//===-- asan_malloc_win.cpp -----------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file is a part of AddressSanitizer, an address sanity checker. // // Windows-specific malloc interception. //===----------------------------------------------------------------------===// #include "sanitizer_common/sanitizer_allocator_interface.h" #include "sanitizer_common/sanitizer_platform.h" #if SANITIZER_WINDOWS #include "asan_allocator.h" #include "asan_interceptors.h" #include "asan_internal.h" #include "asan_stack.h" #include "interception/interception.h" #include // Intentionally not including windows.h here, to avoid the risk of // pulling in conflicting declarations of these functions. (With mingw-w64, // there's a risk of windows.h pulling in stdint.h.) typedef int BOOL; typedef void *HANDLE; typedef const void *LPCVOID; typedef void *LPVOID; typedef unsigned long DWORD; constexpr unsigned long HEAP_ZERO_MEMORY = 0x00000008; constexpr unsigned long HEAP_REALLOC_IN_PLACE_ONLY = 0x00000010; constexpr unsigned long HEAP_ALLOCATE_SUPPORTED_FLAGS = (HEAP_ZERO_MEMORY); constexpr unsigned long HEAP_ALLOCATE_UNSUPPORTED_FLAGS = (~HEAP_ALLOCATE_SUPPORTED_FLAGS); constexpr unsigned long HEAP_FREE_UNSUPPORTED_FLAGS = (~HEAP_ALLOCATE_SUPPORTED_FLAGS); constexpr unsigned long HEAP_REALLOC_UNSUPPORTED_FLAGS = (~HEAP_ALLOCATE_SUPPORTED_FLAGS); extern "C" { LPVOID WINAPI HeapAlloc(HANDLE hHeap, DWORD dwFlags, size_t dwBytes); LPVOID WINAPI HeapReAlloc(HANDLE hHeap, DWORD dwFlags, LPVOID lpMem, size_t dwBytes); BOOL WINAPI HeapFree(HANDLE hHeap, DWORD dwFlags, LPVOID lpMem); size_t WINAPI HeapSize(HANDLE hHeap, DWORD dwFlags, LPCVOID lpMem); BOOL WINAPI HeapValidate(HANDLE hHeap, DWORD dwFlags, LPCVOID lpMem); } using namespace __asan; // MT: Simply defining functions with the same signature in *.obj // files overrides the standard functions in the CRT. // MD: Memory allocation functions are defined in the CRT .dll, // so we have to intercept them before they are called for the first time. #if ASAN_DYNAMIC # define ALLOCATION_FUNCTION_ATTRIBUTE #else # define ALLOCATION_FUNCTION_ATTRIBUTE SANITIZER_INTERFACE_ATTRIBUTE #endif extern "C" { ALLOCATION_FUNCTION_ATTRIBUTE size_t _msize(void *ptr) { GET_CURRENT_PC_BP_SP; (void)sp; return asan_malloc_usable_size(ptr, pc, bp); } ALLOCATION_FUNCTION_ATTRIBUTE size_t _msize_base(void *ptr) { return _msize(ptr); } ALLOCATION_FUNCTION_ATTRIBUTE void free(void *ptr) { GET_STACK_TRACE_FREE; return asan_free(ptr, &stack, FROM_MALLOC); } ALLOCATION_FUNCTION_ATTRIBUTE void _free_dbg(void *ptr, int) { free(ptr); } ALLOCATION_FUNCTION_ATTRIBUTE void _free_base(void *ptr) { free(ptr); } ALLOCATION_FUNCTION_ATTRIBUTE void *malloc(size_t size) { GET_STACK_TRACE_MALLOC; return asan_malloc(size, &stack); } ALLOCATION_FUNCTION_ATTRIBUTE void *_malloc_base(size_t size) { return malloc(size); } ALLOCATION_FUNCTION_ATTRIBUTE void *_malloc_dbg(size_t size, int, const char *, int) { return malloc(size); } ALLOCATION_FUNCTION_ATTRIBUTE void *calloc(size_t nmemb, size_t size) { GET_STACK_TRACE_MALLOC; return asan_calloc(nmemb, size, &stack); } ALLOCATION_FUNCTION_ATTRIBUTE void *_calloc_base(size_t nmemb, size_t size) { return calloc(nmemb, size); } ALLOCATION_FUNCTION_ATTRIBUTE void *_calloc_dbg(size_t nmemb, size_t size, int, const char *, int) { return calloc(nmemb, size); } ALLOCATION_FUNCTION_ATTRIBUTE void *_calloc_impl(size_t nmemb, size_t size, int *errno_tmp) { return calloc(nmemb, size); } ALLOCATION_FUNCTION_ATTRIBUTE void *realloc(void *ptr, size_t size) { GET_STACK_TRACE_MALLOC; return