Mercurial > hg > CbC > CbC_gcc
view libsanitizer/asan/asan_errors.cpp @ 145:1830386684a0
gcc-9.2.0
| author | anatofuz |
|---|---|
| date | Thu, 13 Feb 2020 11:34:05 +0900 |
| parents | |
| children |
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//===-- asan_errors.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 // //===----------------------------------------------------------------------===// // // This file is a part of AddressSanitizer, an address sanity checker. // // ASan implementation for error structures. //===----------------------------------------------------------------------===// #include "asan_errors.h" #include "asan_descriptions.h" #include "asan_mapping.h" #include "asan_report.h" #include "asan_stack.h" #include "sanitizer_common/sanitizer_stackdepot.h" namespace __asan { static void OnStackUnwind(const SignalContext &sig, const void *callback_context, BufferedStackTrace *stack) { bool fast = common_flags()->fast_unwind_on_fatal; #if SANITIZER_FREEBSD || SANITIZER_NETBSD // On FreeBSD the slow unwinding that leverages _Unwind_Backtrace() // yields the call stack of the signal's handler and not of the code // that raised the signal (as it does on Linux). fast = true; #endif // Tests and maybe some users expect that scariness is going to be printed // just before the stack. As only asan has scariness score we have no // corresponding code in the sanitizer_common and we use this callback to // print it. static_cast<const ScarinessScoreBase *>(callback_context)->Print(); stack->Unwind(StackTrace::GetNextInstructionPc(sig.pc), sig.bp, sig.context, fast); } void ErrorDeadlySignal::Print() { ReportDeadlySignal(signal, tid, &OnStackUnwind, &scariness); } void ErrorDoubleFree::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: attempting %s on %p in thread %s:\n", scariness.GetDescription(), addr_description.addr, AsanThreadIdAndName(tid).c_str()); Printf("%s", d.Default()); scariness.Print(); GET_STACK_TRACE_FATAL(second_free_stack->trace[0], second_free_stack->top_frame_bp); stack.Print(); addr_description.Print(); ReportErrorSummary(scariness.GetDescription(), &stack); } void ErrorNewDeleteTypeMismatch::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: %s on %p in thread %s:\n", scariness.GetDescription(), addr_description.addr, AsanThreadIdAndName(tid).c_str()); Printf("%s object passed to delete has wrong type:\n", d.Default()); if (delete_size != 0) { Printf( " size of the allocated type: %zd bytes;\n" " size of the deallocated type: %zd bytes.\n", addr_description.chunk_access.chunk_size, delete_size); } const uptr user_alignment = addr_description.chunk_access.user_requested_alignment; if (delete_alignment != user_alignment) { char user_alignment_str[32]; char delete_alignment_str[32]; internal_snprintf(user_alignment_str, sizeof(user_alignment_str), "%zd bytes", user_alignment); internal_snprintf(delete_alignment_str, sizeof(delete_alignment_str), "%zd bytes", delete_alignment); static const char *kDefaultAlignment = "default-aligned"; Printf( " alignment of the allocated type: %s;\n" " alignment of the deallocated type: %s.\n", user_alignment > 0 ? user_alignment_str : kDefaultAlignment, delete_alignment > 0 ? delete_alignment_str : kDefaultAlignment); } CHECK_GT(free_stack->size, 0); scariness.Print(); GET_STACK_TRACE_FATAL(free_stack->trace[0], free_stack->top_frame_bp); stack.Print(); addr_description.Print(); ReportErrorSummary(scariness.GetDescription(), &stack); Report( "HINT: if you don't care about these errors you may set " "ASAN_OPTIONS=new_delete_type_mismatch=0\n"); } void ErrorFreeNotMalloced::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: attempting free on