ppapi/tests/test_audio.cc - chromium/src - 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.

 #include "ppapi/tests/test_audio.h"

 #include <stddef.h>
 #include <string.h>

 #include "ppapi/c/ppb_audio.h"
 #include "ppapi/c/ppb_audio_config.h"
 #include "ppapi/cpp/module.h"
 #include "ppapi/tests/test_utils.h"
 #include "ppapi/tests/testing_instance.h"

 #if defined(__native_client__)
 #include "native_client/src/untrusted/irt/irt.h"
 #include "ppapi/native_client/src/untrusted/irt_stub/thread_creator.h"
 #endif

 #define ARRAYSIZE_UNSAFE(a) \
   ((sizeof(a) / sizeof(*(a))) / \
    static_cast<size_t>(!(sizeof(a) % sizeof(*(a)))))

 #if defined(__native_client__)
 namespace {

 void GetNaClIrtPpapiHook(struct nacl_irt_ppapihook* hooks) {
   nacl_interface_query(NACL_IRT_PPAPIHOOK_v0_1, hooks, sizeof(*hooks));
 }

 struct PP_ThreadFunctions g_thread_funcs = {};

 void ThreadFunctionsGetter(const struct PP_ThreadFunctions* thread_funcs) {
   g_thread_funcs = *thread_funcs;
 }

 // In order to check if the thread_create is called, CountingThreadCreate()
 // increments this variable. Callers can check if the function is actually
 // called by looking at this value.
 int g_num_thread_create_called = 0;
 int g_num_thread_join_called = 0;

 int CountingThreadCreate(uintptr_t* tid,
                          void (*func)(void* thread_argument),
                          void* thread_argument) {
   ++g_num_thread_create_called;
   return g_thread_funcs.thread_create(tid, func, thread_argument);
 }

 int CountingThreadJoin(uintptr_t tid) {
   ++g_num_thread_join_called;
   return g_thread_funcs.thread_join(tid);
 }

 // Sets NULL for PP_ThreadFunctions to emulate the situation that
 // ppapi_register_thread_creator() is not yet called.
 void SetNullThreadFunctions() {
   nacl_irt_ppapihook hooks;
   GetNaClIrtPpapiHook(&hooks);
   PP_ThreadFunctions thread_functions = {};
   hooks.ppapi_register_thread_creator(&thread_functions);
 }

 void InjectCountingThreadFunctions() {
   // First of all, we extract the system default thread functions.
   // Internally, __nacl_register_thread_creator calls
   // hooks.ppapi_register_thread_creator with default PP_ThreadFunctions
   // instance. ThreadFunctionGetter stores it to g_thread_funcs.
   nacl_irt_ppapihook hooks = { NULL, ThreadFunctionsGetter };
   __nacl_register_thread_creator(&hooks);

   // Here g_thread_funcs stores the thread functions.
   // Inject the CountingThreadCreate.
   PP_ThreadFunctions thread_functions = {
     CountingThreadCreate,
     CountingThreadJoin,
   };
   GetNaClIrtPpapiHook(&hooks);
   hooks.ppapi_register_thread_creator(&thread_functions);
 }

 // Resets the PP_ThreadFunctions on exit from the scope.
 class ScopedThreadFunctionsResetter {
  public:
   ScopedThreadFunctionsResetter() {}
   ~ScopedThreadFunctionsResetter() {
     nacl_irt_ppapihook hooks;
     GetNaClIrtPpapiHook(&hooks);
     __nacl_register_thread_creator(&hooks);
   }
 };

 }  // namespace
 #endif  // __native_client__

 REGISTER_TEST_CASE(Audio);

 TestAudio::TestAudio(TestingInstance* instance)
     : TestCase(instance),
       audio_callback_method_(NULL),
       audio_callback_event_(instance->pp_instance()),
       test_done_(false),
       audio_interface_(NULL),
       audio_interface_1_0_(NULL),
       audio_config_interface_(NULL),
       core_interface_(NULL) {
 }

 TestAudio::~TestAudio() {
 }

 bool TestAudio::Init() {
   audio_interface_ = static_cast<const PPB_Audio_1_1*>(
       pp::Module::Get()->GetBrowserInterface(PPB_AUDIO_INTERFACE_1_1));
   audio_interface_1_0_ = static_cast<const PPB_Audio_1_0*>(
       pp::Module::Get()->GetBrowserInterface(PPB_AUDIO_INTERFACE_1_0));
   audio_config_interface_ = static_cast<const PPB_AudioConfig*>(
       pp::Module::Get()->GetBrowserInterface(PPB_AUDIO_CONFIG_INTERFACE));
   core_interface_ = static_cast<const PPB_Core*>(
       pp::Module::Get()->GetBrowserInterface(PPB_CORE_INTERFACE));
   return audio_interface_ && audio_interface_1_0_ && audio_config_interface_ &&
          core_interface_;
 }

 void TestAudio::RunTests(const std::string& filter) {
   RUN_TEST(Creation, filter);
   RUN_TEST(DestroyNoStop, filter);
   RUN_TEST(Failures, filter);
   RUN_TEST(AudioCallback1, filter);
   RUN_TEST(AudioCallback2, filter);
   RUN_TEST(AudioCallback3, filter);
   RUN_TEST(AudioCallback4, filter);

