media/filters/decrypting_audio_decoder_unittest.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 <stdint.h>

 #include <string>
 #include <vector>

 #include "base/bind.h"
 #include "base/callback_helpers.h"
 #include "base/run_loop.h"
 #include "base/stl_util.h"
 #include "base/test/gmock_callback_support.h"
 #include "base/test/scoped_task_environment.h"
 #include "media/base/audio_buffer.h"
 #include "media/base/decoder_buffer.h"
 #include "media/base/decrypt_config.h"
 #include "media/base/media_util.h"
 #include "media/base/mock_filters.h"
 #include "media/base/test_helpers.h"
 #include "media/base/timestamp_constants.h"
 #include "media/filters/decrypting_audio_decoder.h"
 #include "testing/gmock/include/gmock/gmock.h"

 using ::base::test::RunCallback;
 using ::testing::_;
 using ::testing::AtMost;
 using ::testing::Return;
 using ::testing::SaveArg;
 using ::testing::StrictMock;

 namespace media {

 const int kSampleRate = 44100;

 // Make sure the kFakeAudioFrameSize is a valid frame size for all audio decoder
 // configs used in this test.
 const int kFakeAudioFrameSize = 48;
 const uint8_t kFakeKeyId[] = {0x4b, 0x65, 0x79, 0x20, 0x49, 0x44};
 const uint8_t kFakeIv[DecryptConfig::kDecryptionKeySize] = {0};
 const int kDecodingDelay = 3;

 // Create a fake non-empty encrypted buffer.
 static scoped_refptr<DecoderBuffer> CreateFakeEncryptedBuffer() {
   const int buffer_size = 16;  // Need a non-empty buffer;
   scoped_refptr<DecoderBuffer> buffer(new DecoderBuffer(buffer_size));
   buffer->set_decrypt_config(DecryptConfig::CreateCencConfig(
       std::string(reinterpret_cast<const char*>(kFakeKeyId),
                   base::size(kFakeKeyId)),
       std::string(reinterpret_cast<const char*>(kFakeIv), base::size(kFakeIv)),
       std::vector<SubsampleEntry>()));
   return buffer;
 }

 class DecryptingAudioDecoderTest : public testing::Test {
  public:
   DecryptingAudioDecoderTest()
       : decoder_(new DecryptingAudioDecoder(
             scoped_task_environment_.GetMainThreadTaskRunner(),
             &media_log_)),
         cdm_context_(new StrictMock<MockCdmContext>()),
         decryptor_(new StrictMock<MockDecryptor>()),
         num_decrypt_and_decode_calls_(0),
         num_frames_in_decryptor_(0),
         encrypted_buffer_(CreateFakeEncryptedBuffer()),
         decoded_frame_(NULL),
         decoded_frame_list_() {}

   ~DecryptingAudioDecoderTest() override { Destroy(); }

   void InitializeAndExpectResult(const AudioDecoderConfig& config,
                                  bool success) {
     // Initialize data now that the config is known. Since the code uses
     // invalid values (that CreateEmptyBuffer() doesn't support), tweak them
     // just for CreateEmptyBuffer().
     int channels = ChannelLayoutToChannelCount(config.channel_layout());
     if (channels < 0)
       channels = 0;
     decoded_frame_ = AudioBuffer::CreateEmptyBuffer(
         config.channel_layout(), channels, kSampleRate, kFakeAudioFrameSize,
         kNoTimestamp);
     decoded_frame_list_.push_back(decoded_frame_);

     decoder_->Initialize(config, cdm_context_.get(), NewExpectedBoolCB(success),
                          base::Bind(&DecryptingAudioDecoderTest::FrameReady,
                                     base::Unretained(this)),
                          base::Bind(&DecryptingAudioDecoderTest::OnWaiting,
                                     base::Unretained(this)));
     base::RunLoop().RunUntilIdle();
   }

   enum CdmType { CDM_WITHOUT_DECRYPTOR, CDM_WITH_DECRYPTOR };

   void SetCdmType(CdmType cdm_type) {
     const bool has_decryptor = cdm_type == CDM_WITH_DECRYPTOR;
     EXPECT_CALL(*cdm_context_, GetDecryptor())
         .WillRepeatedly(Return(has_decryptor ? decryptor_.get() : nullptr));
   }

   void Initialize() {
     SetCdmType(CDM_WITH_DECRYPTOR);
     EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
         .Times(AtMost(1))
         .WillOnce(RunCallback<1>(true));
     EXPECT_CALL(*decryptor_, RegisterNewKeyCB(Decryptor::kAudio, _))
         .WillOnce(SaveArg<1>(&key_added_cb_));

     config_.Initialize(kCodecVorbis, kSampleFormatPlanarF32,
                        CHANNEL_LAYOUT_STEREO, kSampleRate, EmptyExtraData(),
                        AesCtrEncryptionScheme(), base::TimeDelta(), 0);
     InitializeAndExpectResult(config_, true);
   }

   void Reinitialize() { ReinitializeConfigChange(config_); }

   void ReinitializeConfigChange(const AudioDecoderConfig& new_config) {
     EXPECT_CALL(*decryptor_, DeinitializeDecoder(Decryptor::kAudio));
     EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
         .WillOnce(RunCallback<1>(true));
     EXPECT_CALL(*decryptor_, RegisterNewKeyCB(Decryptor::kAudio, _))
         .WillOnce(SaveArg<1>(&key_added_cb_));
     decoder_->Initialize(new_config, cdm_context_.get(),
                          NewExpectedBoolCB(true),
                          base::Bind(&DecryptingAudioDecoderTest::FrameReady,
                                     base::Unretained(this)),
                          base::Bind(&DecryptingAudioDecoderTest::OnWaiting,
                                     base::Unretained(this)));
   }

