A short granule is a granule of size between 1 and `TG-1` bytes. The size of a short granule is stored at the location in shadow memory where the granule's tag is normally stored, while the granule's actual tag is stored in the last byte of the granule. This means that in order to verify that a pointer tag matches a memory tag, HWASAN must check for two possibilities: * the pointer tag is equal to the memory tag in shadow memory, or * the shadow memory tag is actually a short granule size, the value being loaded is in bounds of the granule and the pointer tag is equal to the last byte of the granule. Pointer tags between 1 to `TG-1` are possible and are as likely as any other tag. This means that these tags in memory have two interpretations: the full tag interpretation (where the pointer tag is between 1 and `TG-1` and the last byte of the granule is ordinary data) and the short tag interpretation (where the pointer tag is stored in the granule). When HWASAN detects an error near a memory tag between 1 and `TG-1`, it will show both the memory tag and the last byte of the granule. Currently, it is up to the user to disambiguate the two possibilities. Because this functionality obsoletes the right aligned heap feature of the HWASAN memory allocator (and because we can no longer easily test it), the feature is removed. Also update the documentation to cover both short granule tags and outlined checks. Differential Revision: https://reviews.llvm.org/D63908 llvm-svn: 365551
548 lines
20 KiB
C++
548 lines
20 KiB
C++
//===-- hwasan_report.cpp -------------------------------------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file is a part of HWAddressSanitizer.
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//
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// Error reporting.
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//===----------------------------------------------------------------------===//
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#include "hwasan.h"
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#include "hwasan_allocator.h"
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#include "hwasan_mapping.h"
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#include "hwasan_report.h"
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#include "hwasan_thread.h"
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#include "hwasan_thread_list.h"
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#include "sanitizer_common/sanitizer_allocator_internal.h"
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#include "sanitizer_common/sanitizer_common.h"
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#include "sanitizer_common/sanitizer_flags.h"
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#include "sanitizer_common/sanitizer_mutex.h"
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#include "sanitizer_common/sanitizer_report_decorator.h"
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#include "sanitizer_common/sanitizer_stackdepot.h"
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#include "sanitizer_common/sanitizer_stacktrace_printer.h"
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#include "sanitizer_common/sanitizer_symbolizer.h"
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using namespace __sanitizer;
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namespace __hwasan {
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class ScopedReport {
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public:
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ScopedReport(bool fatal = false) : error_message_(1), fatal(fatal) {
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BlockingMutexLock lock(&error_message_lock_);
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error_message_ptr_ = fatal ? &error_message_ : nullptr;
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++hwasan_report_count;
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}
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~ScopedReport() {
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{
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BlockingMutexLock lock(&error_message_lock_);
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if (fatal)
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SetAbortMessage(error_message_.data());
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error_message_ptr_ = nullptr;
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}
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if (common_flags()->print_module_map >= 2 ||
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(fatal && common_flags()->print_module_map))
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DumpProcessMap();
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if (fatal)
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Die();
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}
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static void MaybeAppendToErrorMessage(const char *msg) {
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BlockingMutexLock lock(&error_message_lock_);
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if (!error_message_ptr_)
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return;
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uptr len = internal_strlen(msg);
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uptr old_size = error_message_ptr_->size();
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error_message_ptr_->resize(old_size + len);
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// overwrite old trailing '\0', keep new trailing '\0' untouched.
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internal_memcpy(&(*error_message_ptr_)[old_size - 1], msg, len);
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}
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private:
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ScopedErrorReportLock error_report_lock_;
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InternalMmapVector<char> error_message_;
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bool fatal;
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static InternalMmapVector<char> *error_message_ptr_;
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static BlockingMutex error_message_lock_;
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};
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InternalMmapVector<char> *ScopedReport::error_message_ptr_;
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BlockingMutex ScopedReport::error_message_lock_;
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// If there is an active ScopedReport, append to its error message.
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void AppendToErrorMessageBuffer(const char *buffer) {
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ScopedReport::MaybeAppendToErrorMessage(buffer);
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}
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static StackTrace GetStackTraceFromId(u32 id) {
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CHECK(id);
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StackTrace res = StackDepotGet(id);
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CHECK(res.trace);
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return res;
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}
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// A RAII object that holds a copy of the current thread stack ring buffer.
