webm_parser/tests/cluster_parser_test.cc - platform/external/libwebm - Git at Google

 // Copyright (c) 2016 The WebM project authors. All Rights Reserved.
 //
 // Use of this source code is governed by a BSD-style license
 // that can be found in the LICENSE file in the root of the source
 // tree. An additional intellectual property rights grant can be found
 // in the file PATENTS.  All contributing project authors may
 // be found in the AUTHORS file in the root of the source tree.
 #include "src/cluster_parser.h"

 #include "gmock/gmock.h"
 #include "gtest/gtest.h"

 #include "test_utils/element_parser_test.h"
 #include "webm/element.h"
 #include "webm/id.h"

 using testing::_;
 using testing::DoAll;
 using testing::InSequence;
 using testing::NotNull;
 using testing::Return;
 using testing::SetArgPointee;

 using webm::Action;
 using webm::Ancestory;
 using webm::BlockGroup;
 using webm::Cluster;
 using webm::ClusterParser;
 using webm::ElementMetadata;
 using webm::ElementParserTest;
 using webm::Id;
 using webm::SimpleBlock;
 using webm::Status;

 namespace {

 class ClusterParserTest
     : public ElementParserTest<ClusterParser, Id::kCluster> {};

 TEST_F(ClusterParserTest, DefaultParse) {
   {
     InSequence dummy;

     EXPECT_CALL(callback_, OnClusterBegin(metadata_, Cluster{}, NotNull()))
         .Times(1);

     EXPECT_CALL(callback_, OnClusterEnd(metadata_, Cluster{})).Times(1);
   }

   ParseAndVerify();
 }

 TEST_F(ClusterParserTest, DefaultActionIsRead) {
   {
     InSequence dummy;

     // This intentionally does not set the action and relies on the parser using
     // a default action value of kRead.
     EXPECT_CALL(callback_, OnClusterBegin(metadata_, Cluster{}, NotNull()))
         .WillOnce(Return(Status(Status::kOkCompleted)));
     EXPECT_CALL(callback_, OnClusterEnd(metadata_, Cluster{})).Times(1);
   }

   ParseAndVerify();
 }

 TEST_F(ClusterParserTest, DefaultValues) {
   SetReaderData({
       0xE7,  // ID = 0xE7 (Timecode).
       0x40, 0x00,  // Size = 0.

       0xAB,  // ID = 0xAB (PrevSize).
       0x40, 0x00,  // Size = 0.

       0xA3,  // ID = 0xA3 (SimpleBlock).
       0x85,  // Size = 5.
       0x81,  // Track number = 1.
       0x00, 0x00,  // Timecode = 0.
       0x00,  // Flags = 0.
       0x00,  // Frame 0.

       0xA0,  // ID = 0xA0 (BlockGroup).
       0x40, 0x00,  // Size = 0.
   });

   {
     InSequence dummy;

     Cluster cluster{};
     cluster.timecode.Set(0, true);
     cluster.previous_size.Set(0, true);

     EXPECT_CALL(callback_, OnClusterBegin(metadata_, cluster, NotNull()))
         .Times(1);

     SimpleBlock simple_block{};
     simple_block.track_number = 1;
     simple_block.num_frames = 1;
     simple_block.is_visible = true;
     cluster.simple_blocks.emplace_back(simple_block, true);

     BlockGroup block_group{};
     cluster.block_groups.emplace_back(block_group, true);

     EXPECT_CALL(callback_, OnClusterEnd(metadata_, cluster)).Times(1);
   }

   ParseAndVerify();
 }

 TEST_F(ClusterParserTest, CustomValues) {
   SetReaderData({
       0xE7,  // ID = 0xE7 (Timecode).
       0x40, 0x01,  // Size = 1.
       0x01,  // Body (value = 1).

       0xAB,  // ID = 0xAB (PrevSize).
       0x40, 0x01,  // Size = 1.
       0x02,  // Body (value = 2).

       0xA3,  // ID = 0xA3 (SimpleBlock).
       0x85,  // Size = 5.
       0x81,  // Track number = 1.
       0x00, 0x00,  // Timecode = 0.
       0x00,  // Flags = 0.
       0x00,  // Frame 0.

       0xA3,  // ID = 0xA3 (SimpleBlock).
       0x85,  // Size = 5.
       0x82,  // Track number = 2.
       0x00, 0x00,  // Timecode = 0.
       0x00,  // Flags = 0.
       0x00,  // Frame 0.

