//===-- hwasan_linux.cpp ----------------------------------------*- C++ -*-===// // // 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 // //===----------------------------------------------------------------------===// /// /// \file /// This file is a part of HWAddressSanitizer and contains Linux-, NetBSD- and /// FreeBSD-specific code. /// //===----------------------------------------------------------------------===// #include "sanitizer_common/sanitizer_platform.h" #if SANITIZER_FREEBSD || SANITIZER_LINUX || SANITIZER_NETBSD # include # include # include # include # include # include # include # include # include # include # include # include # include # include "hwasan.h" # include "hwasan_dynamic_shadow.h" # include "hwasan_interface_internal.h" # include "hwasan_mapping.h" # include "hwasan_report.h" # include "hwasan_thread.h" # include "hwasan_thread_list.h" # include "sanitizer_common/sanitizer_common.h" # include "sanitizer_common/sanitizer_procmaps.h" # include "sanitizer_common/sanitizer_stackdepot.h" // Configurations of HWASAN_WITH_INTERCEPTORS and SANITIZER_ANDROID. // // HWASAN_WITH_INTERCEPTORS=OFF, SANITIZER_ANDROID=OFF // Not currently tested. // HWASAN_WITH_INTERCEPTORS=OFF, SANITIZER_ANDROID=ON // Integration tests downstream exist. // HWASAN_WITH_INTERCEPTORS=ON, SANITIZER_ANDROID=OFF // Tested with check-hwasan on x86_64-linux. // HWASAN_WITH_INTERCEPTORS=ON, SANITIZER_ANDROID=ON // Tested with check-hwasan on aarch64-linux-android. # if !SANITIZER_ANDROID SANITIZER_INTERFACE_ATTRIBUTE THREADLOCAL uptr __hwasan_tls; # endif namespace __hwasan { // With the zero shadow base we can not actually map pages starting from 0. // This constant is somewhat arbitrary. constexpr uptr kZeroBaseShadowStart = 0; constexpr uptr kZeroBaseMaxShadowStart = 1 << 18; static void ProtectGap(uptr addr, uptr size) { __sanitizer::ProtectGap(addr, size, kZeroBaseShadowStart, kZeroBaseMaxShadowStart); } uptr kLowMemStart; uptr kLowMemEnd; uptr kHighMemStart; uptr kHighMemEnd; static void PrintRange(uptr start, uptr end, const char *name) { Printf("|| [%p, %p] || %.*s ||\n", (void *)start, (void *)end, 10, name); } static void PrintAddressSpaceLayout() { PrintRange(kHighMemStart, kHighMemEnd, "HighMem"); if (kHighShadowEnd + 1 < kHighMemStart) PrintRange(kHighShadowEnd + 1, kHighMemStart - 1, "ShadowGap"); else CHECK_EQ(kHighShadowEnd + 1, kHighMemStart); PrintRange(kHighShadowStart, kHighShadowEnd, "HighShadow"); if (kLowShadowEnd + 1 < kHighShadowStart) PrintRange(kLowShadowEnd + 1, kHighShadowStart - 1, "ShadowGap"); else CHECK_EQ(kLowMemEnd + 1, kHighShadowStart); PrintRange(kLowShadowStart, kLowShadowEnd, "LowShadow"); if (kLowMemEnd + 1 < kLowShadowStart) PrintRange(kLowMemEnd + 1, kLowShadowStart - 1, "ShadowGap"); else CHECK_EQ(kLowMemEnd + 1, kLowShadowStart); PrintRange(kLowMemStart, kLowMemEnd, "LowMem"); CHECK_EQ(0, kLowMemStart); } static uptr GetHighMemEnd() { // HighMem covers the upper part of the address space. uptr max_address = GetMaxUserVirtualAddress(); // Adjust max address to make sure that kHighMemEnd and kHighMemStart are // properly aligned: max_address |= (GetMmapGranularity() << kShadowScale) - 1; return max_address; } static void InitializeShadowBaseAddress(uptr shadow_size_bytes) { __hwasan_shadow_memory_dynamic_address = FindDynamicShadowStart(shadow_size_bytes); } void InitializeOsSupport() { # define PR_SET_TAGGED_ADDR_CTRL 55 # define PR_GET_TAGGED_ADDR_CTRL 56 # define PR_TAGGED_ADDR_ENABLE (1UL << 0) // Check we're running on a kernel that can use the tagged address ABI. int local_errno = 0; if (internal_iserror(internal_prctl(PR_GET_TAGGED_ADDR_CTRL, 0, 0, 0, 0), &local_errno) && local_errno == EINVAL) { # if SANITIZER_ANDROID || defined(HWASAN_ALIASING_MODE) // Some older Android kernels have the tagged pointer ABI on // unconditionally, and hence don't have the tagged-addr prctl while still // allow the ABI. // If targeting Android and the prctl is not around we assume this is the // case. return; # else if (flags()->fail_without_syscall_abi) { Printf( "FATAL: " "HWAddressSanitizer requires a kernel with tagged address ABI.\n"); Die(); } # endif } // Turn on the tagged address ABI. if ((internal_iserror(internal_prctl(PR_SET_TAGGED_ADDR_CTRL, PR_TAGGED_ADDR_ENABLE, 0, 0, 0)) || !internal_prctl(PR_GET_TAGGED_ADDR_CTRL, 0, 0, 0, 0))) { # if defined(__x86_64__) && !defined(HWASAN_ALIASING_MODE) // Try the new prctl API for Intel LAM. The API is based on a currently // unsubmitted patch to the Linux kernel (as of May 2021) and is thus // subject to change. Patch is here: // https://lore.kernel.org/linux-mm/20210205151631.43511-12-kirill.shutemov@linux.intel.com/ int tag_bits = kTagBits; int tag_shift = kAddressTagShift; if (!internal_iserror( internal_prctl(PR_SET_TAGGED_ADDR_CTRL, PR_TAGGED_ADDR_ENABLE, reinterpret_cast(&tag_bits), reinterpret_cast(&tag_shift), 0))) { CHECK_EQ(tag_bits, kTagBits); CHECK_EQ(tag_shift, kAddressTagShift); return; } # endif // defined(__x86_64__) && !defined(HWASAN_ALIASING_MODE) if (flags()->fail_without_syscall_abi) { Printf( "FATAL: HWAddressSanitizer failed to enable tagged address syscall " "ABI.\nSuggest check `sysctl abi.tagged_addr_disabled` " "configuration.\n"); Die(); } } # undef PR_SET_TAGGED_ADDR_CTRL # undef PR_GET_TAGGED_ADDR_CTRL # undef PR_TAGGED_ADDR_ENABLE } bool InitShadow() { // Define the entire memory range. kHighMemEnd = GetHighMemEnd(); // Determine shadow memory base offset. InitializeShadowBaseAddress(MemToShadowSize(kHighMemEnd)); // Place the low memory first. kLowMemEnd = __hwasan_shadow_memory_dynamic_address - 1; kLowMemStart = 0; // Define the low shadow based on the already placed low memory. kLowShadowEnd = MemToShadow(kLowMemEnd); kLowShadowStart = __hwasan_shadow_memory_dynamic_address; // High shadow takes whatever memory is left up there (making sure it is not // interfering with low memory in the fixed case). kHighShadowEnd = MemToShadow(kHighMemEnd); kHighShadowStart = Max(kLowMemEnd, MemToShadow(kHighShadowEnd)) + 1; // High memory starts where allocated shadow allows. kHighMemStart = ShadowToMem(kHighShadowStart); // Check the sanity of the defined memory ranges (there might be gaps). CHECK_EQ(kHighMemStart % GetMmapGranularity(), 0); CHECK_GT(kHighMemStart, kHighShadowEnd); CHECK_GT(kHighShadowEnd, kHighShadowStart); CHECK_GT(kHighShadowStart, kLowMemEnd); CHECK_GT(kLowMemEnd, kLowMemStart); CHECK_GT(kLowShadowEnd, kLowShadowStart); CHECK_GT(kLowShadowStart, kLowMemEnd); if (Verbosity()) PrintAddressSpaceLayout(); // Reserve shadow memory. ReserveShadowMemoryRange(kLowShadowStart, kLowShadowEnd, "low shadow"); ReserveShadowMemoryRange(kHighShadowStart, kHighShadowEnd, "high shadow"); // Protect all the gaps. ProtectGap(0, Min(kLowMemStart, kLowShadowStart)); if (kLowMemEnd + 1 < kLowShadowStart) ProtectGap(kLowMemEnd + 1, kLowShadowStart - kLowMemEnd - 1); if (kLowShadowEnd + 1 < kHighShadowStart) ProtectGap(kLowShadowEnd + 