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// The actual stack buffer may change while we are iterating over it (for
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// example, Printf may call syslog() which can itself be built with hwasan).
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class SavedStackAllocations {
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public:
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SavedStackAllocations(StackAllocationsRingBuffer *rb) {
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uptr size = rb->size() * sizeof(uptr);
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void *storage =
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MmapAlignedOrDieOnFatalError(size, size * 2, "saved stack allocations");
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new (&rb_) StackAllocationsRingBuffer(*rb, storage);
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}
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~SavedStackAllocations() {
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StackAllocationsRingBuffer *rb = get();
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UnmapOrDie(rb->StartOfStorage(), rb->size() * sizeof(uptr));
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}
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StackAllocationsRingBuffer *get() {
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return (StackAllocationsRingBuffer *)&rb_;
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}
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private:
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uptr rb_;
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};
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class Decorator: public __sanitizer::SanitizerCommonDecorator {
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public:
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Decorator() : SanitizerCommonDecorator() { }
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const char *Access() { return Blue(); }
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const char *Allocation() const { return Magenta(); }
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const char *Origin() const { return Magenta(); }
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const char *Name() const { return Green(); }
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const char *Location() { return Green(); }
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const char *Thread() { return Green(); }
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};
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// Returns the index of the rb element that matches tagged_addr (plus one),
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// or zero if found nothing.
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uptr FindHeapAllocation(HeapAllocationsRingBuffer *rb,
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uptr tagged_addr,
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HeapAllocationRecord *har) {
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if (!rb) return 0;
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for (uptr i = 0, size = rb->size(); i < size; i++) {
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auto h = (*rb)[i];
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if (h.tagged_addr <= tagged_addr &&
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h.tagged_addr + h.requested_size > tagged_addr) {
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*har = h;
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return i + 1;
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}
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}
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return 0;
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}
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static void PrintStackAllocations(StackAllocationsRingBuffer *sa,
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tag_t addr_tag, uptr untagged_addr) {
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uptr frames = Min((uptr)flags()->stack_history_size, sa->size());
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bool found_local = false;
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for (uptr i = 0; i < frames; i++) {
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const uptr *record_addr = &(*sa)[i];
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uptr record = *record_addr;
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if (!record)
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break;
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tag_t base_tag =
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reinterpret_cast<uptr>(record_addr) >> kRecordAddrBaseTagShift;
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uptr fp = (record >> kRecordFPShift) << kRecordFPLShift;
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uptr pc_mask = (1ULL << kRecordFPShift) - 1;
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uptr pc = record & pc_mask;
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FrameInfo frame;
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if (Symbolizer::GetOrInit()->SymbolizeFrame(pc, &frame)) {
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for (LocalInfo &local : frame.locals) {
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if (!local.has_frame_offset || !local.has_size || !local.has_tag_offset)
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continue;
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tag_t obj_tag = base_tag ^ local.tag_offset;
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if (obj_tag != addr_tag)
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continue;
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// Calculate the offset from the object address to the faulting
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// address. Because we only store bits 4-19 of FP (bits 0-3 are
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// guaranteed to be zero), the calculation is performed mod 2^20 and may
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// harmlessly underflow if the address mod 2^20 is below the object
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// address.
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uptr obj_offset =
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(untagged_addr - fp - local.frame_offset) & (kRecordFPModulus - 1);
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if (obj_offset >= local.size)
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continue;
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if (!found_local) {
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Printf("Potentially referenced stack objects:\n");
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found_local = true;
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}
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Printf(" %s in %s %s:%d\n", local.name, local.function_name,
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local.decl_file, local.decl_line);
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}
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frame.Clear();
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}
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}
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if (found_local)
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return;
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// We didn't find any locals. Most likely we don't have symbols, so dump
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// the information that we have for offline analysis.
