// 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 #include #include "base/bind.h" #include "base/logging.h" #include "base/memory/scoped_ptr.h" #include "media/base/video_frame.h" #include "remoting/codec/codec_test.h" #include "remoting/codec/video_decoder.h" #include "remoting/codec/video_encoder.h" #include "remoting/base/util.h" #include "testing/gtest/include/gtest/gtest.h" namespace { const int kBytesPerPixel = 4; // Some sample rects for testing. std::vector > MakeTestRectLists(const SkISize& size) { std::vector > rect_lists; std::vector rects; rects.push_back(SkIRect::MakeXYWH(0, 0, size.width(), size.height())); rect_lists.push_back(rects); rects.clear(); rects.push_back(SkIRect::MakeXYWH(0, 0, size.width() / 2, size.height() / 2)); rect_lists.push_back(rects); rects.clear(); rects.push_back(SkIRect::MakeXYWH(size.width() / 2, size.height() / 2, size.width() / 2, size.height() / 2)); rect_lists.push_back(rects); rects.clear(); rects.push_back(SkIRect::MakeXYWH(16, 16, 16, 16)); rects.push_back(SkIRect::MakeXYWH(128, 64, 32, 32)); rect_lists.push_back(rects); return rect_lists; } } // namespace namespace remoting { // A class to test the message output of the encoder. class EncoderMessageTester { public: EncoderMessageTester() : begin_rect_(0), rect_data_(0), end_rect_(0), added_rects_(0), state_(kWaitingForBeginRect), strict_(false) { } ~EncoderMessageTester() { EXPECT_EQ(begin_rect_, end_rect_); EXPECT_GT(begin_rect_, 0); EXPECT_EQ(kWaitingForBeginRect, state_); if (strict_) { EXPECT_EQ(added_rects_, begin_rect_); } } // Test that we received the correct packet. void ReceivedPacket(VideoPacket* packet) { if (state_ == kWaitingForBeginRect) { EXPECT_TRUE((packet->flags() & VideoPacket::FIRST_PACKET) != 0); state_ = kWaitingForRectData; ++begin_rect_; if (strict_) { SkIRect rect = rects_.front(); rects_.pop_front(); EXPECT_EQ(rect.fLeft, packet->format().x()); EXPECT_EQ(rect.fTop, packet->format().y()); EXPECT_EQ(rect.width(), packet->format().width()); EXPECT_EQ(rect.height(), packet->format().height()); } } else { EXPECT_FALSE((packet->flags() & VideoPacket::FIRST_PACKET) != 0); } if (state_ == kWaitingForRectData) { if (packet->has_data()) { ++rect_data_; } if ((packet->flags() & VideoPacket::LAST_PACKET) != 0) { // Expect that we have received some data. EXPECT_GT(rect_data_, 0); rect_data_ = 0; state_ = kWaitingForBeginRect; ++end_rect_; } if ((packet->flags() & VideoPacket::LAST_PARTITION) != 0) { // LAST_PARTITION must always be marked with LAST_PACKET. EXPECT_TRUE((packet->flags() & VideoPacket::LAST_PACKET) != 0); } } } void set_strict(bool strict) { strict_ = strict; } void AddRects(const SkIRect* rects, int count) { rects_.insert(rects_.begin() + rects_.size(), rects, rects + count); added_rects_ += count; } private: enum State { kWaitingForBeginRect, kWaitingForRectData, }; int begin_rect_; int rect_data_; int end_rect_; int added_rects_; State state_; bool strict_; std::deque rects_; DISALLOW_COPY_AND_ASSIGN(EncoderMessageTester); }; class DecoderTester { public: DecoderTester(Decoder* decoder, const SkISize& screen_size, const SkISize& view_size) : screen_size_(screen_size), view_size_(view_size), strict_(false), decoder_(decoder) { image_data_.reset(new uint8[ view_size_.width() * view_size_.height() * kBytesPerPixel]); EXPECT_TRUE(image_data_.get()); decoder_->Initialize(screen_size_); } void Reset() { expected_region_.setEmpty(); update_region_.setEmpty(); } void ResetRenderedData() { memset(image_data_.get(), 0, view_size_.width() * view_size_.height() * kBytesPerPixel); } void ReceivedPacket(VideoPacket* packet) { Decoder::DecodeResult result = decoder_->DecodePacket(packet); ASSERT_NE(Decoder::DECODE_ERROR, result); if (result == Decoder::DECODE_DONE) { RenderFrame(); } } void RenderFrame() { decoder_->RenderFrame(view_size_, SkIRect::MakeSize(view_size_), image_data_.get(), view_size_.width() * kBytesPerPixel, &update_region_); } void ReceivedScopedPacket(scoped_ptr packet) { ReceivedPacket(packet.get()); } void set_strict(bool strict) { strict_ = strict; } void set_capture_data(scoped_refptr data) { capture_data_ = data; } void AddRects(const SkIRect* rects, int count) { SkRegion new_rects; new_rects.setRects(rects, count); AddRegion(new_rects); } void AddRegion(const SkRegion& region) { expected_region_.op(region, SkRegion::kUnion_Op); } void VerifyResults() { if (!strict_) return; ASSERT_TRUE(capture_data_.get()); // Test the content of