   // Decode |buffer| and expect DecodeDone to get called with |status|.
   void DecodeAndExpect(scoped_refptr<DecoderBuffer> buffer,
                        DecodeStatus status) {
     EXPECT_CALL(*this, DecodeDone(status));
     decoder_->Decode(buffer, base::Bind(&DecryptingAudioDecoderTest::DecodeDone,
                                         base::Unretained(this)));
     base::RunLoop().RunUntilIdle();
   }

   // Helper function to simulate the decrypting and decoding process in the
   // |decryptor_| with a decoding delay of kDecodingDelay buffers.
   void DecryptAndDecodeAudio(scoped_refptr<DecoderBuffer> encrypted,
                              const Decryptor::AudioDecodeCB& audio_decode_cb) {
     num_decrypt_and_decode_calls_++;
     if (!encrypted->end_of_stream())
       num_frames_in_decryptor_++;

     if (num_decrypt_and_decode_calls_ <= kDecodingDelay ||
         num_frames_in_decryptor_ == 0) {
       audio_decode_cb.Run(Decryptor::kNeedMoreData, Decryptor::AudioFrames());
       return;
     }

     num_frames_in_decryptor_--;
     audio_decode_cb.Run(Decryptor::kSuccess,
                         Decryptor::AudioFrames(1, decoded_frame_));
   }

   // Sets up expectations and actions to put DecryptingAudioDecoder in an
   // active normal decoding state.
   void EnterNormalDecodingState() {
     EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
         .WillRepeatedly(
             Invoke(this, &DecryptingAudioDecoderTest::DecryptAndDecodeAudio));
     EXPECT_CALL(*this, FrameReady(decoded_frame_));
     for (int i = 0; i < kDecodingDelay + 1; ++i)
       DecodeAndExpect(encrypted_buffer_, DecodeStatus::OK);
   }

   // Sets up expectations and actions to put DecryptingAudioDecoder in an end
   // of stream state. This function must be called after
   // EnterNormalDecodingState() to work.
   void EnterEndOfStreamState() {
     // The codec in the |decryptor_| will be flushed.
     EXPECT_CALL(*this, FrameReady(decoded_frame_)).Times(kDecodingDelay);
     DecodeAndExpect(DecoderBuffer::CreateEOSBuffer(), DecodeStatus::OK);
     EXPECT_EQ(0, num_frames_in_decryptor_);
   }

   // Make the audio decode callback pending by saving and not firing it.
   void EnterPendingDecodeState() {
     EXPECT_TRUE(!pending_audio_decode_cb_);
     EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(encrypted_buffer_, _))
         .WillOnce(SaveArg<1>(&pending_audio_decode_cb_));

     decoder_->Decode(encrypted_buffer_,
                      base::Bind(&DecryptingAudioDecoderTest::DecodeDone,
                                 base::Unretained(this)));
     base::RunLoop().RunUntilIdle();
     // Make sure the Decode() on the decoder triggers a DecryptAndDecode() on
     // the decryptor.
     EXPECT_FALSE(!pending_audio_decode_cb_);
   }

   void EnterWaitingForKeyState() {
     EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(encrypted_buffer_, _))
         .WillRepeatedly(
             RunCallback<1>(Decryptor::kNoKey, Decryptor::AudioFrames()));
     EXPECT_CALL(*this, OnWaiting(WaitingReason::kNoDecryptionKey));
     decoder_->Decode(encrypted_buffer_,
                      base::Bind(&DecryptingAudioDecoderTest::DecodeDone,
                                 base::Unretained(this)));

     base::RunLoop().RunUntilIdle();
   }

   void AbortPendingAudioDecodeCB() {
     if (pending_audio_decode_cb_) {
       std::move(pending_audio_decode_cb_)
           .Run(Decryptor::kSuccess, Decryptor::AudioFrames());
     }
   }

   void AbortAllPendingCBs() {
     if (pending_init_cb_) {
       ASSERT_TRUE(!pending_audio_decode_cb_);
       std::move(pending_init_cb_).Run(false);
       return;
     }

     AbortPendingAudioDecodeCB();
   }

   void Reset() {
     EXPECT_CALL(*decryptor_, ResetDecoder(Decryptor::kAudio))
         .WillRepeatedly(InvokeWithoutArgs(
             this, &DecryptingAudioDecoderTest::AbortPendingAudioDecodeCB));

     decoder_->Reset(NewExpectedClosure());
     base::RunLoop().RunUntilIdle();
   }

   void Destroy() {
     EXPECT_CALL(*decryptor_, DeinitializeDecoder(Decryptor::kAudio))
         .WillRepeatedly(InvokeWithoutArgs(
             this, &DecryptingAudioDecoderTest::AbortAllPendingCBs));

     decoder_.reset();
     base::RunLoop().RunUntilIdle();
   }

   MOCK_METHOD1(FrameReady, void(scoped_refptr<AudioBuffer>));
   MOCK_METHOD1(DecodeDone, void(DecodeStatus));

