/* * 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 "SkShadowTessellator.h" #include "SkColorPriv.h" #include "SkDrawShadowInfo.h" #include "SkGeometry.h" #include "SkInsetConvexPolygon.h" #include "SkPath.h" #include "SkPoint3.h" #include "SkVertices.h" #if SK_SUPPORT_GPU #include "GrPathUtils.h" #endif /** * Base class */ class SkBaseShadowTessellator { public: SkBaseShadowTessellator(const SkPoint3& zPlaneParams, bool transparent); virtual ~SkBaseShadowTessellator() {} sk_sp releaseVertices() { if (!fSucceeded) { return nullptr; } return SkVertices::MakeCopy(SkVertices::kTriangles_VertexMode, this->vertexCount(), fPositions.begin(), nullptr, fColors.begin(), this->indexCount(), fIndices.begin()); } protected: static constexpr auto kMinHeight = 0.1f; int vertexCount() const { return fPositions.count(); } int indexCount() const { return fIndices.count(); } bool setZOffset(const SkRect& bounds, bool perspective); virtual void handleLine(const SkPoint& p) = 0; void handleLine(const SkMatrix& m, SkPoint* p); void handleQuad(const SkPoint pts[3]); void handleQuad(const SkMatrix& m, SkPoint pts[3]); void handleCubic(const SkMatrix& m, SkPoint pts[4]); void handleConic(const SkMatrix& m, SkPoint pts[3], SkScalar w); bool setTransformedHeightFunc(const SkMatrix& ctm); bool addArc(const SkVector& nextNormal, bool finishArc); SkScalar heightFunc(SkScalar x, SkScalar y) { return fZPlaneParams.fX*x + fZPlaneParams.fY*y + fZPlaneParams.fZ; } SkPoint3 fZPlaneParams; std::function fTransformedHeightFunc; SkScalar fZOffset; // members for perspective height function SkPoint3 fTransformedZParams; SkScalar fPartialDeterminants[3]; // first two points SkTDArray fInitPoints; // temporary buffer SkTDArray fPointBuffer; SkTDArray fPositions; SkTDArray fColors; SkTDArray fIndices; int fFirstVertexIndex; SkVector fFirstOutset; SkPoint fFirstPoint; bool fSucceeded; bool fTransparent; SkColor fUmbraColor; SkColor fPenumbraColor; SkScalar fRadius; SkScalar fDirection; int fPrevUmbraIndex; SkVector fPrevOutset; SkPoint fPrevPoint; }; static bool compute_normal(const SkPoint& p0, const SkPoint& p1, SkScalar dir, SkVector* newNormal) { SkVector normal; // compute perpendicular normal.fX = p0.fY - p1.fY; normal.fY = p1.fX - p0.fX; normal *= dir; if (!normal.normalize()) { return false; } *newNormal = normal; return true; } static void compute_radial_steps(const SkVector& v1, const SkVector& v2, SkScalar r, SkScalar* rotSin, SkScalar* rotCos, int* n) { const SkScalar kRecipPixelsPerArcSegment = 0.125f; SkScalar rCos = v1.dot(v2); SkScalar rSin = v1.cross(v2); SkScalar theta = SkScalarATan2(rSin, rCos); int steps = SkScalarFloorToInt(r*theta*kRecipPixelsPerArcSegment); SkScalar dTheta = theta / steps; *rotSin = SkScalarSinCos(dTheta, rotCos); *n = steps; } SkBaseShadowTessellator::SkBaseShadowTessellator(const SkPoint3& zPlaneParams, bool transparent) : fZPlaneParams(zPlaneParams) , fZOffset(0) , fFirstVertexIndex(-1) , fSucceeded(false) , fTransparent(transparent) , fDirection(1) , fPrevUmbraIndex(-1) { fInitPoints.setReserve(3); // child classes will set reserve for positions, colors and indices } bool SkBaseShadowTessellator::setZOffset(const SkRect& bounds, bool perspective) { SkScalar minZ = this->heightFunc(bounds.fLeft, bounds.fTop); if (perspective) { SkScalar z = this->heightFunc(bounds.fLeft, bounds.fBottom); if (z < minZ) { minZ = z; } z = this->heightFunc(bounds.fRight, bounds.fTop); if (z < minZ) { minZ = z; } z = this->heightFunc(bounds.fRight, bounds.fBottom); if (z < minZ) { minZ = z; } } if (minZ < kMinHeight) { fZOffset = -minZ + kMinHeight; return true; } return false; } // tesselation tolerance values, in device space pixels #if SK_SUPPORT_GPU static const SkScalar kQuadTolerance = 0.2f; static const SkScalar kCubicTolerance = 0.2f; #endif static const SkScalar kConicTolerance = 0.5f; void SkBaseShadowTessellator::handleLine(const SkMatrix& m, SkPoint* p) { m.mapPoints(p, 1); this->handleLine(*p); } void SkBaseShadowTessellator::handleQuad(const SkPoint pts[3]) { #if SK_SUPPORT_GPU // TODO: Pull PathUtils out of Ganesh? int maxCount = GrPathUtils::quadraticPointCount(pts, kQuadTolerance); fPointBuffer.setReserve(maxCount); SkPoint* target = fPointBuffer.begin(); int count = GrPathUtils::generateQuadraticPoints(pts[0], pts[1], pts[2], kQuadTolerance, &target, maxCount); fPointBuffer.setCount(count); for (int i = 0; i < count; i++) { this->handleLine(fPointBuffer[i]); } #else // for now, just to draw something this->handleLine(pts[1]); this->handleLine(pts[2]); #endif } void SkBaseShadowTessellator::handleQuad(const SkMatrix& m, SkPoint pts[3]) { m.mapPoints(pts, 3); this->handleQuad(pts); } void SkBaseShadowTessellator::handleCubic(const SkMatrix& m, SkPoint pts[4]) { m.mapPoints(pts, 4); #if SK_SUPPORT_GPU // TODO: Pull PathUtils out