net/tools/stress_cache/stress_cache.cc - cobalt - Git at Google

 // Copyright (c) 2012 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.

 // This is a simple application that stress-tests the crash recovery of the disk
 // cache. The main application starts a copy of itself on a loop, checking the
 // exit code of the child process. When the child dies in an unexpected way,
 // the main application quits.

 // The child application has two threads: one to exercise the cache in an
 // infinite loop, and another one to asynchronously kill the process.

 // A regular build should never crash.
 // To test that the disk cache doesn't generate critical errors with regular
 // application level crashes, edit stress_support.h.

 #include <string>
 #include <vector>

 #include "base/at_exit.h"
 #include "base/bind.h"
 #include "base/bind_helpers.h"
 #include "base/command_line.h"
 #include "base/debug/debugger.h"
 #include "base/files/file_path.h"
 #include "base/location.h"
 #include "base/logging.h"
 #include "base/message_loop/message_loop.h"
 #include "base/path_service.h"
 #include "base/process/launch.h"
 #include "base/process/process.h"
 #include "base/run_loop.h"
 #include "base/single_thread_task_runner.h"
 #include "base/strings/string_number_conversions.h"
 #include "base/strings/string_util.h"
 #include "base/strings/utf_string_conversions.h"
 #include "base/threading/platform_thread.h"
 #include "base/threading/thread.h"
 #include "base/threading/thread_task_runner_handle.h"
 #include "net/base/io_buffer.h"
 #include "net/base/net_errors.h"
 #include "net/base/test_completion_callback.h"
 #include "net/disk_cache/blockfile/backend_impl.h"
 #include "net/disk_cache/blockfile/stress_support.h"
 #include "net/disk_cache/blockfile/trace.h"
 #include "net/disk_cache/disk_cache.h"
 #include "net/disk_cache/disk_cache_test_util.h"

 #if defined(OS_WIN)
 #include "base/logging_win.h"
 #include "starboard/memory.h"
 #endif

 using base::Time;

 const int kError = -1;
 const int kExpectedCrash = 100;

 // Starts a new process.
 int RunSlave(int iteration) {
   base::FilePath exe;
   base::PathService::Get(base::FILE_EXE, &exe);

   base::CommandLine cmdline(exe);
   cmdline.AppendArg(base::IntToString(iteration));

   base::Process process = base::LaunchProcess(cmdline, base::LaunchOptions());
   if (!process.IsValid()) {
     printf("Unable to run test\n");
     return kError;
   }

   int exit_code;
   if (!process.WaitForExit(&exit_code)) {
     printf("Unable to get return code\n");
     return kError;
   }
   return exit_code;
 }

 // Main loop for the master process.
 int MasterCode() {
   for (int i = 0; i < 100000; i++) {
     int ret = RunSlave(i);
     if (kExpectedCrash != ret)
       return ret;
   }

   printf("More than enough...\n");

   return 0;
 }

 // -----------------------------------------------------------------------

 std::string GenerateStressKey() {
   char key[20 * 1024];
   size_t size = 50 + rand() % 20000;
   CacheTestFillBuffer(key, size, true);

   key[size - 1] = '\0';
   return std::string(key);
 }

 // kNumKeys is meant to be enough to have about 3x or 4x iterations before
 // the process crashes.
 #ifdef NDEBUG
 const int kNumKeys = 4000;
 #else
 const int kNumKeys = 1200;
 #endif
 const int kNumEntries = 30;
 const int kBufferSize = 2000;
 const int kReadSize = 20;

 // Things that an entry can be doing.
 enum Operation { NONE, OPEN, CREATE, READ, WRITE, DOOM };

 // This class encapsulates a cache entry and the operations performed on that
 // entry. An entry is opened or created as needed, the current content is then
 // verified and then something is written to the entry. At that point, the
 // |state_| becomes NONE again, waiting for another write, unless the entry is
 // closed or deleted.
 class EntryWrapper {
  public:
   EntryWrapper() : entry_(nullptr), state_(NONE) {
     buffer_ = base::MakeRefCounted<net::IOBuffer>(kBufferSize);
     memset(buffer_->data(), 'k', kBufferSize);
   }

