// libjingle // Copyright 2014 Google Inc. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are met: // // 1. Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // 2. Redistributions in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // 3. The name of the author may not be used to endorse or promote products // derived from this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED // WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO // EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; // OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, // WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR // OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF // ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include #include "libyuv/convert.h" #include "libyuv/convert_from.h" #include "libyuv/convert_from_argb.h" #include "libyuv/format_conversion.h" #include "libyuv/mjpeg_decoder.h" #include "libyuv/planar_functions.h" #include "talk/media/base/testutils.h" #include "talk/media/base/videocommon.h" #include "webrtc/base/flags.h" #include "webrtc/base/gunit.h" #include "webrtc/base/scoped_ptr.h" // Undefine macros for the windows build. #undef max #undef min using cricket::DumpPlanarYuvTestImage; DEFINE_bool(planarfunctions_dump, false, "whether to write out scaled images for inspection"); DEFINE_int(planarfunctions_repeat, 1, "how many times to perform each scaling operation (for perf testing)"); namespace cricket { // Number of testing colors in each color channel. static const int kTestingColorChannelResolution = 6; // The total number of testing colors // kTestingColorNum = kTestingColorChannelResolution^3; static const int kTestingColorNum = kTestingColorChannelResolution * kTestingColorChannelResolution * kTestingColorChannelResolution; static const int kWidth = 1280; static const int kHeight = 720; static const int kAlignment = 16; class PlanarFunctionsTest : public testing::TestWithParam { protected: PlanarFunctionsTest() : dump_(false), repeat_(1) { InitializeColorBand(); } virtual void SetUp() { dump_ = FLAG_planarfunctions_dump; repeat_ = FLAG_planarfunctions_repeat; } // Initialize the color band for testing. void InitializeColorBand() { testing_color_y_.reset(new uint8[kTestingColorNum]); testing_color_u_.reset(new uint8[kTestingColorNum]); testing_color_v_.reset(new uint8[kTestingColorNum]); testing_color_r_.reset(new uint8[kTestingColorNum]); testing_color_g_.reset(new uint8[kTestingColorNum]); testing_color_b_.reset(new uint8[kTestingColorNum]); int color_counter = 0; for (int i = 0; i < kTestingColorChannelResolution; ++i) { uint8 color_r = static_cast( i * 255 / (kTestingColorChannelResolution - 1)); for (int j = 0; j < kTestingColorChannelResolution; ++j) { uint8 color_g = static_cast( j * 255 / (kTestingColorChannelResolution - 1)); for (int k = 0; k < kTestingColorChannelResolution; ++k) { uint8 color_b = static_cast( k * 255 / (kTestingColorChannelResolution - 1)); testing_color_r_[color_counter] = color_r; testing_color_g_[color_counter] = color_g; testing_color_b_[color_counter] = color_b; // Converting the testing RGB colors to YUV colors. ConvertRgbPixel(color_r, color_g, color_b, &(testing_color_y_[color_counter]), &(testing_color_u_[color_counter]), &(testing_color_v_[color_counter])); ++color_counter; } } } } // Simple and slow RGB->YUV conversion. From NTSC standard, c/o Wikipedia. // (from lmivideoframe_unittest.cc) void ConvertRgbPixel(uint8 r, uint8 g, uint8 b, uint8* y, uint8* u, uint8* v) { *y = ClampUint8(.257 * r + .504 * g + .098 * b + 16); *u = ClampUint8(-.148 * r - .291 * g + .439 * b + 128); *v = ClampUint8(.439 * r - .368 * g - .071 * b + 128); } uint8 ClampUint8(double value) { value = std::max(0., std::min(255., value)); uint8 uint8_value = static_cast(value); return uint8_value; } // Generate a Red-Green-Blue inter-weaving chessboard-like // YUV testing image (I420/I422/I444). // The pattern looks like c0 c1 c2 c3 ... // c1 c2 c3 c4 ... // c2 c3 c4 c5 ... // ............... // The size of each chrome block is (block_size) x (block_size). uint8* CreateFakeYuvTestingImage(int height, int width, int block_size, libyuv::JpegSubsamplingType subsample_type, uint8* &y_pointer, uint8* &u_pointer, uint8* &v_pointer) { if (height <= 0 || width <= 0 || block_size <= 0) { return NULL; } int y_size = height * width; int u_size, v_size; int vertical_sample_ratio = 1, horizontal_sample_ratio = 1; switch (subsample_type) { case libyuv::kJpegYuv420: u_size = ((height + 1) >> 1) * ((width + 1) >> 1); v_size = u_size; vertical_sample_ratio = 2, horizontal_sample_ratio = 2; break; case libyuv::kJpegYuv422: u_size = height * ((width + 1) >> 1); v_size = u_size; vertical_sample_ratio = 1, horizontal_sample_ratio = 2; break; case libyuv::kJpegYuv444: v_size = u_size = y_size; vertical_sample_ratio = 1, horizontal_sample_ratio = 1; break; case libyuv::kJpegUnknown: default: return NULL; break; } uint8* image_pointer = new uint8[y_size + u_size + v_size + kAlignment]; y_pointer = ALIGNP(image_pointer, kAlignment); u_pointer = ALIGNP(&image_pointer[y_size], kAlignment); v_pointer = ALIGNP(&image_pointer[y_size + u_size], kAlignment); uint8* current_y_pointer = y_pointer; uint8* current_u_pointer = u_pointer; uint8* current_v_pointer = v_pointer; for (int j = 0; j < height; ++j) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_y_pointer++) = testing_color_y_[color]; if (i % horizontal_sample_ratio == 0 && j % vertical_sample_ratio == 0) { *(current_u_pointer++) = testing_color_u_[color]; *(current_v_pointer++) = testing_color_v_[color]; } } } return image_pointer; } // Generate a Red-Green-Blue inter-weaving chessboard-like // YUY2/UYVY testing image. // The pattern looks like c0 c1 c2 c3 ... // c1 c2 c3 c4 ... // c2 c3 c4 c5 ... // ............... // The size of each chrome block is (block_size) x (block_size). uint8* CreateFakeInterleaveYuvTestingImage( int height, int width, int block_size, uint8* &yuv_pointer, FourCC fourcc_type) { if (height <= 0 || width <= 0 || block_size <= 0) { return NULL; } if (fourcc_type != FOURCC_YUY2 && fourcc_type != FOURCC_UYVY) { LOG(LS_ERROR) << "Format " << static_cast(fourcc_type) << " is not supported."; return NULL; } // Regularize the width of the output to be even. int awidth = (width + 1) & ~1; uint8* image_pointer = new uint8[2 * height * awidth + kAlignment]; yuv_pointer = ALIGNP(image_pointer, kAlignment); uint8* current_yuv_pointer = yuv_pointer; switch (fourcc_type) { case FOURCC_YUY2: { for (int j = 0; j < height; ++j) { for (int i = 0; i < awidth; i += 2, current_yuv_pointer += 4) { int color1 = ((i / block_size) + (j / block_size)) % kTestingColorNum; int color2 = (((i + 1) / block_size) + (j / block_size)) % kTestingColorNum; current_yuv_pointer[0] = testing_color_y_[color1]; if (i < width) { current_yuv_pointer[1] = static_cast( (static_cast(testing_color_u_[color1]) + static_cast(testing_color_u_[color2])) / 2); current_yuv_pointer[2] = testing_color_y_[color2]; current_yuv_pointer[3] = static_cast( (static_cast(testing_color_v_[color1]) + static_cast(testing_color_v_[color2])) / 2); } else { current_yuv_pointer[1] = testing_color_u_[color1]; current_yuv_pointer[2] = 0; current_yuv_pointer[3] = testing_color_v_[color1]; } } } break; } case FOURCC_UYVY: { for (int j = 0; j < height; ++j) { for (int i = 0; i < awidth; i += 2, current_yuv_pointer += 4) { int color1 = ((i / block_size) + (j / block_size)) % kTestingColorNum; int color2 = (((i + 1) / block_size) + (j / block_size)) % kTestingColorNum; if (i < width) { current_yuv_pointer[0] = static_cast( (static_cast(testing_color_u_[color1]) + static_cast(testing_color_u_[color2])) / 2); current_yuv_pointer[1] = testing_color_y_[color1]; current_yuv_pointer[2] = static_cast( (static_cast(testing_color_v_[color1]) + static_cast(testing_color_v_[color2])) / 2); current_yuv_pointer[3] = testing_color_y_[color2]; } else { current_yuv_pointer[0] = testing_color_u_[color1]; current_yuv_pointer[1] = testing_color_y_[color1]; current_yuv_pointer[2] = testing_color_v_[color1]; current_yuv_pointer[3] = 0; } } } break; } } return image_pointer; } // Generate a Red-Green-Blue inter-weaving chessboard-like // Q420 testing image. // The pattern looks like c0 c1 c2 c3 ... // c1 c2 c3 c4 ... // c2 c3 c4 c5 ... // ............... // The size of each chrome block is (block_size) x (block_size). uint8* CreateFakeQ420TestingImage(int height, int width, int block_size, uint8* &y_pointer, uint8* &yuy2_pointer) { if (height <= 0 || width <= 0 || block_size <= 0) { return