src/gpu/ccpr/GrCCCubicShader.cpp - skia - Git at Google

 /*
  * Copyright 2017 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/GrCCCubicShader.h"

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

 using Shader = GrCCCoverageProcessor::Shader;

 void GrCCCubicShader::emitSetupCode(
         GrGLSLVertexGeoBuilder* s, const char* pts, const char** /*outHull4*/) const {
     // Find the cubic's power basis coefficients.
     s->codeAppendf("float2x4 C = float4x4(-1,  3, -3,  1, "
                                          " 3, -6,  3,  0, "
                                          "-3,  3,  0,  0, "
                                          " 1,  0,  0,  0) * transpose(%s);", pts);

     // Find the cubic's inflection function.
     s->codeAppend ("float D3 = +determinant(float2x2(C[0].yz, C[1].yz));");
     s->codeAppend ("float D2 = -determinant(float2x2(C[0].xz, C[1].xz));");
     s->codeAppend ("float D1 = +determinant(float2x2(C));");

     // Shift the exponents in D so the largest magnitude falls somewhere in 1..2. This protects us
     // from overflow while solving for roots and KLM functionals.
     s->codeAppend ("float Dmax = max(max(abs(D1), abs(D2)), abs(D3));");
     s->codeAppend ("float norm;");
     if (s->getProgramBuilder()->shaderCaps()->fpManipulationSupport()) {
         s->codeAppend ("int exp;");
         s->codeAppend ("frexp(Dmax, exp);");
         s->codeAppend ("norm = ldexp(1, 1 - exp);");
     } else {
         s->codeAppend ("norm = 1/Dmax;"); // Dmax will not be 0 because we cull line cubics on CPU.
     }
     s->codeAppend ("D3 *= norm;");
     s->codeAppend ("D2 *= norm;");
     s->codeAppend ("D1 *= norm;");

     // Calculate the KLM matrix.
     s->declareGlobal(fKLMMatrix);
     s->codeAppend ("float discr = 3*D2*D2 - 4*D1*D3;");
     s->codeAppend ("float x = discr >= 0 ? 3 : 1;");
     s->codeAppend ("float q = sqrt(x * abs(discr));");
     s->codeAppend ("q = x*D2 + (D2 >= 0 ? q : -q);");

     s->codeAppend ("float2 l, m;");
     s->codeAppend ("l.ts = float2(q, 2*x * D1);");
     s->codeAppend ("m.ts = float2(2, q) * (discr >= 0 ? float2(D3, 1) "
                                                      ": float2(D2*D2 - D3*D1, D1));");

     s->codeAppend ("float4 K;");
     s->codeAppend ("float4 lm = l.sstt * m.stst;");
     s->codeAppend ("K = float4(0, lm.x, -lm.y - lm.z, lm.w);");

     s->codeAppend ("float4 L, M;");
     s->codeAppend ("lm.yz += 2*lm.zy;");
     s->codeAppend ("L = float4(-1,x,-x,1) * l.sstt * (discr >= 0 ? l.ssst * l.sttt : lm);");
     s->codeAppend ("M = float4(-1,x,-x,1) * m.sstt * (discr >= 0 ? m.ssst * m.sttt : lm.xzyw);");

     s->codeAppend ("int middlerow = abs(D2) > abs(D1) ? 2 : 1;");
     s->codeAppend ("float3x3 CI = inverse(float3x3(C[0][0], C[0][middlerow], C[0][3], "
                                                   "C[1][0], C[1][middlerow], C[1][3], "
                                                   "      0,               0,       1));");
     s->codeAppendf("%s = CI * float3x3(K[0], K[middlerow], K[3], "
                                       "L[0], L[middlerow], L[3], "
                                       "M[0], M[middlerow], M[3]);", fKLMMatrix.c_str());

     // Evaluate the cubic at T=.5 for a mid-ish point.
     s->codeAppendf("float2 midpoint = %s * float4(.125, .375, .375, .125);", pts);

