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android_system_core/libunwindstack/Unwinder.cpp
Ryan Prichard 9b8f545920 libunwindstack: Support signal frame CIEs. 
Mark a CIE with a S in its augmentation string as signal frame.
This allows the code to properly handle signal frame data if none
of the signal frame pattern matchers work.

For a signal frame, DwarfSectionImpl<AddressType>::Eval needs to
continue the unwinding even if PC is zero. A zero PC means that the
program has crashed, and we should try to recover the real PC using the
return address on the stack or LR. This behavior is tested by
UnwindOffline.signal_{x86,x86_64}, which modify the libc.so files
so that the signal frame pattern matcher fails and the CIE/FDE
data is used instead.

Test: libunwindstack_test
Change-Id: I4655b070028fd984345311a5e743796f8c30ed36
2020-10-02 16:34:14 -07:00

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/*
* Copyright (C) 2017 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#define _GNU_SOURCE 1
#include <elf.h>
#include <inttypes.h>
#include <stdint.h>
#include <string.h>
#include <sys/types.h>
#include <unistd.h>
#include <algorithm>
#include <android-base/stringprintf.h>
#include <android-base/strings.h>
#include <unwindstack/DexFiles.h>
#include <unwindstack/Elf.h>
#include <unwindstack/JitDebug.h>
#include <unwindstack/MapInfo.h>
#include <unwindstack/Maps.h>
#include <unwindstack/Memory.h>
#include <unwindstack/Unwinder.h>
#include "Check.h"
// Use the demangler from libc++.
extern "C" char* __cxa_demangle(const char*, char*, size_t*, int* status);
namespace unwindstack {
// Inject extra 'virtual' frame that represents the dex pc data.
// The dex pc is a magic register defined in the Mterp interpreter,
// and thus it will be restored/observed in the frame after it.
// Adding the dex frame first here will create something like:
// #7 pc 0015fa20 core.vdex java.util.Arrays.binarySearch+8
// #8 pc 006b1ba1 libartd.so ExecuteMterpImpl+14625
// #9 pc 0039a1ef libartd.so art::interpreter::Execute+719
void Unwinder::FillInDexFrame() {
size_t frame_num = frames_.size();
frames_.resize(frame_num + 1);
FrameData* frame = &frames_.at(frame_num);
frame->num = frame_num;
uint64_t dex_pc = regs_->dex_pc();
frame->pc = dex_pc;
frame->sp = regs_->sp();
MapInfo* info = maps_->Find(dex_pc);
if (info != nullptr) {
frame->map_start = info->start;
frame->map_end = info->end;
// Since this is a dex file frame, the elf_start_offset is not set
// by any of the normal code paths. Use the offset of the map since
// that matches the actual offset.
frame->map_elf_start_offset = info->offset;
frame->map_exact_offset = info->offset;
frame->map_load_bias = info->load_bias;
frame->map_flags = info->flags;
if (resolve_names_) {
frame->map_name = info->name;
}
frame->rel_pc = dex_pc - info->start;
} else {
frame->rel_pc = dex_pc;
warnings_ |= WARNING_DEX_PC_NOT_IN_MAP;
return;
}
if (!resolve_names_) {
return;
}
#if defined(DEXFILE_SUPPORT)
if (dex_files_ == nullptr) {
return;
}
dex_files_->GetMethodInformation(maps_, info, dex_pc, &frame->function_name,
&frame->function_offset);
#endif
}
FrameData* Unwinder::FillInFrame(MapInfo* map_info, Elf* elf, uint64_t rel_pc,
uint64_t pc_adjustment) {
size_t frame_num = frames_.size();
frames_.resize(frame_num + 1);
FrameData* frame = &frames_.at(frame_num);
frame->num = frame_num;
frame->sp = regs_->sp();
frame->rel_pc = rel_pc - pc_adjustment;
frame->pc = regs_->pc() - pc_adjustment;
if (map_info == nullptr) {
// Nothing else to update.