address " "which was not malloc()-ed: %p in thread %s\n", addr_description.Address(), AsanThreadIdAndName(tid).c_str()); Printf("%s", d.Default()); CHECK_GT(free_stack->size, 0); scariness.Print(); GET_STACK_TRACE_FATAL(free_stack->trace[0], free_stack->top_frame_bp); stack.Print(); addr_description.Print(); ReportErrorSummary(scariness.GetDescription(), &stack); } void ErrorAllocTypeMismatch::Print() { static const char *alloc_names[] = {"INVALID", "malloc", "operator new", "operator new []"}; static const char *dealloc_names[] = {"INVALID", "free", "operator delete", "operator delete []"}; CHECK_NE(alloc_type, dealloc_type); Decorator d; Printf("%s", d.Error()); Report("ERROR: AddressSanitizer: %s (%s vs %s) on %p\n", scariness.GetDescription(), alloc_names[alloc_type], dealloc_names[dealloc_type], addr_description.Address()); Printf("%s", d.Default()); CHECK_GT(dealloc_stack->size, 0); scariness.Print(); GET_STACK_TRACE_FATAL(dealloc_stack->trace[0], dealloc_stack->top_frame_bp); stack.Print(); addr_description.Print(); ReportErrorSummary(scariness.GetDescription(), &stack); Report( "HINT: if you don't care about these errors you may set " "ASAN_OPTIONS=alloc_dealloc_mismatch=0\n"); } void ErrorMallocUsableSizeNotOwned::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: attempting to call malloc_usable_size() for " "pointer which is not owned: %p\n", addr_description.Address()); Printf("%s", d.Default()); stack->Print(); addr_description.Print(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorSanitizerGetAllocatedSizeNotOwned::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: attempting to call " "__sanitizer_get_allocated_size() for pointer which is not owned: %p\n", addr_description.Address()); Printf("%s", d.Default()); stack->Print(); addr_description.Print(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorCallocOverflow::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: calloc parameters overflow: count * size " "(%zd * %zd) cannot be represented in type size_t (thread %s)\n", count, size, AsanThreadIdAndName(tid).c_str()); Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorReallocArrayOverflow::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: reallocarray parameters overflow: count * size " "(%zd * %zd) cannot be represented in type size_t (thread %s)\n", count, size, AsanThreadIdAndName(tid).c_str()); Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorPvallocOverflow::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: pvalloc parameters overflow: size 0x%zx " "rounded up to system page size 0x%zx cannot be represented in type " "size_t (thread %s)\n", size, GetPageSizeCached(), AsanThreadIdAndName(tid).c_str()); Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorInvalidAllocationAlignment::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: invalid allocation alignment: %zd, " "alignment must be a power of two (thread %s)\n", alignment, AsanThreadIdAndName(tid).c_str()); Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorInvalidAlignedAllocAlignment::Print() { Decorator d; Printf("%s", d.Error()); #if SANITIZER_POSIX Report("ERROR: AddressSanitizer: invalid alignment requested in " "aligned_alloc: %zd, alignment must be a power of two and the " "requested size 0x%zx must be a multiple of alignment " "(thread %s)\n", alignment, size, AsanThreadIdAndName(tid).c_str()); #else Report("ERROR: AddressSanitizer: invalid alignment requested in " "aligned_alloc: %zd, the requested size 0x%zx must be a multiple of " "alignment (thread %s)\n", alignment, size, AsanThreadIdAndName(tid).c_str()); #endif Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorInvalidPosixMemalignAlignment::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: invalid alignment requested in posix_memalign: " "%zd, alignment must be a power of two and a multiple of sizeof(void*) " "== %zd (thread %s)\n", alignment, sizeof(void *), AsanThreadIdAndName(tid).c_str()); Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorAllocationSizeTooBig::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: requested allocation size 0x%zx (0x%zx after " "adjustments for alignment, red zones etc.) exceeds maximum supported " "size of 0x%zx (thread %s)\n", user_size, total_size, max_size, AsanThreadIdAndName(tid).c_str()); Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorRssLimitExceeded::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: specified RSS limit exceeded, currently set to " "soft_rss_limit_mb=%zd\n", common_flags()->soft_rss_limit_mb); Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorOutOfMemory::Print() { Decorator d; Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: allocator is out of memory trying to allocate " "0x%zx bytes\n", requested_size); Printf("%s", d.Default()); stack->Print(); PrintHintAllocatorCannotReturnNull(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorStringFunctionMemoryRangesOverlap::Print() { Decorator d; char bug_type[100]; internal_snprintf(bug_type, sizeof(bug_type), "%s-param-overlap", function); Printf("%s", d.Error()); Report( "ERROR: AddressSanitizer: %s: memory ranges [%p,%p) and [%p, %p) " "overlap\n", bug_type, addr1_description.Address(), addr1_description.Address() + length1, addr2_description.Address(), addr2_description.Address() + length2); Printf("%s", d.Default()); scariness.Print(); stack->Print(); addr1_description.Print(); addr2_description.Print(); ReportErrorSummary(bug_type, stack); } void ErrorStringFunctionSizeOverflow::Print() { Decorator d; Printf("%s", d.Error()); Report("ERROR: AddressSanitizer: %s: (size=%zd)\n", scariness.GetDescription(), size); Printf("%s", d.Default()); scariness.Print(); stack->Print(); addr_description.Print(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorBadParamsToAnnotateContiguousContainer::Print() { Report( "ERROR: AddressSanitizer: bad parameters to " "__sanitizer_annotate_contiguous_container:\n" " beg : %p\n" " end : %p\n" " old_mid : %p\n" " new_mid : %p\n", beg, end, old_mid, new_mid); uptr granularity = SHADOW_GRANULARITY; if (!IsAligned(beg, granularity)) Report("ERROR: beg is not aligned by %d\n", granularity); stack->Print(); ReportErrorSummary(scariness.GetDescription(), stack); } void ErrorODRViolation::Print() { Decorator d; Printf("%s", d.Error()); Report("ERROR: AddressSanitizer: %s (%p):\n", scariness.GetDescription(), global1.beg); Printf("%s", d.Default()); InternalScopedString g1_loc(256), g2_loc(256); PrintGlobalLocation(&g1_loc, global1); PrintGlobalLocation(&g2_loc, global2); Printf(" [1] size=%zd '%s' %s\n", global1.size, MaybeDemangleGlobalName(global1.name), g1_loc.data()); Printf(" [2] size=%zd '%s' %s\n", global2.size, MaybeDemangleGlobalName(global2.name), g2_loc.data()); if (stack_id1 && stack_id2) { Printf("These globals were registered at these points:\n"); Printf(" [1]:\n"); StackDepotGet(stack_id1).Print(); Printf(" [2]:\n"); StackDepotGet(stack_id2).Print(); } Report( "HINT: if you don't care about these errors you may set " "ASAN_OPTIONS=detect_odr_violation=0\n"); InternalScopedString error_msg(256); error_msg.append("%s: global '%s' at %s", scariness.GetDescription(), MaybeDemangleGlobalName(global1.name), g1_loc.data()); ReportErrorSummary(error_msg.data()); } void ErrorInvalidPointerPair::Print() { Decorator d; Printf("%s", d.Error()); Report("ERROR: AddressSanitizer: %s: %p %p\n", scariness.GetDescription(), addr1_description.Address(), addr2_description.Address()); Printf("%s", d.Default()); GET_STACK_TRACE_FATAL(pc, bp); stack.Print(); addr1_description.Print(); addr2_description.Print(); ReportErrorSummary(scariness.GetDescription(), &stack); } static bool AdjacentShadowValuesAreFullyPoisoned(u8 *s) { return s[-1] > 127 && s[1] > 127; } ErrorGeneric::ErrorGeneric(u32 tid, uptr pc_, uptr bp_, uptr sp_, uptr addr, bool is_write_, uptr access_size_) : ErrorBase(tid), addr_description(addr, access_size_, /*shouldLockThreadRegistry=*/false), pc(pc_), bp(bp_), sp(sp_), access_size(access_size_), is_write(is_write_), shadow_val(0) { scariness.Clear(); if (access_size) { if (access_size <= 9) { char desr[] = "?-byte"; desr[0] = '0' + access_size; scariness.Scare(access_size + access_size / 2, desr); } else if (access_size >= 10) { scariness.Scare(15, "multi-byte"); } is_write ? scariness.Scare(20, "write") : scariness.Scare(1, "read"); // Determine the error type. bug_descr = "unknown-crash"; if (AddrIsInMem(addr)) { u8 *shadow_addr = (u8 *)MemToShadow(addr); // If we are accessing 16 bytes, look at the second shadow byte. if (*shadow_addr == 0 && access_size > SHADOW_GRANULARITY) shadow_addr++; // If we are in the partial right redzone, look at the next shadow byte. if (*shadow_addr > 0 && *shadow_addr < 128) shadow_addr++; bool far_from_bounds = false; shadow_val = *shadow_addr; int bug_type_score = 0; // For use-after-frees reads are almost as bad as writes. int read_after_free_bonus = 0; switch (shadow_val) { case kAsanHeapLeftRedzoneMagic: case kAsanArrayCookieMagic: bug_descr = "heap-buffer-overflow"; bug_type_score = 10; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; case kAsanHeapFreeMagic: bug_descr = "heap-use-after-free"; bug_type_score = 20; if (!is_write) read_after_free_bonus = 18; break; case kAsanStackLeftRedzoneMagic: bug_descr = "stack-buffer-underflow"; bug_type_score = 25; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; case kAsanInitializationOrderMagic: bug_descr = "initialization-order-fiasco"; bug_type_score = 1; break; case kAsanStackMidRedzoneMagic: case kAsanStackRightRedzoneMagic: bug_descr = "stack-buffer-overflow"; bug_type_score = 25; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; case kAsanStackAfterReturnMagic: bug_descr = "stack-use-after-return"; bug_type_score = 30; if (!is_write) read_after_free_bonus = 18; break; case kAsanUserPoisonedMemoryMagic: bug_descr = "use-after-poison"; bug_type_score = 20; break; case kAsanContiguousContainerOOBMagic: bug_descr = "container-overflow"; bug_type_score = 10; break; case kAsanStackUseAfterScopeMagic: bug_descr = "stack-use-after-scope"; bug_type_score = 10; break; case kAsanGlobalRedzoneMagic: bug_descr = "global-buffer-overflow"; bug_type_score = 10; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; case kAsanIntraObjectRedzone: bug_descr = "intra-object-overflow"; bug_type_score = 10; break; case kAsanAllocaLeftMagic: case kAsanAllocaRightMagic: bug_descr = "dynamic-stack-buffer-overflow"; bug_type_score = 25; far_from_bounds = AdjacentShadowValuesAreFullyPoisoned(shadow_addr); break; } scariness.Scare(bug_type_score + read_after_free_bonus, bug_descr); if (far_from_bounds) scariness.Scare(10, "far-from-bounds"); } } } static void PrintContainerOverflowHint() { Printf("HINT: if you don't care about these errors you may set " "ASAN_OPTIONS=detect_container_overflow=0.\n" "If you suspect a false positive see also: " "https://github.com/google/sanitizers/wiki/" "AddressSanitizerContainerOverflow.