Mercurial > hg > CbC > CbC_gcc
view libsanitizer/sanitizer_common/sanitizer_win.cc @ 144:8f4e72ab4e11
fix segmentation fault caused by nothing next cur_op to end
| author | Takahiro SHIMIZU <anatofuz@cr.ie.u-ryukyu.ac.jp> |
|---|---|
| date | Sun, 23 Dec 2018 21:23:56 +0900 |
| parents | 04ced10e8804 |
| children |
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//===-- sanitizer_win.cc --------------------------------------------------===// // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file is shared between AddressSanitizer and ThreadSanitizer // run-time libraries and implements windows-specific functions from // sanitizer_libc.h. //===----------------------------------------------------------------------===// #include "sanitizer_platform.h" #if SANITIZER_WINDOWS #define WIN32_LEAN_AND_MEAN #define NOGDI #include <windows.h> #include <io.h> #include <psapi.h> #include <stdlib.h> #include "sanitizer_common.h" #include "sanitizer_dbghelp.h" #include "sanitizer_file.h" #include "sanitizer_libc.h" #include "sanitizer_mutex.h" #include "sanitizer_placement_new.h" #include "sanitizer_stacktrace.h" #include "sanitizer_symbolizer.h" #include "sanitizer_win_defs.h" // A macro to tell the compiler that this part of the code cannot be reached, // if the compiler supports this feature. Since we're using this in // code that is called when terminating the process, the expansion of the // macro should not terminate the process to avoid infinite recursion. #if defined(__clang__) # define BUILTIN_UNREACHABLE() __builtin_unreachable() #elif defined(__GNUC__) && \ (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 5)) # define BUILTIN_UNREACHABLE() __builtin_unreachable() #elif defined(_MSC_VER) # define BUILTIN_UNREACHABLE() __assume(0) #else # define BUILTIN_UNREACHABLE() #endif namespace __sanitizer { #include "sanitizer_syscall_generic.inc" // --------------------- sanitizer_common.h uptr GetPageSize() { SYSTEM_INFO si; GetSystemInfo(&si); return si.dwPageSize; } uptr GetMmapGranularity() { SYSTEM_INFO si; GetSystemInfo(&si); return si.dwAllocationGranularity; } uptr GetMaxVirtualAddress() { SYSTEM_INFO si; GetSystemInfo(&si); return (uptr)si.lpMaximumApplicationAddress; } bool FileExists(const char *filename) { return ::GetFileAttributesA(filename) != INVALID_FILE_ATTRIBUTES; } uptr internal_getpid() { return GetProcessId(GetCurrentProcess()); } // In contrast to POSIX, on Windows GetCurrentThreadId() // returns a system-unique identifier. tid_t GetTid() { return GetCurrentThreadId(); } uptr GetThreadSelf() { return GetTid(); } #if !SANITIZER_GO void GetThreadStackTopAndBottom(bool at_initialization, uptr *stack_top, uptr *stack_bottom) { CHECK(stack_top); CHECK(stack_bottom); MEMORY_BASIC_INFORMATION mbi; CHECK_NE(VirtualQuery(&mbi /* on stack */, &mbi, sizeof(mbi)), 0); // FIXME: is it possible for the stack to not be a single allocation? // Are these values what ASan expects to get (reserved, not committed; // including stack guard page) ? *stack_top = (uptr)mbi.BaseAddress + mbi.RegionSize; *stack_bottom = (uptr)mbi.AllocationBase; } #endif // #if !SANITIZER_GO void *MmapOrDie(uptr size, const char *mem_type, bool raw_report) { void *rv = VirtualAlloc(0, size, MEM_RESERVE | MEM_COMMIT, PAGE_READWRITE); if (rv == 0) ReportMmapFailureAndDie(size, mem_type, "allocate", GetLastError(), raw_report); return rv; } void UnmapOrDie(void *addr, uptr size) { if (!size || !addr) return; MEMORY_BASIC_INFORMATION mbi; CHECK(VirtualQuery(addr, &mbi, sizeof(mbi))); // MEM_RELEASE can only be used to unmap whole regions previously mapped with // VirtualAlloc. So we first try MEM_RELEASE since it is better, and if that // fails try MEM_DECOMMIT. if (VirtualFree(addr, 0, MEM_RELEASE) == 0) { if (VirtualFree(addr, size, MEM_DECOMMIT) == 0) { Report("ERROR: %s failed to " "deallocate 0x%zx (%zd) bytes at address %p (error code: %d)\n", SanitizerToolName, size, size, addr, GetLastError()); CHECK("unable to unmap" && 0); } } } static void *ReturnNullptrOnOOMOrDie(uptr size, const char *mem_type, const char *mmap_type) { error_t last_error = GetLastError(); if (last_error == ERROR_NOT_ENOUGH_MEMORY) return nullptr; ReportMmapFailureAndDie(size, mem_type, mmap_type, last_error); } void *MmapOrDieOnFatalError(uptr size, const char *mem_type) { void *rv = VirtualAlloc(0, size, MEM_RESERVE | MEM_COMMIT, PAGE_READWRITE); if (rv == 0) return ReturnNullptrOnOOMOrDie(size, mem_type, "allocate"); return rv; } // We want to map a chunk of address space aligned to 'alignment'. void *MmapAlignedOrDieOnFatalError(uptr size, uptr alignment, const char *mem_type) { CHECK(IsPowerOfTwo(size)); CHECK(IsPowerOfTwo(alignment)); // Windows will align our allocations to at least 64K. alignment = Max(alignment, GetMmapGranularity()); uptr mapped_addr = (uptr)VirtualAlloc(0, size, MEM_RESERVE | MEM_COMMIT, PAGE_READWRITE); if (!mapped_addr) return ReturnNullptrOnOOMOrDie(size, mem_type, "allocate aligned"); // If we got it right on the first try, return. Otherwise, unmap it and go to // the slow path. if (IsAligned(mapped_addr, alignment)) return (void*)mapped_addr; if (VirtualFree((void *)mapped_addr, 0, MEM_RELEASE) == 0) ReportMmapFailureAndDie(size, mem_type, "deallocate", GetLastError()); // If we didn't get an aligned address, overallocate, find an aligned address, // unmap, and try to allocate at that aligned address. int retries = 0; const int kMaxRetries = 10; for (; retries < kMaxRetries && (mapped_addr == 0 || !IsAligned(mapped_addr, alignment)); retries++) { // Overallocate size + alignment bytes. mapped_addr = (uptr)VirtualAlloc(0, size + alignment, MEM_RESERVE, PAGE_NOACCESS); if (!mapped_addr) return ReturnNullptrOnOOMOrDie(size, mem_type, "allocate aligned"); // Find the aligned address. uptr aligned_addr = RoundUpTo(mapped_addr, alignment); // Free the overallocation. if (VirtualFree((void *)mapped_addr, 0, MEM_RELEASE) == 0) ReportMmapFailureAndDie(size, mem_type, "deallocate", GetLastError()); // Attempt to allocate exactly the number of bytes we need at the aligned // address. This may fail for a number of reasons, in which case we continue // the loop. mapped_addr = (uptr)VirtualAlloc((void *)aligned_addr, size, MEM_RESERVE | MEM_COMMIT, PAGE_READWRITE); } // Fail if we can't make this work quickly. if (retries == kMaxRetries && mapped_addr == 0) return ReturnNullptrOnOOMOrDie(size, mem_type, "allocate aligned"); return (void *)mapped_addr; } void *MmapFixedNoReserve(uptr fixed_addr, uptr size, const char *name) { // FIXME: is this really "NoReserve"? On Win32 this does not matter much, // but on Win64 it does. (void)name; // unsupported #if !SANITIZER_GO && SANITIZER_WINDOWS64 // On asan/Windows64, use MEM_COMMIT would result in error // 1455:ERROR_COMMITMENT_LIMIT. // Asan uses exception handler to commit page on demand. void *p = VirtualAlloc((LPVOID)fixed_addr, size, MEM_RESERVE, PAGE_READWRITE); #else void *p = VirtualAlloc((LPVOID)fixed_addr, size, MEM_RESERVE | MEM_COMMIT, PAGE_READWRITE); #endif if (p == 0) Report("ERROR: %s failed to " "allocate %p (%zd) bytes at %p (error code: %d)\n", SanitizerToolName, size, size, fixed_addr, GetLastError()); return p; } // Memory space mapped by 'MmapFixedOrDie' must have been reserved by // 'MmapFixedNoAccess'. void *MmapFixedOrDie(uptr fixed_addr, uptr size) { void *p = VirtualAlloc((LPVOID)fixed_addr, size, MEM_COMMIT, PAGE_READWRITE); if (p == 0) { char mem_type[30]; internal_snprintf(mem_type, sizeof(mem_type), "memory at address 