blob: 0adf1f485163d98e1d0db11411f9d72145b03937 [file] [log] [blame]
// 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 <string>
#include <vector>
#include "base/basictypes.h"
#include "base/bind.h"
#include "base/callback_helpers.h"
#include "base/message_loop.h"
#include "base/run_loop.h"
#include "cobalt/media/base/decoder_buffer.h"
#include "cobalt/media/base/decrypt_config.h"
#include "cobalt/media/base/gmock_callback_support.h"
#include "cobalt/media/base/media_util.h"
#include "cobalt/media/base/mock_filters.h"
#include "cobalt/media/base/test_helpers.h"
#include "cobalt/media/filters/decrypting_demuxer_stream.h"
#include "starboard/types.h"
#include "testing/gmock/include/gmock/gmock.h"
using ::testing::_;
using ::testing::IsNull;
using ::testing::Return;
using ::testing::SaveArg;
using ::testing::StrictMock;
namespace cobalt {
namespace media {
static const int kFakeBufferSize = 16;
static const uint8_t kFakeKeyId[] = {0x4b, 0x65, 0x79, 0x20, 0x49, 0x44};
static const uint8_t kFakeIv[DecryptConfig::kDecryptionKeySize] = {0};
// Create a fake non-empty buffer in an encrypted stream. When |is_clear| is
// true, the buffer is not encrypted (signaled by an empty IV).
static scoped_refptr<DecoderBuffer> CreateFakeEncryptedStreamBuffer(
bool is_clear) {
scoped_refptr<DecoderBuffer> buffer(new DecoderBuffer(kFakeBufferSize));
std::string iv = is_clear
? std::string()
: std::string(reinterpret_cast<const char*>(kFakeIv),
arraysize(kFakeIv));
buffer->set_decrypt_config(std::unique_ptr<DecryptConfig>(
new DecryptConfig(std::string(reinterpret_cast<const char*>(kFakeKeyId),
arraysize(kFakeKeyId)),
iv, std::vector<SubsampleEntry>())));
return buffer;
}
// Use anonymous namespace here to prevent the actions to be defined multiple
// times across multiple test files. Sadly we can't use static for them.
namespace {
ACTION_P(ReturnBuffer, buffer) {
arg0.Run(buffer.get() ? DemuxerStream::kOk : DemuxerStream::kAborted, buffer);
}
} // namespace
class DecryptingDemuxerStreamTest : public testing::Test {
public:
DecryptingDemuxerStreamTest()
: demuxer_stream_(new DecryptingDemuxerStream(
message_loop_.task_runner(), new MediaLog(),
base::Bind(&DecryptingDemuxerStreamTest::OnWaitingForDecryptionKey,
base::Unretained(this)))),
cdm_context_(new StrictMock<MockCdmContext>()),
decryptor_(new StrictMock<MockDecryptor>()),
is_initialized_(false),
input_audio_stream_(
new StrictMock<MockDemuxerStream>(DemuxerStream::AUDIO)),
input_video_stream_(
new StrictMock<MockDemuxerStream>(DemuxerStream::VIDEO)),
clear_buffer_(CreateFakeEncryptedStreamBuffer(true)),
encrypted_buffer_(CreateFakeEncryptedStreamBuffer(false)),
decrypted_buffer_(new DecoderBuffer(kFakeBufferSize)) {}
virtual ~DecryptingDemuxerStreamTest() {
if (is_initialized_) EXPECT_CALL(*decryptor_, CancelDecrypt(_));
demuxer_stream_.reset();
base::RunLoop().RunUntilIdle();
}
void OnInitialized(PipelineStatus expected_status, PipelineStatus status) {
EXPECT_EQ(expected_status, status);
is_initialized_ = status == PIPELINE_OK;
}
void InitializeAudioAndExpectStatus(const AudioDecoderConfig& config,
PipelineStatus expected_status) {
input_audio_stream_->set_audio_decoder_config(config);
demuxer_stream_->Initialize(
input_audio_stream_.get(), cdm_context_.get(),
base::Bind(&DecryptingDemuxerStreamTest::OnInitialized,
base::Unretained(this), expected_status));
base::RunLoop().RunUntilIdle();
}
void InitializeVideoAndExpectStatus(const VideoDecoderConfig& config,
PipelineStatus expected_status) {
input_video_stream_->set_video_decoder_config(config);
demuxer_stream_->Initialize(
input_video_stream_.get(), cdm_context_.get(),
base::Bind(&DecryptingDemuxerStreamTest::OnInitialized,
base::Unretained(this), expected_status));
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() : NULL));
}
// The following functions are used to test stream-type-neutral logic in
// DecryptingDemuxerStream. Therefore, we don't specify audio or video in the
// function names. But for testing purpose, they all use an audio input
// demuxer stream.