of Ganesh? int maxCount = GrPathUtils::cubicPointCount(pts, kCubicTolerance); fPointBuffer.setReserve(maxCount); SkPoint* target = fPointBuffer.begin(); int count = GrPathUtils::generateCubicPoints(pts[0], pts[1], pts[2], pts[3], kCubicTolerance, &target, maxCount); fPointBuffer.setCount(count); for (int i = 0; i < count; i++) { this->handleLine(fPointBuffer[i]); } #else // for now, just to draw something this->handleLine(pts[1]); this->handleLine(pts[2]); this->handleLine(pts[3]); #endif } void SkBaseShadowTessellator::handleConic(const SkMatrix& m, SkPoint pts[3], SkScalar w) { if (m.hasPerspective()) { w = SkConic::TransformW(pts, w, m); } m.mapPoints(pts, 3); SkAutoConicToQuads quadder; const SkPoint* quads = quadder.computeQuads(pts, w, kConicTolerance); SkPoint lastPoint = *(quads++); int count = quadder.countQuads(); for (int i = 0; i < count; ++i) { SkPoint quadPts[3]; quadPts[0] = lastPoint; quadPts[1] = quads[0]; quadPts[2] = i == count - 1 ? pts[2] : quads[1]; this->handleQuad(quadPts); lastPoint = quadPts[2]; quads += 2; } } bool SkBaseShadowTessellator::addArc(const SkVector& nextNormal, bool finishArc) { // fill in fan from previous quad SkScalar rotSin, rotCos; int numSteps; compute_radial_steps(fPrevOutset, nextNormal, fRadius, &rotSin, &rotCos, &numSteps); SkVector prevNormal = fPrevOutset; for (int i = 0; i < numSteps-1; ++i) { SkVector currNormal; currNormal.fX = prevNormal.fX*rotCos - prevNormal.fY*rotSin; currNormal.fY = prevNormal.fY*rotCos + prevNormal.fX*rotSin; *fPositions.push() = fPrevPoint + currNormal; *fColors.push() = fPenumbraColor; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 2; prevNormal = currNormal; } if (finishArc && numSteps) { *fPositions.push() = fPrevPoint + nextNormal; *fColors.push() = fPenumbraColor; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 2; } fPrevOutset = nextNormal; return (numSteps > 0); } bool SkBaseShadowTessellator::setTransformedHeightFunc(const SkMatrix& ctm) { if (SkScalarNearlyZero(fZPlaneParams.fX) && SkScalarNearlyZero(fZPlaneParams.fY)) { fTransformedHeightFunc = [this](const SkPoint& p) { return fZPlaneParams.fZ; }; } else { SkMatrix ctmInverse; if (!ctm.invert(&ctmInverse)) { return false; } // multiply by transpose fTransformedZParams = SkPoint3::Make( ctmInverse[SkMatrix::kMScaleX] * fZPlaneParams.fX + ctmInverse[SkMatrix::kMSkewY] * fZPlaneParams.fY + ctmInverse[SkMatrix::kMPersp0] * fZPlaneParams.fZ, ctmInverse[SkMatrix::kMSkewX] * fZPlaneParams.fX + ctmInverse[SkMatrix::kMScaleY] * fZPlaneParams.fY + ctmInverse[SkMatrix::kMPersp1] * fZPlaneParams.fZ, ctmInverse[SkMatrix::kMTransX] * fZPlaneParams.fX + ctmInverse[SkMatrix::kMTransY] * fZPlaneParams.fY + ctmInverse[SkMatrix::kMPersp2] * fZPlaneParams.fZ ); if (ctm.hasPerspective()) { // We use Cramer's rule to solve for the W value for a given post-divide X and Y, // so pre-compute those values that are independent of X and Y. // W is det(ctmInverse)/(PD[0]*X + PD[1]*Y + PD[2]) fPartialDeterminants[0] = ctm[SkMatrix::kMSkewY] * ctm[SkMatrix::kMPersp1] - ctm[SkMatrix::kMScaleY] * ctm[SkMatrix::kMPersp0]; fPartialDeterminants[1] = ctm[SkMatrix::kMPersp0] * ctm[SkMatrix::kMSkewX] - ctm[SkMatrix::kMPersp1] * ctm[SkMatrix::kMScaleX]; fPartialDeterminants[2] = ctm[SkMatrix::kMScaleX] * ctm[SkMatrix::kMScaleY] - ctm[SkMatrix::kMSkewX] * ctm[SkMatrix::kMSkewY]; SkScalar ctmDeterminant = ctm[SkMatrix::kMTransX] * fPartialDeterminants[0] + ctm[SkMatrix::kMTransY] * fPartialDeterminants[1] + ctm[SkMatrix::kMPersp2] * fPartialDeterminants[2]; // Pre-bake the numerator of Cramer's rule into the zParams to avoid another multiply. // TODO: this may introduce numerical instability, but I haven't seen any issues yet. fTransformedZParams.fX *= ctmDeterminant; fTransformedZParams.fY *= ctmDeterminant; fTransformedZParams.fZ *= ctmDeterminant; fTransformedHeightFunc = [this](const SkPoint& p) { SkScalar denom = p.fX * fPartialDeterminants[0] + p.fY * fPartialDeterminants[1] + fPartialDeterminants[2]; SkScalar w = SkScalarFastInvert(denom); return fZOffset + w*(fTransformedZParams.fX * p.fX + fTransformedZParams.fY * p.fY + fTransformedZParams.fZ); }; } else { fTransformedHeightFunc = [this](const SkPoint& p) { return fZOffset + fTransformedZParams.fX * p.fX + fTransformedZParams.fY * p.fY + fTransformedZParams.fZ; }; } } return true; } ////////////////////////////////////////////////////////////////////////////////////////////////// class SkAmbientShadowTessellator : public SkBaseShadowTessellator { public: SkAmbientShadowTessellator(const SkPath& path, const SkMatrix& ctm, const SkPoint3& zPlaneParams, bool transparent); private: void handleLine(const SkPoint& p) override; void addEdge(const SkVector& nextPoint, const SkVector& nextNormal); static constexpr auto kMaxEdgeLenSqr = 20 * 20; static constexpr auto