| // Copyright 2013 The Flutter 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 "flutter/testing/testing.h" |
| #include "fml/status_or.h" |
| #include "gmock/gmock.h" |
| #include "impeller/entity/contents/filters/gaussian_blur_filter_contents.h" |
| #include "impeller/entity/contents/texture_contents.h" |
| #include "impeller/entity/entity_playground.h" |
| #include "impeller/geometry/geometry_asserts.h" |
| #include "impeller/renderer/testing/mocks.h" |
| |
| #if FML_OS_MACOSX |
| #define IMPELLER_RAND arc4random |
| #else |
| #define IMPELLER_RAND rand |
| #endif |
| |
| namespace impeller { |
| namespace testing { |
| |
| namespace { |
| |
| // Use newtonian method to give the closest answer to target where |
| // f(x) is less than the target. We do this because the value is `ceil`'d to |
| // grab fractional pixels. |
| fml::StatusOr<float> LowerBoundNewtonianMethod( |
| const std::function<float(float)>& func, |
| float target, |
| float guess, |
| float tolerance) { |
| const double delta = 1e-6; |
| double x = guess; |
| double fx; |
| static const int kMaxIterations = 1000; |
| int count = 0; |
| |
| do { |
| fx = func(x) - target; |
| double derivative = (func(x + delta) - func(x)) / delta; |
| x = x - fx / derivative; |
| if (++count > kMaxIterations) { |
| return fml::Status(fml::StatusCode::kDeadlineExceeded, |
| "Did not converge on answer."); |
| } |
| } while (std::abs(fx) > tolerance || |
| fx < 0.0); // fx < 0.0 makes this lower bound. |
| |
| return x; |
| } |
| |
| fml::StatusOr<Scalar> CalculateSigmaForBlurRadius( |
| Scalar radius, |
| const Matrix& effect_transform) { |
| auto f = [effect_transform](Scalar x) -> Scalar { |
| Vector2 scaled_sigma = (effect_transform.Basis() * |
| Vector2(GaussianBlurFilterContents::ScaleSigma(x), |
| GaussianBlurFilterContents::ScaleSigma(x))) |
| .Abs(); |
| Vector2 blur_radius = Vector2( |
| GaussianBlurFilterContents::CalculateBlurRadius(scaled_sigma.x), |
| GaussianBlurFilterContents::CalculateBlurRadius(scaled_sigma.y)); |
| return std::max(blur_radius.x, blur_radius.y); |
| }; |
| // The newtonian method is used here since inverting the function is |
| // non-trivial because of conditional logic and would be fragile to changes. |
| return LowerBoundNewtonianMethod(f, radius, 2.f, 0.001f); |
| } |
| |
| } // namespace |
| |
| class GaussianBlurFilterContentsTest : public EntityPlayground { |
| public: |
| /// Create a texture that has been cleared to transparent black. |
| std::shared_ptr<Texture> MakeTexture(ISize size) { |
| std::shared_ptr<CommandBuffer> command_buffer = |
| GetContentContext()->GetContext()->CreateCommandBuffer(); |
| if (!command_buffer) { |
| return nullptr; |
| } |
| |
| auto render_target = GetContentContext()->MakeSubpass( |
| "Clear Subpass", size, command_buffer, |
| [](const ContentContext&, RenderPass&) { return true; }); |
| |
| if (!GetContentContext() |
| ->GetContext() |
| ->GetCommandQueue() |
| ->Submit(/*buffers=*/{command_buffer}) |
| .ok()) { |
| return nullptr; |
| } |
| |
| if (render_target.ok()) { |
| return render_target.value().GetRenderTargetTexture(); |
| } |
| return nullptr; |
| } |
| }; |
| INSTANTIATE_PLAYGROUND_SUITE(GaussianBlurFilterContentsTest); |
| |
| TEST(GaussianBlurFilterContentsTest, Create) { |
| GaussianBlurFilterContents contents( |
| /*sigma_x=*/0.0, /*sigma_y=*/0.0, Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| EXPECT_EQ(contents.GetSigmaX(), 0.0); |
