src/core/SkDraw_vertices.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 "include/core/SkColorSpace.h"
 #include "include/core/SkString.h"
 #include "include/private/SkVx.h"
 #include "src/core/SkArenaAlloc.h"
 #include "src/core/SkAutoBlitterChoose.h"
 #include "src/core/SkBlenderBase.h"
 #include "src/core/SkConvertPixels.h"
 #include "src/core/SkCoreBlitters.h"
 #include "src/core/SkDraw.h"
 #include "src/core/SkMatrixProvider.h"
 #include "src/core/SkRasterClip.h"
 #include "src/core/SkRasterPipeline.h"
 #include "src/core/SkScan.h"
 #include "src/core/SkVM.h"
 #include "src/core/SkVMBlitter.h"
 #include "src/core/SkVertState.h"
 #include "src/core/SkVerticesPriv.h"
 #include "src/shaders/SkShaderBase.h"

 struct Matrix43 {
     float fMat[12];    // column major

     skvx::float4 map(float x, float y) const {
         return skvx::float4::Load(&fMat[0]) * x +
                skvx::float4::Load(&fMat[4]) * y +
                skvx::float4::Load(&fMat[8]);
     }

     // Pass a by value, so we don't have to worry about aliasing with this
     void setConcat(const Matrix43 a, const SkMatrix& b) {
         SkASSERT(!b.hasPerspective());

         fMat[ 0] = a.dot(0, b.getScaleX(), b.getSkewY());
         fMat[ 1] = a.dot(1, b.getScaleX(), b.getSkewY());
         fMat[ 2] = a.dot(2, b.getScaleX(), b.getSkewY());
         fMat[ 3] = a.dot(3, b.getScaleX(), b.getSkewY());

         fMat[ 4] = a.dot(0, b.getSkewX(), b.getScaleY());
         fMat[ 5] = a.dot(1, b.getSkewX(), b.getScaleY());
         fMat[ 6] = a.dot(2, b.getSkewX(), b.getScaleY());
         fMat[ 7] = a.dot(3, b.getSkewX(), b.getScaleY());

         fMat[ 8] = a.dot(0, b.getTranslateX(), b.getTranslateY()) + a.fMat[ 8];
         fMat[ 9] = a.dot(1, b.getTranslateX(), b.getTranslateY()) + a.fMat[ 9];
         fMat[10] = a.dot(2, b.getTranslateX(), b.getTranslateY()) + a.fMat[10];
         fMat[11] = a.dot(3, b.getTranslateX(), b.getTranslateY()) + a.fMat[11];
     }

 private:
     float dot(int index, float x, float y) const {
         return fMat[index + 0] * x + fMat[index + 4] * y;
     }
 };

 static bool SK_WARN_UNUSED_RESULT
 texture_to_matrix(const VertState& state, const SkPoint verts[], const SkPoint texs[],
                   SkMatrix* matrix) {
     SkPoint src[3], dst[3];

     src[0] = texs[state.f0];
     src[1] = texs[state.f1];
     src[2] = texs[state.f2];
     dst[0] = verts[state.f0];
     dst[1] = verts[state.f1];
     dst[2] = verts[state.f2];
     return matrix->setPolyToPoly(src, dst, 3);
 }

 class SkTriColorShader : public SkShaderBase {
 public:
     SkTriColorShader(bool isOpaque, bool usePersp) : fIsOpaque(isOpaque), fUsePersp(usePersp) {}

     // This gets called for each triangle, without re-calling onAppendStages.
     bool update(const SkMatrix& ctmInv, const SkPoint pts[], const SkPMColor4f colors[],
                 int index0, int index1, int index2);

 protected:
     bool onAppendStages(const SkStageRec& rec) const override {
         rec.fPipeline->append(SkRasterPipeline::seed_shader);
         if (fUsePersp) {
             rec.fPipeline->append(SkRasterPipeline::matrix_perspective, &fM33);
         }
         rec.fPipeline->append(SkRasterPipeline::matrix_4x3, &fM43);
         return true;
     }

     skvm::Color onProgram(skvm::Builder*,
                           skvm::Coord, skvm::Coord, skvm::Color,
                           const SkMatrixProvider&, const SkMatrix*, const SkColorInfo&,
                           skvm::Uniforms*, SkArenaAlloc*) const override;

 private:
     bool isOpaque() const override { return fIsOpaque; }
     // For serialization.  This will never be called.
     Factory getFactory() const override { return nullptr; }
     const char* getTypeName() const override { return nullptr; }

     // If fUsePersp, we need both of these matrices,
     // otherwise we can combine them, and only use fM43

     Matrix43 fM43;
     SkMatrix fM33;
     const bool fIsOpaque;
     const bool fUsePersp;   // controls our stages, and what we do in update()
     mutable skvm::Uniform fColorMatrix;
     mutable skvm::Uniform fCoordMatrix;

     using INHERITED = SkShaderBase;
 };

 skvm::Color SkTriColorShader::onProgram(skvm::Builder* b,
                                         skvm::Coord device, skvm::Coord local, skvm::Color,
                                         const SkMatrixProvider& matrices, const SkMatrix* localM,
                                         const SkColorInfo&, skvm::Uniforms* uniforms,
                                         SkArenaAlloc* alloc) const {

     fColorMatrix = uniforms->pushPtr(&fM43);

     skvm::F32 x = local.x,
               y = local.y;

     if (fUsePersp) {
         fCoordMatrix = uniforms->pushPtr(&fM33);
         auto dot = [&, x, y](int row) {
             return b->mad(x, b->arrayF(fCoordMatrix, row),
                              b->mad(y, b->arrayF(fCoordMatrix, row + 3),
                                        b->arrayF(fCoordMatrix, row + 6)));
         };