   MOCK_METHOD1(OnWaiting, void(WaitingReason));

   base::test::ScopedTaskEnvironment scoped_task_environment_;
   NullMediaLog media_log_;
   std::unique_ptr<DecryptingAudioDecoder> decoder_;
   std::unique_ptr<StrictMock<MockCdmContext>> cdm_context_;
   std::unique_ptr<StrictMock<MockDecryptor>> decryptor_;
   AudioDecoderConfig config_;

   // Variables to help the |decryptor_| to simulate decoding delay and flushing.
   int num_decrypt_and_decode_calls_;
   int num_frames_in_decryptor_;

   Decryptor::DecoderInitCB pending_init_cb_;
   Decryptor::NewKeyCB key_added_cb_;
   Decryptor::AudioDecodeCB pending_audio_decode_cb_;

   // Constant buffer/frames, to be used/returned by |decoder_| and |decryptor_|.
   scoped_refptr<DecoderBuffer> encrypted_buffer_;
   scoped_refptr<AudioBuffer> decoded_frame_;
   Decryptor::AudioFrames decoded_frame_list_;

  private:
   DISALLOW_COPY_AND_ASSIGN(DecryptingAudioDecoderTest);
 };

 TEST_F(DecryptingAudioDecoderTest, Initialize_Normal) {
   Initialize();
 }

 // Ensure decoder handles invalid audio configs without crashing.
 TEST_F(DecryptingAudioDecoderTest, Initialize_InvalidAudioConfig) {
   AudioDecoderConfig config(kUnknownAudioCodec, kUnknownSampleFormat,
                             CHANNEL_LAYOUT_STEREO, 0, EmptyExtraData(),
                             AesCtrEncryptionScheme());

   InitializeAndExpectResult(config, false);
 }

 // Ensure decoder handles unsupported audio configs without crashing.
 TEST_F(DecryptingAudioDecoderTest, Initialize_UnsupportedAudioConfig) {
   SetCdmType(CDM_WITH_DECRYPTOR);
   EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
       .WillOnce(RunCallback<1>(false));

   AudioDecoderConfig config(kCodecVorbis, kSampleFormatPlanarF32,
                             CHANNEL_LAYOUT_STEREO, kSampleRate,
                             EmptyExtraData(), AesCtrEncryptionScheme());
   InitializeAndExpectResult(config, false);
 }

 TEST_F(DecryptingAudioDecoderTest, Initialize_CdmWithoutDecryptor) {
   SetCdmType(CDM_WITHOUT_DECRYPTOR);
   AudioDecoderConfig config(kCodecVorbis, kSampleFormatPlanarF32,
                             CHANNEL_LAYOUT_STEREO, kSampleRate,
                             EmptyExtraData(), AesCtrEncryptionScheme());
   InitializeAndExpectResult(config, false);
 }

 // Test normal decrypt and decode case.
 TEST_F(DecryptingAudioDecoderTest, DecryptAndDecode_Normal) {
   Initialize();
   EnterNormalDecodingState();
 }

 // Test the case where the decryptor returns error when doing decrypt and
 // decode.
 TEST_F(DecryptingAudioDecoderTest, DecryptAndDecode_DecodeError) {
   Initialize();

   EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
       .WillRepeatedly(
           RunCallback<1>(Decryptor::kError, Decryptor::AudioFrames()));

   DecodeAndExpect(encrypted_buffer_, DecodeStatus::DECODE_ERROR);
 }

 // Test the case where the decryptor returns multiple decoded frames.
 TEST_F(DecryptingAudioDecoderTest, DecryptAndDecode_MultipleFrames) {
   Initialize();

   scoped_refptr<AudioBuffer> frame_a = AudioBuffer::CreateEmptyBuffer(
       config_.channel_layout(),
       ChannelLayoutToChannelCount(config_.channel_layout()), kSampleRate,
       kFakeAudioFrameSize, kNoTimestamp);
   scoped_refptr<AudioBuffer> frame_b = AudioBuffer::CreateEmptyBuffer(
       config_.channel_layout(),
       ChannelLayoutToChannelCount(config_.channel_layout()), kSampleRate,
       kFakeAudioFrameSize, kNoTimestamp);
   decoded_frame_list_.push_back(frame_a);
   decoded_frame_list_.push_back(frame_b);

   EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
       .WillOnce(RunCallback<1>(Decryptor::kSuccess, decoded_frame_list_));

   EXPECT_CALL(*this, FrameReady(decoded_frame_));
   EXPECT_CALL(*this, FrameReady(frame_a));
   EXPECT_CALL(*this, FrameReady(frame_b));
   DecodeAndExpect(encrypted_buffer_, DecodeStatus::OK);
 }

 // Test the case where the decryptor receives end-of-stream buffer.
 TEST_F(DecryptingAudioDecoderTest, DecryptAndDecode_EndOfStream) {
   Initialize();
   EnterNormalDecodingState();
   EnterEndOfStreamState();
 }