\n"); } static void PrintShadowByte(InternalScopedString *str, const char *before, u8 byte, const char *after = "\n") { PrintMemoryByte(str, before, byte, /*in_shadow*/true, after); } static void PrintLegend(InternalScopedString *str) { str->append( "Shadow byte legend (one shadow byte represents %d " "application bytes):\n", (int)SHADOW_GRANULARITY); PrintShadowByte(str, " Addressable: ", 0); str->append(" Partially addressable: "); for (u8 i = 1; i < SHADOW_GRANULARITY; i++) PrintShadowByte(str, "", i, " "); str->append("\n"); PrintShadowByte(str, " Heap left redzone: ", kAsanHeapLeftRedzoneMagic); PrintShadowByte(str, " Freed heap region: ", kAsanHeapFreeMagic); PrintShadowByte(str, " Stack left redzone: ", kAsanStackLeftRedzoneMagic); PrintShadowByte(str, " Stack mid redzone: ", kAsanStackMidRedzoneMagic); PrintShadowByte(str, " Stack right redzone: ", kAsanStackRightRedzoneMagic); PrintShadowByte(str, " Stack after return: ", kAsanStackAfterReturnMagic); PrintShadowByte(str, " Stack use after scope: ", kAsanStackUseAfterScopeMagic); PrintShadowByte(str, " Global redzone: ", kAsanGlobalRedzoneMagic); PrintShadowByte(str, " Global init order: ", kAsanInitializationOrderMagic); PrintShadowByte(str, " Poisoned by user: ", kAsanUserPoisonedMemoryMagic); PrintShadowByte(str, " Container overflow: ", kAsanContiguousContainerOOBMagic); PrintShadowByte(str, " Array cookie: ", kAsanArrayCookieMagic); PrintShadowByte(str, " Intra object redzone: ", kAsanIntraObjectRedzone); PrintShadowByte(str, " ASan internal: ", kAsanInternalHeapMagic); PrintShadowByte(str, " Left alloca redzone: ", kAsanAllocaLeftMagic); PrintShadowByte(str, " Right alloca redzone: ", kAsanAllocaRightMagic); PrintShadowByte(str, " Shadow gap: ", kAsanShadowGap); } static void PrintShadowBytes(InternalScopedString *str, const char *before, u8 *bytes, u8 *guilty, uptr n) { Decorator d; if (before) str->append("%s%p:", before, bytes); for (uptr i = 0; i < n; i++) { u8 *p = bytes + i; const char *before = p == guilty ? "[" : (p - 1 == guilty && i != 0) ? "" : " "; const char *after = p == guilty ? "]" : ""; PrintShadowByte(str, before, *p, after); } str->append("\n"); } static void PrintShadowMemoryForAddress(uptr addr) { if (!AddrIsInMem(addr)) return; uptr shadow_addr = MemToShadow(addr); const uptr n_bytes_per_row = 16; uptr aligned_shadow = shadow_addr & ~(n_bytes_per_row - 1); InternalScopedString str(4096 * 8); str.append("Shadow bytes around the buggy address:\n"); for (int i = -5; i <= 5; i++) { uptr row_shadow_addr = aligned_shadow + i * n_bytes_per_row; // Skip rows that would be outside the shadow range. This can happen when // the user address is near the bottom, top, or shadow gap of the address // space. if (!AddrIsInShadow(row_shadow_addr)) continue; const char *prefix = (i == 0) ? "=>" : " "; PrintShadowBytes(&str, prefix, (u8 *)row_shadow_addr, (u8 *)shadow_addr, n_bytes_per_row); } if (flags()->print_legend) PrintLegend(&str); Printf("%s", str.data()); } void ErrorGeneric::Print() { Decorator d; Printf("%s", d.Error()); uptr addr = addr_description.Address(); Report("ERROR: AddressSanitizer: %s on address %p at pc %p bp %p sp %p\n", bug_descr, (void *)addr, pc, bp, sp); Printf("%s", d.Default()); Printf("%s%s of size %zu at %p thread %s%s\n", d.Access(), access_size ? (is_write ? "WRITE" : "READ") : "ACCESS", access_size, (void *)addr, AsanThreadIdAndName(tid).c_str(), d.Default()); scariness.Print(); GET_STACK_TRACE_FATAL(pc, bp); stack.Print(); // Pass bug_descr because we have a special case for // initialization-order-fiasco addr_description.Print(bug_descr); if (shadow_val == kAsanContiguousContainerOOBMagic) PrintContainerOverflowHint(); ReportErrorSummary(bug_descr, &stack); PrintShadowMemoryForAddress(addr); } } // namespace __asan