     // Orient the KLM matrix so L & M are both positive on the side of the curve we wish to fill.
     s->codeAppendf("float2 orientation = sign(float3(midpoint, 1) * float2x3(%s[1], %s[2]));",
                    fKLMMatrix.c_str(), fKLMMatrix.c_str());
     s->codeAppendf("%s *= float3x3(orientation[0] * orientation[1], 0, 0, "
                                   "0, orientation[0], 0, "
                                   "0, 0, orientation[1]);", fKLMMatrix.c_str());
 }

 void GrCCCubicShader::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, 1) * %s;", position, fKLMMatrix.c_str());
     if (coverage) {
         fKLM_fEdge.reset(kFloat4_GrSLType, scope);
         varyingHandler->addVarying("klm_and_edge", &fKLM_fEdge);
         // Give L&M both the same sign as wind, in order to pass this value to the fragment shader.
         // (Cubics are pre-chopped such that L&M do not change sign within any individual segment.)
         code->appendf("%s.xyz = klm * float3(1, %s, %s);", OutName(fKLM_fEdge), wind, wind);
         // Flat edge opposite the curve.
         code->appendf("%s.w = %s;", OutName(fKLM_fEdge), coverage);
     } else {
         fKLM_fEdge.reset(kFloat3_GrSLType, scope);
         varyingHandler->addVarying("klm", &fKLM_fEdge);
         code->appendf("%s = klm;", OutName(fKLM_fEdge));
     }

     fGradMatrix.reset(kFloat4_GrSLType, scope);
     varyingHandler->addVarying("grad_matrix", &fGradMatrix);
     code->appendf("%s.xy = 2*bloat * 3 * klm[0] * %s[0].xy;",
                   OutName(fGradMatrix), fKLMMatrix.c_str());
     code->appendf("%s.zw = -2*bloat * (klm[1] * %s[2].xy + klm[2] * %s[1].xy);",
                     OutName(fGradMatrix), fKLMMatrix.c_str(), fKLMMatrix.c_str());

     if (cornerCoverage) {
         SkASSERT(coverage);
         code->appendf("half hull_coverage; {");
         this->calcHullCoverage(code, OutName(fKLM_fEdge), OutName(fGradMatrix), "hull_coverage");
         code->appendf("}");
         fCornerCoverage.reset(kHalf2_GrSLType, scope);
         varyingHandler->addVarying("corner_coverage", &fCornerCoverage);
         code->appendf("%s = half2(hull_coverage, 1) * %s;",
                       OutName(fCornerCoverage), cornerCoverage);
     }
 }

 void GrCCCubicShader::emitFragmentCoverageCode(
         GrGLSLFPFragmentBuilder* f, const char* outputCoverage) const {
     this->calcHullCoverage(
             &AccessCodeString(f), fKLM_fEdge.fsIn(), fGradMatrix.fsIn(), outputCoverage);

     // Wind is the sign of both L and/or M. Take the sign of whichever has the larger magnitude.
     // (In reality, either would be fine because we chop cubics with more than a half pixel of
     // padding around the L & M lines, so neither should approach zero.)
     f->codeAppend ("half wind = sign(half(l + m));");
     f->codeAppendf("%s *= wind;", outputCoverage);

     if (fCornerCoverage.fsIn()) {
         f->codeAppendf("%s = %s.x * %s.y + %s;", // Attenuated corner coverage.
                        outputCoverage, fCornerCoverage.fsIn(), fCornerCoverage.fsIn(),
                        outputCoverage);
     }
 }

 void GrCCCubicShader::calcHullCoverage(SkString* code, const char* klmAndEdge,
                                        const char* gradMatrix, const char* outputCoverage) const {
     code->appendf("float k = %s.x, l = %s.y, m = %s.z;", klmAndEdge, klmAndEdge, klmAndEdge);
     code->append ("float f = k*k*k - l*m;");
     code->appendf("float2 grad = %s.xy * k + %s.zw;", gradMatrix, gradMatrix);
     code->append ("float fwidth = abs(grad.x) + abs(grad.y);");
     code->appendf("float curve_coverage = min(0.5 - f/fwidth, 1);");
      // Flat edge opposite the curve.
     code->appendf("float edge_coverage = min(%s.w, 0);", klmAndEdge);
     // Total hull coverage.
     code->appendf("%s = max(half(curve_coverage + edge_coverage), 0);", outputCoverage);
 }

 void GrCCCubicShader::emitSampleMaskCode(GrGLSLFPFragmentBuilder* f) const {
     f->codeAppendf("float k = %s.x, l = %s.y, m = %s.z;",
                    fKLM_fEdge.fsIn(), fKLM_fEdge.fsIn(), fKLM_fEdge.fsIn());
     f->codeAppendf("float f = k*k*k - l*m;");
     f->codeAppendf("float2x2 grad_matrix = float2x2(%s);", fGradMatrix.fsIn());
     f->codeAppendf("float2 grad = grad_matrix * float2(k, 1);");
     f->applyFnToMultisampleMask("f", "grad", GrGLSLFPFragmentBuilder::ScopeFlags::kTopLevel);
 }
	/*
	* Copyright 2017 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/GrCCCubicShader.h"

