third_party/skia/src/gpu/ccpr/GrCCConicShader.cpp - cobalt - Git at Google

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/ccpr/GrCCConicShader.h"

 #include "src/gpu/glsl/GrGLSLFragmentShaderBuilder.h"
 #include "src/gpu/glsl/GrGLSLVertexGeoBuilder.h"

 void GrCCConicShader::emitSetupCode(
         GrGLSLVertexGeoBuilder* s, const char* pts, const char** outHull4) const {
     // K is distance from the line P2 -> P0. L is distance from the line P0 -> P1, scaled by 2w.
     // M is distance from the line P1 -> P2, scaled by 2w. We do this in a space where P1=0.
     s->declareGlobal(fKLMMatrix);
     s->codeAppendf("float x0 = %s[0].x - %s[1].x, x2 = %s[2].x - %s[1].x;", pts, pts, pts, pts);
     s->codeAppendf("float y0 = %s[0].y - %s[1].y, y2 = %s[2].y - %s[1].y;", pts, pts, pts, pts);
     s->codeAppendf("float w = %s[3].x;", pts);
     s->codeAppendf("%s = float3x3(y2 - y0, x0 - x2, x2*y0 - x0*y2, "
                                  "2*w * float2(+y0, -x0), 0, "
                                  "2*w * float2(-y2, +x2), 0);", fKLMMatrix.c_str());

     s->declareGlobal(fControlPoint);
     s->codeAppendf("%s = %s[1];", fControlPoint.c_str(), pts);

     // Scale KLM by the inverse Manhattan width of K, and make sure K is positive. This allows K to
     // double as the flat opposite edge AA. kwidth will not be 0 because we cull degenerate conics
     // on the CPU.
     s->codeAppendf("float kwidth = 2*bloat * (abs(%s[0].x) + abs(%s[0].y)) * sign(%s[0].z);",
                    fKLMMatrix.c_str(), fKLMMatrix.c_str(), fKLMMatrix.c_str());
     s->codeAppendf("%s *= 1/kwidth;", fKLMMatrix.c_str());

     if (outHull4) {
         // Clip the conic triangle by the tangent line at maximum height. Conics have the nice
         // property that maximum height always occurs at T=.5. This is a simple application for
         // De Casteljau's algorithm.
         s->codeAppendf("float2 p1w = %s[1]*w;", pts);
         s->codeAppend ("float r = 1 / (1 + w);");
         s->codeAppend ("float2 conic_hull[4];");
         s->codeAppendf("conic_hull[0] = %s[0];", pts);
         s->codeAppendf("conic_hull[1] = (%s[0] + p1w) * r;", pts);
         s->codeAppendf("conic_hull[2] = (p1w + %s[2]) * r;", pts);
         s->codeAppendf("conic_hull[3] = %s[2];", pts);
         *outHull4 = "conic_hull";
     }
 }

 void GrCCConicShader::onEmitVaryings(
         GrGLSLVaryingHandler* varyingHandler, GrGLSLVarying::Scope scope, SkString* code,
         const char* position, const char* coverage, const char* cornerCoverage, const char* wind) {
     code->appendf("float3 klm = float3(%s - %s, 1) * %s;",
                   position, fControlPoint.c_str(), fKLMMatrix.c_str());
     if (coverage) {
         fKLM_fWind.reset(kFloat4_GrSLType, scope);
         varyingHandler->addVarying("klm_and_wind", &fKLM_fWind);
         code->appendf("%s.w = %s;", OutName(fKLM_fWind), wind);
     } else {
         fKLM_fWind.reset(kFloat3_GrSLType, scope);
         varyingHandler->addVarying("klm", &fKLM_fWind);
     }
     code->appendf("%s.xyz = klm;", OutName(fKLM_fWind));

     fGrad_fCorner.reset(cornerCoverage ? kFloat4_GrSLType : kFloat2_GrSLType, scope);
     varyingHandler->addVarying((cornerCoverage) ? "grad_and_corner" : "grad", &fGrad_fCorner);
     code->appendf("%s.xy = 2*bloat * (float3x2(%s) * float3(2*klm[0], -klm[2], -klm[1]));",
                   OutName(fGrad_fCorner), fKLMMatrix.c_str());

     if (cornerCoverage) {
         SkASSERT(coverage);
         code->appendf("half hull_coverage;");
         this->calcHullCoverage(code, "klm", OutName(fGrad_fCorner), "hull_coverage");
         code->appendf("%s.zw = half2(hull_coverage, 1) * %s;",
                       OutName(fGrad_fCorner), cornerCoverage);
     }
 }

 void GrCCConicShader::emitFragmentCoverageCode(
         GrGLSLFPFragmentBuilder* f, const char* outputCoverage) const {
     this->calcHullCoverage(&AccessCodeString(f), fKLM_fWind.fsIn(), fGrad_fCorner.fsIn(),
                            outputCoverage);
     f->codeAppendf("%s *= half(%s.w);", outputCoverage, fKLM_fWind.fsIn());  // Wind.