 #if defined(__native_client__)
   RUN_TEST(AudioThreadCreatorIsRequired, filter);
   RUN_TEST(AudioThreadCreatorIsCalled, filter);
 #endif
 }

 // Test creating audio resources for all guaranteed sample rates and various
 // frame counts.
 std::string TestAudio::TestCreation() {
   static const PP_AudioSampleRate kSampleRates[] = {
     PP_AUDIOSAMPLERATE_44100,
     PP_AUDIOSAMPLERATE_48000
   };
   static const uint32_t kRequestFrameCounts[] = {
     PP_AUDIOMINSAMPLEFRAMECOUNT,
     PP_AUDIOMAXSAMPLEFRAMECOUNT,
     // Include some "okay-looking" frame counts; check their validity below.
     PP_AUDIOSAMPLERATE_44100 / 100,  // 10ms @ 44.1kHz
     PP_AUDIOSAMPLERATE_48000 / 100,  // 10ms @ 48kHz
     2 * PP_AUDIOSAMPLERATE_44100 / 100,  // 20ms @ 44.1kHz
     2 * PP_AUDIOSAMPLERATE_48000 / 100,  // 20ms @ 48kHz
     1024,
     2048,
     4096
   };
   PP_AudioSampleRate sample_rate = audio_config_interface_->RecommendSampleRate(
       instance_->pp_instance());
   ASSERT_TRUE(sample_rate == PP_AUDIOSAMPLERATE_NONE ||
               sample_rate == PP_AUDIOSAMPLERATE_44100 ||
               sample_rate == PP_AUDIOSAMPLERATE_48000);
   for (size_t i = 0; i < ARRAYSIZE_UNSAFE(kSampleRates); i++) {
     PP_AudioSampleRate sample_rate = kSampleRates[i];

     for (size_t j = 0; j < ARRAYSIZE_UNSAFE(kRequestFrameCounts); j++) {
       // Make a config, create the audio resource, and release the config.
       uint32_t request_frame_count = kRequestFrameCounts[j];
       uint32_t frame_count = audio_config_interface_->RecommendSampleFrameCount(
           instance_->pp_instance(), sample_rate, request_frame_count);
       PP_Resource ac = audio_config_interface_->CreateStereo16Bit(
           instance_->pp_instance(), sample_rate, frame_count);
       ASSERT_TRUE(ac);
       PP_Resource audio = audio_interface_->Create(
           instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
       core_interface_->ReleaseResource(ac);
       ac = 0;

       ASSERT_TRUE(audio);
       ASSERT_TRUE(audio_interface_->IsAudio(audio));

       // Check that the config returned for |audio| matches what we gave it.
       ac = audio_interface_->GetCurrentConfig(audio);
       ASSERT_TRUE(ac);
       ASSERT_TRUE(audio_config_interface_->IsAudioConfig(ac));
       ASSERT_EQ(sample_rate, audio_config_interface_->GetSampleRate(ac));
       ASSERT_EQ(frame_count, audio_config_interface_->GetSampleFrameCount(ac));
       core_interface_->ReleaseResource(ac);
       ac = 0;

       // Start and stop audio playback. The documentation indicates that
       // |StartPlayback()| and |StopPlayback()| may fail, but gives no
       // indication as to why ... so check that they succeed.
       audio_callback_method_ = &TestAudio::AudioCallbackTrivial;
       ASSERT_TRUE(audio_interface_->StartPlayback(audio));
       ASSERT_TRUE(audio_interface_->StopPlayback(audio));
       audio_callback_method_ = NULL;

       core_interface_->ReleaseResource(audio);
     }
   }

   PASS();
 }

 // Test that releasing the resource without calling |StopPlayback()| "works".
 std::string TestAudio::TestDestroyNoStop() {
   PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 2048);
   ASSERT_TRUE(ac);
   audio_callback_method_ = NULL;
   PP_Resource audio = audio_interface_->Create(
       instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
   core_interface_->ReleaseResource(ac);
   ac = 0;

   ASSERT_TRUE(audio);
   ASSERT_TRUE(audio_interface_->IsAudio(audio));

   // Start playback and release the resource.
   audio_callback_method_ = &TestAudio::AudioCallbackTrivial;
   ASSERT_TRUE(audio_interface_->StartPlayback(audio));
   core_interface_->ReleaseResource(audio);
   audio_callback_method_ = NULL;

   PASS();
 }

 std::string TestAudio::TestFailures() {
   // Test invalid parameters to |Create()|.