void Initialize() {
SetCdmType(CDM_WITH_DECRYPTOR);
EXPECT_CALL(*decryptor_, RegisterNewKeyCB(Decryptor::kAudio, _))
.WillOnce(SaveArg<1>(&key_added_cb_));
AudioDecoderConfig input_config(kCodecVorbis, kSampleFormatPlanarF32,
CHANNEL_LAYOUT_STEREO, 44100,
EmptyExtraData(), AesCtrEncryptionScheme());
InitializeAudioAndExpectStatus(input_config, PIPELINE_OK);
const AudioDecoderConfig& output_config =
demuxer_stream_->audio_decoder_config();
EXPECT_EQ(DemuxerStream::AUDIO, demuxer_stream_->type());
EXPECT_FALSE(output_config.is_encrypted());
EXPECT_EQ(input_config.bits_per_channel(),
output_config.bits_per_channel());
EXPECT_EQ(input_config.channel_layout(), output_config.channel_layout());
EXPECT_EQ(input_config.sample_format(), output_config.sample_format());
EXPECT_EQ(input_config.samples_per_second(),
output_config.samples_per_second());
}
void ReadAndExpectBufferReadyWith(
DemuxerStream::Status status,
const scoped_refptr<DecoderBuffer>& decrypted_buffer) {
if (status != DemuxerStream::kOk)
EXPECT_CALL(*this, BufferReady(status, IsNull()));
else if (decrypted_buffer->end_of_stream())
EXPECT_CALL(*this, BufferReady(status, IsEndOfStream()));
else
EXPECT_CALL(*this, BufferReady(status, decrypted_buffer));
demuxer_stream_->Read(base::Bind(&DecryptingDemuxerStreamTest::BufferReady,
base::Unretained(this)));
base::RunLoop().RunUntilIdle();
}
void EnterClearReadingState() {
EXPECT_TRUE(clear_buffer_->decrypt_config());
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillOnce(ReturnBuffer(clear_buffer_));
// For clearbuffer, decryptor->Decrypt() will not be called.
scoped_refptr<DecoderBuffer> decrypted_buffer;
EXPECT_CALL(*this, BufferReady(DemuxerStream::kOk, _))
.WillOnce(SaveArg<1>(&decrypted_buffer));
demuxer_stream_->Read(base::Bind(&DecryptingDemuxerStreamTest::BufferReady,
base::Unretained(this)));
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(decrypted_buffer->decrypt_config());
}
// Sets up expectations and actions to put DecryptingDemuxerStream in an
// active normal reading state.
void EnterNormalReadingState() {
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillOnce(ReturnBuffer(encrypted_buffer_));
EXPECT_CALL(*decryptor_, Decrypt(_, _, _))
.WillOnce(RunCallback<2>(Decryptor::kSuccess, decrypted_buffer_));
ReadAndExpectBufferReadyWith(DemuxerStream::kOk, decrypted_buffer_);
}
// Make the read callback pending by saving and not firing it.
void EnterPendingReadState() {
EXPECT_TRUE(pending_demuxer_read_cb_.is_null());
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillOnce(SaveArg<0>(&pending_demuxer_read_cb_));
demuxer_stream_->Read(base::Bind(&DecryptingDemuxerStreamTest::BufferReady,
base::Unretained(this)));
base::RunLoop().RunUntilIdle();
// Make sure the Read() triggers a Read() on the input demuxer stream.
EXPECT_FALSE(pending_demuxer_read_cb_.is_null());
}
// Make the decrypt callback pending by saving and not firing it.
void EnterPendingDecryptState() {
EXPECT_TRUE(pending_decrypt_cb_.is_null());
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillRepeatedly(ReturnBuffer(encrypted_buffer_));
EXPECT_CALL(*decryptor_, Decrypt(_, encrypted_buffer_, _))
.WillOnce(SaveArg<2>(&pending_decrypt_cb_));
demuxer_stream_->Read(base::Bind(&DecryptingDemuxerStreamTest::BufferReady,
base::Unretained(this)));
base::RunLoop().RunUntilIdle();
// Make sure Read() triggers a Decrypt() on the decryptor.
