| /* |
| * 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 "GrCCPRCubicProcessor.h" |
| |
| #include "glsl/GrGLSLFragmentShaderBuilder.h" |
| #include "glsl/GrGLSLGeometryShaderBuilder.h" |
| #include "glsl/GrGLSLVertexShaderBuilder.h" |
| |
| void GrCCPRCubicProcessor::onEmitVertexShader(const GrCCPRCoverageProcessor& proc, |
| GrGLSLVertexBuilder* v, |
| const TexelBufferHandle& pointsBuffer, |
| const char* atlasOffset, const char* rtAdjust, |
| GrGPArgs* gpArgs) const { |
| float inset = 1 - kAABloatRadius; |
| #ifdef SK_DEBUG |
| if (proc.debugVisualizations()) { |
| inset *= GrCCPRCoverageProcessor::kDebugBloat; |
| } |
| #endif |
| |
| // Fetch all 4 cubic bezier points. |
| v->codeAppendf("ivec4 indices = ivec4(%s.y, %s.x, %s.x + 1, %s.y + 1);", |
| proc.instanceAttrib(), proc.instanceAttrib(), proc.instanceAttrib(), |
| proc.instanceAttrib()); |
| v->codeAppend ("highp mat4x2 bezierpts = mat4x2("); |
| v->appendTexelFetch(pointsBuffer, "indices[sk_VertexID]"); |
| v->codeAppend (".xy, "); |
| v->appendTexelFetch(pointsBuffer, "indices[(sk_VertexID + 1) % 4]"); |
| v->codeAppend (".xy, "); |
| v->appendTexelFetch(pointsBuffer, "indices[(sk_VertexID + 2) % 4]"); |
| v->codeAppend (".xy, "); |
| v->appendTexelFetch(pointsBuffer, "indices[(sk_VertexID + 3) % 4]"); |
| v->codeAppend (".xy);"); |
| |
| // Find the corner of the inset geometry that corresponds to this bezier vertex (bezierpts[0]). |
| v->codeAppend ("highp mat2 N = mat2(bezierpts[3].y - bezierpts[0].y, " |
| "bezierpts[0].x - bezierpts[3].x, " |
| "bezierpts[1].y - bezierpts[0].y, " |
| "bezierpts[0].x - bezierpts[1].x);"); |
| v->codeAppend ("highp mat2 P = mat2(bezierpts[3], bezierpts[1]);"); |
| v->codeAppend ("if (abs(determinant(N)) < 2) {"); // Area of [pts[3], pts[0], pts[1]] < 1px. |
| // The inset corner doesn't exist because we are effectively colinear with |
| // both neighbor vertices. Just duplicate a neighbor's inset corner. |
| v->codeAppend ( "int smallidx = (dot(N[0], N[0]) > dot(N[1], N[1])) ? 1 : 0;"); |
| v->codeAppend ( "N[smallidx] = vec2(bezierpts[2].y - bezierpts[3 - smallidx * 2].y, " |
| "bezierpts[3 - smallidx * 2].x - bezierpts[2].x);"); |
| v->codeAppend ( "P[smallidx] = bezierpts[2];"); |
| v->codeAppend ("}"); |
| v->codeAppend ("N[0] *= sign(dot(N[0], P[1] - P[0]));"); |
| v->codeAppend ("N[1] *= sign(dot(N[1], P[0] - P[1]));"); |
| |
| v->codeAppendf("highp vec2 K = vec2(dot(N[0], P[0] + %f * sign(N[0])), " |
| "dot(N[1], P[1] + %f * sign(N[1])));", inset, inset); |
| v->codeAppendf("%s.xy = K * inverse(N) + %s;", fInset.vsOut(), atlasOffset); |
| v->codeAppendf("%s.xy = %s.xy * %s.xz + %s.yw;", |
| fInset.vsOut(), fInset.vsOut(), rtAdjust, rtAdjust); |
| |
| // The z component tells the gemetry shader how "sharp" this corner is. |
| v->codeAppendf("%s.z = determinant(N) * sign(%s.x) * sign(%s.z);", |
| fInset.vsOut(), rtAdjust, rtAdjust); |
| |
| // Fetch one of the t,s klm root values for the geometry shader. |
| v->codeAppendf("%s = ", fTS.vsOut()); |
| v->appendTexelFetch(pointsBuffer, |
| SkStringPrintf("%s.x + 2 + sk_VertexID/2", proc.instanceAttrib()).c_str()); |
| v->codeAppend ("[sk_VertexID % 2];"); |
| |
| // Emit the vertex position. |