       0xA0,  // ID = 0xA0 (BlockGroup).
       0x40, 0x04,  // Size = 4.

       0x9B,  //   ID = 0x9B (BlockDuration).
       0x40, 0x01,  //   Size = 1.
       0x01,  //   Body (value = 1).

       0xA0,  // ID = 0xA0 (BlockGroup).
       0x40, 0x04,  // Size = 4.

       0x9B,  //   ID = 0x9B (BlockDuration).
       0x40, 0x01,  //   Size = 1.
       0x02,  //   Body (value = 2).
   });

   {
     InSequence dummy;

     Cluster cluster{};
     cluster.timecode.Set(1, true);
     cluster.previous_size.Set(2, true);

     EXPECT_CALL(callback_, OnClusterBegin(metadata_, cluster, NotNull()))
         .Times(1);

     SimpleBlock simple_block{};
     simple_block.num_frames = 1;
     simple_block.is_visible = true;

     simple_block.track_number = 1;
     cluster.simple_blocks.emplace_back(simple_block, true);
     simple_block.track_number = 2;
     cluster.simple_blocks.emplace_back(simple_block, true);

     BlockGroup block_group{};
     block_group.duration.Set(1, true);
     cluster.block_groups.emplace_back(block_group, true);
     block_group.duration.Set(2, true);
     cluster.block_groups.emplace_back(block_group, true);

     EXPECT_CALL(callback_, OnClusterEnd(metadata_, cluster)).Times(1);
   }

   ParseAndVerify();
 }

 TEST_F(ClusterParserTest, SkipOnClusterBegin) {
   {
     InSequence dummy;

     EXPECT_CALL(callback_, OnClusterBegin(_, _, _)).Times(0);

     EXPECT_CALL(callback_, OnBlockGroupBegin(_, NotNull())).Times(1);

     EXPECT_CALL(callback_, OnClusterEnd(_, _)).Times(1);
   }

   ElementMetadata child_metadata = {Id::kBlockGroup, 0, 0, 0};

   Ancestory ancestory;
   ASSERT_TRUE(Ancestory::ById(child_metadata.id, &ancestory));
   // Skip the Segment and Cluster ancestors.
   ancestory = ancestory.next().next();

   parser_.InitAfterSeek(ancestory, child_metadata);

   std::uint64_t num_bytes_read = 0;
   const Status status = parser_.Feed(&callback_, &reader_, &num_bytes_read);
   EXPECT_EQ(Status::kOkCompleted, status.code);
   EXPECT_EQ(reader_.size(), num_bytes_read);
 }

 TEST_F(ClusterParserTest, SkipSimpleBlock) {
   SetReaderData({
       0xA3,  // ID = 0xA3 (SimpleBlock).
       0x85,  // Size = 5.
       0x81,  // Track number = 1.
       0x00, 0x00,  // Timecode = 0.
       0x00,  // Flags = 0.
       0x00,  // Frame 0.
   });

   {
     InSequence dummy;

     Cluster cluster{};
     EXPECT_CALL(callback_, OnClusterBegin(metadata_, cluster, NotNull()))
         .Times(1);

     SimpleBlock simple_block{};
     simple_block.num_frames = 1;
     simple_block.is_visible = true;
     simple_block.track_number = 1;

     EXPECT_CALL(callback_, OnSimpleBlockBegin(_, simple_block, NotNull()))
         .WillOnce(DoAll(SetArgPointee<2>(Action::kSkip),
                         Return(Status(Status::kOkCompleted))));

     EXPECT_CALL(callback_, OnClusterEnd(metadata_, cluster)).Times(1);
   }

   ParseAndVerify();
 }

 TEST_F(ClusterParserTest, SkipBlockGroup) {
   SetReaderData({
       0xA0,  // ID = 0xA0 (BlockGroup).
       0x40, 0x04,  // Size = 4.