EXPECT_FALSE(pending_decrypt_cb_.is_null());
}
void EnterWaitingForKeyState() {
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillRepeatedly(ReturnBuffer(encrypted_buffer_));
EXPECT_CALL(*decryptor_, Decrypt(_, encrypted_buffer_, _))
.WillRepeatedly(
RunCallback<2>(Decryptor::kNoKey, scoped_refptr<DecoderBuffer>()));
EXPECT_CALL(*this, OnWaitingForDecryptionKey());
demuxer_stream_->Read(base::Bind(&DecryptingDemuxerStreamTest::BufferReady,
base::Unretained(this)));
base::RunLoop().RunUntilIdle();
}
void AbortPendingDecryptCB() {
if (!pending_decrypt_cb_.is_null()) {
base::ResetAndReturn(&pending_decrypt_cb_).Run(Decryptor::kSuccess, NULL);
}
}
void SatisfyPendingDemuxerReadCB(DemuxerStream::Status status) {
scoped_refptr<DecoderBuffer> buffer =
(status == DemuxerStream::kOk) ? encrypted_buffer_ : NULL;
base::ResetAndReturn(&pending_demuxer_read_cb_).Run(status, buffer);
}
void Reset() {
EXPECT_CALL(*decryptor_, CancelDecrypt(Decryptor::kAudio))
.WillRepeatedly(InvokeWithoutArgs(
this, &DecryptingDemuxerStreamTest::AbortPendingDecryptCB));
demuxer_stream_->Reset(NewExpectedClosure());
base::RunLoop().RunUntilIdle();
}
MOCK_METHOD2(BufferReady, void(DemuxerStream::Status,
const scoped_refptr<DecoderBuffer>&));
MOCK_METHOD0(OnWaitingForDecryptionKey, void(void));
base::MessageLoop message_loop_;
std::unique_ptr<DecryptingDemuxerStream> demuxer_stream_;
std::unique_ptr<StrictMock<MockCdmContext>> cdm_context_;
std::unique_ptr<StrictMock<MockDecryptor>> decryptor_;
// Whether the |demuxer_stream_| is successfully initialized.
bool is_initialized_;
std::unique_ptr<StrictMock<MockDemuxerStream>> input_audio_stream_;
std::unique_ptr<StrictMock<MockDemuxerStream>> input_video_stream_;
DemuxerStream::ReadCB pending_demuxer_read_cb_;
Decryptor::NewKeyCB key_added_cb_;
Decryptor::DecryptCB pending_decrypt_cb_;
// Constant buffers to be returned by the input demuxer streams and the
// |decryptor_|.
scoped_refptr<DecoderBuffer> clear_buffer_;
scoped_refptr<DecoderBuffer> encrypted_buffer_;
scoped_refptr<DecoderBuffer> decrypted_buffer_;
private:
DISALLOW_COPY_AND_ASSIGN(DecryptingDemuxerStreamTest);
};
TEST_F(DecryptingDemuxerStreamTest, Initialize_NormalAudio) { Initialize(); }
TEST_F(DecryptingDemuxerStreamTest, Initialize_NormalVideo) {
SetCdmType(CDM_WITH_DECRYPTOR);
EXPECT_CALL(*decryptor_, RegisterNewKeyCB(Decryptor::kVideo, _))
.WillOnce(SaveArg<1>(&key_added_cb_));
VideoDecoderConfig input_config = TestVideoConfig::NormalEncrypted();
InitializeVideoAndExpectStatus(input_config, PIPELINE_OK);
const VideoDecoderConfig& output_config =
demuxer_stream_->video_decoder_config();
EXPECT_EQ(DemuxerStream::VIDEO, demuxer_stream_->type());
EXPECT_FALSE(output_config.is_encrypted());
EXPECT_EQ(input_config.codec(), output_config.codec());
EXPECT_EQ(input_config.format(), output_config.format());
EXPECT_EQ(input_config.profile(), output_config.profile());
EXPECT_EQ(input_config.coded_size(), output_config.coded_size());
EXPECT_EQ(input_config.visible_rect(), output_config.visible_rect());
EXPECT_EQ(input_config.natural_size(), output_config.natural_size());
ASSERT_EQ(input_config.extra_data(), output_config.extra_data());
}
TEST_F(DecryptingDemuxerStreamTest, Initialize_CdmWithoutDecryptor) {
SetCdmType(CDM_WITHOUT_DECRYPTOR);
AudioDecoderConfig input_config(kCodecVorbis, kSampleFormatPlanarF32,
CHANNEL_LAYOUT_STEREO, 44100,
EmptyExtraData(), AesCtrEncryptionScheme());
InitializeAudioAndExpectStatus(input_config, DECODER_ERROR_NOT_SUPPORTED);
}
// Test normal read case where the buffer is encrypted.