NULL; } // Regularize the width of the output to be even. int awidth = (width + 1) & ~1; uint8* image_pointer = new uint8[(height / 2) * awidth * 2 + ((height + 1) / 2) * width + kAlignment]; y_pointer = ALIGNP(image_pointer, kAlignment); yuy2_pointer = y_pointer + ((height + 1) / 2) * width; uint8* current_yuy2_pointer = yuy2_pointer; uint8* current_y_pointer = y_pointer; for (int j = 0; j < height; ++j) { if (j % 2 == 0) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_y_pointer++) = testing_color_y_[color]; } } else { for (int i = 0; i < awidth; i += 2, current_yuy2_pointer += 4) { int color1 = ((i / block_size) + (j / block_size)) % kTestingColorNum; int color2 = (((i + 1) / block_size) + (j / block_size)) % kTestingColorNum; current_yuy2_pointer[0] = testing_color_y_[color1]; if (i < width) { current_yuy2_pointer[1] = static_cast( (static_cast(testing_color_u_[color1]) + static_cast(testing_color_u_[color2])) / 2); current_yuy2_pointer[2] = testing_color_y_[color2]; current_yuy2_pointer[3] = static_cast( (static_cast(testing_color_v_[color1]) + static_cast(testing_color_v_[color2])) / 2); } else { current_yuy2_pointer[1] = testing_color_u_[color1]; current_yuy2_pointer[2] = 0; current_yuy2_pointer[3] = testing_color_v_[color1]; } } } } return image_pointer; } // Generate a Red-Green-Blue inter-weaving chessboard-like // NV12 testing image. // (Note: No interpolation is used.) // The pattern looks like c0 c1 c2 c3 ... // c1 c2 c3 c4 ... // c2 c3 c4 c5 ... // ............... // The size of each chrome block is (block_size) x (block_size). uint8* CreateFakeNV12TestingImage(int height, int width, int block_size, uint8* &y_pointer, uint8* &uv_pointer) { if (height <= 0 || width <= 0 || block_size <= 0) { return NULL; } uint8* image_pointer = new uint8[height * width + ((height + 1) / 2) * ((width + 1) / 2) * 2 + kAlignment]; y_pointer = ALIGNP(image_pointer, kAlignment); uv_pointer = y_pointer + height * width; uint8* current_uv_pointer = uv_pointer; uint8* current_y_pointer = y_pointer; for (int j = 0; j < height; ++j) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_y_pointer++) = testing_color_y_[color]; } if (j % 2 == 0) { for (int i = 0; i < width; i += 2, current_uv_pointer += 2) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; current_uv_pointer[0] = testing_color_u_[color]; current_uv_pointer[1] = testing_color_v_[color]; } } } return image_pointer; } // Generate a Red-Green-Blue inter-weaving chessboard-like // M420 testing image. // (Note: No interpolation is used.) // The pattern looks like c0 c1 c2 c3 ... // c1 c2 c3 c4 ... // c2 c3 c4 c5 ... // ............... // The size of each chrome block is (block_size) x (block_size). uint8* CreateFakeM420TestingImage( int height, int width, int block_size, uint8* &m420_pointer) { if (height <= 0 || width <= 0 || block_size <= 0) { return NULL; } uint8* image_pointer = new uint8[height * width + ((height + 1) / 2) * ((width + 1) / 2) * 2 + kAlignment]; m420_pointer = ALIGNP(image_pointer, kAlignment); uint8* current_m420_pointer = m420_pointer; for (int j = 0; j < height; ++j) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_m420_pointer++) = testing_color_y_[color]; } if (j % 2 == 1) { for (int i = 0; i < width; i += 2, current_m420_pointer += 2) { int color = ((i / block_size) + ((j - 1) / block_size)) % kTestingColorNum; current_m420_pointer[0] = testing_color_u_[color]; current_m420_pointer[1] = testing_color_v_[color]; } } } return image_pointer; } // Generate a Red-Green-Blue inter-weaving chessboard-like // ARGB/ABGR/RAW/BG24 testing image. // The pattern looks like c0 c1 c2 c3 ... // c1 c2 c3 c4 ... // c2 c3 c4 c5 ... // ............... // The size of each chrome block is (block_size) x (block_size). uint8* CreateFakeArgbTestingImage(int height, int width, int block_size, uint8* &argb_pointer, FourCC fourcc_type) { if (height <= 0 || width <= 0 || block_size <= 0) { return NULL; } uint8* image_pointer = NULL; if (fourcc_type == FOURCC_ABGR || fourcc_type == FOURCC_BGRA || fourcc_type == FOURCC_ARGB) { image_pointer = new uint8[height * width * 4 + kAlignment]; } else if (fourcc_type == FOURCC_RAW || fourcc_type == FOURCC_24BG) { image_pointer = new uint8[height * width * 3 + kAlignment]; } else { LOG(LS_ERROR) << "Format " << static_cast(fourcc_type) << " is not supported."; return NULL; } argb_pointer = ALIGNP(image_pointer, kAlignment); uint8* current_pointer = argb_pointer; switch (fourcc_type) { case FOURCC_ARGB: { for (int j = 0; j < height; ++j) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_pointer++) = testing_color_b_[color]; *(current_pointer++) = testing_color_g_[color]; *(current_pointer++) = testing_color_r_[color]; *(current_pointer++) = 255; } } break; } case FOURCC_ABGR: { for (int j = 0; j < height; ++j) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_pointer++) = testing_color_r_[color]; *(current_pointer++) = testing_color_g_[color]; *(current_pointer++) = testing_color_b_[color]; *(current_pointer++) = 255; } } break; } case FOURCC_BGRA: { for (int j = 0; j < height; ++j) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_pointer++) = 255; *(current_pointer++) = testing_color_r_[color]; *(current_pointer++) = testing_color_g_[color]; *(current_pointer++) = testing_color_b_[color]; } } break; } case FOURCC_24BG: { for (int j = 0; j < height; ++j) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_pointer++) = testing_color_b_[color]; *(current_pointer++) = testing_color_g_[color]; *(current_pointer++) = testing_color_r_[color]; } } break; } case FOURCC_RAW: { for (int j = 0; j < height; ++j) { for (int i = 0; i < width; ++i) { int color = ((i / block_size) + (j / block_size)) % kTestingColorNum; *(current_pointer++) = testing_color_r_[color]; *(current_pointer++) = testing_color_g_[color]; *(current_pointer++) = testing_color_b_[color]; } } break; } default: { LOG(LS_ERROR) << "Format " << static_cast(fourcc_type) << " is not supported."; } } return image_pointer; } // Check if two memory chunks are equal. // (tolerate MSE errors within a threshold). static bool IsMemoryEqual(const uint8* ibuf, const uint8* obuf, int osize, double average_error) { double sse = cricket::ComputeSumSquareError(ibuf, obuf, osize); double error = sse / osize; // Mean Squared Error. double PSNR = cricket::ComputePSNR(sse, osize); LOG(LS_INFO) << "Image MSE: " << error << " Image PSNR: " << PSNR << " First Diff Byte: " << FindDiff(ibuf, obuf, osize); return (error < average_error); } // Returns the index of the first differing byte. Easier to debug than memcmp. static int FindDiff(const uint8* buf1, const uint8* buf2, int len) { int i = 0; while (i < len && buf1[i] == buf2[i]) { i++; } return (i < len) ? i : -1; } // Dump the result image (ARGB format). void DumpArgbImage(const uint8* obuf, int width, int height) { DumpPlanarArgbTestImage(GetTestName(), obuf, width, height); } // Dump the result image (YUV420 format). void DumpYuvImage(const uint8* obuf, int width, int height) { DumpPlanarYuvTestImage(GetTestName(), obuf, width, height); } std::string GetTestName() { const testing::TestInfo* const test_info = testing::UnitTest::GetInstance()->current_test_info(); std::string test_name(test_info->name()); return test_name; } bool dump_; int repeat_; // Y, U, V and R, G, B channels of testing colors. rtc::scoped_ptr testing_color_y_; rtc::scoped_ptr testing_color_u_; rtc::scoped_ptr testing_color_v_; rtc::scoped_ptr testing_color_r_; rtc::scoped_ptr testing_color_g_; rtc::scoped_ptr testing_color_b_; }; TEST_F(PlanarFunctionsTest, I420Copy) { uint8 *y_pointer = NULL, *u_pointer = NULL, *v_pointer = NULL; int y_pitch = kWidth; int u_pitch = (kWidth + 1) >> 1; int v_pitch = (kWidth + 1) >> 1; int y_size = kHeight * kWidth; int uv_size = ((kHeight + 1) >> 1) * ((kWidth + 1) >> 1); int block_size = 3; // Generate a fake input image. rtc::scoped_ptr yuv_input( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv420, y_pointer, u_pointer, v_pointer)); // Allocate space for the output image. rtc::scoped_ptr yuv_output( new uint8[I420_SIZE(kHeight, kWidth) + kAlignment]); uint8 *y_output_pointer = ALIGNP(yuv_output.get(), kAlignment); uint8 *u_output_pointer = y_output_pointer + y_size; uint8 *v_output_pointer = u_output_pointer + uv_size; for (int i = 0; i < repeat_; ++i) { libyuv::I420Copy(y_pointer, y_pitch, u_pointer, u_pitch, v_pointer, v_pitch, y_output_pointer, y_pitch, u_output_pointer, u_pitch, v_output_pointer, v_pitch, kWidth, kHeight); } // Expect the copied frame to be exactly the