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// Copyright (c) 2006, Google Inc.
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// minidump.cc: A minidump reader.
//
// See minidump.h for documentation.
//
// Author: Mark Mentovai
#include <fcntl.h>
#include <stdio.h>
#include <time.h>
#include <unistd.h>
#ifdef _WIN32
#include <io.h>
typedef SSIZE_T ssize_t;
#define open _open
#define read _read
#define lseek _lseek
#else // _WIN32
#define O_BINARY 0
#endif // _WIN32
#include <map>
#include <vector>
#include "processor/range_map-inl.h"
#include "processor/minidump.h"
#include "processor/scoped_ptr.h"
namespace google_airbag {
using std::vector;
//
// Swapping routines
//
// Inlining these doesn't increase code size significantly, and it saves
// a whole lot of unnecessary jumping back and forth.
//
// Swapping an 8-bit quantity is a no-op. This function is only provided
// to account for certain templatized operations that require swapping for
// wider types but handle u_int8_t too
// (MinidumpMemoryRegion::GetMemoryAtAddressInternal).
static inline void Swap(u_int8_t* value) {
}
// Optimization: don't need to AND the furthest right shift, because we're
// shifting an unsigned quantity. The standard requires zero-filling in this
// case. If the quantities were signed, a bitmask whould be needed for this
// right shift to avoid an arithmetic shift (which retains the sign bit).
// The furthest left shift never needs to be ANDed bitmask.
static inline void Swap(u_int16_t* value) {
*value = (*value >> 8) |
(*value << 8);
}
static inline void Swap(u_int32_t* value) {
*value = (*value >> 24) |
((*value >> 8) & 0x0000ff00) |
((*value << 8) & 0x00ff0000) |
(*value << 24);
}
static inline void Swap(u_int64_t* value) {
*value = (*value >> 56) |
((*value >> 40) & 0x000000000000ff00LL) |
((*value >> 24) & 0x0000000000ff0000LL) |
((*value >> 8) & 0x00000000ff000000LL) |
((*value << 8) & 0x000000ff00000000LL) |
((*value << 24) & 0x0000ff0000000000LL) |
((*value << 40) & 0x00ff000000000000LL) |
(*value << 56);
}
// Nontrivial, not often used, not inline. This will put *value into
// native endianness even on machines where there is no native 128-bit type.
// half[0] will be the most significant half on big-endian CPUs and half[1]
// will be the most significant half on little-endian CPUs.
static void Swap(u_int128_t* value) {
Swap(&value->half[0]);
Swap(&value->half[1]);
// Swap the two sections with one another.
u_int64_t temp = value->half[0];
value->half[0] = value->half[1];
value->half[1] = temp;
}
static inline void Swap(MDLocationDescriptor* location_descriptor) {
Swap(&location_descriptor->data_size);
Swap(&location_descriptor->rva);
}
static inline void Swap(MDMemoryDescriptor* memory_descriptor) {
Swap(&memory_descriptor->start_of_memory_range);
Swap(&memory_descriptor->memory);
}
static inline void Swap(MDGUID* guid) {
Swap(&guid->data1);
Swap(&guid->data2);
Swap(&guid->data3);
// Don't swap guid->data4[] because it contains 8-bit quantities.
}
//
// Character conversion routines
//
// Standard wide-character conversion routines depend on the system's own
// idea of what width a wide character should be: some use 16 bits, and
// some use 32 bits. For the purposes of a minidump, wide strings are
// always represented with 16-bit UTF-16 chracters. iconv isn't available
// everywhere, and its interface varies where it is available. iconv also
// deals purely with char* pointers, so in addition to considering the swap
// parameter, a converter that uses iconv would also need to take the host
// CPU's endianness into consideration. It doesn't seems worth the trouble
// of making it a dependency when we don't care about anything but UTF-16.
static string* UTF16ToUTF8(const vector<u_int16_t>& in,
bool swap) {
scoped_ptr<string> out(new string());
// Set the string's initial capacity to the number of UTF-16 characters,
// because the UTF-8 representation will always be at least this long.
// If the UTF-8 representation is longer, the string will grow dynamically.
out->reserve(in.size());
for (vector<u_int16_t>::const_iterator iterator = in.begin();
iterator != in.end();
++iterator) {
// Get a 16-bit value from the input
u_int16_t in_word = *iterator;
if (swap)
Swap(&in_word);
// Convert the input value (in_word) into a Unicode code point (unichar).
u_int32_t unichar;
if (in_word >= 0xdc00 && in_word <= 0xdcff) {
// Low surrogate not following high surrogate, fail.
return NULL;
} else if (in_word >= 0xd800 && in_word <= 0xdbff) {
// High surrogate.
unichar = (in_word - 0xd7c0) << 10;
if (++iterator == in.end()) {
// End of input
return NULL;
}
in_word = *iterator;
if (in_word < 0xdc00 || in_word > 0xdcff) {
// Expected low surrogate, found something else
return NULL;
}
unichar |= in_word & 0x03ff;
} else {
// The ordinary case, a single non-surrogate Unicode character encoded
// as a single 16-bit value.
unichar = in_word;
}
// Convert the Unicode code point (unichar) into its UTF-8 representation,
// appending it to the out string.
if (unichar < 0x80) {
(*out) += unichar;
} else if (unichar < 0x800) {
(*out) += 0xc0 | (unichar >> 6);
(*out) += 0x80 | (unichar & 0x3f);
} else if (unichar < 0x10000) {
(*out) += 0xe0 | (unichar >> 12);
(*out) += 0x80 | ((unichar >> 6) & 0x3f);
(*out) += 0x80 | (unichar & 0x3f);
} else if (unichar < 0x200000) {
(*out) += 0xf0 | (unichar >> 18);
(*out) += 0x80 | ((unichar >> 12) & 0x3f);
(*out) += 0x80 | ((unichar >> 6) & 0x3f);
(*out) += 0x80 | (unichar & 0x3f);
} else {
// Some (high) value that's not (presently) defined in UTF-8
return NULL;
}
}
return out.release();
}
//
// MinidumpObject
//
MinidumpObject::MinidumpObject(Minidump* minidump)
: minidump_(minidump),
valid_(false) {
}
//
// MinidumpStream
//
MinidumpStream::MinidumpStream(Minidump* minidump)
: MinidumpObject(minidump) {
}
//
// MinidumpContext
//
MinidumpContext::MinidumpContext(Minidump* minidump)
: MinidumpStream(minidump),
context_() {
}
MinidumpContext::~MinidumpContext() {
FreeContext();
}
bool MinidumpContext::Read(u_int32_t expected_size) {
valid_ = false;
FreeContext();
// First, figure out what type of CPU this context structure is for.
u_int32_t context_flags;
if (!minidump_->ReadBytes(&context_flags, sizeof(context_flags)))
return false;
if (minidump_->swap())
Swap(&context_flags);
u_int32_t cpu_type = context_flags & MD_CONTEXT_CPU_MASK;
// Allocate the context structure for the correct CPU and fill it. The
// casts are slightly unorthodox, but it seems better to do that than to
// maintain a separate pointer for each type of CPU context structure
// when only one of them will be used.
switch (cpu_type) {
case MD_CONTEXT_X86: {
if (expected_size != sizeof(MDRawContextX86))
return false;
scoped_ptr<MDRawContextX86> context_x86(new MDRawContextX86());
// Set the context_flags member, which has already been read, and
// read the rest of the structure beginning with the first member
// after context_flags.
context_x86->context_flags = context_flags;
size_t flags_size = sizeof(context_x86->context_flags);
u_int8_t* context_after_flags =
reinterpret_cast<u_int8_t*>(context_x86.get()) + flags_size;
if (!minidump_->ReadBytes(context_after_flags,
sizeof(MDRawContextX86) - flags_size)) {
return false;
}
// Do this after reading the entire MDRawContext structure because
// GetSystemInfo may seek minidump to a new position.
if (!CheckAgainstSystemInfo(cpu_type))
return false;
if (minidump_->swap()) {
// context_x86->context_flags was already swapped.
Swap(&context_x86->dr0);
Swap(&context_x86->dr1);
Swap(&context_x86->dr2);
Swap(&context_x86->dr3);
Swap(&context_x86->dr6);
Swap(&context_x86->dr7);
Swap(&context_x86->float_save.control_word);
Swap(&context_x86->float_save.status_word);
Swap(&context_x86->float_save.tag_word);
Swap(&context_x86->float_save.error_offset);
Swap(&context_x86->float_save.error_selector);
Swap(&context_x86->float_save.data_offset);
Swap(&context_x86->float_save.data_selector);
// context_x86->float_save.register_area[] contains 8-bit quantities
// and does not need to be swapped.