| v->codeAppendf("highp vec2 self = bezierpts[0] + %s;", atlasOffset); |
| gpArgs->fPositionVar.set(kVec2f_GrSLType, "self"); |
| } |
| |
| void GrCCPRCubicProcessor::emitWind(GrGLSLGeometryBuilder* g, const char* rtAdjust, |
| const char* outputWind) const { |
| // We will define bezierpts in onEmitGeometryShader. |
| g->codeAppend ("highp float area_times_2 = determinant(mat3(1, bezierpts[0], " |
| "1, bezierpts[2], " |
| "0, bezierpts[3] - bezierpts[1]));"); |
| // Drop curves that are nearly flat. The KLM math becomes unstable in this case. |
| g->codeAppendf("if (2 * abs(area_times_2) < length((bezierpts[3] - bezierpts[0]) * %s.zx)) {", |
| rtAdjust); |
| #ifndef SK_BUILD_FOR_MAC |
| g->codeAppend ( "return;"); |
| #else |
| // Returning from this geometry shader makes Mac very unhappy. Instead we make wind 0. |
| g->codeAppend ( "area_times_2 = 0;"); |
| #endif |
| g->codeAppend ("}"); |
| g->codeAppendf("%s = sign(area_times_2);", outputWind); |
| } |
| |
| void GrCCPRCubicProcessor::onEmitGeometryShader(GrGLSLGeometryBuilder* g, const char* emitVertexFn, |
| const char* wind, const char* rtAdjust) const { |
| // Prepend bezierpts at the start of the shader. |
| g->codePrependf("highp mat4x2 bezierpts = mat4x2(sk_in[0].gl_Position.xy, " |
| "sk_in[1].gl_Position.xy, " |
| "sk_in[2].gl_Position.xy, " |
| "sk_in[3].gl_Position.xy);"); |
| |
| // Evaluate the cubic at t=.5 for an approximate midpoint. |
| g->codeAppendf("highp vec2 midpoint = bezierpts * vec4(.125, .375, .375, .125);"); |
| |
| // Finish finding the inset geometry we started in the vertex shader. The z component tells us |
| // how "sharp" an inset corner is. And the vertex shader already skips one corner if it is |
| // colinear with its neighbors. So at this point, if a corner is flat, it means the inset |
| // geometry is all empty (it should never be non-convex because the curve gets chopped into |
| // convex segments ahead of time). |
| g->codeAppendf("bool isempty = " |
| "any(lessThan(vec4(%s[0].z, %s[1].z, %s[2].z, %s[3].z) * %s, vec4(2)));", |
| fInset.gsIn(), fInset.gsIn(), fInset.gsIn(), fInset.gsIn(), wind); |
| g->codeAppendf("highp vec2 inset[4];"); |
| g->codeAppend ("for (int i = 0; i < 4; ++i) {"); |
| g->codeAppendf( "inset[i] = isempty ? midpoint : %s[i].xy;", fInset.gsIn()); |
| g->codeAppend ("}"); |
| |
| // We determine crossover and/or degeneracy by how many inset edges run the opposite direction |
| // of their corresponding bezier edge. If there is one backwards edge, the inset geometry is |
| // actually triangle with a vertex at the crossover point. If there are >1 backwards edges, the |
| // inset geometry doesn't exist (i.e. the bezier quadrilateral isn't large enough) and we |
| // degenerate to the midpoint. |
| g->codeAppend ("lowp float backwards[4];"); |
| g->codeAppend ("lowp int numbackwards = 0;"); |
| g->codeAppend ("for (int i = 0; i < 4; ++i) {"); |
| g->codeAppend ( "lowp int j = (i + 1) % 4;"); |
| g->codeAppendf( "highp vec2 inner = inset[j] - inset[i];"); |
| g->codeAppendf( "highp vec2 outer = sk_in[j].gl_Position.xy - sk_in[i].gl_Position.xy;"); |
| g->codeAppendf( "backwards[i] = sign(dot(outer, inner));"); |
| g->codeAppendf( "numbackwards += backwards[i] < 0 ? 1 : 0;"); |
| g->codeAppend ("}"); |
| |