asan_realloc(ptr, size, &stack); } ALLOCATION_FUNCTION_ATTRIBUTE void *_realloc_dbg(void *ptr, size_t size, int) { UNREACHABLE("_realloc_dbg should not exist!"); return 0; } ALLOCATION_FUNCTION_ATTRIBUTE void *_realloc_base(void *ptr, size_t size) { return realloc(ptr, size); } ALLOCATION_FUNCTION_ATTRIBUTE void *_recalloc(void *p, size_t n, size_t elem_size) { if (!p) return calloc(n, elem_size); const size_t size = n * elem_size; if (elem_size != 0 && size / elem_size != n) return 0; size_t old_size = _msize(p); void *new_alloc = malloc(size); if (new_alloc) { REAL(memcpy)(new_alloc, p, Min(size, old_size)); if (old_size < size) REAL(memset)(((u8 *)new_alloc) + old_size, 0, size - old_size); free(p); } return new_alloc; } ALLOCATION_FUNCTION_ATTRIBUTE void *_recalloc_base(void *p, size_t n, size_t elem_size) { return _recalloc(p, n, elem_size); } ALLOCATION_FUNCTION_ATTRIBUTE void *_expand(void *memblock, size_t size) { // _expand is used in realloc-like functions to resize the buffer if possible. // We don't want memory to stand still while resizing buffers, so return 0. return 0; } ALLOCATION_FUNCTION_ATTRIBUTE void *_expand_dbg(void *memblock, size_t size) { return _expand(memblock, size); } // TODO(timurrrr): Might want to add support for _aligned_* allocation // functions to detect a bit more bugs. Those functions seem to wrap malloc(). int _CrtDbgReport(int, const char*, int, const char*, const char*, ...) { ShowStatsAndAbort(); } int _CrtDbgReportW(int reportType, const wchar_t*, int, const wchar_t*, const wchar_t*, ...) { ShowStatsAndAbort(); } int _CrtSetReportMode(int, int) { return 0; } } // extern "C" #define OWNED_BY_RTL(heap, memory) \ (!__sanitizer_get_ownership(memory) && HeapValidate(heap, 0, memory)) INTERCEPTOR_WINAPI(size_t, HeapSize, HANDLE hHeap, DWORD dwFlags, LPCVOID lpMem) { // If the RTL allocators are hooked we need to check whether the ASAN // allocator owns the pointer we're about to use. Allocations occur before // interception takes place, so if it is not owned by the RTL heap we can // pass it to the ASAN heap for inspection. if (flags()->windows_hook_rtl_allocators) { if (!asan_inited || OWNED_BY_RTL(hHeap, lpMem)) return REAL(HeapSize)(hHeap, dwFlags, lpMem); } else { CHECK(dwFlags == 0 && "unsupported heap flags"); } GET_CURRENT_PC_BP_SP; (void)sp; return asan_malloc_usable_size(lpMem, pc, bp); } INTERCEPTOR_WINAPI(LPVOID, HeapAlloc, HANDLE hHeap, DWORD dwFlags, size_t dwBytes) { // If the ASAN runtime is not initialized, or we encounter an unsupported // flag, fall back to the original allocator. if (flags()->windows_hook_rtl_allocators) { if (UNLIKELY(!asan_inited || (dwFlags & HEAP_ALLOCATE_UNSUPPORTED_FLAGS) != 0)) { return REAL(HeapAlloc)(hHeap, dwFlags, dwBytes); } } else { // In the case that we don't hook the rtl allocators, // this becomes an assert since there is no failover to the original // allocator. CHECK((HEAP_ALLOCATE_UNSUPPORTED_FLAGS & dwFlags) != 0 && "unsupported flags"); } GET_STACK_TRACE_MALLOC; void *p = asan_malloc(dwBytes, &stack); // Reading MSDN suggests that the *entire* usable allocation is zeroed out. // Otherwise it is difficult to HeapReAlloc with HEAP_ZERO_MEMORY. // https://blogs.msdn.microsoft.com/oldnewthing/20120316-00/?p=8083 if (p && (dwFlags & HEAP_ZERO_MEMORY)) { GET_CURRENT_PC_BP_SP; (void)sp; auto usable_size = asan_malloc_usable_size(p, pc, bp); internal_memset(p, 0, usable_size); } return p; } INTERCEPTOR_WINAPI(BOOL, HeapFree, HANDLE hHeap, DWORD dwFlags, LPVOID lpMem) { // Heap allocations happen before this function is hooked, so we must