Swap(&context_x86->float_save.cr0_npx_state);
Swap(&context_x86->gs);
Swap(&context_x86->fs);
Swap(&context_x86->es);
Swap(&context_x86->ds);
Swap(&context_x86->edi);
Swap(&context_x86->esi);
Swap(&context_x86->ebx);
Swap(&context_x86->edx);
Swap(&context_x86->ecx);
Swap(&context_x86->eax);
Swap(&context_x86->ebp);
Swap(&context_x86->eip);
Swap(&context_x86->cs);
Swap(&context_x86->eflags);
Swap(&context_x86->esp);
Swap(&context_x86->ss);
// context_x86->extended_registers[] contains 8-bit quantities and
// does not need to be swapped.
}
context_.x86 = context_x86.release();
break;
}
case MD_CONTEXT_PPC: {
if (expected_size != sizeof(MDRawContextPPC))
return false;
scoped_ptr<MDRawContextPPC> context_ppc(new MDRawContextPPC());
// Set the context_flags member, which has already been read, and
// read the rest of the structure beginning with the first member
// after context_flags.
context_ppc->context_flags = context_flags;
size_t flags_size = sizeof(context_ppc->context_flags);
u_int8_t* context_after_flags =
reinterpret_cast<u_int8_t*>(context_ppc.get()) + flags_size;
if (!minidump_->ReadBytes(context_after_flags,
sizeof(MDRawContextPPC) - flags_size)) {
return false;
}
// Do this after reading the entire MDRawContext structure because
// GetSystemInfo may seek minidump to a new position.
if (!CheckAgainstSystemInfo(cpu_type))
return false;
if (minidump_->swap()) {
// context_ppc->context_flags was already swapped.
Swap(&context_ppc->srr0);
Swap(&context_ppc->srr1);
for (unsigned int gpr_index = 0;
gpr_index < MD_CONTEXT_PPC_GPR_COUNT;
++gpr_index) {
Swap(&context_ppc->gpr[gpr_index]);
}
Swap(&context_ppc->cr);
Swap(&context_ppc->xer);
Swap(&context_ppc->lr);
Swap(&context_ppc->ctr);
Swap(&context_ppc->mq);
Swap(&context_ppc->vrsave);
for (unsigned int fpr_index = 0;
fpr_index < MD_FLOATINGSAVEAREA_PPC_FPR_COUNT;
++fpr_index) {
Swap(&context_ppc->float_save.fpregs[fpr_index]);
}
// Don't swap context_ppc->float_save.fpscr_pad because it is only
// used for padding.
Swap(&context_ppc->float_save.fpscr);
for (unsigned int vr_index = 0;
vr_index < MD_VECTORSAVEAREA_PPC_VR_COUNT;
++vr_index) {
Swap(&context_ppc->vector_save.save_vr[vr_index]);
}
Swap(&context_ppc->vector_save.save_vscr);
// Don't swap the padding fields in vector_save.
Swap(&context_ppc->vector_save.save_vrvalid);
}
context_.ppc = context_ppc.release();
break;
}
default: {
// Unknown context type
return false;
break;
}
}
valid_ = true;
return true;
}
u_int32_t MinidumpContext::GetContextCPU() const {
return valid_ ? context_.base->context_flags & MD_CONTEXT_CPU_MASK : 0;
}
const MDRawContextX86* MinidumpContext::GetContextX86() const {
return GetContextCPU() == MD_CONTEXT_X86 ? context_.x86 : NULL;
}
const MDRawContextPPC* MinidumpContext::GetContextPPC() const {
return GetContextCPU() == MD_CONTEXT_PPC ? context_.ppc : NULL;
}
void MinidumpContext::FreeContext() {
switch (GetContextCPU()) {
case MD_CONTEXT_X86:
delete context_.x86;
break;
case MD_CONTEXT_PPC:
delete context_.ppc;
break;
default:
// There is no context record (valid_ is false) or there's a
// context record for an unknown CPU (shouldn't happen, only known
// records are stored by Read).
break;
}
context_.base = NULL;
}
bool MinidumpContext::CheckAgainstSystemInfo(u_int32_t context_cpu_type) {
// It's OK if the minidump doesn't contain a SYSTEM_INFO_STREAM,
// as this function just implements a sanity check.
MinidumpSystemInfo* system_info = minidump_->GetSystemInfo();
if (!system_info)
return true;
// If there is a SYSTEM_INFO_STREAM, it should contain valid system info.
const MDRawSystemInfo* raw_system_info = system_info->system_info();
if (!raw_system_info)
return false;
MDCPUArchitecture system_info_cpu_type = static_cast<MDCPUArchitecture>(
raw_system_info->processor_architecture);
// Compare the CPU type of the context record to the CPU type in the
// minidump's system info stream.
switch (context_cpu_type) {
case MD_CONTEXT_X86:
if (system_info_cpu_type != MD_CPU_ARCHITECTURE_X86 &&
system_info_cpu_type != MD_CPU_ARCHITECTURE_X86_WIN64) {
return false;
}
break;
case MD_CONTEXT_PPC:
if (system_info_cpu_type != MD_CPU_ARCHITECTURE_PPC)
return false;
break;
default:
// Unknown context_cpu_type, this should not happen.
return false;
break;
}
return true;
}
void MinidumpContext::Print() {
switch (GetContextCPU()) {
case MD_CONTEXT_X86: {
const MDRawContextX86* context_x86 = GetContextX86();
printf("MDRawContextX86\n");
printf(" context_flags = 0x%x\n",
context_x86->context_flags);
printf(" dr0 = 0x%x\n", context_x86->dr0);
printf(" dr1 = 0x%x\n", context_x86->dr1);
printf(" dr2 = 0x%x\n", context_x86->dr2);
printf(" dr3 = 0x%x\n", context_x86->dr3);
printf(" dr6 = 0x%x\n", context_x86->dr6);
printf(" dr7 = 0x%x\n", context_x86->dr7);
printf(" float_save.control_word = 0x%x\n",
context_x86->float_save.control_word);
printf(" float_save.status_word = 0x%x\n",
context_x86->float_save.status_word);
printf(" float_save.tag_word = 0x%x\n",
context_x86->float_save.tag_word);
printf(" float_save.error_offset = 0x%x\n",
context_x86->float_save.error_offset);
printf(" float_save.error_selector = 0x%x\n",
context_x86->float_save.error_selector);
printf(" float_save.data_offset = 0x%x\n",
context_x86->float_save.data_offset);
printf(" float_save.data_selector = 0x%x\n",
context_x86->float_save.data_selector);
printf(" float_save.register_area[%2d] = 0x",
MD_FLOATINGSAVEAREA_X86_REGISTERAREA_SIZE);
for (unsigned int register_index = 0;
register_index < MD_FLOATINGSAVEAREA_X86_REGISTERAREA_SIZE;
++register_index) {
printf("%02x", context_x86->float_save.register_area[register_index]);
}
printf("\n");
printf(" float_save.cr0_npx_state = 0x%x\n",
context_x86->float_save.cr0_npx_state);
printf(" gs = 0x%x\n", context_x86->gs);
printf(" fs = 0x%x\n", context_x86->fs);
printf(" es = 0x%x\n", context_x86->es);
printf(" ds = 0x%x\n", context_x86->ds);
printf(" edi = 0x%x\n", context_x86->edi);
printf(" esi = 0x%x\n", context_x86->esi);
printf(" ebx = 0x%x\n", context_x86->ebx);
printf(" edx = 0x%x\n", context_x86->edx);
printf(" ecx = 0x%x\n", context_x86->ecx);
printf(" eax = 0x%x\n", context_x86->eax);
printf(" ebp = 0x%x\n", context_x86->ebp);
printf(" eip = 0x%x\n", context_x86->eip);
printf(" cs = 0x%x\n", context_x86->cs);
printf(" eflags = 0x%x\n", context_x86->eflags);
printf(" esp = 0x%x\n", context_x86->esp);
printf(" ss = 0x%x\n", context_x86->ss);
printf(" extended_registers[%3d] = 0x",
MD_CONTEXT_X86_EXTENDED_REGISTERS_SIZE);
for (unsigned int register_index = 0;
register_index < MD_CONTEXT_X86_EXTENDED_REGISTERS_SIZE;
++register_index) {
printf("%02x", context_x86->extended_registers[register_index]);
}
printf("\n\n");
break;
}
case MD_CONTEXT_PPC: {
const MDRawContextPPC* context_ppc = GetContextPPC();
printf("MDRawContextPPC\n");
printf(" context_flags = 0x%x\n",
context_ppc->context_flags);
printf(" srr0 = 0x%x\n", context_ppc->srr0);
printf(" srr1 = 0x%x\n", context_ppc->srr1);
for (unsigned int gpr_index = 0;
gpr_index < MD_CONTEXT_PPC_GPR_COUNT;
++gpr_index) {
printf(" gpr[%2d] = 0x%x\n",
gpr_index, context_ppc->gpr[gpr_index]);
}
printf(" cr = 0x%x\n", context_ppc->cr);
printf(" xer = 0x%x\n", context_ppc->xer);
printf(" lr = 0x%x\n", context_ppc->lr);
printf(" ctr = 0x%x\n", context_ppc->ctr);
printf(" mq = 0x%x\n", context_ppc->mq);
printf(" vrsave = 0x%x\n", context_ppc->vrsave);
for (unsigned int fpr_index = 0;
fpr_index < MD_FLOATINGSAVEAREA_PPC_FPR_COUNT;
++fpr_index) {
printf(" float_save.fpregs[%2d] = 0x%llx\n",
fpr_index, context_ppc->float_save.fpregs[fpr_index]);
}
printf(" float_save.fpscr = 0x%x\n",
context_ppc->float_save.fpscr);
// TODO(mmentovai): print the 128-bit quantities in
// context_ppc->vector_save. This isn't done yet because printf
// doesn't support 128-bit quantities, and printing them using
// %llx as two 64-bit quantities requires knowledge of the CPU's
// byte ordering.
