//===-- sanitizer_posix_libcdep.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 libc-dependent POSIX-specific functions // from sanitizer_libc.h. //===----------------------------------------------------------------------===// #include "sanitizer_platform.h" #if SANITIZER_POSIX #include "sanitizer_common.h" #include "sanitizer_flags.h" #include "sanitizer_platform_limits_netbsd.h" #include "sanitizer_platform_limits_posix.h" #include "sanitizer_posix.h" #include "sanitizer_procmaps.h" #include "sanitizer_stacktrace.h" #include "sanitizer_symbolizer.h" #include #include #include #include #include #include #include #include #include #include #include #include #if SANITIZER_FREEBSD // The MAP_NORESERVE define has been removed in FreeBSD 11.x, and even before // that, it was never implemented. So just define it to zero. #undef MAP_NORESERVE #define MAP_NORESERVE 0 #endif typedef void (*sa_sigaction_t)(int, siginfo_t *, void *); namespace __sanitizer { u32 GetUid() { return getuid(); } uptr GetThreadSelf() { return (uptr)pthread_self(); } void ReleaseMemoryPagesToOS(uptr beg, uptr end) { uptr page_size = GetPageSizeCached(); uptr beg_aligned = RoundUpTo(beg, page_size); uptr end_aligned = RoundDownTo(end, page_size); if (beg_aligned < end_aligned) madvise((void*)beg_aligned, end_aligned - beg_aligned, MADV_DONTNEED); } void NoHugePagesInRegion(uptr addr, uptr size) { #ifdef MADV_NOHUGEPAGE // May not be defined on old systems. madvise((void *)addr, size, MADV_NOHUGEPAGE); #endif // MADV_NOHUGEPAGE } void DontDumpShadowMemory(uptr addr, uptr length) { #ifdef MADV_DONTDUMP madvise((void *)addr, length, MADV_DONTDUMP); #endif } static rlim_t getlim(int res) { rlimit rlim; CHECK_EQ(0, getrlimit(res, &rlim)); return rlim.rlim_cur; } static void setlim(int res, rlim_t lim) { // The following magic is to prevent clang from replacing it with memset. volatile struct rlimit rlim; rlim.rlim_cur = lim; rlim.rlim_max = lim; if (setrlimit(res, const_cast(&rlim))) { Report("ERROR: %s setrlimit() failed %d\n", SanitizerToolName, errno); Die(); } } void DisableCoreDumperIfNecessary() { if (common_flags()->disable_coredump) { setlim(RLIMIT_CORE, 0); } } bool StackSizeIsUnlimited() { rlim_t stack_size = getlim(RLIMIT_STACK); return (stack_size == RLIM_INFINITY); } uptr GetStackSizeLimitInBytes() { return (uptr)getlim(RLIMIT_STACK); } void SetStackSizeLimitInBytes(uptr limit) { setlim(RLIMIT_STACK, (rlim_t)limit); CHECK(!StackSizeIsUnlimited()); } bool AddressSpaceIsUnlimited() { rlim_t as_size = getlim(RLIMIT_AS); return (as_size == RLIM_INFINITY); } void SetAddressSpaceUnlimited() { setlim(RLIMIT_AS, RLIM_INFINITY); CHECK(AddressSpaceIsUnlimited()); } void SleepForSeconds(int seconds) { sleep(seconds); } void SleepForMillis(int millis) { usleep(millis * 1000); } void Abort() { #if !SANITIZER_GO // If we are handling SIGABRT, unhandle it first. // TODO(vitalybuka): Check if handler belongs to sanitizer. if (GetHandleSignalMode(SIGABRT) != kHandleSignalNo) { struct sigaction sigact; internal_memset(&sigact, 0, sizeof(sigact)); sigact.sa_sigaction = (sa_sigaction_t)SIG_DFL; internal_sigaction(SIGABRT, &sigact, nullptr); } #endif abort(); } int Atexit(void (*function)(void)) { #if !SANITIZER_GO return atexit(function); #else return 0; #endif } bool SupportsColoredOutput(fd_t fd) { return isatty(fd) != 0; } #if !SANITIZER_GO // TODO(glider): different tools may require different altstack size. static const uptr kAltStackSize = SIGSTKSZ * 4; // SIGSTKSZ is not enough. void SetAlternateSignalStack() { stack_t altstack, oldstack; CHECK_EQ(0, sigaltstack(nullptr, &oldstack)); // If the alternate stack is already in place, do nothing. // Android always sets an alternate stack, but it's too small for us. if (!SANITIZER_ANDROID && !