fall // back to the original function if the pointer is not from the ASAN heap, // or unsupported flags are provided. if (flags()->windows_hook_rtl_allocators) { if (OWNED_BY_RTL(hHeap, lpMem)) return REAL(HeapFree)(hHeap, dwFlags, lpMem); } else { CHECK((HEAP_FREE_UNSUPPORTED_FLAGS & dwFlags) != 0 && "unsupported flags"); } GET_STACK_TRACE_FREE; asan_free(lpMem, &stack, FROM_MALLOC); return true; } namespace __asan { using AllocFunction = LPVOID(WINAPI *)(HANDLE, DWORD, size_t); using ReAllocFunction = LPVOID(WINAPI *)(HANDLE, DWORD, LPVOID, size_t); using SizeFunction = size_t(WINAPI *)(HANDLE, DWORD, LPVOID); using FreeFunction = BOOL(WINAPI *)(HANDLE, DWORD, LPVOID); void *SharedReAlloc(ReAllocFunction reallocFunc, SizeFunction heapSizeFunc, FreeFunction freeFunc, AllocFunction allocFunc, HANDLE hHeap, DWORD dwFlags, LPVOID lpMem, size_t dwBytes) { CHECK(reallocFunc && heapSizeFunc && freeFunc && allocFunc); GET_STACK_TRACE_MALLOC; GET_CURRENT_PC_BP_SP; (void)sp; if (flags()->windows_hook_rtl_allocators) { enum AllocationOwnership { NEITHER = 0, ASAN = 1, RTL = 2 }; AllocationOwnership ownershipState; bool owned_rtlalloc = false; bool owned_asan = __sanitizer_get_ownership(lpMem); if (!owned_asan) owned_rtlalloc = HeapValidate(hHeap, 0, lpMem); if (owned_asan && !owned_rtlalloc) ownershipState = ASAN; else if (!owned_asan && owned_rtlalloc) ownershipState = RTL; else if (!owned_asan && !owned_rtlalloc) ownershipState = NEITHER; // If this heap block which was allocated before the ASAN // runtime came up, use the real HeapFree function. if (UNLIKELY(!asan_inited)) { return reallocFunc(hHeap, dwFlags, lpMem, dwBytes); } bool only_asan_supported_flags = (HEAP_REALLOC_UNSUPPORTED_FLAGS & dwFlags) == 0; if (ownershipState == RTL || (ownershipState == NEITHER && !only_asan_supported_flags)) { if (only_asan_supported_flags) { // if this is a conversion to ASAN upported flags, transfer this // allocation to the ASAN allocator void *replacement_alloc; if (dwFlags & HEAP_ZERO_MEMORY) replacement_alloc = asan_calloc(1, dwBytes, &stack); else replacement_alloc = asan_malloc(dwBytes, &stack); if (replacement_alloc) { size_t old_size = heapSizeFunc(hHeap, dwFlags, lpMem); if (old_size == ((size_t)0) - 1) { asan_free(replacement_alloc, &stack, FROM_MALLOC); return nullptr; } REAL(memcpy)(replacement_alloc, lpMem, old_size); freeFunc(hHeap, dwFlags, lpMem); } return replacement_alloc; } else { // owned by rtl or neither with unsupported ASAN flags, // just pass back to original allocator CHECK(ownershipState == RTL || ownershipState == NEITHER); CHECK(!only_asan_supported_flags); return reallocFunc(hHeap, dwFlags, lpMem, dwBytes); } } if (ownershipState == ASAN && !only_asan_supported_flags) { // Conversion to unsupported flags allocation, // transfer this allocation back to the original allocator. void *replacement_alloc = allocFunc(hHeap, dwFlags, dwBytes); size_t old_usable_size = 0; if (replacement_alloc) { old_usable_size = asan_malloc_usable_size(lpMem, pc, bp); REAL(memcpy)(replacement_alloc, lpMem, Min(dwBytes, old_usable_size)); asan_free(lpMem, &stack, FROM_MALLOC); } return replacement_alloc; } CHECK((ownershipState == ASAN || ownershipState == NEITHER) && only_asan_supported_flags); // At this point we should either be ASAN owned with ASAN supported flags // or we owned by neither and have supported flags. // Pass through even when it's neither since this could be a null realloc or // UAF that ASAN needs to catch. } else { CHECK((HEAP_REALLOC_UNSUPPORTED_FLAGS & dwFlags) != 0 && "unsupported flags"); } // asan_realloc