printf(" vector_save.save_vrvalid = 0x%x\n",
context_ppc->vector_save.save_vrvalid);
printf("\n");
break;
}
default: {
break;
}
}
}
//
// MinidumpMemoryRegion
//
MinidumpMemoryRegion::MinidumpMemoryRegion(Minidump* minidump)
: MinidumpObject(minidump),
descriptor_(NULL),
memory_(NULL) {
}
MinidumpMemoryRegion::~MinidumpMemoryRegion() {
delete memory_;
}
void MinidumpMemoryRegion::SetDescriptor(MDMemoryDescriptor* descriptor) {
descriptor_ = descriptor;
valid_ = descriptor &&
(descriptor_->start_of_memory_range +
descriptor_->memory.data_size) >
descriptor_->start_of_memory_range;
}
const u_int8_t* MinidumpMemoryRegion::GetMemory() {
if (!valid_)
return NULL;
if (!memory_) {
if (!minidump_->SeekSet(descriptor_->memory.rva))
return NULL;
// TODO(mmentovai): verify rational size!
scoped_ptr< vector<u_int8_t> > memory(
new vector<u_int8_t>(descriptor_->memory.data_size));
if (!minidump_->ReadBytes(&(*memory)[0], descriptor_->memory.data_size))
return NULL;
memory_ = memory.release();
}
return &(*memory_)[0];
}
u_int64_t MinidumpMemoryRegion::GetBase() {
return valid_ ? descriptor_->start_of_memory_range : (u_int64_t)-1;
}
u_int32_t MinidumpMemoryRegion::GetSize() {
return valid_ ? descriptor_->memory.data_size : 0;
}
void MinidumpMemoryRegion::FreeMemory() {
delete memory_;
memory_ = NULL;
}
template<typename T>
bool MinidumpMemoryRegion::GetMemoryAtAddressInternal(u_int64_t address,
T* value) {
if (!valid_ || !value)
return false;
if (address < descriptor_->start_of_memory_range ||
address + sizeof(T) > descriptor_->start_of_memory_range +
descriptor_->memory.data_size) {
return false;
}
const u_int8_t* memory = GetMemory();
if (!memory)
return false;
// If the CPU requires memory accesses to be aligned, this can crash.
// x86 and ppc are able to cope, though.
*value = *reinterpret_cast<const T*>(
&memory[address - descriptor_->start_of_memory_range]);
if (minidump_->swap())
Swap(value);
return true;
}
bool MinidumpMemoryRegion::GetMemoryAtAddress(u_int64_t address,
u_int8_t* value) {
return GetMemoryAtAddressInternal(address, value);
}
bool MinidumpMemoryRegion::GetMemoryAtAddress(u_int64_t address,
u_int16_t* value) {
return GetMemoryAtAddressInternal(address, value);
}
bool MinidumpMemoryRegion::GetMemoryAtAddress(u_int64_t address,
u_int32_t* value) {
return GetMemoryAtAddressInternal(address, value);
}
bool MinidumpMemoryRegion::GetMemoryAtAddress(u_int64_t address,
u_int64_t* value) {
return GetMemoryAtAddressInternal(address, value);
}
void MinidumpMemoryRegion::Print() {
if (!valid_)
return;
const u_int8_t* memory = GetMemory();
if (memory) {
printf("0x");
for (unsigned int byte_index = 0;
byte_index < descriptor_->memory.data_size;
byte_index++) {
printf("%02x", memory[byte_index]);
}
printf("\n");
} else {
printf("No memory\n");
}
}
//
// MinidumpThread
//
MinidumpThread::MinidumpThread(Minidump* minidump)
: MinidumpObject(minidump),
thread_(),
memory_(NULL),
context_(NULL) {
}
MinidumpThread::~MinidumpThread() {
delete memory_;
delete context_;
}
bool MinidumpThread::Read() {
// Invalidate cached data.
delete memory_;
memory_ = NULL;
delete context_;
context_ = NULL;
valid_ = false;
if (!minidump_->ReadBytes(&thread_, sizeof(thread_)))
return false;
if (minidump_->swap()) {
Swap(&thread_.thread_id);
Swap(&thread_.suspend_count);
Swap(&thread_.priority_class);
Swap(&thread_.priority);
Swap(&thread_.teb);
Swap(&thread_.stack);
Swap(&thread_.thread_context);
}
// Check for base + size overflow or undersize. A separate size==0
// check is needed in case base == 0.
u_int64_t high_address = thread_.stack.start_of_memory_range +
thread_.stack.memory.data_size - 1;
if (thread_.stack.memory.data_size == 0 ||
high_address < thread_.stack.start_of_memory_range)
return false;
memory_ = new MinidumpMemoryRegion(minidump_);
memory_->SetDescriptor(&thread_.stack);
valid_ = true;
return true;
}
MinidumpMemoryRegion* MinidumpThread::GetMemory() {
return !valid_ ? NULL : memory_;
}
MinidumpContext* MinidumpThread::GetContext() {
if (!valid_)
return NULL;
if (!context_) {
if (!minidump_->SeekSet(thread_.thread_context.rva))
return NULL;
scoped_ptr<MinidumpContext> context(new MinidumpContext(minidump_));
if (!context->Read(thread_.thread_context.data_size))
return NULL;
context_ = context.release();
}
return context_;
}
u_int32_t MinidumpThread::GetThreadID() {
return valid_ ? thread_.thread_id : (u_int32_t)-1;
}
void MinidumpThread::Print() {
if (!valid_)
return;
printf("MDRawThread\n");
printf(" thread_id = 0x%x\n", thread_.thread_id);
printf(" suspend_count = %d\n", thread_.suspend_count);
printf(" priority_class = 0x%x\n", thread_.priority_class);
printf(" priority = 0x%x\n", thread_.priority);
printf(" teb = 0x%llx\n", thread_.teb);
printf(" stack.start_of_memory_range = 0x%llx\n",
thread_.stack.start_of_memory_range);
printf(" stack.memory.data_size = 0x%x\n",
thread_.stack.memory.data_size);
printf(" stack.memory.rva = 0x%x\n", thread_.stack.memory.rva);
printf(" thread_context.data_size = 0x%x\n",
thread_.thread_context.data_size);
printf(" thread_context.rva = 0x%x\n",
thread_.thread_context.rva);
MinidumpContext* context = GetContext();
if (context) {
printf("\n");
context->Print();
} else {
printf(" (no context)\n");
printf("\n");
}
MinidumpMemoryRegion* memory = GetMemory();
if (memory) {
printf("Stack\n");
memory->Print();
} else {
printf("No stack\n");
}
printf("\n");
}
//
// MinidumpThreadList
//
MinidumpThreadList::MinidumpThreadList(Minidump* minidump)
: MinidumpStream(minidump),
id_to_thread_map_(),
threads_(NULL),
thread_count_(0) {
}
MinidumpThreadList::~MinidumpThreadList() {
delete threads_;
}
bool MinidumpThreadList::Read(u_int32_t expected_size) {
// Invalidate cached data.