       0x9B,  //   ID = 0x9B (BlockDuration).
       0x40, 0x01,  //   Size = 1.
       0x01,  //   Body (value = 1).
   });

   {
     InSequence dummy;

     Cluster cluster{};
     EXPECT_CALL(callback_, OnClusterBegin(metadata_, cluster, NotNull()))
         .Times(1);

     EXPECT_CALL(callback_, OnBlockGroupBegin(_, NotNull()))
         .WillOnce(DoAll(SetArgPointee<1>(Action::kSkip),
                         Return(Status(Status::kOkCompleted))));

     EXPECT_CALL(callback_, OnClusterEnd(metadata_, cluster)).Times(1);
   }

   ParseAndVerify();
 }

 }  // namespace
	// Copyright (c) 2016 The WebM project authors. All Rights Reserved.
	//
	// Use of this source code is governed by a BSD-style license
	// that can be found in the LICENSE file in the root of the source
	// tree. An additional intellectual property rights grant can be found
	// in the file PATENTS. All contributing project authors may
	// be found in the AUTHORS file in the root of the source tree.
	#include "src/cluster_parser.h"

	#include "gmock/gmock.h"
	#include "gtest/gtest.h"

	#include "test_utils/element_parser_test.h"
	#include "webm/element.h"
	#include "webm/id.h"

	using testing::_;
	using testing::DoAll;
	using testing::InSequence;
	using testing::NotNull;
	using testing::Return;
	using testing::SetArgPointee;

	using webm::Action;
	using webm::Ancestory;
	using webm::BlockGroup;
	using webm::Cluster;
	using webm::ClusterParser;
	using webm::ElementMetadata;
	using webm::ElementParserTest;
	using webm::Id;
	using webm::SimpleBlock;
	using webm::Status;

	namespace {

	class ClusterParserTest
	: public ElementParserTest<ClusterParser, Id::kCluster> {};

	TEST_F(ClusterParserTest, DefaultParse) {
	{
	InSequence dummy;

	EXPECT_CALL(callback_, OnClusterBegin(metadata_, Cluster{}, NotNull()))
	.Times(1);

	EXPECT_CALL(callback_, OnClusterEnd(metadata_, Cluster{})).Times(1);
	}

	ParseAndVerify();
	}

	TEST_F(ClusterParserTest, DefaultActionIsRead) {
	{
	InSequence dummy;

	// This intentionally does not set the action and relies on the parser using
	// a default action value of kRead.
	EXPECT_CALL(callback_, OnClusterBegin(metadata_, Cluster{}, NotNull()))
	.WillOnce(Return(Status(Status::kOkCompleted)));
	EXPECT_CALL(callback_, OnClusterEnd(metadata_, Cluster{})).Times(1);
	}

	ParseAndVerify();
	}

	TEST_F(ClusterParserTest, DefaultValues) {
	SetReaderData({
	0xE7, // ID = 0xE7 (Timecode).
	0x40, 0x00, // Size = 0.

	0xAB, // ID = 0xAB (PrevSize).
	0x40, 0x00, // Size = 0.

	0xA3, // ID = 0xA3 (SimpleBlock).
	0x85, // Size = 5.
	0x81, // Track number = 1.
	0x00, 0x00, // Timecode = 0.
	0x00, // Flags = 0.
	0x00, // Frame 0.

	0xA0, // ID = 0xA0 (BlockGroup).
	0x40, 0x00, // Size = 0.
	});

	{
	InSequence dummy;

	Cluster cluster{};
	cluster.timecode.Set(0, true);
	cluster.previous_size.Set(0, true);

	EXPECT_CALL(callback_, OnClusterBegin(metadata_, cluster, NotNull()))
	.Times(1);

	SimpleBlock simple_block{};
	simple_block.track_number = 1;
	simple_block.num_frames = 1;
	simple_block.is_visible = true;
	cluster.simple_blocks.emplace_back(simple_block, true);

	BlockGroup block_group{};
	cluster.block_groups.emplace_back(block_group, true);

	EXPECT_CALL(callback_, OnClusterEnd(metadata_, cluster)).Times(1);
	}

	ParseAndVerify();
	}

	TEST_F(ClusterParserTest, CustomValues) {
	SetReaderData({
	0xE7, // ID = 0xE7 (Timecode).
	0x40, 0x01, // Size = 1.
	0x01, // Body (value = 1).

	0xAB, // ID = 0xAB (PrevSize).
	0x40, 0x01, // Size = 1.
	0x02, // Body (value = 2).

	0xA3, // ID = 0xA3 (SimpleBlock).
	0x85, // Size = 5.
	0x81, // Track number = 1.
	0x00, 0x00, // Timecode = 0.
	0x00, // Flags = 0.
	0x00, // Frame 0.

	0xA3, // ID = 0xA3 (SimpleBlock).
	0x85, // Size = 5.
	0x82, // Track number = 2.
	0x00, 0x00, // Timecode = 0.
	0x00, // Flags = 0.
	0x00, // Frame 0.

