/*++ Copyright (c) 1989 Microsoft Corporation Module Name: heapdbg.c Abstract: This module implements a debugging layer on top of heap allocator. Author: Steve Wood (stevewo) 20-Sep-1994 Revision History: --*/ #include "ntrtlp.h" #include "heap.h" #include "heappriv.h" BOOLEAN RtlpValidateHeapHdrsEnable = FALSE; // Set to TRUE if headers are being corrupted BOOLEAN RtlpValidateHeapTagsEnable; // Set to TRUE if tag counts are off and you want to know why HEAP_STOP_ON_VALUES RtlpHeapStopOn; const struct { ULONG Offset; LPSTR Description; } RtlpHeapHeaderFieldOffsets[] = { FIELD_OFFSET( HEAP, Entry ), "Entry", FIELD_OFFSET( HEAP, Signature ), "Signature", FIELD_OFFSET( HEAP, Flags ), "Flags", FIELD_OFFSET( HEAP, ForceFlags ), "ForceFlags", FIELD_OFFSET( HEAP, VirtualMemoryThreshold ), "VirtualMemoryThreshold", FIELD_OFFSET( HEAP, SegmentReserve ), "SegmentReserve", FIELD_OFFSET( HEAP, SegmentCommit ), "SegmentCommit", FIELD_OFFSET( HEAP, DeCommitFreeBlockThreshold ), "DeCommitFreeBlockThreshold", FIELD_OFFSET( HEAP, DeCommitTotalFreeThreshold ), "DeCommitTotalFreeThreshold", FIELD_OFFSET( HEAP, TotalFreeSize ), "TotalFreeSize", FIELD_OFFSET( HEAP, MaximumAllocationSize ), "MaximumAllocationSize", FIELD_OFFSET( HEAP, ProcessHeapsListIndex ), "ProcessHeapsListIndex", FIELD_OFFSET( HEAP, HeaderValidateLength ), "HeaderValidateLength", FIELD_OFFSET( HEAP, HeaderValidateCopy ), "HeaderValidateCopy", FIELD_OFFSET( HEAP, NextAvailableTagIndex ), "NextAvailableTagIndex", FIELD_OFFSET( HEAP, MaximumTagIndex ), "MaximumTagIndex", FIELD_OFFSET( HEAP, TagEntries ), "TagEntries", FIELD_OFFSET( HEAP, UCRSegments ), "UCRSegments", FIELD_OFFSET( HEAP, UnusedUnCommittedRanges ), "UnusedUnCommittedRanges", FIELD_OFFSET( HEAP, AlignRound ), "AlignRound", FIELD_OFFSET( HEAP, AlignMask ), "AlignMask", FIELD_OFFSET( HEAP, VirtualAllocdBlocks ), "VirtualAllocdBlocks", FIELD_OFFSET( HEAP, Segments ), "Segments", FIELD_OFFSET( HEAP, u ), "FreeListsInUse", FIELD_OFFSET( HEAP, u2 ), "FreeListsInUseTerminate", FIELD_OFFSET( HEAP, AllocatorBackTraceIndex ), "AllocatorBackTraceIndex", FIELD_OFFSET( HEAP, NonDedicatedListLength ), "NonDedicatedListLength", FIELD_OFFSET( HEAP, PseudoTagEntries ), "PseudoTagEntries", FIELD_OFFSET( HEAP, FreeLists ), "FreeLists", FIELD_OFFSET( HEAP, LockVariable ), "LockVariable", FIELD_OFFSET( HEAP, FrontEndHeap ), "FrontEndHeap", FIELD_OFFSET( HEAP, FrontHeapLockCount ), "FrontHeapLockCount", FIELD_OFFSET( HEAP, FrontEndHeapType ), "FrontEndHeapType", FIELD_OFFSET( HEAP, LastSegmentIndex ), "LastSegmentIndex", sizeof( HEAP ), "Uncommitted Ranges", 0xFFFF, NULL }; VOID RtlpUpdateHeapListIndex ( USHORT OldIndex, USHORT NewIndex ) /*++ Routine Description: Arguments: Return Value: --*/ { if (RtlpHeapStopOn.AllocTag.HeapIndex == OldIndex) { RtlpHeapStopOn.AllocTag.HeapIndex = NewIndex; } if (RtlpHeapStopOn.ReAllocTag.HeapIndex == OldIndex) { RtlpHeapStopOn.ReAllocTag.HeapIndex = NewIndex; } if (RtlpHeapStopOn.FreeTag.HeapIndex == OldIndex) { RtlpHeapStopOn.FreeTag.HeapIndex = NewIndex; } return; } BOOLEAN RtlpValidateHeapHeaders ( IN PHEAP Heap, IN BOOLEAN Recompute ) /*++ Routine Description: Arguments: Return Value: --*/ { ULONG i; SIZE_T n; SIZE_T nEqual; NTSTATUS Status; if (!RtlpValidateHeapHdrsEnable) { return TRUE; } if (Heap->HeaderValidateCopy == NULL) { n = Heap->HeaderValidateLength; Status = NtAllocateVirtualMemory( NtCurrentProcess(), &Heap->HeaderValidateCopy, 0, &n, MEM_COMMIT, PAGE_READWRITE ); if (!NT_SUCCESS( Status )) { return TRUE; } Recompute = TRUE; } n = Heap->HeaderValidateLength; if (!Recompute) { nEqual = RtlCompareMemory( Heap, Heap->HeaderValidateCopy, n ); } else { RtlCopyMemory( Heap->HeaderValidateCopy, Heap, n ); nEqual = n; } if (n != nEqual) { HeapDebugPrint(( "Heap %x - headers modified (%x is %x instead of %x)\n", Heap, (PCHAR)Heap + nEqual, *(PULONG)((PCHAR)Heap + nEqual), *(PULONG)((PCHAR)Heap->HeaderValidateCopy + nEqual))); for (i=0; RtlpHeapHeaderFieldOffsets[ i ].Description != NULL; i++) { if ((nEqual >= RtlpHeapHeaderFieldOffsets[ i ].Offset) && (nEqual < RtlpHeapHeaderFieldOffsets[ i+1 ].Offset)) { DbgPrint( " This is located in the %s field of the heap header.