id_to_thread_map_.clear();
delete threads_;
threads_ = NULL;
thread_count_ = 0;
valid_ = false;
u_int32_t thread_count;
if (expected_size < sizeof(thread_count))
return false;
if (!minidump_->ReadBytes(&thread_count, sizeof(thread_count)))
return false;
if (minidump_->swap())
Swap(&thread_count);
if (expected_size != sizeof(thread_count) +
thread_count * sizeof(MDRawThread)) {
return false;
}
// TODO(mmentovai): verify rational size!
scoped_ptr<MinidumpThreads> threads(
new MinidumpThreads(thread_count, MinidumpThread(minidump_)));
for (unsigned int thread_index = 0;
thread_index < thread_count;
++thread_index) {
MinidumpThread* thread = &(*threads)[thread_index];
// Assume that the file offset is correct after the last read.
if (!thread->Read())
return false;
u_int32_t thread_id = thread->GetThreadID();
if (GetThreadByID(thread_id)) {
// Another thread with this ID is already in the list. Data error.
return false;
}
id_to_thread_map_[thread_id] = thread;
}
threads_ = threads.release();
thread_count_ = thread_count;
valid_ = true;
return true;
}
MinidumpThread* MinidumpThreadList::GetThreadAtIndex(unsigned int index)
const {
if (!valid_ || index >= thread_count_)
return NULL;
return &(*threads_)[index];
}
MinidumpThread* MinidumpThreadList::GetThreadByID(u_int32_t thread_id) {
// Don't check valid_. Read calls this method before everything is
// validated. It is safe to not check valid_ here.
return id_to_thread_map_[thread_id];
}
void MinidumpThreadList::Print() {
if (!valid_)
return;
printf("MinidumpThreadList\n");
printf(" thread_count = %d\n", thread_count_);
printf("\n");
for (unsigned int thread_index = 0;
thread_index < thread_count_;
++thread_index) {
printf("thread[%d]\n", thread_index);
(*threads_)[thread_index].Print();
}
}
//
// MinidumpModule
//
MinidumpModule::MinidumpModule(Minidump* minidump)
: MinidumpObject(minidump),
module_(),
name_(NULL),
cv_record_(NULL),
misc_record_(NULL),
debug_filename_(NULL) {
}
MinidumpModule::~MinidumpModule() {
delete name_;
delete cv_record_;
delete misc_record_;
delete debug_filename_;
}
bool MinidumpModule::Read() {
// Invalidate cached data.
delete name_;
name_ = NULL;
delete cv_record_;
cv_record_ = NULL;
delete misc_record_;
misc_record_ = NULL;
delete debug_filename_;
debug_filename_ = NULL;
valid_ = false;
if (!minidump_->ReadBytes(&module_, MD_MODULE_SIZE))
return false;
if (minidump_->swap()) {
Swap(&module_.base_of_image);
Swap(&module_.size_of_image);
Swap(&module_.checksum);
Swap(&module_.time_date_stamp);
Swap(&module_.module_name_rva);
Swap(&module_.version_info.signature);
Swap(&module_.version_info.struct_version);
Swap(&module_.version_info.file_version_hi);
Swap(&module_.version_info.file_version_lo);
Swap(&module_.version_info.product_version_hi);
Swap(&module_.version_info.product_version_lo);
Swap(&module_.version_info.file_flags_mask);
Swap(&module_.version_info.file_flags);
Swap(&module_.version_info.file_os);
Swap(&module_.version_info.file_type);
Swap(&module_.version_info.file_subtype);
Swap(&module_.version_info.file_date_hi);
Swap(&module_.version_info.file_date_lo);
Swap(&module_.cv_record);
Swap(&module_.misc_record);
// Don't swap reserved fields because their contents are unknown (as
// are their proper widths).
}
// Check for base + size overflow or undersize. A separate size==0
// check is needed in case base == 0.
u_int64_t high_address = module_.base_of_image + module_.size_of_image - 1;
if (module_.size_of_image == 0 || high_address < module_.base_of_image)
return false;
valid_ = true;
return true;
}
const string* MinidumpModule::GetName() {
if (!valid_)
return NULL;
if (!name_)
name_ = minidump_->ReadString(module_.module_name_rva);
return name_;
}
const u_int8_t* MinidumpModule::GetCVRecord() {
if (!valid_)
return NULL;
if (!cv_record_) {
// Only check against the smallest possible structure size now - recheck
// if necessary later if the actual structure is larger.
if (sizeof(MDCVInfoPDB20) > module_.cv_record.data_size)
return NULL;
if (!minidump_->SeekSet(module_.cv_record.rva))
return NULL;
// TODO(mmentovai): verify rational size!
// Allocating something that will be accessed as MDCVInfoPDB70 or
// MDCVInfoPDB20 but is allocated as u_int8_t[] can cause alignment
// problems. x86 and ppc are able to cope, though. This allocation
// style is needed because the MDCVInfoPDB70 or MDCVInfoPDB20 are
// variable-sized due to their pdb_file_name fields; these structures
// are not sizeof(MDCVInfoPDB70) or sizeof(MDCVInfoPDB20) and treating
// them as such would result in incomplete structures or overruns.
scoped_ptr< vector<u_int8_t> > cv_record(
new vector<u_int8_t>(module_.cv_record.data_size));
if (!minidump_->ReadBytes(&(*cv_record)[0], module_.cv_record.data_size))
return NULL;
MDCVInfoPDB70* cv_record_70 =
reinterpret_cast<MDCVInfoPDB70*>(&(*cv_record)[0]);
u_int32_t signature = cv_record_70->cv_signature;
if (minidump_->swap())
Swap(&signature);
if (signature == MD_CVINFOPDB70_SIGNATURE) {
// Now that the structure type is known, recheck the size.
if (sizeof(MDCVInfoPDB70) > module_.cv_record.data_size)
return NULL;
if (minidump_->swap()) {
Swap(&cv_record_70->cv_signature);
Swap(&cv_record_70->signature);
Swap(&cv_record_70->age);
// Don't swap cv_record_70.pdb_file_name because it's an array of 8-bit
// quanities. (It's a path, is it UTF-8?)
}
} else if (signature == MD_CVINFOPDB20_SIGNATURE) {
if (minidump_->swap()) {
MDCVInfoPDB20* cv_record_20 =
reinterpret_cast<MDCVInfoPDB20*>(&(*cv_record)[0]);
Swap(&cv_record_20->cv_header.signature);
Swap(&cv_record_20->cv_header.offset);
Swap(&cv_record_20->signature);
Swap(&cv_record_20->age);
// Don't swap cv_record_20.pdb_file_name because it's an array of 8-bit
// quantities. (It's a path, is it UTF-8?)
}
} else {
// Some unknown structure type. We don't need to bail out here, but we
// do instead of returning it, because this method guarantees properly
// swapped data, and data in an unknown format can't possibly be swapped.
return NULL;
}
// The last field of either structure is null-terminated 8-bit character
// data. Ensure that it's null-terminated.
if ((*cv_record)[module_.cv_record.data_size - 1] != '\0')
return NULL;
// Store the vector type because that's how storage was allocated, but
// return it casted to u_int8_t*.
cv_record_ = cv_record.release();
}
return &(*cv_record_)[0];
}
const MDImageDebugMisc* MinidumpModule::GetMiscRecord() {
if (!valid_)
return NULL;
if (!misc_record_) {
if (sizeof(MDImageDebugMisc) > module_.misc_record.data_size)
return NULL;
if (!minidump_->SeekSet(module_.misc_record.rva))
return NULL;
// TODO(mmentovai): verify rational size!
// Allocating something that will be accessed as MDImageDebugMisc but
// is allocated as u_int8_t[] can cause alignment problems. x86 and
// ppc are able to cope, though. This allocation style is needed
// because the MDImageDebugMisc is variable-sized due to its data field;
// this structure is not sizeof(MDImageDebugMisc) and treating it as such
// would result in an incomplete structure or an overrun.
scoped_ptr< vector<u_int8_t> > misc_record_mem(
new vector<u_int8_t>(module_.misc_record.data_size));
MDImageDebugMisc* misc_record =
reinterpret_cast<MDImageDebugMisc*>(&(*misc_record_mem)[0]);
if (!minidump_->ReadBytes(misc_record, module_.misc_record.data_size))
return NULL;
if (minidump_->swap()) {
Swap(&misc_record->data_type);
Swap(&misc_record->length);
// Don't swap misc_record.unicode because it's an 8-bit quantity.