   Operation state() const { return state_; }

   void DoOpen(int key);

  private:
   void OnOpenDone(int key, int result);
   void DoRead();
   void OnReadDone(int result);
   void DoWrite();
   void OnWriteDone(int size, int result);
   void DoDelete(const std::string& key);
   void OnDeleteDone(int result);
   void DoIdle();

   disk_cache::Entry* entry_;
   Operation state_;
   scoped_refptr<net::IOBuffer> buffer_;
 };

 // The data that the main thread is working on.
 struct Data {
   Data() : pendig_operations(0), writes(0), iteration(0), cache(nullptr) {}

   int pendig_operations;  // Counter of simultaneous operations.
   int writes;             // How many writes since this iteration started.
   int iteration;          // The iteration (number of crashes).
   disk_cache::BackendImpl* cache;
   std::string keys[kNumKeys];
   EntryWrapper entries[kNumEntries];
 };

 Data* g_data = nullptr;

 void EntryWrapper::DoOpen(int key) {
   DCHECK_EQ(state_, NONE);
   if (entry_)
     return DoRead();

   state_ = OPEN;
   int rv = g_data->cache->OpenEntry(
       g_data->keys[key], net::HIGHEST, &entry_,
       base::Bind(&EntryWrapper::OnOpenDone, base::Unretained(this), key));
   if (rv != net::ERR_IO_PENDING)
     OnOpenDone(key, rv);
 }

 void EntryWrapper::OnOpenDone(int key, int result) {
   if (result == net::OK)
     return DoRead();

   CHECK_EQ(state_, OPEN);
   state_ = CREATE;
   result = g_data->cache->CreateEntry(
       g_data->keys[key], net::HIGHEST, &entry_,
       base::Bind(&EntryWrapper::OnOpenDone, base::Unretained(this), key));
   if (result != net::ERR_IO_PENDING)
     OnOpenDone(key, result);
 }

 void EntryWrapper::DoRead() {
   int current_size = entry_->GetDataSize(0);
   if (!current_size)
     return DoWrite();

   state_ = READ;
   memset(buffer_->data(), 'k', kReadSize);
   int rv = entry_->ReadData(
       0, 0, buffer_.get(), kReadSize,
       base::Bind(&EntryWrapper::OnReadDone, base::Unretained(this)));
   if (rv != net::ERR_IO_PENDING)
     OnReadDone(rv);
 }

 void EntryWrapper::OnReadDone(int result) {
   DCHECK_EQ(state_, READ);
   CHECK_EQ(result, kReadSize);
   CHECK_EQ(0, memcmp(buffer_->data(), "Write: ", 7));
   DoWrite();
 }

 void EntryWrapper::DoWrite() {
   bool truncate = (rand() % 2 == 0);
   int size = kBufferSize - (rand() % 20) * kBufferSize / 20;
   state_ = WRITE;
   base::snprintf(buffer_->data(), kBufferSize,
                  "Write: %d iter: %d, size: %d, truncate: %d     ",
                  g_data->writes, g_data->iteration, size, truncate ? 1 : 0);
   int rv = entry_->WriteData(
       0, 0, buffer_.get(), size,
       base::Bind(&EntryWrapper::OnWriteDone, base::Unretained(this), size),
       truncate);
   if (rv != net::ERR_IO_PENDING)
     OnWriteDone(size, rv);
 }

 void EntryWrapper::OnWriteDone(int size, int result) {
   DCHECK_EQ(state_, WRITE);
   CHECK_EQ(size, result);
   if (!(g_data->writes++ % 100))
     printf("Entries: %d    \r", g_data->writes);

   int random = rand() % 100;
   std::string key = entry_->GetKey();
   if (random > 90)
     return DoDelete(key);  // 10% delete then close.

   if (random > 60) {  // 20% close.
     entry_->Close();
     entry_ = nullptr;
   }

   if (random > 80)
     return DoDelete(key);  // 10% close then delete.