         x = dot(0);
         y = dot(1);
         x = x * (1.0f / dot(2));
         y = y * (1.0f / dot(2));
     }

     auto colorDot = [&, x, y](int row) {
         return b->mad(x, b->arrayF(fColorMatrix, row),
                          b->mad(y, b->arrayF(fColorMatrix, row + 4),
                                    b->arrayF(fColorMatrix, row + 8)));
     };

     skvm::Color color;
     color.r = colorDot(0);
     color.g = colorDot(1);
     color.b = colorDot(2);
     color.a = colorDot(3);
     return color;
 }

 bool SkTriColorShader::update(const SkMatrix& ctmInv, const SkPoint pts[],
                               const SkPMColor4f colors[], int index0, int index1, int index2) {
     SkMatrix m, im;
     m.reset();
     m.set(0, pts[index1].fX - pts[index0].fX);
     m.set(1, pts[index2].fX - pts[index0].fX);
     m.set(2, pts[index0].fX);
     m.set(3, pts[index1].fY - pts[index0].fY);
     m.set(4, pts[index2].fY - pts[index0].fY);
     m.set(5, pts[index0].fY);
     if (!m.invert(&im)) {
         return false;
     }

     fM33.setConcat(im, ctmInv);

     auto c0 = skvx::float4::Load(colors[index0].vec()),
          c1 = skvx::float4::Load(colors[index1].vec()),
          c2 = skvx::float4::Load(colors[index2].vec());

     (c1 - c0).store(&fM43.fMat[0]);
     (c2 - c0).store(&fM43.fMat[4]);
     c0.store(&fM43.fMat[8]);

     if (!fUsePersp) {
         fM43.setConcat(fM43, fM33);
     }
     return true;
 }

 // Convert the SkColors into float colors. The conversion depends on some conditions:
 // - If the pixmap has a dst colorspace, we have to be "color-correct".
 //   Do we map into dst-colorspace before or after we interpolate?
 // - We have to decide when to apply per-color alpha (before or after we interpolate)
 //
 // For now, we will take a simple approach, but recognize this is just a start:
 // - convert colors into dst colorspace before interpolation (matches gradients)
 // - apply per-color alpha before interpolation (matches old version of vertices)
 //
 static SkPMColor4f* convert_colors(const SkColor src[],
                                    int count,
                                    SkColorSpace* deviceCS,
                                    SkArenaAlloc* alloc,
                                    bool skipColorXform) {
     SkPMColor4f* dst = alloc->makeArray<SkPMColor4f>(count);

     // Passing `nullptr` for the destination CS effectively disables color conversion.
     auto dstCS = skipColorXform ? nullptr : sk_ref_sp(deviceCS);
     SkImageInfo srcInfo = SkImageInfo::Make(
             count, 1, kBGRA_8888_SkColorType, kUnpremul_SkAlphaType, SkColorSpace::MakeSRGB());
     SkImageInfo dstInfo =
             SkImageInfo::Make(count, 1, kRGBA_F32_SkColorType, kPremul_SkAlphaType, dstCS);
     SkAssertResult(SkConvertPixels(dstInfo, dst, 0, srcInfo, src, 0));
     return dst;
 }

 static bool compute_is_opaque(const SkColor colors[], int count) {
     uint32_t c = ~0;
     for (int i = 0; i < count; ++i) {
         c &= colors[i];
     }
     return SkColorGetA(c) == 0xFF;
 }

 static void fill_triangle_2(const VertState& state, SkBlitter* blitter, const SkRasterClip& rc,
                             const SkPoint dev2[]) {
     SkPoint tmp[] = {
         dev2[state.f0], dev2[state.f1], dev2[state.f2]
     };
     SkScan::FillTriangle(tmp, rc, blitter);
 }

 static constexpr int kMaxClippedTrianglePointCount = 4;
 static void fill_triangle_3(const VertState& state, SkBlitter* blitter, const SkRasterClip& rc,
                             const SkPoint3 dev3[]) {
     // Compute the crossing point (across zero) for the two values, expressed as a
     // normalized 0...1 value. If curr is 0, returns 0. If next is 0, returns 1.
     auto computeT = [](float curr, float next) {
         // Check that 0 is between next and curr.
         SkASSERT((next <= 0 && 0 < curr) || (curr <= 0 && 0 < next));
         float t = curr / (curr - next);
         SkASSERT(0 <= t && t <= 1);
         return t;
     };

     auto lerp = [](SkPoint3 curr, SkPoint3 next, float t) {
         return curr + t * (next - curr);
     };

     constexpr float tol = 0.05f;
     // tol is the nudge away from zero, to keep the numerics nice.
     // Think of it as our near-clipping-plane (or w-plane).
     auto clip = [&](SkPoint3 curr, SkPoint3 next) {
         // Return the point between curr and next where the fZ value crosses tol.
         // To be (really) perspective correct, we should be computing based on 1/Z, not Z.
         // For now, this is close enough (and faster).
         return lerp(curr, next, computeT(curr.fZ - tol, next.fZ - tol));
     };

     // Clip a triangle (based on its homogeneous W values), and return the projected polygon.
     // Since we only clip against one "edge"/plane, the max number of points in the clipped
     // polygon is 4.
     auto clipTriangle = [&](SkPoint dst[], const int idx[3], const SkPoint3 pts[]) -> int {
         SkPoint3 outPoints[kMaxClippedTrianglePointCount];
         SkPoint3* outP = outPoints;

         for (int i = 0; i < 3; ++i) {
             int curr = idx[i];
             int next = idx[(i + 1) % 3];
             if (pts[curr].fZ > tol) {
                 *outP++ = pts[curr];
                 if (pts[next].fZ <= tol) { // curr is IN, next is OUT
                     *outP++ = clip(pts[curr], pts[next]);
                 }
             } else {
                 if (pts[next].fZ > tol) { // curr is OUT, next is IN
                     *outP++ = clip(pts[curr], pts[next]);
                 }
             }
         }

         const int count = SkTo<int>(outP - outPoints);
         SkASSERT(count == 0 || count == 3 || count == 4);
         for (int i = 0; i < count; ++i) {
             float scale = sk_ieee_float_divide(1.0f, outPoints[i].fZ);
             dst[i].set(outPoints[i].fX * scale, outPoints[i].fY * scale);
         }
         return count;
     };

