| #include <algorithm> |
| #include <vector> |
| |
| #include "./aom_dsp/noise_model.h" |
| #include "./aom_dsp/noise_util.h" |
| #include "third_party/googletest/src/googletest/include/gtest/gtest.h" |
| |
| extern "C" double aom_randn(double sigma); |
| |
| TEST(NoiseStrengthSolver, GetCentersTwoBins) { |
| aom_noise_strength_solver_t solver; |
| aom_noise_strength_solver_init(&solver, 2); |
| EXPECT_NEAR(0, aom_noise_strength_solver_get_center(&solver, 0), 1e-5); |
| EXPECT_NEAR(255, aom_noise_strength_solver_get_center(&solver, 1), 1e-5); |
| aom_noise_strength_solver_free(&solver); |
| } |
| |
| TEST(NoiseStrengthSolver, GetCenters256Bins) { |
| const int num_bins = 256; |
| aom_noise_strength_solver_t solver; |
| aom_noise_strength_solver_init(&solver, num_bins); |
| |
| for (int i = 0; i < 256; ++i) { |
| EXPECT_NEAR(i, aom_noise_strength_solver_get_center(&solver, i), 1e-5); |
| } |
| aom_noise_strength_solver_free(&solver); |
| } |
| |
| // Tests that the noise strength solver returns the identity transform when |
| // given identity-like constraints. |
| TEST(NoiseStrengthSolver, ObserveIdentity) { |
| const int num_bins = 256; |
| aom_noise_strength_solver_t solver; |
| EXPECT_EQ(1, aom_noise_strength_solver_init(&solver, num_bins)); |
| |
| // We have to add a big more strength to constraints at the boundary to |
| // overcome any regularization. |
| for (int j = 0; j < 5; ++j) { |
| aom_noise_strength_solver_add_measurement(&solver, 0, 0); |
| aom_noise_strength_solver_add_measurement(&solver, 255, 255); |
| } |
| for (int i = 0; i < 256; ++i) { |
| aom_noise_strength_solver_add_measurement(&solver, i, i); |
| } |
| EXPECT_EQ(1, aom_noise_strength_solver_solve(&solver)); |
| for (int i = 2; i < num_bins - 2; ++i) { |
| EXPECT_NEAR(i, solver.eqns.x[i], 0.1); |
| } |
| |
| aom_noise_strength_lut_t lut; |
| EXPECT_EQ(1, aom_noise_strength_solver_fit_piecewise(&solver, &lut)); |
| |
| ASSERT_EQ(2, lut.num_points); |
| EXPECT_NEAR(0.0, lut.points[0][0], 1e-5); |
| EXPECT_NEAR(0.0, lut.points[0][1], 0.5); |
| EXPECT_NEAR(255.0, lut.points[1][0], 1e-5); |
| EXPECT_NEAR(255.0, lut.points[1][1], 0.5); |
| |
| aom_noise_strength_lut_free(&lut); |
| aom_noise_strength_solver_free(&solver); |
| } |
| |
| TEST(NoiseStrengthLut, LutEvalSinglePoint) { |
| aom_noise_strength_lut_t lut; |
| ASSERT_TRUE(aom_noise_strength_lut_init(&lut, 1)); |
| ASSERT_EQ(1, lut.num_points); |
| lut.points[0][0] = 0; |
| lut.points[0][1] = 1; |
| EXPECT_EQ(1, aom_noise_strength_lut_eval(&lut, -1)); |
| EXPECT_EQ(1, aom_noise_strength_lut_eval(&lut, 0)); |
| EXPECT_EQ(1, aom_noise_strength_lut_eval(&lut, 1)); |
| aom_noise_strength_lut_free(&lut); |
| } |
| |
| TEST(NoiseStrengthLut, LutEvalMultiPointInterp) { |
| const double kEps = 1e-5; |
| aom_noise_strength_lut_t lut; |
| ASSERT_TRUE(aom_noise_strength_lut_init(&lut, 4)); |
| ASSERT_EQ(4, lut.num_points); |
| |
| lut.points[0][0] = 0; |
| lut.points[0][1] = 0; |
| |
| lut.points[1][0] = 1; |
| lut.points[1][1] = 1; |
| |
| lut.points[2][0] = 2; |