\n", RtlpHeapHeaderFieldOffsets[ i ].Description ); break; } } return FALSE; } else { return TRUE; } } PVOID RtlDebugCreateHeap ( IN ULONG Flags, IN PVOID HeapBase OPTIONAL, IN SIZE_T ReserveSize OPTIONAL, IN SIZE_T CommitSize OPTIONAL, IN PVOID Lock OPTIONAL, IN PRTL_HEAP_PARAMETERS Parameters ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap; NTSTATUS Status; MEMORY_BASIC_INFORMATION MemoryInformation; if (ReserveSize <= sizeof( HEAP_ENTRY )) { HeapDebugPrint(( "Invalid ReserveSize parameter - %p\n", ReserveSize )); HeapDebugBreak( NULL ); return NULL; } if (ReserveSize < CommitSize) { HeapDebugPrint(( "Invalid CommitSize parameter - %p\n", CommitSize )); HeapDebugBreak( NULL ); return NULL; } if ((Flags & HEAP_NO_SERIALIZE) && ARGUMENT_PRESENT( Lock )) { HeapDebugPrint(( "May not specify Lock parameter with HEAP_NO_SERIALIZE\n" )); HeapDebugBreak( NULL ); return NULL; } if (ARGUMENT_PRESENT( HeapBase )) { Status = NtQueryVirtualMemory( NtCurrentProcess(), HeapBase, MemoryBasicInformation, &MemoryInformation, sizeof( MemoryInformation ), NULL ); if (!NT_SUCCESS( Status )) { HeapDebugPrint(( "Specified HeapBase (%p) invalid, Status = %lx\n", HeapBase, Status )); HeapDebugBreak( NULL ); return NULL; } if (MemoryInformation.BaseAddress != HeapBase) { HeapDebugPrint(( "Specified HeapBase (%p) != to BaseAddress (%p)\n", HeapBase, MemoryInformation.BaseAddress )); HeapDebugBreak( NULL ); return NULL; } if (MemoryInformation.State == MEM_FREE) { HeapDebugPrint(( "Specified HeapBase (%p) is free or not writable\n", MemoryInformation.BaseAddress )); HeapDebugBreak( NULL ); return NULL; } } Heap = RtlCreateHeap( Flags | HEAP_SKIP_VALIDATION_CHECKS | HEAP_TAIL_CHECKING_ENABLED | HEAP_FREE_CHECKING_ENABLED, HeapBase, ReserveSize, CommitSize, Lock, Parameters ); if (Heap != NULL) { if (Heap->Flags & HEAP_CAPTURE_STACK_BACKTRACES) { Heap->AllocatorBackTraceIndex = (USHORT)RtlLogStackBackTrace(); } RtlpValidateHeapHeaders( Heap, TRUE ); } return Heap; } BOOLEAN RtlpSerializeHeap ( IN PVOID HeapHandle ) /*++ Routine Description: Arguments: Return Value: --*/ { NTSTATUS Status; PHEAP Heap = (PHEAP)HeapHandle; PHEAP_LOCK Lock; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapSerialize( HeapHandle )); // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlpSerializeHeap" )) { return FALSE; } // // Lock the heap. // if (Heap->Flags & HEAP_NO_SERIALIZE) { Lock = RtlAllocateHeap( HeapHandle, HEAP_NO_SERIALIZE, sizeof( *Lock ) ); if ( Lock == NULL ) { return FALSE; } Status = RtlInitializeLockRoutine( Lock ); if (!NT_SUCCESS( Status )) { RtlFreeHeap( HeapHandle, HEAP_NO_SERIALIZE, Lock ); return FALSE; } Heap->LockVariable = Lock; Heap->Flags &= ~HEAP_NO_SERIALIZE; Heap->ForceFlags &= ~HEAP_NO_SERIALIZE; RtlpValidateHeapHeaders( Heap, TRUE ); } return TRUE; } BOOLEAN RtlDebugDestroyHeap ( IN PVOID HeapHandle ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; LIST_ENTRY ListEntry; SIZE_T n; if (HeapHandle == NtCurrentPeb()->ProcessHeap) { HeapDebugPrint(( "May not destroy the process heap at %x\n", HeapHandle )); return FALSE; } if (!RtlpCheckHeapSignature( Heap, "RtlDestroyHeap" )) { return FALSE; } if (!RtlpValidateHeap( Heap, FALSE )) { return FALSE; } // // Now mark the heap as invalid by zeroing the signature field. // Heap->Signature = 0; if (Heap->HeaderValidateCopy != NULL) { n = 0; RtlpHeapFreeVirtualMemory( NtCurrentProcess(), &Heap->HeaderValidateCopy, &n, MEM_RELEASE ); } return TRUE; } PVOID RtlDebugAllocateHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN SIZE_T Size ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; BOOLEAN LockAcquired = FALSE; PVOID ReturnValue = NULL; SIZE_T AllocationSize; USHORT TagIndex; PHEAP_ENTRY BusyBlock; PHEAP_ENTRY_EXTRA ExtraStuff; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapAllocate( HeapHandle, Flags, Size )); try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlAllocateHeap" )) { ReturnValue = NULL; leave; } Flags |= Heap->ForceFlags | HEAP_SETTABLE_USER_VALUE | HEAP_SKIP_VALIDATION_CHECKS; // // Verify that the size did not wrap or exceed the limit for this heap. // AllocationSize = (((Size ? Size : 1) + Heap->AlignRound) & Heap->AlignMask) + sizeof( HEAP_ENTRY_EXTRA ); if ((AllocationSize < Size) || (AllocationSize > Heap->MaximumAllocationSize)) { HeapDebugPrint(( "Invalid allocation size - %p (exceeded %x)\n", Size, Heap->MaximumAllocationSize )); ReturnValue = NULL; leave; } // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } RtlpValidateHeap( Heap, FALSE ); ReturnValue = RtlAllocateHeapSlowly( HeapHandle, Flags, Size ); RtlpValidateHeapHeaders( Heap, TRUE ); if (ReturnValue != NULL) { BusyBlock = (PHEAP_ENTRY)ReturnValue - 1; if (BusyBlock->Flags & HEAP_ENTRY_EXTRA_PRESENT) { ExtraStuff = RtlpGetExtraStuffPointer( BusyBlock ); if (Heap->Flags & HEAP_CAPTURE_STACK_BACKTRACES) { ExtraStuff->AllocatorBackTraceIndex = (USHORT)RtlLogStackBackTrace(); } else { ExtraStuff->AllocatorBackTraceIndex = 0; } TagIndex = ExtraStuff->TagIndex; } else { TagIndex = BusyBlock->SmallTagIndex; } if (Heap->Flags & HEAP_VALIDATE_ALL_ENABLED) { RtlpValidateHeap( Heap, FALSE ); } } if (ReturnValue != NULL) { if ((ULONG_PTR)ReturnValue == RtlpHeapStopOn.AllocAddress) { HeapDebugPrint(( "Just allocated block at %p for 0x%x bytes\n", RtlpHeapStopOn.AllocAddress, Size )); HeapDebugBreak( NULL ); } else if ((IS_HEAP_TAGGING_ENABLED()) && (TagIndex != 0) && (TagIndex == RtlpHeapStopOn.AllocTag.TagIndex) && (Heap->ProcessHeapsListIndex == RtlpHeapStopOn.AllocTag.HeapIndex)) { HeapDebugPrint(( "Just allocated block at %p for 0x%x bytes with tag %ws\n", ReturnValue, Size, RtlpGetTagName( Heap, TagIndex ))); HeapDebugBreak( NULL ); } } } except( GetExceptionCode() == STATUS_NO_MEMORY ? EXCEPTION_CONTINUE_SEARCH : EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); ReturnValue = NULL; } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return ReturnValue; } PVOID RtlDebugReAllocateHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN PVOID BaseAddress, IN SIZE_T Size ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; SIZE_T AllocationSize; PHEAP_ENTRY BusyBlock; PHEAP_ENTRY_EXTRA ExtraStuff; BOOLEAN LockAcquired = FALSE; PVOID ReturnValue = NULL; USHORT TagIndex; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapReAllocate( HeapHandle, Flags, BaseAddress, Size )); try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlReAllocateHeap" )) { ReturnValue = NULL; leave; } Flags |= Heap->ForceFlags | HEAP_SETTABLE_USER_VALUE | HEAP_SKIP_VALIDATION_CHECKS; // // Verify that the size did not wrap or exceed the limit for this heap. // AllocationSize = (((Size ? Size : 1) + Heap->AlignRound) & Heap->AlignMask) + sizeof( HEAP_ENTRY_EXTRA ); if (AllocationSize < Size || AllocationSize > Heap->MaximumAllocationSize) { HeapDebugPrint(( "Invalid allocation size - %p (exceeded %x)\n", Size, Heap->MaximumAllocationSize )); HeapDebugBreak( NULL ); ReturnValue = NULL; leave; } // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } RtlpValidateHeap( Heap, FALSE ); BusyBlock = (PHEAP_ENTRY)BaseAddress - 1; if (RtlpValidateHeapEntry( Heap, BusyBlock, "RtlReAllocateHeap" )) { if ((ULONG_PTR)BaseAddress == RtlpHeapStopOn.ReAllocAddress) { HeapDebugPrint(( "About to reallocate block at %p to 0x%x bytes\n", RtlpHeapStopOn.ReAllocAddress, Size )); HeapDebugBreak( NULL ); } else if (IS_HEAP_TAGGING_ENABLED() && RtlpHeapStopOn.ReAllocTag.HeapAndTagIndex != 0) { if (BusyBlock->Flags & HEAP_ENTRY_EXTRA_PRESENT) { ExtraStuff = RtlpGetExtraStuffPointer( BusyBlock ); TagIndex = ExtraStuff->TagIndex; } else { TagIndex = BusyBlock->SmallTagIndex; } if ((TagIndex != 0) && (TagIndex == RtlpHeapStopOn.ReAllocTag.TagIndex) && (Heap->ProcessHeapsListIndex == RtlpHeapStopOn.ReAllocTag.HeapIndex)) { HeapDebugPrint(( "About to rellocate block at %p to 0x%x bytes with tag %ws\n", BaseAddress, Size, RtlpGetTagName( Heap, TagIndex ))); HeapDebugBreak( NULL ); } } ReturnValue = RtlReAllocateHeap( HeapHandle, Flags, BaseAddress, Size ); if (ReturnValue != NULL) { BusyBlock = (PHEAP_ENTRY)ReturnValue - 1; if (BusyBlock->Flags & HEAP_ENTRY_EXTRA_PRESENT) { ExtraStuff = RtlpGetExtraStuffPointer( BusyBlock ); if (Heap->Flags & HEAP_CAPTURE_STACK_BACKTRACES) { ExtraStuff->AllocatorBackTraceIndex = (USHORT)RtlLogStackBackTrace(); } else { ExtraStuff->AllocatorBackTraceIndex = 0; } TagIndex = ExtraStuff->TagIndex; } else { TagIndex = BusyBlock->SmallTagIndex; } } RtlpValidateHeapHeaders( Heap, TRUE ); RtlpValidateHeap( Heap, FALSE ); } if (ReturnValue != NULL) { if ((ULONG_PTR)ReturnValue == RtlpHeapStopOn.ReAllocAddress) { HeapDebugPrint(( "Just reallocated block at %p to 0x%x bytes\n", RtlpHeapStopOn.ReAllocAddress, Size )); HeapDebugBreak( NULL ); } else if ((IS_HEAP_TAGGING_ENABLED()) && (TagIndex == RtlpHeapStopOn.ReAllocTag.TagIndex) && (Heap->ProcessHeapsListIndex == RtlpHeapStopOn.ReAllocTag.HeapIndex)) { HeapDebugPrint(( "Just reallocated block at %p to 0x%x bytes with