     SkPoint tmp[kMaxClippedTrianglePointCount];
     int idx[] = { state.f0, state.f1, state.f2 };
     if (int n = clipTriangle(tmp, idx, dev3)) {
         // TODO: SkScan::FillConvexPoly(tmp, n, ...);
         SkASSERT(n == 3 || n == 4);
         SkScan::FillTriangle(tmp, rc, blitter);
         if (n == 4) {
             tmp[1] = tmp[2];
             tmp[2] = tmp[3];
             SkScan::FillTriangle(tmp, rc, blitter);
         }
     }
 }

 static void fill_triangle(const VertState& state, SkBlitter* blitter, const SkRasterClip& rc,
                           const SkPoint dev2[], const SkPoint3 dev3[]) {
     if (dev3) {
         fill_triangle_3(state, blitter, rc, dev3);
     } else {
         fill_triangle_2(state, blitter, rc, dev2);
     }
 }

 extern bool gUseSkVMBlitter;

 void SkDraw::drawFixedVertices(const SkVertices* vertices,
                                sk_sp<SkBlender> blender,
                                const SkPaint& paint,
                                const SkMatrix& ctmInverse,
                                const SkPoint* dev2,
                                const SkPoint3* dev3,
                                SkArenaAlloc* outerAlloc,
                                bool skipColorXform) const {
     SkVerticesPriv info(vertices->priv());

     const int vertexCount = info.vertexCount();
     const int indexCount = info.indexCount();
     const SkPoint* positions = info.positions();
     const SkPoint* texCoords = info.texCoords();
     const uint16_t* indices = info.indices();
     const SkColor* colors = info.colors();

     SkShader* paintShader = paint.getShader();

     if (paintShader) {
         if (!texCoords) {
             texCoords = positions;
         }
     } else {
         texCoords = nullptr;
     }

     bool blenderIsDst = false;
     // We can simplify things for certain blend modes. This is for speed, and SkShader_Blend
     // itself insists we don't pass kSrc or kDst to it.
     if (std::optional<SkBlendMode> bm = as_BB(blender)->asBlendMode(); bm.has_value() && colors) {
         switch (*bm) {
             case SkBlendMode::kSrc:
                 colors = nullptr;
                 break;
             case SkBlendMode::kDst:
                 blenderIsDst = true;
                 texCoords = nullptr;
                 paintShader = nullptr;
                 break;
             default: break;
         }
     }

     // There is a paintShader iff there is texCoords.
     SkASSERT((texCoords != nullptr) == (paintShader != nullptr));

     SkMatrix ctm = fMatrixProvider->localToDevice();
     const bool usePerspective = ctm.hasPerspective();

     SkTriColorShader* triColorShader = nullptr;
     SkPMColor4f* dstColors = nullptr;
     if (colors) {
         dstColors =
                 convert_colors(colors, vertexCount, fDst.colorSpace(), outerAlloc, skipColorXform);
         triColorShader = outerAlloc->make<SkTriColorShader>(compute_is_opaque(colors, vertexCount),
                                                             usePerspective);
     }

     // Combines per-vertex colors with 'shader' using 'blender'.
     auto applyShaderColorBlend = [&](SkShader* shader) -> sk_sp<SkShader> {
         if (!colors) {
             return sk_ref_sp(shader);
         }
         if (blenderIsDst) {
             return sk_ref_sp(triColorShader);
         }
         sk_sp<SkShader> shaderWithWhichToBlend;
         if (!shader) {
             // When there is no shader then the blender applies to the vertex colors and opaque
             // paint color.
             shaderWithWhichToBlend = SkShaders::Color(paint.getColor4f().makeOpaque(), nullptr);
         } else {
             shaderWithWhichToBlend = sk_ref_sp(shader);
         }
         return SkShaders::Blend(blender,
                                 sk_ref_sp(triColorShader),
                                 std::move(shaderWithWhichToBlend));
     };

     auto rpblit = [&]() {
         VertState state(vertexCount, indices, indexCount);
         VertState::Proc vertProc = state.chooseProc(info.mode());
         sk_sp<SkShader> blendShader = applyShaderColorBlend(paintShader);
         SkSurfaceProps props = SkSurfacePropsCopyOrDefault(fProps);

         SkPaint shaderPaint(paint);
         shaderPaint.setShader(blendShader);

         if (!texCoords) {  // only tricolor shader
             auto blitter = SkCreateRasterPipelineBlitter(fDst, shaderPaint, *fMatrixProvider,
                                                          outerAlloc, this->fRC->clipShader(),
                                                          props);
             if (!blitter) {
                 return false;
             }
             while (vertProc(&state)) {
                 if (triColorShader && !triColorShader->update(ctmInverse, positions, dstColors,
                                                               state.f0, state.f1, state.f2)) {
                     continue;
                 }
                 fill_triangle(state, blitter, *fRC, dev2, dev3);
             }
             return true;
         }