the update region. EXPECT_EQ(expected_region_, update_region_); for (SkRegion::Iterator i(update_region_); !i.done(); i.next()) { const int stride = view_size_.width() * kBytesPerPixel; EXPECT_EQ(stride, capture_data_->data_planes().strides[0]); const int offset = stride * i.rect().top() + kBytesPerPixel * i.rect().left(); const uint8* original = capture_data_->data_planes().data[0] + offset; const uint8* decoded = image_data_.get() + offset; const int row_size = kBytesPerPixel * i.rect().width(); for (int y = 0; y < i.rect().height(); ++y) { EXPECT_EQ(0, memcmp(original, decoded, row_size)) << "Row " << y << " is different"; original += stride; decoded += stride; } } } // The error at each pixel is the root mean square of the errors in // the R, G, and B components, each normalized to [0, 1]. This routine // checks that the maximum and mean pixel errors do not exceed given limits. void VerifyResultsApprox(const uint8* expected_view_data, double max_error_limit, double mean_error_limit) { double max_error = 0.0; double sum_error = 0.0; int error_num = 0; for (SkRegion::Iterator i(update_region_); !i.done(); i.next()) { const int stride = view_size_.width() * kBytesPerPixel; const int offset = stride * i.rect().top() + kBytesPerPixel * i.rect().left(); const uint8* expected = expected_view_data + offset; const uint8* actual = image_data_.get() + offset; for (int y = 0; y < i.rect().height(); ++y) { for (int x = 0; x < i.rect().width(); ++x) { double error = CalculateError(expected, actual); max_error = std::max(max_error, error); sum_error += error; ++error_num; expected += 4; actual += 4; } } } EXPECT_LE(max_error, max_error_limit); double mean_error = sum_error / error_num; EXPECT_LE(mean_error, mean_error_limit); LOG(INFO) << "Max error: " << max_error; LOG(INFO) << "Mean error: " << mean_error; } double CalculateError(const uint8* original, const uint8* decoded) { double error_sum_squares = 0.0; for (int i = 0; i < 3; i++) { double error = static_cast(*original++) - static_cast(*decoded++); error /= 255.0; error_sum_squares += error * error; } original++; decoded++; return sqrt(error_sum_squares / 3.0); } private: SkISize screen_size_; SkISize view_size_; bool strict_; SkRegion expected_region_; SkRegion update_region_; Decoder* decoder_; scoped_array image_data_; scoped_refptr capture_data_; DISALLOW_COPY_AND_ASSIGN(DecoderTester); }; // The EncoderTester provides a hook for retrieving the data, and passing the // message to other subprograms for validaton. class EncoderTester { public: EncoderTester(EncoderMessageTester* message_tester) : message_tester_(message_tester), decoder_tester_(NULL), data_available_(0) { } ~EncoderTester() { EXPECT_GT(data_available_, 0); } void DataAvailable(scoped_ptr packet) { ++data_available_; message_tester_->ReceivedPacket(packet.get()); // Send the message to the DecoderTester. if (decoder_tester_) { decoder_tester_->ReceivedPacket(packet.get()); } } void AddRects(const SkIRect* rects, int count) { message_tester_->AddRects(rects, count); } void set_decoder_tester(DecoderTester* decoder_tester) { decoder_tester_ = decoder_tester; } private: EncoderMessageTester* message_tester_; DecoderTester* decoder_tester_; int data_available_; DISALLOW_COPY_AND_ASSIGN(EncoderTester); }; scoped_refptr PrepareEncodeData(const SkISize& size, media::VideoFrame::Format format, uint8** memory) { // TODO(hclam): Support also YUV format. CHECK_EQ(format, media::VideoFrame::RGB32); int memory_size = size.width() * size.height() * kBytesPerPixel; *memory = new uint8[memory_size]; srand(0); for (int i = 0; i < memory_size; ++i) { (*memory)[i] = rand() % 256; } DataPlanes planes; memset(planes.data, 0, sizeof(planes.data)); memset(planes.strides, 0, sizeof(planes.strides)); planes.data[0] = *memory; planes.strides[0] = size.width() * kBytesPerPixel; scoped_refptr data = new CaptureData(planes, size, format); return data; } static void TestEncodingRects(Encoder* encoder, EncoderTester* tester, scoped_refptr data, const SkIRect* rects, int count) { data->mutable_dirty_region().setEmpty(); for (int i = 0; i < count; ++i) { data->mutable_dirty_region().op(rects[i], SkRegion::kUnion_Op); } tester->AddRects(rects, count); encoder->Encode(data, true, base::Bind( &EncoderTester::DataAvailable, base::Unretained(tester))); } void TestEncoder(Encoder* encoder, bool strict) { SkISize kSize = SkISize::Make(320, 240); EncoderMessageTester message_tester; message_tester.set_strict(strict); EncoderTester