| // Find the crossover point. If there actually isn't one, this math is meaningless and will get |
| // dropped on the floor later. |
| g->codeAppend ("lowp int x = (backwards[0] != backwards[2]) ? 1 : 0;"); |
| g->codeAppend ("lowp int x3 = (x + 3) % 4;"); |
| g->codeAppend ("highp mat2 X = mat2(inset[x].y - inset[x+1].y, " |
| "inset[x+1].x - inset[x].x, " |
| "inset[x+2].y - inset[x3].y, " |
| "inset[x3].x - inset[x+2].x);"); |
| g->codeAppend ("highp vec2 KK = vec2(dot(X[0], inset[x]), dot(X[1], inset[x+2]));"); |
| g->codeAppend ("highp vec2 crossoverpoint = KK * inverse(X);"); |
| |
| // Determine what point backwards edges should collapse into. If there is one backwards edge, |
| // it should collapse to the crossover point. If >1, they should all collapse to the midpoint. |
| g->codeAppend ("highp vec2 collapsepoint = numbackwards == 1 ? crossoverpoint : midpoint;"); |
| |
| // Collapse backwards egdes to the "collapse" point. |
| g->codeAppend ("for (int i = 0; i < 4; ++i) {"); |
| g->codeAppend ( "if (backwards[i] < 0) {"); |
| g->codeAppend ( "inset[i] = inset[(i + 1) % 4] = collapsepoint;"); |
| g->codeAppend ( "}"); |
| g->codeAppend ("}"); |
| |
| // Calculate the KLM matrix. |
| g->declareGlobal(fKLMMatrix); |
| g->codeAppend ("highp vec4 K, L, M;"); |
| if (Type::kSerpentine == fType) { |
| g->codeAppend ("highp vec2 l,m;"); |
| g->codeAppendf("l.ts = vec2(%s[0], %s[1]);", fTS.gsIn(), fTS.gsIn()); |
| g->codeAppendf("m.ts = vec2(%s[2], %s[3]);", fTS.gsIn(), fTS.gsIn()); |
| g->codeAppend ("K = vec4(0, l.s * m.s, -l.t * m.s - m.t * l.s, l.t * m.t);"); |
| g->codeAppend ("L = vec4(-1,3,-3,1) * l.ssst * l.sstt * l.sttt;"); |
| g->codeAppend ("M = vec4(-1,3,-3,1) * m.ssst * m.sstt * m.sttt;"); |
| |
| } else { |
| g->codeAppend ("highp vec2 d,e;"); |
| g->codeAppendf("d.ts = vec2(%s[0], %s[1]);", fTS.gsIn(), fTS.gsIn()); |
| g->codeAppendf("e.ts = vec2(%s[2], %s[3]);", fTS.gsIn(), fTS.gsIn()); |
| g->codeAppend ("highp vec4 dxe = vec4(d.s * e.s, d.s * e.t, d.t * e.s, d.t * e.t);"); |
| g->codeAppend ("K = vec4(0, dxe.x, -dxe.y - dxe.z, dxe.w);"); |
| g->codeAppend ("L = vec4(-1,1,-1,1) * d.sstt * (dxe.xyzw + vec4(0, 2*dxe.zy, 0));"); |
| g->codeAppend ("M = vec4(-1,1,-1,1) * e.sstt * (dxe.xzyw + vec4(0, 2*dxe.yz, 0));"); |
| } |
| |
| g->codeAppend ("highp mat2x4 C = mat4(-1, 3, -3, 1, " |
| " 3, -6, 3, 0, " |
| "-3, 3, 0, 0, " |
| " 1, 0, 0, 0) * transpose(bezierpts);"); |
| |
| g->codeAppend ("highp vec2 absdet = abs(C[0].xx * C[1].zy - C[1].xx * C[0].zy);"); |
| g->codeAppend ("lowp int middlerow = absdet[0] > absdet[1] ? 2 : 1;"); |
| |
| g->codeAppend ("highp mat3 CI = inverse(mat3(C[0][0], C[0][middlerow], C[0][3], " |
| "C[1][0], C[1][middlerow], C[1][3], " |
| " 0, 0, 1));"); |
| g->codeAppendf("%s = CI * mat3(K[0], K[middlerow], K[3], " |
| "L[0], L[middlerow], L[3], " |
| "M[0], M[middlerow], M[3]);", fKLMMatrix.c_str()); |
| |
| // Orient the KLM matrix so we fill the correct side of the curve. |
| g->codeAppendf("lowp vec2 orientation = sign(vec3(midpoint, 1) * mat2x3(%s[1], %s[2]));", |
| fKLMMatrix.c_str(), fKLMMatrix.c_str()); |
| g->codeAppendf("%s *= mat3(orientation[0] * orientation[1], 0, 0, " |
| "0, orientation[0], 0, " |
| "0, 0, orientation[1]);", fKLMMatrix.c_str()); |