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InternalScopedString frame_desc(GetPageSizeCached() * 2);
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Printf("Previously allocated frames:\n");
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for (uptr i = 0; i < frames; i++) {
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const uptr *record_addr = &(*sa)[i];
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uptr record = *record_addr;
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if (!record)
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break;
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uptr pc_mask = (1ULL << 48) - 1;
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uptr pc = record & pc_mask;
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frame_desc.append(" record_addr:0x%zx record:0x%zx",
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reinterpret_cast<uptr>(record_addr), record);
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if (SymbolizedStack *frame = Symbolizer::GetOrInit()->SymbolizePC(pc)) {
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RenderFrame(&frame_desc, " %F %L\n", 0, frame->info,
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common_flags()->symbolize_vs_style,
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common_flags()->strip_path_prefix);
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frame->ClearAll();
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}
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Printf("%s", frame_desc.data());
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frame_desc.clear();
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}
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}
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// Returns true if tag == *tag_ptr, reading tags from short granules if
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// necessary. This may return a false positive if tags 1-15 are used as a
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// regular tag rather than a short granule marker.
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static bool TagsEqual(tag_t tag, tag_t *tag_ptr) {
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if (tag == *tag_ptr)
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return true;
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if (*tag_ptr == 0 || *tag_ptr > kShadowAlignment - 1)
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return false;
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uptr mem = ShadowToMem(reinterpret_cast<uptr>(tag_ptr));
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tag_t inline_tag = *reinterpret_cast<tag_t *>(mem + kShadowAlignment - 1);
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return tag == inline_tag;
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}
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void PrintAddressDescription(
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uptr tagged_addr, uptr access_size,
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StackAllocationsRingBuffer *current_stack_allocations) {
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Decorator d;
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int num_descriptions_printed = 0;
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uptr untagged_addr = UntagAddr(tagged_addr);
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// Print some very basic information about the address, if it's a heap.
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HwasanChunkView chunk = FindHeapChunkByAddress(untagged_addr);
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if (uptr beg = chunk.Beg()) {
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uptr size = chunk.ActualSize();
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Printf("%s[%p,%p) is a %s %s heap chunk; "
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"size: %zd offset: %zd\n%s",
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d.Location(),
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beg, beg + size,
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chunk.FromSmallHeap() ? "small" : "large",
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chunk.IsAllocated() ? "allocated" : "unallocated",
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size, untagged_addr - beg,
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d.Default());
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}
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// Check if this looks like a heap buffer overflow by scanning
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// the shadow left and right and looking for the first adjacent
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// object with a different memory tag. If that tag matches addr_tag,
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// check the allocator if it has a live chunk there.
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tag_t addr_tag = GetTagFromPointer(tagged_addr);
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tag_t *tag_ptr = reinterpret_cast<tag_t*>(MemToShadow(untagged_addr));
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tag_t *candidate = nullptr, *left = tag_ptr, *right = tag_ptr;
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for (int i = 0; i < 1000; i++) {
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if (TagsEqual(addr_tag, left)) {
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candidate = left;
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break;
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}
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--left;
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if (TagsEqual(addr_tag, right)) {
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candidate = right;
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break;
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}
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++right;
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}
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if (candidate) {
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uptr mem = ShadowToMem(reinterpret_cast<uptr>(candidate));
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HwasanChunkView chunk = FindHeapChunkByAddress(mem);
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if (chunk.IsAllocated()) {
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Printf("%s", d.Location());
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Printf("%p is located %zd bytes to the %s of %zd-byte region [%p,%p)\n",
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untagged_addr,
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candidate == left ? untagged_addr - chunk.End()
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: chunk.Beg() - untagged_addr,
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candidate == left ? "right" : "left", chunk.UsedSize(),
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chunk.Beg(), chunk.End());
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Printf("%s", d.Allocation());
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Printf("allocated here:\n");
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Printf("%s", d.Default());
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GetStackTraceFromId(chunk.GetAllocStackId()).Print();
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num_descriptions_printed++;
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}
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}
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hwasanThreadList().VisitAllLiveThreads([&](Thread *t) {
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// Scan all threads' ring buffers to find if it's a heap-use-after-free.