| EXPECT_EQ(contents.GetSigmaY(), 0.0); |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, CoverageEmpty) { |
| GaussianBlurFilterContents contents( |
| /*sigma_x=*/0.0, /*sigma_y=*/0.0, Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| FilterInput::Vector inputs = {}; |
| Entity entity; |
| std::optional<Rect> coverage = |
| contents.GetFilterCoverage(inputs, entity, /*effect_transform=*/Matrix()); |
| ASSERT_FALSE(coverage.has_value()); |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, CoverageSimple) { |
| GaussianBlurFilterContents contents( |
| /*sigma_x=*/0.0, /*sigma_y=*/0.0, Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| FilterInput::Vector inputs = { |
| FilterInput::Make(Rect::MakeLTRB(10, 10, 110, 110))}; |
| Entity entity; |
| std::optional<Rect> coverage = |
| contents.GetFilterCoverage(inputs, entity, /*effect_transform=*/Matrix()); |
| |
| ASSERT_EQ(coverage, Rect::MakeLTRB(10, 10, 110, 110)); |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, CoverageWithSigma) { |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, Matrix()); |
| ASSERT_TRUE(sigma_radius_1.ok()); |
| GaussianBlurFilterContents contents( |
| /*sigma_x=*/sigma_radius_1.value(), |
| /*sigma_y=*/sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| FilterInput::Vector inputs = { |
| FilterInput::Make(Rect::MakeLTRB(100, 100, 200, 200))}; |
| Entity entity; |
| std::optional<Rect> coverage = |
| contents.GetFilterCoverage(inputs, entity, /*effect_transform=*/Matrix()); |
| |
| EXPECT_TRUE(coverage.has_value()); |
| if (coverage.has_value()) { |
| EXPECT_RECT_NEAR(coverage.value(), Rect::MakeLTRB(99, 99, 201, 201)); |
| } |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, CoverageWithTexture) { |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, Matrix()); |
| ASSERT_TRUE(sigma_radius_1.ok()); |
| GaussianBlurFilterContents contents( |
| /*sigma_X=*/sigma_radius_1.value(), |
| /*sigma_y=*/sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(100, 100)); |
| FilterInput::Vector inputs = {FilterInput::Make(texture)}; |
| Entity entity; |
| entity.SetTransform(Matrix::MakeTranslation({100, 100, 0})); |
| std::optional<Rect> coverage = |
| contents.GetFilterCoverage(inputs, entity, /*effect_transform=*/Matrix()); |
| |
| EXPECT_TRUE(coverage.has_value()); |
| if (coverage.has_value()) { |
| EXPECT_RECT_NEAR(coverage.value(), Rect::MakeLTRB(99, 99, 201, 201)); |
| } |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, CoverageWithEffectTransform) { |
| Matrix effect_transform = Matrix::MakeScale({2.0, 2.0, 1.0}); |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, effect_transform); |
| ASSERT_TRUE(sigma_radius_1.ok()); |
| GaussianBlurFilterContents contents( |
| /*sigma_x=*/sigma_radius_1.value(), |
| /*sigma_y=*/sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(100, 100)); |
| FilterInput::Vector inputs = {FilterInput::Make(texture)}; |
| Entity entity; |
| entity.SetTransform(Matrix::MakeTranslation({100, 100, 0})); |
| std::optional<Rect> coverage = |
| contents.GetFilterCoverage(inputs, entity, effect_transform); |
| EXPECT_TRUE(coverage.has_value()); |
| if (coverage.has_value()) { |
| EXPECT_RECT_NEAR(coverage.value(), |
| Rect::MakeLTRB(100 - 1, 100 - 1, 200 + 1, 200 + 1)); |