     if (kFloat4_GrSLType == fGrad_fCorner.type()) {
         f->codeAppendf("%s = fma(half(%s.z), half(%s.w), %s);",  // Attenuated corner coverage.
                        outputCoverage, fGrad_fCorner.fsIn(), fGrad_fCorner.fsIn(),
                        outputCoverage);
     }
 }

 void GrCCConicShader::calcHullCoverage(SkString* code, const char* klm, const char* grad,
                                        const char* outputCoverage) const {
     code->appendf("float k = %s.x, l = %s.y, m = %s.z;", klm, klm, klm);
     code->append ("float f = k*k - l*m;");
     code->appendf("float fwidth = abs(%s.x) + abs(%s.y);", grad, grad);
     code->appendf("float curve_coverage = min(0.5 - f/fwidth, 1);");
     // K doubles as the flat opposite edge's AA.
     code->append ("float edge_coverage = min(k - 0.5, 0);");
     // Total hull coverage.
     code->appendf("%s = max(half(curve_coverage + edge_coverage), 0);", outputCoverage);
 }

 void GrCCConicShader::emitSampleMaskCode(GrGLSLFPFragmentBuilder* f) const {
     f->codeAppendf("float k = %s.x, l = %s.y, m = %s.z;",
                    fKLM_fWind.fsIn(), fKLM_fWind.fsIn(), fKLM_fWind.fsIn());
     f->codeAppendf("float f = k*k - l*m;");
     f->codeAppendf("float2 grad = %s;", fGrad_fCorner.fsIn());
     f->applyFnToMultisampleMask("f", "grad", GrGLSLFPFragmentBuilder::ScopeFlags::kTopLevel);
 }
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/ccpr/GrCCConicShader.h"

	#include "src/gpu/glsl/GrGLSLFragmentShaderBuilder.h"
	#include "src/gpu/glsl/GrGLSLVertexGeoBuilder.h"

	void GrCCConicShader::emitSetupCode(
	GrGLSLVertexGeoBuilder* s, const char* pts, const char** outHull4) const {
	// K is distance from the line P2 -> P0. L is distance from the line P0 -> P1, scaled by 2w.
	// M is distance from the line P1 -> P2, scaled by 2w. We do this in a space where P1=0.
	s->declareGlobal(fKLMMatrix);
	s->codeAppendf("float x0 = %s[0].x - %s[1].x, x2 = %s[2].x - %s[1].x;", pts, pts, pts, pts);
	s->codeAppendf("float y0 = %s[0].y - %s[1].y, y2 = %s[2].y - %s[1].y;", pts, pts, pts, pts);
	s->codeAppendf("float w = %s[3].x;", pts);
	s->codeAppendf("%s = float3x3(y2 - y0, x0 - x2, x2y0 - x0y2, "
	"2w float2(+y0, -x0), 0, "
	"2w float2(-y2, +x2), 0);", fKLMMatrix.c_str());

	s->declareGlobal(fControlPoint);
	s->codeAppendf("%s = %s[1];", fControlPoint.c_str(), pts);

	// Scale KLM by the inverse Manhattan width of K, and make sure K is positive. This allows K to
	// double as the flat opposite edge AA. kwidth will not be 0 because we cull degenerate conics
	// on the CPU.
	s->codeAppendf("float kwidth = 2bloat (abs(%s[0].x) + abs(%s[0].y)) * sign(%s[0].z);",
	fKLMMatrix.c_str(), fKLMMatrix.c_str(), fKLMMatrix.c_str());
	s->codeAppendf("%s *= 1/kwidth;", fKLMMatrix.c_str());