tester(&message_tester); uint8* memory; scoped_refptr data = PrepareEncodeData(kSize, media::VideoFrame::RGB32, &memory); scoped_array memory_wrapper(memory); std::vector > test_rect_lists = MakeTestRectLists(kSize); for (size_t i = 0; i < test_rect_lists.size(); ++i) { const std::vector& test_rects = test_rect_lists[i]; TestEncodingRects(encoder, &tester, data, &test_rects[0], test_rects.size()); } } static void TestEncodeDecodeRects(Encoder* encoder, EncoderTester* encoder_tester, DecoderTester* decoder_tester, scoped_refptr data, const SkIRect* rects, int count) { data->mutable_dirty_region().setRects(rects, count); encoder_tester->AddRects(rects, count); decoder_tester->AddRects(rects, count); // Generate random data for the updated region. srand(0); for (int i = 0; i < count; ++i) { CHECK_EQ(data->pixel_format(), media::VideoFrame::RGB32); const int bytes_per_pixel = 4; // Because of RGB32 on previous line. const int row_size = bytes_per_pixel * rects[i].width(); uint8* memory = data->data_planes().data[0] + data->data_planes().strides[0] * rects[i].top() + bytes_per_pixel * rects[i].left(); for (int y = 0; y < rects[i].height(); ++y) { for (int x = 0; x < row_size; ++x) memory[x] = rand() % 256; memory += data->data_planes().strides[0]; } } encoder->Encode(data, true, base::Bind(&EncoderTester::DataAvailable, base::Unretained(encoder_tester))); decoder_tester->VerifyResults(); decoder_tester->Reset(); } void TestEncoderDecoder(Encoder* encoder, Decoder* decoder, bool strict) { SkISize kSize = SkISize::Make(320, 240); EncoderMessageTester message_tester; message_tester.set_strict(strict); EncoderTester encoder_tester(&message_tester); uint8* memory; scoped_refptr data = PrepareEncodeData(kSize, media::VideoFrame::RGB32, &memory); scoped_array memory_wrapper(memory); DecoderTester decoder_tester(decoder, kSize, kSize); decoder_tester.set_strict(strict); decoder_tester.set_capture_data(data); encoder_tester.set_decoder_tester(&decoder_tester); std::vector > test_rect_lists = MakeTestRectLists(kSize); for (size_t i = 0; i < test_rect_lists.size(); ++i) { const std::vector test_rects = test_rect_lists[i]; TestEncodeDecodeRects(encoder, &encoder_tester, &decoder_tester, data, &test_rects[0], test_rects.size()); } } static void FillWithGradient(uint8* memory, const SkISize& frame_size, const SkIRect& rect) { for (int j = rect.top(); j < rect.bottom(); ++j) { uint8* p = memory + ((j * frame_size.width()) + rect.left()) * 4; for (int i = rect.left(); i < rect.right(); ++i) { *p++ = static_cast((255.0 * i) / frame_size.width()); *p++ = static_cast((164.0 * j) / frame_size.height()); *p++ = static_cast((82.0 * (i + j)) / (frame_size.width() + frame_size.height())); *p++ = 0; } } } void TestEncoderDecoderGradient(Encoder* encoder, Decoder* decoder, const SkISize& screen_size, const SkISize& view_size, double max_error_limit, double mean_error_limit) { SkIRect screen_rect = SkIRect::MakeSize(screen_size); scoped_array screen_data(new uint8[ screen_size.width() * screen_size.height() * kBytesPerPixel]); FillWithGradient(screen_data.get(), screen_size, screen_rect); SkIRect view_rect = SkIRect::MakeSize(view_size); scoped_array expected_view_data(new uint8[ view_size.width() * view_size.height() * kBytesPerPixel]); FillWithGradient(expected_view_data.get(), view_size, view_rect); DataPlanes planes; memset(planes.data, 0, sizeof(planes.data)); memset(planes.strides, 0, sizeof(planes.strides)); planes.data[0] = screen_data.get(); planes.strides[0] = screen_size.width() * kBytesPerPixel; scoped_refptr capture_data = new CaptureData(planes, screen_size, media::VideoFrame::RGB32); capture_data->mutable_dirty_region().op(screen_rect, SkRegion::kUnion_Op); DecoderTester decoder_tester(decoder, screen_size, view_size); decoder_tester.set_capture_data(capture_data); decoder_tester.AddRegion(capture_data->dirty_region()); encoder->Encode(capture_data, true, base::Bind(&DecoderTester::ReceivedScopedPacket, base::Unretained(&decoder_tester))); decoder_tester.VerifyResultsApprox(expected_view_data.get(), max_error_limit, mean_error_limit); // Check that the decoder correctly re-renders the frame if its client // invalidates the frame. decoder_tester.ResetRenderedData(); decoder->Invalidate(view_size, SkRegion(view_rect)); decoder_tester.RenderFrame(); decoder_tester.VerifyResultsApprox(expected_view_data.get(), max_error_limit, mean_error_limit); } } // namespace remoting