   DoIdle();  // 60% do another write later.
 }

 void EntryWrapper::DoDelete(const std::string& key) {
   state_ = DOOM;
   int rv = g_data->cache->DoomEntry(
       key, net::HIGHEST,
       base::Bind(&EntryWrapper::OnDeleteDone, base::Unretained(this)));
   if (rv != net::ERR_IO_PENDING)
     OnDeleteDone(rv);
 }

 void EntryWrapper::OnDeleteDone(int result) {
   DCHECK_EQ(state_, DOOM);
   if (entry_) {
     entry_->Close();
     entry_ = nullptr;
   }
   DoIdle();
 }

 void LoopTask();

 void EntryWrapper::DoIdle() {
   state_ = NONE;
   g_data->pendig_operations--;
   DCHECK(g_data->pendig_operations);
   base::ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
                                                 base::Bind(&LoopTask));
 }

 // The task that keeps the main thread busy. Whenever an entry becomes idle this
 // task is executed again.
 void LoopTask() {
   if (g_data->pendig_operations >= kNumEntries)
     return;

   int slot = rand() % kNumEntries;
   if (g_data->entries[slot].state() == NONE) {
     // Each slot will have some keys assigned to it so that the same entry will
     // not be open by two slots, which means that the state is well known at
     // all times.
     int keys_per_entry = kNumKeys / kNumEntries;
     int key = rand() % keys_per_entry + keys_per_entry * slot;
     g_data->pendig_operations++;
     g_data->entries[slot].DoOpen(key);
   }

   base::ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
                                                 base::Bind(&LoopTask));
 }

 // This thread will loop forever, adding and removing entries from the cache.
 // iteration is the current crash cycle, so the entries on the cache are marked
 // to know which instance of the application wrote them.
 void StressTheCache(int iteration) {
   int cache_size = 0x2000000;  // 32MB.
   uint32_t mask = 0xfff;       // 4096 entries.

   base::FilePath path;
   base::PathService::Get(base::DIR_TEMP, &path);
   path = path.AppendASCII("cache_test_stress");

   base::Thread cache_thread("CacheThread");
   if (!cache_thread.StartWithOptions(
           base::Thread::Options(base::MessageLoop::TYPE_IO, 0)))
     return;

   g_data = new Data();
   g_data->iteration = iteration;
   g_data->cache = new disk_cache::BackendImpl(
       path, mask, cache_thread.task_runner().get(), NULL);
   g_data->cache->SetMaxSize(cache_size);
   g_data->cache->SetFlags(disk_cache::kNoLoadProtection);

   net::TestCompletionCallback cb;
   int rv = g_data->cache->Init(cb.callback());

   if (cb.GetResult(rv) != net::OK) {
     printf("Unable to initialize cache.\n");
     return;
   }
   printf("Iteration %d, initial entries: %d\n", iteration,
          g_data->cache->GetEntryCount());

   int seed = static_cast<int>(Time::Now().ToInternalValue());
   srand(seed);

   for (int i = 0; i < kNumKeys; i++)
     g_data->keys[i] = GenerateStressKey();

   base::ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
                                                 base::Bind(&LoopTask));
   base::RunLoop().Run();
 }

 // We want to prevent the timer thread from killing the process while we are
 // waiting for the debugger to attach.
 bool g_crashing = false;

 // RunSoon() and CrashCallback() reference each other, unfortunately.
 void RunSoon(scoped_refptr<base::SingleThreadTaskRunner> task_runner);

 void CrashCallback() {
   // Keep trying to run.
   RunSoon(base::ThreadTaskRunnerHandle::Get());

   if (g_crashing)
     return;

   if (rand() % 100 > 30) {
     printf("sweet death...\n");

     // Terminate the current process without doing normal process-exit cleanup.
     base::Process::TerminateCurrentProcessImmediately(kExpectedCrash);
   }
 }

 void RunSoon(scoped_refptr<base::SingleThreadTaskRunner> task_runner) {
   const base::TimeDelta kTaskDelay = base::TimeDelta::FromSeconds(10);
   task_runner->PostDelayedTask(FROM_HERE, base::Bind(&CrashCallback),
                                kTaskDelay);
 }

 // We leak everything here :)
 bool StartCrashThread() {
   base::Thread* thread = new base::Thread("party_crasher");
   if (!thread->Start())
     return false;