kInsetFactor = -0.5f; SkScalar offset(SkScalar z) { return SkDrawShadowMetrics::AmbientBlurRadius(z); } SkColor umbraColor(SkScalar z) { SkScalar umbraAlpha = SkScalarInvert(SkDrawShadowMetrics::AmbientRecipAlpha(z)); return SkColorSetARGB(umbraAlpha * 255.9999f, 0, 0, 0); } int fCentroidCount; bool fSplitFirstEdge; bool fSplitPreviousEdge; typedef SkBaseShadowTessellator INHERITED; }; SkAmbientShadowTessellator::SkAmbientShadowTessellator(const SkPath& path, const SkMatrix& ctm, const SkPoint3& zPlaneParams, bool transparent) : INHERITED(zPlaneParams, transparent) , fSplitFirstEdge(false) , fSplitPreviousEdge(false) { // Set base colors SkScalar umbraAlpha = SkScalarInvert(SkDrawShadowMetrics::AmbientRecipAlpha(heightFunc(0, 0))); // umbraColor is the interior value, penumbraColor the exterior value. // umbraAlpha is the factor that is linearly interpolated from outside to inside, and // then "blurred" by the GrBlurredEdgeFP. It is then multiplied by fAmbientAlpha to get // the final alpha. fUmbraColor = SkColorSetARGB(umbraAlpha * 255.9999f, 0, 0, 0); fPenumbraColor = SkColorSetARGB(0, 0, 0, 0); // make sure we're not below the canvas plane this->setZOffset(path.getBounds(), ctm.hasPerspective()); this->setTransformedHeightFunc(ctm); // Outer ring: 3*numPts // Middle ring: numPts fPositions.setReserve(4 * path.countPoints()); fColors.setReserve(4 * path.countPoints()); // Outer ring: 12*numPts // Middle ring: 0 fIndices.setReserve(12 * path.countPoints()); // walk around the path, tessellate and generate outer ring // if original path is transparent, will accumulate sum of points for centroid SkPath::Iter iter(path, true); SkPoint pts[4]; SkPath::Verb verb; if (fTransparent) { *fPositions.push() = SkPoint::Make(0, 0); *fColors.push() = fUmbraColor; fCentroidCount = 0; } while ((verb = iter.next(pts)) != SkPath::kDone_Verb) { switch (verb) { case SkPath::kLine_Verb: this->INHERITED::handleLine(ctm, &pts[1]); break; case SkPath::kQuad_Verb: this->handleQuad(ctm, pts); break; case SkPath::kCubic_Verb: this->handleCubic(ctm, pts); break; case SkPath::kConic_Verb: this->handleConic(ctm, pts, iter.conicWeight()); break; case SkPath::kMove_Verb: case SkPath::kClose_Verb: case SkPath::kDone_Verb: break; } } if (!this->indexCount()) { return; } // Finish up SkVector normal; if (compute_normal(fPrevPoint, fFirstPoint, fDirection, &normal)) { SkScalar z = fTransformedHeightFunc(fPrevPoint); fRadius = this->offset(z); SkVector scaledNormal(normal); scaledNormal *= fRadius; this->addArc(scaledNormal, true); // fix-up the last and first umbra points SkVector inset = normal; // adding to an average, so multiply by an additional half inset *= 0.5f*kInsetFactor; fPositions[fPrevUmbraIndex] += inset; fPositions[fFirstVertexIndex] += inset; // we multiply by another half because now we're adding to an average of an average inset *= 0.5f; if (fSplitPreviousEdge) { fPositions[fPrevUmbraIndex - 2] += inset; } if (fSplitFirstEdge) { fPositions[fFirstVertexIndex + 2] += inset; } // set up for final edge z = fTransformedHeightFunc(fFirstPoint); normal *= this->offset(z); // make sure we don't end up with a sharp alpha edge along the quad diagonal if (fColors[fPrevUmbraIndex] != fColors[fFirstVertexIndex] && fFirstPoint.distanceToSqd(fPositions[fPrevUmbraIndex]) > kMaxEdgeLenSqr) { SkPoint centerPoint = fPositions[fPrevUmbraIndex] + fPositions[fFirstVertexIndex]; centerPoint *= 0.5f; *fPositions.push() = centerPoint; *fColors.push() = SkPMLerp(fColors[fFirstVertexIndex], fColors[fPrevUmbraIndex], 128); centerPoint = fPositions[fPositions.count()-2] + fPositions[fFirstVertexIndex+1]; centerPoint *= 0.5f; *fPositions.push() = centerPoint; *fColors.push() = fPenumbraColor; if (fColors[fPrevUmbraIndex] > fColors[fPositions.count() - 2]) { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 3; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 3; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 2; } else { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 3; } // if transparent, add point to first one in array and add to center fan if (fTransparent) { fPositions[0] += centerPoint; ++fCentroidCount; *fIndices.push() = 0; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; } fPrevUmbraIndex = fPositions.count() - 2; } // final edge *fPositions.push() = fFirstPoint + normal; *fColors.push() = fPenumbraColor; if (fColors[fPrevUmbraIndex] > fColors[fFirstVertexIndex]) { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fFirstVertexIndex; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fFirstVertexIndex; } else { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fFirstVertexIndex; } fPrevOutset = normal; } // finalize centroid if (fTransparent) { fPositions[0] *= SkScalarFastInvert(fCentroidCount); fColors[0] = this->umbraColor(fTransformedHeightFunc(fPositions[0])); *fIndices.push() = 0; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fFirstVertexIndex; } // final fan if (fPositions.count() >= 3) { fPrevUmbraIndex = fFirstVertexIndex; fPrevPoint = fFirstPoint; fRadius = this->offset(fTransformedHeightFunc(fPrevPoint)); if (this->addArc(fFirstOutset, false)) { *fIndices.push() = fFirstVertexIndex; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fFirstVertexIndex + 1; } else { // arc is too small, set the first penumbra point to be the same position // as the last one fPositions[fFirstVertexIndex + 1] = fPositions[fPositions.count() - 1]; } } fSucceeded = true; } void SkAmbientShadowTessellator::handleLine(const SkPoint& p) { if (fInitPoints.count() < 2) { *fInitPoints.push() = p; return; } if (fInitPoints.count() == 2) { // determine if cw or ccw SkVector v0 = fInitPoints[1] - fInitPoints[0]; SkVector v1 = p - fInitPoints[0]; SkScalar perpDot = v0.fX*v1.fY - v0.fY*v1.fX; if (SkScalarNearlyZero(perpDot)) { // nearly parallel, just treat as straight line and continue fInitPoints[1] = p; return; } // if perpDot > 0, winding is ccw fDirection = (perpDot > 0) ? -1 : 1; // add first quad SkVector normal; if (!compute_normal(fInitPoints[0], fInitPoints[1], fDirection, &normal)) { // first two points are incident, make the third point the second and continue fInitPoints[1] = p; return; } fFirstPoint = fInitPoints[0]; fFirstVertexIndex = fPositions.count(); SkScalar z = fTransformedHeightFunc(fFirstPoint); fFirstOutset = normal; fFirstOutset *= this->offset(z); fPrevOutset = fFirstOutset; fPrevPoint = fFirstPoint; fPrevUmbraIndex = fFirstVertexIndex; *fPositions.push() = fFirstPoint; *fColors.push() = this->umbraColor(z); *fPositions.push() = fFirstPoint + fFirstOutset; *fColors.push() = fPenumbraColor; if (fTransparent) { fPositions[0] += fFirstPoint; fCentroidCount = 1; } // add the first quad z = fTransformedHeightFunc(fInitPoints[1]); fRadius = this->offset(z); fUmbraColor = this->umbraColor(z); this->addEdge(fInitPoints[1], normal); // to ensure we skip this block next time *fInitPoints.push() = p; } SkVector normal; if (compute_normal(fPrevPoint, p, fDirection, &normal)) { SkVector scaledNormal = normal; scaledNormal *= fRadius; this->addArc(scaledNormal, true); SkScalar z = fTransformedHeightFunc(p); fRadius = this->offset(z); fUmbraColor = this->umbraColor(z); this->addEdge(p, normal); } } void SkAmbientShadowTessellator::addEdge(const SkPoint& nextPoint, const SkVector& nextNormal) { // We compute the inset in two stages: first we inset by half the current normal, // then on the next addEdge() we add half of the next normal to get an average of the two SkVector insetNormal = nextNormal; insetNormal *= 0.5f*kInsetFactor; // Adding the other half of the average for the previous edge fPositions[fPrevUmbraIndex] += insetNormal; SkPoint umbraPoint = nextPoint + insetNormal; SkVector outsetNormal = nextNormal; outsetNormal *= fRadius; SkPoint penumbraPoint = nextPoint + outsetNormal; // For split edges, we're adding an average of two averages, so we multiply by another half if (fSplitPreviousEdge) { insetNormal *= 0.5f; fPositions[fPrevUmbraIndex - 2] += insetNormal; } // Split the edge to make sure we don't end up with a sharp alpha edge along the quad diagonal if (fColors[fPrevUmbraIndex] != fUmbraColor && nextPoint.distanceToSqd(fPositions[fPrevUmbraIndex]) > kMaxEdgeLenSqr) { // This is lacking 1/4 of the next inset -- we'll add it the next time we call addEdge() SkPoint centerPoint = fPositions[fPrevUmbraIndex] + umbraPoint; centerPoint *= 0.5f; *fPositions.push() = centerPoint; *fColors.push() = SkPMLerp(fUmbraColor, fColors[fPrevUmbraIndex], 128); centerPoint = fPositions[fPositions.count()-2] + penumbraPoint; centerPoint *= 0.5f; *fPositions.push() = centerPoint; *fColors.push() = fPenumbraColor; // set triangularization to get best interpolation of color if (fColors[fPrevUmbraIndex] > fColors[fPositions.count() - 2]) { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 3; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 3; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 2; } else { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 3; } // if transparent, add point to first one in array and add to center fan if (fTransparent) { fPositions[0] += centerPoint; ++fCentroidCount; *fIndices.push() = 0; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; } fSplitPreviousEdge = true; if (fPrevUmbraIndex == fFirstVertexIndex) { fSplitFirstEdge = true; } fPrevUmbraIndex = fPositions.count() - 2; } else { fSplitPreviousEdge = false; } // add next quad *fPositions.push() = umbraPoint; *fColors.push() = fUmbraColor; *fPositions.push() = penumbraPoint; *fColors.push() = fPenumbraColor; // set triangularization to get best interpolation of color if (fColors[fPrevUmbraIndex] > fColors[fPositions.count() - 2]) { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 3; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 3; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 2; } else { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 3; } // if transparent, add point to first one in array and add to center fan if (fTransparent) { fPositions[0] += nextPoint; ++fCentroidCount; *fIndices.push() = 0; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; } fPrevUmbraIndex = fPositions.count() - 2; fPrevPoint = nextPoint; fPrevOutset = outsetNormal; } /////////////////////////////////////////////////////////////////////////////////////////////////// class SkSpotShadowTessellator : public SkBaseShadowTessellator { public: SkSpotShadowTessellator(const SkPath& path, const SkMatrix& ctm, const SkPoint3& zPlaneParams, const SkPoint3& lightPos, SkScalar lightRadius, bool transparent); private: void computeClipAndPathPolygons(const SkPath& path, const SkMatrix& ctm, const SkMatrix& shadowTransform); void computeClipVectorsAndTestCentroid(); bool clipUmbraPoint(const SkPoint& umbraPoint, const SkPoint& centroid, SkPoint* clipPoint); int getClosestUmbraPoint(const SkPoint& point); void handleLine(const SkPoint& p) override; bool handlePolyPoint(const SkPoint& p); void mapPoints(SkScalar scale, const SkVector& xlate, SkPoint* pts, int count); bool addInnerPoint(const SkPoint& pathPoint); void addEdge(const SkVector& nextPoint, const SkVector& nextNormal); SkScalar offset(SkScalar z) { float zRatio = SkTPin(z / (fLightZ - z), 0.0f, 0.95f); return fLightRadius*zRatio; } SkScalar fLightZ; SkScalar fLightRadius; SkScalar fOffsetAdjust; SkTDArray fClipPolygon; SkTDArray fClipVectors; SkPoint fCentroid; SkScalar fArea; SkTDArray fPathPolygon; SkTDArray fUmbraPolygon; int fCurrClipPoint; int fCurrUmbraPoint; bool fPrevUmbraOutside; bool fFirstUmbraOutside; bool fValidUmbra; typedef SkBaseShadowTessellator INHERITED; }; SkSpotShadowTessellator::SkSpotShadowTessellator(const SkPath& path, const SkMatrix& ctm, const SkPoint3& zPlaneParams, const SkPoint3& lightPos, SkScalar lightRadius, bool transparent) : INHERITED(zPlaneParams, transparent) , fLightZ(lightPos.fZ) , fLightRadius(lightRadius) , fOffsetAdjust(0) , fCurrClipPoint(0) , fPrevUmbraOutside(false) , fFirstUmbraOutside(false) , fValidUmbra(true) { // make sure we're not below the canvas plane if (this->setZOffset(path.getBounds(), ctm.hasPerspective())) { // Adjust light height and radius fLightRadius *= (fLightZ + fZOffset) / fLightZ; fLightZ += fZOffset; } // Set radius and colors SkPoint center = SkPoint::Make(path.getBounds().centerX(), path.getBounds().centerY()); SkScalar occluderHeight = this->heightFunc(center.fX, center.fY) + fZOffset; fUmbraColor = SkColorSetARGB(255, 0, 0, 0); fPenumbraColor = SkColorSetARGB(0, 0, 0, 0); // Compute the blur radius, scale and translation for the spot shadow. SkScalar radius; SkMatrix shadowTransform; if (!ctm.hasPerspective()) { SkScalar scale; SkVector translate; SkDrawShadowMetrics::GetSpotParams(occluderHeight, lightPos.fX, lightPos.fY, fLightZ, lightRadius, &radius, &scale, &translate); shadowTransform.setScaleTranslate(scale, scale, translate.fX, translate.fY); } else { // For perspective, we have a scale, a z-shear, and another projective divide -- // this varies at each point so we can't use an affine transform. // We'll just apply this to each generated point in turn. shadowTransform.reset(); // Also can't cull the center (for now). fTransparent = true; radius = SkDrawShadowMetrics::SpotBlurRadius(occluderHeight, lightPos.fZ, lightRadius); } fRadius = radius; SkMatrix fullTransform = SkMatrix::Concat(shadowTransform, ctm); // Set up our reverse mapping this->setTransformedHeightFunc(fullTransform); // TODO: calculate these reserves better // Penumbra ring: 3*numPts // Umbra ring: numPts // Inner ring: numPts fPositions.setReserve(5 * path.countPoints()); fColors.setReserve(5 * path.countPoints()); // Penumbra ring: 12*numPts // Umbra ring: 3*numPts fIndices.setReserve(15 * path.countPoints()); fClipPolygon.setReserve(path.countPoints()); // compute rough clip bounds for umbra, plus offset polygon, plus centroid this->computeClipAndPathPolygons(path, ctm, shadowTransform); if (fClipPolygon.count() < 3 || fPathPolygon.count() < 3) { return; } // check to see if umbra collapses SkScalar minDistSq = fCentroid.distanceToLineSegmentBetweenSqd(fPathPolygon[0], fPathPolygon[1]); SkRect bounds; bounds.setBounds(&fPathPolygon[0], fPathPolygon.count()); for (int i = 1; i < fPathPolygon.count(); ++i) { int j = i + 1; if (i == fPathPolygon.count() - 1) { j = 0; } SkPoint currPoint = fPathPolygon[i]; SkPoint nextPoint = fPathPolygon[j]; SkScalar distSq = fCentroid.distanceToLineSegmentBetweenSqd(currPoint, nextPoint); if (distSq < minDistSq) { minDistSq = distSq; } } static constexpr auto kTolerance = 1.0e-2f; if (minDistSq < (radius + kTolerance)*(radius + kTolerance)) { // if the umbra would collapse, we back off a bit on inner blur and adjust the alpha SkScalar newRadius = SkScalarSqrt(minDistSq) - kTolerance; fOffsetAdjust = newRadius - radius; SkScalar ratio = 128 * (newRadius + radius) / radius; // they aren't PMColors, but the interpolation algorithm is the same fUmbraColor = SkPMLerp(fUmbraColor, fPenumbraColor, (unsigned)ratio); radius = newRadius; } // compute vectors for clip tests this->computeClipVectorsAndTestCentroid(); // generate inner ring if (!SkInsetConvexPolygon(&fPathPolygon[0], fPathPolygon.count(), radius, &fUmbraPolygon)) { // this shouldn't happen, but just in case we'll inset using the centroid fValidUmbra = false; } // walk around the path polygon, generate outer ring and connect to inner ring if (fTransparent) { *fPositions.push() = fCentroid; *fColors.push() = fUmbraColor; } fCurrUmbraPoint = 0; for (int i = 0; i < fPathPolygon.count(); ++i) { if (!this->handlePolyPoint(fPathPolygon[i])) { return; } } if (!this->indexCount()) { return; } // finish up the final verts SkVector normal; if (compute_normal(fPrevPoint, fFirstPoint, fDirection, &normal)) { normal *= fRadius; this->addArc(normal, true); // add to center fan if (fTransparent) { *fIndices.push() = 0; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fFirstVertexIndex; // or to clip ring } else { if (fFirstUmbraOutside) { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fFirstVertexIndex; *fIndices.push() = fFirstVertexIndex + 1; if (fPrevUmbraOutside) { // fill out quad *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fFirstVertexIndex + 1; *fIndices.push() = fPrevUmbraIndex + 1; } } else if (fPrevUmbraOutside) { // add tri *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fFirstVertexIndex; *fIndices.push() = fPrevUmbraIndex + 1; } } // add final edge *fPositions.push() = fFirstPoint + normal; *fColors.push() = fPenumbraColor; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fFirstVertexIndex; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fFirstVertexIndex; fPrevOutset = normal; } // final fan if (fPositions.count() >= 3) { fPrevUmbraIndex = fFirstVertexIndex; fPrevPoint = fFirstPoint; if (this->addArc(fFirstOutset, false)) { *fIndices.push() = fFirstVertexIndex; *fIndices.push() = fPositions.count() - 1; if (fFirstUmbraOutside) { *fIndices.push() = fFirstVertexIndex + 2; } else { *fIndices.push() = fFirstVertexIndex + 1; } } else { // no arc added, fix up by setting first penumbra point position to last one if (fFirstUmbraOutside) { fPositions[fFirstVertexIndex + 2] = fPositions[fPositions.count() - 1]; } else { fPositions[fFirstVertexIndex + 1] = fPositions[fPositions.count() - 1]; } } } if (ctm.hasPerspective()) { for (int i = 0; i < fPositions.count(); ++i) { SkScalar pathZ = fTransformedHeightFunc(fPositions[i]); SkScalar factor = SkScalarInvert(fLightZ - pathZ); fPositions[i].fX = (fPositions[i].fX*fLightZ - lightPos.fX*pathZ)*factor; fPositions[i].fY = (fPositions[i].fY*fLightZ - lightPos.fY*pathZ)*factor; } #ifdef DRAW_CENTROID SkScalar pathZ = fTransformedHeightFunc(fCentroid); SkScalar factor = SkScalarInvert(fLightZ - pathZ); fCentroid.fX = (fCentroid.fX*fLightZ - lightPos.fX*pathZ)*factor; fCentroid.fY = (fCentroid.fY*fLightZ - lightPos.fY*pathZ)*factor; #endif } #ifdef DRAW_CENTROID *fPositions.push() = fCentroid + SkVector::Make(-2, -2); *fColors.push() = SkColorSetARGB(255, 0, 255, 255); *fPositions.push() = fCentroid + SkVector::Make(2, -2); *fColors.push() = SkColorSetARGB(255, 0, 255, 255); *fPositions.push() = fCentroid + SkVector::Make(-2, 2); *fColors.push() = SkColorSetARGB(255, 0, 255, 255); *fPositions.push() = fCentroid + SkVector::Make(2, 2); *fColors.push() = SkColorSetARGB(255, 0, 255, 255); *fIndices.push() = fPositions.count() - 4; *fIndices.push() = fPositions.count() - 2; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 4; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = fPositions.count() - 3; #endif fSucceeded = true; } void SkSpotShadowTessellator::computeClipAndPathPolygons(const SkPath& path, const SkMatrix& ctm, const SkMatrix& shadowTransform) { fPathPolygon.setReserve(path.countPoints()); // Walk around the path and compute clip polygon and path polygon. // Will also accumulate sum of areas for centroid. // For Bezier curves, we compute additional interior points on curve. SkPath::Iter iter(path, true); SkPoint pts[4]; SkPath::Verb verb; fClipPolygon.reset(); // init centroid fCentroid = SkPoint::Make(0, 0); fArea = 0; // coefficients to compute cubic Bezier at t = 5/16 static constexpr SkScalar kA = 0.32495117187f; static constexpr SkScalar kB = 0.44311523437f; static constexpr