         SkRasterPipeline pipeline(outerAlloc);
         SkStageRec rec = {&pipeline,
                           outerAlloc,
                           fDst.colorType(),
                           fDst.colorSpace(),
                           shaderPaint,
                           nullptr,
                           *fMatrixProvider,
                           props};
         if (auto updater = as_SB(blendShader)->appendUpdatableStages(rec)) {
             bool isOpaque = blendShader->isOpaque();
             if (triColorShader) {
                 isOpaque = false;  // unless we want to walk all the colors, and see if they are
                                    // all opaque (and the blend mode will keep them that way
             }

             // Positions as texCoords? The local matrix is always identity, so update once
             if (texCoords == positions) {
                 if (!updater->update(ctm)) {
                     return true;
                 }
             }

             auto blitter = SkCreateRasterPipelineBlitter(
                     fDst, shaderPaint, pipeline, isOpaque, outerAlloc, fRC->clipShader());
             if (!blitter) {
                 return false;
             }
             while (vertProc(&state)) {
                 if (triColorShader && !triColorShader->update(ctmInverse, positions, dstColors,
                                                               state.f0, state.f1, state.f2)) {
                     continue;
                 }

                 SkMatrix localM;
                 if ((texCoords == positions) ||
                     (texture_to_matrix(state, positions, texCoords, &localM) &&
                      updater->update(SkMatrix::Concat(ctm, localM)))) {
                     fill_triangle(state, blitter, *fRC, dev2, dev3);
                 }
             }
         } else {
             // must rebuild pipeline for each triangle, to pass in the computed ctm
             while (vertProc(&state)) {
                 if (triColorShader && !triColorShader->update(ctmInverse, positions, dstColors,
                                                               state.f0, state.f1, state.f2)) {
                     continue;
                 }

                 SkSTArenaAlloc<2048> innerAlloc;

                 const SkMatrixProvider* matrixProvider = fMatrixProvider;
                 SkTLazy<SkPreConcatMatrixProvider> preConcatMatrixProvider;
                 if (texCoords && (texCoords != positions)) {
                     SkMatrix localM;
                     if (!texture_to_matrix(state, positions, texCoords, &localM)) {
                         continue;
                     }
                     matrixProvider = preConcatMatrixProvider.init(*matrixProvider, localM);
                 }

                 // It'd be nice if we could detect this will fail earlier.
                 auto blitter = SkCreateRasterPipelineBlitter(fDst, shaderPaint, *matrixProvider,
                                                              &innerAlloc, this->fRC->clipShader(),
                                                              props);
                 if (!blitter) {
                     return false;
                 }
                 fill_triangle(state, blitter, *fRC, dev2, dev3);
             }
         }
         return true;
     };

     if (gUseSkVMBlitter || !rpblit()) {
         VertState state(vertexCount, indices, indexCount);
         VertState::Proc vertProc = state.chooseProc(info.mode());

         // No colors are changing and no texture coordinates are changing, so no updates between
         // triangles are needed. Use SkVM to blit the triangles.
         SkShader* shader = paintShader;
         SkUpdatableShader* texCoordShader = nullptr;
         if (texCoords && texCoords != positions) {
             texCoordShader = as_SB(shader)->updatableShader(outerAlloc);
             shader = texCoordShader;
         }
         sk_sp<SkShader> blenderShader = applyShaderColorBlend(shader);

         SkPaint shaderPaint{paint};
         shaderPaint.setShader(std::move(blenderShader));
         auto blitter = SkVMBlitter::Make(
                 fDst, shaderPaint, *fMatrixProvider, outerAlloc, this->fRC->clipShader());
         if (!blitter) {
             return;
         }
         while (vertProc(&state)) {
             SkMatrix localM;
             if (texCoordShader && !(texture_to_matrix(state, positions, texCoords, &localM) &&
                                     texCoordShader->update(SkMatrix::Concat(ctm, localM)))) {
                 continue;
             }

             if (triColorShader && !triColorShader->update(ctmInverse, positions, dstColors,state.f0,
                                                           state.f1, state.f2)) {
                 continue;
             }

             fill_triangle(state, blitter, *fRC, dev2, dev3);
         }
     }
 }

 void SkDraw::drawVertices(const SkVertices* vertices,
                           sk_sp<SkBlender> blender,
                           const SkPaint& paint,
                           bool skipColorXform) const {
     SkVerticesPriv info(vertices->priv());
     const int vertexCount = info.vertexCount();
     const int indexCount = info.indexCount();

     // abort early if there is nothing to draw
     if (vertexCount < 3 || (indexCount > 0 && indexCount < 3) || fRC->isEmpty()) {
         return;
     }
     SkMatrix ctm = fMatrixProvider->localToDevice();
     SkMatrix ctmInv;
     if (!ctm.invert(&ctmInv)) {
         return;
     }

     constexpr size_t kDefVertexCount = 16;
     constexpr size_t kOuterSize = sizeof(SkTriColorShader) +
                                   (2 * sizeof(SkPoint) + sizeof(SkColor4f)) * kDefVertexCount;
     SkSTArenaAlloc<kOuterSize> outerAlloc;

     SkPoint*  dev2 = nullptr;
     SkPoint3* dev3 = nullptr;

     if (ctm.hasPerspective()) {
         dev3 = outerAlloc.makeArray<SkPoint3>(vertexCount);
         ctm.mapHomogeneousPoints(dev3, info.positions(), vertexCount);
         // similar to the bounds check for 2d points (below)
         if (!SkScalarsAreFinite((const SkScalar*)dev3, vertexCount * 3)) {
             return;
         }
     } else {
         dev2 = outerAlloc.makeArray<SkPoint>(vertexCount);
         ctm.mapPoints(dev2, info.positions(), vertexCount);