	0xA0, // ID = 0xA0 (BlockGroup).
	0x40, 0x04, // Size = 4.

	0x9B, // ID = 0x9B (BlockDuration).
	0x40, 0x01, // Size = 1.
	0x01, // Body (value = 1).

	0xA0, // ID = 0xA0 (BlockGroup).
	0x40, 0x04, // Size = 4.

	0x9B, // ID = 0x9B (BlockDuration).
	0x40, 0x01, // Size = 1.
	0x02, // Body (value = 2).
	});

	{
	InSequence dummy;

	Cluster cluster{};
	cluster.timecode.Set(1, true);
	cluster.previous_size.Set(2, true);

	EXPECT_CALL(callback_, OnClusterBegin(metadata_, cluster, NotNull()))
	.Times(1);

	SimpleBlock simple_block{};
	simple_block.num_frames = 1;
	simple_block.is_visible = true;

	simple_block.track_number = 1;
	cluster.simple_blocks.emplace_back(simple_block, true);
	simple_block.track_number = 2;
	cluster.simple_blocks.emplace_back(simple_block, true);

	BlockGroup block_group{};
	block_group.duration.Set(1, true);
	cluster.block_groups.emplace_back(block_group, true);
	block_group.duration.Set(2, true);
	cluster.block_groups.emplace_back(block_group, true);

	EXPECT_CALL(callback_, OnClusterEnd(metadata_, cluster)).Times(1);
	}

	ParseAndVerify();
	}

	TEST_F(ClusterParserTest, SkipOnClusterBegin) {
	{
	InSequence dummy;

	EXPECT_CALL(callback_, OnClusterBegin(_, _, _)).Times(0);

	EXPECT_CALL(callback_, OnBlockGroupBegin(_, NotNull())).Times(1);

	EXPECT_CALL(callback_, OnClusterEnd(_, _)).Times(1);
	}

	ElementMetadata child_metadata = {Id::kBlockGroup, 0, 0, 0};

	Ancestory ancestory;
	ASSERT_TRUE(Ancestory::ById(child_metadata.id, &ancestory));
	// Skip the Segment and Cluster ancestors.
	ancestory = ancestory.next().next();

	parser_.InitAfterSeek(ancestory, child_metadata);

	std::uint64_t num_bytes_read = 0;
	const Status status = parser_.Feed(&callback_, &reader_, &num_bytes_read);
	EXPECT_EQ(Status::kOkCompleted, status.code);
	EXPECT_EQ(reader_.size(), num_bytes_read);
	}

	TEST_F(ClusterParserTest, SkipSimpleBlock) {
	SetReaderData({
	0xA3, // ID = 0xA3 (SimpleBlock).
	0x85, // Size = 5.
	0x81, // Track number = 1.
	0x00, 0x00, // Timecode = 0.
	0x00, // Flags = 0.
	0x00, // Frame 0.
	});

	{
	InSequence dummy;

	Cluster cluster{};
	EXPECT_CALL(callback_, OnClusterBegin(metadata_, cluster, NotNull()))
	.Times(1);

	SimpleBlock simple_block{};
	simple_block.num_frames = 1;
	simple_block.is_visible = true;
	simple_block.track_number = 1;

	EXPECT_CALL(callback_, OnSimpleBlockBegin(_, simple_block, NotNull()))
	.WillOnce(DoAll(SetArgPointee<2>(Action::kSkip),
	Return(Status(Status::kOkCompleted))));

	EXPECT_CALL(callback_, OnClusterEnd(metadata_, cluster)).Times(1);
	}

	ParseAndVerify();
	}

	TEST_F(ClusterParserTest, SkipBlockGroup) {
	SetReaderData({
	0xA0, // ID = 0xA0 (BlockGroup).
	0x40, 0x04, // Size = 4.

	0x9B, // ID = 0x9B (BlockDuration).
	0x40, 0x01, // Size = 1.
	0x01, // Body (value = 1).
	});

	{
	InSequence dummy;

	Cluster cluster{};
	EXPECT_CALL(callback_, OnClusterBegin(metadata_, cluster, NotNull()))
	.Times(1);

	EXPECT_CALL(callback_, OnBlockGroupBegin(_, NotNull()))
	.WillOnce(DoAll(SetArgPointee<1>(Action::kSkip),
	Return(Status(Status::kOkCompleted))));

	EXPECT_CALL(callback_, OnClusterEnd(metadata_, cluster)).Times(1);
	}

	ParseAndVerify();
	}

	} // namespace