   // We want a valid config for some of our tests of |Create()|.
   PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 2048);
   ASSERT_TRUE(ac);

   // Failure cases should never lead to the callback being called.
   audio_callback_method_ = NULL;

   // Invalid instance -> failure.
   PP_Resource audio = audio_interface_->Create(
       0, ac, AudioCallbackTrampoline, this);
   ASSERT_EQ(0, audio);

   // Invalid config -> failure.
   audio = audio_interface_->Create(
       instance_->pp_instance(), 0, AudioCallbackTrampoline, this);
   ASSERT_EQ(0, audio);

   // Null callback -> failure.
   audio = audio_interface_->Create(
       instance_->pp_instance(), ac, NULL, NULL);
   ASSERT_EQ(0, audio);

   core_interface_->ReleaseResource(ac);
   ac = 0;

   // Test the other functions with an invalid audio resource.
   ASSERT_FALSE(audio_interface_->IsAudio(0));
   ASSERT_EQ(0, audio_interface_->GetCurrentConfig(0));
   ASSERT_FALSE(audio_interface_->StartPlayback(0));
   ASSERT_FALSE(audio_interface_->StopPlayback(0));

   PASS();
 }

 // NOTE: |TestAudioCallbackN| assumes that the audio callback is called at least
 // once. If the audio stream does not start up correctly or is interrupted this
 // may not be the case and these tests will fail. However, in order to properly
 // test the audio callbacks, we must have a configuration where audio can
 // successfully play, so we assume this is the case on bots.

 // This test starts playback and verifies that:
 //  1) the audio callback is actually called;
 //  2) that |StopPlayback()| waits for the audio callback to finish.
 std::string TestAudio::TestAudioCallback1() {
   PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
   ASSERT_TRUE(ac);
   audio_callback_method_ = NULL;
   PP_Resource audio = audio_interface_->Create(
       instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
   core_interface_->ReleaseResource(ac);
   ac = 0;

   audio_callback_event_.Reset();
   test_done_ = false;

   audio_callback_method_ = &TestAudio::AudioCallbackTest;
   ASSERT_TRUE(audio_interface_->StartPlayback(audio));

   // Wait for the audio callback to be called.
   audio_callback_event_.Wait();
   ASSERT_TRUE(audio_interface_->StopPlayback(audio));
   test_done_ = true;

   // If any more audio callbacks are generated, we should crash (which is good).
   audio_callback_method_ = NULL;

   core_interface_->ReleaseResource(audio);

   PASS();
 }

 // This is the same as |TestAudioCallback1()|, except that instead of calling
 // |StopPlayback()|, it just releases the resource.
 std::string TestAudio::TestAudioCallback2() {
   PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
   ASSERT_TRUE(ac);
   audio_callback_method_ = NULL;
   PP_Resource audio = audio_interface_->Create(
       instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
   core_interface_->ReleaseResource(ac);
   ac = 0;

   audio_callback_event_.Reset();
   test_done_ = false;

   audio_callback_method_ = &TestAudio::AudioCallbackTest;
   ASSERT_TRUE(audio_interface_->StartPlayback(audio));

   // Wait for the audio callback to be called.
   audio_callback_event_.Wait();

   core_interface_->ReleaseResource(audio);

   test_done_ = true;

   // If any more audio callbacks are generated, we should crash (which is good).
   audio_callback_method_ = NULL;

   PASS();
 }

 // This is the same as |TestAudioCallback1()|, except that it attempts a second
 // round of |StartPlayback| and |StopPlayback| to make sure the callback
 // function still responds when using the same audio resource.
 std::string TestAudio::TestAudioCallback3() {
   PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
   ASSERT_TRUE(ac);
   audio_callback_method_ = NULL;
   PP_Resource audio = audio_interface_->Create(
       instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
   core_interface_->ReleaseResource(ac);
   ac = 0;

   audio_callback_event_.Reset();
   test_done_ = false;

   audio_callback_method_ = &TestAudio::AudioCallbackTest;
   ASSERT_TRUE(audio_interface_->StartPlayback(audio));

   // Wait for the audio callback to be called.
   audio_callback_event_.Wait();

   ASSERT_TRUE(audio_interface_->StopPlayback(audio));

   // Repeat one more |StartPlayback| & |StopPlayback| cycle, and verify again
   // that the callback function was invoked.
   audio_callback_event_.Reset();
   ASSERT_TRUE(audio_interface_->StartPlayback(audio));

   // Wait for the audio callback to be called.
   audio_callback_event_.Wait();
   ASSERT_TRUE(audio_interface_->StopPlayback(audio));
   test_done_ = true;

   // If any more audio callbacks are generated, we should crash (which is good).
   audio_callback_method_ = NULL;

   core_interface_->ReleaseResource(audio);

   PASS();
 }

 // This is the same as |TestAudioCallback1()|, except that it uses
 // PPB_Audio_1_0.
 std::string TestAudio::TestAudioCallback4() {
   PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
   ASSERT_TRUE(ac);
   audio_callback_method_ = NULL;
   PP_Resource audio = audio_interface_1_0_->Create(
       instance_->pp_instance(), ac, AudioCallbackTrampoline1_0, this);
   core_interface_->ReleaseResource(ac);
   ac = 0;

   audio_callback_event_.Reset();
   test_done_ = false;

   audio_callback_method_ = &TestAudio::AudioCallbackTest;
   ASSERT_TRUE(audio_interface_1_0_->StartPlayback(audio));

   // Wait for the audio callback to be called.
   audio_callback_event_.Wait();
   ASSERT_TRUE(audio_interface_1_0_->StopPlayback(audio));
   test_done_ = true;

