| /* |
| * Copyright 2015 Google Inc. |
| * |
| * Use of this source code is governed by a BSD-style license that can be |
| * found in the LICENSE file. |
| */ |
| |
| #include "GrCircleBlurFragmentProcessor.h" |
| |
| #if SK_SUPPORT_GPU |
| |
| #include "GrContext.h" |
| #include "GrInvariantOutput.h" |
| #include "GrTextureProvider.h" |
| |
| #include "glsl/GrGLSLFragmentProcessor.h" |
| #include "glsl/GrGLSLFragmentShaderBuilder.h" |
| #include "glsl/GrGLSLProgramDataManager.h" |
| #include "glsl/GrGLSLUniformHandler.h" |
| |
| #include "SkFixed.h" |
| |
| class GrCircleBlurFragmentProcessor::GLSLProcessor : public GrGLSLFragmentProcessor { |
| public: |
| void emitCode(EmitArgs&) override; |
| |
| protected: |
| void onSetData(const GrGLSLProgramDataManager&, const GrProcessor&) override; |
| |
| private: |
| GrGLSLProgramDataManager::UniformHandle fDataUniform; |
| |
| typedef GrGLSLFragmentProcessor INHERITED; |
| }; |
| |
| void GrCircleBlurFragmentProcessor::GLSLProcessor::emitCode(EmitArgs& args) { |
| const char *dataName; |
| |
| // The data is formatted as: |
| // x,y - the center of the circle |
| // z - inner radius that should map to 0th entry in the texture. |
| // w - the inverse of the distance over which the texture is stretched. |
| fDataUniform = args.fUniformHandler->addUniform(kFragment_GrShaderFlag, |
| kVec4f_GrSLType, |
| kDefault_GrSLPrecision, |
| "data", |
| &dataName); |
| |
| GrGLSLFPFragmentBuilder* fragBuilder = args.fFragBuilder; |
| |
| if (args.fInputColor) { |
| fragBuilder->codeAppendf("vec4 src=%s;", args.fInputColor); |
| } else { |
| fragBuilder->codeAppendf("vec4 src=vec4(1);"); |
| } |
| |
| // We just want to compute "(length(vec) - %s.z + 0.5) * %s.w" but need to rearrange |
| // for precision. |
| fragBuilder->codeAppendf("vec2 vec = vec2( (sk_FragCoord.x - %s.x) * %s.w, " |
| "(sk_FragCoord.y - %s.y) * %s.w );", |
| dataName, dataName, dataName, dataName); |
| fragBuilder->codeAppendf("float dist = length(vec) + (0.5 - %s.z) * %s.w;", |
| dataName, dataName); |
| |
| fragBuilder->codeAppendf("float intensity = "); |
| fragBuilder->appendTextureLookup(args.fTexSamplers[0], "vec2(dist, 0.5)"); |
| fragBuilder->codeAppend(".a;"); |
| |
| fragBuilder->codeAppendf("%s = src * intensity;\n", args.fOutputColor ); |
| } |
| |
| void GrCircleBlurFragmentProcessor::GLSLProcessor::onSetData(const GrGLSLProgramDataManager& pdman, |
| const GrProcessor& proc) { |
| const GrCircleBlurFragmentProcessor& cbfp = proc.cast<GrCircleBlurFragmentProcessor>(); |
| const SkRect& circle = cbfp.fCircle; |
| |
| // The data is formatted as: |
| // x,y - the center of the circle |
| // z - inner radius that should map to 0th entry in the texture. |
| // w - the inverse of the distance over which the profile texture is stretched. |
| pdman.set4f(fDataUniform, circle.centerX(), circle.centerY(), cbfp.fSolidRadius, |
| 1.f / cbfp.fTextureRadius); |
| } |
| |
| /////////////////////////////////////////////////////////////////////////////// |
| |
| GrCircleBlurFragmentProcessor::GrCircleBlurFragmentProcessor(const SkRect& circle, |
| float textureRadius, |
| float solidRadius, |
| GrTexture* blurProfile) |
| : fCircle(circle) |
| , fSolidRadius(solidRadius) |
| , fTextureRadius(textureRadius) |
| , fBlurProfileSampler(blurProfile, GrSamplerParams::kBilerp_FilterMode) { |
| this->initClassID<GrCircleBlurFragmentProcessor>(); |
| this->addTextureSampler(&fBlurProfileSampler); |
| } |
| |
| GrGLSLFragmentProcessor* GrCircleBlurFragmentProcessor::onCreateGLSLInstance() const { |
| return new GLSLProcessor; |