return nullptr;
}
if (resolve_names_) {
frame->map_name = map_info->name;
if (embedded_soname_ && map_info->elf_start_offset != 0 && !frame->map_name.empty()) {
std::string soname = elf->GetSoname();
if (!soname.empty()) {
frame->map_name += '!' + soname;
}
}
}
frame->map_elf_start_offset = map_info->elf_start_offset;
frame->map_exact_offset = map_info->offset;
frame->map_start = map_info->start;
frame->map_end = map_info->end;
frame->map_flags = map_info->flags;
frame->map_load_bias = elf->GetLoadBias();
return frame;
}
static bool ShouldStop(const std::vector<std::string>* map_suffixes_to_ignore,
std::string& map_name) {
if (map_suffixes_to_ignore == nullptr) {
return false;
}
auto pos = map_name.find_last_of('.');
if (pos == std::string::npos) {
return false;
}
return std::find(map_suffixes_to_ignore->begin(), map_suffixes_to_ignore->end(),
map_name.substr(pos + 1)) != map_suffixes_to_ignore->end();
}
void Unwinder::Unwind(const std::vector<std::string>* initial_map_names_to_skip,
const std::vector<std::string>* map_suffixes_to_ignore) {
CHECK(arch_ != ARCH_UNKNOWN);
ClearErrors();
frames_.clear();
elf_from_memory_not_file_ = false;
bool return_address_attempt = false;
bool adjust_pc = false;
for (; frames_.size() < max_frames_;) {
uint64_t cur_pc = regs_->pc();
uint64_t cur_sp = regs_->sp();
MapInfo* map_info = maps_->Find(regs_->pc());
uint64_t pc_adjustment = 0;
uint64_t step_pc;
uint64_t rel_pc;
Elf* elf;
if (map_info == nullptr) {
step_pc = regs_->pc();
rel_pc = step_pc;
last_error_.code = ERROR_INVALID_MAP;
} else {
if (ShouldStop(map_suffixes_to_ignore, map_info->name)) {
break;
}
elf = map_info->GetElf(process_memory_, arch_);
// If this elf is memory backed, and there is a valid file, then set
// an indicator that we couldn't open the file.
if (!elf_from_memory_not_file_ && map_info->memory_backed_elf && !map_info->name.empty() &&
map_info->name[0] != '[' && !android::base::StartsWith(map_info->name, "/memfd:")) {
elf_from_memory_not_file_ = true;
}
step_pc = regs_->pc();
rel_pc = elf->GetRelPc(step_pc, map_info);
// Everyone except elf data in gdb jit debug maps uses the relative pc.
if (!(map_info->flags & MAPS_FLAGS_JIT_SYMFILE_MAP)) {
step_pc = rel_pc;
}
if (adjust_pc) {
pc_adjustment = GetPcAdjustment(rel_pc, elf, arch_);
} else {
pc_adjustment = 0;
}
step_pc -= pc_adjustment;
// If the pc is in an invalid elf file, try and get an Elf object
// using the jit debug information.
if (!elf->valid() && jit_debug_ != nullptr) {
uint64_t adjusted_jit_pc = regs_->pc() - pc_adjustment;
Elf* jit_elf = jit_debug_->GetElf(maps_, adjusted_jit_pc);
if (jit_elf != nullptr) {
// The jit debug information requires a non relative adjusted pc.
step_pc = adjusted_jit_pc;
elf = jit_elf;
}
}
}
FrameData* frame = nullptr;
if (map_info == nullptr || initial_map_names_to_skip == nullptr ||
std::find(initial_map_names_to_skip->begin(), initial_map_names_to_skip->end(),
basename(map_info->name.c_str())) == initial_map_names_to_skip->end()) {
if (regs_->dex_pc() != 0) {
// Add a frame to represent the dex file.