| |
| g->declareGlobal(fKLMDerivatives); |
| g->codeAppendf("%s[0] = %s[0].xy * %s.xz;", |
| fKLMDerivatives.c_str(), fKLMMatrix.c_str(), rtAdjust); |
| g->codeAppendf("%s[1] = %s[1].xy * %s.xz;", |
| fKLMDerivatives.c_str(), fKLMMatrix.c_str(), rtAdjust); |
| g->codeAppendf("%s[2] = %s[2].xy * %s.xz;", |
| fKLMDerivatives.c_str(), fKLMMatrix.c_str(), rtAdjust); |
| |
| this->emitCubicGeometry(g, emitVertexFn, wind, rtAdjust); |
| } |
| |
| void GrCCPRCubicInsetProcessor::emitCubicGeometry(GrGLSLGeometryBuilder* g, |
| const char* emitVertexFn, const char* wind, |
| const char* rtAdjust) const { |
| // FIXME: we should clip this geometry at the tip of the curve. |
| g->codeAppendf("%s(inset[0], 1);", emitVertexFn); |
| g->codeAppendf("%s(inset[1], 1);", emitVertexFn); |
| g->codeAppendf("%s(inset[3], 1);", emitVertexFn); |
| g->codeAppendf("%s(inset[2], 1);", emitVertexFn); |
| g->codeAppend ("EndPrimitive();"); |
| |
| g->configure(GrGLSLGeometryBuilder::InputType::kLinesAdjacency, |
| GrGLSLGeometryBuilder::OutputType::kTriangleStrip, |
| 4, 1); |
| } |
| |
| void GrCCPRCubicInsetProcessor::emitPerVertexGeometryCode(SkString* fnBody, const char* position, |
| const char* /*coverage*/, |
| const char* /*wind*/) const { |
| fnBody->appendf("highp vec3 klm = vec3(%s, 1) * %s;", position, fKLMMatrix.c_str()); |
| fnBody->appendf("%s = klm;", fKLM.gsOut()); |
| fnBody->appendf("%s[0] = 3 * klm[0] * %s[0];", fGradMatrix.gsOut(), fKLMDerivatives.c_str()); |
| fnBody->appendf("%s[1] = -klm[1] * %s[2].xy - klm[2] * %s[1].xy;", |
| fGradMatrix.gsOut(), fKLMDerivatives.c_str(), fKLMDerivatives.c_str()); |
| } |
| |
| void GrCCPRCubicInsetProcessor::emitShaderCoverage(GrGLSLFragmentBuilder* f, |
| const char* outputCoverage) const { |
| f->codeAppendf("highp float k = %s.x, l = %s.y, m = %s.z;", |
| fKLM.fsIn(), fKLM.fsIn(), fKLM.fsIn()); |
| f->codeAppend ("highp float f = k*k*k - l*m;"); |
| f->codeAppendf("highp vec2 grad = %s * vec2(k, 1);", fGradMatrix.fsIn()); |
| f->codeAppend ("highp float d = f * inversesqrt(dot(grad, grad));"); |
| f->codeAppendf("%s = clamp(0.5 - d, 0, 1);", outputCoverage); |
| } |
| |
| void GrCCPRCubicBorderProcessor::emitCubicGeometry(GrGLSLGeometryBuilder* g, |
| const char* emitVertexFn, const char* wind, |
| const char* rtAdjust) const { |
| // We defined bezierpts in onEmitGeometryShader. |
| g->declareGlobal(fEdgeDistanceEquation); |
| g->codeAppendf("int edgeidx0 = %s > 0 ? 3 : 0;", wind); |
| g->codeAppendf("highp vec2 edgept0 = bezierpts[edgeidx0];"); |
| g->codeAppendf("highp vec2 edgept1 = bezierpts[3 - edgeidx0];"); |
| this->emitEdgeDistanceEquation(g, "edgept0", "edgept1", fEdgeDistanceEquation.c_str()); |
| g->codeAppendf("%s.z += 0.5;", fEdgeDistanceEquation.c_str()); // outer = -.5, inner = .5 |
| |
| g->declareGlobal(fEdgeDistanceDerivatives); |
| g->codeAppendf("%s = %s.xy * %s.xz;", |
| fEdgeDistanceDerivatives.c_str(), fEdgeDistanceEquation.c_str(), rtAdjust); |
| |
| g->declareGlobal(fEdgeSpaceTransform); |
| g->codeAppend ("highp vec4 edgebbox = vec4(min(bezierpts[0], bezierpts[3]) - bloat, " |
| "max(bezierpts[0], bezierpts[3]) + bloat);"); |
| g->codeAppendf("%s.xy = 2 / vec2(edgebbox.zw - edgebbox.xy);", fEdgeSpaceTransform.c_str()); |