0x%zx", fixed_addr); ReportMmapFailureAndDie(size, mem_type, "allocate", GetLastError()); } return p; } void *MmapFixedOrDieOnFatalError(uptr fixed_addr, uptr size) { void *p = VirtualAlloc((LPVOID)fixed_addr, size, MEM_COMMIT, PAGE_READWRITE); if (p == 0) { char mem_type[30]; internal_snprintf(mem_type, sizeof(mem_type), "memory at address 0x%zx", fixed_addr); return ReturnNullptrOnOOMOrDie(size, mem_type, "allocate"); } return p; } void *MmapNoReserveOrDie(uptr size, const char *mem_type) { // FIXME: make this really NoReserve? return MmapOrDie(size, mem_type); } void *MmapFixedNoAccess(uptr fixed_addr, uptr size, const char *name) { (void)name; // unsupported void *res = VirtualAlloc((LPVOID)fixed_addr, size, MEM_RESERVE, PAGE_NOACCESS); if (res == 0) Report("WARNING: %s failed to " "mprotect %p (%zd) bytes at %p (error code: %d)\n", SanitizerToolName, size, size, fixed_addr, GetLastError()); return res; } void *MmapNoAccess(uptr size) { void *res = VirtualAlloc(nullptr, size, MEM_RESERVE, PAGE_NOACCESS); if (res == 0) Report("WARNING: %s failed to " "mprotect %p (%zd) bytes (error code: %d)\n", SanitizerToolName, size, size, GetLastError()); return res; } bool MprotectNoAccess(uptr addr, uptr size) { DWORD old_protection; return VirtualProtect((LPVOID)addr, size, PAGE_NOACCESS, &old_protection); } void ReleaseMemoryPagesToOS(uptr beg, uptr end) { // This is almost useless on 32-bits. // FIXME: add madvise-analog when we move to 64-bits. } void NoHugePagesInRegion(uptr addr, uptr size) { // FIXME: probably similar to ReleaseMemoryToOS. } void DontDumpShadowMemory(uptr addr, uptr length) { // This is almost useless on 32-bits. // FIXME: add madvise-analog when we move to 64-bits. } uptr FindAvailableMemoryRange(uptr size, uptr alignment, uptr left_padding, uptr *largest_gap_found) { uptr address = 0; while (true) { MEMORY_BASIC_INFORMATION info; if (!::VirtualQuery((void*)address, &info, sizeof(info))) return 0; if (info.State == MEM_FREE) { uptr shadow_address = RoundUpTo((uptr)info.BaseAddress + left_padding, alignment); if (shadow_address + size < (uptr)info.BaseAddress + info.RegionSize) return shadow_address; } // Move to the next region. address = (uptr)info.BaseAddress + info.RegionSize; } return 0; } bool MemoryRangeIsAvailable(uptr range_start, uptr range_end) { MEMORY_BASIC_INFORMATION mbi; CHECK(VirtualQuery((void *)range_start, &mbi, sizeof(mbi))); return mbi.Protect == PAGE_NOACCESS && (uptr)mbi.BaseAddress + mbi.RegionSize >= range_end; } void *MapFileToMemory(const char *file_name, uptr *buff_size) { UNIMPLEMENTED(); } void *MapWritableFileToMemory(void *addr, uptr size, fd_t fd, OFF_T offset) { UNIMPLEMENTED(); } static const int kMaxEnvNameLength = 128; static const DWORD kMaxEnvValueLength = 32767; namespace { struct EnvVariable { char name[kMaxEnvNameLength]; char value[kMaxEnvValueLength]; }; } // namespace static const int kEnvVariables = 5; static EnvVariable env_vars[kEnvVariables]; static int num_env_vars; const char *GetEnv(const char *name) { // Note: this implementation caches the values of the environment variables // and limits their quantity. for (int i = 0; i < num_env_vars; i++) { if (0 == internal_strcmp(name, env_vars[i].name)) return env_vars[i].value; } CHECK_LT(num_env_vars, kEnvVariables); DWORD rv = GetEnvironmentVariableA(name, env_vars[num_env_vars].value, kMaxEnvValueLength); if (rv > 0 && rv < kMaxEnvValueLength) { CHECK_LT(internal_strlen(name), kMaxEnvNameLength); internal_strncpy(env_vars[num_env_vars].name, name, kMaxEnvNameLength); num_env_vars++; return env_vars[num_env_vars - 1].value; } return 0; } const char *GetPwd() { UNIMPLEMENTED(); } u32 GetUid() { UNIMPLEMENTED(); } namespace { struct ModuleInfo { const char *filepath; uptr base_address; uptr