// Don't swap the reserved fields for the same reason, and because
// they don't contain any valid data.
if (misc_record->unicode) {
// There is a potential alignment problem, but shouldn't be a problem
// in practice due to the layout of MDImageDebugMisc.
u_int16_t* data16 = reinterpret_cast<u_int16_t*>(&(misc_record->data));
unsigned int dataBytes = module_.misc_record.data_size -
sizeof(MDImageDebugMisc);
unsigned int dataLength = dataBytes / 2;
for (unsigned int characterIndex = 0;
characterIndex < dataLength;
++characterIndex) {
Swap(&data16[characterIndex]);
}
}
}
if (module_.misc_record.data_size != misc_record->length)
return NULL;
// Store the vector type because that's how storage was allocated, but
// return it casted to MDImageDebugMisc*.
misc_record_ = misc_record_mem.release();
}
return reinterpret_cast<MDImageDebugMisc*>(&(*misc_record_)[0]);
}
// This method will perform no allocation-size checking on its own; it relies
// on GetCVRecord() and GetMiscRecord() to have made the determination that
// the necessary structures aren't oversized.
const string* MinidumpModule::GetDebugFilename() {
if (!valid_)
return NULL;
if (!debug_filename_) {
// Prefer the CodeView record if present.
const MDCVInfoPDB70* cv_record_70 =
reinterpret_cast<const MDCVInfoPDB70*>(GetCVRecord());
if (cv_record_70) {
if (cv_record_70->cv_signature == MD_CVINFOPDB70_SIGNATURE) {
// GetCVRecord guarantees pdb_file_name is null-terminated.
debug_filename_ = new string(
reinterpret_cast<const char*>(cv_record_70->pdb_file_name));
return debug_filename_;
} else if (cv_record_70->cv_signature == MD_CVINFOPDB20_SIGNATURE) {
// It's actually a MDCVInfoPDB20 structure.
const MDCVInfoPDB20* cv_record_20 =
reinterpret_cast<const MDCVInfoPDB20*>(cv_record_70);
// GetCVRecord guarantees pdb_file_name is null-terminated.
debug_filename_ = new string(
reinterpret_cast<const char*>(cv_record_20->pdb_file_name));
return debug_filename_;
}
// If there's a CodeView record but it doesn't match either of those
// signatures, try the miscellaneous record - but it's suspicious because
// GetCVRecord shouldn't have returned a CodeView record that doesn't
// match either signature.
}
// No usable CodeView record. Try the miscellaneous debug record.
const MDImageDebugMisc* misc_record = GetMiscRecord();
if (!misc_record)
return NULL;
if (!misc_record->unicode) {
// If it's not Unicode, just stuff it into the string. It's unclear
// if misc_record->data is 0-terminated, so use an explicit size.
debug_filename_ = new string(
reinterpret_cast<const char*>(misc_record->data),
module_.misc_record.data_size - sizeof(MDImageDebugMisc));
return debug_filename_;
}
// There's a misc_record but it encodes the debug filename in UTF-16.
// (Actually, because miscellaneous records are so old, it's probably
// UCS-2.) Convert it to UTF-8 for congruity with the other strings that
// this method (and all other methods in the Minidump family) return.
unsigned int bytes =
module_.misc_record.data_size - sizeof(MDImageDebugMisc);
if (bytes % 2 != 0)
return NULL;
unsigned int utf16_words = bytes / 2;
// UTF16ToUTF8 expects a vector<u_int16_t>, so create a temporary one and
// copy the UTF-16 data into it.
vector<u_int16_t> string_utf16(utf16_words);
memcpy(&string_utf16[0], &misc_record->data, bytes);
// GetMiscRecord already byte-swapped the data[] field if it contains
// UTF-16, so pass false as the swap argument.
debug_filename_ = UTF16ToUTF8(string_utf16, false);
}
return debug_filename_;
}
void MinidumpModule::Print() {
if (!valid_)
return;
printf("MDRawModule\n");
printf(" base_of_image = 0x%llx\n",
module_.base_of_image);
printf(" size_of_image = 0x%x\n",
module_.size_of_image);
printf(" checksum = 0x%x\n",
module_.checksum);
printf(" time_date_stamp = 0x%x\n",
module_.time_date_stamp);
printf(" module_name_rva = 0x%x\n",
module_.module_name_rva);
printf(" version_info.signature = 0x%x\n",
module_.version_info.signature);
printf(" version_info.struct_version = 0x%x\n",
module_.version_info.struct_version);
printf(" version_info.file_version = 0x%x:0x%x\n",
module_.version_info.file_version_hi,
module_.version_info.file_version_lo);
printf(" version_info.product_version = 0x%x:0x%x\n",
module_.version_info.product_version_hi,
module_.version_info.product_version_lo);
printf(" version_info.file_flags_mask = 0x%x\n",
module_.version_info.file_flags_mask);
printf(" version_info.file_flags = 0x%x\n",
module_.version_info.file_flags);
printf(" version_info.file_os = 0x%x\n",
module_.version_info.file_os);
printf(" version_info.file_type = 0x%x\n",
module_.version_info.file_type);
printf(" version_info.file_subtype = 0x%x\n",
module_.version_info.file_subtype);
printf(" version_info.file_date = 0x%x:0x%x\n",
module_.version_info.file_date_hi,
module_.version_info.file_date_lo);
printf(" cv_record.data_size = %d\n",
module_.cv_record.data_size);
printf(" cv_record.rva = 0x%x\n",
module_.cv_record.rva);
printf(" misc_record.data_size = %d\n",
module_.misc_record.data_size);
printf(" misc_record.rva = 0x%x\n",
module_.misc_record.rva);
const char* module_name = GetName()->c_str();
if (module_name)
printf(" (module_name) = \"%s\"\n", module_name);
else
printf(" (module_name) = (null)\n");
const MDCVInfoPDB70* cv_record =
reinterpret_cast<const MDCVInfoPDB70*>(GetCVRecord());
if (cv_record) {
if (cv_record->cv_signature == MD_CVINFOPDB70_SIGNATURE) {
printf(" (cv_record).cv_signature = 0x%x\n",
cv_record->cv_signature);
printf(" (cv_record).signature = %08x-%04x-%04x-%02x%02x-",
cv_record->signature.data1,
cv_record->signature.data2,
cv_record->signature.data3,
cv_record->signature.data4[0],
cv_record->signature.data4[1]);
for (unsigned int guidIndex = 2;
guidIndex < 8;
++guidIndex) {
printf("%02x", cv_record->signature.data4[guidIndex]);
}
printf("\n");
printf(" (cv_record).age = %d\n",
cv_record->age);
printf(" (cv_record).pdb_file_name = \"%s\"\n",
cv_record->pdb_file_name);
} else {
const MDCVInfoPDB20* cv_record_20 =
reinterpret_cast<const MDCVInfoPDB20*>(cv_record);
printf(" (cv_record).cv_header.signature = 0x%x\n",
cv_record_20->cv_header.signature);
printf(" (cv_record).cv_header.offset = 0x%x\n",
cv_record_20->cv_header.offset);
printf(" (cv_record).signature = 0x%x\n",
cv_record_20->signature);
printf(" (cv_record).age = %d\n",
cv_record_20->age);
printf(" (cv_record).pdb_file_name = \"%s\"\n",
cv_record_20->pdb_file_name);
}
} else {
printf(" (cv_record) = (null)\n");
}
const MDImageDebugMisc* misc_record = GetMiscRecord();
if (misc_record) {
printf(" (misc_record).data_type = 0x%x\n",
misc_record->data_type);
printf(" (misc_record).length = 0x%x\n",
misc_record->length);
printf(" (misc_record).unicode = %d\n",
misc_record->unicode);
// Don't bother printing the UTF-16, we don't really even expect to ever
// see this misc_record anyway.
if (misc_record->unicode)
printf(" (misc_record).data = \"%s\"\n",
misc_record->data);
else
printf(" (misc_record).data = (UTF-16)\n");
} else {
printf(" (misc_record) = (null)\n");
}
const string* debug_filename = GetDebugFilename();
if (debug_filename) {
printf(" (debug_filename) = \"%s\"\n",
debug_filename->c_str());
} else {
printf(" (debug_filename) = (null)\n");
}
printf("\n");
}
//
// MinidumpModuleList
//
MinidumpModuleList::MinidumpModuleList(Minidump* minidump)
: MinidumpStream(minidump),
range_map_(),
modules_(NULL),
module_count_(0) {
}
MinidumpModuleList::~MinidumpModuleList() {
delete modules_;
}
bool MinidumpModuleList::Read(u_int32_t expected_size) {
// Invalidate cached data.