| } |
| |
| void GrCircleBlurFragmentProcessor::onGetGLSLProcessorKey(const GrShaderCaps& caps, |
| GrProcessorKeyBuilder* b) const { |
| // The code for this processor is always the same so there is nothing to add to the key. |
| return; |
| } |
| |
| void GrCircleBlurFragmentProcessor::onComputeInvariantOutput(GrInvariantOutput* inout) const { |
| inout->mulByUnknownSingleComponent(); |
| } |
| |
| // Computes an unnormalized half kernel (right side). Returns the summation of all the half kernel |
| // values. |
| static float make_unnormalized_half_kernel(float* halfKernel, int halfKernelSize, float sigma) { |
| const float invSigma = 1.f / sigma; |
| const float b = -0.5f * invSigma * invSigma; |
| float tot = 0.0f; |
| // Compute half kernel values at half pixel steps out from the center. |
| float t = 0.5f; |
| for (int i = 0; i < halfKernelSize; ++i) { |
| float value = expf(t * t * b); |
| tot += value; |
| halfKernel[i] = value; |
| t += 1.f; |
| } |
| return tot; |
| } |
| |
| // Create a Gaussian half-kernel (right side) and a summed area table given a sigma and number of |
| // discrete steps. The half kernel is normalized to sum to 0.5. |
| static void make_half_kernel_and_summed_table(float* halfKernel, float* summedHalfKernel, |
| int halfKernelSize, float sigma) { |
| // The half kernel should sum to 0.5 not 1.0. |
| const float tot = 2.f * make_unnormalized_half_kernel(halfKernel, halfKernelSize, sigma); |
| float sum = 0.f; |
| for (int i = 0; i < halfKernelSize; ++i) { |
| halfKernel[i] /= tot; |
| sum += halfKernel[i]; |
| summedHalfKernel[i] = sum; |
| } |
| } |
| |
| // Applies the 1D half kernel vertically at points along the x axis to a circle centered at the |
| // origin with radius circleR. |
| void apply_kernel_in_y(float* results, int numSteps, float firstX, float circleR, |
| int halfKernelSize, const float* summedHalfKernelTable) { |
| float x = firstX; |
| for (int i = 0; i < numSteps; ++i, x += 1.f) { |
| if (x < -circleR || x > circleR) { |
| results[i] = 0; |
| continue; |
| } |
| float y = sqrtf(circleR * circleR - x * x); |
| // In the column at x we exit the circle at +y and -y |
| // The summed table entry j is actually reflects an offset of j + 0.5. |
| y -= 0.5f; |
| int yInt = SkScalarFloorToInt(y); |
| SkASSERT(yInt >= -1); |
| if (y < 0) { |
| results[i] = (y + 0.5f) * summedHalfKernelTable[0]; |
| } else if (yInt >= halfKernelSize - 1) { |
| results[i] = 0.5f; |
| } else { |
| float yFrac = y - yInt; |
| results[i] = (1.f - yFrac) * summedHalfKernelTable[yInt] + |
| yFrac * summedHalfKernelTable[yInt + 1]; |
| } |
| } |
| } |
| |
| // Apply a Gaussian at point (evalX, 0) to a circle centered at the origin with radius circleR. |
| // This relies on having a half kernel computed for the Gaussian and a table of applications of |
| // the half kernel in y to columns at (evalX - halfKernel, evalX - halfKernel + 1, ..., evalX + |
| // halfKernel) passed in as yKernelEvaluations. |
| static uint8_t eval_at(float evalX, float circleR, const float* halfKernel, int halfKernelSize, |
| const float* yKernelEvaluations) { |
| float acc = 0; |
| |
| float x = evalX - halfKernelSize; |
| for (int i = 0; i < halfKernelSize; ++i, x += 1.f) { |
| if (x < -circleR || x > circleR) { |
| continue; |
| } |
| float verticalEval = yKernelEvaluations[i]; |
| acc += verticalEval * halfKernel[halfKernelSize - i - 1]; |
| } |
| for (int i = 0; i < halfKernelSize; ++i, x += 1.f) { |
| if (x < -circleR || x > circleR) { |
| continue; |
| } |
| float verticalEval = yKernelEvaluations[i + halfKernelSize]; |
