platform_system_core/libunwindstack/ArmExidx.cpp
Christopher Ferris 2fcf4cf13e Add error propagation into Unwinder/Elf objects.
The backtrace offline code uses these error codes to diagnose errors.
In addtion, I've had cases where seeing these errors would help diagnose
failures.

This also allows us to add a few features to indicate why an unwind
terminated (such as max frames exceeded).

Bug: 65682279

Test: Updated unit tests pass.
Change-Id: If82b5092698e8a194016d670efff1320f9b44d50
2018-01-24 17:50:46 -08:00

699 lines
17 KiB
C++

/*
* Copyright (C) 2016 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.
*/
#include <stdint.h>
#include <deque>
#include <string>
#include <android-base/stringprintf.h>
#include <unwindstack/Log.h>
#include <unwindstack/Memory.h>
#include <unwindstack/RegsArm.h>
#include "ArmExidx.h"
#include "Check.h"
#include "MachineArm.h"
namespace unwindstack {
void ArmExidx::LogRawData() {
std::string log_str("Raw Data:");
for (const uint8_t data : data_) {
log_str += android::base::StringPrintf(" 0x%02x", data);
}
log(log_indent_, log_str.c_str());
}
bool ArmExidx::ExtractEntryData(uint32_t entry_offset) {
data_.clear();
status_ = ARM_STATUS_NONE;
if (entry_offset & 1) {
// The offset needs to be at least two byte aligned.
status_ = ARM_STATUS_INVALID_ALIGNMENT;
return false;
}
// Each entry is a 32 bit prel31 offset followed by 32 bits
// of unwind information. If bit 31 of the unwind data is zero,
// then this is a prel31 offset to the start of the unwind data.
// If the unwind data is 1, then this is a cant unwind entry.
// Otherwise, this data is the compact form of the unwind information.
uint32_t data;
if (!elf_memory_->Read32(entry_offset + 4, &data)) {
status_ = ARM_STATUS_READ_FAILED;
status_address_ = entry_offset + 4;
return false;
}
if (data == 1) {
// This is a CANT UNWIND entry.
status_ = ARM_STATUS_NO_UNWIND;
if (log_) {
log(log_indent_, "Raw Data: 0x00 0x00 0x00 0x01");
log(log_indent_, "[cantunwind]");
}
return false;
}
if (data & (1UL << 31)) {
// This is a compact table entry.
if ((data >> 24) & 0xf) {
// This is a non-zero index, this code doesn't support
// other formats.
status_ = ARM_STATUS_INVALID_PERSONALITY;
return false;
}
data_.push_back((data >> 16) & 0xff);
data_.push_back((data >> 8) & 0xff);
uint8_t last_op = data & 0xff;
data_.push_back(last_op);
if (last_op != ARM_OP_FINISH) {
// If this didn't end with a finish op, add one.
data_.push_back(ARM_OP_FINISH);
}
if (log_) {
LogRawData();
}
return true;
}
// Get the address of the ops.
// Sign extend the data value if necessary.
int32_t signed_data = static_cast<int32_t>(data << 1) >> 1;
uint32_t addr = (entry_offset + 4) + signed_data;
if (!elf_memory_->Read32(addr, &data)) {
status_ = ARM_STATUS_READ_FAILED;
status_address_ = addr;
return false;
}
size_t num_table_words;
if (data & (1UL << 31)) {
// Compact model.
switch ((data >> 24) & 0xf) {
case 0:
num_table_words = 0;
data_.push_back((data >> 16) & 0xff);
break;
case 1:
case 2:
num_table_words = (data >> 16) & 0xff;
addr += 4;
break;
default:
// Only a personality of 0, 1, 2 is valid.
status_ = ARM_STATUS_INVALID_PERSONALITY;
return false;
}
data_.push_back((data >> 8) & 0xff);
data_.push_back(data & 0xff);
} else {
// Generic model.