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

	using Shader = GrCCCoverageProcessor::Shader;

	void GrCCCubicShader::emitSetupCode(
	GrGLSLVertexGeoBuilder* s, const char* pts, const char** /outHull4/) const {
	// Find the cubic's power basis coefficients.
	s->codeAppendf("float2x4 C = float4x4(-1, 3, -3, 1, "
	" 3, -6, 3, 0, "
	"-3, 3, 0, 0, "
	" 1, 0, 0, 0) * transpose(%s);", pts);

	// Find the cubic's inflection function.
	s->codeAppend ("float D3 = +determinant(float2x2(C[0].yz, C[1].yz));");
	s->codeAppend ("float D2 = -determinant(float2x2(C[0].xz, C[1].xz));");
	s->codeAppend ("float D1 = +determinant(float2x2(C));");

	// Shift the exponents in D so the largest magnitude falls somewhere in 1..2. This protects us
	// from overflow while solving for roots and KLM functionals.
	s->codeAppend ("float Dmax = max(max(abs(D1), abs(D2)), abs(D3));");
	s->codeAppend ("float norm;");
	if (s->getProgramBuilder()->shaderCaps()->fpManipulationSupport()) {
	s->codeAppend ("int exp;");
	s->codeAppend ("frexp(Dmax, exp);");
	s->codeAppend ("norm = ldexp(1, 1 - exp);");
	} else {
	s->codeAppend ("norm = 1/Dmax;"); // Dmax will not be 0 because we cull line cubics on CPU.
	}
	s->codeAppend ("D3 *= norm;");
	s->codeAppend ("D2 *= norm;");
	s->codeAppend ("D1 *= norm;");

	// Calculate the KLM matrix.
	s->declareGlobal(fKLMMatrix);
	s->codeAppend ("float discr = 3D2D2 - 4D1D3;");
	s->codeAppend ("float x = discr >= 0 ? 3 : 1;");
	s->codeAppend ("float q = sqrt(x * abs(discr));");
	s->codeAppend ("q = x*D2 + (D2 >= 0 ? q : -q);");

	s->codeAppend ("float2 l, m;");
	s->codeAppend ("l.ts = float2(q, 2x D1);");
	s->codeAppend ("m.ts = float2(2, q) * (discr >= 0 ? float2(D3, 1) "
	": float2(D2D2 - D3D1, D1));");

	s->codeAppend ("float4 K;");
	s->codeAppend ("float4 lm = l.sstt * m.stst;");
	s->codeAppend ("K = float4(0, lm.x, -lm.y - lm.z, lm.w);");

	s->codeAppend ("float4 L, M;");
	s->codeAppend ("lm.yz += 2*lm.zy;");
	s->codeAppend ("L = float4(-1,x,-x,1) * l.sstt * (discr >= 0 ? l.ssst * l.sttt : lm);");
	s->codeAppend ("M = float4(-1,x,-x,1) * m.sstt * (discr >= 0 ? m.ssst * m.sttt : lm.xzyw);");

	s->codeAppend ("int middlerow = abs(D2) > abs(D1) ? 2 : 1;");
	s->codeAppend ("float3x3 CI = inverse(float3x3(C[0][0], C[0][middlerow], C[0][3], "
	"C[1][0], C[1][middlerow], C[1][3], "
	" 0, 0, 1));");
	s->codeAppendf("%s = CI * float3x3(K[0], K[middlerow], K[3], "
	"L[0], L[middlerow], L[3], "
	"M[0], M[middlerow], M[3]);", fKLMMatrix.c_str());

	// Evaluate the cubic at T=.5 for a mid-ish point.
	s->codeAppendf("float2 midpoint = %s * float4(.125, .375, .375, .125);", pts);

