//===-- sanitizer_common.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 shared between AddressSanitizer and ThreadSanitizer // run-time libraries. //===----------------------------------------------------------------------===// #include "sanitizer_common.h" #include "sanitizer_allocator_interface.h" #include "sanitizer_allocator_internal.h" #include "sanitizer_atomic.h" #include "sanitizer_flags.h" #include "sanitizer_libc.h" #include "sanitizer_placement_new.h" namespace __sanitizer { const char *SanitizerToolName = "SanitizerTool"; atomic_uint32_t current_verbosity; uptr PageSizeCached; u32 NumberOfCPUsCached; // PID of the tracer task in StopTheWorld. It shares the address space with the // main process, but has a different PID and thus requires special handling. uptr stoptheworld_tracer_pid = 0; // Cached pid of parent process - if the parent process dies, we want to keep // writing to the same log file. uptr stoptheworld_tracer_ppid = 0; void NORETURN ReportMmapFailureAndDie(uptr size, const char *mem_type, const char *mmap_type, error_t err, bool raw_report) { static int recursion_count; if (raw_report || recursion_count) { // If raw report is requested or we went into recursion just die. The // Report() and CHECK calls below may call mmap recursively and fail. RawWrite("ERROR: Failed to mmap\n"); Die(); } recursion_count++; Report("ERROR: %s failed to " "%s 0x%zx (%zd) bytes of %s (error code: %d)\n", SanitizerToolName, mmap_type, size, size, mem_type, err); #if !SANITIZER_GO DumpProcessMap(); #endif UNREACHABLE("unable to mmap"); } typedef bool UptrComparisonFunction(const uptr &a, const uptr &b); typedef bool U32ComparisonFunction(const u32 &a, const u32 &b); const char *StripPathPrefix(const char *filepath, const char *strip_path_prefix) { if (!filepath) return nullptr; if (!strip_path_prefix) return filepath; const char *res = filepath; if (const char *pos = internal_strstr(filepath, strip_path_prefix)) res = pos + internal_strlen(strip_path_prefix); if (res[0] == '.' && res[1] == '/') res += 2; return res; } const char *StripModuleName(const char *module) { if (!module) return nullptr; if (SANITIZER_WINDOWS) { // On Windows, both slash and backslash are possible. // Pick the one that goes last. if (const char *bslash_pos = internal_strrchr(module, '\\')) return StripModuleName(bslash_pos + 1); } if (const char *slash_pos = internal_strrchr(module, '/')) { return slash_pos + 1; } return module; } void ReportErrorSummary(const char *error_message, const char *alt_tool_name) { if (!common_flags()->print_summary) return; InternalScopedString buff; buff.append("SUMMARY: %s: %s", alt_tool_name ? alt_tool_name : SanitizerToolName, error_message); __sanitizer_report_error_summary(buff.data()); } // Removes the ANSI escape sequences from the input string (in-place). void RemoveANSIEscapeSequencesFromString(char *str) { if (!str) return; // We are going to remove the escape sequences in place. char *s = str; char *z = str; while (*s != '\0') { CHECK_GE(s, z); // Skip over ANSI escape sequences with pointer 's'. if (*s == '\033' && *(s + 1) == '[') { s = internal_strchrnul(s, 'm'); if (*s == '\0') { break; } s++; continue; } // 's' now points at a character we want to keep. Copy over the buffer // content if the escape sequence has been perviously skipped andadvance // both pointers. if (s != z) *z = *s; // If we have not seen an escape sequence, just advance both pointers. z++; s++; } // Null terminate the string. *z = '\0'; } void LoadedModule::set(const char *module_name, uptr base_address) { clear(); full_name_ = internal_strdup(module_name); base_address_ = base_address; } void LoadedModule::set(const char *module_name, uptr base_address, ModuleArch arch, u8 uuid[kModuleUUIDSize], bool instrumented) { set(module_name, base_address); arch_ = arch; internal_memcpy(uuid_, uuid, sizeof(uuid_)); uuid_size_ = kModuleUUIDSize; instrumented_ = instrumented; } void LoadedModule::setUuid(const char *uuid, uptr size) { if (size > kModuleUUIDSize) size = kModuleUUIDSize; internal_memcpy(uuid_, uuid, size); uuid_size_ = size; } void LoadedModule::clear() { InternalFree(full_name_); base_address_ = 0; max_executable_address_ = 0; full_name_ = nullptr; arch_ = kModuleArchUnknown; internal_memset(uuid_, 0, kModuleUUIDSize); instrumented_ = false; while (!ranges_.empty()) { AddressRange *r = ranges_.front(); ranges_.pop_front(); InternalFree(r); } } void LoadedModule::addAddressRange(uptr beg, uptr end, bool executable, bool writable, const char *name) { void *mem = InternalAlloc(sizeof(AddressRange)); AddressRange *r = new(mem) AddressRange(beg, end, executable, writable, name); ranges_.push_back(r); if (executable && end > max_executable_address_) max_executable_address_ = end; } bool LoadedModule::containsAddress(uptr