// Skip the personality routine data, it doesn't contain any data
// needed to decode the unwind information.
addr += 4;
if (!elf_memory_->Read32(addr, &data)) {
status_ = ARM_STATUS_READ_FAILED;
status_address_ = addr;
return false;
}
num_table_words = (data >> 24) & 0xff;
data_.push_back((data >> 16) & 0xff);
data_.push_back((data >> 8) & 0xff);
data_.push_back(data & 0xff);
addr += 4;
}
if (num_table_words > 5) {
status_ = ARM_STATUS_MALFORMED;
return false;
}
for (size_t i = 0; i < num_table_words; i++) {
if (!elf_memory_->Read32(addr, &data)) {
status_ = ARM_STATUS_READ_FAILED;
status_address_ = addr;
return false;
}
data_.push_back((data >> 24) & 0xff);
data_.push_back((data >> 16) & 0xff);
data_.push_back((data >> 8) & 0xff);
data_.push_back(data & 0xff);
addr += 4;
}
if (data_.back() != ARM_OP_FINISH) {
// If this didn't end with a finish op, add one.
data_.push_back(ARM_OP_FINISH);
}
if (log_) {
LogRawData();
}
return true;
}
inline bool ArmExidx::GetByte(uint8_t* byte) {
if (data_.empty()) {
status_ = ARM_STATUS_TRUNCATED;
return false;
}
*byte = data_.front();
data_.pop_front();
return true;
}
inline bool ArmExidx::DecodePrefix_10_00(uint8_t byte) {
CHECK((byte >> 4) == 0x8);
uint16_t registers = (byte & 0xf) << 8;
if (!GetByte(&byte)) {
return false;
}
registers |= byte;
if (registers == 0) {
// 10000000 00000000: Refuse to unwind
if (log_) {
log(log_indent_, "Refuse to unwind");
}
status_ = ARM_STATUS_NO_UNWIND;
return false;
}
// 1000iiii iiiiiiii: Pop up to 12 integer registers under masks {r15-r12}, {r11-r4}
if (log_) {
bool add_comma = false;
std::string msg = "pop {";
for (size_t i = 0; i < 12; i++) {
if (registers & (1 << i)) {
if (add_comma) {
msg += ", ";
}
msg += android::base::StringPrintf("r%zu", i + 4);
add_comma = true;
}
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
registers <<= 4;
for (size_t reg = 4; reg < 16; reg++) {
if (registers & (1 << reg)) {
if (!process_memory_->Read32(cfa_, &(*regs_)[reg])) {
status_ = ARM_STATUS_READ_FAILED;
status_address_ = cfa_;
return false;
}
cfa_ += 4;
}
}
// If the sp register is modified, change the cfa value.
if (registers & (1 << ARM_REG_SP)) {
cfa_ = (*regs_)[ARM_REG_SP];
}
// Indicate if the pc register was set.
if (registers & (1 << ARM_REG_PC)) {
pc_set_ = true;
}
return true;
}
inline bool ArmExidx::DecodePrefix_10_01(uint8_t byte) {
CHECK((byte >> 4) == 0x9);
uint8_t bits = byte & 0xf;
if (bits == 13 || bits == 15) {
// 10011101: Reserved as prefix for ARM register to register moves
// 10011111: Reserved as prefix for Intel Wireless MMX register to register moves
if (log_) {
log(log_indent_, "[Reserved]");
}
status_ = ARM_STATUS_RESERVED;
return false;
}
// 1001nnnn: Set vsp = r[nnnn] (nnnn != 13, 15)
if (log_) {
log(log_indent_, "vsp = r%d", bits);
if (log_skip_execution_) {
return true;
}
}
// It is impossible for bits to be larger than the total number of
// arm registers, so don't bother checking if bits is a valid register.