         SkRect bounds;
         // this also sets bounds to empty if we see a non-finite value
         bounds.setBounds(dev2, vertexCount);
         if (bounds.isEmpty()) {
             return;
         }
     }

     this->drawFixedVertices(
             vertices, std::move(blender), paint, ctmInv, dev2, dev3, &outerAlloc, skipColorXform);
 }
	/*
	* 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 "include/core/SkColorSpace.h"
	#include "include/core/SkString.h"
	#include "include/private/SkVx.h"
	#include "src/core/SkArenaAlloc.h"
	#include "src/core/SkAutoBlitterChoose.h"
	#include "src/core/SkBlenderBase.h"
	#include "src/core/SkConvertPixels.h"
	#include "src/core/SkCoreBlitters.h"
	#include "src/core/SkDraw.h"
	#include "src/core/SkMatrixProvider.h"
	#include "src/core/SkRasterClip.h"
	#include "src/core/SkRasterPipeline.h"
	#include "src/core/SkScan.h"
	#include "src/core/SkVM.h"
	#include "src/core/SkVMBlitter.h"
	#include "src/core/SkVertState.h"
	#include "src/core/SkVerticesPriv.h"
	#include "src/shaders/SkShaderBase.h"

	struct Matrix43 {
	float fMat[12]; // column major

	skvx::float4 map(float x, float y) const {
	return skvx::float4::Load(&fMat[0]) * x +
	skvx::float4::Load(&fMat[4]) * y +
	skvx::float4::Load(&fMat[8]);
	}

	// Pass a by value, so we don't have to worry about aliasing with this
	void setConcat(const Matrix43 a, const SkMatrix& b) {
	SkASSERT(!b.hasPerspective());

	fMat[ 0] = a.dot(0, b.getScaleX(), b.getSkewY());
	fMat[ 1] = a.dot(1, b.getScaleX(), b.getSkewY());
	fMat[ 2] = a.dot(2, b.getScaleX(), b.getSkewY());
	fMat[ 3] = a.dot(3, b.getScaleX(), b.getSkewY());

	fMat[ 4] = a.dot(0, b.getSkewX(), b.getScaleY());
	fMat[ 5] = a.dot(1, b.getSkewX(), b.getScaleY());
	fMat[ 6] = a.dot(2, b.getSkewX(), b.getScaleY());
	fMat[ 7] = a.dot(3, b.getSkewX(), b.getScaleY());

	fMat[ 8] = a.dot(0, b.getTranslateX(), b.getTranslateY()) + a.fMat[ 8];
	fMat[ 9] = a.dot(1, b.getTranslateX(), b.getTranslateY()) + a.fMat[ 9];
	fMat[10] = a.dot(2, b.getTranslateX(), b.getTranslateY()) + a.fMat[10];
	fMat[11] = a.dot(3, b.getTranslateX(), b.getTranslateY()) + a.fMat[11];
	}

	private:
	float dot(int index, float x, float y) const {
	return fMat[index + 0] * x + fMat[index + 4] * y;
	}
	};

	static bool SK_WARN_UNUSED_RESULT
	texture_to_matrix(const VertState& state, const SkPoint verts[], const SkPoint texs[],
	SkMatrix* matrix) {
	SkPoint src[3], dst[3];

	src[0] = texs[state.f0];
	src[1] = texs[state.f1];
	src[2] = texs[state.f2];
	dst[0] = verts[state.f0];
	dst[1] = verts[state.f1];
	dst[2] = verts[state.f2];
	return matrix->setPolyToPoly(src, dst, 3);
	}

	class SkTriColorShader : public SkShaderBase {
	public:
	SkTriColorShader(bool isOpaque, bool usePersp) : fIsOpaque(isOpaque), fUsePersp(usePersp) {}

	// This gets called for each triangle, without re-calling onAppendStages.
	bool update(const SkMatrix& ctmInv, const SkPoint pts[], const SkPMColor4f colors[],
	int index0, int index1, int index2);

	protected:
	bool onAppendStages(const SkStageRec& rec) const override {
	rec.fPipeline->append(SkRasterPipeline::seed_shader);
	if (fUsePersp) {
	rec.fPipeline->append(SkRasterPipeline::matrix_perspective, &fM33);
	}
	rec.fPipeline->append(SkRasterPipeline::matrix_4x3, &fM43);
	return true;
	}

	skvm::Color onProgram(skvm::Builder*,
	skvm::Coord, skvm::Coord, skvm::Color,
	const SkMatrixProvider&, const SkMatrix*, const SkColorInfo&,
	skvm::Uniforms, SkArenaAlloc) const override;

	private:
	bool isOpaque() const override { return fIsOpaque; }
	// For serialization. This will never be called.
	Factory getFactory() const override { return nullptr; }
	const char* getTypeName() const override { return nullptr; }

	// If fUsePersp, we need both of these matrices,
	// otherwise we can combine them, and only use fM43

	Matrix43 fM43;
	SkMatrix fM33;
	const bool fIsOpaque;
	const bool fUsePersp; // controls our stages, and what we do in update()
	mutable skvm::Uniform fColorMatrix;
	mutable skvm::Uniform fCoordMatrix;

	using INHERITED = SkShaderBase;
	};

	skvm::Color SkTriColorShader::onProgram(skvm::Builder* b,
	skvm::Coord device, skvm::Coord local, skvm::Color,
	const SkMatrixProvider& matrices, const SkMatrix* localM,
	const SkColorInfo&, skvm::Uniforms* uniforms,
	SkArenaAlloc* alloc) const {

	fColorMatrix = uniforms->pushPtr(&fM43);

	skvm::F32 x = local.x,
	y = local.y;

	if (fUsePersp) {
	fCoordMatrix = uniforms->pushPtr(&fM33);
	auto dot = [&, x, y](int row) {
	return b->mad(x, b->arrayF(fCoordMatrix, row),
	b->mad(y, b->arrayF(fCoordMatrix, row + 3),
	b->arrayF(fCoordMatrix, row + 6)));
	};