   RunSoon(thread->task_runner());
   return true;
 }

 void CrashHandler(const char* file,
                   int line,
                   const base::StringPiece str,
                   const base::StringPiece stack_trace) {
   g_crashing = true;
   base::debug::BreakDebugger();
 }

 bool MessageHandler(int severity, const char* file, int line,
                     size_t message_start, const std::string& str) {
   const size_t kMaxMessageLen = 48;
   char message[kMaxMessageLen];
   size_t len = std::min(str.length() - message_start, kMaxMessageLen - 1);

   memcpy(message, str.c_str() + message_start, len);
   message[len] = '\0';
 #if !defined(DISK_CACHE_TRACE_TO_LOG)
   disk_cache::Trace("%s", message);
 #endif
   return false;
 }

 // -----------------------------------------------------------------------

 #if defined(OS_WIN)
 // {B9A153D4-31C3-48e4-9ABF-D54383F14A0D}
 const GUID kStressCacheTraceProviderName = {
     0xb9a153d4, 0x31c3, 0x48e4,
         { 0x9a, 0xbf, 0xd5, 0x43, 0x83, 0xf1, 0x4a, 0xd } };
 #endif

 int main(int argc, const char* argv[]) {
   // Setup an AtExitManager so Singleton objects will be destructed.
   base::AtExitManager at_exit_manager;

   if (argc < 2)
     return MasterCode();

   logging::ScopedLogAssertHandler scoped_assert_handler(
       base::Bind(CrashHandler));
   logging::SetLogMessageHandler(MessageHandler);

 #if defined(OS_WIN)
   logging::LogEventProvider::Initialize(kStressCacheTraceProviderName);
 #else
   base::CommandLine::Init(argc, argv);
   logging::LoggingSettings settings;
   settings.logging_dest = logging::LOG_TO_SYSTEM_DEBUG_LOG;
   logging::InitLogging(settings);
 #endif

   // Some time for the memory manager to flush stuff.
   base::PlatformThread::Sleep(base::TimeDelta::FromSeconds(3));
   base::MessageLoopForIO message_loop;

   char* end;
   long int iteration = strtol(argv[1], &end, 0);

   if (!StartCrashThread()) {
     printf("failed to start thread\n");
     return kError;
   }

   StressTheCache(iteration);
   return 0;
 }
	// Copyright (c) 2012 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.

	// This is a simple application that stress-tests the crash recovery of the disk
	// cache. The main application starts a copy of itself on a loop, checking the
	// exit code of the child process. When the child dies in an unexpected way,
	// the main application quits.

	// The child application has two threads: one to exercise the cache in an
	// infinite loop, and another one to asynchronously kill the process.

	// A regular build should never crash.
	// To test that the disk cache doesn't generate critical errors with regular
	// application level crashes, edit stress_support.h.

	#include <string>
	#include <vector>

	#include "base/at_exit.h"
	#include "base/bind.h"
	#include "base/bind_helpers.h"
	#include "base/command_line.h"
	#include "base/debug/debugger.h"
	#include "base/files/file_path.h"
	#include "base/location.h"
	#include "base/logging.h"
	#include "base/message_loop/message_loop.h"
	#include "base/path_service.h"
	#include "base/process/launch.h"
	#include "base/process/process.h"
	#include "base/run_loop.h"
	#include "base/single_thread_task_runner.h"
	#include "base/strings/string_number_conversions.h"
	#include "base/strings/string_util.h"
	#include "base/strings/utf_string_conversions.h"
	#include "base/threading/platform_thread.h"
	#include "base/threading/thread.h"
	#include "base/threading/thread_task_runner_handle.h"
	#include "net/base/io_buffer.h"
	#include "net/base/net_errors.h"
	#include "net/base/test_completion_callback.h"
	#include "net/disk_cache/blockfile/backend_impl.h"
	#include "net/disk_cache/blockfile/stress_support.h"
	#include "net/disk_cache/blockfile/trace.h"
	#include "net/disk_cache/disk_cache.h"
	#include "net/disk_cache/disk_cache_test_util.h"

	#if defined(OS_WIN)
	#include "base/logging_win.h"
	#include "starboard/memory.h"
	#endif

	using base::Time;

	const int kError = -1;
	const int kExpectedCrash = 100;