| acc += verticalEval * halfKernel[i]; |
| } |
| // Since we applied a half kernel in y we multiply acc by 2 (the circle is symmetric about the |
| // x axis). |
| return SkUnitScalarClampToByte(2.f * acc); |
| } |
| |
| // This function creates a profile of a blurred circle. It does this by computing a kernel for |
| // half the Gaussian and a matching summed area table. The summed area table is used to compute |
| // an array of vertical applications of the half kernel to the circle along the x axis. The table |
| // of y evaluations has 2 * k + n entries where k is the size of the half kernel and n is the size |
| // of the profile being computed. Then for each of the n profile entries we walk out k steps in each |
| // horizontal direction multiplying the corresponding y evaluation by the half kernel entry and |
| // sum these values to compute the profile entry. |
| static uint8_t* create_circle_profile(float sigma, float circleR, int profileTextureWidth) { |
| const int numSteps = profileTextureWidth; |
| uint8_t* weights = new uint8_t[numSteps]; |
| |
| // The full kernel is 6 sigmas wide. |
| int halfKernelSize = SkScalarCeilToInt(6.0f*sigma); |
| // round up to next multiple of 2 and then divide by 2 |
| halfKernelSize = ((halfKernelSize + 1) & ~1) >> 1; |
| |
| // Number of x steps at which to apply kernel in y to cover all the profile samples in x. |
| int numYSteps = numSteps + 2 * halfKernelSize; |
| |
| SkAutoTArray<float> bulkAlloc(halfKernelSize + halfKernelSize + numYSteps); |
| float* halfKernel = bulkAlloc.get(); |
| float* summedKernel = bulkAlloc.get() + halfKernelSize; |
| float* yEvals = bulkAlloc.get() + 2 * halfKernelSize; |
| make_half_kernel_and_summed_table(halfKernel, summedKernel, halfKernelSize, sigma); |
| |
| float firstX = -halfKernelSize + 0.5f; |
| apply_kernel_in_y(yEvals, numYSteps, firstX, circleR, halfKernelSize, summedKernel); |
| |
| for (int i = 0; i < numSteps - 1; ++i) { |
| float evalX = i + 0.5f; |
| weights[i] = eval_at(evalX, circleR, halfKernel, halfKernelSize, yEvals + i); |
| } |
| // Ensure the tail of the Gaussian goes to zero. |
| weights[numSteps - 1] = 0; |
| return weights; |
| } |
| |
| static uint8_t* create_half_plane_profile(int profileWidth) { |
| SkASSERT(!(profileWidth & 0x1)); |
| // The full kernel is 6 sigmas wide. |
| float sigma = profileWidth / 6.f; |
| int halfKernelSize = profileWidth / 2; |
| |
| SkAutoTArray<float> halfKernel(halfKernelSize); |
| uint8_t* profile = new uint8_t[profileWidth]; |
| |
| // The half kernel should sum to 0.5. |
| const float tot = 2.f * make_unnormalized_half_kernel(halfKernel.get(), halfKernelSize, sigma); |
| float sum = 0.f; |
| // Populate the profile from the right edge to the middle. |
| for (int i = 0; i < halfKernelSize; ++i) { |
| halfKernel[halfKernelSize - i - 1] /= tot; |
| sum += halfKernel[halfKernelSize - i - 1]; |
| profile[profileWidth - i - 1] = SkUnitScalarClampToByte(sum); |
| } |
| // Populate the profile from the middle to the left edge (by flipping the half kernel and |
| // continuing the summation). |
| for (int i = 0; i < halfKernelSize; ++i) { |
| sum += halfKernel[i]; |
| profile[halfKernelSize - i - 1] = SkUnitScalarClampToByte(sum); |
| } |
| // Ensure tail goes to 0. |
| profile[profileWidth - 1] = 0; |
| return profile; |
| } |
| |
| static GrTexture* create_profile_texture(GrTextureProvider* textureProvider, const SkRect& circle, |
| float sigma, float* solidRadius, float* textureRadius) { |
| float circleR = circle.width() / 2.0f; |
| // Profile textures are cached by the ratio of sigma to circle radius and by the size of the |