 // Test reinitializing decode with a new encrypted config.
 TEST_F(DecryptingAudioDecoderTest, Reinitialize_EncryptedToEncrypted) {
   Initialize();

   EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
       .Times(AtMost(1))
       .WillOnce(RunCallback<1>(true));

   // The new config is different from the initial config in bits-per-channel,
   // channel layout and samples_per_second.
   AudioDecoderConfig new_config(kCodecVorbis, kSampleFormatPlanarS16,
                                 CHANNEL_LAYOUT_5_1, 88200, EmptyExtraData(),
                                 AesCtrEncryptionScheme());
   EXPECT_NE(new_config.bits_per_channel(), config_.bits_per_channel());
   EXPECT_NE(new_config.channel_layout(), config_.channel_layout());
   EXPECT_NE(new_config.samples_per_second(), config_.samples_per_second());
   ASSERT_TRUE(new_config.is_encrypted());

   ReinitializeConfigChange(new_config);
   base::RunLoop().RunUntilIdle();
 }

 // Test reinitializing decode with a new clear config.
 TEST_F(DecryptingAudioDecoderTest, Reinitialize_EncryptedToClear) {
   Initialize();

   EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
       .Times(AtMost(1))
       .WillOnce(RunCallback<1>(true));

   // The new config is different from the initial config in bits-per-channel,
   // channel layout and samples_per_second.
   AudioDecoderConfig new_config(kCodecVorbis, kSampleFormatPlanarS16,
                                 CHANNEL_LAYOUT_5_1, 88200, EmptyExtraData(),
                                 Unencrypted());
   EXPECT_NE(new_config.bits_per_channel(), config_.bits_per_channel());
   EXPECT_NE(new_config.channel_layout(), config_.channel_layout());
   EXPECT_NE(new_config.samples_per_second(), config_.samples_per_second());
   ASSERT_FALSE(new_config.is_encrypted());

   ReinitializeConfigChange(new_config);
   base::RunLoop().RunUntilIdle();
 }

 // Test the case where the a key is added when the decryptor is in
 // kWaitingForKey state.
 TEST_F(DecryptingAudioDecoderTest, KeyAdded_DuringWaitingForKey) {
   Initialize();
   EnterWaitingForKeyState();

   EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
       .WillRepeatedly(RunCallback<1>(Decryptor::kSuccess, decoded_frame_list_));
   EXPECT_CALL(*this, FrameReady(decoded_frame_));
   EXPECT_CALL(*this, DecodeDone(DecodeStatus::OK));
   key_added_cb_.Run();
   base::RunLoop().RunUntilIdle();
 }

 // Test the case where the a key is added when the decryptor is in
 // kPendingDecode state.
 TEST_F(DecryptingAudioDecoderTest, KeyAdded_DruingPendingDecode) {
   Initialize();
   EnterPendingDecodeState();

   EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
       .WillRepeatedly(RunCallback<1>(Decryptor::kSuccess, decoded_frame_list_));
   EXPECT_CALL(*this, FrameReady(decoded_frame_));
   EXPECT_CALL(*this, DecodeDone(DecodeStatus::OK));
   // The audio decode callback is returned after the correct decryption key is
   // added.
   key_added_cb_.Run();
   std::move(pending_audio_decode_cb_)
       .Run(Decryptor::kNoKey, Decryptor::AudioFrames());
   base::RunLoop().RunUntilIdle();
 }

 // Test resetting when the decoder is in kIdle state but has not decoded any
 // frame.
 TEST_F(DecryptingAudioDecoderTest, Reset_DuringIdleAfterInitialization) {
   Initialize();
   Reset();
 }

 // Test resetting when the decoder is in kIdle state after it has decoded one
 // frame.
 TEST_F(DecryptingAudioDecoderTest, Reset_DuringIdleAfterDecodedOneFrame) {
   Initialize();
   EnterNormalDecodingState();
   Reset();
 }

 // Test resetting when the decoder is in kPendingDecode state.
 TEST_F(DecryptingAudioDecoderTest, Reset_DuringPendingDecode) {
   Initialize();
   EnterPendingDecodeState();

   EXPECT_CALL(*this, DecodeDone(DecodeStatus::ABORTED));

   Reset();
 }

 // Test resetting when the decoder is in kWaitingForKey state.
 TEST_F(DecryptingAudioDecoderTest, Reset_DuringWaitingForKey) {
   Initialize();
   EnterWaitingForKeyState();

   EXPECT_CALL(*this, DecodeDone(DecodeStatus::ABORTED));

   Reset();
 }

 // Test resetting when the decoder has hit end of stream and is in
 // kDecodeFinished state.
 TEST_F(DecryptingAudioDecoderTest, Reset_AfterDecodeFinished) {
   Initialize();
   EnterNormalDecodingState();
   EnterEndOfStreamState();
   Reset();
 }

 // Test resetting after the decoder has been reset.
 TEST_F(DecryptingAudioDecoderTest, Reset_AfterReset) {
   Initialize();
   EnterNormalDecodingState();
   Reset();
   Reset();
 }

 }  // namespace media
	// 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 <stdint.h>