	// Starts a new process.
	int RunSlave(int iteration) {
	base::FilePath exe;
	base::PathService::Get(base::FILE_EXE, &exe);

	base::CommandLine cmdline(exe);
	cmdline.AppendArg(base::IntToString(iteration));

	base::Process process = base::LaunchProcess(cmdline, base::LaunchOptions());
	if (!process.IsValid()) {
	printf("Unable to run test\n");
	return kError;
	}

	int exit_code;
	if (!process.WaitForExit(&exit_code)) {
	printf("Unable to get return code\n");
	return kError;
	}
	return exit_code;
	}

	// Main loop for the master process.
	int MasterCode() {
	for (int i = 0; i < 100000; i++) {
	int ret = RunSlave(i);
	if (kExpectedCrash != ret)
	return ret;
	}

	printf("More than enough...\n");

	return 0;
	}

	// -----------------------------------------------------------------------

	std::string GenerateStressKey() {
	char key[20 * 1024];
	size_t size = 50 + rand() % 20000;
	CacheTestFillBuffer(key, size, true);

	key[size - 1] = '\0';
	return std::string(key);
	}

	// kNumKeys is meant to be enough to have about 3x or 4x iterations before
	// the process crashes.
	#ifdef NDEBUG
	const int kNumKeys = 4000;
	#else
	const int kNumKeys = 1200;
	#endif
	const int kNumEntries = 30;
	const int kBufferSize = 2000;
	const int kReadSize = 20;

	// Things that an entry can be doing.
	enum Operation { NONE, OPEN, CREATE, READ, WRITE, DOOM };

	// This class encapsulates a cache entry and the operations performed on that
	// entry. An entry is opened or created as needed, the current content is then
	// verified and then something is written to the entry. At that point, the
	// \|state_\| becomes NONE again, waiting for another write, unless the entry is
	// closed or deleted.
	class EntryWrapper {
	public:
	EntryWrapper() : entry_(nullptr), state_(NONE) {
	buffer_ = base::MakeRefCounted<net::IOBuffer>(kBufferSize);
	memset(buffer_->data(), 'k', kBufferSize);
	}

	Operation state() const { return state_; }

	void DoOpen(int key);

	private:
	void OnOpenDone(int key, int result);
	void DoRead();
	void OnReadDone(int result);
	void DoWrite();
	void OnWriteDone(int size, int result);
	void DoDelete(const std::string& key);
	void OnDeleteDone(int result);
	void DoIdle();

	disk_cache::Entry* entry_;
	Operation state_;
	scoped_refptr<net::IOBuffer> buffer_;
	};

	// The data that the main thread is working on.
	struct Data {
	Data() : pendig_operations(0), writes(0), iteration(0), cache(nullptr) {}

	int pendig_operations; // Counter of simultaneous operations.
	int writes; // How many writes since this iteration started.
	int iteration; // The iteration (number of crashes).
	disk_cache::BackendImpl* cache;
	std::string keys[kNumKeys];
	EntryWrapper entries[kNumEntries];
	};

	Data* g_data = nullptr;

	void EntryWrapper::DoOpen(int key) {
	DCHECK_EQ(state_, NONE);
	if (entry_)
	return DoRead();

	state_ = OPEN;
	int rv = g_data->cache->OpenEntry(
	g_data->keys[key], net::HIGHEST, &entry_,
	base::Bind(&EntryWrapper::OnOpenDone, base::Unretained(this), key));
	if (rv != net::ERR_IO_PENDING)
	OnOpenDone(key, rv);
	}

	void EntryWrapper::OnOpenDone(int key, int result) {
	if (result == net::OK)
	return DoRead();