cfa_ = (*regs_)[bits];
return true;
}
inline bool ArmExidx::DecodePrefix_10_10(uint8_t byte) {
CHECK((byte >> 4) == 0xa);
// 10100nnn: Pop r4-r[4+nnn]
// 10101nnn: Pop r4-r[4+nnn], r14
if (log_) {
std::string msg = "pop {r4";
uint8_t end_reg = byte & 0x7;
if (end_reg) {
msg += android::base::StringPrintf("-r%d", 4 + end_reg);
}
if (byte & 0x8) {
log(log_indent_, "%s, r14}", msg.c_str());
} else {
log(log_indent_, "%s}", msg.c_str());
}
if (log_skip_execution_) {
return true;
}
}
for (size_t i = 4; i <= 4 + (byte & 0x7); i++) {
if (!process_memory_->Read32(cfa_, &(*regs_)[i])) {
status_ = ARM_STATUS_READ_FAILED;
status_address_ = cfa_;
return false;
}
cfa_ += 4;
}
if (byte & 0x8) {
if (!process_memory_->Read32(cfa_, &(*regs_)[ARM_REG_R14])) {
status_ = ARM_STATUS_READ_FAILED;
status_address_ = cfa_;
return false;
}
cfa_ += 4;
}
return true;
}
inline bool ArmExidx::DecodePrefix_10_11_0000() {
// 10110000: Finish
if (log_) {
log(log_indent_, "finish");
if (log_skip_execution_) {
status_ = ARM_STATUS_FINISH;
return false;
}
}
status_ = ARM_STATUS_FINISH;
return false;
}
inline bool ArmExidx::DecodePrefix_10_11_0001() {
uint8_t byte;
if (!GetByte(&byte)) {
return false;
}
if (byte == 0) {
// 10110001 00000000: Spare
if (log_) {
log(log_indent_, "Spare");
}
status_ = ARM_STATUS_SPARE;
return false;
}
if (byte >> 4) {
// 10110001 xxxxyyyy: Spare (xxxx != 0000)
if (log_) {
log(log_indent_, "Spare");
}
status_ = ARM_STATUS_SPARE;
return false;
}
// 10110001 0000iiii: Pop integer registers under mask {r3, r2, r1, r0}
if (log_) {
bool add_comma = false;
std::string msg = "pop {";
for (size_t i = 0; i < 4; i++) {
if (byte & (1 << i)) {
if (add_comma) {
msg += ", ";
}
msg += android::base::StringPrintf("r%zu", i);
add_comma = true;
}
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
for (size_t reg = 0; reg < 4; reg++) {
if (byte & (1 << reg)) {
if (!process_memory_->Read32(cfa_, &(*regs_)[reg])) {
status_ = ARM_STATUS_READ_FAILED;
status_address_ = cfa_;
return false;
}
cfa_ += 4;
}
}
return true;
}
inline bool ArmExidx::DecodePrefix_10_11_0010() {
// 10110010 uleb128: vsp = vsp + 0x204 + (uleb128 << 2)
uint32_t result = 0;
uint32_t shift = 0;
uint8_t byte;
do {
if (!GetByte(&byte)) {
return false;
}
result |= (byte & 0x7f) << shift;
shift += 7;
} while (byte & 0x80);
result <<= 2;
if (log_) {
log(log_indent_, "vsp = vsp + %d", 0x204 + result);
if (log_skip_execution_) {
return true;
}
}
cfa_ += 0x204 + result;
return true;
}
inline bool ArmExidx::DecodePrefix_10_11_0011() {
// 10110011 sssscccc: Pop VFP double precision registers D[ssss]-D[ssss+cccc] by FSTMFDX
uint8_t byte;
if (!GetByte(&byte)) {
return false;
}
if (log_) {
uint8_t start_reg = byte >> 4;
std::string msg = android::base::StringPrintf("pop {d%d", start_reg);
uint8_t end_reg = start_reg + (byte & 0xf);
if (end_reg) {
msg += android::base::StringPrintf("-d%d", end_reg);
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
cfa_ += (byte & 0xf) * 8 + 12;
return true;
}
inline bool ArmExidx::DecodePrefix_10_11_01nn() {
// 101101nn: Spare
if (log_) {
log(log_indent_, "Spare");
}
status_ = ARM_STATUS_SPARE;
return false;
}
inline bool ArmExidx::DecodePrefix_10_11_1nnn(uint8_t byte) {
CHECK((byte & ~0x07) == 0xb8);
// 10111nnn: Pop VFP double-precision registers D[8]-D[8+nnn] by FSTMFDX
if (log_) {
std::string msg = "pop {d8";
uint8_t last_reg = (byte & 0x7);
if (last_reg) {
msg += android::base::StringPrintf("-d%d", last_reg + 8);
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
// Only update the cfa.