| lut.points[2][1] = 1; |
| |
| lut.points[3][0] = 100; |
| lut.points[3][1] = 1001; |
| |
| // Test lower boundary |
| EXPECT_EQ(0, aom_noise_strength_lut_eval(&lut, -1)); |
| EXPECT_EQ(0, aom_noise_strength_lut_eval(&lut, 0)); |
| |
| // Test first part that should be identity |
| EXPECT_NEAR(0.25, aom_noise_strength_lut_eval(&lut, 0.25), kEps); |
| EXPECT_NEAR(0.75, aom_noise_strength_lut_eval(&lut, 0.75), kEps); |
| |
| // This is a constant section (should evaluate to 1) |
| EXPECT_NEAR(1.0, aom_noise_strength_lut_eval(&lut, 1.25), kEps); |
| EXPECT_NEAR(1.0, aom_noise_strength_lut_eval(&lut, 1.75), kEps); |
| |
| // Test interpolation between to non-zero y coords. |
| EXPECT_NEAR(1, aom_noise_strength_lut_eval(&lut, 2), kEps); |
| EXPECT_NEAR(251, aom_noise_strength_lut_eval(&lut, 26.5), kEps); |
| EXPECT_NEAR(751, aom_noise_strength_lut_eval(&lut, 75.5), kEps); |
| |
| // Test upper boundary |
| EXPECT_EQ(1001, aom_noise_strength_lut_eval(&lut, 100)); |
| EXPECT_EQ(1001, aom_noise_strength_lut_eval(&lut, 101)); |
| |
| aom_noise_strength_lut_free(&lut); |
| } |
| |
| TEST(NoiseModel, InitSuccessWithValidSquareShape) { |
| aom_noise_model_params_t params = { AOM_NOISE_SHAPE_SQUARE, 2 }; |
| aom_noise_model_t model; |
| |
| EXPECT_TRUE(aom_noise_model_init(&model, params)); |
| |
| const int kNumCoords = 12; |
| const int kCoords[][2] = { { -2, -2 }, { -1, -2 }, { 0, -2 }, { 1, -2 }, |
| { 2, -2 }, { -2, -1 }, { -1, -1 }, { 0, -1 }, |
| { 1, -1 }, { 2, -1 }, { -2, 0 }, { -1, 0 } }; |
| EXPECT_EQ(kNumCoords, model.n); |
| for (int i = 0; i < kNumCoords; ++i) { |
| const int *coord = kCoords[i]; |
| EXPECT_EQ(coord[0], model.coords[i][0]); |
| EXPECT_EQ(coord[1], model.coords[i][1]); |
| } |
| aom_noise_model_free(&model); |
| } |
| |
| TEST(NoiseModel, InitSuccessWithValidDiamondShape) { |
| aom_noise_model_t model; |
| aom_noise_model_params_t params = { AOM_NOISE_SHAPE_DIAMOND, 2 }; |
| EXPECT_TRUE(aom_noise_model_init(&model, params)); |
| EXPECT_EQ(6, model.n); |
| const int kNumCoords = 6; |
| const int kCoords[][2] = { { 0, -2 }, { -1, -1 }, { 0, -1 }, |
| { 1, -1 }, { -2, 0 }, { -1, 0 } }; |
| EXPECT_EQ(kNumCoords, model.n); |
| for (int i = 0; i < kNumCoords; ++i) { |
| const int *coord = kCoords[i]; |
| EXPECT_EQ(coord[0], model.coords[i][0]); |
| EXPECT_EQ(coord[1], model.coords[i][1]); |
| } |
| aom_noise_model_free(&model); |
| } |
| |
| TEST(NoiseModel, InitFailsWithTooLargeLag) { |
| aom_noise_model_t model; |
| aom_noise_model_params_t params = { AOM_NOISE_SHAPE_SQUARE, 10 }; |
| EXPECT_FALSE(aom_noise_model_init(&model, params)); |
| aom_noise_model_free(&model); |
| } |
| |
| TEST(NoiseModel, InitFailsWithTooSmallLag) { |
| aom_noise_model_t model; |
| aom_noise_model_params_t params = { AOM_NOISE_SHAPE_SQUARE, 0 }; |
| EXPECT_FALSE(aom_noise_model_init(&model, params)); |
| aom_noise_model_free(&model); |
| } |
| |
| TEST(NoiseModel, InitFailsWithInvalidShape) { |
| aom_noise_model_t model; |
| aom_noise_model_params_t params = { aom_noise_shape(100), 3 }; |
