components/browser_watcher/dump_stability_report_main_win.cc - chromium/src.git - Git at Google

 // Copyright 2016 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // A utility for printing the contents of a postmortem stability minidump.

 #include <windows.h>  // NOLINT

 #include <dbghelp.h>

 #include "base/command_line.h"
 #include "base/files/file_path.h"
 #include "base/files/file_util.h"
 #include "base/files/scoped_file.h"
 #include "base/logging.h"
 #include "base/strings/stringprintf.h"
 #include "components/browser_watcher/stability_report.pb.h"

 namespace {

 const char kUsage[] =
     "Usage: %ls --minidump=<minidump file>\n"
     "\n"
     "  Dumps the contents of a postmortem minidump in a human readable way.\n";

 bool ParseCommandLine(const base::CommandLine* cmd,
                       base::FilePath* minidump_path) {
   *minidump_path = cmd->GetSwitchValuePath("minidump");
   if (minidump_path->empty()) {
     LOG(ERROR) << "Missing minidump file.\n";
     LOG(ERROR) << base::StringPrintf(kUsage, cmd->GetProgram().value().c_str());
     return false;
   }
   return true;
 }

 void Indent(FILE* out, int indent_level) {
   DCHECK(out);
   for (int i = 0; i < indent_level; ++i)
     fprintf(out, "  ");
 }

 void PrintUserData(
     FILE* out,
     int indent_level,
     const google::protobuf::Map<std::string, browser_watcher::TypedValue>&
         user_data) {
   DCHECK(out);
   Indent(out, indent_level);
   fprintf(out, "User data (%zu)\n", user_data.size());
   for (const auto& kv : user_data) {
     Indent(out, indent_level + 1);
     fprintf(out, "%s : ", kv.first.c_str());
     const browser_watcher::TypedValue& value = kv.second;
     switch (kv.second.value_case()) {
       case browser_watcher::TypedValue::kBytesValue: {
         const std::string& bytes_value = value.bytes_value();
         for (size_t i = 0; i < bytes_value.size(); ++i)
           fprintf(out, "%02X ", bytes_value.at(i));
         fprintf(out, "\n");
         break;
       }
       case browser_watcher::TypedValue::kBytesReference:
         fprintf(out, "bytes reference (address: %llX, size: %llX)\n",
                 value.bytes_reference().address(),
                 value.bytes_reference().size());
         break;
       case browser_watcher::TypedValue::kStringValue:
         fprintf(out, "\"%s\"\n", value.string_value().c_str());
         break;
       case browser_watcher::TypedValue::kStringReference:
         fprintf(out, "string reference (address: %llX, size: %llX)\n",
                 value.string_reference().address(),
                 value.string_reference().size());
         break;
       case browser_watcher::TypedValue::kCharValue:
         fprintf(out, "'%s'\n", value.char_value().c_str());
         break;
       case browser_watcher::TypedValue::kBoolValue:
         fprintf(out, "%s\n", value.bool_value() ? "true" : "false");
         break;
       case browser_watcher::TypedValue::kSignedValue:
         fprintf(out, "%lld\n", value.signed_value());
         break;
       case browser_watcher::TypedValue::kUnsignedValue:
         fprintf(out, "%llu\n", value.unsigned_value());
         break;
       case browser_watcher::TypedValue::VALUE_NOT_SET:
         fprintf(out, "<not set>\n");
         break;
     }
   }
 }

 void PrintActivity(FILE* out,
                    int indent_level,
                    const browser_watcher::Activity& activity) {
   DCHECK(out);
   Indent(out, indent_level);
   fprintf(out, "Activity\n");
   Indent(out, indent_level + 1);
   fprintf(out, "type: %d\n", activity.type());
   Indent(out, indent_level + 1);
   fprintf(out, "time: %lld\n", activity.time());
   Indent(out, indent_level + 1);
   fprintf(out, "address: %llX\n", activity.address());
   switch (activity.type()) {
     case browser_watcher::Activity::UNKNOWN:
       break;
     case browser_watcher::Activity::ACT_TASK_RUN:
       Indent(out, indent_level + 1);
       fprintf(out, "origin_address: %llX\n", activity.origin_address());
       fprintf(out, "task_sequence_id: %lld\n", activity.task_sequence_id());
       break;
     case browser_watcher::Activity::ACT_LOCK_ACQUIRE:
       Indent(out, indent_level + 1);
       fprintf(out, "lock_address: %llX\n", activity.lock_address());
       break;
     case browser_watcher::Activity::ACT_EVENT_WAIT:
       Indent(out, indent_level + 1);
       fprintf(out, "event_address: %llX\n", activity.event_address());
       break;
     case browser_watcher::Activity::ACT_THREAD_JOIN:
       Indent(out, indent_level + 1);
       fprintf(out, "thread_id: %lld\n", activity.thread_id());
       break;
     case browser_watcher::Activity::ACT_PROCESS_WAIT:
       Indent(out, indent_level + 1);
       fprintf(out, "process_id: %lld\n", activity.process_id());
       break;
     case browser_watcher::Activity::ACT_GENERIC:
       Indent(out, indent_level + 1);
       fprintf(out, "id: %u, data: %d\n", activity.generic_id(),
               activity.generic_data());
       break;
   }