range_map_.Clear();
delete modules_;
modules_ = NULL;
module_count_ = 0;
valid_ = false;
u_int32_t module_count;
if (expected_size < sizeof(module_count))
return false;
if (!minidump_->ReadBytes(&module_count, sizeof(module_count)))
return false;
if (minidump_->swap())
Swap(&module_count);
if (expected_size != sizeof(module_count) +
module_count * MD_MODULE_SIZE) {
return false;
}
// TODO(mmentovai): verify rational size!
scoped_ptr<MinidumpModules> modules(
new MinidumpModules(module_count, MinidumpModule(minidump_)));
for (unsigned int module_index = 0;
module_index < module_count;
++module_index) {
MinidumpModule* module = &(*modules)[module_index];
// Assume that the file offset is correct after the last read.
if (!module->Read())
return false;
u_int64_t base_address = module->base_address();
u_int64_t module_size = module->size();
if (base_address == (u_int64_t)-1)
return false;
if (!range_map_.StoreRange(base_address, module_size, module_index))
return false;
}
modules_ = modules.release();
module_count_ = module_count;
valid_ = true;
return true;
}
MinidumpModule* MinidumpModuleList::GetModuleAtIndex(unsigned int index)
const {
if (!valid_ || index >= module_count_)
return NULL;
return &(*modules_)[index];
}
MinidumpModule* MinidumpModuleList::GetModuleForAddress(u_int64_t address) {
if (!valid_)
return NULL;
unsigned int module_index;
if (!range_map_.RetrieveRange(address, &module_index, NULL, NULL))
return NULL;
return GetModuleAtIndex(module_index);
}
void MinidumpModuleList::Print() {
if (!valid_)
return;
printf("MinidumpModuleList\n");
printf(" module_count = %d\n", module_count_);
printf("\n");
for (unsigned int module_index = 0;
module_index < module_count_;
++module_index) {
printf("module[%d]\n", module_index);
(*modules_)[module_index].Print();
}
}
//
// MinidumpMemoryList
//
MinidumpMemoryList::MinidumpMemoryList(Minidump* minidump)
: MinidumpStream(minidump),
range_map_(),
descriptors_(NULL),
regions_(NULL),
region_count_(0) {
}
MinidumpMemoryList::~MinidumpMemoryList() {
delete descriptors_;
delete regions_;
}
bool MinidumpMemoryList::Read(u_int32_t expected_size) {
// Invalidate cached data.
delete descriptors_;
descriptors_ = NULL;
delete regions_;
regions_ = NULL;
range_map_.Clear();
region_count_ = 0;
valid_ = false;
u_int32_t region_count;
if (expected_size < sizeof(region_count))
return false;
if (!minidump_->ReadBytes(®ion_count, sizeof(region_count)))
return false;
if (minidump_->swap())
Swap(®ion_count);
if (expected_size != sizeof(region_count) +
region_count * sizeof(MDMemoryDescriptor)) {
return false;
}
// TODO(mmentovai): verify rational size!
scoped_ptr<MemoryDescriptors> descriptors(
new MemoryDescriptors(region_count));
// Read the entire array in one fell swoop, instead of reading one entry
// at a time in the loop.
if (!minidump_->ReadBytes(&(*descriptors)[0],
sizeof(MDMemoryDescriptor) * region_count)) {
return false;
}
scoped_ptr<MemoryRegions> regions(
new MemoryRegions(region_count, MinidumpMemoryRegion(minidump_)));
for (unsigned int region_index = 0;
region_index < region_count;
++region_index) {
MDMemoryDescriptor* descriptor = &(*descriptors)[region_index];
if (minidump_->swap())
Swap(&*descriptor);
u_int64_t base_address = descriptor->start_of_memory_range;
u_int32_t region_size = descriptor->memory.data_size;
// Check for base + size overflow or undersize. A separate size==0
// check is needed in case base == 0.
u_int64_t high_address = base_address + region_size - 1;
if (region_size == 0 || high_address < base_address)
return false;
if (!range_map_.StoreRange(base_address, region_size, region_index))
return false;
(*regions)[region_index].SetDescriptor(descriptor);
}
region_count_ = region_count;
descriptors_ = descriptors.release();
regions_ = regions.release();
valid_ = true;
return true;
}
MinidumpMemoryRegion* MinidumpMemoryList::GetMemoryRegionAtIndex(
unsigned int index) {
if (!valid_ || index >= region_count_)
return NULL;
return &(*regions_)[index];
}
MinidumpMemoryRegion* MinidumpMemoryList::GetMemoryRegionForAddress(
u_int64_t address) {
if (!valid_)
return NULL;
unsigned int region_index;
if (!range_map_.RetrieveRange(address, ®ion_index, NULL, NULL))
return NULL;
return GetMemoryRegionAtIndex(region_index);
}
void MinidumpMemoryList::Print() {
if (!valid_)
return;
printf("MinidumpMemoryList\n");
printf(" region_count = %d\n", region_count_);
printf("\n");
for (unsigned int region_index = 0;
region_index < region_count_;
++region_index) {
MDMemoryDescriptor* descriptor = &(*descriptors_)[region_index];
printf("region[%d]\n", region_index);
printf("MDMemoryDescriptor\n");
printf(" start_of_memory_range = 0x%llx\n",
descriptor->start_of_memory_range);
printf(" memory.data_size = 0x%x\n", descriptor->memory.data_size);
printf(" memory.rva = 0x%x\n", descriptor->memory.rva);
MinidumpMemoryRegion* region = GetMemoryRegionAtIndex(region_index);
if (region) {
printf("Memory\n");
region->Print();
} else {
printf("No memory\n");
}
printf("\n");
}
}
//
// MinidumpException
//
MinidumpException::MinidumpException(Minidump* minidump)
: MinidumpStream(minidump),
exception_(),
context_(NULL) {
}
MinidumpException::~MinidumpException() {
delete context_;
}
bool MinidumpException::Read(u_int32_t expected_size) {
// Invalidate cached data.
delete context_;
context_ = NULL;
valid_ = false;
if (expected_size != sizeof(exception_))
return false;
if (!minidump_->ReadBytes(&exception_, sizeof(exception_)))
return false;
if (minidump_->swap()) {
Swap(&exception_.thread_id);
// exception_.__align is for alignment only and does not need to be
// swapped.
Swap(&exception_.exception_record.exception_code);
Swap(&exception_.exception_record.exception_flags);
Swap(&exception_.exception_record.exception_record);
Swap(&exception_.exception_record.exception_address);
Swap(&exception_.exception_record.number_parameters);
// exception_.exception_record.__align is for alignment only and does not
// need to be swapped.
for (unsigned int parameter_index = 0;
parameter_index < MD_EXCEPTION_MAXIMUM_PARAMETERS;
++parameter_index) {
Swap(&exception_.exception_record.exception_information[parameter_index]);
}
Swap(&exception_.thread_context);
}
valid_ = true;
return true;
}
u_int32_t MinidumpException::GetThreadID() {
return valid_ ? exception_.thread_id : 0;
}
MinidumpContext* MinidumpException::GetContext() {
if (!valid_)
return NULL;
if (!context_) {
if (!minidump_->SeekSet(exception_.thread_context.rva))
return NULL;
scoped_ptr<MinidumpContext> context(new MinidumpContext(minidump_));
if (!context->Read(exception_.thread_context.data_size))
return NULL;
context_ = context.release();
}
return context_;
}
void MinidumpException::Print() {
if (!valid_)
return;
printf("MDException\n");
printf(" thread_id = 0x%x\n",
exception_.thread_id);
printf(" exception_record.exception_code = 0x%x\n",
exception_.exception_record.exception_code);
printf(" exception_record.exception_flags = 0x%x\n",
exception_.exception_record.exception_flags);
printf(" exception_record.exception_record = 0x%llx\n",
exception_.exception_record.exception_record);
printf(" exception_record.exception_address = 0x%llx\n",
exception_.exception_record.exception_address);
printf(" exception_record.number_parameters = %d\n",
exception_.exception_record.number_parameters);
for (unsigned int parameterIndex = 0;
parameterIndex < exception_.exception_record.number_parameters;
++parameterIndex) {
printf(" exception_record.exception_information[%2d] = 0x%llx\n",
parameterIndex,
exception_.exception_record.exception_information[parameterIndex]);
}
printf(" thread_context.data_size = %d\n",
exception_.thread_context.data_size);
printf(" thread_context.rva = 0x%x\n",
exception_.thread_context.rva);
MinidumpContext* context = GetContext();
if (context) {
printf("\n");
context->Print();
} else {
printf(" (no context)\n");
printf("\n");
}
}
//
// MinidumpSystemInfo
//
MinidumpSystemInfo::MinidumpSystemInfo(Minidump* minidump)
: MinidumpStream(minidump),
system_info_(),
csd_version_(NULL),
cpu_vendor_(NULL) {
}
MinidumpSystemInfo::~MinidumpSystemInfo() {
delete csd_version_;
delete cpu_vendor_;
}
bool MinidumpSystemInfo::Read(u_int32_t expected_size) {
// Invalidate cached data.
delete csd_version_;
csd_version_ = NULL;
delete cpu_vendor_;
cpu_vendor_ = NULL;
valid_ = false;
if (expected_size != sizeof(system_info_))
return false;
if (!minidump_->ReadBytes(&system_info_, sizeof(system_info_)))
return false;
if (minidump_->swap()) {
Swap(&system_info_.processor_architecture);
Swap(&system_info_.processor_level);
Swap(&system_info_.processor_revision);
// number_of_processors and product_type are 8-bit quantities and need no
// swapping.