	if (outHull4) {
	// Clip the conic triangle by the tangent line at maximum height. Conics have the nice
	// property that maximum height always occurs at T=.5. This is a simple application for
	// De Casteljau's algorithm.
	s->codeAppendf("float2 p1w = %s[1]*w;", pts);
	s->codeAppend ("float r = 1 / (1 + w);");
	s->codeAppend ("float2 conic_hull[4];");
	s->codeAppendf("conic_hull[0] = %s[0];", pts);
	s->codeAppendf("conic_hull[1] = (%s[0] + p1w) * r;", pts);
	s->codeAppendf("conic_hull[2] = (p1w + %s[2]) * r;", pts);
	s->codeAppendf("conic_hull[3] = %s[2];", pts);
	*outHull4 = "conic_hull";
	}
	}

	void GrCCConicShader::onEmitVaryings(
	GrGLSLVaryingHandler* varyingHandler, GrGLSLVarying::Scope scope, SkString* code,
	const char* position, const char* coverage, const char* cornerCoverage, const char* wind) {
	code->appendf("float3 klm = float3(%s - %s, 1) * %s;",
	position, fControlPoint.c_str(), fKLMMatrix.c_str());
	if (coverage) {
	fKLM_fWind.reset(kFloat4_GrSLType, scope);
	varyingHandler->addVarying("klm_and_wind", &fKLM_fWind);
	code->appendf("%s.w = %s;", OutName(fKLM_fWind), wind);
	} else {
	fKLM_fWind.reset(kFloat3_GrSLType, scope);
	varyingHandler->addVarying("klm", &fKLM_fWind);
	}
	code->appendf("%s.xyz = klm;", OutName(fKLM_fWind));

	fGrad_fCorner.reset(cornerCoverage ? kFloat4_GrSLType : kFloat2_GrSLType, scope);
	varyingHandler->addVarying((cornerCoverage) ? "grad_and_corner" : "grad", &fGrad_fCorner);
	code->appendf("%s.xy = 2bloat (float3x2(%s) * float3(2*klm[0], -klm[2], -klm[1]));",
	OutName(fGrad_fCorner), fKLMMatrix.c_str());

	if (cornerCoverage) {
	SkASSERT(coverage);
	code->appendf("half hull_coverage;");
	this->calcHullCoverage(code, "klm", OutName(fGrad_fCorner), "hull_coverage");
	code->appendf("%s.zw = half2(hull_coverage, 1) * %s;",
	OutName(fGrad_fCorner), cornerCoverage);
	}
	}

	void GrCCConicShader::emitFragmentCoverageCode(
	GrGLSLFPFragmentBuilder* f, const char* outputCoverage) const {
	this->calcHullCoverage(&AccessCodeString(f), fKLM_fWind.fsIn(), fGrad_fCorner.fsIn(),
	outputCoverage);
	f->codeAppendf("%s *= half(%s.w);", outputCoverage, fKLM_fWind.fsIn()); // Wind.

	if (kFloat4_GrSLType == fGrad_fCorner.type()) {
	f->codeAppendf("%s = fma(half(%s.z), half(%s.w), %s);", // Attenuated corner coverage.
	outputCoverage, fGrad_fCorner.fsIn(), fGrad_fCorner.fsIn(),
	outputCoverage);
	}
	}

	void GrCCConicShader::calcHullCoverage(SkString* code, const char* klm, const char* grad,
	const char* outputCoverage) const {
	code->appendf("float k = %s.x, l = %s.y, m = %s.z;", klm, klm, klm);
	code->append ("float f = kk - lm;");
	code->appendf("float fwidth = abs(%s.x) + abs(%s.y);", grad, grad);
	code->appendf("float curve_coverage = min(0.5 - f/fwidth, 1);");
	// K doubles as the flat opposite edge's AA.
	code->append ("float edge_coverage = min(k - 0.5, 0);");
	// Total hull coverage.
	code->appendf("%s = max(half(curve_coverage + edge_coverage), 0);", outputCoverage);
	}

	void GrCCConicShader::emitSampleMaskCode(GrGLSLFPFragmentBuilder* f) const {
	f->codeAppendf("float k = %s.x, l = %s.y, m = %s.z;",
	fKLM_fWind.fsIn(), fKLM_fWind.fsIn(), fKLM_fWind.fsIn());
	f->codeAppendf("float f = kk - lm;");
	f->codeAppendf("float2 grad = %s;", fGrad_fCorner.fsIn());
	f->applyFnToMultisampleMask("f", "grad", GrGLSLFPFragmentBuilder::ScopeFlags::kTopLevel);
	}