	#include <string>
	#include <vector>

	#include "base/bind.h"
	#include "base/callback_helpers.h"
	#include "base/run_loop.h"
	#include "base/stl_util.h"
	#include "base/test/gmock_callback_support.h"
	#include "base/test/scoped_task_environment.h"
	#include "media/base/audio_buffer.h"
	#include "media/base/decoder_buffer.h"
	#include "media/base/decrypt_config.h"
	#include "media/base/media_util.h"
	#include "media/base/mock_filters.h"
	#include "media/base/test_helpers.h"
	#include "media/base/timestamp_constants.h"
	#include "media/filters/decrypting_audio_decoder.h"
	#include "testing/gmock/include/gmock/gmock.h"

	using ::base::test::RunCallback;
	using ::testing::_;
	using ::testing::AtMost;
	using ::testing::Return;
	using ::testing::SaveArg;
	using ::testing::StrictMock;

	namespace media {

	const int kSampleRate = 44100;

	// Make sure the kFakeAudioFrameSize is a valid frame size for all audio decoder
	// configs used in this test.
	const int kFakeAudioFrameSize = 48;
	const uint8_t kFakeKeyId[] = {0x4b, 0x65, 0x79, 0x20, 0x49, 0x44};
	const uint8_t kFakeIv[DecryptConfig::kDecryptionKeySize] = {0};
	const int kDecodingDelay = 3;

	// Create a fake non-empty encrypted buffer.
	static scoped_refptr<DecoderBuffer> CreateFakeEncryptedBuffer() {
	const int buffer_size = 16; // Need a non-empty buffer;
	scoped_refptr<DecoderBuffer> buffer(new DecoderBuffer(buffer_size));
	buffer->set_decrypt_config(DecryptConfig::CreateCencConfig(
	std::string(reinterpret_cast<const char*>(kFakeKeyId),
	base::size(kFakeKeyId)),
	std::string(reinterpret_cast<const char*>(kFakeIv), base::size(kFakeIv)),
	std::vector<SubsampleEntry>()));
	return buffer;
	}

	class DecryptingAudioDecoderTest : public testing::Test {
	public:
	DecryptingAudioDecoderTest()
	: decoder_(new DecryptingAudioDecoder(
	scoped_task_environment_.GetMainThreadTaskRunner(),
	&media_log_)),
	cdm_context_(new StrictMock<MockCdmContext>()),
	decryptor_(new StrictMock<MockDecryptor>()),
	num_decrypt_and_decode_calls_(0),
	num_frames_in_decryptor_(0),
	encrypted_buffer_(CreateFakeEncryptedBuffer()),
	decoded_frame_(NULL),
	decoded_frame_list_() {}

	~DecryptingAudioDecoderTest() override { Destroy(); }

	void InitializeAndExpectResult(const AudioDecoderConfig& config,
	bool success) {
	// Initialize data now that the config is known. Since the code uses
	// invalid values (that CreateEmptyBuffer() doesn't support), tweak them
	// just for CreateEmptyBuffer().
	int channels = ChannelLayoutToChannelCount(config.channel_layout());
	if (channels < 0)
	channels = 0;
	decoded_frame_ = AudioBuffer::CreateEmptyBuffer(
	config.channel_layout(), channels, kSampleRate, kFakeAudioFrameSize,
	kNoTimestamp);
	decoded_frame_list_.push_back(decoded_frame_);

	decoder_->Initialize(config, cdm_context_.get(), NewExpectedBoolCB(success),
	base::Bind(&DecryptingAudioDecoderTest::FrameReady,
	base::Unretained(this)),
	base::Bind(&DecryptingAudioDecoderTest::OnWaiting,
	base::Unretained(this)));
	base::RunLoop().RunUntilIdle();
	}

	enum CdmType { CDM_WITHOUT_DECRYPTOR, CDM_WITH_DECRYPTOR };

	void SetCdmType(CdmType cdm_type) {
	const bool has_decryptor = cdm_type == CDM_WITH_DECRYPTOR;
	EXPECT_CALL(*cdm_context_, GetDecryptor())
	.WillRepeatedly(Return(has_decryptor ? decryptor_.get() : nullptr));
	}

	void Initialize() {
	SetCdmType(CDM_WITH_DECRYPTOR);
	EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
	.Times(AtMost(1))
	.WillOnce(RunCallback<1>(true));
	EXPECT_CALL(*decryptor_, RegisterNewKeyCB(Decryptor::kAudio, _))
	.WillOnce(SaveArg<1>(&key_added_cb_));

	config_.Initialize(kCodecVorbis, kSampleFormatPlanarF32,
	CHANNEL_LAYOUT_STEREO, kSampleRate, EmptyExtraData(),
	AesCtrEncryptionScheme(), base::TimeDelta(), 0);
	InitializeAndExpectResult(config_, true);
	}

	void Reinitialize() { ReinitializeConfigChange(config_); }

	void ReinitializeConfigChange(const AudioDecoderConfig& new_config) {
	EXPECT_CALL(*decryptor_, DeinitializeDecoder(Decryptor::kAudio));
	EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
	.WillOnce(RunCallback<1>(true));
	EXPECT_CALL(*decryptor_, RegisterNewKeyCB(Decryptor::kAudio, _))
	.WillOnce(SaveArg<1>(&key_added_cb_));
	decoder_->Initialize(new_config, cdm_context_.get(),
	NewExpectedBoolCB(true),
	base::Bind(&DecryptingAudioDecoderTest::FrameReady,
	base::Unretained(this)),
	base::Bind(&DecryptingAudioDecoderTest::OnWaiting,
	base::Unretained(this)));
	}