FillInDexFrame();
// Clear the dex pc so that we don't repeat this frame later.
regs_->set_dex_pc(0);
// Make sure there is enough room for the real frame.
if (frames_.size() == max_frames_) {
last_error_.code = ERROR_MAX_FRAMES_EXCEEDED;
break;
}
}
frame = FillInFrame(map_info, elf, rel_pc, pc_adjustment);
// Once a frame is added, stop skipping frames.
initial_map_names_to_skip = nullptr;
}
adjust_pc = true;
bool stepped = false;
bool in_device_map = false;
bool finished = false;
if (map_info != nullptr) {
if (map_info->flags & MAPS_FLAGS_DEVICE_MAP) {
// Do not stop here, fall through in case we are
// in the speculative unwind path and need to remove
// some of the speculative frames.
in_device_map = true;
} else {
MapInfo* sp_info = maps_->Find(regs_->sp());
if (sp_info != nullptr && sp_info->flags & MAPS_FLAGS_DEVICE_MAP) {
// Do not stop here, fall through in case we are
// in the speculative unwind path and need to remove
// some of the speculative frames.
in_device_map = true;
} else {
bool is_signal_frame = false;
if (elf->StepIfSignalHandler(rel_pc, regs_, process_memory_.get())) {
stepped = true;
is_signal_frame = true;
} else if (elf->Step(step_pc, regs_, process_memory_.get(), &finished,
&is_signal_frame)) {
stepped = true;
}
if (is_signal_frame && frame != nullptr) {
// Need to adjust the relative pc because the signal handler
// pc should not be adjusted.
frame->rel_pc = rel_pc;
frame->pc += pc_adjustment;
step_pc = rel_pc;
}
elf->GetLastError(&last_error_);
}
}
}
if (frame != nullptr) {
if (!resolve_names_ ||
!elf->GetFunctionName(step_pc, &frame->function_name, &frame->function_offset)) {
frame->function_name = "";
frame->function_offset = 0;
}
}
if (finished) {
break;
}
if (!stepped) {
if (return_address_attempt) {
// Only remove the speculative frame if there are more than two frames
// or the pc in the first frame is in a valid map.
// This allows for a case where the code jumps into the middle of
// nowhere, but there is no other unwind information after that.
if (frames_.size() > 2 || (frames_.size() > 0 && maps_->Find(frames_[0].pc) != nullptr)) {
// Remove the speculative frame.
frames_.pop_back();
}
break;
} else if (in_device_map) {
// Do not attempt any other unwinding, pc or sp is in a device
// map.
break;
} else {
// Steping didn't work, try this secondary method.
if (!regs_->SetPcFromReturnAddress(process_memory_.get())) {
break;
}
return_address_attempt = true;
}
} else {
return_address_attempt = false;
if (max_frames_ == frames_.size()) {
last_error_.code = ERROR_MAX_FRAMES_EXCEEDED;
}
}
// If the pc and sp didn't change, then consider everything stopped.
if (cur_pc == regs_->pc() && cur_sp == regs_->sp()) {
last_error_.code = ERROR_REPEATED_FRAME;
break;
}
}
}
std::string Unwinder::FormatFrame(const FrameData& frame) const {
std::string data;
if (ArchIs32Bit(arch_)) {
data += android::base::StringPrintf(" #%02zu pc %08" PRIx64, frame.num, frame.rel_pc);
} else {
data += android::base::StringPrintf(" #%02zu pc %016" PRIx64, frame.num, frame.rel_pc);
}
if (frame.map_start == frame.map_end) {
// No valid map associated with this frame.