(oldstack.ss_flags & SS_DISABLE)) return; // TODO(glider): the mapped stack should have the MAP_STACK flag in the // future. It is not required by man 2 sigaltstack now (they're using // malloc()). void* base = MmapOrDie(kAltStackSize, __func__); altstack.ss_sp = (char*) base; altstack.ss_flags = 0; altstack.ss_size = kAltStackSize; CHECK_EQ(0, sigaltstack(&altstack, nullptr)); } void UnsetAlternateSignalStack() { stack_t altstack, oldstack; altstack.ss_sp = nullptr; altstack.ss_flags = SS_DISABLE; altstack.ss_size = kAltStackSize; // Some sane value required on Darwin. CHECK_EQ(0, sigaltstack(&altstack, &oldstack)); UnmapOrDie(oldstack.ss_sp, oldstack.ss_size); } static void MaybeInstallSigaction(int signum, SignalHandlerType handler) { if (GetHandleSignalMode(signum) == kHandleSignalNo) return; struct sigaction sigact; internal_memset(&sigact, 0, sizeof(sigact)); sigact.sa_sigaction = (sa_sigaction_t)handler; // Do not block the signal from being received in that signal's handler. // Clients are responsible for handling this correctly. sigact.sa_flags = SA_SIGINFO | SA_NODEFER; if (common_flags()->use_sigaltstack) sigact.sa_flags |= SA_ONSTACK; CHECK_EQ(0, internal_sigaction(signum, &sigact, nullptr)); VReport(1, "Installed the sigaction for signal %d\n", signum); } void InstallDeadlySignalHandlers(SignalHandlerType handler) { // Set the alternate signal stack for the main thread. // This will cause SetAlternateSignalStack to be called twice, but the stack // will be actually set only once. if (common_flags()->use_sigaltstack) SetAlternateSignalStack(); MaybeInstallSigaction(SIGSEGV, handler); MaybeInstallSigaction(SIGBUS, handler); MaybeInstallSigaction(SIGABRT, handler); MaybeInstallSigaction(SIGFPE, handler); MaybeInstallSigaction(SIGILL, handler); } bool SignalContext::IsStackOverflow() const { // Access at a reasonable offset above SP, or slightly below it (to account // for x86_64 or PowerPC redzone, ARM push of multiple registers, etc) is // probably a stack overflow. #ifdef __s390__ // On s390, the fault address in siginfo points to start of the page, not // to the precise word that was accessed. Mask off the low bits of sp to // take it into account. bool IsStackAccess = addr >= (sp & ~0xFFF) && addr < sp + 0xFFFF; #else bool IsStackAccess = addr + 512 > sp && addr < sp + 0xFFFF; #endif #if __powerpc__ // Large stack frames can be allocated with e.g. // lis r0,-10000 // stdux r1,r1,r0 # store sp to [sp-10000] and update sp by -10000 // If the store faults then sp will not have been updated, so test above // will not work, because the fault address will be more than just "slightly" // below sp. if (!IsStackAccess && IsAccessibleMemoryRange(pc, 4)) { u32 inst = *(unsigned *)pc; u32 ra = (inst >> 16) & 0x1F; u32 opcd = inst >> 26; u32 xo = (inst >> 1) & 0x3FF; // Check for store-with-update to