	// Decode \|buffer\| and expect DecodeDone to get called with \|status\|.
	void DecodeAndExpect(scoped_refptr<DecoderBuffer> buffer,
	DecodeStatus status) {
	EXPECT_CALL(*this, DecodeDone(status));
	decoder_->Decode(buffer, base::Bind(&DecryptingAudioDecoderTest::DecodeDone,
	base::Unretained(this)));
	base::RunLoop().RunUntilIdle();
	}

	// Helper function to simulate the decrypting and decoding process in the
	// \|decryptor_\| with a decoding delay of kDecodingDelay buffers.
	void DecryptAndDecodeAudio(scoped_refptr<DecoderBuffer> encrypted,
	const Decryptor::AudioDecodeCB& audio_decode_cb) {
	num_decrypt_and_decode_calls_++;
	if (!encrypted->end_of_stream())
	num_frames_in_decryptor_++;

	if (num_decrypt_and_decode_calls_ <= kDecodingDelay \|\|
	num_frames_in_decryptor_ == 0) {
	audio_decode_cb.Run(Decryptor::kNeedMoreData, Decryptor::AudioFrames());
	return;
	}

	num_frames_in_decryptor_--;
	audio_decode_cb.Run(Decryptor::kSuccess,
	Decryptor::AudioFrames(1, decoded_frame_));
	}

	// Sets up expectations and actions to put DecryptingAudioDecoder in an
	// active normal decoding state.
	void EnterNormalDecodingState() {
	EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
	.WillRepeatedly(
	Invoke(this, &DecryptingAudioDecoderTest::DecryptAndDecodeAudio));
	EXPECT_CALL(*this, FrameReady(decoded_frame_));
	for (int i = 0; i < kDecodingDelay + 1; ++i)
	DecodeAndExpect(encrypted_buffer_, DecodeStatus::OK);
	}

	// Sets up expectations and actions to put DecryptingAudioDecoder in an end
	// of stream state. This function must be called after
	// EnterNormalDecodingState() to work.
	void EnterEndOfStreamState() {
	// The codec in the \|decryptor_\| will be flushed.
	EXPECT_CALL(*this, FrameReady(decoded_frame_)).Times(kDecodingDelay);
	DecodeAndExpect(DecoderBuffer::CreateEOSBuffer(), DecodeStatus::OK);
	EXPECT_EQ(0, num_frames_in_decryptor_);
	}

	// Make the audio decode callback pending by saving and not firing it.
	void EnterPendingDecodeState() {
	EXPECT_TRUE(!pending_audio_decode_cb_);
	EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(encrypted_buffer_, _))
	.WillOnce(SaveArg<1>(&pending_audio_decode_cb_));

	decoder_->Decode(encrypted_buffer_,
	base::Bind(&DecryptingAudioDecoderTest::DecodeDone,
	base::Unretained(this)));
	base::RunLoop().RunUntilIdle();
	// Make sure the Decode() on the decoder triggers a DecryptAndDecode() on
	// the decryptor.
	EXPECT_FALSE(!pending_audio_decode_cb_);
	}

	void EnterWaitingForKeyState() {
	EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(encrypted_buffer_, _))
	.WillRepeatedly(
	RunCallback<1>(Decryptor::kNoKey, Decryptor::AudioFrames()));
	EXPECT_CALL(*this, OnWaiting(WaitingReason::kNoDecryptionKey));
	decoder_->Decode(encrypted_buffer_,
	base::Bind(&DecryptingAudioDecoderTest::DecodeDone,
	base::Unretained(this)));

	base::RunLoop().RunUntilIdle();
	}

	void AbortPendingAudioDecodeCB() {
	if (pending_audio_decode_cb_) {
	std::move(pending_audio_decode_cb_)
	.Run(Decryptor::kSuccess, Decryptor::AudioFrames());
	}
	}

	void AbortAllPendingCBs() {
	if (pending_init_cb_) {
	ASSERT_TRUE(!pending_audio_decode_cb_);
	std::move(pending_init_cb_).Run(false);
	return;
	}

	AbortPendingAudioDecodeCB();
	}

	void Reset() {
	EXPECT_CALL(*decryptor_, ResetDecoder(Decryptor::kAudio))
	.WillRepeatedly(InvokeWithoutArgs(
	this, &DecryptingAudioDecoderTest::AbortPendingAudioDecodeCB));

	decoder_->Reset(NewExpectedClosure());
	base::RunLoop().RunUntilIdle();
	}

	void Destroy() {
	EXPECT_CALL(*decryptor_, DeinitializeDecoder(Decryptor::kAudio))
	.WillRepeatedly(InvokeWithoutArgs(
	this, &DecryptingAudioDecoderTest::AbortAllPendingCBs));

	decoder_.reset();
	base::RunLoop().RunUntilIdle();
	}

	MOCK_METHOD1(FrameReady, void(scoped_refptr<AudioBuffer>));
	MOCK_METHOD1(DecodeDone, void(DecodeStatus));