Swap(&system_info_.major_version);
Swap(&system_info_.minor_version);
Swap(&system_info_.build_number);
Swap(&system_info_.platform_id);
Swap(&system_info_.csd_version_rva);
Swap(&system_info_.suite_mask);
// Don't swap the reserved2 field because its contents are unknown.
if (system_info_.processor_architecture == MD_CPU_ARCHITECTURE_X86 ||
system_info_.processor_architecture == MD_CPU_ARCHITECTURE_X86_WIN64) {
for (unsigned int i = 0; i < 3; ++i)
Swap(&system_info_.cpu.x86_cpu_info.vendor_id[i]);
Swap(&system_info_.cpu.x86_cpu_info.version_information);
Swap(&system_info_.cpu.x86_cpu_info.feature_information);
Swap(&system_info_.cpu.x86_cpu_info.amd_extended_cpu_features);
} else {
for (unsigned int i = 0; i < 2; ++i)
Swap(&system_info_.cpu.other_cpu_info.processor_features[i]);
}
}
valid_ = true;
return true;
}
const string* MinidumpSystemInfo::GetCSDVersion() {
if (!valid_)
return NULL;
if (!csd_version_)
csd_version_ = minidump_->ReadString(system_info_.csd_version_rva);
return csd_version_;
}
const string* MinidumpSystemInfo::GetCPUVendor() {
if (!valid_)
return NULL;
// CPU vendor information can only be determined from x86 minidumps.
if (!cpu_vendor_ &&
(system_info_.processor_architecture == MD_CPU_ARCHITECTURE_X86 ||
system_info_.processor_architecture == MD_CPU_ARCHITECTURE_X86_WIN64)) {
char cpu_vendor_string[13];
snprintf(cpu_vendor_string, sizeof(cpu_vendor_string),
"%c%c%c%c%c%c%c%c%c%c%c%c",
system_info_.cpu.x86_cpu_info.vendor_id[0] & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[0] >> 8) & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[0] >> 16) & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[0] >> 24) & 0xff,
system_info_.cpu.x86_cpu_info.vendor_id[1] & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[1] >> 8) & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[1] >> 16) & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[1] >> 24) & 0xff,
system_info_.cpu.x86_cpu_info.vendor_id[2] & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[2] >> 8) & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[2] >> 16) & 0xff,
(system_info_.cpu.x86_cpu_info.vendor_id[2] >> 24) & 0xff);
cpu_vendor_ = new string(cpu_vendor_string);
}
return cpu_vendor_;
}
void MinidumpSystemInfo::Print() {
if (!valid_)
return;
printf("MDRawSystemInfo\n");
printf(" processor_architecture = %d\n",
system_info_.processor_architecture);
printf(" processor_level = %d\n",
system_info_.processor_level);
printf(" processor_revision = 0x%x\n",
system_info_.processor_revision);
printf(" number_of_processors = %d\n",
system_info_.number_of_processors);
printf(" product_type = %d\n",
system_info_.product_type);
printf(" major_version = %d\n",
system_info_.major_version);
printf(" minor_version = %d\n",
system_info_.minor_version);
printf(" build_number = %d\n",
system_info_.build_number);
printf(" platform_id = %d\n",
system_info_.platform_id);
printf(" csd_version_rva = 0x%x\n",
system_info_.csd_version_rva);
printf(" suite_mask = 0x%x\n",
system_info_.suite_mask);
for (unsigned int i = 0; i < 3; ++i) {
printf(" cpu.x86_cpu_info.vendor_id[%d] = 0x%x\n",
i, system_info_.cpu.x86_cpu_info.vendor_id[i]);
}
printf(" cpu.x86_cpu_info.version_information = 0x%x\n",
system_info_.cpu.x86_cpu_info.version_information);
printf(" cpu.x86_cpu_info.feature_information = 0x%x\n",
system_info_.cpu.x86_cpu_info.feature_information);
printf(" cpu.x86_cpu_info.amd_extended_cpu_features = 0x%x\n",
system_info_.cpu.x86_cpu_info.amd_extended_cpu_features);
const string* csd_version = GetCSDVersion();
if (csd_version) {
printf(" (csd_version) = \"%s\"\n",
csd_version->c_str());
} else {
printf(" (csd_version) = (null)\n");
}
const string* cpu_vendor = GetCPUVendor();
if (cpu_vendor) {
printf(" (cpu_vendor) = \"%s\"\n",
cpu_vendor->c_str());
} else {
printf(" (cpu_vendor) = (null)\n");
}
printf("\n");
}
//
// MinidumpMiscInfo
//
MinidumpMiscInfo::MinidumpMiscInfo(Minidump* minidump)
: MinidumpStream(minidump),
misc_info_() {
}
bool MinidumpMiscInfo::Read(u_int32_t expected_size) {
valid_ = false;
if (expected_size != MD_MISCINFO_SIZE &&
expected_size != MD_MISCINFO2_SIZE) {
return false;
}
if (!minidump_->ReadBytes(&misc_info_, expected_size))
return false;
if (minidump_->swap()) {
Swap(&misc_info_.size_of_info);
Swap(&misc_info_.flags1);
Swap(&misc_info_.process_id);
Swap(&misc_info_.process_create_time);
Swap(&misc_info_.process_user_time);
Swap(&misc_info_.process_kernel_time);
if (misc_info_.size_of_info > MD_MISCINFO_SIZE) {
Swap(&misc_info_.processor_max_mhz);
Swap(&misc_info_.processor_current_mhz);
Swap(&misc_info_.processor_mhz_limit);
Swap(&misc_info_.processor_max_idle_state);
Swap(&misc_info_.processor_current_idle_state);
}
}
if (misc_info_.size_of_info != expected_size)
return false;
valid_ = true;
return true;
}
void MinidumpMiscInfo::Print() {
if (!valid_)
return;
printf("MDRawMiscInfo\n");
printf(" size_of_info = %d\n", misc_info_.size_of_info);
printf(" flags1 = 0x%x\n", misc_info_.flags1);
printf(" process_id = 0x%x\n", misc_info_.process_id);
printf(" process_create_time = 0x%x\n",
misc_info_.process_create_time);
printf(" process_user_time = 0x%x\n",
misc_info_.process_user_time);
printf(" process_kernel_time = 0x%x\n",
misc_info_.process_kernel_time);
if (misc_info_.size_of_info > MD_MISCINFO_SIZE) {
printf(" processor_max_mhz = %d\n",
misc_info_.processor_max_mhz);
printf(" processor_current_mhz = %d\n",
misc_info_.processor_current_mhz);
printf(" processor_mhz_limit = %d\n",
misc_info_.processor_mhz_limit);
printf(" processor_max_idle_state = 0x%x\n",
misc_info_.processor_max_idle_state);
printf(" processor_current_idle_state = 0x%x\n",
misc_info_.processor_current_idle_state);
}
}
//
// Minidump
//
Minidump::Minidump(const string& path)
: header_(),
directory_(NULL),
stream_map_(NULL),
path_(path),
fd_(-1),
swap_(false),
valid_(false) {
}
Minidump::~Minidump() {
delete directory_;
delete stream_map_;
if (fd_ != -1)
close(fd_);
}
bool Minidump::Open() {
if (fd_ != -1) {
// The file is already open. Seek to the beginning, which is the position
// the file would be at if it were opened anew.
return SeekSet(0);
}
// O_BINARY is useful (and defined) on Windows. On other platforms, it's
// useless, and because it's defined as 0 above, harmless.
fd_ = open(path_.c_str(), O_RDONLY | O_BINARY);
if (fd_ == -1)
return false;
return true;
}
bool Minidump::Read() {
// Invalidate cached data.