tag %ws\n", ReturnValue, Size, RtlpGetTagName( Heap, TagIndex ))); HeapDebugBreak( NULL ); } } } except( GetExceptionCode() == STATUS_NO_MEMORY ? EXCEPTION_CONTINUE_SEARCH : EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); ReturnValue = NULL; } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return ReturnValue; } BOOLEAN RtlDebugFreeHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN PVOID BaseAddress ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; PHEAP_ENTRY BusyBlock; PHEAP_ENTRY_EXTRA ExtraStuff; SIZE_T Size; BOOLEAN Result = FALSE; BOOLEAN LockAcquired = FALSE; USHORT TagIndex; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapFree( HeapHandle, Flags, BaseAddress )); try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlFreeHeap" )) { Result = FALSE; leave; } Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } RtlpValidateHeap( Heap, FALSE ); BusyBlock = (PHEAP_ENTRY)BaseAddress - 1; Size = BusyBlock->Size << HEAP_GRANULARITY_SHIFT; if (RtlpValidateHeapEntry( Heap, BusyBlock, "RtlFreeHeap" )) { if ((ULONG_PTR)BaseAddress == RtlpHeapStopOn.FreeAddress) { HeapDebugPrint(( "About to free block at %p\n", RtlpHeapStopOn.FreeAddress )); HeapDebugBreak( NULL ); } else if ((IS_HEAP_TAGGING_ENABLED()) && (RtlpHeapStopOn.FreeTag.HeapAndTagIndex != 0)) { if (BusyBlock->Flags & HEAP_ENTRY_EXTRA_PRESENT) { ExtraStuff = RtlpGetExtraStuffPointer( BusyBlock ); TagIndex = ExtraStuff->TagIndex; } else { TagIndex = BusyBlock->SmallTagIndex; } if ((TagIndex != 0) && (TagIndex == RtlpHeapStopOn.FreeTag.TagIndex) && (Heap->ProcessHeapsListIndex == RtlpHeapStopOn.FreeTag.HeapIndex)) { HeapDebugPrint(( "About to free block at %p with tag %ws\n", BaseAddress, RtlpGetTagName( Heap, TagIndex ))); HeapDebugBreak( NULL ); } } Result = RtlFreeHeapSlowly( HeapHandle, Flags, BaseAddress ); RtlpValidateHeapHeaders( Heap, TRUE ); RtlpValidateHeap( Heap, FALSE ); } } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); Result = FALSE; } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return Result; } BOOLEAN RtlDebugGetUserInfoHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN PVOID BaseAddress, OUT PVOID *UserValue OPTIONAL, OUT PULONG UserFlags OPTIONAL ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; PHEAP_ENTRY BusyBlock; BOOLEAN Result = FALSE; BOOLEAN LockAcquired = FALSE; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapGetUserInfo( HeapHandle, Flags, BaseAddress, UserValue, UserFlags )); try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlGetUserInfoHeap" )) { Result = FALSE; leave; } Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } RtlpValidateHeap( Heap, FALSE ); BusyBlock = (PHEAP_ENTRY)BaseAddress - 1; if (RtlpValidateHeapEntry( Heap, BusyBlock, "RtlGetUserInfoHeap" )) { Result = RtlGetUserInfoHeap( HeapHandle, Flags, BaseAddress, UserValue, UserFlags ); } } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return Result; } BOOLEAN RtlDebugSetUserValueHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN PVOID BaseAddress, IN PVOID UserValue ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; PHEAP_ENTRY BusyBlock; BOOLEAN Result = FALSE; BOOLEAN LockAcquired = FALSE; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapSetUserValue( HeapHandle, Flags, BaseAddress, UserValue )); try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlSetUserValueHeap" )) { Result = FALSE; leave; } Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } RtlpValidateHeap( Heap, FALSE ); BusyBlock = (PHEAP_ENTRY)BaseAddress - 1; if (RtlpValidateHeapEntry( Heap, BusyBlock, "RtlSetUserValueHeap" )) { Result = RtlSetUserValueHeap( HeapHandle, Flags, BaseAddress, UserValue ); RtlpValidateHeap( Heap, FALSE ); } } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return Result; } BOOLEAN RtlDebugSetUserFlagsHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN PVOID BaseAddress, IN ULONG UserFlagsReset, IN ULONG UserFlagsSet ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; PHEAP_ENTRY BusyBlock; BOOLEAN Result = FALSE; BOOLEAN LockAcquired = FALSE; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapSetUserFlags( HeapHandle, Flags, BaseAddress, UserFlagsReset, UserFlagsSet )); if ((UserFlagsReset & ~HEAP_SETTABLE_USER_FLAGS) || (UserFlagsSet & ~HEAP_SETTABLE_USER_FLAGS)) { return FALSE; } try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlSetUserFlagsHeap" )) { Result = FALSE; leave; } Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } RtlpValidateHeap( Heap, FALSE ); BusyBlock = (PHEAP_ENTRY)BaseAddress - 1; if (RtlpValidateHeapEntry( Heap, BusyBlock, "RtlSetUserFlagsHeap" )) { Result = RtlSetUserFlagsHeap( HeapHandle, Flags, BaseAddress, UserFlagsReset, UserFlagsSet ); RtlpValidateHeap( Heap, FALSE ); } } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return Result; } SIZE_T RtlDebugSizeHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN PVOID BaseAddress ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; PHEAP_ENTRY BusyBlock; BOOLEAN LockAcquired = FALSE; SIZE_T BusySize; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapSize( HeapHandle, Flags, BaseAddress )); BusySize = 0xFFFFFFFF; try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlSizeHeap" )) { BusySize = FALSE; leave; } Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); Flags |= HEAP_NO_SERIALIZE; LockAcquired = TRUE; } RtlpValidateHeap( Heap, FALSE ); BusyBlock = (PHEAP_ENTRY)BaseAddress - 1; if (RtlpValidateHeapEntry( Heap, BusyBlock, "RtlSizeHeap" )) { BusySize = RtlSizeHeap( HeapHandle, Flags, BaseAddress ); } } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return BusySize; } SIZE_T RtlDebugCompactHeap ( IN PVOID HeapHandle, IN ULONG Flags ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; BOOLEAN LockAcquired = FALSE; SIZE_T LargestFreeSize; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapCompact( HeapHandle, Flags )); LargestFreeSize = 0; try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlCompactHeap" )) { LargestFreeSize = 0; leave; } Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } RtlpValidateHeap( Heap, FALSE ); LargestFreeSize = RtlCompactHeap( HeapHandle, Flags ); RtlpValidateHeapHeaders( Heap, TRUE ); } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return LargestFreeSize; } NTSTATUS RtlDebugZeroHeap ( IN PVOID HeapHandle, IN ULONG Flags ) /*++ Routine Description: Arguments: Return Value: --*/ { NTSTATUS Status; PHEAP Heap = (PHEAP)HeapHandle; BOOLEAN LockAcquired = FALSE; SIZE_T LargestFreeSize; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapZero( HeapHandle, Flags )); Status = STATUS_SUCCESS; LargestFreeSize = 0; try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlZeroHeap" )) { Status = STATUS_INVALID_PARAMETER; leave; } Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } if (!RtlpValidateHeap( Heap, FALSE )) { Status = STATUS_INVALID_PARAMETER; } else { Status = RtlZeroHeap( HeapHandle, Flags ); } } except( EXCEPTION_EXECUTE_HANDLER ) { Status = GetExceptionCode(); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return Status; } NTSTATUS RtlDebugCreateTagHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN PWSTR TagPrefix OPTIONAL, IN PWSTR TagNames ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; BOOLEAN LockAcquired = FALSE; ULONG TagIndex; TagIndex = 0; try { try { // // Validate that HeapAddress points to a HEAP structure. // if (RtlpCheckHeapSignature( Heap, "RtlCreateTagHeap" )) { Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } if (RtlpValidateHeap( Heap, FALSE )) { TagIndex = RtlCreateTagHeap( HeapHandle, Flags, TagPrefix, TagNames ); } RtlpValidateHeapHeaders( Heap, TRUE ); } } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return TagIndex; } NTSYSAPI PWSTR NTAPI RtlDebugQueryTagHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN USHORT TagIndex, IN BOOLEAN ResetCounters, OUT PRTL_HEAP_TAG_INFO TagInfo OPTIONAL ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; BOOLEAN LockAcquired = FALSE; PWSTR Result; Result = NULL; try { try { // // Validate that HeapAddress points to a HEAP structure. // if (RtlpCheckHeapSignature( Heap, "RtlQueryTagHeap" )) { Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } if (RtlpValidateHeap( Heap, FALSE )) { Result = RtlQueryTagHeap( HeapHandle, Flags, TagIndex, ResetCounters, TagInfo ); } } } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return Result; } NTSTATUS RtlDebugUsageHeap ( IN PVOID HeapHandle, IN ULONG Flags, IN OUT PRTL_HEAP_USAGE Usage ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; NTSTATUS Status; BOOLEAN LockAcquired = FALSE; IF_DEBUG_PAGE_HEAP_THEN_RETURN( HeapHandle, RtlpDebugPageHeapUsage( HeapHandle, Flags, Usage )); Status = STATUS_SUCCESS; try { try { // // Validate that HeapAddress points to a HEAP structure. // if (!RtlpCheckHeapSignature( Heap, "RtlUsageHeap" )) { Status = STATUS_INVALID_PARAMETER; leave; } Flags |= Heap->ForceFlags | HEAP_SKIP_VALIDATION_CHECKS; // // Lock the heap // if (!