	MOCK_METHOD1(OnWaiting, void(WaitingReason));

	base::test::ScopedTaskEnvironment scoped_task_environment_;
	NullMediaLog media_log_;
	std::unique_ptr<DecryptingAudioDecoder> decoder_;
	std::unique_ptr<StrictMock<MockCdmContext>> cdm_context_;
	std::unique_ptr<StrictMock<MockDecryptor>> decryptor_;
	AudioDecoderConfig config_;

	// Variables to help the \|decryptor_\| to simulate decoding delay and flushing.
	int num_decrypt_and_decode_calls_;
	int num_frames_in_decryptor_;

	Decryptor::DecoderInitCB pending_init_cb_;
	Decryptor::NewKeyCB key_added_cb_;
	Decryptor::AudioDecodeCB pending_audio_decode_cb_;

	// Constant buffer/frames, to be used/returned by \|decoder_\| and \|decryptor_\|.
	scoped_refptr<DecoderBuffer> encrypted_buffer_;
	scoped_refptr<AudioBuffer> decoded_frame_;
	Decryptor::AudioFrames decoded_frame_list_;

	private:
	DISALLOW_COPY_AND_ASSIGN(DecryptingAudioDecoderTest);
	};

	TEST_F(DecryptingAudioDecoderTest, Initialize_Normal) {
	Initialize();
	}

	// Ensure decoder handles invalid audio configs without crashing.
	TEST_F(DecryptingAudioDecoderTest, Initialize_InvalidAudioConfig) {
	AudioDecoderConfig config(kUnknownAudioCodec, kUnknownSampleFormat,
	CHANNEL_LAYOUT_STEREO, 0, EmptyExtraData(),
	AesCtrEncryptionScheme());

	InitializeAndExpectResult(config, false);
	}

	// Ensure decoder handles unsupported audio configs without crashing.
	TEST_F(DecryptingAudioDecoderTest, Initialize_UnsupportedAudioConfig) {
	SetCdmType(CDM_WITH_DECRYPTOR);
	EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
	.WillOnce(RunCallback<1>(false));

	AudioDecoderConfig config(kCodecVorbis, kSampleFormatPlanarF32,
	CHANNEL_LAYOUT_STEREO, kSampleRate,
	EmptyExtraData(), AesCtrEncryptionScheme());
	InitializeAndExpectResult(config, false);
	}

	TEST_F(DecryptingAudioDecoderTest, Initialize_CdmWithoutDecryptor) {
	SetCdmType(CDM_WITHOUT_DECRYPTOR);
	AudioDecoderConfig config(kCodecVorbis, kSampleFormatPlanarF32,
	CHANNEL_LAYOUT_STEREO, kSampleRate,
	EmptyExtraData(), AesCtrEncryptionScheme());
	InitializeAndExpectResult(config, false);
	}

	// Test normal decrypt and decode case.
	TEST_F(DecryptingAudioDecoderTest, DecryptAndDecode_Normal) {
	Initialize();
	EnterNormalDecodingState();
	}

	// Test the case where the decryptor returns error when doing decrypt and
	// decode.
	TEST_F(DecryptingAudioDecoderTest, DecryptAndDecode_DecodeError) {
	Initialize();

	EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
	.WillRepeatedly(
	RunCallback<1>(Decryptor::kError, Decryptor::AudioFrames()));

	DecodeAndExpect(encrypted_buffer_, DecodeStatus::DECODE_ERROR);
	}

	// Test the case where the decryptor returns multiple decoded frames.
	TEST_F(DecryptingAudioDecoderTest, DecryptAndDecode_MultipleFrames) {
	Initialize();

	scoped_refptr<AudioBuffer> frame_a = AudioBuffer::CreateEmptyBuffer(
	config_.channel_layout(),
	ChannelLayoutToChannelCount(config_.channel_layout()), kSampleRate,
	kFakeAudioFrameSize, kNoTimestamp);
	scoped_refptr<AudioBuffer> frame_b = AudioBuffer::CreateEmptyBuffer(
	config_.channel_layout(),
	ChannelLayoutToChannelCount(config_.channel_layout()), kSampleRate,
	kFakeAudioFrameSize, kNoTimestamp);
	decoded_frame_list_.push_back(frame_a);
	decoded_frame_list_.push_back(frame_b);

	EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
	.WillOnce(RunCallback<1>(Decryptor::kSuccess, decoded_frame_list_));

	EXPECT_CALL(*this, FrameReady(decoded_frame_));
	EXPECT_CALL(*this, FrameReady(frame_a));
	EXPECT_CALL(*this, FrameReady(frame_b));
	DecodeAndExpect(encrypted_buffer_, DecodeStatus::OK);
	}

	// Test the case where the decryptor receives end-of-stream buffer.
	TEST_F(DecryptingAudioDecoderTest, DecryptAndDecode_EndOfStream) {
	Initialize();
	EnterNormalDecodingState();
	EnterEndOfStreamState();
	}