same. EXPECT_TRUE(IsMemoryEqual(y_output_pointer, y_pointer, I420_SIZE(kHeight, kWidth), 1.e-6)); if (dump_) { DumpYuvImage(y_output_pointer, kWidth, kHeight); } } TEST_F(PlanarFunctionsTest, I422ToI420) { uint8 *y_pointer = NULL, *u_pointer = NULL, *v_pointer = NULL; int y_pitch = kWidth; int u_pitch = (kWidth + 1) >> 1; int v_pitch = (kWidth + 1) >> 1; int y_size = kHeight * kWidth; int uv_size = ((kHeight + 1) >> 1) * ((kWidth + 1) >> 1); int block_size = 2; // Generate a fake input image. rtc::scoped_ptr yuv_input( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv422, y_pointer, u_pointer, v_pointer)); // Allocate space for the output image. rtc::scoped_ptr yuv_output( new uint8[I420_SIZE(kHeight, kWidth) + kAlignment]); uint8 *y_output_pointer = ALIGNP(yuv_output.get(), kAlignment); uint8 *u_output_pointer = y_output_pointer + y_size; uint8 *v_output_pointer = u_output_pointer + uv_size; // Generate the expected output. uint8 *y_expected_pointer = NULL, *u_expected_pointer = NULL, *v_expected_pointer = NULL; rtc::scoped_ptr yuv_output_expected( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv420, y_expected_pointer, u_expected_pointer, v_expected_pointer)); for (int i = 0; i < repeat_; ++i) { libyuv::I422ToI420(y_pointer, y_pitch, u_pointer, u_pitch, v_pointer, v_pitch, y_output_pointer, y_pitch, u_output_pointer, u_pitch, v_output_pointer, v_pitch, kWidth, kHeight); } // Compare the output frame with what is expected; expect exactly the same. // Note: MSE should be set to a larger threshold if an odd block width // is used, since the conversion will be lossy. EXPECT_TRUE(IsMemoryEqual(y_output_pointer, y_expected_pointer, I420_SIZE(kHeight, kWidth), 1.e-6)); if (dump_) { DumpYuvImage(y_output_pointer, kWidth, kHeight); } } TEST_P(PlanarFunctionsTest, Q420ToI420) { // Get the unalignment offset int unalignment = GetParam(); uint8 *y_pointer = NULL, *yuy2_pointer = NULL; int y_pitch = kWidth; int yuy2_pitch = 2 * ((kWidth + 1) & ~1); int u_pitch = (kWidth + 1) >> 1; int v_pitch = (kWidth + 1) >> 1; int y_size = kHeight * kWidth; int uv_size = ((kHeight + 1) >> 1) * ((kWidth + 1) >> 1); int block_size = 2; // Generate a fake input image. rtc::scoped_ptr yuv_input( CreateFakeQ420TestingImage(kHeight, kWidth, block_size, y_pointer, yuy2_pointer)); // Allocate space for the output image. rtc::scoped_ptr yuv_output( new uint8[I420_SIZE(kHeight, kWidth) + kAlignment + unalignment]); uint8 *y_output_pointer = ALIGNP(yuv_output.get(), kAlignment) + unalignment; uint8 *u_output_pointer = y_output_pointer + y_size; uint8 *v_output_pointer = u_output_pointer + uv_size; // Generate the expected output. uint8 *y_expected_pointer = NULL, *u_expected_pointer = NULL, *v_expected_pointer = NULL; rtc::scoped_ptr yuv_output_expected( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv420, y_expected_pointer, u_expected_pointer, v_expected_pointer)); for (int i = 0; i < repeat_; ++i) { libyuv::Q420ToI420(y_pointer, y_pitch, yuy2_pointer, yuy2_pitch, y_output_pointer, y_pitch, u_output_pointer, u_pitch, v_output_pointer, v_pitch, kWidth, kHeight); } // Compare the output frame with what is expected; expect exactly the same. // Note: MSE should be set to a larger threshold if an odd block width // is used, since the conversion will be lossy. EXPECT_TRUE(IsMemoryEqual(y_output_pointer, y_expected_pointer, I420_SIZE(kHeight, kWidth), 1.e-6)); if (dump_) { DumpYuvImage(y_output_pointer, kWidth, kHeight); } } TEST_P(PlanarFunctionsTest, M420ToI420) { // Get the unalignment offset int unalignment = GetParam(); uint8 *m420_pointer = NULL; int y_pitch = kWidth; int m420_pitch = kWidth; int u_pitch = (kWidth + 1) >> 1; int v_pitch = (kWidth + 1) >> 1; int y_size = kHeight * kWidth; int uv_size = ((kHeight + 1) >> 1) * ((kWidth + 1) >> 1); int block_size = 2; // Generate a fake input image. rtc::scoped_ptr yuv_input( CreateFakeM420TestingImage(kHeight, kWidth, block_size, m420_pointer)); // Allocate space for the output image. rtc::scoped_ptr yuv_output( new uint8[I420_SIZE(kHeight, kWidth) + kAlignment + unalignment]); uint8 *y_output_pointer = ALIGNP(yuv_output.get(), kAlignment) + unalignment; uint8 *u_output_pointer = y_output_pointer + y_size; uint8 *v_output_pointer = u_output_pointer + uv_size; // Generate the expected output. uint8 *y_expected_pointer = NULL, *u_expected_pointer = NULL, *v_expected_pointer = NULL; rtc::scoped_ptr yuv_output_expected( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv420, y_expected_pointer, u_expected_pointer, v_expected_pointer)); for (int i = 0; i < repeat_; ++i) { libyuv::M420ToI420(m420_pointer, m420_pitch, y_output_pointer, y_pitch, u_output_pointer, u_pitch, v_output_pointer, v_pitch, kWidth, kHeight); } // Compare the output frame with what is expected; expect exactly the same. // Note: MSE should be set to a larger threshold if an odd block width // is used, since the conversion will be lossy. EXPECT_TRUE(IsMemoryEqual(y_output_pointer, y_expected_pointer, I420_SIZE(kHeight, kWidth), 1.e-6)); if (dump_) { DumpYuvImage(y_output_pointer, kWidth, kHeight); } } TEST_P(PlanarFunctionsTest, NV12ToI420) { // Get the unalignment offset int unalignment = GetParam(); uint8 *y_pointer = NULL, *uv_pointer = NULL; int y_pitch = kWidth; int uv_pitch = 2 * ((kWidth + 1) >> 1); int u_pitch = (kWidth + 1) >> 1; int v_pitch = (kWidth + 1) >> 1; int y_size = kHeight * kWidth; int uv_size = ((kHeight + 1) >> 1) * ((kWidth + 1) >> 1); int block_size = 2; // Generate a fake input image. rtc::scoped_ptr yuv_input( CreateFakeNV12TestingImage(kHeight, kWidth, block_size, y_pointer, uv_pointer)); // Allocate space for the output image. rtc::scoped_ptr yuv_output( new uint8[I420_SIZE(kHeight, kWidth) + kAlignment + unalignment]); uint8 *y_output_pointer = ALIGNP(yuv_output.get(), kAlignment) + unalignment; uint8 *u_output_pointer = y_output_pointer + y_size; uint8 *v_output_pointer = u_output_pointer + uv_size; // Generate the expected output. uint8 *y_expected_pointer = NULL, *u_expected_pointer = NULL, *v_expected_pointer = NULL; rtc::scoped_ptr yuv_output_expected( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv420, y_expected_pointer, u_expected_pointer, v_expected_pointer)); for (int i = 0; i < repeat_; ++i) { libyuv::NV12ToI420(y_pointer, y_pitch, uv_pointer, uv_pitch, y_output_pointer, y_pitch, u_output_pointer, u_pitch, v_output_pointer, v_pitch, kWidth, kHeight); } // Compare the output frame with what is expected; expect exactly the same. // Note: MSE should be set to a larger threshold if an odd block width // is used, since the conversion will be lossy. EXPECT_TRUE(IsMemoryEqual(y_output_pointer, y_expected_pointer, I420_SIZE(kHeight, kWidth), 1.e-6)); if (dump_) { DumpYuvImage(y_output_pointer, kWidth, kHeight); } } // A common macro for testing converting YUY2/UYVY to I420. #define TEST_YUVTOI420(SRC_NAME, MSE, BLOCK_SIZE) \ TEST_P(PlanarFunctionsTest, SRC_NAME##ToI420) { \ /* Get the unalignment offset.*/ \ int unalignment = GetParam(); \ uint8 *yuv_pointer = NULL; \ int yuv_pitch = 2 * ((kWidth + 1) & ~1); \ int y_pitch = kWidth; \ int u_pitch = (kWidth + 1) >> 1; \ int v_pitch = (kWidth + 1) >> 1; \ int y_size = kHeight * kWidth; \ int uv_size = ((kHeight + 1) >> 1) * ((kWidth + 1) >> 1); \ int block_size = 2; \ /* Generate a fake input image.*/ \ rtc::scoped_ptr yuv_input( \ CreateFakeInterleaveYuvTestingImage(kHeight, kWidth, BLOCK_SIZE, \ yuv_pointer, FOURCC_##SRC_NAME)); \ /* Allocate space for the output image.*/ \ rtc::scoped_ptr yuv_output( \ new uint8[I420_SIZE(kHeight, kWidth) + kAlignment + unalignment]); \ uint8 *y_output_pointer = ALIGNP(yuv_output.get(), kAlignment) + \ unalignment; \ uint8 *u_output_pointer = y_output_pointer + y_size; \ uint8 *v_output_pointer = u_output_pointer + uv_size; \ /* Generate the expected output.*/ \ uint8 *y_expected_pointer = NULL, *u_expected_pointer = NULL, \ *v_expected_pointer = NULL; \ rtc::scoped_ptr yuv_output_expected( \ CreateFakeYuvTestingImage(kHeight, kWidth, block_size, \ libyuv::kJpegYuv420, \ y_expected_pointer, u_expected_pointer, v_expected_pointer)); \ for (int i = 0; i < repeat_; ++i) { \ libyuv::SRC_NAME##ToI420(yuv_pointer, yuv_pitch, \ y_output_pointer, y_pitch, \ u_output_pointer, u_pitch, \ v_output_pointer, v_pitch, \ kWidth, kHeight); \ } \ /* Compare the output frame with what is expected.*/ \ /* Note: MSE should be set to a larger threshold if an odd block width*/ \ /* is used, since the conversion will be lossy.