1, kHighShadowStart - kLowShadowEnd - 1); if (kHighShadowEnd + 1 < kHighMemStart) ProtectGap(kHighShadowEnd + 1, kHighMemStart - kHighShadowEnd - 1); return true; } void InitThreads() { CHECK(__hwasan_shadow_memory_dynamic_address); uptr guard_page_size = GetMmapGranularity(); uptr thread_space_start = __hwasan_shadow_memory_dynamic_address - (1ULL << kShadowBaseAlignment); uptr thread_space_end = __hwasan_shadow_memory_dynamic_address - guard_page_size; ReserveShadowMemoryRange(thread_space_start, thread_space_end - 1, "hwasan threads", /*madvise_shadow*/ false); ProtectGap(thread_space_end, __hwasan_shadow_memory_dynamic_address - thread_space_end); InitThreadList(thread_space_start, thread_space_end - thread_space_start); hwasanThreadList().CreateCurrentThread(); } bool MemIsApp(uptr p) { // Memory outside the alias range has non-zero tags. # if !defined(HWASAN_ALIASING_MODE) CHECK(GetTagFromPointer(p) == 0); # endif return (p >= kHighMemStart && p <= kHighMemEnd) || (p >= kLowMemStart && p <= kLowMemEnd); } void InstallAtExitHandler() { atexit(HwasanAtExit); } // ---------------------- TSD ---------------- {{{1 extern "C" void __hwasan_thread_enter() { hwasanThreadList().CreateCurrentThread()->EnsureRandomStateInited(); } extern "C" void __hwasan_thread_exit() { Thread *t = GetCurrentThread(); // Make sure that signal handler can not see a stale current thread pointer. atomic_signal_fence(memory_order_seq_cst); if (t) hwasanThreadList().ReleaseThread(t); } # if HWASAN_WITH_INTERCEPTORS static pthread_key_t tsd_key; static bool tsd_key_inited = false; void HwasanTSDThreadInit() { if (tsd_key_inited) CHECK_EQ(0, pthread_setspecific(tsd_key, (void *)GetPthreadDestructorIterations())); } void HwasanTSDDtor(void *tsd) { uptr iterations = (uptr)tsd; if (iterations > 1) { CHECK_EQ(0, pthread_setspecific(tsd_key, (void *)(iterations - 1))); return; } __hwasan_thread_exit(); } void HwasanTSDInit() { CHECK(!tsd_key_inited); tsd_key_inited = true; CHECK_EQ(0, pthread_key_create(&tsd_key, HwasanTSDDtor)); } # else void HwasanTSDInit() {} void HwasanTSDThreadInit() {} # endif # if SANITIZER_ANDROID uptr *GetCurrentThreadLongPtr() { return (uptr *)get_android_tls_ptr(); } # else uptr *GetCurrentThreadLongPtr() { return &__hwasan_tls; } # endif # if SANITIZER_ANDROID void AndroidTestTlsSlot() { uptr kMagicValue = 0x010203040A0B0C0D; uptr *tls_ptr = GetCurrentThreadLongPtr(); uptr old_value = *tls_ptr; *tls_ptr = kMagicValue; dlerror(); if (*(uptr *)get_android_tls_ptr() != kMagicValue) { Printf( "ERROR: Incompatible version of Android: TLS_SLOT_SANITIZER(6) is used " "for dlerror().\n"); Die(); } *tls_ptr = old_value; } # else void AndroidTestTlsSlot() {} # endif static AccessInfo GetAccessInfo(siginfo_t *info, ucontext_t *uc) { // Access type is passed in a platform dependent way (see below) and encoded // as 0xXY, where X&1 is 1 for store, 0 for load, and X&2 is 1 if the error is // recoverable. Valid values of Y are 0 to 4, which are interpreted as // log2(access_size), and 0xF, which means that access size is passed via // platform dependent register (see below). # if defined(__aarch64__) // Access type is encoded in BRK immediate as 0x900 + 0xXY. For Y == 0xF, // access size is stored in X1 register. Access address is always in X0 // register. uptr pc = (uptr)info->si_addr; const unsigned code = ((*(u32 *)pc) >> 5) & 0xffff; if ((code & 0xff00) != 0x900) return AccessInfo{}; // Not ours. const bool is_store = code & 0x10; const bool