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HeapAllocationRecord har;
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if (uptr D = FindHeapAllocation(t->heap_allocations(), tagged_addr, &har)) {
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Printf("%s", d.Location());
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Printf("%p is located %zd bytes inside of %zd-byte region [%p,%p)\n",
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untagged_addr, untagged_addr - UntagAddr(har.tagged_addr),
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har.requested_size, UntagAddr(har.tagged_addr),
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UntagAddr(har.tagged_addr) + har.requested_size);
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Printf("%s", d.Allocation());
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Printf("freed by thread T%zd here:\n", t->unique_id());
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Printf("%s", d.Default());
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GetStackTraceFromId(har.free_context_id).Print();
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Printf("%s", d.Allocation());
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Printf("previously allocated here:\n", t);
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Printf("%s", d.Default());
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GetStackTraceFromId(har.alloc_context_id).Print();
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// Print a developer note: the index of this heap object
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// in the thread's deallocation ring buffer.
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Printf("hwasan_dev_note_heap_rb_distance: %zd %zd\n", D,
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flags()->heap_history_size);
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t->Announce();
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num_descriptions_printed++;
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}
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// Very basic check for stack memory.
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if (t->AddrIsInStack(untagged_addr)) {
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Printf("%s", d.Location());
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Printf("Address %p is located in stack of thread T%zd\n", untagged_addr,
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t->unique_id());
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Printf("%s", d.Default());
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t->Announce();
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auto *sa = (t == GetCurrentThread() && current_stack_allocations)
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? current_stack_allocations
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: t->stack_allocations();
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PrintStackAllocations(sa, addr_tag, untagged_addr);
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num_descriptions_printed++;
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}
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});
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// Print the remaining threads, as an extra information, 1 line per thread.
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hwasanThreadList().VisitAllLiveThreads([&](Thread *t) { t->Announce(); });
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if (!num_descriptions_printed)
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// We exhausted our possibilities. Bail out.
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Printf("HWAddressSanitizer can not describe address in more detail.\n");
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}
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void ReportStats() {}
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static void PrintTagInfoAroundAddr(tag_t *tag_ptr, uptr num_rows,
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void (*print_tag)(InternalScopedString &s,
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tag_t *tag)) {
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const uptr row_len = 16; // better be power of two.
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tag_t *center_row_beg = reinterpret_cast<tag_t *>(
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RoundDownTo(reinterpret_cast<uptr>(tag_ptr), row_len));
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tag_t *beg_row = center_row_beg - row_len * (num_rows / 2);
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tag_t *end_row = center_row_beg + row_len * ((num_rows + 1) / 2);
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InternalScopedString s(GetPageSizeCached() * 8);
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for (tag_t *row = beg_row; row < end_row; row += row_len) {
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s.append("%s", row == center_row_beg ? "=>" : " ");
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for (uptr i = 0; i < row_len; i++) {
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s.append("%s", row + i == tag_ptr ? "[" : " ");
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print_tag(s, &row[i]);
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s.append("%s", row + i == tag_ptr ? "]" : " ");
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}
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s.append("%s\n", row == center_row_beg ? "<=" : " ");
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}
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Printf("%s", s.data());
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}
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static void PrintTagsAroundAddr(tag_t *tag_ptr) {
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Printf(
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"Memory tags around the buggy address (one tag corresponds to %zd "
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"bytes):\n", kShadowAlignment);
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PrintTagInfoAroundAddr(tag_ptr, 17, [](InternalScopedString &s, tag_t *tag) {
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s.append("%02x", *tag);
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});
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Printf(
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"Tags for short granules around the buggy address (one tag corresponds "
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"to %zd bytes):\n",
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kShadowAlignment);
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PrintTagInfoAroundAddr(tag_ptr, 3, [](InternalScopedString &s, tag_t *tag) {
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if (*tag >= 1 && *tag <= kShadowAlignment) {