data += " <unknown>";
} else if (!frame.map_name.empty()) {
data += " " + frame.map_name;
} else {
data += android::base::StringPrintf(" <anonymous:%" PRIx64 ">", frame.map_start);
}
if (frame.map_elf_start_offset != 0) {
data += android::base::StringPrintf(" (offset 0x%" PRIx64 ")", frame.map_elf_start_offset);
}
if (!frame.function_name.empty()) {
char* demangled_name = __cxa_demangle(frame.function_name.c_str(), nullptr, nullptr, nullptr);
if (demangled_name == nullptr) {
data += " (" + frame.function_name;
} else {
data += " (";
data += demangled_name;
free(demangled_name);
}
if (frame.function_offset != 0) {
data += android::base::StringPrintf("+%" PRId64, frame.function_offset);
}
data += ')';
}
MapInfo* map_info = maps_->Find(frame.map_start);
if (map_info != nullptr && display_build_id_) {
std::string build_id = map_info->GetPrintableBuildID();
if (!build_id.empty()) {
data += " (BuildId: " + build_id + ')';
}
}
return data;
}
std::string Unwinder::FormatFrame(size_t frame_num) const {
if (frame_num >= frames_.size()) {
return "";
}
return FormatFrame(frames_[frame_num]);
}
void Unwinder::SetJitDebug(JitDebug* jit_debug) {
CHECK(arch_ != ARCH_UNKNOWN);
jit_debug->SetArch(arch_);
jit_debug_ = jit_debug;
}
void Unwinder::SetDexFiles(DexFiles* dex_files) {
CHECK(arch_ != ARCH_UNKNOWN);
dex_files->SetArch(arch_);
dex_files_ = dex_files;
}
bool UnwinderFromPid::Init() {
CHECK(arch_ != ARCH_UNKNOWN);
if (initted_) {
return true;
}
initted_ = true;
if (pid_ == getpid()) {
maps_ptr_.reset(new LocalMaps());
} else {
maps_ptr_.reset(new RemoteMaps(pid_));
}
if (!maps_ptr_->Parse()) {
ClearErrors();
last_error_.code = ERROR_INVALID_MAP;
return false;
}
maps_ = maps_ptr_.get();
process_memory_ = Memory::CreateProcessMemoryCached(pid_);
jit_debug_ptr_.reset(new JitDebug(process_memory_));
jit_debug_ = jit_debug_ptr_.get();
SetJitDebug(jit_debug_);
#if defined(DEXFILE_SUPPORT)
dex_files_ptr_.reset(new DexFiles(process_memory_));
dex_files_ = dex_files_ptr_.get();
SetDexFiles(dex_files_);
#endif
return true;
}
void UnwinderFromPid::Unwind(const std::vector<std::string>* initial_map_names_to_skip,
const std::vector<std::string>* map_suffixes_to_ignore) {
if (!Init()) {
return;
}
Unwinder::Unwind(initial_map_names_to_skip, map_suffixes_to_ignore);
}
FrameData Unwinder::BuildFrameFromPcOnly(uint64_t pc, ArchEnum arch, Maps* maps,
JitDebug* jit_debug,
std::shared_ptr<Memory> process_memory,
bool resolve_names) {
FrameData frame;
MapInfo* map_info = maps->Find(pc);
if (map_info == nullptr || arch == ARCH_UNKNOWN) {
frame.pc = pc;
frame.rel_pc = pc;
return frame;
}
Elf* elf = map_info->GetElf(process_memory, arch);
uint64_t relative_pc = elf->GetRelPc(pc, map_info);
uint64_t pc_adjustment = GetPcAdjustment(relative_pc, elf, arch);
relative_pc -= pc_adjustment;
// The debug PC may be different if the PC comes from the JIT.
uint64_t debug_pc = relative_pc;
// If we don't have a valid ELF file, check the JIT.
if (!elf->valid() && jit_debug != nullptr) {
uint64_t jit_pc = pc - pc_adjustment;
Elf* jit_elf = jit_debug->GetElf(maps, jit_pc);
if (jit_elf != nullptr) {
debug_pc = jit_pc;
elf = jit_elf;
}
}
// Copy all the things we need into the frame for symbolization.
frame.rel_pc = relative_pc;
frame.pc = pc - pc_adjustment;
frame.map_name = map_info->name;
frame.map_elf_start_offset = map_info->elf_start_offset;
frame.map_exact_offset = map_info->offset;
frame.map_start = map_info->start;
frame.map_end = map_info->end;
frame.map_flags = map_info->flags;
frame.map_load_bias = elf->GetLoadBias();
if (!resolve_names ||
!elf->GetFunctionName(debug_pc, &frame.function_name, &frame.function_offset)) {
frame.function_name = "";
frame.function_offset = 0;
}
return frame;
}
FrameData Unwinder::BuildFrameFromPcOnly(uint64_t pc) {
return BuildFrameFromPcOnly(pc, arch_, maps_, jit_debug_, process_memory_, resolve_names_);
}
} // namespace unwindstack
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