| EXPECT_FALSE(aom_noise_model_init(&model, params)); |
| aom_noise_model_free(&model); |
| } |
| |
| TEST(FlatBlockEstimator, ExtractBlock) { |
| const int kBlockSize = 16; |
| aom_flat_block_finder_t flat_block_finder; |
| ASSERT_EQ(1, aom_flat_block_finder_init(&flat_block_finder, kBlockSize)); |
| |
| // Test with an image of more than one block. |
| const int h = 2 * kBlockSize; |
| const int w = 2 * kBlockSize; |
| const int stride = 2 * kBlockSize; |
| std::vector<uint8_t> data(h * stride, 128); |
| |
| // Set up the (0,0) block to be a plane and the (0,1) block to be a |
| // checkerboard |
| for (int y = 0; y < kBlockSize; ++y) { |
| for (int x = 0; x < kBlockSize; ++x) { |
| data[y * stride + x] = -y + x + 128; |
| data[y * stride + x + kBlockSize] = |
| (x % 2 + y % 2) % 2 ? 128 - 20 : 128 + 20; |
| } |
| } |
| std::vector<double> block(kBlockSize * kBlockSize, 1); |
| std::vector<double> plane(kBlockSize * kBlockSize, 1); |
| |
| // The block data should be a constant (zero) and the rest of the plane |
| // trend is covered in the plane data. |
| aom_flat_block_finder_extract_block(&flat_block_finder, &data[0], w, h, |
| stride, 0, 0, &plane[0], &block[0]); |
| for (int y = 0; y < kBlockSize; ++y) { |
| for (int x = 0; x < kBlockSize; ++x) { |
| EXPECT_NEAR(0, block[y * kBlockSize + x], 1e-5); |
| EXPECT_NEAR((double)(data[y * stride + x]) / 255, |
| plane[y * kBlockSize + x], 1e-5); |
| } |
| } |
| |
| // The plane trend is a constant, and the block is a zero mean checkerboard. |
| aom_flat_block_finder_extract_block(&flat_block_finder, &data[0], w, h, |
| stride, kBlockSize, 0, &plane[0], |
| &block[0]); |
| for (int y = 0; y < kBlockSize; ++y) { |
| for (int x = 0; x < kBlockSize; ++x) { |
| EXPECT_NEAR(((double)data[y * stride + x + kBlockSize] - 128.0) / 255, |
| block[y * kBlockSize + x], 1e-5); |
| EXPECT_NEAR(128.0 / 255.0, plane[y * kBlockSize + x], 1e-5); |
| } |
| } |
| aom_flat_block_finder_free(&flat_block_finder); |
| } |
| |
| TEST(FlatBlockEstimator, FindFlatBlocks) { |
| const int kBlockSize = 32; |
| aom_flat_block_finder_t flat_block_finder; |
| ASSERT_EQ(1, aom_flat_block_finder_init(&flat_block_finder, kBlockSize)); |
| |
| const int num_blocks_w = 8; |
| const int h = kBlockSize; |
| const int w = kBlockSize * num_blocks_w; |
| const int stride = w; |
| std::vector<uint8_t> data(h * stride, 128); |
| std::vector<uint8_t> flat_blocks(num_blocks_w, 0); |
| |
| for (int y = 0; y < kBlockSize; ++y) { |
| for (int x = 0; x < kBlockSize; ++x) { |
| // Block 0 (not flat): constant doesn't have enough variance to qualify |
| data[y * stride + x + 0 * kBlockSize] = 128; |
| |
| // Block 1 (not flat): too high of variance is hard to validate as flat |
| data[y * stride + x + 1 * kBlockSize] = (uint8_t)(128 + aom_randn(5)); |
| |
| // Block 2 (flat): slight checkerboard added to constant |
| const int check = (x % 2 + y % 2) % 2 ? -2 : 2; |
| data[y * stride + x + 2 * kBlockSize] = 128 + check; |
| |