	// Orient the KLM matrix so L & M are both positive on the side of the curve we wish to fill.
	s->codeAppendf("float2 orientation = sign(float3(midpoint, 1) * float2x3(%s[1], %s[2]));",
	fKLMMatrix.c_str(), fKLMMatrix.c_str());
	s->codeAppendf("%s = float3x3(orientation[0] orientation[1], 0, 0, "
	"0, orientation[0], 0, "
	"0, 0, orientation[1]);", fKLMMatrix.c_str());
	}

	void GrCCCubicShader::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, 1) * %s;", position, fKLMMatrix.c_str());
	if (coverage) {
	fKLM_fEdge.reset(kFloat4_GrSLType, scope);
	varyingHandler->addVarying("klm_and_edge", &fKLM_fEdge);
	// Give L&M both the same sign as wind, in order to pass this value to the fragment shader.
	// (Cubics are pre-chopped such that L&M do not change sign within any individual segment.)
	code->appendf("%s.xyz = klm * float3(1, %s, %s);", OutName(fKLM_fEdge), wind, wind);
	// Flat edge opposite the curve.
	code->appendf("%s.w = %s;", OutName(fKLM_fEdge), coverage);
	} else {
	fKLM_fEdge.reset(kFloat3_GrSLType, scope);
	varyingHandler->addVarying("klm", &fKLM_fEdge);
	code->appendf("%s = klm;", OutName(fKLM_fEdge));
	}

	fGradMatrix.reset(kFloat4_GrSLType, scope);
	varyingHandler->addVarying("grad_matrix", &fGradMatrix);
	code->appendf("%s.xy = 2bloat 3 * klm[0] * %s[0].xy;",
	OutName(fGradMatrix), fKLMMatrix.c_str());
	code->appendf("%s.zw = -2bloat (klm[1] * %s[2].xy + klm[2] * %s[1].xy);",
	OutName(fGradMatrix), fKLMMatrix.c_str(), fKLMMatrix.c_str());

	if (cornerCoverage) {
	SkASSERT(coverage);
	code->appendf("half hull_coverage; {");
	this->calcHullCoverage(code, OutName(fKLM_fEdge), OutName(fGradMatrix), "hull_coverage");
	code->appendf("}");
	fCornerCoverage.reset(kHalf2_GrSLType, scope);
	varyingHandler->addVarying("corner_coverage", &fCornerCoverage);
	code->appendf("%s = half2(hull_coverage, 1) * %s;",
	OutName(fCornerCoverage), cornerCoverage);
	}
	}

	void GrCCCubicShader::emitFragmentCoverageCode(
	GrGLSLFPFragmentBuilder* f, const char* outputCoverage) const {
	this->calcHullCoverage(
	&AccessCodeString(f), fKLM_fEdge.fsIn(), fGradMatrix.fsIn(), outputCoverage);

	// Wind is the sign of both L and/or M. Take the sign of whichever has the larger magnitude.
	// (In reality, either would be fine because we chop cubics with more than a half pixel of
	// padding around the L & M lines, so neither should approach zero.)
	f->codeAppend ("half wind = sign(half(l + m));");
	f->codeAppendf("%s *= wind;", outputCoverage);

	if (fCornerCoverage.fsIn()) {
	f->codeAppendf("%s = %s.x * %s.y + %s;", // Attenuated corner coverage.
	outputCoverage, fCornerCoverage.fsIn(), fCornerCoverage.fsIn(),
	outputCoverage);
	}
	}

	void GrCCCubicShader::calcHullCoverage(SkString* code, const char* klmAndEdge,
	const char* gradMatrix, const char* outputCoverage) const {
	code->appendf("float k = %s.x, l = %s.y, m = %s.z;", klmAndEdge, klmAndEdge, klmAndEdge);
	code->append ("float f = kkk - l*m;");
	code->appendf("float2 grad = %s.xy * k + %s.zw;", gradMatrix, gradMatrix);
	code->append ("float fwidth = abs(grad.x) + abs(grad.y);");
	code->appendf("float curve_coverage = min(0.5 - f/fwidth, 1);");
	// Flat edge opposite the curve.
	code->appendf("float edge_coverage = min(%s.w, 0);", klmAndEdge);
	// Total hull coverage.
	code->appendf("%s = max(half(curve_coverage + edge_coverage), 0);", outputCoverage);
	}

	void GrCCCubicShader::emitSampleMaskCode(GrGLSLFPFragmentBuilder* f) const {
	f->codeAppendf("float k = %s.x, l = %s.y, m = %s.z;",
	fKLM_fEdge.fsIn(), fKLM_fEdge.fsIn(), fKLM_fEdge.fsIn());
	f->codeAppendf("float f = kkk - l*m;");
	f->codeAppendf("float2x2 grad_matrix = float2x2(%s);", fGradMatrix.fsIn());
	f->codeAppendf("float2 grad = grad_matrix * float2(k, 1);");
	f->applyFnToMultisampleMask("f", "grad", GrGLSLFPFragmentBuilder::ScopeFlags::kTopLevel);
	}