   PrintUserData(out, indent_level + 1, activity.user_data());
 }

 void PrintProcessState(FILE* out,
                        const browser_watcher::ProcessState& process) {
   std::string process_type;
   switch (process.process_type()) {
     case browser_watcher::ProcessState::UNKNOWN_PROCESS:
       process_type = "unknown type";
       break;
     case browser_watcher::ProcessState::BROWSER_PROCESS:
       process_type = "browser";
       break;
     case browser_watcher::ProcessState::WATCHER_PROCESS:
       process_type = "watcher";
       break;
     default:
       base::SStringPrintf(&process_type, "process type %d",
                           process.process_type());
       break;
   }

   fprintf(out, "Process %lld (%s, %d threads)\n", process.process_id(),
           process_type.c_str(), process.threads_size());

   if (process.has_memory_state() &&
       process.memory_state().has_windows_memory()) {
     const auto& windows_memory = process.memory_state().windows_memory();
     if (windows_memory.has_process_private_usage()) {
       fprintf(out, "process_private_usage: %u pages\n",
               windows_memory.process_private_usage());
     }
     if (windows_memory.has_process_peak_workingset_size()) {
       fprintf(out, "process_peak_workingset_size: %u pages\n",
               windows_memory.process_peak_workingset_size());
     }
     if (windows_memory.has_process_peak_pagefile_usage()) {
       fprintf(out, "process_peak_pagefile_usage: %u pages\n",
               windows_memory.process_peak_pagefile_usage());
     }
     if (windows_memory.has_process_allocation_attempt()) {
       fprintf(out, "process_allocation_attempt: %u bytes\n",
               windows_memory.process_allocation_attempt());
     }
     if (windows_memory.has_process_handle_count()) {
       fprintf(out, "process_handle_count: %u handles\n",
               windows_memory.process_handle_count());
     }
   }

   for (const browser_watcher::ThreadState& thread : process.threads()) {
     fprintf(out, "Thread %lld (%s) : %d activities\n", thread.thread_id(),
             thread.thread_name().c_str(), thread.activity_count());
     for (const browser_watcher::Activity& activity : thread.activities())
       PrintActivity(out, 1, activity);
   }

   PrintUserData(out, 1, process.data());
 }

 // TODO(manzagop): flesh out as StabilityReport gets fleshed out.
 void PrintReport(FILE* out, const browser_watcher::StabilityReport& report) {
   if (report.has_system_memory_state() &&
       report.system_memory_state().has_windows_memory()) {
     const auto& windows_memory = report.system_memory_state().windows_memory();

     if (windows_memory.has_system_commit_limit()) {
       fprintf(out, "system_commit_limit: %u pages\n",
               windows_memory.system_commit_limit());
     }
     if (windows_memory.has_system_commit_remaining()) {
       fprintf(out, "system_commit_remaining: %u pages\n",
               windows_memory.system_commit_remaining());
     }
     if (windows_memory.has_system_handle_count()) {
       fprintf(out, "system_handle_count: %u handles\n",
               windows_memory.system_handle_count());
     }
   }
   PrintUserData(out, 0, report.global_data());
   for (int i = 0; i < report.process_states_size(); ++i) {
     const browser_watcher::ProcessState process = report.process_states(i);
     PrintProcessState(out, process);
   }
 }

 bool GetStabilityStreamRvaAndSize(RVA directory_rva,
                                   ULONG32 stream_count,
                                   FILE* file,
                                   RVA* report_rva,
                                   ULONG32* report_size_bytes) {
   std::vector<MINIDUMP_DIRECTORY> directory;
   directory.resize(stream_count);