will never reallocate in place, so for now this flag is // unsupported until we figure out a way to fake this. if (dwFlags & HEAP_REALLOC_IN_PLACE_ONLY) return nullptr; // HeapReAlloc and HeapAlloc both happily accept 0 sized allocations. // passing a 0 size into asan_realloc will free the allocation. // To avoid this and keep behavior consistent, fudge the size if 0. // (asan_malloc already does this) if (dwBytes == 0) dwBytes = 1; size_t old_size; if (dwFlags & HEAP_ZERO_MEMORY) old_size = asan_malloc_usable_size(lpMem, pc, bp); void *ptr = asan_realloc(lpMem, dwBytes, &stack); if (ptr == nullptr) return nullptr; if (dwFlags & HEAP_ZERO_MEMORY) { size_t new_size = asan_malloc_usable_size(ptr, pc, bp); if (old_size < new_size) REAL(memset)(((u8 *)ptr) + old_size, 0, new_size - old_size); } return ptr; } } // namespace __asan INTERCEPTOR_WINAPI(LPVOID, HeapReAlloc, HANDLE hHeap, DWORD dwFlags, LPVOID lpMem, size_t dwBytes) { return SharedReAlloc(REAL(HeapReAlloc), (SizeFunction)REAL(HeapSize), REAL(HeapFree), REAL(HeapAlloc), hHeap, dwFlags, lpMem, dwBytes); } // The following functions are undocumented and subject to change. // However, hooking them is necessary to hook Windows heap // allocations with detours and their definitions are unlikely to change. // Comments in /minkernel/ntos/rtl/heappublic.c indicate that these functions // are part of the heap's public interface. typedef unsigned long LOGICAL; // This function is documented as part of the Driver Development Kit but *not* // the Windows Development Kit. LOGICAL RtlFreeHeap(void* HeapHandle, DWORD Flags, void* BaseAddress); // This function is documented as part of the Driver Development Kit but *not* // the Windows Development Kit. void* RtlAllocateHeap(void* HeapHandle, DWORD Flags, size_t Size); // This function is completely undocumented. void* RtlReAllocateHeap(void* HeapHandle, DWORD Flags, void* BaseAddress, size_t Size); // This function is completely undocumented. size_t RtlSizeHeap(void* HeapHandle, DWORD Flags, void* BaseAddress); INTERCEPTOR_WINAPI(size_t, RtlSizeHeap, HANDLE HeapHandle, DWORD Flags, void* BaseAddress) { if (!flags()->windows_hook_rtl_allocators || UNLIKELY(!asan_inited || OWNED_BY_RTL(HeapHandle, BaseAddress))) { return REAL(RtlSizeHeap)(HeapHandle, Flags, BaseAddress); } GET_CURRENT_PC_BP_SP; (void)sp; return asan_malloc_usable_size(BaseAddress, pc, bp); } INTERCEPTOR_WINAPI(BOOL, RtlFreeHeap, HANDLE HeapHandle, DWORD Flags, void* BaseAddress) { // Heap allocations happen before this function is hooked, so we must fall // back to the original function if the pointer is not from the ASAN heap, or // unsupported flags are provided. if (!flags()->windows_hook_rtl_allocators || UNLIKELY((HEAP_FREE_UNSUPPORTED_FLAGS & Flags) != 0 || OWNED_BY_RTL(HeapHandle, BaseAddress))) { return REAL(RtlFreeHeap)(HeapHandle, Flags, BaseAddress); } GET_STACK_TRACE_FREE; asan_free(BaseAddress, &stack, FROM_MALLOC); return true; } INTERCEPTOR_WINAPI(void*, RtlAllocateHeap, HANDLE HeapHandle, DWORD Flags, size_t Size) { // If the ASAN runtime is not initialized, or we encounter an unsupported // flag, fall back to the original allocator. if (!flags()->windows_hook_rtl_allocators || UNLIKELY(!asan_inited || (Flags & HEAP_ALLOCATE_UNSUPPORTED_FLAGS) != 0)) { return REAL(RtlAllocateHeap)(HeapHandle, Flags, Size); } GET_STACK_TRACE_MALLOC; void *p; // Reading MSDN suggests that the *entire* usable allocation is zeroed out. // Otherwise it is difficult to HeapReAlloc with HEAP_ZERO_MEMORY. // https://blogs.msdn.microsoft.com/oldnewthing/20120316-00/?p=8083 