| } |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, FilterSourceCoverage) { |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, Matrix()); |
| ASSERT_TRUE(sigma_radius_1.ok()); |
| auto contents = std::make_unique<GaussianBlurFilterContents>( |
| sigma_radius_1.value(), sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| std::optional<Rect> coverage = contents->GetFilterSourceCoverage( |
| /*effect_transform=*/Matrix::MakeScale({2.0, 2.0, 1.0}), |
| /*output_limit=*/Rect::MakeLTRB(100, 100, 200, 200)); |
| EXPECT_TRUE(coverage.has_value()); |
| if (coverage.has_value()) { |
| EXPECT_RECT_NEAR(coverage.value(), |
| Rect::MakeLTRB(100 - 2, 100 - 2, 200 + 2, 200 + 2)); |
| } |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, CalculateSigmaValues) { |
| EXPECT_EQ(GaussianBlurFilterContents::CalculateScale(1.0f), 1); |
| EXPECT_EQ(GaussianBlurFilterContents::CalculateScale(2.0f), 1); |
| EXPECT_EQ(GaussianBlurFilterContents::CalculateScale(3.0f), 1); |
| EXPECT_EQ(GaussianBlurFilterContents::CalculateScale(4.0f), 1); |
| EXPECT_EQ(GaussianBlurFilterContents::CalculateScale(16.0f), 0.25); |
| // Hang on to 1/8 as long as possible. |
| EXPECT_EQ(GaussianBlurFilterContents::CalculateScale(95.0f), 0.125); |
| EXPECT_EQ(GaussianBlurFilterContents::CalculateScale(96.0f), 0.0625); |
| // Downsample clamped to 1/16th. |
| EXPECT_EQ(GaussianBlurFilterContents::CalculateScale(1024.0f), 0.0625); |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, RenderCoverageMatchesGetCoverage) { |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(100, 100)); |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, Matrix()); |
| ASSERT_TRUE(sigma_radius_1.ok()); |
| auto contents = std::make_unique<GaussianBlurFilterContents>( |
| sigma_radius_1.value(), sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| contents->SetInputs({FilterInput::Make(texture)}); |
| std::shared_ptr<ContentContext> renderer = GetContentContext(); |
| |
| Entity entity; |
| std::optional<Entity> result = |
| contents->GetEntity(*renderer, entity, /*coverage_hint=*/{}); |
| EXPECT_TRUE(result.has_value()); |
| if (result.has_value()) { |
| EXPECT_EQ(result.value().GetBlendMode(), BlendMode::kSourceOver); |
| std::optional<Rect> result_coverage = result.value().GetCoverage(); |
| std::optional<Rect> contents_coverage = contents->GetCoverage(entity); |
| EXPECT_TRUE(result_coverage.has_value()); |
| EXPECT_TRUE(contents_coverage.has_value()); |
| if (result_coverage.has_value() && contents_coverage.has_value()) { |
| EXPECT_TRUE(RectNear(contents_coverage.value(), |
| Rect::MakeLTRB(-1, -1, 101, 101))); |
| EXPECT_TRUE( |
| RectNear(result_coverage.value(), Rect::MakeLTRB(-1, -1, 101, 101))); |
| } |
| } |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, |
| RenderCoverageMatchesGetCoverageTranslate) { |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(100, 100)); |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, Matrix()); |
| ASSERT_TRUE(sigma_radius_1.ok()); |
| auto contents = std::make_unique<GaussianBlurFilterContents>( |
| sigma_radius_1.value(), sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| contents->SetInputs({FilterInput::Make(texture)}); |
| std::shared_ptr<ContentContext> renderer = GetContentContext(); |
| |
| Entity entity; |
| entity.SetTransform(Matrix::MakeTranslation({100, 200, 0})); |
| std::optional<Entity> result = |
| contents->GetEntity(*renderer, entity, /*coverage_hint=*/{}); |