end_address; }; #if !SANITIZER_GO int CompareModulesBase(const void *pl, const void *pr) { const ModuleInfo *l = (ModuleInfo *)pl, *r = (ModuleInfo *)pr; if (l->base_address < r->base_address) return -1; return l->base_address > r->base_address; } #endif } // namespace #if !SANITIZER_GO void DumpProcessMap() { Report("Dumping process modules:\n"); ListOfModules modules; modules.init(); uptr num_modules = modules.size(); InternalScopedBuffer<ModuleInfo> module_infos(num_modules); for (size_t i = 0; i < num_modules; ++i) { module_infos[i].filepath = modules[i].full_name(); module_infos[i].base_address = modules[i].ranges().front()->beg; module_infos[i].end_address = modules[i].ranges().back()->end; } qsort(module_infos.data(), num_modules, sizeof(ModuleInfo), CompareModulesBase); for (size_t i = 0; i < num_modules; ++i) { const ModuleInfo &mi = module_infos[i]; if (mi.end_address != 0) { Printf("\t%p-%p %s\n", mi.base_address, mi.end_address, mi.filepath[0] ? mi.filepath : "[no name]"); } else if (mi.filepath[0]) { Printf("\t??\?-??? %s\n", mi.filepath); } else { Printf("\t???\n"); } } } #endif void PrintModuleMap() { } void DisableCoreDumperIfNecessary() { // Do nothing. } void ReExec() { UNIMPLEMENTED(); } void PrepareForSandboxing(__sanitizer_sandbox_arguments *args) { } bool StackSizeIsUnlimited() { UNIMPLEMENTED(); } void SetStackSizeLimitInBytes(uptr limit) { UNIMPLEMENTED(); } bool AddressSpaceIsUnlimited() { UNIMPLEMENTED(); } void SetAddressSpaceUnlimited() { UNIMPLEMENTED(); } bool IsPathSeparator(const char c) { return c == '\\' || c == '/'; } bool IsAbsolutePath(const char *path) { UNIMPLEMENTED(); } void SleepForSeconds(int seconds) { Sleep(seconds * 1000); } void SleepForMillis(int millis) { Sleep(millis); } u64 NanoTime() { return 0; } void Abort() { internal__exit(3); } #if !SANITIZER_GO // Read the file to extract the ImageBase field from the PE header. If ASLR is // disabled and this virtual address is available, the loader will typically // load the image at this address. Therefore, we call it the preferred base. Any // addresses in the DWARF typically assume that the object has been loaded at // this address. static uptr GetPreferredBase(const char *modname) { fd_t fd = OpenFile(modname, RdOnly, nullptr); if (fd == kInvalidFd) return 0; FileCloser closer(fd); // Read just the DOS header. IMAGE_DOS_HEADER dos_header; uptr bytes_read; if (!ReadFromFile(fd, &dos_header, sizeof(dos_header), &bytes_read) || bytes_read != sizeof(dos_header)) return 0; // The file should start with the right signature. if (dos_header.e_magic != IMAGE_DOS_SIGNATURE) return 0; // The layout at e_lfanew is: // "PE\0\0" // IMAGE_FILE_HEADER // IMAGE_OPTIONAL_HEADER // Seek to e_lfanew and read all that data. char buf[4 + sizeof(IMAGE_FILE_HEADER) + sizeof(IMAGE_OPTIONAL_HEADER)]; if (::SetFilePointer(fd, dos_header.e_lfanew, nullptr, FILE_BEGIN) == INVALID_SET_FILE_POINTER) return 0; if (!ReadFromFile(fd, &buf[0], sizeof(buf), &bytes_read) || bytes_read != sizeof(buf)) return 0; // Check for "PE\0\0" before the PE header. char *pe_sig = &buf[0]; if (internal_memcmp(pe_sig, "PE\0\0", 4) != 0) return 0; // Skip over IMAGE_FILE_HEADER. We could do more validation here if we wanted. IMAGE_OPTIONAL_HEADER *pe_header = (IMAGE_OPTIONAL_HEADER *)(pe_sig + 4 + sizeof(IMAGE_FILE_HEADER)); // Check for more magic in the PE header. if (pe_header->Magic != IMAGE_NT_OPTIONAL_HDR_MAGIC) return 0; // Finally, return the ImageBase. return (uptr)pe_header->ImageBase; } void ListOfModules::init() { clearOrInit(); HANDLE cur_process = GetCurrentProcess(); // Query the list of modules. Start by assuming there are no more than 256 // modules and retry if that's not sufficient. HMODULE *hmodules = 0; uptr