TEST_F(DecryptingDemuxerStreamTest, Read_Normal) {
Initialize();
EnterNormalReadingState();
}
// Test normal read case where the buffer is clear.
TEST_F(DecryptingDemuxerStreamTest, Read_Clear) {
Initialize();
EnterClearReadingState();
}
// Test the case where the decryptor returns error during read.
TEST_F(DecryptingDemuxerStreamTest, Read_DecryptError) {
Initialize();
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillRepeatedly(ReturnBuffer(encrypted_buffer_));
EXPECT_CALL(*decryptor_, Decrypt(_, encrypted_buffer_, _))
.WillRepeatedly(
RunCallback<2>(Decryptor::kError, scoped_refptr<DecoderBuffer>()));
ReadAndExpectBufferReadyWith(DemuxerStream::kAborted, NULL);
}
// Test the case where the input is an end-of-stream buffer.
TEST_F(DecryptingDemuxerStreamTest, Read_EndOfStream) {
Initialize();
EnterNormalReadingState();
// No Decryptor::Decrypt() call is expected for EOS buffer.
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillOnce(ReturnBuffer(DecoderBuffer::CreateEOSBuffer()));
ReadAndExpectBufferReadyWith(DemuxerStream::kOk,
DecoderBuffer::CreateEOSBuffer());
}
// Test the case where the a key is added when the decryptor is in
// kWaitingForKey state.
TEST_F(DecryptingDemuxerStreamTest, KeyAdded_DuringWaitingForKey) {
Initialize();
EnterWaitingForKeyState();
EXPECT_CALL(*decryptor_, Decrypt(_, encrypted_buffer_, _))
.WillRepeatedly(RunCallback<2>(Decryptor::kSuccess, decrypted_buffer_));
EXPECT_CALL(*this, BufferReady(DemuxerStream::kOk, decrypted_buffer_));
key_added_cb_.Run();
base::RunLoop().RunUntilIdle();
}
// Test the case where the a key is added when the decryptor is in
// kPendingDecrypt state.
TEST_F(DecryptingDemuxerStreamTest, KeyAdded_DuringPendingDecrypt) {
Initialize();
EnterPendingDecryptState();
EXPECT_CALL(*decryptor_, Decrypt(_, encrypted_buffer_, _))
.WillRepeatedly(RunCallback<2>(Decryptor::kSuccess, decrypted_buffer_));
EXPECT_CALL(*this, BufferReady(DemuxerStream::kOk, decrypted_buffer_));
// The decrypt callback is returned after the correct decryption key is added.
key_added_cb_.Run();
base::ResetAndReturn(&pending_decrypt_cb_).Run(Decryptor::kNoKey, NULL);
base::RunLoop().RunUntilIdle();
}
// Test resetting in kIdle state but has not returned any buffer.
TEST_F(DecryptingDemuxerStreamTest, Reset_DuringIdleAfterInitialization) {
Initialize();
Reset();
}
// Test resetting in kIdle state after having returned one buffer.
TEST_F(DecryptingDemuxerStreamTest, Reset_DuringIdleAfterReadOneBuffer) {
Initialize();
EnterNormalReadingState();
Reset();
}
// Test resetting in kPendingDemuxerRead state.
TEST_F(DecryptingDemuxerStreamTest, Reset_DuringPendingDemuxerRead) {
Initialize();
EnterPendingReadState();
EXPECT_CALL(*this, BufferReady(DemuxerStream::kAborted, IsNull()));
Reset();
SatisfyPendingDemuxerReadCB(DemuxerStream::kOk);
base::RunLoop().RunUntilIdle();
}
// Test resetting in kPendingDecrypt state.
TEST_F(DecryptingDemuxerStreamTest, Reset_DuringPendingDecrypt) {
Initialize();
EnterPendingDecryptState();
EXPECT_CALL(*this, BufferReady(DemuxerStream::kAborted, IsNull()));
Reset();
}
// Test resetting in kWaitingForKey state.