| |
| EXPECT_TRUE(result.has_value()); |
| if (result.has_value()) { |
| EXPECT_EQ(result.value().GetBlendMode(), BlendMode::kSourceOver); |
| std::optional<Rect> result_coverage = result.value().GetCoverage(); |
| std::optional<Rect> contents_coverage = contents->GetCoverage(entity); |
| EXPECT_TRUE(result_coverage.has_value()); |
| EXPECT_TRUE(contents_coverage.has_value()); |
| if (result_coverage.has_value() && contents_coverage.has_value()) { |
| EXPECT_TRUE(RectNear(contents_coverage.value(), |
| Rect::MakeLTRB(99, 199, 201, 301))); |
| EXPECT_TRUE( |
| RectNear(result_coverage.value(), Rect::MakeLTRB(99, 199, 201, 301))); |
| } |
| } |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, |
| RenderCoverageMatchesGetCoverageRotated) { |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(400, 300)); |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, Matrix()); |
| auto contents = std::make_unique<GaussianBlurFilterContents>( |
| sigma_radius_1.value(), sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| contents->SetInputs({FilterInput::Make(texture)}); |
| std::shared_ptr<ContentContext> renderer = GetContentContext(); |
| |
| Entity entity; |
| // Rotate around the top left corner, then push it over to (100, 100). |
| entity.SetTransform(Matrix::MakeTranslation({400, 100, 0}) * |
| Matrix::MakeRotationZ(Degrees(90.0))); |
| std::optional<Entity> result = |
| contents->GetEntity(*renderer, entity, /*coverage_hint=*/{}); |
| EXPECT_TRUE(result.has_value()); |
| if (result.has_value()) { |
| EXPECT_EQ(result.value().GetBlendMode(), BlendMode::kSourceOver); |
| std::optional<Rect> result_coverage = result.value().GetCoverage(); |
| std::optional<Rect> contents_coverage = contents->GetCoverage(entity); |
| EXPECT_TRUE(result_coverage.has_value()); |
| EXPECT_TRUE(contents_coverage.has_value()); |
| if (result_coverage.has_value() && contents_coverage.has_value()) { |
| EXPECT_TRUE(RectNear(contents_coverage.value(), |
| Rect::MakeLTRB(99, 99, 401, 501))); |
| EXPECT_TRUE( |
| RectNear(result_coverage.value(), Rect::MakeLTRB(99, 99, 401, 501))); |
| } |
| } |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, CalculateUVsSimple) { |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(100, 100)); |
| auto filter_input = FilterInput::Make(texture); |
| Entity entity; |
| Quad uvs = GaussianBlurFilterContents::CalculateUVs( |
| filter_input, entity, Rect::MakeSize(ISize(100, 100)), ISize(100, 100)); |
| std::optional<Rect> uvs_bounds = Rect::MakePointBounds(uvs); |
| EXPECT_TRUE(uvs_bounds.has_value()); |
| if (uvs_bounds.has_value()) { |
| EXPECT_TRUE(RectNear(uvs_bounds.value(), Rect::MakeXYWH(0, 0, 1, 1))); |
| } |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, TextureContentsWithDestinationRect) { |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(100, 100)); |
| auto texture_contents = std::make_shared<TextureContents>(); |
| texture_contents->SetSourceRect(Rect::MakeSize(texture->GetSize())); |
| texture_contents->SetTexture(texture); |
| texture_contents->SetDestinationRect(Rect::MakeXYWH( |
| 50, 40, texture->GetSize().width, texture->GetSize().height)); |
| |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, Matrix()); |
| auto contents = std::make_unique<GaussianBlurFilterContents>( |
| sigma_radius_1.value(), sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| contents->SetInputs({FilterInput::Make(texture_contents)}); |