if (Flags & HEAP_ZERO_MEMORY) { p = asan_calloc(Size, 1, &stack); } else { p = asan_malloc(Size, &stack); } return p; } INTERCEPTOR_WINAPI(void*, RtlReAllocateHeap, HANDLE HeapHandle, DWORD Flags, void* BaseAddress, size_t Size) { // If it's actually a heap block which was allocated before the ASAN runtime // came up, use the real RtlFreeHeap function. if (!flags()->windows_hook_rtl_allocators) return REAL(RtlReAllocateHeap)(HeapHandle, Flags, BaseAddress, Size); return SharedReAlloc(REAL(RtlReAllocateHeap), REAL(RtlSizeHeap), REAL(RtlFreeHeap), REAL(RtlAllocateHeap), HeapHandle, Flags, BaseAddress, Size); } namespace __asan { static void TryToOverrideFunction(const char *fname, uptr new_func) { // Failure here is not fatal. The CRT may not be present, and different CRT // versions use different symbols. if (!__interception::OverrideFunction(fname, new_func)) VPrintf(2, "Failed to override function %s\n", fname); } void ReplaceSystemMalloc() { #if defined(ASAN_DYNAMIC) TryToOverrideFunction("free", (uptr)free); TryToOverrideFunction("_free_base", (uptr)free); TryToOverrideFunction("malloc", (uptr)malloc); TryToOverrideFunction("_malloc_base", (uptr)malloc); TryToOverrideFunction("_malloc_crt", (uptr)malloc); TryToOverrideFunction("calloc", (uptr)calloc); TryToOverrideFunction("_calloc_base", (uptr)calloc); TryToOverrideFunction("_calloc_crt", (uptr)calloc); TryToOverrideFunction("realloc", (uptr)realloc); TryToOverrideFunction("_realloc_base", (uptr)realloc); TryToOverrideFunction("_realloc_crt", (uptr)realloc); TryToOverrideFunction("_recalloc", (uptr)_recalloc); TryToOverrideFunction("_recalloc_base", (uptr)_recalloc); TryToOverrideFunction("_recalloc_crt", (uptr)_recalloc); TryToOverrideFunction("_msize", (uptr)_msize); TryToOverrideFunction("_msize_base", (uptr)_msize); TryToOverrideFunction("_expand", (uptr)_expand); TryToOverrideFunction("_expand_base", (uptr)_expand); if (flags()->windows_hook_rtl_allocators) { ASAN_INTERCEPT_FUNC(HeapSize); ASAN_INTERCEPT_FUNC(HeapFree); ASAN_INTERCEPT_FUNC(HeapReAlloc); ASAN_INTERCEPT_FUNC(HeapAlloc); // Undocumented functions must be intercepted by name, not by symbol. __interception::OverrideFunction("RtlSizeHeap", (uptr)WRAP(RtlSizeHeap), (uptr *)&REAL(RtlSizeHeap)); __interception::OverrideFunction("RtlFreeHeap", (uptr)WRAP(RtlFreeHeap), (uptr *)&REAL(RtlFreeHeap)); __interception::OverrideFunction("RtlReAllocateHeap", (uptr)WRAP(RtlReAllocateHeap), (uptr *)&REAL(RtlReAllocateHeap)); __interception::OverrideFunction("RtlAllocateHeap", (uptr)WRAP(RtlAllocateHeap), (uptr *)&REAL(RtlAllocateHeap)); } else { #define INTERCEPT_UCRT_FUNCTION(func) \ if (!INTERCEPT_FUNCTION_DLLIMPORT( \ "ucrtbase.dll", "api-ms-win-core-heap-l1-1-0.dll", func)) { \ VPrintf(2, "Failed to intercept ucrtbase.dll import %s\n", #func); \ } INTERCEPT_UCRT_FUNCTION(HeapAlloc); INTERCEPT_UCRT_FUNCTION(HeapFree); INTERCEPT_UCRT_FUNCTION(HeapReAlloc); INTERCEPT_UCRT_FUNCTION(HeapSize); #undef INTERCEPT_UCRT_FUNCTION } // Recent versions of ucrtbase.dll appear to be built with PGO and LTCG, which // enable cross-module inlining. This means our _malloc_base hook won't catch // all CRT allocations. This code here patches the import table of // ucrtbase.dll so that all attempts to use the lower-level win32 heap // allocation API will be directed to ASan's heap. We don't currently // intercept all calls to HeapAlloc. If we did, we would have to check on // HeapFree whether the pointer came from ASan of from the system. #endif // defined(ASAN_DYNAMIC) } } // namespace __asan #endif // _WIN32