recover = code & 0x20; const uptr addr = uc->uc_mcontext.regs[0]; const unsigned size_log = code & 0xf; if (size_log > 4 && size_log != 0xf) return AccessInfo{}; // Not ours. const uptr size = size_log == 0xf ? uc->uc_mcontext.regs[1] : 1U << size_log; # elif defined(__x86_64__) // Access type is encoded in the instruction following INT3 as // NOP DWORD ptr [EAX + 0x40 + 0xXY]. For Y == 0xF, access size is stored in // RSI register. Access address is always in RDI register. uptr pc = (uptr)uc->uc_mcontext.gregs[REG_RIP]; uint8_t *nop = (uint8_t *)pc; if (*nop != 0x0f || *(nop + 1) != 0x1f || *(nop + 2) != 0x40 || *(nop + 3) < 0x40) return AccessInfo{}; // Not ours. const unsigned code = *(nop + 3); const bool is_store = code & 0x10; const bool recover = code & 0x20; const uptr addr = uc->uc_mcontext.gregs[REG_RDI]; const unsigned size_log = code & 0xf; if (size_log > 4 && size_log != 0xf) return AccessInfo{}; // Not ours. const uptr size = size_log == 0xf ? uc->uc_mcontext.gregs[REG_RSI] : 1U << size_log; # else # error Unsupported architecture # endif return AccessInfo{addr, size, is_store, !is_store, recover}; } static bool HwasanOnSIGTRAP(int signo, siginfo_t *info, ucontext_t *uc) { AccessInfo ai = GetAccessInfo(info, uc); if (!ai.is_store && !ai.is_load) return false; SignalContext sig{info, uc}; HandleTagMismatch(ai, StackTrace::GetNextInstructionPc(sig.pc), sig.bp, uc); # if defined(__aarch64__) uc->uc_mcontext.pc += 4; # elif defined(__x86_64__) # else # error Unsupported architecture # endif return true; } static void OnStackUnwind(const SignalContext &sig, const void *, BufferedStackTrace *stack) { stack->Unwind(StackTrace::GetNextInstructionPc(sig.pc), sig.bp, sig.context, common_flags()->fast_unwind_on_fatal); } void HwasanOnDeadlySignal(int signo, void *info, void *context) { // Probably a tag mismatch. if (signo == SIGTRAP) if (HwasanOnSIGTRAP(signo, (siginfo_t *)info, (ucontext_t *)context)) return; HandleDeadlySignal(info, context, GetTid(), &OnStackUnwind, nullptr); } void Thread::InitStackAndTls(const InitState *) { uptr tls_size; uptr stack_size; GetThreadStackAndTls(IsMainThread(), &stack_bottom_, &stack_size, &tls_begin_, &tls_size); stack_top_ = stack_bottom_ + stack_size; tls_end_ = tls_begin_ + tls_size; } uptr TagMemoryAligned(uptr p, uptr size, tag_t tag) { CHECK(IsAligned(p, kShadowAlignment)); CHECK(IsAligned(size, kShadowAlignment)); uptr shadow_start = MemToShadow(p); uptr shadow_size = MemToShadowSize(size); uptr page_size = GetPageSizeCached(); uptr page_start = RoundUpTo(shadow_start, page_size); uptr page_end = RoundDownTo(shadow_start + shadow_size, page_size); uptr threshold = common_flags()->clear_shadow_mmap_threshold; if (SANITIZER_LINUX && UNLIKELY(page_end >= page_start + threshold && tag == 0)) { internal_memset((void *)shadow_start, tag, page_start - shadow_start); internal_memset((void *)page_end, tag, shadow_start + shadow_size - page_end); // For an anonymous private mapping MADV_DONTNEED will return a zero page on // Linux. ReleaseMemoryPagesToOSAndZeroFill(page_start, page_end); } else { internal_memset((void *)shadow_start, tag, shadow_size); } return AddTagToPointer(p, tag); } void HwasanInstallAtForkHandler() { auto before = []() { HwasanAllocatorLock(); StackDepotLockAll(); }; auto after = []() { StackDepotUnlockAll(); HwasanAllocatorUnlock(); }; pthread_atfork(before, after, after); } } // namespace __hwasan #endif // SANITIZER_FREEBSD || SANITIZER_LINUX || SANITIZER_NETBSD