| g->codeAppendf("%s.zw = -1 - %s.xy * edgebbox.xy;", |
| fEdgeSpaceTransform.c_str(), fEdgeSpaceTransform.c_str()); |
| |
| int maxVertices = this->emitHullGeometry(g, emitVertexFn, "bezierpts", 4, "sk_InvocationID", |
| "inset"); |
| |
| g->configure(GrGLSLGeometryBuilder::InputType::kLinesAdjacency, |
| GrGLSLGeometryBuilder::OutputType::kTriangleStrip, |
| maxVertices, 4); |
| } |
| |
| void GrCCPRCubicBorderProcessor::emitPerVertexGeometryCode(SkString* fnBody, const char* position, |
| const char* /*coverage*/, |
| const char* /*wind*/) const { |
| fnBody->appendf("highp vec3 klm = vec3(%s, 1) * %s;", position, fKLMMatrix.c_str()); |
| fnBody->appendf("highp float d = dot(vec3(%s, 1), %s);", |
| position, fEdgeDistanceEquation.c_str()); |
| fnBody->appendf("%s = vec4(klm, d);", fKLMD.gsOut()); |
| fnBody->appendf("%s = vec4(%s[0].x, %s[1].x, %s[2].x, %s.x);", |
| fdKLMDdx.gsOut(), fKLMDerivatives.c_str(), fKLMDerivatives.c_str(), |
| fKLMDerivatives.c_str(), fEdgeDistanceDerivatives.c_str()); |
| fnBody->appendf("%s = vec4(%s[0].y, %s[1].y, %s[2].y, %s.y);", |
| fdKLMDdy.gsOut(), fKLMDerivatives.c_str(), fKLMDerivatives.c_str(), |
| fKLMDerivatives.c_str(), fEdgeDistanceDerivatives.c_str()); |
| fnBody->appendf("%s = position * %s.xy + %s.zw;", fEdgeSpaceCoord.gsOut(), |
| fEdgeSpaceTransform.c_str(), fEdgeSpaceTransform.c_str()); |
| |
| // Otherwise, fEdgeDistances = fEdgeDistances * sign(wind * rtAdjust.x * rdAdjust.z). |
| GR_STATIC_ASSERT(kTopLeft_GrSurfaceOrigin == GrCCPRCoverageProcessor::kAtlasOrigin); |
| } |
| |
| void GrCCPRCubicBorderProcessor::emitShaderCoverage(GrGLSLFragmentBuilder* f, |
| const char* outputCoverage) const { |
| // Use software msaa to determine coverage. |
| const int sampleCount = this->defineSoftSampleLocations(f, "samples"); |
| |
| // Along the shared edge, we start with distance-to-edge coverage, then subtract out the |
| // remaining pixel coverage that is still inside the shared edge, but outside the curve. |
| // Outside the shared edege, we just use standard msaa to count samples inside the curve. |
| f->codeAppendf("bool use_edge = all(lessThan(abs(%s), vec2(1)));", fEdgeSpaceCoord.fsIn()); |
| f->codeAppendf("%s = (use_edge ? clamp(%s.w + 0.5, 0, 1) : 0) * %i;", |
| outputCoverage, fKLMD.fsIn(), sampleCount); |
| |
| f->codeAppendf("highp mat2x4 grad_klmd = mat2x4(%s, %s);", fdKLMDdx.fsIn(), fdKLMDdy.fsIn()); |
| |
| f->codeAppendf("for (int i = 0; i < %i; ++i) {", sampleCount); |
| f->codeAppendf( "highp vec4 klmd = grad_klmd * samples[i] + %s;", fKLMD.fsIn()); |
| f->codeAppend ( "lowp float f = klmd.y * klmd.z - klmd.x * klmd.x * klmd.x;"); |
| // A sample is inside our cubic sub-section if it is inside the implicit AND L & M are both |
| // positive. This works because the sections get chopped at the K/L and K/M intersections. |
| f->codeAppend ( "bvec4 inside = greaterThan(vec4(f,klmd.yzw), vec4(0));"); |
| f->codeAppend ( "lowp float in_curve = all(inside.xyz) ? 1 : 0;"); |
| f->codeAppend ( "lowp float in_edge = inside.w ? 1 : 0;"); |
| f->codeAppendf( "%s += use_edge ? in_edge * (in_curve - 1) : in_curve;", outputCoverage); |
| f->codeAppend ("}"); |
| |
| f->codeAppendf("%s *= %f;", outputCoverage, 1.0 / sampleCount); |
| } |