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uptr granule_addr = ShadowToMem(reinterpret_cast<uptr>(tag));
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s.append("%02x",
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*reinterpret_cast<u8 *>(granule_addr + kShadowAlignment - 1));
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} else {
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s.append("..");
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}
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});
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Printf(
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"See "
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"https://clang.llvm.org/docs/"
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"HardwareAssistedAddressSanitizerDesign.html#short-granules for a "
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"description of short granule tags\n");
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}
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void ReportInvalidFree(StackTrace *stack, uptr tagged_addr) {
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ScopedReport R(flags()->halt_on_error);
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uptr untagged_addr = UntagAddr(tagged_addr);
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tag_t ptr_tag = GetTagFromPointer(tagged_addr);
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tag_t *tag_ptr = reinterpret_cast<tag_t*>(MemToShadow(untagged_addr));
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tag_t mem_tag = *tag_ptr;
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Decorator d;
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Printf("%s", d.Error());
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uptr pc = stack->size ? stack->trace[0] : 0;
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const char *bug_type = "invalid-free";
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Report("ERROR: %s: %s on address %p at pc %p\n", SanitizerToolName, bug_type,
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untagged_addr, pc);
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Printf("%s", d.Access());
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Printf("tags: %02x/%02x (ptr/mem)\n", ptr_tag, mem_tag);
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Printf("%s", d.Default());
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stack->Print();
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PrintAddressDescription(tagged_addr, 0, nullptr);
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PrintTagsAroundAddr(tag_ptr);
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ReportErrorSummary(bug_type, stack);
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}
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void ReportTailOverwritten(StackTrace *stack, uptr tagged_addr, uptr orig_size,
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const u8 *expected) {
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uptr tail_size = kShadowAlignment - (orig_size % kShadowAlignment);
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ScopedReport R(flags()->halt_on_error);
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Decorator d;
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uptr untagged_addr = UntagAddr(tagged_addr);
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Printf("%s", d.Error());
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const char *bug_type = "alocation-tail-overwritten";
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Report("ERROR: %s: %s; heap object [%p,%p) of size %zd\n", SanitizerToolName,
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bug_type, untagged_addr, untagged_addr + orig_size, orig_size);
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Printf("\n%s", d.Default());
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stack->Print();
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HwasanChunkView chunk = FindHeapChunkByAddress(untagged_addr);
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if (chunk.Beg()) {
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Printf("%s", d.Allocation());
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Printf("allocated here:\n");
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Printf("%s", d.Default());
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GetStackTraceFromId(chunk.GetAllocStackId()).Print();
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}
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InternalScopedString s(GetPageSizeCached() * 8);
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CHECK_GT(tail_size, 0U);
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CHECK_LT(tail_size, kShadowAlignment);
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u8 *tail = reinterpret_cast<u8*>(untagged_addr + orig_size);
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s.append("Tail contains: ");
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for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
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s.append(".. ");
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for (uptr i = 0; i < tail_size; i++)
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s.append("%02x ", tail[i]);
|
|
s.append("\n");
|
|
s.append("Expected: ");
|
|
for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
|
|
s.append(".. ");
|
|
for (uptr i = 0; i < tail_size; i++)
|
|
s.append("%02x ", expected[i]);
|
|
s.append("\n");
|
|
s.append(" ");
|
|
for (uptr i = 0; i < kShadowAlignment - tail_size; i++)
|
|
s.append(" ");
|
|
for (uptr i = 0; i < tail_size; i++)
|
|
s.append("%s ", expected[i] != tail[i] ? "^^" : " ");
|
|
|
|
s.append("\nThis error occurs when a buffer overflow overwrites memory\n"
|
|
"to the right of a heap object, but within the %zd-byte granule, e.g.\n"
|
|
" char *x = new char[20];\n"
|
|
" x[25] = 42;\n"
|
|
"%s does not detect such bugs in uninstrumented code at the time of write,"
|
|
"\nbut can detect them at the time of free/delete.\n"
|
|
"To disable this feature set HWASAN_OPTIONS=free_checks_tail_magic=0\n",
|
|
kShadowAlignment, SanitizerToolName);
|
|
Printf("%s", s.data());
|
|
GetCurrentThread()->Announce();
|
|
|
|
tag_t *tag_ptr = reinterpret_cast<tag_t*>(MemToShadow(untagged_addr));
|
|
PrintTagsAroundAddr(tag_ptr);
|
|
|
|
ReportErrorSummary(bug_type, stack);
|
|
}
|
|
|
|
void ReportTagMismatch(StackTrace *stack, uptr tagged_addr, uptr access_size,
|
|
bool is_store, bool fatal, uptr *registers_frame) {
|
|
ScopedReport R(fatal);
|
|
SavedStackAllocations current_stack_allocations(
|
|
GetCurrentThread()->stack_allocations());
|
|
|
|
Decorator d;
|
|
Printf("%s", d.Error());
|
|
uptr untagged_addr = UntagAddr(tagged_addr);
|
|
// TODO: when possible, try to print heap-use-after-free, etc.