	x = dot(0);
	y = dot(1);
	x = x * (1.0f / dot(2));
	y = y * (1.0f / dot(2));
	}

	auto colorDot = [&, x, y](int row) {
	return b->mad(x, b->arrayF(fColorMatrix, row),
	b->mad(y, b->arrayF(fColorMatrix, row + 4),
	b->arrayF(fColorMatrix, row + 8)));
	};

	skvm::Color color;
	color.r = colorDot(0);
	color.g = colorDot(1);
	color.b = colorDot(2);
	color.a = colorDot(3);
	return color;
	}

	bool SkTriColorShader::update(const SkMatrix& ctmInv, const SkPoint pts[],
	const SkPMColor4f colors[], int index0, int index1, int index2) {
	SkMatrix m, im;
	m.reset();
	m.set(0, pts[index1].fX - pts[index0].fX);
	m.set(1, pts[index2].fX - pts[index0].fX);
	m.set(2, pts[index0].fX);
	m.set(3, pts[index1].fY - pts[index0].fY);
	m.set(4, pts[index2].fY - pts[index0].fY);
	m.set(5, pts[index0].fY);
	if (!m.invert(&im)) {
	return false;
	}

	fM33.setConcat(im, ctmInv);

	auto c0 = skvx::float4::Load(colors[index0].vec()),
	c1 = skvx::float4::Load(colors[index1].vec()),
	c2 = skvx::float4::Load(colors[index2].vec());

	(c1 - c0).store(&fM43.fMat[0]);
	(c2 - c0).store(&fM43.fMat[4]);
	c0.store(&fM43.fMat[8]);

	if (!fUsePersp) {
	fM43.setConcat(fM43, fM33);
	}
	return true;
	}

	// Convert the SkColors into float colors. The conversion depends on some conditions:
	// - If the pixmap has a dst colorspace, we have to be "color-correct".
	// Do we map into dst-colorspace before or after we interpolate?
	// - We have to decide when to apply per-color alpha (before or after we interpolate)
	//
	// For now, we will take a simple approach, but recognize this is just a start:
	// - convert colors into dst colorspace before interpolation (matches gradients)
	// - apply per-color alpha before interpolation (matches old version of vertices)
	//
	static SkPMColor4f* convert_colors(const SkColor src[],
	int count,
	SkColorSpace* deviceCS,
	SkArenaAlloc* alloc,
	bool skipColorXform) {
	SkPMColor4f* dst = alloc->makeArray<SkPMColor4f>(count);

	// Passing `nullptr` for the destination CS effectively disables color conversion.
	auto dstCS = skipColorXform ? nullptr : sk_ref_sp(deviceCS);
	SkImageInfo srcInfo = SkImageInfo::Make(
	count, 1, kBGRA_8888_SkColorType, kUnpremul_SkAlphaType, SkColorSpace::MakeSRGB());
	SkImageInfo dstInfo =
	SkImageInfo::Make(count, 1, kRGBA_F32_SkColorType, kPremul_SkAlphaType, dstCS);
	SkAssertResult(SkConvertPixels(dstInfo, dst, 0, srcInfo, src, 0));
	return dst;
	}

	static bool compute_is_opaque(const SkColor colors[], int count) {
	uint32_t c = ~0;
	for (int i = 0; i < count; ++i) {
	c &= colors[i];
	}
	return SkColorGetA(c) == 0xFF;
	}

	static void fill_triangle_2(const VertState& state, SkBlitter* blitter, const SkRasterClip& rc,
	const SkPoint dev2[]) {
	SkPoint tmp[] = {
	dev2[state.f0], dev2[state.f1], dev2[state.f2]
	};
	SkScan::FillTriangle(tmp, rc, blitter);
	}

	static constexpr int kMaxClippedTrianglePointCount = 4;
	static void fill_triangle_3(const VertState& state, SkBlitter* blitter, const SkRasterClip& rc,
	const SkPoint3 dev3[]) {
	// Compute the crossing point (across zero) for the two values, expressed as a
	// normalized 0...1 value. If curr is 0, returns 0. If next is 0, returns 1.
	auto computeT = [](float curr, float next) {
	// Check that 0 is between next and curr.
	SkASSERT((next <= 0 && 0 < curr) \|\| (curr <= 0 && 0 < next));
	float t = curr / (curr - next);
	SkASSERT(0 <= t && t <= 1);
	return t;
	};

	auto lerp = [](SkPoint3 curr, SkPoint3 next, float t) {
	return curr + t * (next - curr);
	};

	constexpr float tol = 0.05f;
	// tol is the nudge away from zero, to keep the numerics nice.
	// Think of it as our near-clipping-plane (or w-plane).
	auto clip = [&](SkPoint3 curr, SkPoint3 next) {
	// Return the point between curr and next where the fZ value crosses tol.
	// To be (really) perspective correct, we should be computing based on 1/Z, not Z.
	// For now, this is close enough (and faster).
	return lerp(curr, next, computeT(curr.fZ - tol, next.fZ - tol));
	};