sp. The instructions we accept are: // stbu rs,d(ra) stbux rs,ra,rb // sthu rs,d(ra) sthux rs,ra,rb // stwu rs,d(ra) stwux rs,ra,rb // stdu rs,ds(ra) stdux rs,ra,rb // where ra is r1 (the stack pointer). if (ra == 1 && (opcd == 39 || opcd == 45 || opcd == 37 || opcd == 62 || (opcd == 31 && (xo == 247 || xo == 439 || xo == 183 || xo == 181)))) IsStackAccess = true; } #endif // __powerpc__ // We also check si_code to filter out SEGV caused by something else other // then hitting the guard page or unmapped memory, like, for example, // unaligned memory access. auto si = static_cast(siginfo); return IsStackAccess && (si->si_code == si_SEGV_MAPERR || si->si_code == si_SEGV_ACCERR); } #endif // SANITIZER_GO bool IsAccessibleMemoryRange(uptr beg, uptr size) { uptr page_size = GetPageSizeCached(); // Checking too large memory ranges is slow. CHECK_LT(size, page_size * 10); int sock_pair[2]; if (pipe(sock_pair)) return false; uptr bytes_written = internal_write(sock_pair[1], reinterpret_cast(beg), size); int write_errno; bool result; if (internal_iserror(bytes_written, &write_errno)) { CHECK_EQ(EFAULT, write_errno); result = false; } else { result = (bytes_written == size); } internal_close(sock_pair[0]); internal_close(sock_pair[1]); return result; } void PrepareForSandboxing(__sanitizer_sandbox_arguments *args) { // Some kinds of sandboxes may forbid filesystem access, so we won't be able // to read the file mappings from /proc/self/maps. Luckily, neither the // process will be able to load additional libraries, so it's fine to use the // cached mappings. MemoryMappingLayout::CacheMemoryMappings(); // Same for /proc/self/exe in the symbolizer. #if !SANITIZER_GO Symbolizer::GetOrInit()->PrepareForSandboxing(); #endif } #if SANITIZER_ANDROID || SANITIZER_GO int GetNamedMappingFd(const char *name, uptr size) { return -1; } #else int GetNamedMappingFd(const char *name, uptr size) { if (!common_flags()->decorate_proc_maps) return -1; char shmname[200]; CHECK(internal_strlen(name) < sizeof(shmname) - 10); internal_snprintf(shmname, sizeof(shmname), "%zu [%s]", internal_getpid(), name); int fd = shm_open(shmname, O_RDWR | O_CREAT | O_TRUNC, S_IRWXU); CHECK_GE(fd, 0); int res = internal_ftruncate(fd, size); CHECK_EQ(0, res); res = shm_unlink(shmname); CHECK_EQ(0, res); return fd; } #endif void *MmapFixedNoReserve(uptr fixed_addr, uptr size, const char *name) { int fd = name ? GetNamedMappingFd(name, size) : -1; unsigned flags = MAP_PRIVATE | MAP_FIXED | MAP_NORESERVE; if (fd == -1) flags |= MAP_ANON; uptr PageSize = GetPageSizeCached(); uptr p = internal_mmap((void *)(fixed_addr & ~(PageSize - 1)), RoundUpTo(size, PageSize), PROT_READ | PROT_WRITE, flags, fd, 0); int reserrno; if (internal_iserror(p, &reserrno)) Report("ERROR: %s failed to " "allocate 0x%zx (%zd) bytes at address %zx (errno: %d)\n", SanitizerToolName, size, size, fixed_addr, reserrno); IncreaseTotalMmap(size); return (void *)p; } void *MmapFixedNoAccess(uptr fixed_addr, uptr size, const char *name) { int fd = name ? GetNamedMappingFd(name, size) : -1; unsigned flags = MAP_PRIVATE | MAP_FIXED | MAP_NORESERVE; if (fd == -1) flags |= MAP_ANON; return (void *)internal_mmap((void *)fixed_addr, size, PROT_NONE, flags, fd, 0); } void *MmapNoAccess(uptr size) { unsigned flags = MAP_PRIVATE | MAP_ANON | MAP_NORESERVE; return (void *)internal_mmap(nullptr, size, PROT_NONE, flags, -1, 0); } // This function is defined elsewhere if we intercepted pthread_attr_getstack. extern "C" { SANITIZER_WEAK_ATTRIBUTE int real_pthread_attr_getstack(void *attr, void **addr, size_t *size); } // extern "C" int my_pthread_attr_getstack(void *attr, void **addr, uptr *size) { #if !SANITIZER_GO && !SANITIZER_MAC if (&real_pthread_attr_getstack) return real_pthread_attr_getstack((pthread_attr_t *)attr, addr, (size_t *)size); #endif return pthread_attr_getstack((pthread_attr_t *)attr, addr, (size_t *)size); } #if !SANITIZER_GO void AdjustStackSize(void *attr_) { pthread_attr_t *attr = (pthread_attr_t *)attr_; uptr stackaddr = 0; uptr stacksize = 0; my_pthread_attr_getstack(attr, (void**)&stackaddr, &stacksize); // GLibC will return (0 - stacksize) as the stack address in the case when // stacksize is set, but stackaddr is not. bool stack_set = (stackaddr != 0) && (stackaddr + stacksize != 0); // We place a lot of tool data into TLS, account for that. const uptr minstacksize = GetTlsSize() + 128*1024; if (stacksize < minstacksize) { if (!stack_set) { if (stacksize != 0) { VPrintf(1, "Sanitizer: increasing stacksize %zu->%zu\n", stacksize, minstacksize); pthread_attr_setstacksize(attr, minstacksize); } } else { Printf("Sanitizer: pre-allocated stack size is insufficient: " "%zu < %zu\n", stacksize, minstacksize); Printf("Sanitizer: pthread_create is likely to fail.\n"); } } } #endif // !SANITIZER_GO pid_t StartSubprocess(const char *program, const char *const argv[], fd_t stdin_fd, fd_t stdout_fd, fd_t stderr_fd) { auto file_closer = at_scope_exit([&] { if (stdin_fd != kInvalidFd) { internal_close(stdin_fd); } if (stdout_fd != kInvalidFd) { internal_close(stdout_fd); } if (stderr_fd != kInvalidFd) { internal_close(stderr_fd); } }); int pid = internal_fork(); if (pid < 0) { int rverrno; if (internal_iserror(pid, &rverrno)) { Report("WARNING: failed to fork (errno %d)\n", rverrno); } return pid; } if (pid == 0) { // Child subprocess if (stdin_fd != kInvalidFd) { internal_close(STDIN_FILENO); internal_dup2(stdin_fd, STDIN_FILENO); internal_close(stdin_fd); } if (stdout_fd != kInvalidFd) { internal_close(STDOUT_FILENO); internal_dup2(stdout_fd, STDOUT_FILENO); internal_close(stdout_fd); } if (stderr_fd != kInvalidFd) { internal_close(STDERR_FILENO); internal_dup2(stderr_fd, STDERR_FILENO); internal_close(stderr_fd); } for (int fd = sysconf(_SC_OPEN_MAX); fd > 2; fd--) internal_close(fd); execv(program, const_cast(&argv[0])); internal__exit(1); } return pid; } bool IsProcessRunning(pid_t pid) { int process_status; uptr waitpid_status = internal_waitpid(pid, &process_status, WNOHANG); int local_errno; if (internal_iserror(waitpid_status, &local_errno)) { VReport(1, "Waiting on the process failed (errno %d).\n", local_errno); return false; } return waitpid_status == 0; } int WaitForProcess(pid_t pid) { int process_status; uptr waitpid_status = internal_waitpid(pid, &process_status, 0); int local_errno; if (internal_iserror(waitpid_status, &local_errno)) { VReport(1, "Waiting on the process failed (errno %d).\n", local_errno); return -1; } return process_status; } bool IsStateDetached(int state) { return state == PTHREAD_CREATE_DETACHED; } } // namespace __sanitizer #endif // SANITIZER_POSIX