	CHECK_EQ(state_, OPEN);
	state_ = CREATE;
	result = g_data->cache->CreateEntry(
	g_data->keys[key], net::HIGHEST, &entry_,
	base::Bind(&EntryWrapper::OnOpenDone, base::Unretained(this), key));
	if (result != net::ERR_IO_PENDING)
	OnOpenDone(key, result);
	}

	void EntryWrapper::DoRead() {
	int current_size = entry_->GetDataSize(0);
	if (!current_size)
	return DoWrite();

	state_ = READ;
	memset(buffer_->data(), 'k', kReadSize);
	int rv = entry_->ReadData(
	0, 0, buffer_.get(), kReadSize,
	base::Bind(&EntryWrapper::OnReadDone, base::Unretained(this)));
	if (rv != net::ERR_IO_PENDING)
	OnReadDone(rv);
	}

	void EntryWrapper::OnReadDone(int result) {
	DCHECK_EQ(state_, READ);
	CHECK_EQ(result, kReadSize);
	CHECK_EQ(0, memcmp(buffer_->data(), "Write: ", 7));
	DoWrite();
	}

	void EntryWrapper::DoWrite() {
	bool truncate = (rand() % 2 == 0);
	int size = kBufferSize - (rand() % 20) * kBufferSize / 20;
	state_ = WRITE;
	base::snprintf(buffer_->data(), kBufferSize,
	"Write: %d iter: %d, size: %d, truncate: %d ",
	g_data->writes, g_data->iteration, size, truncate ? 1 : 0);
	int rv = entry_->WriteData(
	0, 0, buffer_.get(), size,
	base::Bind(&EntryWrapper::OnWriteDone, base::Unretained(this), size),
	truncate);
	if (rv != net::ERR_IO_PENDING)
	OnWriteDone(size, rv);
	}

	void EntryWrapper::OnWriteDone(int size, int result) {
	DCHECK_EQ(state_, WRITE);
	CHECK_EQ(size, result);
	if (!(g_data->writes++ % 100))
	printf("Entries: %d \r", g_data->writes);

	int random = rand() % 100;
	std::string key = entry_->GetKey();
	if (random > 90)
	return DoDelete(key); // 10% delete then close.

	if (random > 60) { // 20% close.
	entry_->Close();
	entry_ = nullptr;
	}

	if (random > 80)
	return DoDelete(key); // 10% close then delete.

	DoIdle(); // 60% do another write later.
	}

	void EntryWrapper::DoDelete(const std::string& key) {
	state_ = DOOM;
	int rv = g_data->cache->DoomEntry(
	key, net::HIGHEST,
	base::Bind(&EntryWrapper::OnDeleteDone, base::Unretained(this)));
	if (rv != net::ERR_IO_PENDING)
	OnDeleteDone(rv);
	}

	void EntryWrapper::OnDeleteDone(int result) {
	DCHECK_EQ(state_, DOOM);
	if (entry_) {
	entry_->Close();
	entry_ = nullptr;
	}
	DoIdle();
	}

	void LoopTask();

	void EntryWrapper::DoIdle() {
	state_ = NONE;
	g_data->pendig_operations--;
	DCHECK(g_data->pendig_operations);
	base::ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
	base::Bind(&LoopTask));
	}

	// The task that keeps the main thread busy. Whenever an entry becomes idle this
	// task is executed again.
	void LoopTask() {
	if (g_data->pendig_operations >= kNumEntries)
	return;

	int slot = rand() % kNumEntries;
	if (g_data->entries[slot].state() == NONE) {
	// Each slot will have some keys assigned to it so that the same entry will
	// not be open by two slots, which means that the state is well known at
	// all times.
	int keys_per_entry = kNumKeys / kNumEntries;
	int key = rand() % keys_per_entry + keys_per_entry * slot;
	g_data->pendig_operations++;
	g_data->entries[slot].DoOpen(key);
	}

	base::ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
	base::Bind(&LoopTask));
	}

	// This thread will loop forever, adding and removing entries from the cache.
	// iteration is the current crash cycle, so the entries on the cache are marked
	// to know which instance of the application wrote them.
	void StressTheCache(int iteration) {
	int cache_size = 0x2000000; // 32MB.
	uint32_t mask = 0xfff; // 4096 entries.