	// Clip a triangle (based on its homogeneous W values), and return the projected polygon.
	// Since we only clip against one "edge"/plane, the max number of points in the clipped
	// polygon is 4.
	auto clipTriangle = [&](SkPoint dst[], const int idx[3], const SkPoint3 pts[]) -> int {
	SkPoint3 outPoints[kMaxClippedTrianglePointCount];
	SkPoint3* outP = outPoints;

	for (int i = 0; i < 3; ++i) {
	int curr = idx[i];
	int next = idx[(i + 1) % 3];
	if (pts[curr].fZ > tol) {
	*outP++ = pts[curr];
	if (pts[next].fZ <= tol) { // curr is IN, next is OUT
	*outP++ = clip(pts[curr], pts[next]);
	}
	} else {
	if (pts[next].fZ > tol) { // curr is OUT, next is IN
	*outP++ = clip(pts[curr], pts[next]);
	}
	}
	}

	const int count = SkTo<int>(outP - outPoints);
	SkASSERT(count == 0 \|\| count == 3 \|\| count == 4);
	for (int i = 0; i < count; ++i) {
	float scale = sk_ieee_float_divide(1.0f, outPoints[i].fZ);
	dst[i].set(outPoints[i].fX * scale, outPoints[i].fY * scale);
	}
	return count;
	};

	SkPoint tmp[kMaxClippedTrianglePointCount];
	int idx[] = { state.f0, state.f1, state.f2 };
	if (int n = clipTriangle(tmp, idx, dev3)) {
	// TODO: SkScan::FillConvexPoly(tmp, n, ...);
	SkASSERT(n == 3 \|\| n == 4);
	SkScan::FillTriangle(tmp, rc, blitter);
	if (n == 4) {
	tmp[1] = tmp[2];
	tmp[2] = tmp[3];
	SkScan::FillTriangle(tmp, rc, blitter);
	}
	}
	}

	static void fill_triangle(const VertState& state, SkBlitter* blitter, const SkRasterClip& rc,
	const SkPoint dev2[], const SkPoint3 dev3[]) {
	if (dev3) {
	fill_triangle_3(state, blitter, rc, dev3);
	} else {
	fill_triangle_2(state, blitter, rc, dev2);
	}
	}

	extern bool gUseSkVMBlitter;

	void SkDraw::drawFixedVertices(const SkVertices* vertices,
	sk_sp<SkBlender> blender,
	const SkPaint& paint,
	const SkMatrix& ctmInverse,
	const SkPoint* dev2,
	const SkPoint3* dev3,
	SkArenaAlloc* outerAlloc,
	bool skipColorXform) const {
	SkVerticesPriv info(vertices->priv());

	const int vertexCount = info.vertexCount();
	const int indexCount = info.indexCount();
	const SkPoint* positions = info.positions();
	const SkPoint* texCoords = info.texCoords();
	const uint16_t* indices = info.indices();
	const SkColor* colors = info.colors();

	SkShader* paintShader = paint.getShader();

	if (paintShader) {
	if (!texCoords) {
	texCoords = positions;
	}
	} else {
	texCoords = nullptr;
	}

	bool blenderIsDst = false;
	// We can simplify things for certain blend modes. This is for speed, and SkShader_Blend
	// itself insists we don't pass kSrc or kDst to it.
	if (std::optional<SkBlendMode> bm = as_BB(blender)->asBlendMode(); bm.has_value() && colors) {
	switch (*bm) {
	case SkBlendMode::kSrc:
	colors = nullptr;
	break;
	case SkBlendMode::kDst:
	blenderIsDst = true;
	texCoords = nullptr;
	paintShader = nullptr;
	break;
	default: break;
	}
	}

	// There is a paintShader iff there is texCoords.
	SkASSERT((texCoords != nullptr) == (paintShader != nullptr));

	SkMatrix ctm = fMatrixProvider->localToDevice();
	const bool usePerspective = ctm.hasPerspective();

	SkTriColorShader* triColorShader = nullptr;
	SkPMColor4f* dstColors = nullptr;
	if (colors) {
	dstColors =
	convert_colors(colors, vertexCount, fDst.colorSpace(), outerAlloc, skipColorXform);
	triColorShader = outerAlloc->make<SkTriColorShader>(compute_is_opaque(colors, vertexCount),
	usePerspective);
	}

	// Combines per-vertex colors with 'shader' using 'blender'.
	auto applyShaderColorBlend = [&](SkShader* shader) -> sk_sp<SkShader> {
	if (!colors) {
	return sk_ref_sp(shader);
	}
	if (blenderIsDst) {
	return sk_ref_sp(triColorShader);
	}
	sk_sp<SkShader> shaderWithWhichToBlend;
	if (!shader) {
	// When there is no shader then the blender applies to the vertex colors and opaque
	// paint color.
	shaderWithWhichToBlend = SkShaders::Color(paint.getColor4f().makeOpaque(), nullptr);
	} else {
	shaderWithWhichToBlend = sk_ref_sp(shader);
	}
	return SkShaders::Blend(blender,
	sk_ref_sp(triColorShader),
	std::move(shaderWithWhichToBlend));
	};

	auto rpblit = [&]() {
	VertState state(vertexCount, indices, indexCount);
	VertState::Proc vertProc = state.chooseProc(info.mode());
	sk_sp<SkShader> blendShader = applyShaderColorBlend(paintShader);
	SkSurfaceProps props = SkSurfacePropsCopyOrDefault(fProps);

	SkPaint shaderPaint(paint);
	shaderPaint.setShader(blendShader);

	if (!texCoords) { // only tricolor shader
	auto blitter = SkCreateRasterPipelineBlitter(fDst, shaderPaint, *fMatrixProvider,
	outerAlloc, this->fRC->clipShader(),
	props);
	if (!blitter) {
	return false;
	}
	while (vertProc(&state)) {
	if (triColorShader && !triColorShader->update(ctmInverse, positions, dstColors,
	state.f0, state.f1, state.f2)) {
	continue;
	}
	fill_triangle(state, blitter, *fRC, dev2, dev3);
	}
	return true;
	}