| std::shared_ptr<ContentContext> renderer = GetContentContext(); |
| |
| Entity entity; |
| std::optional<Entity> result = |
| contents->GetEntity(*renderer, entity, /*coverage_hint=*/{}); |
| EXPECT_TRUE(result.has_value()); |
| if (result.has_value()) { |
| EXPECT_EQ(result.value().GetBlendMode(), BlendMode::kSourceOver); |
| std::optional<Rect> result_coverage = result.value().GetCoverage(); |
| std::optional<Rect> contents_coverage = contents->GetCoverage(entity); |
| EXPECT_TRUE(result_coverage.has_value()); |
| EXPECT_TRUE(contents_coverage.has_value()); |
| if (result_coverage.has_value() && contents_coverage.has_value()) { |
| EXPECT_TRUE(RectNear(result_coverage.value(), contents_coverage.value())); |
| EXPECT_TRUE(RectNear(result_coverage.value(), |
| Rect::MakeLTRB(49.f, 39.f, 151.f, 141.f))); |
| } |
| } |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, |
| TextureContentsWithDestinationRectScaled) { |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(100, 100)); |
| auto texture_contents = std::make_shared<TextureContents>(); |
| texture_contents->SetSourceRect(Rect::MakeSize(texture->GetSize())); |
| texture_contents->SetTexture(texture); |
| texture_contents->SetDestinationRect(Rect::MakeXYWH( |
| 50, 40, texture->GetSize().width, texture->GetSize().height)); |
| |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, Matrix()); |
| auto contents = std::make_unique<GaussianBlurFilterContents>( |
| sigma_radius_1.value(), sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| contents->SetInputs({FilterInput::Make(texture_contents)}); |
| std::shared_ptr<ContentContext> renderer = GetContentContext(); |
| |
| Entity entity; |
| entity.SetTransform(Matrix::MakeScale({2.0, 2.0, 1.0})); |
| std::optional<Entity> result = |
| contents->GetEntity(*renderer, entity, /*coverage_hint=*/{}); |
| EXPECT_TRUE(result.has_value()); |
| if (result.has_value()) { |
| EXPECT_EQ(result.value().GetBlendMode(), BlendMode::kSourceOver); |
| std::optional<Rect> result_coverage = result.value().GetCoverage(); |
| std::optional<Rect> contents_coverage = contents->GetCoverage(entity); |
| EXPECT_TRUE(result_coverage.has_value()); |
| EXPECT_TRUE(contents_coverage.has_value()); |
| if (result_coverage.has_value() && contents_coverage.has_value()) { |
| EXPECT_TRUE(RectNear(result_coverage.value(), contents_coverage.value())); |
| EXPECT_TRUE(RectNear(contents_coverage.value(), |
| Rect::MakeLTRB(98.f, 78.f, 302.f, 282.f))); |
| } |
| } |
| } |
| |
| TEST_P(GaussianBlurFilterContentsTest, TextureContentsWithEffectTransform) { |
| Matrix effect_transform = Matrix::MakeScale({2.0, 2.0, 1.0}); |
| std::shared_ptr<Texture> texture = MakeTexture(ISize(100, 100)); |
| auto texture_contents = std::make_shared<TextureContents>(); |
| texture_contents->SetSourceRect(Rect::MakeSize(texture->GetSize())); |
| texture_contents->SetTexture(texture); |
| texture_contents->SetDestinationRect(Rect::MakeXYWH( |
| 50, 40, texture->GetSize().width, texture->GetSize().height)); |
| |
| fml::StatusOr<Scalar> sigma_radius_1 = |
| CalculateSigmaForBlurRadius(1.0, effect_transform); |
| ASSERT_TRUE(sigma_radius_1.ok()); |
| auto contents = std::make_unique<GaussianBlurFilterContents>( |
| sigma_radius_1.value(), sigma_radius_1.value(), Entity::TileMode::kDecal, |
| FilterContents::BlurStyle::kNormal, /*mask_geometry=*/nullptr); |