   // If any more audio callbacks are generated, we should crash (which is good).
   audio_callback_method_ = NULL;

   core_interface_->ReleaseResource(audio);

   PASS();
 }

 #if defined(__native_client__)
 // Tests the behavior of the thread_create functions.
 // For PPB_Audio_Shared to work properly, the user code must call
 // ppapi_register_thread_creator(). This test checks the error handling for the
 // case when user code doesn't call ppapi_register_thread_creator().
 std::string TestAudio::TestAudioThreadCreatorIsRequired() {
   // We'll inject some thread functions in this test case.
   // Reset them at the end of this case.
   ScopedThreadFunctionsResetter thread_resetter;

   // Set the thread functions to NULLs to emulate the situation where
   // ppapi_register_thread_creator() is not called by user code.
   SetNullThreadFunctions();

   PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
   ASSERT_TRUE(ac);
   audio_callback_method_ = NULL;
   PP_Resource audio = audio_interface_->Create(
       instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
   core_interface_->ReleaseResource(ac);
   ac = 0;

   // StartPlayback() fails, because no thread creating function
   // is available.
   ASSERT_FALSE(audio_interface_->StartPlayback(audio));

   // If any more audio callbacks are generated,
   // we should crash (which is good).
   audio_callback_method_ = NULL;

   core_interface_->ReleaseResource(audio);

   PASS();
 }

 // Tests whether the thread functions passed from the user code are actually
 // called.
 std::string TestAudio::TestAudioThreadCreatorIsCalled() {
   // We'll inject some thread functions in this test case.
   // Reset them at the end of this case.
   ScopedThreadFunctionsResetter thread_resetter;

   // Inject the thread counting function. In the injected function,
   // when called, g_num_thread_create_called is incremented.
   g_num_thread_create_called = 0;
   g_num_thread_join_called = 0;
   InjectCountingThreadFunctions();

   PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
   ASSERT_TRUE(ac);
   audio_callback_method_ = NULL;
   PP_Resource audio = audio_interface_->Create(
       instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
   core_interface_->ReleaseResource(ac);
   ac = 0;

   audio_callback_event_.Reset();
   test_done_ = false;

   audio_callback_method_ = &TestAudio::AudioCallbackTest;
   ASSERT_TRUE(audio_interface_->StartPlayback(audio));

   // Wait for the audio callback to be called.
   audio_callback_event_.Wait();
   // Here, the injected thread_create is called, but thread_join is not yet.
   ASSERT_EQ(1, g_num_thread_create_called);
   ASSERT_EQ(0, g_num_thread_join_called);

   ASSERT_TRUE(audio_interface_->StopPlayback(audio));

   test_done_ = true;

   // Here, the injected thread_join is called.
   ASSERT_EQ(1, g_num_thread_join_called);

   // If any more audio callbacks are generated,
   // we should crash (which is good).
   audio_callback_method_ = NULL;

   core_interface_->ReleaseResource(audio);

   PASS();
 }
 #endif

 // TODO(raymes): Test that actually playback happens correctly, etc.

 static void Crash() {
   *static_cast<volatile unsigned*>(NULL) = 0xdeadbeef;
 }

 // static
 void TestAudio::AudioCallbackTrampoline(void* sample_buffer,
                                         uint32_t buffer_size_in_bytes,
                                         PP_TimeDelta latency,
                                         void* user_data) {
   TestAudio* thiz = static_cast<TestAudio*>(user_data);

   // Crash if on the main thread.
   if (thiz->core_interface_->IsMainThread())
     Crash();

   AudioCallbackMethod method = thiz->audio_callback_method_;
   (thiz->*method)(sample_buffer, buffer_size_in_bytes, latency);
 }

 // static
 void TestAudio::AudioCallbackTrampoline1_0(void* sample_buffer,
                                            uint32_t buffer_size_in_bytes,
                                            void* user_data) {
   AudioCallbackTrampoline(sample_buffer, buffer_size_in_bytes, 0.0, user_data);
 }

 void TestAudio::AudioCallbackTrivial(void* sample_buffer,
                                      uint32_t buffer_size_in_bytes,
                                      PP_TimeDelta latency) {
   if (latency < 0)
     Crash();

   memset(sample_buffer, 0, buffer_size_in_bytes);
 }

 void TestAudio::AudioCallbackTest(void* sample_buffer,
                                   uint32_t buffer_size_in_bytes,
                                   PP_TimeDelta latency) {
   if (test_done_ || latency < 0)
     Crash();

   memset(sample_buffer, 0, buffer_size_in_bytes);
   audio_callback_event_.Signal();
 }

 PP_Resource TestAudio::CreateAudioConfig(
     PP_AudioSampleRate sample_rate,
     uint32_t requested_sample_frame_count) {
   uint32_t frame_count = audio_config_interface_->RecommendSampleFrameCount(
       instance_->pp_instance(), sample_rate, requested_sample_frame_count);
   return audio_config_interface_->CreateStereo16Bit(
       instance_->pp_instance(), sample_rate, frame_count);
 }
	// 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.