| // Block 3 (flat): planar block with checkerboard pattern is also flat |
| data[y * stride + x + 3 * kBlockSize] = y * 2 - x / 2 + 128 + check; |
| |
| // Block 4 (flat): gaussian random with standard deviation 1. |
| data[y * stride + x + 4 * kBlockSize] = |
| (uint8_t)(aom_randn(1) + x + 128.0); |
| |
| // Block 5 (flat): gaussian random with standard deviation 2. |
| data[y * stride + x + 5 * kBlockSize] = |
| (uint8_t)(aom_randn(2) + y + 128.0); |
| |
| // Block 6 (not flat): too high of directional gradient. |
| const int strong_edge = x > kBlockSize / 2 ? 64 : 0; |
| data[y * stride + x + 6 * kBlockSize] = |
| (uint8_t)(aom_randn(1) + strong_edge + 128.0); |
| |
| // Block 7 (not flat): too high gradient. |
| const int big_check = ((x >> 2) % 2 + (y >> 2) % 2) % 2 ? -16 : 16; |
| data[y * stride + x + 7 * kBlockSize] = |
| (uint8_t)(aom_randn(1) + big_check + 128.0); |
| } |
| } |
| |
| EXPECT_EQ(4, aom_flat_block_finder_run(&flat_block_finder, &data[0], w, h, |
| stride, &flat_blocks[0])); |
| |
| // First two blocks are not flat |
| EXPECT_EQ(0, flat_blocks[0]); |
| EXPECT_EQ(0, flat_blocks[1]); |
| |
| // Next 4 blocks are flat. |
| EXPECT_NE(0, flat_blocks[2]); |
| EXPECT_NE(0, flat_blocks[3]); |
| EXPECT_NE(0, flat_blocks[4]); |
| EXPECT_NE(0, flat_blocks[5]); |
| |
| // Last 2 are not. |
| EXPECT_EQ(0, flat_blocks[6]); |
| EXPECT_EQ(0, flat_blocks[7]); |
| |
| aom_flat_block_finder_free(&flat_block_finder); |
| } |
| |
| class NoiseModelUpdateTest : public ::testing::Test { |
| public: |
| static const int kWidth = 128; |
| static const int kHeight = 128; |
| static const int kBlockSize = 16; |
| static const int kNumBlocksX = kWidth / kBlockSize; |
| static const int kNumBlocksY = kHeight / kBlockSize; |
| |
| void SetUp() { |
| const aom_noise_model_params_t params = { AOM_NOISE_SHAPE_SQUARE, 3 }; |
| ASSERT_TRUE(aom_noise_model_init(&model_, params)); |
| |
| data_.resize(kWidth * kHeight * 3); |
| denoised_.resize(kWidth * kHeight * 3); |
| noise_.resize(kWidth * kHeight * 3); |
| renoise_.resize(kWidth * kHeight); |
| flat_blocks_.resize(kNumBlocksX * kNumBlocksY); |
| |
| for (int c = 0, offset = 0; c < 3; ++c, offset += kWidth * kHeight) { |
| data_ptr_[c] = &data_[offset]; |
| noise_ptr_[c] = &noise_[offset]; |
| denoised_ptr_[c] = &denoised_[offset]; |
| strides_[c] = kWidth; |
| } |
| chroma_sub_[0] = 0; |
| chroma_sub_[1] = 0; |
| } |
| |
| void TearDown() { aom_noise_model_free(&model_); } |
| |
| protected: |
| aom_noise_model_t model_; |
| std::vector<uint8_t> data_; |
| std::vector<uint8_t> denoised_; |
| |
| std::vector<double> noise_; |
| std::vector<double> renoise_; |
| std::vector<uint8_t> flat_blocks_; |
| |
| uint8_t *data_ptr_[3]; |
| uint8_t *denoised_ptr_[3]; |
| double *noise_ptr_[3]; |
| int strides_[3]; |
| int chroma_sub_[2]; |
| }; |
| |
| TEST_F(NoiseModelUpdateTest, UpdateFailsNoFlatBlocks) { |
| EXPECT_EQ(AOM_NOISE_STATUS_INSUFFICIENT_FLAT_BLOCKS, |
| aom_noise_model_update(&model_, data_ptr_, denoised_ptr_, kWidth, |
| kHeight, strides_, chroma_sub_, |