(Flags & HEAP_NO_SERIALIZE)) { RtlAcquireLockRoutine( Heap->LockVariable ); LockAcquired = TRUE; Flags |= HEAP_NO_SERIALIZE; } if (!RtlpValidateHeap( Heap, FALSE )) { Status = STATUS_INVALID_PARAMETER; } else { Status = RtlUsageHeap( HeapHandle, Flags, Usage ); } } except( EXCEPTION_EXECUTE_HANDLER ) { Status = GetExceptionCode(); } } finally { if (LockAcquired) { RtlReleaseLockRoutine( Heap->LockVariable ); } } return Status; } BOOLEAN RtlDebugWalkHeap ( IN PVOID HeapHandle, IN OUT PRTL_HEAP_WALK_ENTRY Entry ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP Heap = (PHEAP)HeapHandle; BOOLEAN Result; // // Assumed the caller has serialized via RtlLockHeap or their own locking mechanism. // Result = FALSE; try { if (RtlpCheckHeapSignature( Heap, "RtlWalkHeap" )) { Result = RtlpValidateHeap( Heap, FALSE ); } } except( EXCEPTION_EXECUTE_HANDLER ) { SET_LAST_STATUS( GetExceptionCode() ); } return Result; } BOOLEAN RtlpValidateHeapEntry ( IN PHEAP Heap, IN PHEAP_ENTRY BusyBlock, IN PCHAR Reason ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP_SEGMENT Segment; UCHAR SegmentIndex; BOOLEAN Result; if ((BusyBlock != NULL) && (BusyBlock->SegmentIndex == HEAP_LFH_INDEX)) { if ((RtlpGetLowFragHeap(Heap) == NULL) || ((ULONG_PTR)BusyBlock & (HEAP_GRANULARITY-1)) || (BusyBlock->Flags & HEAP_ENTRY_VIRTUAL_ALLOC) || !(BusyBlock->Flags & HEAP_ENTRY_BUSY)) { goto InvalidBlock; } return TRUE; } if ((BusyBlock == NULL) || ((ULONG_PTR)BusyBlock & (HEAP_GRANULARITY-1)) || ((BusyBlock->Flags & HEAP_ENTRY_VIRTUAL_ALLOC) && ((ULONG_PTR)BusyBlock & (PAGE_SIZE-1)) != FIELD_OFFSET( HEAP_VIRTUAL_ALLOC_ENTRY, BusyBlock )) || (!(BusyBlock->Flags & HEAP_ENTRY_VIRTUAL_ALLOC) && ((BusyBlock->SegmentIndex >= HEAP_MAXIMUM_SEGMENTS) || !(Segment = Heap->Segments[ BusyBlock->SegmentIndex ]) || (BusyBlock < Segment->FirstEntry) || (BusyBlock >= Segment->LastValidEntry))) || !(BusyBlock->Flags & HEAP_ENTRY_BUSY) || ((BusyBlock->Flags & HEAP_ENTRY_FILL_PATTERN) && !RtlpCheckBusyBlockTail( BusyBlock ))) { InvalidBlock: HeapDebugPrint(( "Invalid Address specified to %s( %p, %p )\n", Reason, Heap, BusyBlock + 1 )); HeapDebugBreak( BusyBlock ); return FALSE; } else { if (BusyBlock->Flags & HEAP_ENTRY_VIRTUAL_ALLOC) { Result = TRUE; } else { for (SegmentIndex=0; SegmentIndexSegments[ SegmentIndex ]; if (Segment) { if ((BusyBlock >= Segment->FirstEntry) && (BusyBlock < Segment->LastValidEntry)) { Result = TRUE; break; } } } } if (!Result) { goto InvalidBlock; } return TRUE; } } BOOLEAN RtlpValidateHeapSegment ( IN PHEAP Heap, IN PHEAP_SEGMENT Segment, IN UCHAR SegmentIndex, IN OUT PULONG CountOfFreeBlocks, IN OUT PSIZE_T TotalFreeSize, OUT PVOID *BadAddress, IN OUT PSIZE_T ComputedTagEntries, IN OUT PSIZE_T ComputedPseudoTagEntries ) /*++ Routine Description: Arguments: Return Value: --*/ { PHEAP_ENTRY CurrentBlock, PreviousBlock; SIZE_T Size; USHORT PreviousSize, TagIndex; PHEAP_UNCOMMMTTED_RANGE UnCommittedRange; PHEAP_ENTRY_EXTRA ExtraStuff; ULONG NumberOfUnCommittedPages; ULONG NumberOfUnCommittedRanges; RTL_PAGED_CODE(); NumberOfUnCommittedPages = 0; NumberOfUnCommittedRanges = 0; UnCommittedRange = Segment->UnCommittedRanges; if (Segment->BaseAddress == Heap) { CurrentBlock = &Heap->Entry; } else { CurrentBlock = &Segment->Entry; } while (CurrentBlock < Segment->LastValidEntry) { *BadAddress = CurrentBlock; if ((UnCommittedRange != NULL) && ((ULONG_PTR)CurrentBlock >= UnCommittedRange->Address)) { HeapDebugPrint(( "Heap entry %p is beyond uncommited range [%x .. %x)\n", CurrentBlock, UnCommittedRange->Address, (PCHAR)UnCommittedRange->Address + UnCommittedRange->Size )); return FALSE; } PreviousSize = 0; while (CurrentBlock < Segment->LastValidEntry) { *BadAddress = CurrentBlock; if (PreviousSize != CurrentBlock->PreviousSize) { HeapDebugPrint(( "Heap entry %p has incorrect PreviousSize field (%04x instead of %04x)\n", CurrentBlock, CurrentBlock->PreviousSize, PreviousSize )); return FALSE; } PreviousSize = CurrentBlock->Size; Size = (ULONG_PTR)CurrentBlock->Size << HEAP_GRANULARITY_SHIFT; if (CurrentBlock->Flags & HEAP_ENTRY_BUSY) { if (ComputedTagEntries != NULL) { if (CurrentBlock->Flags & HEAP_ENTRY_EXTRA_PRESENT) { ExtraStuff = RtlpGetExtraStuffPointer( CurrentBlock ); TagIndex = ExtraStuff->TagIndex; } else { TagIndex = CurrentBlock->SmallTagIndex; } if (TagIndex != 0) { if (TagIndex & HEAP_PSEUDO_TAG_FLAG) { TagIndex &= ~HEAP_PSEUDO_TAG_FLAG; if (TagIndex < HEAP_NUMBER_OF_PSEUDO_TAG) { ComputedPseudoTagEntries[ TagIndex ] += CurrentBlock->Size; } } else if (TagIndex & HEAP_GLOBAL_TAG) { // // Ignore these since they are global across more than // one heap. // } else if (TagIndex < Heap->NextAvailableTagIndex) { ComputedTagEntries[ TagIndex ] += CurrentBlock->Size; } } } if (CurrentBlock->Flags & HEAP_ENTRY_FILL_PATTERN) { if (!RtlpCheckBusyBlockTail( CurrentBlock )) { return FALSE; } } } else { *CountOfFreeBlocks += 1; *TotalFreeSize += CurrentBlock->Size; if ((Heap->Flags & HEAP_FREE_CHECKING_ENABLED) && (CurrentBlock->Flags & HEAP_ENTRY_FILL_PATTERN)) { SIZE_T cb, cbEqual; cb = Size - sizeof( HEAP_FREE_ENTRY ); if ((CurrentBlock->Flags & HEAP_ENTRY_EXTRA_PRESENT) && (cb > sizeof( HEAP_FREE_ENTRY_EXTRA ))) { cb -= sizeof( HEAP_FREE_ENTRY_EXTRA ); } cbEqual = RtlCompareMemoryUlong( (PCHAR)((PHEAP_FREE_ENTRY)CurrentBlock + 1), cb, FREE_HEAP_FILL ); if (cbEqual != cb) { HeapDebugPrint(( "Free Heap block %p modified at %p after it was freed\n", CurrentBlock, (PCHAR)(CurrentBlock + 1) + cbEqual )); return FALSE; } } } if (CurrentBlock->SegmentIndex != SegmentIndex) { HeapDebugPrint(( "Heap block at %p has incorrect segment index (%x)\n", CurrentBlock, SegmentIndex )); return FALSE; } if (CurrentBlock->Flags & HEAP_ENTRY_LAST_ENTRY) { CurrentBlock = (PHEAP_ENTRY)((PCHAR)CurrentBlock + Size); if (UnCommittedRange == NULL) { if (CurrentBlock != Segment->LastValidEntry) { HeapDebugPrint(( "Heap block at %p is not last block in segment (%x)\n", CurrentBlock, Segment->LastValidEntry )); return FALSE; } } else if ((ULONG_PTR)CurrentBlock != UnCommittedRange->Address) { HeapDebugPrint(( "Heap block at %p does not match address of next uncommitted address (%x)\n", CurrentBlock, UnCommittedRange->Address )); return FALSE; } else { NumberOfUnCommittedPages += (ULONG) (UnCommittedRange->Size / PAGE_SIZE); NumberOfUnCommittedRanges += 1; CurrentBlock = (PHEAP_ENTRY) ((PCHAR)UnCommittedRange->Address + UnCommittedRange->Size); UnCommittedRange = UnCommittedRange->Next; } break; } CurrentBlock = (PHEAP_ENTRY)((PCHAR)CurrentBlock + Size); } } *BadAddress = Segment; if (Segment->NumberOfUnCommittedPages != NumberOfUnCommittedPages) { HeapDebugPrint(( "Heap Segment at %p contains invalid NumberOfUnCommittedPages (%x != %x)\n", Segment, Segment->NumberOfUnCommittedPages, NumberOfUnCommittedPages )); return FALSE; } if (Segment->NumberOfUnCommittedRanges != NumberOfUnCommittedRanges) { HeapDebugPrint(( "Heap Segment at %p contains invalid NumberOfUnCommittedRanges (%x != %x)\n", Segment, Segment->NumberOfUnCommittedRanges, NumberOfUnCommittedRanges )); return FALSE; } return TRUE; } BOOLEAN RtlpValidateHeap ( IN PHEAP Heap, IN BOOLEAN AlwaysValidate ) /*++ Routine Description: Arguments: Return Value: --*/ { NTSTATUS Status; PHEAP_SEGMENT Segment; PLIST_ENTRY Head, Next; PHEAP_FREE_ENTRY FreeBlock; BOOLEAN EmptyFreeList; ULONG NumberOfFreeListEntries; ULONG CountOfFreeBlocks; SIZE_T TotalFreeSize; SIZE_T Size; USHORT PreviousSize; UCHAR SegmentIndex; PVOID BadAddress; PSIZE_T ComputedTagEntries = NULL; PSIZE_T ComputedPseudoTagEntries = NULL; PHEAP_VIRTUAL_ALLOC_ENTRY VirtualAllocBlock; USHORT TagIndex; RTL_PAGED_CODE(); BadAddress = Heap; if (!RtlpValidateHeapHeaders( Heap, FALSE )) { goto errorExit; } if (!AlwaysValidate && !(Heap->Flags & HEAP_VALIDATE_ALL_ENABLED)) { goto exit; } NumberOfFreeListEntries = 0; Head = &Heap->FreeLists[ 0 ]; for (Size = 0; Size < HEAP_MAXIMUM_FREELISTS; Size++) { if (Size != 0) { EmptyFreeList = (BOOLEAN)(IsListEmpty( Head )); BadAddress = &Heap->u.FreeListsInUseBytes[ Size / 8 ]; if (Heap->u.FreeListsInUseBytes[ Size / 8 ] & (1 << (Size & 7)) ) { if (EmptyFreeList) { HeapDebugPrint(( "dedicated (%04x) free list empty but marked as non-empty\n", Size )); goto errorExit; } } else { if (!EmptyFreeList) { HeapDebugPrint(( "dedicated (%04x) free list non-empty but marked as empty\n", Size )); goto errorExit; } } } Next = Head->Flink; PreviousSize = 0; while (Head != Next) { FreeBlock = CONTAINING_RECORD( Next, HEAP_FREE_ENTRY, FreeList ); Next = Next->Flink; BadAddress = FreeBlock; if (FreeBlock->Flags & HEAP_ENTRY_BUSY) { HeapDebugPrint(( "dedicated (%04x) free list element %p is marked busy\n", Size, FreeBlock )); goto errorExit; } if ((Size != 0) && (FreeBlock->Size != Size)) { HeapDebugPrint(( "Dedicated (%04x) free list element %p is wrong size (%04x)\n", Size, FreeBlock, FreeBlock->Size )); goto errorExit; } else if ((Size == 0) && (FreeBlock->Size < HEAP_MAXIMUM_FREELISTS)) { HeapDebugPrint(( "Non-Dedicated free list element %p with too small size (%04x)\n", FreeBlock, FreeBlock->Size )); goto errorExit; } else if ((Size == 0) && (FreeBlock->Size < PreviousSize)) { HeapDebugPrint(( "Non-Dedicated free list element %p is out of order\n", FreeBlock )); goto errorExit; } else { PreviousSize = FreeBlock->Size; } NumberOfFreeListEntries++; } Head++; } Size = (HEAP_NUMBER_OF_PSEUDO_TAG + Heap->NextAvailableTagIndex + 1) * sizeof( SIZE_T ); if ((RtlpValidateHeapTagsEnable) && (Heap->PseudoTagEntries != NULL)) { Status = NtAllocateVirtualMemory( NtCurrentProcess(), &ComputedPseudoTagEntries, 0, &Size, MEM_COMMIT, PAGE_READWRITE ); if (NT_SUCCESS( Status )) { ComputedTagEntries = ComputedPseudoTagEntries + HEAP_NUMBER_OF_PSEUDO_TAG; } } Head = &Heap->VirtualAllocdBlocks; Next = Head->Flink; while (Head != Next) { VirtualAllocBlock = CONTAINING_RECORD( Next, HEAP_VIRTUAL_ALLOC_ENTRY, Entry ); if (ComputedTagEntries != NULL) { TagIndex = VirtualAllocBlock->ExtraStuff.TagIndex; if (TagIndex != 0) { if (TagIndex & HEAP_PSEUDO_TAG_FLAG) { TagIndex &= ~HEAP_PSEUDO_TAG_FLAG; if (TagIndex < HEAP_NUMBER_OF_PSEUDO_TAG) { ComputedPseudoTagEntries[ TagIndex ] += VirtualAllocBlock->CommitSize >> HEAP_GRANULARITY_SHIFT; } } else if (TagIndex & HEAP_GLOBAL_TAG) { // // Ignore these since they are global across more than // one heap. // } else if (TagIndex < Heap->NextAvailableTagIndex) { ComputedTagEntries[ TagIndex ] += VirtualAllocBlock->CommitSize >> HEAP_GRANULARITY_SHIFT; } } } if (VirtualAllocBlock->BusyBlock.Flags & HEAP_ENTRY_FILL_PATTERN) { if (!RtlpCheckBusyBlockTail( &VirtualAllocBlock->BusyBlock )) { return FALSE; } } Next = Next->Flink; } CountOfFreeBlocks = 0; TotalFreeSize = 0; for (SegmentIndex=0; SegmentIndexSegments[ SegmentIndex ]; if (Segment) { if (!RtlpValidateHeapSegment( Heap, Segment, SegmentIndex, &CountOfFreeBlocks, &TotalFreeSize, &BadAddress, ComputedTagEntries, ComputedPseudoTagEntries )) { goto errorExit; } } } BadAddress = Heap; if (NumberOfFreeListEntries != CountOfFreeBlocks) { HeapDebugPrint(( "Number of free blocks in arena (%ld) does not match number in the free lists (%ld)\n", CountOfFreeBlocks, NumberOfFreeListEntries )); goto errorExit; } if (Heap->TotalFreeSize != TotalFreeSize) { HeapDebugPrint(( "Total size of free blocks in arena (%ld) does not match number total in heap header (%ld)\n", TotalFreeSize, Heap->TotalFreeSize )); goto errorExit; } if (ComputedPseudoTagEntries != NULL) { PHEAP_PSEUDO_TAG_ENTRY PseudoTagEntries; PHEAP_TAG_ENTRY TagEntries; USHORT TagIndex; PseudoTagEntries = Heap->PseudoTagEntries; if (PseudoTagEntries != NULL) { for (TagIndex=1; TagIndexSize) { HeapDebugPrint(( "Pseudo Tag %04x size incorrect (%x != %x) %x\n", TagIndex, PseudoTagEntries->Size, ComputedPseudoTagEntries[ TagIndex ] &ComputedPseudoTagEntries[ TagIndex ] )); goto errorExit; } } } TagEntries = Heap->TagEntries; if (TagEntries != NULL) { for (TagIndex=1; TagIndexNextAvailableTagIndex; TagIndex++) { TagEntries += 1; if (ComputedTagEntries[ TagIndex ] != TagEntries->Size) { HeapDebugPrint(( "Tag %04x (%ws) size incorrect (%x != %x) %x\n", TagIndex, TagEntries->TagName, TagEntries->Size, ComputedTagEntries[ TagIndex ], &ComputedTagEntries[ TagIndex ] )); goto errorExit; } } } Size = 0; RtlpHeapFreeVirtualMemory( NtCurrentProcess(), &ComputedPseudoTagEntries, &Size, MEM_RELEASE ); } exit: return TRUE; errorExit: HeapDebugBreak( BadAddress ); if (ComputedPseudoTagEntries != NULL) { Size = 0; RtlpHeapFreeVirtualMemory( NtCurrentProcess(), &ComputedPseudoTagEntries, &Size, MEM_RELEASE ); } return FALSE; } BOOLEAN RtlpHeapInvalidBreakPoint; PVOID RtlpHeapInvalidBadAddress; VOID RtlpBreakPointHeap ( IN PVOID BadAddress ) /*++ Routine Description: Arguments: Return Value: --*/ { if (NtCurrentPeb()->BeingDebugged) { *(BOOLEAN volatile *)&RtlpHeapInvalidBreakPoint = TRUE; RtlpHeapInvalidBadAddress = BadAddress; DbgBreakPoint(); *(BOOLEAN volatile *)&RtlpHeapInvalidBreakPoint = FALSE; } }