	#include "ppapi/tests/test_audio.h"

	#include <stddef.h>
	#include <string.h>

	#include "ppapi/c/ppb_audio.h"
	#include "ppapi/c/ppb_audio_config.h"
	#include "ppapi/cpp/module.h"
	#include "ppapi/tests/test_utils.h"
	#include "ppapi/tests/testing_instance.h"

	#if defined(__native_client__)
	#include "native_client/src/untrusted/irt/irt.h"
	#include "ppapi/native_client/src/untrusted/irt_stub/thread_creator.h"
	#endif

	#define ARRAYSIZE_UNSAFE(a) \
	((sizeof(a) / sizeof(*(a))) / \
	static_cast<size_t>(!(sizeof(a) % sizeof(*(a)))))

	#if defined(__native_client__)
	namespace {

	void GetNaClIrtPpapiHook(struct nacl_irt_ppapihook* hooks) {
	nacl_interface_query(NACL_IRT_PPAPIHOOK_v0_1, hooks, sizeof(*hooks));
	}

	struct PP_ThreadFunctions g_thread_funcs = {};

	void ThreadFunctionsGetter(const struct PP_ThreadFunctions* thread_funcs) {
	g_thread_funcs = *thread_funcs;
	}

	// In order to check if the thread_create is called, CountingThreadCreate()
	// increments this variable. Callers can check if the function is actually
	// called by looking at this value.
	int g_num_thread_create_called = 0;
	int g_num_thread_join_called = 0;

	int CountingThreadCreate(uintptr_t* tid,
	void (func)(void thread_argument),
	void* thread_argument) {
	++g_num_thread_create_called;
	return g_thread_funcs.thread_create(tid, func, thread_argument);
	}

	int CountingThreadJoin(uintptr_t tid) {
	++g_num_thread_join_called;
	return g_thread_funcs.thread_join(tid);
	}

	// Sets NULL for PP_ThreadFunctions to emulate the situation that
	// ppapi_register_thread_creator() is not yet called.
	void SetNullThreadFunctions() {
	nacl_irt_ppapihook hooks;
	GetNaClIrtPpapiHook(&hooks);
	PP_ThreadFunctions thread_functions = {};
	hooks.ppapi_register_thread_creator(&thread_functions);
	}

	void InjectCountingThreadFunctions() {
	// First of all, we extract the system default thread functions.
	// Internally, __nacl_register_thread_creator calls
	// hooks.ppapi_register_thread_creator with default PP_ThreadFunctions
	// instance. ThreadFunctionGetter stores it to g_thread_funcs.
	nacl_irt_ppapihook hooks = { NULL, ThreadFunctionsGetter };
	__nacl_register_thread_creator(&hooks);

	// Here g_thread_funcs stores the thread functions.
	// Inject the CountingThreadCreate.
	PP_ThreadFunctions thread_functions = {
	CountingThreadCreate,
	CountingThreadJoin,
	};
	GetNaClIrtPpapiHook(&hooks);
	hooks.ppapi_register_thread_creator(&thread_functions);
	}

	// Resets the PP_ThreadFunctions on exit from the scope.
	class ScopedThreadFunctionsResetter {
	public:
	ScopedThreadFunctionsResetter() {}
	~ScopedThreadFunctionsResetter() {
	nacl_irt_ppapihook hooks;
	GetNaClIrtPpapiHook(&hooks);
	__nacl_register_thread_creator(&hooks);
	}
	};

	} // namespace
	#endif // __native_client__

	REGISTER_TEST_CASE(Audio);

	TestAudio::TestAudio(TestingInstance* instance)
	: TestCase(instance),
	audio_callback_method_(NULL),
	audio_callback_event_(instance->pp_instance()),
	test_done_(false),
	audio_interface_(NULL),
	audio_interface_1_0_(NULL),
	audio_config_interface_(NULL),
	core_interface_(NULL) {
	}

	TestAudio::~TestAudio() {
	}

	bool TestAudio::Init() {
	audio_interface_ = static_cast<const PPB_Audio_1_1*>(
	pp::Module::Get()->GetBrowserInterface(PPB_AUDIO_INTERFACE_1_1));
	audio_interface_1_0_ = static_cast<const PPB_Audio_1_0*>(
	pp::Module::Get()->GetBrowserInterface(PPB_AUDIO_INTERFACE_1_0));
	audio_config_interface_ = static_cast<const PPB_AudioConfig*>(
	pp::Module::Get()->GetBrowserInterface(PPB_AUDIO_CONFIG_INTERFACE));
	core_interface_ = static_cast<const PPB_Core*>(
	pp::Module::Get()->GetBrowserInterface(PPB_CORE_INTERFACE));
	return audio_interface_ && audio_interface_1_0_ && audio_config_interface_ &&
	core_interface_;
	}

	void TestAudio::RunTests(const std::string& filter) {
	RUN_TEST(Creation, filter);
	RUN_TEST(DestroyNoStop, filter);
	RUN_TEST(Failures, filter);
	RUN_TEST(AudioCallback1, filter);
	RUN_TEST(AudioCallback2, filter);
	RUN_TEST(AudioCallback3, filter);
	RUN_TEST(AudioCallback4, filter);