|
|
const char *bug_type = "tag-mismatch";
|
|
uptr pc = stack->size ? stack->trace[0] : 0;
|
|
Report("ERROR: %s: %s on address %p at pc %p\n", SanitizerToolName, bug_type,
|
|
untagged_addr, pc);
|
|
|
|
Thread *t = GetCurrentThread();
|
|
|
|
sptr offset =
|
|
__hwasan_test_shadow(reinterpret_cast<void *>(tagged_addr), access_size);
|
|
CHECK(offset >= 0 && offset < static_cast<sptr>(access_size));
|
|
tag_t ptr_tag = GetTagFromPointer(tagged_addr);
|
|
tag_t *tag_ptr =
|
|
reinterpret_cast<tag_t *>(MemToShadow(untagged_addr + offset));
|
|
tag_t mem_tag = *tag_ptr;
|
|
|
|
Printf("%s", d.Access());
|
|
Printf("%s of size %zu at %p tags: %02x/%02x (ptr/mem) in thread T%zd\n",
|
|
is_store ? "WRITE" : "READ", access_size, untagged_addr, ptr_tag,
|
|
mem_tag, t->unique_id());
|
|
if (offset != 0)
|
|
Printf("Invalid access starting at offset [%zu, %zu)\n", offset,
|
|
Min(access_size, static_cast<uptr>(offset) + (1 << kShadowScale)));
|
|
Printf("%s", d.Default());
|
|
|
|
stack->Print();
|
|
|
|
PrintAddressDescription(tagged_addr, access_size,
|
|
current_stack_allocations.get());
|
|
t->Announce();
|
|
|
|
PrintTagsAroundAddr(tag_ptr);
|
|
|
|
if (registers_frame)
|
|
ReportRegisters(registers_frame, pc);
|
|
|
|
ReportErrorSummary(bug_type, stack);
|
|
}
|
|
|
|
// See the frame breakdown defined in __hwasan_tag_mismatch (from
|
|
// hwasan_tag_mismatch_aarch64.S).
|
|
void ReportRegisters(uptr *frame, uptr pc) {
|
|
Printf("Registers where the failure occurred (pc %p):\n", pc);
|
|
|
|
// We explicitly print a single line (4 registers/line) each iteration to
|
|
// reduce the amount of logcat error messages printed. Each Printf() will
|
|
// result in a new logcat line, irrespective of whether a newline is present,
|
|
// and so we wish to reduce the number of Printf() calls we have to make.
|
|
Printf(" x0 %016llx x1 %016llx x2 %016llx x3 %016llx\n",
|
|
frame[0], frame[1], frame[2], frame[3]);
|
|
Printf(" x4 %016llx x5 %016llx x6 %016llx x7 %016llx\n",
|
|
frame[4], frame[5], frame[6], frame[7]);
|
|
Printf(" x8 %016llx x9 %016llx x10 %016llx x11 %016llx\n",
|
|
frame[8], frame[9], frame[10], frame[11]);
|
|
Printf(" x12 %016llx x13 %016llx x14 %016llx x15 %016llx\n",
|
|
frame[12], frame[13], frame[14], frame[15]);
|
|
Printf(" x16 %016llx x17 %016llx x18 %016llx x19 %016llx\n",
|
|
frame[16], frame[17], frame[18], frame[19]);
|
|
Printf(" x20 %016llx x21 %016llx x22 %016llx x23 %016llx\n",
|
|
frame[20], frame[21], frame[22], frame[23]);
|
|
Printf(" x24 %016llx x25 %016llx x26 %016llx x27 %016llx\n",
|
|
frame[24], frame[25], frame[26], frame[27]);
|
|
Printf(" x28 %016llx x29 %016llx x30 %016llx\n",
|
|
frame[28], frame[29], frame[30]);
|
|
}
|
|
|
|
} // namespace __hwasan
|