*/ \ EXPECT_TRUE(IsMemoryEqual(y_output_pointer, y_expected_pointer, \ I420_SIZE(kHeight, kWidth), MSE)); \ if (dump_) { DumpYuvImage(y_output_pointer, kWidth, kHeight); } \ } \ // TEST_P(PlanarFunctionsTest, YUV2ToI420) TEST_YUVTOI420(YUY2, 1.e-6, 2); // TEST_P(PlanarFunctionsTest, UYVYToI420) TEST_YUVTOI420(UYVY, 1.e-6, 2); // A common macro for testing converting I420 to ARGB, BGRA and ABGR. #define TEST_YUVTORGB(SRC_NAME, DST_NAME, JPG_TYPE, MSE, BLOCK_SIZE) \ TEST_F(PlanarFunctionsTest, SRC_NAME##To##DST_NAME) { \ uint8 *y_pointer = NULL, *u_pointer = NULL, *v_pointer = NULL; \ uint8 *argb_expected_pointer = NULL; \ int y_pitch = kWidth; \ int u_pitch = (kWidth + 1) >> 1; \ int v_pitch = (kWidth + 1) >> 1; \ /* Generate a fake input image.*/ \ rtc::scoped_ptr yuv_input( \ CreateFakeYuvTestingImage(kHeight, kWidth, BLOCK_SIZE, JPG_TYPE, \ y_pointer, u_pointer, v_pointer)); \ /* Generate the expected output.*/ \ rtc::scoped_ptr argb_expected( \ CreateFakeArgbTestingImage(kHeight, kWidth, BLOCK_SIZE, \ argb_expected_pointer, FOURCC_##DST_NAME)); \ /* Allocate space for the output.*/ \ rtc::scoped_ptr argb_output( \ new uint8[kHeight * kWidth * 4 + kAlignment]); \ uint8 *argb_pointer = ALIGNP(argb_expected.get(), kAlignment); \ for (int i = 0; i < repeat_; ++i) { \ libyuv::SRC_NAME##To##DST_NAME(y_pointer, y_pitch, \ u_pointer, u_pitch, \ v_pointer, v_pitch, \ argb_pointer, \ kWidth * 4, \ kWidth, kHeight); \ } \ EXPECT_TRUE(IsMemoryEqual(argb_expected_pointer, argb_pointer, \ kHeight * kWidth * 4, MSE)); \ if (dump_) { DumpArgbImage(argb_pointer, kWidth, kHeight); } \ } // TEST_F(PlanarFunctionsTest, I420ToARGB) TEST_YUVTORGB(I420, ARGB, libyuv::kJpegYuv420, 3., 2); // TEST_F(PlanarFunctionsTest, I420ToABGR) TEST_YUVTORGB(I420, ABGR, libyuv::kJpegYuv420, 3., 2); // TEST_F(PlanarFunctionsTest, I420ToBGRA) TEST_YUVTORGB(I420, BGRA, libyuv::kJpegYuv420, 3., 2); // TEST_F(PlanarFunctionsTest, I422ToARGB) TEST_YUVTORGB(I422, ARGB, libyuv::kJpegYuv422, 3., 2); // TEST_F(PlanarFunctionsTest, I444ToARGB) TEST_YUVTORGB(I444, ARGB, libyuv::kJpegYuv444, 3., 3); // Note: an empirical MSE tolerance 3.0 is used here for the probable // error from float-to-uint8 type conversion. TEST_F(PlanarFunctionsTest, I400ToARGB_Reference) { uint8 *y_pointer = NULL, *u_pointer = NULL, *v_pointer = NULL; int y_pitch = kWidth; int u_pitch = (kWidth + 1) >> 1; int v_pitch = (kWidth + 1) >> 1; int block_size = 3; // Generate a fake input image. rtc::scoped_ptr yuv_input( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv420, y_pointer, u_pointer, v_pointer)); // As the comparison standard, we convert a grayscale image (by setting both // U and V channels to be 128) using an I420 converter. int uv_size = ((kHeight + 1) >> 1) * ((kWidth + 1) >> 1); rtc::scoped_ptr uv(new uint8[uv_size + kAlignment]); u_pointer = v_pointer = ALIGNP(uv.get(), kAlignment); memset(u_pointer, 128, uv_size); // Allocate space for the output image and generate the expected output. rtc::scoped_ptr argb_expected( new uint8[kHeight * kWidth * 4 + kAlignment]); rtc::scoped_ptr argb_output( new uint8[kHeight * kWidth * 4 + kAlignment]); uint8 *argb_expected_pointer = ALIGNP(argb_expected.get(), kAlignment); uint8 *argb_pointer = ALIGNP(argb_output.get(), kAlignment); libyuv::I420ToARGB(y_pointer, y_pitch, u_pointer, u_pitch, v_pointer, v_pitch, argb_expected_pointer, kWidth * 4, kWidth, kHeight); for (int i = 0; i < repeat_; ++i) { libyuv::I400ToARGB_Reference(y_pointer, y_pitch, argb_pointer, kWidth * 4, kWidth, kHeight); } // Note: I420ToARGB and I400ToARGB_Reference should produce identical results. EXPECT_TRUE(IsMemoryEqual(argb_expected_pointer, argb_pointer, kHeight * kWidth * 4, 2.)); if (dump_) { DumpArgbImage(argb_pointer, kWidth, kHeight); } } TEST_P(PlanarFunctionsTest, I400ToARGB) { // Get the unalignment offset int unalignment = GetParam(); uint8 *y_pointer = NULL, *u_pointer = NULL, *v_pointer = NULL; int y_pitch = kWidth; int u_pitch = (kWidth + 1) >> 1; int v_pitch = (kWidth + 1) >> 1; int block_size = 3; // Generate a fake input image. rtc::scoped_ptr yuv_input( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv420, y_pointer, u_pointer, v_pointer)); // As the comparison standard, we convert a grayscale image (by setting both // U and V channels to be 128) using an I420 converter. int uv_size = ((kHeight + 1) >> 1) * ((kWidth + 1) >> 1); // 1 byte extra if in the