   CHECK_EQ(0, fseek(file, directory_rva, SEEK_SET));
   CHECK_EQ(stream_count, fread(directory.data(), sizeof(MINIDUMP_DIRECTORY),
                                stream_count, file));

   for (const MINIDUMP_DIRECTORY& entry : directory) {
     constexpr ULONG32 kStabilityStream = static_cast<ULONG32>(0x4B6B0002);
     if (entry.StreamType == kStabilityStream) {
       *report_rva = entry.Location.Rva;
       *report_size_bytes = entry.Location.DataSize;
       return true;
     }
   }

   return false;
 }

 int Main(int argc, char** argv) {
   base::CommandLine::Init(argc, argv);

   // Get the dump.
   base::FilePath minidump_path;
   if (!ParseCommandLine(base::CommandLine::ForCurrentProcess(), &minidump_path))
     return 1;

   // Read the minidump to extract the proto.
   base::ScopedFILE minidump_file;
   minidump_file.reset(base::OpenFile(minidump_path, "rb"));
   CHECK(minidump_file.get());

   // Read the header.
   // TODO(manzagop): leverage Crashpad to do this.
   MINIDUMP_HEADER header = {};
   CHECK_EQ(1U, fread(&header, sizeof(header), 1U, minidump_file.get()));
   CHECK_EQ(static_cast<ULONG32>(MINIDUMP_SIGNATURE), header.Signature);
   fprintf(stdout, "Number of streams: %u\n", header.NumberOfStreams);
   RVA directory_rva = header.StreamDirectoryRva;

   RVA report_rva;
   ULONG32 report_size_bytes;
   CHECK(GetStabilityStreamRvaAndSize(directory_rva, header.NumberOfStreams,
                                      minidump_file.get(), &report_rva,
                                      &report_size_bytes));

   // Read the serialized stability report.
   std::string serialized_report;
   serialized_report.resize(report_size_bytes);
   CHECK_EQ(0, fseek(minidump_file.get(), report_rva, SEEK_SET));
   CHECK_EQ(report_size_bytes, fread(&serialized_report.at(0), 1,
                                     report_size_bytes, minidump_file.get()));

   browser_watcher::StabilityReport report;
   CHECK(report.ParseFromString(serialized_report));

   // Note: we can't use the usual protocol buffer human readable API due to
   // the use of optimize_for = LITE_RUNTIME.
   PrintReport(stdout, report);

   return 0;
 }

 }  // namespace

 int main(int argc, char** argv) {
   return Main(argc, argv);
 }
	// Copyright 2016 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// A utility for printing the contents of a postmortem stability minidump.

	#include <windows.h> // NOLINT

	#include <dbghelp.h>

	#include "base/command_line.h"
	#include "base/files/file_path.h"
	#include "base/files/file_util.h"
	#include "base/files/scoped_file.h"
	#include "base/logging.h"
	#include "base/strings/stringprintf.h"
	#include "components/browser_watcher/stability_report.pb.h"

	namespace {

	const char kUsage[] =
	"Usage: %ls --minidump=<minidump file>\n"
	"\n"
	" Dumps the contents of a postmortem minidump in a human readable way.\n";

	bool ParseCommandLine(const base::CommandLine* cmd,
	base::FilePath* minidump_path) {
	*minidump_path = cmd->GetSwitchValuePath("minidump");
	if (minidump_path->empty()) {
	LOG(ERROR) << "Missing minidump file.\n";
	LOG(ERROR) << base::StringPrintf(kUsage, cmd->GetProgram().value().c_str());
	return false;
	}
	return true;
	}

	void Indent(FILE* out, int indent_level) {
	DCHECK(out);
	for (int i = 0; i < indent_level; ++i)
	fprintf(out, " ");
	}