cfa_ += (byte & 0x7) * 8 + 12;
return true;
}
inline bool ArmExidx::DecodePrefix_10(uint8_t byte) {
CHECK((byte >> 6) == 0x2);
switch ((byte >> 4) & 0x3) {
case 0:
return DecodePrefix_10_00(byte);
case 1:
return DecodePrefix_10_01(byte);
case 2:
return DecodePrefix_10_10(byte);
default:
switch (byte & 0xf) {
case 0:
return DecodePrefix_10_11_0000();
case 1:
return DecodePrefix_10_11_0001();
case 2:
return DecodePrefix_10_11_0010();
case 3:
return DecodePrefix_10_11_0011();
default:
if (byte & 0x8) {
return DecodePrefix_10_11_1nnn(byte);
} else {
return DecodePrefix_10_11_01nn();
}
}
}
}
inline bool ArmExidx::DecodePrefix_11_000(uint8_t byte) {
CHECK((byte & ~0x07) == 0xc0);
uint8_t bits = byte & 0x7;
if (bits == 6) {
if (!GetByte(&byte)) {
return false;
}
// 11000110 sssscccc: Intel Wireless MMX pop wR[ssss]-wR[ssss+cccc]
if (log_) {
uint8_t start_reg = byte >> 4;
std::string msg = android::base::StringPrintf("pop {wR%d", start_reg);
uint8_t end_reg = byte & 0xf;
if (end_reg) {
msg += android::base::StringPrintf("-wR%d", start_reg + end_reg);
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
// Only update the cfa.
cfa_ += (byte & 0xf) * 8 + 8;
} else if (bits == 7) {
if (!GetByte(&byte)) {
return false;
}
if (byte == 0) {
// 11000111 00000000: Spare
if (log_) {
log(log_indent_, "Spare");
}
status_ = ARM_STATUS_SPARE;
return false;
} else if ((byte >> 4) == 0) {
// 11000111 0000iiii: Intel Wireless MMX pop wCGR registers {wCGR0,1,2,3}
if (log_) {
bool add_comma = false;
std::string msg = "pop {";
for (size_t i = 0; i < 4; i++) {
if (byte & (1 << i)) {
if (add_comma) {
msg += ", ";
}
msg += android::base::StringPrintf("wCGR%zu", i);
add_comma = true;
}
}
log(log_indent_, "%s}", msg.c_str());
}
// Only update the cfa.
cfa_ += __builtin_popcount(byte) * 4;
} else {
// 11000111 xxxxyyyy: Spare (xxxx != 0000)
if (log_) {
log(log_indent_, "Spare");
}
status_ = ARM_STATUS_SPARE;
return false;
}
} else {
// 11000nnn: Intel Wireless MMX pop wR[10]-wR[10+nnn] (nnn != 6, 7)
if (log_) {
std::string msg = "pop {wR10";
uint8_t nnn = byte & 0x7;
if (nnn) {
msg += android::base::StringPrintf("-wR%d", 10 + nnn);
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
// Only update the cfa.