modules_buffer_size = sizeof(HMODULE) * 256; DWORD bytes_required; while (!hmodules) { hmodules = (HMODULE *)MmapOrDie(modules_buffer_size, __FUNCTION__); CHECK(EnumProcessModules(cur_process, hmodules, modules_buffer_size, &bytes_required)); if (bytes_required > modules_buffer_size) { // Either there turned out to be more than 256 hmodules, or new hmodules // could have loaded since the last try. Retry. UnmapOrDie(hmodules, modules_buffer_size); hmodules = 0; modules_buffer_size = bytes_required; } } // |num_modules| is the number of modules actually present, size_t num_modules = bytes_required / sizeof(HMODULE); for (size_t i = 0; i < num_modules; ++i) { HMODULE handle = hmodules[i]; MODULEINFO mi; if (!GetModuleInformation(cur_process, handle, &mi, sizeof(mi))) continue; // Get the UTF-16 path and convert to UTF-8. wchar_t modname_utf16[kMaxPathLength]; int modname_utf16_len = GetModuleFileNameW(handle, modname_utf16, kMaxPathLength); if (modname_utf16_len == 0) modname_utf16[0] = '\0'; char module_name[kMaxPathLength]; int module_name_len = ::WideCharToMultiByte(CP_UTF8, 0, modname_utf16, modname_utf16_len + 1, &module_name[0], kMaxPathLength, NULL, NULL); module_name[module_name_len] = '\0'; uptr base_address = (uptr)mi.lpBaseOfDll; uptr end_address = (uptr)mi.lpBaseOfDll + mi.SizeOfImage; // Adjust the base address of the module so that we get a VA instead of an // RVA when computing the module offset. This helps llvm-symbolizer find the // right DWARF CU. In the common case that the image is loaded at it's // preferred address, we will now print normal virtual addresses. uptr preferred_base = GetPreferredBase(&module_name[0]); uptr adjusted_base = base_address - preferred_base; LoadedModule cur_module; cur_module.set(module_name, adjusted_base); // We add the whole module as one single address range. cur_module.addAddressRange(base_address, end_address, /*executable*/ true, /*writable*/ true); modules_.push_back(cur_module); } UnmapOrDie(hmodules, modules_buffer_size); } void ListOfModules::fallbackInit() { clear(); } // We can't use atexit() directly at __asan_init time as the CRT is not fully // initialized at this point. Place the functions into a vector and use // atexit() as soon as it is ready for use (i.e. after .CRT$XIC initializers). InternalMmapVectorNoCtor<void (*)(void)> atexit_functions; int Atexit(void (*function)(void)) { atexit_functions.push_back(function); return 0; } static int RunAtexit() { int ret = 0; for (uptr i = 0; i < atexit_functions.size(); ++i) { ret |= atexit(atexit_functions[i]); } return ret; } #pragma section(".CRT$XID", long, read) // NOLINT __declspec(allocate(".CRT$XID")) int (*__run_atexit)() = RunAtexit; #endif // ------------------ sanitizer_libc.h fd_t OpenFile(const char *filename, FileAccessMode mode, error_t *last_error) { // FIXME: Use the wide variants to handle Unicode filenames. fd_t res; if (mode == RdOnly) { res = CreateFileA(filename, GENERIC_READ, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE, nullptr, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, nullptr); } else if (mode == WrOnly) { res = CreateFileA(filename, GENERIC_WRITE, 0, nullptr, CREATE_ALWAYS, FILE_ATTRIBUTE_NORMAL, nullptr); } else { UNIMPLEMENTED(); } CHECK(res != kStdoutFd || kStdoutFd == kInvalidFd); CHECK(res != kStderrFd || kStderrFd == kInvalidFd); if (res == kInvalidFd && last_error) *last_error = GetLastError(); return res; } void CloseFile(fd_t fd) { CloseHandle(fd); } bool ReadFromFile(fd_t fd, void *buff, uptr buff_size, uptr *bytes_read, error_t *error_p) { CHECK(fd != kInvalidFd); // bytes_read can't be passed directly to ReadFile: // uptr is unsigned long long on 64-bit Windows. unsigned long num_read_long; bool success = ::ReadFile(fd, buff, buff_size, &num_read_long, nullptr); if (!success && error_p) *error_p = GetLastError(); if (bytes_read) *bytes_read = num_read_long; return success; } bool SupportsColoredOutput(fd_t fd) { // FIXME: support colored output. return false; } bool WriteToFile(fd_t fd, const void *buff, uptr buff_size, uptr *bytes_written, error_t *error_p) { CHECK(fd != kInvalidFd); // Handle null optional parameters. error_t dummy_error; error_p = error_p ? error_p : &dummy_error; uptr dummy_bytes_written; bytes_written = bytes_written ? bytes_written : &dummy_bytes_written; // Initialize output parameters in case we fail. *error_p = 0; *bytes_written = 0; // Map the conventional Unix fds 1 and 2 to Windows handles. They might be // closed, in which case this will fail. if (fd == kStdoutFd || fd == kStderrFd) { fd = GetStdHandle(fd == kStdoutFd ? STD_OUTPUT_HANDLE : STD_ERROR_HANDLE); if (fd == 0) { *error_p = ERROR_INVALID_HANDLE; return false; } } DWORD bytes_written_32; if (!WriteFile(fd, buff, buff_size, &bytes_written_32, 0)) { *error_p = GetLastError(); return false; } else { *bytes_written = bytes_written_32; return true; } } bool RenameFile(const char *oldpath, const char *newpath, error_t *error_p) { UNIMPLEMENTED(); } uptr internal_sched_yield() { Sleep(0); return 0; } void internal__exit(int exitcode) { // ExitProcess runs some finalizers, so use TerminateProcess to avoid that. // The debugger doesn't stop on TerminateProcess like it does on ExitProcess, // so add our own breakpoint here. if (::IsDebuggerPresent()) __debugbreak(); TerminateProcess(GetCurrentProcess(), exitcode); BUILTIN_UNREACHABLE(); } uptr internal_ftruncate(fd_t fd, uptr size) { UNIMPLEMENTED(); } uptr GetRSS() { return 0; } void *internal_start_thread(void (*func)(void *arg), void *arg) { return 0; } void internal_join_thread(void *th) { } // ---------------------- BlockingMutex ---------------- {{{1 const uptr LOCK_UNINITIALIZED = 0; const uptr LOCK_READY = (uptr)-1; BlockingMutex::BlockingMutex(LinkerInitialized li) { // FIXME: see comments in BlockingMutex::Lock() for the details. CHECK(li == LINKER_INITIALIZED || owner_ == LOCK_UNINITIALIZED); CHECK(sizeof(CRITICAL_SECTION) <= sizeof(opaque_storage_)); InitializeCriticalSection((LPCRITICAL_SECTION)opaque_storage_); owner_ = LOCK_READY; } BlockingMutex::BlockingMutex() { CHECK(sizeof(CRITICAL_SECTION) <= sizeof(opaque_storage_)); InitializeCriticalSection((LPCRITICAL_SECTION)opaque_storage_); owner_ = LOCK_READY; } void BlockingMutex::Lock() { if (owner_ == LOCK_UNINITIALIZED) { // FIXME: hm, global BlockingMutex objects are not initialized?!? // This might be a side effect of the clang+cl+link Frankenbuild... new(this) BlockingMutex((LinkerInitialized)(LINKER_INITIALIZED + 1)); // FIXME: If it turns out the linker doesn't invoke our // constructors, we should probably manually Lock/Unlock all the global // locks while we're starting in one thread to avoid double-init races. } EnterCriticalSection((LPCRITICAL_SECTION)opaque_storage_); CHECK_EQ(owner_, LOCK_READY); owner_ = GetThreadSelf(); } void BlockingMutex::Unlock() { CHECK_EQ(owner_, GetThreadSelf()); owner_ = LOCK_READY; LeaveCriticalSection((LPCRITICAL_SECTION)opaque_storage_); } void BlockingMutex::CheckLocked() { CHECK_EQ(owner_, GetThreadSelf()); } uptr GetTlsSize() { return 0; } void InitTlsSize() { } void GetThreadStackAndTls(bool main, uptr *stk_addr, uptr *stk_size, uptr *tls_addr, uptr *tls_size) { #if SANITIZER_GO *stk_addr = 0; *stk_size = 0; *tls_addr = 0; *tls_size = 0; #else uptr stack_top, stack_bottom; GetThreadStackTopAndBottom(main, &stack_top, &stack_bottom); *stk_addr = stack_bottom; *stk_size = stack_top - stack_bottom; *tls_addr = 0; *tls_size = 0; #endif } #if !SANITIZER_GO void BufferedStackTrace::SlowUnwindStack(uptr