unaligned mode. rtc::scoped_ptr uv(new uint8[uv_size * 2 + kAlignment]); u_pointer = ALIGNP(uv.get(), kAlignment); v_pointer = u_pointer + uv_size; memset(u_pointer, 128, uv_size); memset(v_pointer, 128, uv_size); // Allocate space for the output image and generate the expected output. rtc::scoped_ptr argb_expected( new uint8[kHeight * kWidth * 4 + kAlignment]); // 1 byte extra if in the misalinged mode. rtc::scoped_ptr argb_output( new uint8[kHeight * kWidth * 4 + kAlignment + unalignment]); uint8 *argb_expected_pointer = ALIGNP(argb_expected.get(), kAlignment); uint8 *argb_pointer = ALIGNP(argb_output.get(), kAlignment) + unalignment; libyuv::I420ToARGB(y_pointer, y_pitch, u_pointer, u_pitch, v_pointer, v_pitch, argb_expected_pointer, kWidth * 4, kWidth, kHeight); for (int i = 0; i < repeat_; ++i) { libyuv::I400ToARGB(y_pointer, y_pitch, argb_pointer, kWidth * 4, kWidth, kHeight); } // Note: current I400ToARGB uses an approximate method, // so the error tolerance is larger here. EXPECT_TRUE(IsMemoryEqual(argb_expected_pointer, argb_pointer, kHeight * kWidth * 4, 64.0)); if (dump_) { DumpArgbImage(argb_pointer, kWidth, kHeight); } } TEST_P(PlanarFunctionsTest, ARGBToI400) { // Get the unalignment offset int unalignment = GetParam(); // Create a fake ARGB input image. uint8 *y_pointer = NULL, *u_pointer = NULL, *v_pointer = NULL; uint8 *argb_pointer = NULL; int block_size = 3; // Generate a fake input image. rtc::scoped_ptr argb_input( CreateFakeArgbTestingImage(kHeight, kWidth, block_size, argb_pointer, FOURCC_ARGB)); // Generate the expected output. Only Y channel is used rtc::scoped_ptr yuv_expected( CreateFakeYuvTestingImage(kHeight, kWidth, block_size, libyuv::kJpegYuv420, y_pointer, u_pointer, v_pointer)); // Allocate space for the Y output. rtc::scoped_ptr y_output( new uint8[kHeight * kWidth + kAlignment + unalignment]); uint8 *y_output_pointer = ALIGNP(y_output.get(), kAlignment) + unalignment; for (int i = 0; i < repeat_; ++i) { libyuv::ARGBToI400(argb_pointer, kWidth * 4, y_output_pointer, kWidth, kWidth, kHeight); } // Check if the output matches the input Y channel. // Note: an empirical MSE tolerance 2.0 is used here for the probable // error from float-to-uint8 type conversion. EXPECT_TRUE(IsMemoryEqual(y_output_pointer, y_pointer, kHeight * kWidth, 2.)); if (dump_) { DumpArgbImage(argb_pointer, kWidth, kHeight); } } // A common macro for testing converting RAW, BG24, BGRA, and ABGR // to ARGB. #define TEST_ARGB(SRC_NAME, FC_ID, BPP, BLOCK_SIZE) \ TEST_P(PlanarFunctionsTest, SRC_NAME##ToARGB) { \ int unalignment = GetParam(); /* Get the unalignment offset.*/ \ uint8 *argb_expected_pointer = NULL, *src_pointer = NULL; \ /* Generate a fake input image.*/ \ rtc::scoped_ptr src_input( \ CreateFakeArgbTestingImage(kHeight, kWidth, BLOCK_SIZE, \ src_pointer, FOURCC_##FC_ID)); \ /* Generate the expected output.*/ \ rtc::scoped_ptr argb_expected( \ CreateFakeArgbTestingImage(kHeight, kWidth, BLOCK_SIZE, \ argb_expected_pointer, FOURCC_ARGB)); \ /* Allocate space for the output; 1 byte extra if in the unaligned mode.*/ \ rtc::scoped_ptr argb_output( \ new uint8[kHeight * kWidth * 4 + kAlignment + unalignment]); \ uint8 *argb_pointer = ALIGNP(argb_output.get(), kAlignment) + unalignment; \ for (int i = 0; i < repeat_; ++i) { \ libyuv:: SRC_NAME##ToARGB(src_pointer, kWidth * (BPP), argb_pointer, \ kWidth * 4, kWidth, kHeight); \ } \ /* Compare the result; expect identical.*/ \ EXPECT_TRUE(IsMemoryEqual(argb_expected_pointer, argb_pointer, \ kHeight * kWidth * 4, 1.e-6)); \ if (dump_) { DumpArgbImage(argb_pointer, kWidth, kHeight); } \ } TEST_ARGB(RAW, RAW, 3, 3); // TEST_P(PlanarFunctionsTest, RAWToARGB) TEST_ARGB(BG24, 24BG, 3, 3); // TEST_P(PlanarFunctionsTest, BG24ToARGB) TEST_ARGB(ABGR, ABGR, 4, 3); // TEST_P(PlanarFunctionsTest, ABGRToARGB) TEST_ARGB(BGRA, BGRA, 4, 3); // TEST_P(PlanarFunctionsTest, BGRAToARGB) // Parameter Test: The parameter is the unalignment offset. // Aligned data for testing assembly versions. INSTANTIATE_TEST_CASE_P(PlanarFunctionsAligned, PlanarFunctionsTest, ::testing::Values(0)); // Purposely unalign the output argb pointer to test slow path (C version). INSTANTIATE_TEST_CASE_P(PlanarFunctionsMisaligned, PlanarFunctionsTest, ::testing::Values(1)); } // namespace cricket