	#if defined(__native_client__)
	RUN_TEST(AudioThreadCreatorIsRequired, filter);
	RUN_TEST(AudioThreadCreatorIsCalled, filter);
	#endif
	}

	// Test creating audio resources for all guaranteed sample rates and various
	// frame counts.
	std::string TestAudio::TestCreation() {
	static const PP_AudioSampleRate kSampleRates[] = {
	PP_AUDIOSAMPLERATE_44100,
	PP_AUDIOSAMPLERATE_48000
	};
	static const uint32_t kRequestFrameCounts[] = {
	PP_AUDIOMINSAMPLEFRAMECOUNT,
	PP_AUDIOMAXSAMPLEFRAMECOUNT,
	// Include some "okay-looking" frame counts; check their validity below.
	PP_AUDIOSAMPLERATE_44100 / 100, // 10ms @ 44.1kHz
	PP_AUDIOSAMPLERATE_48000 / 100, // 10ms @ 48kHz
	2 * PP_AUDIOSAMPLERATE_44100 / 100, // 20ms @ 44.1kHz
	2 * PP_AUDIOSAMPLERATE_48000 / 100, // 20ms @ 48kHz
	1024,
	2048,
	4096
	};
	PP_AudioSampleRate sample_rate = audio_config_interface_->RecommendSampleRate(
	instance_->pp_instance());
	ASSERT_TRUE(sample_rate == PP_AUDIOSAMPLERATE_NONE \|\|
	sample_rate == PP_AUDIOSAMPLERATE_44100 \|\|
	sample_rate == PP_AUDIOSAMPLERATE_48000);
	for (size_t i = 0; i < ARRAYSIZE_UNSAFE(kSampleRates); i++) {
	PP_AudioSampleRate sample_rate = kSampleRates[i];

	for (size_t j = 0; j < ARRAYSIZE_UNSAFE(kRequestFrameCounts); j++) {
	// Make a config, create the audio resource, and release the config.
	uint32_t request_frame_count = kRequestFrameCounts[j];
	uint32_t frame_count = audio_config_interface_->RecommendSampleFrameCount(
	instance_->pp_instance(), sample_rate, request_frame_count);
	PP_Resource ac = audio_config_interface_->CreateStereo16Bit(
	instance_->pp_instance(), sample_rate, frame_count);
	ASSERT_TRUE(ac);
	PP_Resource audio = audio_interface_->Create(
	instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
	core_interface_->ReleaseResource(ac);
	ac = 0;

	ASSERT_TRUE(audio);
	ASSERT_TRUE(audio_interface_->IsAudio(audio));

	// Check that the config returned for \|audio\| matches what we gave it.
	ac = audio_interface_->GetCurrentConfig(audio);
	ASSERT_TRUE(ac);
	ASSERT_TRUE(audio_config_interface_->IsAudioConfig(ac));
	ASSERT_EQ(sample_rate, audio_config_interface_->GetSampleRate(ac));
	ASSERT_EQ(frame_count, audio_config_interface_->GetSampleFrameCount(ac));
	core_interface_->ReleaseResource(ac);
	ac = 0;

	// Start and stop audio playback. The documentation indicates that
	// \|StartPlayback()\| and \|StopPlayback()\| may fail, but gives no
	// indication as to why ... so check that they succeed.
	audio_callback_method_ = &TestAudio::AudioCallbackTrivial;
	ASSERT_TRUE(audio_interface_->StartPlayback(audio));
	ASSERT_TRUE(audio_interface_->StopPlayback(audio));
	audio_callback_method_ = NULL;

	core_interface_->ReleaseResource(audio);
	}
	}

	PASS();
	}

	// Test that releasing the resource without calling \|StopPlayback()\| "works".
	std::string TestAudio::TestDestroyNoStop() {
	PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 2048);
	ASSERT_TRUE(ac);
	audio_callback_method_ = NULL;
	PP_Resource audio = audio_interface_->Create(
	instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
	core_interface_->ReleaseResource(ac);
	ac = 0;

	ASSERT_TRUE(audio);
	ASSERT_TRUE(audio_interface_->IsAudio(audio));

	// Start playback and release the resource.
	audio_callback_method_ = &TestAudio::AudioCallbackTrivial;
	ASSERT_TRUE(audio_interface_->StartPlayback(audio));
	core_interface_->ReleaseResource(audio);
	audio_callback_method_ = NULL;

	PASS();
	}

	std::string TestAudio::TestFailures() {
	// Test invalid parameters to \|Create()\|.