	base::FilePath path;
	base::PathService::Get(base::DIR_TEMP, &path);
	path = path.AppendASCII("cache_test_stress");

	base::Thread cache_thread("CacheThread");
	if (!cache_thread.StartWithOptions(
	base::Thread::Options(base::MessageLoop::TYPE_IO, 0)))
	return;

	g_data = new Data();
	g_data->iteration = iteration;
	g_data->cache = new disk_cache::BackendImpl(
	path, mask, cache_thread.task_runner().get(), NULL);
	g_data->cache->SetMaxSize(cache_size);
	g_data->cache->SetFlags(disk_cache::kNoLoadProtection);

	net::TestCompletionCallback cb;
	int rv = g_data->cache->Init(cb.callback());

	if (cb.GetResult(rv) != net::OK) {
	printf("Unable to initialize cache.\n");
	return;
	}
	printf("Iteration %d, initial entries: %d\n", iteration,
	g_data->cache->GetEntryCount());

	int seed = static_cast<int>(Time::Now().ToInternalValue());
	srand(seed);

	for (int i = 0; i < kNumKeys; i++)
	g_data->keys[i] = GenerateStressKey();

	base::ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
	base::Bind(&LoopTask));
	base::RunLoop().Run();
	}

	// We want to prevent the timer thread from killing the process while we are
	// waiting for the debugger to attach.
	bool g_crashing = false;

	// RunSoon() and CrashCallback() reference each other, unfortunately.
	void RunSoon(scoped_refptr<base::SingleThreadTaskRunner> task_runner);

	void CrashCallback() {
	// Keep trying to run.
	RunSoon(base::ThreadTaskRunnerHandle::Get());

	if (g_crashing)
	return;

	if (rand() % 100 > 30) {
	printf("sweet death...\n");

	// Terminate the current process without doing normal process-exit cleanup.
	base::Process::TerminateCurrentProcessImmediately(kExpectedCrash);
	}
	}

	void RunSoon(scoped_refptr<base::SingleThreadTaskRunner> task_runner) {
	const base::TimeDelta kTaskDelay = base::TimeDelta::FromSeconds(10);
	task_runner->PostDelayedTask(FROM_HERE, base::Bind(&CrashCallback),
	kTaskDelay);
	}

	// We leak everything here :)
	bool StartCrashThread() {
	base::Thread* thread = new base::Thread("party_crasher");
	if (!thread->Start())
	return false;

	RunSoon(thread->task_runner());
	return true;
	}

	void CrashHandler(const char* file,
	int line,
	const base::StringPiece str,
	const base::StringPiece stack_trace) {
	g_crashing = true;
	base::debug::BreakDebugger();
	}

	bool MessageHandler(int severity, const char* file, int line,
	size_t message_start, const std::string& str) {
	const size_t kMaxMessageLen = 48;
	char message[kMaxMessageLen];
	size_t len = std::min(str.length() - message_start, kMaxMessageLen - 1);

	memcpy(message, str.c_str() + message_start, len);
	message[len] = '\0';
	#if !defined(DISK_CACHE_TRACE_TO_LOG)
	disk_cache::Trace("%s", message);
	#endif
	return false;
	}

	// -----------------------------------------------------------------------

	#if defined(OS_WIN)
	// {B9A153D4-31C3-48e4-9ABF-D54383F14A0D}
	const GUID kStressCacheTraceProviderName = {
	0xb9a153d4, 0x31c3, 0x48e4,
	{ 0x9a, 0xbf, 0xd5, 0x43, 0x83, 0xf1, 0x4a, 0xd } };
	#endif

	int main(int argc, const char* argv[]) {
	// Setup an AtExitManager so Singleton objects will be destructed.
	base::AtExitManager at_exit_manager;

	if (argc < 2)
	return MasterCode();

	logging::ScopedLogAssertHandler scoped_assert_handler(
	base::Bind(CrashHandler));
	logging::SetLogMessageHandler(MessageHandler);

	#if defined(OS_WIN)
	logging::LogEventProvider::Initialize(kStressCacheTraceProviderName);
	#else
	base::CommandLine::Init(argc, argv);
	logging::LoggingSettings settings;
	settings.logging_dest = logging::LOG_TO_SYSTEM_DEBUG_LOG;
	logging::InitLogging(settings);
	#endif

	// Some time for the memory manager to flush stuff.
	base::PlatformThread::Sleep(base::TimeDelta::FromSeconds(3));
	base::MessageLoopForIO message_loop;

	char* end;
	long int iteration = strtol(argv[1], &end, 0);

	if (!StartCrashThread()) {
	printf("failed to start thread\n");
	return kError;
	}

	StressTheCache(iteration);
	return 0;
	}