| contents->SetInputs({FilterInput::Make(texture_contents)}); |
| contents->SetEffectTransform(effect_transform); |
| std::shared_ptr<ContentContext> renderer = GetContentContext(); |
| |
| Entity entity; |
| std::optional<Entity> result = |
| contents->GetEntity(*renderer, entity, /*coverage_hint=*/{}); |
| EXPECT_TRUE(result.has_value()); |
| if (result.has_value()) { |
| EXPECT_EQ(result.value().GetBlendMode(), BlendMode::kSourceOver); |
| std::optional<Rect> result_coverage = result.value().GetCoverage(); |
| std::optional<Rect> contents_coverage = contents->GetCoverage(entity); |
| EXPECT_TRUE(result_coverage.has_value()); |
| EXPECT_TRUE(contents_coverage.has_value()); |
| if (result_coverage.has_value() && contents_coverage.has_value()) { |
| EXPECT_TRUE(RectNear(result_coverage.value(), contents_coverage.value())); |
| EXPECT_TRUE(RectNear(contents_coverage.value(), |
| Rect::MakeXYWH(49.f, 39.f, 102.f, 102.f))); |
| } |
| } |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, CalculateSigmaForBlurRadius) { |
| Scalar sigma = 1.0; |
| Scalar radius = GaussianBlurFilterContents::CalculateBlurRadius( |
| GaussianBlurFilterContents::ScaleSigma(sigma)); |
| fml::StatusOr<Scalar> derived_sigma = |
| CalculateSigmaForBlurRadius(radius, Matrix()); |
| ASSERT_TRUE(derived_sigma.ok()); |
| EXPECT_NEAR(sigma, derived_sigma.value(), 0.01f); |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, Coefficients) { |
| BlurParameters parameters = {.blur_uv_offset = Point(1, 0), |
| .blur_sigma = 1, |
| .blur_radius = 5, |
| .step_size = 1}; |
| KernelPipeline::FragmentShader::KernelSamples samples = |
| GenerateBlurInfo(parameters); |
| EXPECT_EQ(samples.sample_count, 9); |
| |
| // Coefficients should add up to 1. |
| Scalar tally = 0; |
| for (int i = 0; i < samples.sample_count; ++i) { |
| tally += samples.samples[i].coefficient; |
| } |
| EXPECT_FLOAT_EQ(tally, 1.0f); |
| |
| // Verify the shape of the curve. |
| for (int i = 0; i < 4; ++i) { |
| EXPECT_FLOAT_EQ(samples.samples[i].coefficient, |
| samples.samples[8 - i].coefficient); |
| EXPECT_TRUE(samples.samples[i + 1].coefficient > |
| samples.samples[i].coefficient); |
| } |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, LerpHackKernelSamplesSimple) { |
| KernelPipeline::FragmentShader::KernelSamples kernel_samples = { |
| .sample_count = 5, |
| .samples = |
| { |
| { |
| .uv_offset = Vector2(-2, 0), |
| .coefficient = 0.1f, |
| }, |
| { |
| .uv_offset = Vector2(-1, 0), |
| .coefficient = 0.2f, |
| }, |
| { |
| .uv_offset = Vector2(0, 0), |
| .coefficient = 0.4f, |
| }, |
| { |
| .uv_offset = Vector2(1, 0), |
| .coefficient = 0.2f, |
| }, |
| { |
| .uv_offset = Vector2(2, 0), |
| .coefficient = 0.1f, |
| }, |
| }, |
| }; |
| |
| KernelPipeline::FragmentShader::KernelSamples fast_kernel_samples = |
| LerpHackKernelSamples(kernel_samples); |
| EXPECT_EQ(fast_kernel_samples.sample_count, 3); |
| |
| KernelPipeline::FragmentShader::KernelSample* samples = |
| kernel_samples.samples; |
| KernelPipeline::FragmentShader::KernelSample* fast_samples = |
| fast_kernel_samples.samples; |
| |
| ////////////////////////////////////////////////////////////////////////////// |
| // Check output kernel. |
| |
| EXPECT_FLOAT_EQ(fast_samples[0].uv_offset.x, -1.3333333); |
| EXPECT_FLOAT_EQ(fast_samples[0].uv_offset.y, 0); |
| EXPECT_FLOAT_EQ(fast_samples[0].coefficient, 0.3); |