delete directory_;
directory_ = NULL;
delete stream_map_;
stream_map_ = NULL;
valid_ = false;
if (!Open())
return false;
if (!ReadBytes(&header_, sizeof(MDRawHeader)))
return false;
if (header_.signature != MD_HEADER_SIGNATURE) {
// The file may be byte-swapped. Under the present architecture, these
// classes don't know or need to know what CPU (or endianness) the
// minidump was produced on in order to parse it. Use the signature as
// a byte order marker.
u_int32_t signature_swapped = header_.signature;
Swap(&signature_swapped);
if (signature_swapped != MD_HEADER_SIGNATURE) {
// This isn't a minidump or a byte-swapped minidump.
return false;
}
swap_ = true;
} else {
// The file is not byte-swapped. Set swap_ false (it may have been true
// if the object is being reused?)
swap_ = false;
}
if (swap_) {
Swap(&header_.signature);
Swap(&header_.version);
Swap(&header_.stream_count);
Swap(&header_.stream_directory_rva);
Swap(&header_.checksum);
Swap(&header_.time_date_stamp);
Swap(&header_.flags);
}
// Version check. The high 16 bits of header_.version contain something
// else "implementation specific."
if ((header_.version & 0x0000ffff) != MD_HEADER_VERSION) {
return false;
}
if (!SeekSet(header_.stream_directory_rva))
return false;
// TODO(mmentovai): verify rational size!
scoped_ptr<MinidumpDirectoryEntries> directory(
new MinidumpDirectoryEntries(header_.stream_count));
// Read the entire array in one fell swoop, instead of reading one entry
// at a time in the loop.
if (!ReadBytes(&(*directory)[0],
sizeof(MDRawDirectory) * header_.stream_count))
return false;
scoped_ptr<MinidumpStreamMap> stream_map(new MinidumpStreamMap());
for (unsigned int stream_index = 0;
stream_index < header_.stream_count;
++stream_index) {
MDRawDirectory* directory_entry = &(*directory)[stream_index];
if (swap_) {
Swap(&directory_entry->stream_type);
Swap(&directory_entry->location);
}
// Initialize the stream_map map, which speeds locating a stream by
// type.
unsigned int stream_type = directory_entry->stream_type;
switch (stream_type) {
case THREAD_LIST_STREAM:
case MODULE_LIST_STREAM:
case MEMORY_LIST_STREAM:
case EXCEPTION_STREAM:
case SYSTEM_INFO_STREAM:
case MISC_INFO_STREAM: {
if (stream_map->find(stream_type) != stream_map->end()) {
// Another stream with this type was already found. A minidump
// file should contain at most one of each of these stream types.
return false;
}
// Fall through to default
}
default: {
// Overwrites for stream types other than those above, but it's
// expected to be the user's burden in that case.
(*stream_map)[stream_type].stream_index = stream_index;
}
}
}
directory_ = directory.release();
stream_map_ = stream_map.release();
valid_ = true;
return true;
}
MinidumpThreadList* Minidump::GetThreadList() {
MinidumpThreadList* thread_list;
return GetStream(&thread_list);
}
MinidumpModuleList* Minidump::GetModuleList() {
MinidumpModuleList* module_list;
return GetStream(&module_list);
}
MinidumpMemoryList* Minidump::GetMemoryList() {
MinidumpMemoryList* memory_list;
return GetStream(&memory_list);
}
MinidumpException* Minidump::GetException() {
MinidumpException* exception;
return GetStream(&exception);
}
MinidumpSystemInfo* Minidump::GetSystemInfo() {
MinidumpSystemInfo* system_info;
return GetStream(&system_info);
}
MinidumpMiscInfo* Minidump::GetMiscInfo() {
MinidumpMiscInfo* misc_info;
return GetStream(&misc_info);
}
void Minidump::Print() {
if (!valid_)
return;
printf("MDRawHeader\n");
printf(" signature = 0x%x\n", header_.signature);
printf(" version = 0x%x\n", header_.version);
printf(" stream_count = %d\n", header_.stream_count);
printf(" stream_directory_rva = 0x%x\n", header_.stream_directory_rva);
printf(" checksum = 0x%x\n", header_.checksum);
struct tm* timestruct =
gmtime(reinterpret_cast<time_t*>(&header_.time_date_stamp));
char timestr[20];
strftime(timestr, 20, "%Y-%m-%d %H:%M:%S", timestruct);
printf(" time_date_stamp = 0x%x %s\n", header_.time_date_stamp,
timestr);
printf(" flags = 0x%llx\n", header_.flags);
printf("\n");
for (unsigned int stream_index = 0;
stream_index < header_.stream_count;
++stream_index) {
MDRawDirectory* directory_entry = &(*directory_)[stream_index];
printf("mDirectory[%d]\n", stream_index);
printf("MDRawDirectory\n");
printf(" stream_type = %d\n", directory_entry->stream_type);
printf(" location.data_size = %d\n",
directory_entry->location.data_size);
printf(" location.rva = 0x%x\n", directory_entry->location.rva);
printf("\n");
}
printf("Streams:\n");
for (MinidumpStreamMap::const_iterator iterator = stream_map_->begin();
iterator != stream_map_->end();
++iterator) {
u_int32_t stream_type = iterator->first;
MinidumpStreamInfo info = iterator->second;
printf(" stream type %2d at index %d\n", stream_type, info.stream_index);
}
printf("\n");
}
const MDRawDirectory* Minidump::GetDirectoryEntryAtIndex(unsigned int index)
const {
if (!valid_ || index >= header_.stream_count)
return NULL;
return &(*directory_)[index];
}
bool Minidump::ReadBytes(void* bytes, size_t count) {
// Can't check valid_ because Read needs to call this method before
// validity can be determined. The only member that this method
// depends on is mFD, and an unset or invalid fd may generate an
// error but should not cause a crash.
ssize_t bytes_read = read(fd_, bytes, count);
if (static_cast<size_t>(bytes_read) != count)
return false;
return true;
}
bool Minidump::SeekSet(off_t offset) {
// Can't check valid_ because Read needs to call this method before
// validity can be determined. The only member that this method
// depends on is mFD, and an unset or invalid fd may generate an
// error but should not cause a crash.
off_t sought = lseek(fd_, offset, SEEK_SET);
if (sought != offset)
return false;
return true;
}
string* Minidump::ReadString(off_t offset) {
if (!valid_)
return NULL;
if (!SeekSet(offset))
return NULL;
u_int32_t bytes;
if (!ReadBytes(&bytes, sizeof(bytes)))
return NULL;
if (swap_)
Swap(&bytes);
if (bytes % 2 != 0)
return NULL;
unsigned int utf16_words = bytes / 2;
// TODO(mmentovai): verify rational size!
vector<u_int16_t> string_utf16(utf16_words);
if (!ReadBytes(&string_utf16[0], bytes))
return NULL;
return UTF16ToUTF8(string_utf16, swap_);
}
bool Minidump::SeekToStreamType(u_int32_t stream_type,
u_int32_t* stream_length) {
if (!valid_ || !stream_length)
return false;
MinidumpStreamMap::const_iterator iterator = stream_map_->find(stream_type);
if (iterator == stream_map_->end()) {
// This stream type didn't exist in the directory.
return false;
}
MinidumpStreamInfo info = iterator->second;
if (info.stream_index >= header_.stream_count)
return false;
MDRawDirectory* directory_entry = &(*directory_)[info.stream_index];
if (!SeekSet(directory_entry->location.rva))
return false;
*stream_length = directory_entry->location.data_size;
return true;
}
template<typename T>
T* Minidump::GetStream(T** stream) {
// stream is a garbage parameter that's present only to account for C++'s
// inability to overload a method based solely on its return type.
if (!stream)
return NULL;
*stream = NULL;
if (!valid_)
return NULL;
u_int32_t stream_type = T::kStreamType;
MinidumpStreamMap::iterator iterator = stream_map_->find(stream_type);
if (iterator == stream_map_->end()) {
// This stream type didn't exist in the directory.
return NULL;
}
// Get a pointer so that the stored stream field can be altered.
MinidumpStreamInfo* info = &iterator->second;
if (info->stream) {
// This cast is safe because info.stream is only populated by this
// method, and there is a direct correlation between T and stream_type.
*stream = static_cast<T*>(info->stream);
return *stream;
}
u_int32_t stream_length;
if (!SeekToStreamType(stream_type, &stream_length))
return NULL;
scoped_ptr<T> new_stream(new T(this));
if (!new_stream->Read(stream_length))
return NULL;
*stream = new_stream.release();
info->stream = *stream;
return *stream;
}
} // namespace google_airbag
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