	void PrintUserData(
	FILE* out,
	int indent_level,
	const google::protobuf::Map<std::string, browser_watcher::TypedValue>&
	user_data) {
	DCHECK(out);
	Indent(out, indent_level);
	fprintf(out, "User data (%zu)\n", user_data.size());
	for (const auto& kv : user_data) {
	Indent(out, indent_level + 1);
	fprintf(out, "%s : ", kv.first.c_str());
	const browser_watcher::TypedValue& value = kv.second;
	switch (kv.second.value_case()) {
	case browser_watcher::TypedValue::kBytesValue: {
	const std::string& bytes_value = value.bytes_value();
	for (size_t i = 0; i < bytes_value.size(); ++i)
	fprintf(out, "%02X ", bytes_value.at(i));
	fprintf(out, "\n");
	break;
	}
	case browser_watcher::TypedValue::kBytesReference:
	fprintf(out, "bytes reference (address: %llX, size: %llX)\n",
	value.bytes_reference().address(),
	value.bytes_reference().size());
	break;
	case browser_watcher::TypedValue::kStringValue:
	fprintf(out, "\"%s\"\n", value.string_value().c_str());
	break;
	case browser_watcher::TypedValue::kStringReference:
	fprintf(out, "string reference (address: %llX, size: %llX)\n",
	value.string_reference().address(),
	value.string_reference().size());
	break;
	case browser_watcher::TypedValue::kCharValue:
	fprintf(out, "'%s'\n", value.char_value().c_str());
	break;
	case browser_watcher::TypedValue::kBoolValue:
	fprintf(out, "%s\n", value.bool_value() ? "true" : "false");
	break;
	case browser_watcher::TypedValue::kSignedValue:
	fprintf(out, "%lld\n", value.signed_value());
	break;
	case browser_watcher::TypedValue::kUnsignedValue:
	fprintf(out, "%llu\n", value.unsigned_value());
	break;
	case browser_watcher::TypedValue::VALUE_NOT_SET:
	fprintf(out, "<not set>\n");
	break;
	}
	}
	}

	void PrintActivity(FILE* out,
	int indent_level,
	const browser_watcher::Activity& activity) {
	DCHECK(out);
	Indent(out, indent_level);
	fprintf(out, "Activity\n");
	Indent(out, indent_level + 1);
	fprintf(out, "type: %d\n", activity.type());
	Indent(out, indent_level + 1);
	fprintf(out, "time: %lld\n", activity.time());
	Indent(out, indent_level + 1);
	fprintf(out, "address: %llX\n", activity.address());
	switch (activity.type()) {
	case browser_watcher::Activity::UNKNOWN:
	break;
	case browser_watcher::Activity::ACT_TASK_RUN:
	Indent(out, indent_level + 1);
	fprintf(out, "origin_address: %llX\n", activity.origin_address());
	fprintf(out, "task_sequence_id: %lld\n", activity.task_sequence_id());
	break;
	case browser_watcher::Activity::ACT_LOCK_ACQUIRE:
	Indent(out, indent_level + 1);
	fprintf(out, "lock_address: %llX\n", activity.lock_address());
	break;
	case browser_watcher::Activity::ACT_EVENT_WAIT:
	Indent(out, indent_level + 1);
	fprintf(out, "event_address: %llX\n", activity.event_address());
	break;
	case browser_watcher::Activity::ACT_THREAD_JOIN:
	Indent(out, indent_level + 1);
	fprintf(out, "thread_id: %lld\n", activity.thread_id());
	break;
	case browser_watcher::Activity::ACT_PROCESS_WAIT:
	Indent(out, indent_level + 1);
	fprintf(out, "process_id: %lld\n", activity.process_id());
	break;
	case browser_watcher::Activity::ACT_GENERIC:
	Indent(out, indent_level + 1);
	fprintf(out, "id: %u, data: %d\n", activity.generic_id(),
	activity.generic_data());
	break;
	}

	PrintUserData(out, indent_level + 1, activity.user_data());
	}

	void PrintProcessState(FILE* out,
	const browser_watcher::ProcessState& process) {
	std::string process_type;
	switch (process.process_type()) {
	case browser_watcher::ProcessState::UNKNOWN_PROCESS:
	process_type = "unknown type";
	break;
	case browser_watcher::ProcessState::BROWSER_PROCESS:
	process_type = "browser";
	break;
	case browser_watcher::ProcessState::WATCHER_PROCESS:
	process_type = "watcher";
	break;
	default:
	base::SStringPrintf(&process_type, "process type %d",
	process.process_type());
	break;
	}

	fprintf(out, "Process %lld (%s, %d threads)\n", process.process_id(),
	process_type.c_str(), process.threads_size());

	if (process.has_memory_state() &&
	process.memory_state().has_windows_memory()) {
	const auto& windows_memory = process.memory_state().windows_memory();
	if (windows_memory.has_process_private_usage()) {
	fprintf(out, "process_private_usage: %u pages\n",
	windows_memory.process_private_usage());
	}
	if (windows_memory.has_process_peak_workingset_size()) {
	fprintf(out, "process_peak_workingset_size: %u pages\n",
	windows_memory.process_peak_workingset_size());
	}
	if (windows_memory.has_process_peak_pagefile_usage()) {
	fprintf(out, "process_peak_pagefile_usage: %u pages\n",
	windows_memory.process_peak_pagefile_usage());
	}
	if (windows_memory.has_process_allocation_attempt()) {
	fprintf(out, "process_allocation_attempt: %u bytes\n",
	windows_memory.process_allocation_attempt());
	}
	if (windows_memory.has_process_handle_count()) {
	fprintf(out, "process_handle_count: %u handles\n",
	windows_memory.process_handle_count());
	}
	}

	for (const browser_watcher::ThreadState& thread : process.threads()) {
	fprintf(out, "Thread %lld (%s) : %d activities\n", thread.thread_id(),
	thread.thread_name().c_str(), thread.activity_count());
	for (const browser_watcher::Activity& activity : thread.activities())
	PrintActivity(out, 1, activity);
	}