	// Test reinitializing decode with a new encrypted config.
	TEST_F(DecryptingAudioDecoderTest, Reinitialize_EncryptedToEncrypted) {
	Initialize();

	EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
	.Times(AtMost(1))
	.WillOnce(RunCallback<1>(true));

	// The new config is different from the initial config in bits-per-channel,
	// channel layout and samples_per_second.
	AudioDecoderConfig new_config(kCodecVorbis, kSampleFormatPlanarS16,
	CHANNEL_LAYOUT_5_1, 88200, EmptyExtraData(),
	AesCtrEncryptionScheme());
	EXPECT_NE(new_config.bits_per_channel(), config_.bits_per_channel());
	EXPECT_NE(new_config.channel_layout(), config_.channel_layout());
	EXPECT_NE(new_config.samples_per_second(), config_.samples_per_second());
	ASSERT_TRUE(new_config.is_encrypted());

	ReinitializeConfigChange(new_config);
	base::RunLoop().RunUntilIdle();
	}

	// Test reinitializing decode with a new clear config.
	TEST_F(DecryptingAudioDecoderTest, Reinitialize_EncryptedToClear) {
	Initialize();

	EXPECT_CALL(*decryptor_, InitializeAudioDecoder(_, _))
	.Times(AtMost(1))
	.WillOnce(RunCallback<1>(true));

	// The new config is different from the initial config in bits-per-channel,
	// channel layout and samples_per_second.
	AudioDecoderConfig new_config(kCodecVorbis, kSampleFormatPlanarS16,
	CHANNEL_LAYOUT_5_1, 88200, EmptyExtraData(),
	Unencrypted());
	EXPECT_NE(new_config.bits_per_channel(), config_.bits_per_channel());
	EXPECT_NE(new_config.channel_layout(), config_.channel_layout());
	EXPECT_NE(new_config.samples_per_second(), config_.samples_per_second());
	ASSERT_FALSE(new_config.is_encrypted());

	ReinitializeConfigChange(new_config);
	base::RunLoop().RunUntilIdle();
	}

	// Test the case where the a key is added when the decryptor is in
	// kWaitingForKey state.
	TEST_F(DecryptingAudioDecoderTest, KeyAdded_DuringWaitingForKey) {
	Initialize();
	EnterWaitingForKeyState();

	EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
	.WillRepeatedly(RunCallback<1>(Decryptor::kSuccess, decoded_frame_list_));
	EXPECT_CALL(*this, FrameReady(decoded_frame_));
	EXPECT_CALL(*this, DecodeDone(DecodeStatus::OK));
	key_added_cb_.Run();
	base::RunLoop().RunUntilIdle();
	}

	// Test the case where the a key is added when the decryptor is in
	// kPendingDecode state.
	TEST_F(DecryptingAudioDecoderTest, KeyAdded_DruingPendingDecode) {
	Initialize();
	EnterPendingDecodeState();

	EXPECT_CALL(*decryptor_, DecryptAndDecodeAudio(_, _))
	.WillRepeatedly(RunCallback<1>(Decryptor::kSuccess, decoded_frame_list_));
	EXPECT_CALL(*this, FrameReady(decoded_frame_));
	EXPECT_CALL(*this, DecodeDone(DecodeStatus::OK));
	// The audio decode callback is returned after the correct decryption key is
	// added.
	key_added_cb_.Run();
	std::move(pending_audio_decode_cb_)
	.Run(Decryptor::kNoKey, Decryptor::AudioFrames());
	base::RunLoop().RunUntilIdle();
	}

	// Test resetting when the decoder is in kIdle state but has not decoded any
	// frame.
	TEST_F(DecryptingAudioDecoderTest, Reset_DuringIdleAfterInitialization) {
	Initialize();
	Reset();
	}

	// Test resetting when the decoder is in kIdle state after it has decoded one
	// frame.
	TEST_F(DecryptingAudioDecoderTest, Reset_DuringIdleAfterDecodedOneFrame) {
	Initialize();
	EnterNormalDecodingState();
	Reset();
	}

	// Test resetting when the decoder is in kPendingDecode state.
	TEST_F(DecryptingAudioDecoderTest, Reset_DuringPendingDecode) {
	Initialize();
	EnterPendingDecodeState();

	EXPECT_CALL(*this, DecodeDone(DecodeStatus::ABORTED));

	Reset();
	}

	// Test resetting when the decoder is in kWaitingForKey state.
	TEST_F(DecryptingAudioDecoderTest, Reset_DuringWaitingForKey) {
	Initialize();
	EnterWaitingForKeyState();

	EXPECT_CALL(*this, DecodeDone(DecodeStatus::ABORTED));

	Reset();
	}

	// Test resetting when the decoder has hit end of stream and is in
	// kDecodeFinished state.
	TEST_F(DecryptingAudioDecoderTest, Reset_AfterDecodeFinished) {
	Initialize();
	EnterNormalDecodingState();
	EnterEndOfStreamState();
	Reset();
	}

	// Test resetting after the decoder has been reset.
	TEST_F(DecryptingAudioDecoderTest, Reset_AfterReset) {
	Initialize();
	EnterNormalDecodingState();
	Reset();
	Reset();
	}

	} // namespace media