| // profile texture (binned by powers of 2). |
| SkScalar sigmaToCircleRRatio = sigma / circleR; |
| // When sigma is really small this becomes a equivalent to convolving a Gaussian with a half- |
| // plane. Similarly, in the extreme high ratio cases circle becomes a point WRT to the Guassian |
| // and the profile texture is a just a Gaussian evaluation. However, we haven't yet implemented |
| // this latter optimization. |
| sigmaToCircleRRatio = SkTMin(sigmaToCircleRRatio, 8.f); |
| SkFixed sigmaToCircleRRatioFixed; |
| static const SkScalar kHalfPlaneThreshold = 0.1f; |
| bool useHalfPlaneApprox = false; |
| if (sigmaToCircleRRatio <= kHalfPlaneThreshold) { |
| useHalfPlaneApprox = true; |
| sigmaToCircleRRatioFixed = 0; |
| *solidRadius = circleR - 3 * sigma; |
| *textureRadius = 6 * sigma; |
| } else { |
| // Convert to fixed point for the key. |
| sigmaToCircleRRatioFixed = SkScalarToFixed(sigmaToCircleRRatio); |
| // We shave off some bits to reduce the number of unique entries. We could probably shave |
| // off more than we do. |
| sigmaToCircleRRatioFixed &= ~0xff; |
| sigmaToCircleRRatio = SkFixedToScalar(sigmaToCircleRRatioFixed); |
| sigma = circleR * sigmaToCircleRRatio; |
| *solidRadius = 0; |
| *textureRadius = circleR + 3 * sigma; |
| } |
| |
| static const GrUniqueKey::Domain kDomain = GrUniqueKey::GenerateDomain(); |
| GrUniqueKey key; |
| GrUniqueKey::Builder builder(&key, kDomain, 1); |
| builder[0] = sigmaToCircleRRatioFixed; |
| builder.finish(); |
| |
| GrTexture *blurProfile = textureProvider->findAndRefTextureByUniqueKey(key); |
| if (!blurProfile) { |
| static constexpr int kProfileTextureWidth = 512; |
| GrSurfaceDesc texDesc; |
| texDesc.fWidth = kProfileTextureWidth; |
| texDesc.fHeight = 1; |
| texDesc.fConfig = kAlpha_8_GrPixelConfig; |
| |
| std::unique_ptr<uint8_t[]> profile(nullptr); |
| if (useHalfPlaneApprox) { |
| profile.reset(create_half_plane_profile(kProfileTextureWidth)); |
| } else { |
| // Rescale params to the size of the texture we're creating. |
| SkScalar scale = kProfileTextureWidth / *textureRadius; |
| profile.reset(create_circle_profile(sigma * scale, circleR * scale, |
| kProfileTextureWidth)); |
| } |
| |
| blurProfile = textureProvider->createTexture(texDesc, SkBudgeted::kYes, profile.get(), 0); |
| if (blurProfile) { |
| textureProvider->assignUniqueKeyToTexture(key, blurProfile); |
| } |
| } |
| |
| return blurProfile; |
| } |
| |
| ////////////////////////////////////////////////////////////////////////////// |
| |
| sk_sp<GrFragmentProcessor> GrCircleBlurFragmentProcessor::Make(GrTextureProvider*textureProvider, |
| const SkRect& circle, float sigma) { |
| float solidRadius; |
| float textureRadius; |
| sk_sp<GrTexture> profile(create_profile_texture(textureProvider, circle, sigma, |
| &solidRadius, &textureRadius)); |
| if (!profile) { |
| return nullptr; |
| } |
| return sk_sp<GrFragmentProcessor>( |
| new GrCircleBlurFragmentProcessor(circle, textureRadius, solidRadius, profile.get())); |
| } |
| |
| ////////////////////////////////////////////////////////////////////////////// |
| |
| GR_DEFINE_FRAGMENT_PROCESSOR_TEST(GrCircleBlurFragmentProcessor); |
| |
| sk_sp<GrFragmentProcessor> GrCircleBlurFragmentProcessor::TestCreate(GrProcessorTestData* d) { |
| SkScalar wh = d->fRandom->nextRangeScalar(100.f, 1000.f); |
| SkScalar sigma = d->fRandom->nextRangeF(1.f,10.f); |
| SkRect circle = SkRect::MakeWH(wh, wh); |
| return GrCircleBlurFragmentProcessor::Make(d->fContext->textureProvider(), circle, sigma); |
| } |
| |
| #endif |