cfa_ += (byte & 0x7) * 8 + 8;
}
return true;
}
inline bool ArmExidx::DecodePrefix_11_001(uint8_t byte) {
CHECK((byte & ~0x07) == 0xc8);
uint8_t bits = byte & 0x7;
if (bits == 0) {
// 11001000 sssscccc: Pop VFP double precision registers D[16+ssss]-D[16+ssss+cccc] by VPUSH
if (!GetByte(&byte)) {
return false;
}
if (log_) {
uint8_t start_reg = byte >> 4;
std::string msg = android::base::StringPrintf("pop {d%d", 16 + start_reg);
uint8_t end_reg = byte & 0xf;
if (end_reg) {
msg += android::base::StringPrintf("-d%d", 16 + start_reg + end_reg);
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
// Only update the cfa.
cfa_ += (byte & 0xf) * 8 + 8;
} else if (bits == 1) {
// 11001001 sssscccc: Pop VFP double precision registers D[ssss]-D[ssss+cccc] by VPUSH
if (!GetByte(&byte)) {
return false;
}
if (log_) {
uint8_t start_reg = byte >> 4;
std::string msg = android::base::StringPrintf("pop {d%d", start_reg);
uint8_t end_reg = byte & 0xf;
if (end_reg) {
msg += android::base::StringPrintf("-d%d", start_reg + end_reg);
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
// Only update the cfa.
cfa_ += (byte & 0xf) * 8 + 8;
} else {
// 11001yyy: Spare (yyy != 000, 001)
if (log_) {
log(log_indent_, "Spare");
}
status_ = ARM_STATUS_SPARE;
return false;
}
return true;
}
inline bool ArmExidx::DecodePrefix_11_010(uint8_t byte) {
CHECK((byte & ~0x07) == 0xd0);
// 11010nnn: Pop VFP double precision registers D[8]-D[8+nnn] by VPUSH
if (log_) {
std::string msg = "pop {d8";
uint8_t end_reg = byte & 0x7;
if (end_reg) {
msg += android::base::StringPrintf("-d%d", 8 + end_reg);
}
log(log_indent_, "%s}", msg.c_str());
if (log_skip_execution_) {
return true;
}
}
cfa_ += (byte & 0x7) * 8 + 8;
return true;
}
inline bool ArmExidx::DecodePrefix_11(uint8_t byte) {
CHECK((byte >> 6) == 0x3);
switch ((byte >> 3) & 0x7) {
case 0:
return DecodePrefix_11_000(byte);
case 1:
return DecodePrefix_11_001(byte);
case 2:
return DecodePrefix_11_010(byte);
default:
// 11xxxyyy: Spare (xxx != 000, 001, 010)
if (log_) {
log(log_indent_, "Spare");
}
status_ = ARM_STATUS_SPARE;
return false;
}
}
bool ArmExidx::Decode() {
status_ = ARM_STATUS_NONE;
uint8_t byte;
if (!GetByte(&byte)) {
return false;
}
switch (byte >> 6) {
case 0:
// 00xxxxxx: vsp = vsp + (xxxxxxx << 2) + 4
if (log_) {
log(log_indent_, "vsp = vsp + %d", ((byte & 0x3f) << 2) + 4);
if (log_skip_execution_) {
break;
}
}
cfa_ += ((byte & 0x3f) << 2) + 4;
break;
case 1:
// 01xxxxxx: vsp = vsp - (xxxxxxx << 2) + 4
if (log_) {
log(log_indent_, "vsp = vsp - %d", ((byte & 0x3f) << 2) + 4);
if (log_skip_execution_) {
break;
}
}
cfa_ -= ((byte & 0x3f) << 2) + 4;
break;
case 2:
return DecodePrefix_10(byte);
default:
return DecodePrefix_11(byte);
}
return true;
}
bool ArmExidx::Eval() {
pc_set_ = false;
while (Decode());
return status_ == ARM_STATUS_FINISH;
}
} // namespace unwindstack