	// We want a valid config for some of our tests of \|Create()\|.
	PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 2048);
	ASSERT_TRUE(ac);

	// Failure cases should never lead to the callback being called.
	audio_callback_method_ = NULL;

	// Invalid instance -> failure.
	PP_Resource audio = audio_interface_->Create(
	0, ac, AudioCallbackTrampoline, this);
	ASSERT_EQ(0, audio);

	// Invalid config -> failure.
	audio = audio_interface_->Create(
	instance_->pp_instance(), 0, AudioCallbackTrampoline, this);
	ASSERT_EQ(0, audio);

	// Null callback -> failure.
	audio = audio_interface_->Create(
	instance_->pp_instance(), ac, NULL, NULL);
	ASSERT_EQ(0, audio);

	core_interface_->ReleaseResource(ac);
	ac = 0;

	// Test the other functions with an invalid audio resource.
	ASSERT_FALSE(audio_interface_->IsAudio(0));
	ASSERT_EQ(0, audio_interface_->GetCurrentConfig(0));
	ASSERT_FALSE(audio_interface_->StartPlayback(0));
	ASSERT_FALSE(audio_interface_->StopPlayback(0));

	PASS();
	}

	// NOTE: \|TestAudioCallbackN\| assumes that the audio callback is called at least
	// once. If the audio stream does not start up correctly or is interrupted this
	// may not be the case and these tests will fail. However, in order to properly
	// test the audio callbacks, we must have a configuration where audio can
	// successfully play, so we assume this is the case on bots.

	// This test starts playback and verifies that:
	// 1) the audio callback is actually called;
	// 2) that \|StopPlayback()\| waits for the audio callback to finish.
	std::string TestAudio::TestAudioCallback1() {
	PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
	ASSERT_TRUE(ac);
	audio_callback_method_ = NULL;
	PP_Resource audio = audio_interface_->Create(
	instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
	core_interface_->ReleaseResource(ac);
	ac = 0;

	audio_callback_event_.Reset();
	test_done_ = false;

	audio_callback_method_ = &TestAudio::AudioCallbackTest;
	ASSERT_TRUE(audio_interface_->StartPlayback(audio));

	// Wait for the audio callback to be called.
	audio_callback_event_.Wait();
	ASSERT_TRUE(audio_interface_->StopPlayback(audio));
	test_done_ = true;

	// If any more audio callbacks are generated, we should crash (which is good).
	audio_callback_method_ = NULL;

	core_interface_->ReleaseResource(audio);

	PASS();
	}

	// This is the same as \|TestAudioCallback1()\|, except that instead of calling
	// \|StopPlayback()\|, it just releases the resource.
	std::string TestAudio::TestAudioCallback2() {
	PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
	ASSERT_TRUE(ac);
	audio_callback_method_ = NULL;
	PP_Resource audio = audio_interface_->Create(
	instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
	core_interface_->ReleaseResource(ac);
	ac = 0;

	audio_callback_event_.Reset();
	test_done_ = false;

	audio_callback_method_ = &TestAudio::AudioCallbackTest;
	ASSERT_TRUE(audio_interface_->StartPlayback(audio));

	// Wait for the audio callback to be called.
	audio_callback_event_.Wait();

	core_interface_->ReleaseResource(audio);

	test_done_ = true;

	// If any more audio callbacks are generated, we should crash (which is good).
	audio_callback_method_ = NULL;

	PASS();
	}

	// This is the same as \|TestAudioCallback1()\|, except that it attempts a second
	// round of \|StartPlayback\| and \|StopPlayback\| to make sure the callback
	// function still responds when using the same audio resource.
	std::string TestAudio::TestAudioCallback3() {
	PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
	ASSERT_TRUE(ac);
	audio_callback_method_ = NULL;
	PP_Resource audio = audio_interface_->Create(
	instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
	core_interface_->ReleaseResource(ac);
	ac = 0;

	audio_callback_event_.Reset();
	test_done_ = false;

	audio_callback_method_ = &TestAudio::AudioCallbackTest;
	ASSERT_TRUE(audio_interface_->StartPlayback(audio));

	// Wait for the audio callback to be called.
	audio_callback_event_.Wait();

	ASSERT_TRUE(audio_interface_->StopPlayback(audio));

	// Repeat one more \|StartPlayback\| & \|StopPlayback\| cycle, and verify again
	// that the callback function was invoked.
	audio_callback_event_.Reset();
	ASSERT_TRUE(audio_interface_->StartPlayback(audio));

	// Wait for the audio callback to be called.
	audio_callback_event_.Wait();
	ASSERT_TRUE(audio_interface_->StopPlayback(audio));
	test_done_ = true;

	// If any more audio callbacks are generated, we should crash (which is good).
	audio_callback_method_ = NULL;

	core_interface_->ReleaseResource(audio);

	PASS();
	}

	// This is the same as \|TestAudioCallback1()\|, except that it uses
	// PPB_Audio_1_0.
	std::string TestAudio::TestAudioCallback4() {
	PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
	ASSERT_TRUE(ac);
	audio_callback_method_ = NULL;
	PP_Resource audio = audio_interface_1_0_->Create(
	instance_->pp_instance(), ac, AudioCallbackTrampoline1_0, this);
	core_interface_->ReleaseResource(ac);
	ac = 0;

	audio_callback_event_.Reset();
	test_done_ = false;

	audio_callback_method_ = &TestAudio::AudioCallbackTest;
	ASSERT_TRUE(audio_interface_1_0_->StartPlayback(audio));

	// Wait for the audio callback to be called.
	audio_callback_event_.Wait();
	ASSERT_TRUE(audio_interface_1_0_->StopPlayback(audio));
	test_done_ = true;