pc, u32 max_depth) { CHECK_GE(max_depth, 2); // FIXME: CaptureStackBackTrace might be too slow for us. // FIXME: Compare with StackWalk64. // FIXME: Look at LLVMUnhandledExceptionFilter in Signals.inc size = CaptureStackBackTrace(1, Min(max_depth, kStackTraceMax), (void**)trace, 0); if (size == 0) return; // Skip the RTL frames by searching for the PC in the stacktrace. uptr pc_location = LocatePcInTrace(pc); PopStackFrames(pc_location); } void BufferedStackTrace::SlowUnwindStackWithContext(uptr pc, void *context, u32 max_depth) { CONTEXT ctx = *(CONTEXT *)context; STACKFRAME64 stack_frame; memset(&stack_frame, 0, sizeof(stack_frame)); InitializeDbgHelpIfNeeded(); size = 0; #if defined(_WIN64) int machine_type = IMAGE_FILE_MACHINE_AMD64; stack_frame.AddrPC.Offset = ctx.Rip; stack_frame.AddrFrame.Offset = ctx.Rbp; stack_frame.AddrStack.Offset = ctx.Rsp; #else int machine_type = IMAGE_FILE_MACHINE_I386; stack_frame.AddrPC.Offset = ctx.Eip; stack_frame.AddrFrame.Offset = ctx.Ebp; stack_frame.AddrStack.Offset = ctx.Esp; #endif stack_frame.AddrPC.Mode = AddrModeFlat; stack_frame.AddrFrame.Mode = AddrModeFlat; stack_frame.AddrStack.Mode = AddrModeFlat; while (StackWalk64(machine_type, GetCurrentProcess(), GetCurrentThread(), &stack_frame, &ctx, NULL, SymFunctionTableAccess64, SymGetModuleBase64, NULL) && size < Min(max_depth, kStackTraceMax)) { trace_buffer[size++] = (uptr)stack_frame.AddrPC.Offset; } } #endif // #if !SANITIZER_GO void ReportFile::Write(const char *buffer, uptr length) { SpinMutexLock l(mu); ReopenIfNecessary(); if (!WriteToFile(fd, buffer, length)) { // stderr may be closed, but we may be able to print to the debugger // instead. This is the case when launching a program from Visual Studio, // and the following routine should write to its console. OutputDebugStringA(buffer); } } void SetAlternateSignalStack() { // FIXME: Decide what to do on Windows. } void UnsetAlternateSignalStack() { // FIXME: Decide what to do on Windows. } void InstallDeadlySignalHandlers(SignalHandlerType handler) { (void)handler; // FIXME: Decide what to do on Windows. } HandleSignalMode GetHandleSignalMode(int signum) { // FIXME: Decide what to do on Windows. return kHandleSignalNo; } // Check based on flags if we should handle this exception. bool IsHandledDeadlyException(DWORD exceptionCode) { switch (exceptionCode) { case EXCEPTION_ACCESS_VIOLATION: case EXCEPTION_ARRAY_BOUNDS_EXCEEDED: case EXCEPTION_STACK_OVERFLOW: case EXCEPTION_DATATYPE_MISALIGNMENT: case EXCEPTION_IN_PAGE_ERROR: return common_flags()->handle_segv; case EXCEPTION_ILLEGAL_INSTRUCTION: case EXCEPTION_PRIV_INSTRUCTION: case EXCEPTION_BREAKPOINT: return common_flags()->handle_sigill; case EXCEPTION_FLT_DENORMAL_OPERAND: case EXCEPTION_FLT_DIVIDE_BY_ZERO: case EXCEPTION_FLT_INEXACT_RESULT: case EXCEPTION_FLT_INVALID_OPERATION: case EXCEPTION_FLT_OVERFLOW: case EXCEPTION_FLT_STACK_CHECK: case EXCEPTION_FLT_UNDERFLOW: case EXCEPTION_INT_DIVIDE_BY_ZERO: case EXCEPTION_INT_OVERFLOW: return common_flags()->handle_sigfpe; } return false; } bool IsAccessibleMemoryRange(uptr beg, uptr size) { SYSTEM_INFO si; GetNativeSystemInfo(&si); uptr page_size = si.dwPageSize; uptr page_mask = ~(page_size - 1); for (uptr page = beg & page_mask, end = (beg + size - 1) & page_mask; page <= end;) { MEMORY_BASIC_INFORMATION info; if (VirtualQuery((LPCVOID)page, &info, sizeof(info)) != sizeof(info)) return false; if (info.Protect == 0 || info.Protect == PAGE_NOACCESS || info.Protect == PAGE_EXECUTE) return false; if (info.RegionSize == 0) return false; page += info.RegionSize; } return true; } bool SignalContext::IsStackOverflow() const { return GetType() == EXCEPTION_STACK_OVERFLOW; } void SignalContext::InitPcSpBp() { EXCEPTION_RECORD *exception_record = (EXCEPTION_RECORD *)siginfo; CONTEXT *context_record = (CONTEXT *)context; pc = (uptr)exception_record->ExceptionAddress; #ifdef _WIN64 bp = (uptr)context_record->Rbp; sp = (uptr)context_record->Rsp; #else bp = (uptr)context_record->Ebp; sp = (uptr)context_record->Esp; #endif } uptr SignalContext::GetAddress() const { EXCEPTION_RECORD *exception_record = (EXCEPTION_RECORD *)siginfo; return exception_record->ExceptionInformation[1]; } bool SignalContext::IsMemoryAccess() const { return GetWriteFlag() != SignalContext::UNKNOWN; } SignalContext::WriteFlag SignalContext::GetWriteFlag() const { EXCEPTION_RECORD *exception_record = (EXCEPTION_RECORD *)siginfo; // The contents of this array are documented at // https://msdn.microsoft.com/en-us/library/windows/desktop/aa363082(v=vs.85).aspx // The first element indicates read as 0, write as 1, or execute as 8. The // second element is the faulting address. switch (exception_record->ExceptionInformation[0]) { case 0: return SignalContext::READ; case 1: return SignalContext::WRITE; case 8: return SignalContext::UNKNOWN; } return SignalContext::UNKNOWN; } void SignalContext::DumpAllRegisters(void *context) { // FIXME: Implement this. } int SignalContext::GetType() const { return static_cast<const EXCEPTION_RECORD *>(siginfo)->ExceptionCode; } const char *SignalContext::Describe() const { unsigned code = GetType(); // Get the string description of the exception if this is a known deadly // exception. switch (code) { case EXCEPTION_ACCESS_VIOLATION: return "access-violation"; case EXCEPTION_ARRAY_BOUNDS_EXCEEDED: return "array-bounds-exceeded"; case EXCEPTION_STACK_OVERFLOW: return "stack-overflow"; case EXCEPTION_DATATYPE_MISALIGNMENT: return "datatype-misalignment"; case EXCEPTION_IN_PAGE_ERROR: return "in-page-error"; case EXCEPTION_ILLEGAL_INSTRUCTION: return "illegal-instruction"; case EXCEPTION_PRIV_INSTRUCTION: return "priv-instruction"; case EXCEPTION_BREAKPOINT: return "breakpoint"; case EXCEPTION_FLT_DENORMAL_OPERAND: return "flt-denormal-operand"; case EXCEPTION_FLT_DIVIDE_BY_ZERO: return "flt-divide-by-zero"; case EXCEPTION_FLT_INEXACT_RESULT: return "flt-inexact-result"; case EXCEPTION_FLT_INVALID_OPERATION: return "flt-invalid-operation"; case EXCEPTION_FLT_OVERFLOW: return "flt-overflow"; case EXCEPTION_FLT_STACK_CHECK: return "flt-stack-check"; case EXCEPTION_FLT_UNDERFLOW: return "flt-underflow"; case EXCEPTION_INT_DIVIDE_BY_ZERO: return "int-divide-by-zero"; case EXCEPTION_INT_OVERFLOW: return "int-overflow"; } return "unknown exception"; } uptr ReadBinaryName(/*out*/char *buf, uptr buf_len) { // FIXME: Actually implement this function. CHECK_GT(buf_len, 0); buf[0] = 0; return 0; } uptr ReadLongProcessName(/*out*/char *buf, uptr buf_len) { return ReadBinaryName(buf, buf_len); } void CheckVMASize() { // Do nothing. } void MaybeReexec() { // No need to re-exec on Windows. } char **GetArgv() { // FIXME: Actually implement this function. return 0; } pid_t StartSubprocess(const char *program, const char *const argv[], fd_t stdin_fd, fd_t stdout_fd, fd_t stderr_fd) { // FIXME: implement on this platform // Should be implemented based on // SymbolizerProcess::StarAtSymbolizerSubprocess // from lib/sanitizer_common/sanitizer_symbolizer_win.cc. return -1; } bool IsProcessRunning(pid_t pid) { // FIXME: implement on this platform. return false; } int WaitForProcess(pid_t pid) { return -1; } // FIXME implement on this platform. void GetMemoryProfile(fill_profile_f cb, uptr *stats, uptr stats_size) { } void CheckNoDeepBind(const char *filename, int flag) { // Do nothing. } // FIXME: implement on this platform. bool GetRandom(void *buffer, uptr length, bool blocking) { UNIMPLEMENTED(); } } // namespace __sanitizer #endif // _WIN32