCount--; } else MatchedEntry = NO_MATCH; ERROR6: return MatchedEntry; } // // SortByBlockSize // // Compare function required by qsort (uses quick sort to sort // the elements in the array). // // More info about the arguments and the return values could be // found in MSDN. // int __cdecl SortByBlockSize(const void * arg1, const void *arg2) { int iCompare; LPHEAP_ENTRY_INFO hpEntry1 = (LPHEAP_ENTRY_INFO)arg1; LPHEAP_ENTRY_INFO hpEntry2 = (LPHEAP_ENTRY_INFO)arg2; iCompare = (hpEntry2->BlockSize - hpEntry1->BlockSize); return iCompare; } // // DisplayHeapFragStatistics // // Sorts and displays the fragmentation statistics. It displays // two tables one for free blocks and another for allocated blocks. // // Arguments // // File Pointer to C FILE structure, to which the heap frag- // mentation statistics have to be dumped. // // pList Pointer to HEAP_ENTRY_LIST, to be sorted and // dumped to 'File'. // // Return Value // VOID DisplayHeapFragStatistics( FILE * File, PVOID HeapAddress, LPHEAP_ENTRY_LIST pList ) { if (!pList) return; fprintf( File, "\n*- - - - - - - - - - Heap %p Fragmentation Statistics - - - - - - - - - -\n\n", HeapAddress ); SortHeapEntries(pList); PrintList(File, pList, HEAP_BLOCK_BUSY); PrintList(File, pList, HEAP_BLOCK_FREE); } // // SortHeapEntries // // Sorts the heap entries based on their sizes. The top most entry // would be having the maximun block size. // // Also, removes those heap entries from the array whose block count // has dropped to zero, making available more space. // // Arguments // // pList Pointer to HEAP_ENTRY_LIST, whose entries to be sorted by // their sizes. // // Return Value // VOID SortHeapEntries(LPHEAP_ENTRY_LIST pList) { UINT Index; if (!pList) return; if (FALSE == pList->ListSorted) { qsort( pList->pHeapEntries, pList->HeapEntryCount, sizeof(HEAP_ENTRY_INFO), &SortByBlockSize ); for (Index = pList->HeapEntryCount-1; Index > 0; Index--) { if (0 != pList->pHeapEntries[Index].BlockCount) break; } pList->HeapEntryCount = Index + 1; pList->ListSorted = TRUE; } } // // PrintList // // Utility function that prints out the heap entries to the stdout/ // file, whose status is equal to "State". // // Arguments // // File Pointer to C FILE structure, to which the heap frag- // mentation statistics have to be dumped. // // pList Pointer to HEAP_ENTRY_LIST, to be sorted and // dumped to 'File'. // // State State of the blocks to be displayed. // // Return Value // VOID PrintList(FILE * File, LPHEAP_ENTRY_LIST pList, BLOCK_STATE State) { UINT Index; if (!pList) return; if (HEAP_BLOCK_FREE == State) fprintf(File, "\nTable of Free Blocks\n\n"); else if (HEAP_BLOCK_BUSY == State) fprintf(File, "\nTable of Allocated Blocks\n\n"); fprintf(File, " SIZE | COUNT\n"); fprintf(File, " --------------\n"); for (Index = 0; Index < pList->HeapEntryCount; Index++) { if (State == pList->pHeapEntries[Index].BlockState) { fprintf( File, " 0x%04x | 0x%02x\n", pList->pHeapEntries[Index].BlockSize, pList->pHeapEntries[Index].BlockCount ); } } fprintf(File, "\n"); }