| &flat_blocks_[0], kBlockSize)); |
| } |
| |
| TEST_F(NoiseModelUpdateTest, UpdateSuccessForZeroNoiseAllFlat) { |
| flat_blocks_.assign(flat_blocks_.size(), 1); |
| denoised_.assign(denoised_.size(), 128); |
| data_.assign(denoised_.size(), 128); |
| EXPECT_EQ(AOM_NOISE_STATUS_INTERNAL_ERROR, |
| aom_noise_model_update(&model_, data_ptr_, denoised_ptr_, kWidth, |
| kHeight, strides_, chroma_sub_, |
| &flat_blocks_[0], kBlockSize)); |
| } |
| |
| TEST_F(NoiseModelUpdateTest, UpdateFailsBlockSizeTooSmall) { |
| flat_blocks_.assign(flat_blocks_.size(), 1); |
| denoised_.assign(denoised_.size(), 128); |
| data_.assign(denoised_.size(), 128); |
| EXPECT_EQ( |
| AOM_NOISE_STATUS_INVALID_ARGUMENT, |
| aom_noise_model_update(&model_, data_ptr_, denoised_ptr_, kWidth, kHeight, |
| strides_, chroma_sub_, &flat_blocks_[0], |
| 6 /* block_size=2 is too small*/)); |
| } |
| |
| TEST_F(NoiseModelUpdateTest, UpdateSuccessForWhiteRandomNoise) { |
| for (int y = 0; y < kHeight; ++y) { |
| for (int x = 0; x < kWidth; ++x) { |
| data_ptr_[0][y * kWidth + x] = int(64 + y + aom_randn(1)); |
| denoised_ptr_[0][y * kWidth + x] = 64 + y; |
| // Make the chroma planes completely correlated with the Y plane |
| for (int c = 1; c < 3; ++c) { |
| data_ptr_[c][y * kWidth + x] = data_ptr_[0][y * kWidth + x]; |
| denoised_ptr_[c][y * kWidth + x] = denoised_ptr_[0][y * kWidth + x]; |
| } |
| } |
| } |
| flat_blocks_.assign(flat_blocks_.size(), 1); |
| EXPECT_EQ(AOM_NOISE_STATUS_OK, |
| aom_noise_model_update(&model_, data_ptr_, denoised_ptr_, kWidth, |
| kHeight, strides_, chroma_sub_, |
| &flat_blocks_[0], kBlockSize)); |
| |
| const double kCoeffEps = 0.075; |
| const int n = model_.n; |
| for (int c = 0; c < 3; ++c) { |
| for (int i = 0; i < n; ++i) { |
| EXPECT_NEAR(0, model_.latest_state[c].eqns.x[i], kCoeffEps); |
| EXPECT_NEAR(0, model_.combined_state[c].eqns.x[i], kCoeffEps); |
| } |
| // The second and third channels are highly correlated with the first. |
| if (c > 0) { |
| ASSERT_EQ(n + 1, model_.latest_state[c].eqns.n); |
| ASSERT_EQ(n + 1, model_.combined_state[c].eqns.n); |
| |
| EXPECT_NEAR(1, model_.latest_state[c].eqns.x[n], kCoeffEps); |
| EXPECT_NEAR(1, model_.combined_state[c].eqns.x[n], kCoeffEps); |
| } |
| } |
| |
| // The fitted noise strength should be close to the standard deviation |
| // for all intensity bins. |
| const double kStdEps = 0.1; |
| for (int i = 0; i < model_.latest_state[0].strength_solver.eqns.n; ++i) { |
| EXPECT_NEAR(1.0, model_.latest_state[0].strength_solver.eqns.x[i], kStdEps); |
| EXPECT_NEAR(1.0, model_.combined_state[0].strength_solver.eqns.x[i], |
| kStdEps); |
| } |
| |
| aom_noise_strength_lut_t lut; |
| aom_noise_strength_solver_fit_piecewise( |
| &model_.latest_state[0].strength_solver, &lut); |
| ASSERT_EQ(2, lut.num_points); |
| EXPECT_NEAR(0.0, lut.points[0][0], 1e-5); |
| EXPECT_NEAR(1.0, lut.points[0][1], kStdEps); |
| EXPECT_NEAR(255.0, lut.points[1][0], 1e-5); |
| EXPECT_NEAR(1.0, lut.points[1][1], kStdEps); |
| aom_noise_strength_lut_free(&lut); |