	SkRasterPipeline pipeline(outerAlloc);
	SkStageRec rec = {&pipeline,
	outerAlloc,
	fDst.colorType(),
	fDst.colorSpace(),
	shaderPaint,
	nullptr,
	*fMatrixProvider,
	props};
	if (auto updater = as_SB(blendShader)->appendUpdatableStages(rec)) {
	bool isOpaque = blendShader->isOpaque();
	if (triColorShader) {
	isOpaque = false; // unless we want to walk all the colors, and see if they are
	// all opaque (and the blend mode will keep them that way
	}

	// Positions as texCoords? The local matrix is always identity, so update once
	if (texCoords == positions) {
	if (!updater->update(ctm)) {
	return true;
	}
	}

	auto blitter = SkCreateRasterPipelineBlitter(
	fDst, shaderPaint, pipeline, isOpaque, outerAlloc, fRC->clipShader());
	if (!blitter) {
	return false;
	}
	while (vertProc(&state)) {
	if (triColorShader && !triColorShader->update(ctmInverse, positions, dstColors,
	state.f0, state.f1, state.f2)) {
	continue;
	}

	SkMatrix localM;
	if ((texCoords == positions) \|\|
	(texture_to_matrix(state, positions, texCoords, &localM) &&
	updater->update(SkMatrix::Concat(ctm, localM)))) {
	fill_triangle(state, blitter, *fRC, dev2, dev3);
	}
	}
	} else {
	// must rebuild pipeline for each triangle, to pass in the computed ctm
	while (vertProc(&state)) {
	if (triColorShader && !triColorShader->update(ctmInverse, positions, dstColors,
	state.f0, state.f1, state.f2)) {
	continue;
	}

	SkSTArenaAlloc<2048> innerAlloc;

	const SkMatrixProvider* matrixProvider = fMatrixProvider;
	SkTLazy<SkPreConcatMatrixProvider> preConcatMatrixProvider;
	if (texCoords && (texCoords != positions)) {
	SkMatrix localM;
	if (!texture_to_matrix(state, positions, texCoords, &localM)) {
	continue;
	}
	matrixProvider = preConcatMatrixProvider.init(*matrixProvider, localM);
	}

	// It'd be nice if we could detect this will fail earlier.
	auto blitter = SkCreateRasterPipelineBlitter(fDst, shaderPaint, *matrixProvider,
	&innerAlloc, this->fRC->clipShader(),
	props);
	if (!blitter) {
	return false;
	}
	fill_triangle(state, blitter, *fRC, dev2, dev3);
	}
	}
	return true;
	};

	if (gUseSkVMBlitter \|\| !rpblit()) {
	VertState state(vertexCount, indices, indexCount);
	VertState::Proc vertProc = state.chooseProc(info.mode());

	// No colors are changing and no texture coordinates are changing, so no updates between
	// triangles are needed. Use SkVM to blit the triangles.
	SkShader* shader = paintShader;
	SkUpdatableShader* texCoordShader = nullptr;
	if (texCoords && texCoords != positions) {
	texCoordShader = as_SB(shader)->updatableShader(outerAlloc);
	shader = texCoordShader;
	}
	sk_sp<SkShader> blenderShader = applyShaderColorBlend(shader);

	SkPaint shaderPaint{paint};
	shaderPaint.setShader(std::move(blenderShader));
	auto blitter = SkVMBlitter::Make(
	fDst, shaderPaint, *fMatrixProvider, outerAlloc, this->fRC->clipShader());
	if (!blitter) {
	return;
	}
	while (vertProc(&state)) {
	SkMatrix localM;
	if (texCoordShader && !(texture_to_matrix(state, positions, texCoords, &localM) &&
	texCoordShader->update(SkMatrix::Concat(ctm, localM)))) {
	continue;
	}

	if (triColorShader && !triColorShader->update(ctmInverse, positions, dstColors,state.f0,
	state.f1, state.f2)) {
	continue;
	}

	fill_triangle(state, blitter, *fRC, dev2, dev3);
	}
	}
	}

	void SkDraw::drawVertices(const SkVertices* vertices,
	sk_sp<SkBlender> blender,
	const SkPaint& paint,
	bool skipColorXform) const {
	SkVerticesPriv info(vertices->priv());
	const int vertexCount = info.vertexCount();
	const int indexCount = info.indexCount();

	// abort early if there is nothing to draw
	if (vertexCount < 3 \|\| (indexCount > 0 && indexCount < 3) \|\| fRC->isEmpty()) {
	return;
	}
	SkMatrix ctm = fMatrixProvider->localToDevice();
	SkMatrix ctmInv;
	if (!ctm.invert(&ctmInv)) {
	return;
	}

	constexpr size_t kDefVertexCount = 16;
	constexpr size_t kOuterSize = sizeof(SkTriColorShader) +
	(2 * sizeof(SkPoint) + sizeof(SkColor4f)) * kDefVertexCount;
	SkSTArenaAlloc<kOuterSize> outerAlloc;

	SkPoint* dev2 = nullptr;
	SkPoint3* dev3 = nullptr;

	if (ctm.hasPerspective()) {
	dev3 = outerAlloc.makeArray<SkPoint3>(vertexCount);
	ctm.mapHomogeneousPoints(dev3, info.positions(), vertexCount);
	// similar to the bounds check for 2d points (below)
	if (!SkScalarsAreFinite((const SkScalar)dev3, vertexCount 3)) {
	return;
	}
	} else {
	dev2 = outerAlloc.makeArray<SkPoint>(vertexCount);
	ctm.mapPoints(dev2, info.positions(), vertexCount);

	SkRect bounds;
	// this also sets bounds to empty if we see a non-finite value
	bounds.setBounds(dev2, vertexCount);
	if (bounds.isEmpty()) {
	return;
	}
	}

	this->drawFixedVertices(
	vertices, std::move(blender), paint, ctmInv, dev2, dev3, &outerAlloc, skipColorXform);
	}