| EXPECT_FLOAT_EQ(fast_samples[1].uv_offset.x, 0); |
| EXPECT_FLOAT_EQ(fast_samples[1].uv_offset.y, 0); |
| EXPECT_FLOAT_EQ(fast_samples[1].coefficient, 0.4); |
| EXPECT_FLOAT_EQ(fast_samples[2].uv_offset.x, 1.3333333); |
| EXPECT_FLOAT_EQ(fast_samples[2].uv_offset.y, 0); |
| EXPECT_FLOAT_EQ(fast_samples[2].coefficient, 0.3); |
| |
| ////////////////////////////////////////////////////////////////////////////// |
| // Check output of fast kernel versus original kernel. |
| |
| Scalar data[5] = {0.25, 0.5, 0.5, 1.0, 0.2}; |
| Scalar original_output = |
| samples[0].coefficient * data[0] + samples[1].coefficient * data[1] + |
| samples[2].coefficient * data[2] + samples[3].coefficient * data[3] + |
| samples[4].coefficient * data[4]; |
| |
| auto lerp = [](const Point& point, Scalar left, Scalar right) { |
| Scalar int_part; |
| Scalar fract = fabsf(modf(point.x, &int_part)); |
| if (point.x < 0) { |
| return left * fract + right * (1.0 - fract); |
| } else { |
| return left * (1.0 - fract) + right * fract; |
| } |
| }; |
| Scalar fast_output = |
| /*1st*/ lerp(fast_samples[0].uv_offset, data[0], data[1]) * |
| fast_samples[0].coefficient + |
| /*2nd*/ data[2] * fast_samples[1].coefficient + |
| /*3rd*/ lerp(fast_samples[2].uv_offset, data[3], data[4]) * |
| fast_samples[2].coefficient; |
| |
| EXPECT_NEAR(original_output, fast_output, 0.01); |
| } |
| |
| TEST(GaussianBlurFilterContentsTest, LerpHackKernelSamplesComplex) { |
| Scalar sigma = 10.0f; |
| int32_t blur_radius = static_cast<int32_t>( |
| std::ceil(GaussianBlurFilterContents::CalculateBlurRadius(sigma))); |
| BlurParameters parameters = {.blur_uv_offset = Point(1, 0), |
| .blur_sigma = sigma, |
| .blur_radius = blur_radius, |
| .step_size = 1}; |
| KernelPipeline::FragmentShader::KernelSamples kernel_samples = |
| GenerateBlurInfo(parameters); |
| EXPECT_EQ(kernel_samples.sample_count, 33); |
| KernelPipeline::FragmentShader::KernelSamples fast_kernel_samples = |
| LerpHackKernelSamples(kernel_samples); |
| EXPECT_EQ(fast_kernel_samples.sample_count, 17); |
| float data[33]; |
| srand(0); |
| for (int i = 0; i < 33; i++) { |
| data[i] = 255.0 * static_cast<double>(IMPELLER_RAND()) / RAND_MAX; |
| } |
| |
| auto sampler = [data](Point point) -> Scalar { |
| FML_CHECK(point.y == 0.0f); |
| FML_CHECK(point.x >= -16); |
| FML_CHECK(point.x <= 16); |
| Scalar fint_part; |
| Scalar fract = fabsf(modf(point.x, &fint_part)); |
| if (fract == 0) { |
| int32_t int_part = static_cast<int32_t>(fint_part) + 16; |
| return data[int_part]; |
| } else { |
| int32_t left = static_cast<int32_t>(floor(point.x)) + 16; |
| int32_t right = static_cast<int32_t>(ceil(point.x)) + 16; |
| if (point.x < 0) { |
| return fract * data[left] + (1.0 - fract) * data[right]; |
| } else { |
| return (1.0 - fract) * data[left] + fract * data[right]; |
| } |
| } |
| }; |
| |
| Scalar output = 0.0; |
| for (int i = 0; i < kernel_samples.sample_count; ++i) { |
| auto sample = kernel_samples.samples[i]; |
| output += sample.coefficient * sampler(sample.uv_offset); |
| } |
| |
| Scalar fast_output = 0.0; |
| for (int i = 0; i < fast_kernel_samples.sample_count; ++i) { |
| auto sample = fast_kernel_samples.samples[i]; |
| fast_output += sample.coefficient * sampler(sample.uv_offset); |
| } |
| |
| EXPECT_NEAR(output, fast_output, 0.1); |
| } |
| |
| } // namespace testing |
| } // namespace impeller |