	PrintUserData(out, 1, process.data());
	}

	// TODO(manzagop): flesh out as StabilityReport gets fleshed out.
	void PrintReport(FILE* out, const browser_watcher::StabilityReport& report) {
	if (report.has_system_memory_state() &&
	report.system_memory_state().has_windows_memory()) {
	const auto& windows_memory = report.system_memory_state().windows_memory();

	if (windows_memory.has_system_commit_limit()) {
	fprintf(out, "system_commit_limit: %u pages\n",
	windows_memory.system_commit_limit());
	}
	if (windows_memory.has_system_commit_remaining()) {
	fprintf(out, "system_commit_remaining: %u pages\n",
	windows_memory.system_commit_remaining());
	}
	if (windows_memory.has_system_handle_count()) {
	fprintf(out, "system_handle_count: %u handles\n",
	windows_memory.system_handle_count());
	}
	}
	PrintUserData(out, 0, report.global_data());
	for (int i = 0; i < report.process_states_size(); ++i) {
	const browser_watcher::ProcessState process = report.process_states(i);
	PrintProcessState(out, process);
	}
	}

	bool GetStabilityStreamRvaAndSize(RVA directory_rva,
	ULONG32 stream_count,
	FILE* file,
	RVA* report_rva,
	ULONG32* report_size_bytes) {
	std::vector<MINIDUMP_DIRECTORY> directory;
	directory.resize(stream_count);

	CHECK_EQ(0, fseek(file, directory_rva, SEEK_SET));
	CHECK_EQ(stream_count, fread(directory.data(), sizeof(MINIDUMP_DIRECTORY),
	stream_count, file));

	for (const MINIDUMP_DIRECTORY& entry : directory) {
	constexpr ULONG32 kStabilityStream = static_cast<ULONG32>(0x4B6B0002);
	if (entry.StreamType == kStabilityStream) {
	*report_rva = entry.Location.Rva;
	*report_size_bytes = entry.Location.DataSize;
	return true;
	}
	}

	return false;
	}

	int Main(int argc, char** argv) {
	base::CommandLine::Init(argc, argv);

	// Get the dump.
	base::FilePath minidump_path;
	if (!ParseCommandLine(base::CommandLine::ForCurrentProcess(), &minidump_path))
	return 1;

	// Read the minidump to extract the proto.
	base::ScopedFILE minidump_file;
	minidump_file.reset(base::OpenFile(minidump_path, "rb"));
	CHECK(minidump_file.get());

	// Read the header.
	// TODO(manzagop): leverage Crashpad to do this.
	MINIDUMP_HEADER header = {};
	CHECK_EQ(1U, fread(&header, sizeof(header), 1U, minidump_file.get()));
	CHECK_EQ(static_cast<ULONG32>(MINIDUMP_SIGNATURE), header.Signature);
	fprintf(stdout, "Number of streams: %u\n", header.NumberOfStreams);
	RVA directory_rva = header.StreamDirectoryRva;

	RVA report_rva;
	ULONG32 report_size_bytes;
	CHECK(GetStabilityStreamRvaAndSize(directory_rva, header.NumberOfStreams,
	minidump_file.get(), &report_rva,
	&report_size_bytes));

	// Read the serialized stability report.
	std::string serialized_report;
	serialized_report.resize(report_size_bytes);
	CHECK_EQ(0, fseek(minidump_file.get(), report_rva, SEEK_SET));
	CHECK_EQ(report_size_bytes, fread(&serialized_report.at(0), 1,
	report_size_bytes, minidump_file.get()));

	browser_watcher::StabilityReport report;
	CHECK(report.ParseFromString(serialized_report));

	// Note: we can't use the usual protocol buffer human readable API due to
	// the use of optimize_for = LITE_RUNTIME.
	PrintReport(stdout, report);

	return 0;
	}

	} // namespace

	int main(int argc, char** argv) {
	return Main(argc, argv);
	}