address) const { for (const AddressRange &r : ranges()) { if (r.beg <= address && address < r.end) return true; } return false; } static atomic_uintptr_t g_total_mmaped; void IncreaseTotalMmap(uptr size) { if (!common_flags()->mmap_limit_mb) return; uptr total_mmaped = atomic_fetch_add(&g_total_mmaped, size, memory_order_relaxed) + size; // Since for now mmap_limit_mb is not a user-facing flag, just kill // a program. Use RAW_CHECK to avoid extra mmaps in reporting. RAW_CHECK((total_mmaped >> 20) < common_flags()->mmap_limit_mb); } void DecreaseTotalMmap(uptr size) { if (!common_flags()->mmap_limit_mb) return; atomic_fetch_sub(&g_total_mmaped, size, memory_order_relaxed); } bool TemplateMatch(const char *templ, const char *str) { if ((!str) || str[0] == 0) return false; bool start = false; if (templ && templ[0] == '^') { start = true; templ++; } bool asterisk = false; while (templ && templ[0]) { if (templ[0] == '*') { templ++; start = false; asterisk = true; continue; } if (templ[0] == '$') return str[0] == 0 || asterisk; if (str[0] == 0) return false; char *tpos = (char*)internal_strchr(templ, '*'); char *tpos1 = (char*)internal_strchr(templ, '$'); if ((!tpos) || (tpos1 && tpos1 < tpos)) tpos = tpos1; if (tpos) tpos[0] = 0; const char *str0 = str; const char *spos = internal_strstr(str, templ); str = spos + internal_strlen(templ); templ = tpos; if (tpos) tpos[0] = tpos == tpos1 ? '$' : '*'; if (!spos) return false; if (start && spos != str0) return false; start = false; asterisk = false; } return true; } static char binary_name_cache_str[kMaxPathLength]; static char process_name_cache_str[kMaxPathLength]; const char *GetProcessName() { return process_name_cache_str; } static uptr ReadProcessName(/*out*/ char *buf, uptr buf_len) { ReadLongProcessName(buf, buf_len); char *s = const_cast(StripModuleName(buf)); uptr len = internal_strlen(s); if (s != buf) { internal_memmove(buf, s, len); buf[len] = '\0'; } return len; } void UpdateProcessName() { ReadProcessName(process_name_cache_str, sizeof(process_name_cache_str)); } // Call once to make sure that binary_name_cache_str is initialized void CacheBinaryName() { if (binary_name_cache_str[0] != '\0') return; ReadBinaryName(binary_name_cache_str, sizeof(binary_name_cache_str)); ReadProcessName(process_name_cache_str, sizeof(process_name_cache_str)); } uptr ReadBinaryNameCached(/*out*/char *buf, uptr buf_len) { CacheBinaryName(); uptr name_len = internal_strlen(binary_name_cache_str); name_len = (name_len < buf_len - 1) ? name_len : buf_len - 1; if (buf_len == 0) return 0; internal_memcpy(buf, binary_name_cache_str, name_len); buf[name_len] = '\0'; return name_len; } uptr ReadBinaryDir(/*out*/ char *buf, uptr buf_len) { ReadBinaryNameCached(buf, buf_len); const char *exec_name_pos = StripModuleName(buf); uptr name_len = exec_name_pos - buf; buf[name_len] = '\0'; return name_len; } #if !SANITIZER_GO void PrintCmdline() { char **argv = GetArgv(); if (!argv) return; Printf("\nCommand: "); for (uptr i = 0; argv[i]; ++i) Printf("%s ", argv[i]); Printf("\n\n"); } #endif // Malloc hooks. static const int kMaxMallocFreeHooks = 5; struct MallocFreeHook { void (*malloc_hook)(const void *, uptr); void (*free_hook)(const void *); }; static MallocFreeHook MFHooks[kMaxMallocFreeHooks]; void RunMallocHooks(const void *ptr, uptr size) { for (int i = 0; i < kMaxMallocFreeHooks; i++) { auto hook = MFHooks[i].malloc_hook; if (!hook) return; hook(ptr, size); } } void RunFreeHooks(const void *ptr) { for (int i = 0; i < kMaxMallocFreeHooks; i++) { auto hook = MFHooks[i].free_hook; if (!hook) return; hook(ptr); } } static int InstallMallocFreeHooks(void (*malloc_hook)(const void *, uptr), void (*free_hook)(const void *)) { if (!malloc_hook || !free_hook) return 0; for (int i = 0; i < kMaxMallocFreeHooks; i++) { if (MFHooks[i].malloc_hook == nullptr) { MFHooks[i].malloc_hook = malloc_hook; MFHooks[i].free_hook = free_hook; return i + 1; } } return 0; } void internal_sleep(unsigned seconds) { internal_usleep((u64)seconds * 1000 * 1000); } void SleepForSeconds(unsigned seconds) { internal_usleep((u64)seconds * 1000 * 1000); } void SleepForMillis(unsigned millis) { internal_usleep((u64)millis * 1000); } } // namespace __sanitizer using namespace __sanitizer; extern "C" { SANITIZER_INTERFACE_WEAK_DEF(void, __sanitizer_report_error_summary, const char *error_summary) { Printf("%s\n", error_summary); } SANITIZER_INTERFACE_ATTRIBUTE int __sanitizer_acquire_crash_state() { static atomic_uint8_t in_crash_state = {}; return !atomic_exchange(&in_crash_state, 1, memory_order_relaxed); } SANITIZER_INTERFACE_ATTRIBUTE int __sanitizer_install_malloc_and_free_hooks(void (*malloc_hook)(const void *, uptr), void (*free_hook)(const void *)) { return InstallMallocFreeHooks(malloc_hook, free_hook); } } // extern "C"