| } |
| |
| TEST_F(NoiseModelUpdateTest, UpdateSuccessForScaledWhiteNoise) { |
| const double kCoeffEps = 0.055; |
| const double kLowStd = 1; |
| const double kHighStd = 4; |
| for (int y = 0; y < kHeight; ++y) { |
| for (int x = 0; x < kWidth; ++x) { |
| for (int c = 0; c < 3; ++c) { |
| // The image data is bimodal: |
| // Bottom half has low intensity and low noise strength |
| // Top half has high intensity and high noise strength |
| const int avg = (y < kHeight / 2) ? 4 : 245; |
| const double std = (y < kHeight / 2) ? kLowStd : kHighStd; |
| data_ptr_[c][y * kWidth + x] = |
| (uint8_t)std::min((int)255, (int)(2 + avg + aom_randn(std))); |
| denoised_ptr_[c][y * kWidth + x] = 2 + avg; |
| } |
| } |
| } |
| // Label all blocks as flat for the update |
| flat_blocks_.assign(flat_blocks_.size(), 1); |
| EXPECT_EQ(AOM_NOISE_STATUS_OK, |
| aom_noise_model_update(&model_, data_ptr_, denoised_ptr_, kWidth, |
| kHeight, strides_, chroma_sub_, |
| &flat_blocks_[0], kBlockSize)); |
| |
| const int n = model_.n; |
| // The noise is uncorrelated spatially and with the y channel. |
| // All coefficients should be reasonably close to zero. |
| for (int c = 0; c < 3; ++c) { |
| for (int i = 0; i < n; ++i) { |
| EXPECT_NEAR(0, model_.latest_state[c].eqns.x[i], kCoeffEps); |
| EXPECT_NEAR(0, model_.combined_state[c].eqns.x[i], kCoeffEps); |
| } |
| if (c > 0) { |
| ASSERT_EQ(n + 1, model_.latest_state[c].eqns.n); |
| ASSERT_EQ(n + 1, model_.combined_state[c].eqns.n); |
| |
| // The correlation to the y channel should be low (near zero) |
| EXPECT_NEAR(0, model_.latest_state[c].eqns.x[n], kCoeffEps); |
| EXPECT_NEAR(0, model_.combined_state[c].eqns.x[n], kCoeffEps); |
| } |
| } |
| |
| // Noise strength should vary between kLowStd and kHighStd. |
| const double kStdEps = 0.15; |
| ASSERT_EQ(20, model_.latest_state[0].strength_solver.eqns.n); |
| for (int i = 0; i < model_.latest_state[0].strength_solver.eqns.n; ++i) { |
| const double a = i / 19.0; |
| const double expected = (kLowStd * (1.0 - a) + kHighStd * a); |
| EXPECT_NEAR(expected, model_.latest_state[0].strength_solver.eqns.x[i], |
| kStdEps); |
| EXPECT_NEAR(expected, model_.combined_state[0].strength_solver.eqns.x[i], |
| kStdEps); |
| } |
| |
| // If we fit a piecewise linear model, there should be two points: |
| // one near kLowStd at 0, and the other near kHighStd and 255. |
| aom_noise_strength_lut_t lut; |
| aom_noise_strength_solver_fit_piecewise( |
| &model_.latest_state[0].strength_solver, &lut); |
| ASSERT_EQ(2, lut.num_points); |
| EXPECT_NEAR(0, lut.points[0][0], 1e-4); |
| EXPECT_NEAR(kLowStd, lut.points[0][1], kStdEps); |
| EXPECT_NEAR(255.0, lut.points[1][0], 1e-5); |
| EXPECT_NEAR(kHighStd, lut.points[1][1], kStdEps); |
| aom_noise_strength_lut_free(&lut); |
| } |
| |
| TEST_F(NoiseModelUpdateTest, UpdateSuccessForCorrelatedNoise) { |
| const int kNumCoeffs = 24; |
| const double kStd = 4; |
| const double kStdEps = 0.3; |
| const int kBlockSize = 16; |
| const double kCoeffEps = 0.06; |