	// If any more audio callbacks are generated, we should crash (which is good).
	audio_callback_method_ = NULL;

	core_interface_->ReleaseResource(audio);

	PASS();
	}

	#if defined(__native_client__)
	// Tests the behavior of the thread_create functions.
	// For PPB_Audio_Shared to work properly, the user code must call
	// ppapi_register_thread_creator(). This test checks the error handling for the
	// case when user code doesn't call ppapi_register_thread_creator().
	std::string TestAudio::TestAudioThreadCreatorIsRequired() {
	// We'll inject some thread functions in this test case.
	// Reset them at the end of this case.
	ScopedThreadFunctionsResetter thread_resetter;

	// Set the thread functions to NULLs to emulate the situation where
	// ppapi_register_thread_creator() is not called by user code.
	SetNullThreadFunctions();

	PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
	ASSERT_TRUE(ac);
	audio_callback_method_ = NULL;
	PP_Resource audio = audio_interface_->Create(
	instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
	core_interface_->ReleaseResource(ac);
	ac = 0;

	// StartPlayback() fails, because no thread creating function
	// is available.
	ASSERT_FALSE(audio_interface_->StartPlayback(audio));

	// If any more audio callbacks are generated,
	// we should crash (which is good).
	audio_callback_method_ = NULL;

	core_interface_->ReleaseResource(audio);

	PASS();
	}

	// Tests whether the thread functions passed from the user code are actually
	// called.
	std::string TestAudio::TestAudioThreadCreatorIsCalled() {
	// We'll inject some thread functions in this test case.
	// Reset them at the end of this case.
	ScopedThreadFunctionsResetter thread_resetter;

	// Inject the thread counting function. In the injected function,
	// when called, g_num_thread_create_called is incremented.
	g_num_thread_create_called = 0;
	g_num_thread_join_called = 0;
	InjectCountingThreadFunctions();

	PP_Resource ac = CreateAudioConfig(PP_AUDIOSAMPLERATE_44100, 1024);
	ASSERT_TRUE(ac);
	audio_callback_method_ = NULL;
	PP_Resource audio = audio_interface_->Create(
	instance_->pp_instance(), ac, AudioCallbackTrampoline, this);
	core_interface_->ReleaseResource(ac);
	ac = 0;

	audio_callback_event_.Reset();
	test_done_ = false;

	audio_callback_method_ = &TestAudio::AudioCallbackTest;
	ASSERT_TRUE(audio_interface_->StartPlayback(audio));

	// Wait for the audio callback to be called.
	audio_callback_event_.Wait();
	// Here, the injected thread_create is called, but thread_join is not yet.
	ASSERT_EQ(1, g_num_thread_create_called);
	ASSERT_EQ(0, g_num_thread_join_called);

	ASSERT_TRUE(audio_interface_->StopPlayback(audio));

	test_done_ = true;

	// Here, the injected thread_join is called.
	ASSERT_EQ(1, g_num_thread_join_called);

	// If any more audio callbacks are generated,
	// we should crash (which is good).
	audio_callback_method_ = NULL;

	core_interface_->ReleaseResource(audio);

	PASS();
	}
	#endif

	// TODO(raymes): Test that actually playback happens correctly, etc.

	static void Crash() {
	static_cast<volatile unsigned>(NULL) = 0xdeadbeef;
	}

	// static
	void TestAudio::AudioCallbackTrampoline(void* sample_buffer,
	uint32_t buffer_size_in_bytes,
	PP_TimeDelta latency,
	void* user_data) {
	TestAudio* thiz = static_cast<TestAudio*>(user_data);

	// Crash if on the main thread.
	if (thiz->core_interface_->IsMainThread())
	Crash();

	AudioCallbackMethod method = thiz->audio_callback_method_;
	(thiz->*method)(sample_buffer, buffer_size_in_bytes, latency);
	}

	// static
	void TestAudio::AudioCallbackTrampoline1_0(void* sample_buffer,
	uint32_t buffer_size_in_bytes,
	void* user_data) {
	AudioCallbackTrampoline(sample_buffer, buffer_size_in_bytes, 0.0, user_data);
	}

	void TestAudio::AudioCallbackTrivial(void* sample_buffer,
	uint32_t buffer_size_in_bytes,
	PP_TimeDelta latency) {
	if (latency < 0)
	Crash();

	memset(sample_buffer, 0, buffer_size_in_bytes);
	}

	void TestAudio::AudioCallbackTest(void* sample_buffer,
	uint32_t buffer_size_in_bytes,
	PP_TimeDelta latency) {
	if (test_done_ \|\| latency < 0)
	Crash();

	memset(sample_buffer, 0, buffer_size_in_bytes);
	audio_callback_event_.Signal();
	}

	PP_Resource TestAudio::CreateAudioConfig(
	PP_AudioSampleRate sample_rate,
	uint32_t requested_sample_frame_count) {
	uint32_t frame_count = audio_config_interface_->RecommendSampleFrameCount(
	instance_->pp_instance(), sample_rate, requested_sample_frame_count);
	return audio_config_interface_->CreateStereo16Bit(
	instance_->pp_instance(), sample_rate, frame_count);
	}