TEST_F(DecryptingDemuxerStreamTest, Reset_DuringWaitingForKey) {
Initialize();
EnterWaitingForKeyState();
EXPECT_CALL(*this, BufferReady(DemuxerStream::kAborted, IsNull()));
Reset();
}
// Test resetting after reset.
TEST_F(DecryptingDemuxerStreamTest, Reset_AfterReset) {
Initialize();
EnterNormalReadingState();
Reset();
Reset();
}
// Test aborted read on the demuxer stream.
TEST_F(DecryptingDemuxerStreamTest, DemuxerRead_Aborted) {
Initialize();
// ReturnBuffer() with NULL triggers aborted demuxer read.
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillOnce(ReturnBuffer(scoped_refptr<DecoderBuffer>()));
ReadAndExpectBufferReadyWith(DemuxerStream::kAborted, NULL);
}
// Test resetting when waiting for an aborted read.
TEST_F(DecryptingDemuxerStreamTest, Reset_DuringAbortedDemuxerRead) {
Initialize();
EnterPendingReadState();
// Make sure we get a NULL audio frame returned.
EXPECT_CALL(*this, BufferReady(DemuxerStream::kAborted, IsNull()));
Reset();
SatisfyPendingDemuxerReadCB(DemuxerStream::kAborted);
base::RunLoop().RunUntilIdle();
}
// Test config change on the input demuxer stream.
TEST_F(DecryptingDemuxerStreamTest, DemuxerRead_ConfigChanged) {
Initialize();
AudioDecoderConfig new_config(kCodecVorbis, kSampleFormatPlanarF32,
CHANNEL_LAYOUT_STEREO, 88200, EmptyExtraData(),
AesCtrEncryptionScheme());
input_audio_stream_->set_audio_decoder_config(new_config);
EXPECT_CALL(*input_audio_stream_, Read(_))
.WillOnce(RunCallback<0>(DemuxerStream::kConfigChanged,
scoped_refptr<DecoderBuffer>()));
ReadAndExpectBufferReadyWith(DemuxerStream::kConfigChanged, NULL);
}
// Test resetting when waiting for a config changed read.
TEST_F(DecryptingDemuxerStreamTest, Reset_DuringConfigChangedDemuxerRead) {
Initialize();
EnterPendingReadState();
// Make sure we get a |kConfigChanged| instead of a |kAborted|.
EXPECT_CALL(*this, BufferReady(DemuxerStream::kConfigChanged, IsNull()));
Reset();
SatisfyPendingDemuxerReadCB(DemuxerStream::kConfigChanged);
base::RunLoop().RunUntilIdle();
}
// The following tests test destruction in various scenarios. The destruction
// happens in DecryptingDemuxerStreamTest's dtor.
// Test destruction in kIdle state but has not returned any buffer.
TEST_F(DecryptingDemuxerStreamTest, Destroy_DuringIdleAfterInitialization) {
Initialize();
}
// Test destruction in kIdle state after having returned one buffer.
TEST_F(DecryptingDemuxerStreamTest, Destroy_DuringIdleAfterReadOneBuffer) {
Initialize();
EnterNormalReadingState();
}
// Test destruction in kPendingDemuxerRead state.
TEST_F(DecryptingDemuxerStreamTest, Destroy_DuringPendingDemuxerRead) {
Initialize();
EnterPendingReadState();
EXPECT_CALL(*this, BufferReady(DemuxerStream::kAborted, IsNull()));
}
// Test destruction in kPendingDecrypt state.
TEST_F(DecryptingDemuxerStreamTest, Destroy_DuringPendingDecrypt) {
Initialize();
EnterPendingDecryptState();
EXPECT_CALL(*this, BufferReady(DemuxerStream::kAborted, IsNull()));
}
// Test destruction in kWaitingForKey state.
TEST_F(DecryptingDemuxerStreamTest, Destroy_DuringWaitingForKey) {
Initialize();
EnterWaitingForKeyState();
EXPECT_CALL(*this, BufferReady(DemuxerStream::kAborted, IsNull()));
}
// Test destruction after reset.
TEST_F(DecryptingDemuxerStreamTest, Destroy_AfterReset) {
Initialize();
EnterNormalReadingState();
Reset();
}
} // namespace media
} // namespace cobalt