| // Use different coefficients for each channel |
| const double kCoeffs[3][24] = { |
| { 0.02884, -0.03356, 0.00633, 0.01757, 0.02849, -0.04620, |
| 0.02833, -0.07178, 0.07076, -0.11603, -0.10413, -0.16571, |
| 0.05158, -0.07969, 0.02640, -0.07191, 0.02530, 0.41968, |
| 0.21450, -0.00702, -0.01401, -0.03676, -0.08713, 0.44196 }, |
| { 0.00269, -0.01291, -0.01513, 0.07234, 0.03208, 0.00477, |
| 0.00226, -0.00254, 0.03533, 0.12841, -0.25970, -0.06336, |
| 0.05238, -0.00845, -0.03118, 0.09043, -0.36558, 0.48903, |
| 0.00595, -0.11938, 0.02106, 0.095956, -0.350139, 0.59305 }, |
| { -0.00643, -0.01080, -0.01466, 0.06951, 0.03707, -0.00482, |
| 0.00817, -0.00909, 0.02949, 0.12181, -0.25210, -0.07886, |
| 0.06083, -0.01210, -0.03108, 0.08944, -0.35875, 0.49150, |
| 0.00415, -0.12905, 0.02870, 0.09740, -0.34610, 0.58824 }, |
| }; |
| ASSERT_EQ(model_.n, kNumCoeffs); |
| chroma_sub_[0] = chroma_sub_[1] = 1; |
| |
| flat_blocks_.assign(flat_blocks_.size(), 1); |
| |
| // Add different noise onto each plane |
| for (int c = 0; c < 3; ++c) { |
| aom_noise_synth(model_.params.lag, model_.n, model_.coords, kCoeffs[c], |
| noise_ptr_[c], kWidth, kHeight); |
| const int x_shift = c > 0 ? chroma_sub_[0] : 0; |
| const int y_shift = c > 0 ? chroma_sub_[1] : 0; |
| for (int y = 0; y < (kHeight >> y_shift); ++y) { |
| for (int x = 0; x < (kWidth >> x_shift); ++x) { |
| const uint8_t value = 64 + x / 2 + y / 4; |
| data_ptr_[c][y * kWidth + x] = |
| uint8_t(value + noise_ptr_[c][y * strides_[c] + x] * kStd); |
| denoised_ptr_[c][y * strides_[c] + x] = value; |
| } |
| } |
| } |
| EXPECT_EQ(AOM_NOISE_STATUS_OK, |
| aom_noise_model_update(&model_, data_ptr_, denoised_ptr_, kWidth, |
| kHeight, strides_, chroma_sub_, |
| &flat_blocks_[0], kBlockSize)); |
| |
| // For the Y plane, the solved coefficients should be close to the original |
| const int n = model_.n; |
| for (int c = 0; c < 3; ++c) { |
| for (int i = 0; i < n; ++i) { |
| EXPECT_NEAR(kCoeffs[c][i], model_.latest_state[c].eqns.x[i], kCoeffEps); |
| EXPECT_NEAR(kCoeffs[c][i], model_.combined_state[c].eqns.x[i], kCoeffEps); |
| } |
| // The chroma planes should be uncorrelated with the luma plane |
| if (c > 0) { |
| EXPECT_NEAR(0, model_.latest_state[c].eqns.x[n], kCoeffEps); |
| EXPECT_NEAR(0, model_.combined_state[c].eqns.x[n], kCoeffEps); |
| } |
| // Correlation between the coefficient vector and the fitted coefficients |
| // should be close to 1. |
| EXPECT_LT(0.98, aom_normalized_cross_correlation( |
| model_.latest_state[c].eqns.x, kCoeffs[c], kNumCoeffs)); |
| |
| aom_noise_synth(model_.params.lag, model_.n, model_.coords, |
| model_.latest_state[c].eqns.x, &renoise_[0], kWidth, |
| kHeight); |
| |
| EXPECT_TRUE(aom_noise_data_validate(&renoise_[0], kWidth, kHeight)); |
| } |
| |
| // Check fitted noise strength |
| for (int c = 0; c < 3; ++c) { |
| for (int i = 0; i < model_.latest_state[c].strength_solver.eqns.n; ++i) { |
| EXPECT_NEAR(kStd, model_.latest_state[c].strength_solver.eqns.x[i], |
| kStdEps); |
| } |
| } |
| } |