SkScalar kC = 0.20141601562f; static constexpr SkScalar kD = 0.03051757812f; SkPoint curvePoint; SkScalar w; while ((verb = iter.next(pts)) != SkPath::kDone_Verb) { switch (verb) { case SkPath::kLine_Verb: ctm.mapPoints(&pts[1], 1); *fClipPolygon.push() = pts[1]; this->INHERITED::handleLine(shadowTransform, &pts[1]); break; case SkPath::kQuad_Verb: ctm.mapPoints(pts, 3); // point at t = 1/2 curvePoint.fX = 0.25f*pts[0].fX + 0.5f*pts[1].fX + 0.25f*pts[2].fX; curvePoint.fY = 0.25f*pts[0].fY + 0.5f*pts[1].fY + 0.25f*pts[2].fY; *fClipPolygon.push() = curvePoint; *fClipPolygon.push() = pts[2]; this->handleQuad(shadowTransform, pts); break; case SkPath::kConic_Verb: ctm.mapPoints(pts, 3); w = iter.conicWeight(); // point at t = 1/2 curvePoint.fX = 0.25f*pts[0].fX + w*0.5f*pts[1].fX + 0.25f*pts[2].fX; curvePoint.fY = 0.25f*pts[0].fY + w*0.5f*pts[1].fY + 0.25f*pts[2].fY; curvePoint *= SkScalarInvert(0.5f + 0.5f*w); *fClipPolygon.push() = curvePoint; *fClipPolygon.push() = pts[2]; this->handleConic(shadowTransform, pts, w); break; case SkPath::kCubic_Verb: ctm.mapPoints(pts, 4); // point at t = 5/16 curvePoint.fX = kA*pts[0].fX + kB*pts[1].fX + kC*pts[2].fX + kD*pts[3].fX; curvePoint.fY = kA*pts[0].fY + kB*pts[1].fY + kC*pts[2].fY + kD*pts[3].fY; *fClipPolygon.push() = curvePoint; // point at t = 11/16 curvePoint.fX = kD*pts[0].fX + kC*pts[1].fX + kB*pts[2].fX + kA*pts[3].fX; curvePoint.fY = kD*pts[0].fY + kC*pts[1].fY + kB*pts[2].fY + kA*pts[3].fY; *fClipPolygon.push() = curvePoint; *fClipPolygon.push() = pts[3]; this->handleCubic(shadowTransform, pts); break; case SkPath::kMove_Verb: case SkPath::kClose_Verb: case SkPath::kDone_Verb: break; default: SkDEBUGFAIL("unknown verb"); } } // finish centroid if (fPathPolygon.count() > 0) { SkPoint currPoint = fPathPolygon[fPathPolygon.count() - 1]; SkPoint nextPoint = fPathPolygon[0]; SkScalar quadArea = currPoint.cross(nextPoint); fCentroid.fX += (currPoint.fX + nextPoint.fX) * quadArea; fCentroid.fY += (currPoint.fY + nextPoint.fY) * quadArea; fArea += quadArea; fCentroid *= SK_Scalar1 / (3 * fArea); } fCurrClipPoint = fClipPolygon.count() - 1; } void SkSpotShadowTessellator::computeClipVectorsAndTestCentroid() { SkASSERT(fClipPolygon.count() >= 3); // init clip vectors SkVector v0 = fClipPolygon[1] - fClipPolygon[0]; *fClipVectors.push() = v0; // init centroid check bool hiddenCentroid = true; SkVector v1 = fCentroid - fClipPolygon[0]; SkScalar initCross = v0.cross(v1); for (int p = 1; p < fClipPolygon.count(); ++p) { // add to clip vectors v0 = fClipPolygon[(p + 1) % fClipPolygon.count()] - fClipPolygon[p]; *fClipVectors.push() = v0; // Determine if transformed centroid is inside clipPolygon. v1 = fCentroid - fClipPolygon[p]; if (initCross*v0.cross(v1) <= 0) { hiddenCentroid = false; } } SkASSERT(fClipVectors.count() == fClipPolygon.count()); fTransparent = fTransparent || !hiddenCentroid; } bool SkSpotShadowTessellator::clipUmbraPoint(const SkPoint& umbraPoint, const SkPoint& centroid, SkPoint* clipPoint) { SkVector segmentVector = centroid - umbraPoint; int startClipPoint = fCurrClipPoint; do { SkVector dp = umbraPoint - fClipPolygon[fCurrClipPoint]; SkScalar denom = fClipVectors[fCurrClipPoint].cross(segmentVector); SkScalar t_num = dp.cross(segmentVector); // if line segments are nearly parallel if (SkScalarNearlyZero(denom)) { // and collinear if (SkScalarNearlyZero(t_num)) { return false; } // otherwise are separate, will try the next poly segment // else if crossing lies within poly segment } else if (t_num >= 0 && t_num <= denom) { SkScalar s_num = dp.cross(fClipVectors[fCurrClipPoint]); // if umbra point is inside the clip polygon if (s_num >= 0 && s_num <= denom) { segmentVector *= s_num/denom; *clipPoint = umbraPoint + segmentVector; return true; } } fCurrClipPoint = (fCurrClipPoint + 1) % fClipPolygon.count(); } while (fCurrClipPoint != startClipPoint); return false; } int SkSpotShadowTessellator::getClosestUmbraPoint(const SkPoint& p) { SkScalar minDistance = p.distanceToSqd(fUmbraPolygon[fCurrUmbraPoint]); int index = fCurrUmbraPoint; int dir = 1; int next = (index + dir) % fUmbraPolygon.count(); // init travel direction SkScalar distance = p.distanceToSqd(fUmbraPolygon[next]); if (distance < minDistance) { index = next; minDistance = distance; } else { dir = fUmbraPolygon.count()-1; } // iterate until we find a point that increases the distance next = (index + dir) % fUmbraPolygon.count(); distance = p.distanceToSqd(fUmbraPolygon[next]); while (distance < minDistance) { index = next; minDistance = distance; next = (index + dir) % fUmbraPolygon.count(); distance = p.distanceToSqd(fUmbraPolygon[next]); } fCurrUmbraPoint = index; return index; } void SkSpotShadowTessellator::mapPoints(SkScalar scale, const SkVector& xlate, SkPoint* pts, int count) { // TODO: vectorize for (int i = 0; i < count; ++i) { pts[i] *= scale; pts[i] += xlate; } } static bool duplicate_pt(const SkPoint& p0, const SkPoint& p1) { static constexpr SkScalar kClose = (SK_Scalar1 / 16); static constexpr SkScalar kCloseSqd = kClose*kClose; SkScalar distSq = p0.distanceToSqd(p1); return distSq < kCloseSqd; } static SkScalar perp_dot(const SkPoint& p0, const SkPoint& p1, const SkPoint& p2) { SkVector v0 = p1 - p0; SkVector v1 = p2 - p0; return v0.cross(v1); } static bool is_collinear(const SkPoint& p0, const SkPoint& p1, const SkPoint& p2) { return (SkScalarNearlyZero(perp_dot(p0, p1, p2))); } void SkSpotShadowTessellator::handleLine(const SkPoint& p) { // remove coincident points and add to centroid if (fPathPolygon.count() > 0) { const SkPoint& lastPoint = fPathPolygon[fPathPolygon.count() - 1]; if (duplicate_pt(p, lastPoint)) { return; } SkScalar quadArea = lastPoint.cross(p); fCentroid.fX += (p.fX + lastPoint.fX) * quadArea; fCentroid.fY += (p.fY + lastPoint.fY) * quadArea; fArea += quadArea; } // try to remove collinear points if (fPathPolygon.count() > 1 && is_collinear(fPathPolygon[fPathPolygon.count()-2], fPathPolygon[fPathPolygon.count()-1], p)) { fPathPolygon[fPathPolygon.count() - 1] = p; } else { *fPathPolygon.push() = p; } } bool SkSpotShadowTessellator::handlePolyPoint(const SkPoint& p) { if (fInitPoints.count() < 2) { *fInitPoints.push() = p; return true; } if (fInitPoints.count() == 2) { // determine if cw or ccw SkScalar perpDot = perp_dot(fInitPoints[0], fInitPoints[1], p); if (SkScalarNearlyZero(perpDot)) { // nearly parallel, just treat as straight line and continue fInitPoints[1] = p; return true; } // if perpDot > 0, winding is ccw fDirection = (perpDot > 0) ? -1 : 1; // add first quad if (!compute_normal(fInitPoints[0], fInitPoints[1], fDirection, &fFirstOutset)) { // first two points are incident, make the third point the second and continue fInitPoints[1] = p; return true; } fFirstOutset *= fRadius; fFirstPoint = fInitPoints[0]; fFirstVertexIndex = fPositions.count(); fPrevOutset = fFirstOutset; fPrevPoint = fFirstPoint; fPrevUmbraIndex = -1; this->addInnerPoint(fFirstPoint); fPrevUmbraIndex = fFirstVertexIndex; if (!fTransparent) { SkPoint clipPoint; bool isOutside = this->clipUmbraPoint(fPositions[fFirstVertexIndex], fCentroid, &clipPoint); if (isOutside) { *fPositions.push() = clipPoint; *fColors.push() = fUmbraColor; } fPrevUmbraOutside = isOutside; fFirstUmbraOutside = isOutside; } SkPoint newPoint = fFirstPoint + fFirstOutset; *fPositions.push() = newPoint; *fColors.push() = fPenumbraColor; this->addEdge(fInitPoints[1], fFirstOutset); // to ensure we skip this block next time *fInitPoints.push() = p; } // if concave, abort SkScalar perpDot = perp_dot(fInitPoints[1], fInitPoints[2], p); if (fDirection*perpDot > 0) { return false; } SkVector normal; if (compute_normal(fPrevPoint, p, fDirection, &normal)) { normal *= fRadius; this->addArc(normal, true); this->addEdge(p, normal); fInitPoints[1] = fInitPoints[2]; fInitPoints[2] = p; } return true; } bool SkSpotShadowTessellator::addInnerPoint(const SkPoint& pathPoint) { SkPoint umbraPoint; if (!fValidUmbra) { SkVector v = fCentroid - pathPoint; v *= 0.95f; umbraPoint = pathPoint + v; } else { umbraPoint = fUmbraPolygon[this->getClosestUmbraPoint(pathPoint)]; } fPrevPoint = pathPoint; // merge "close" points if (fPrevUmbraIndex == -1 || !duplicate_pt(umbraPoint, fPositions[fPrevUmbraIndex])) { *fPositions.push() = umbraPoint; *fColors.push() = fUmbraColor; return false; } else { return true; } } void SkSpotShadowTessellator::addEdge(const SkPoint& nextPoint, const SkVector& nextNormal) { // add next umbra point bool duplicate = this->addInnerPoint(nextPoint); int prevPenumbraIndex = duplicate ? fPositions.count()-1 : fPositions.count()-2; int currUmbraIndex = duplicate ? fPrevUmbraIndex : fPositions.count()-1; if (!duplicate) { // add to center fan if transparent or centroid showing if (fTransparent) { *fIndices.push() = 0; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = currUmbraIndex; // otherwise add to clip ring } else { SkPoint clipPoint; bool isOutside = this->clipUmbraPoint(fPositions[currUmbraIndex], fCentroid, &clipPoint); if (isOutside) { *fPositions.push() = clipPoint; *fColors.push() = fUmbraColor; *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = currUmbraIndex; *fIndices.push() = currUmbraIndex + 1; if (fPrevUmbraOutside) { // fill out quad *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = currUmbraIndex + 1; *fIndices.push() = fPrevUmbraIndex + 1; } } else if (fPrevUmbraOutside) { // add tri *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = currUmbraIndex; *fIndices.push() = fPrevUmbraIndex + 1; } fPrevUmbraOutside = isOutside; } } // add next penumbra point and quad SkPoint newPoint = nextPoint + nextNormal; *fPositions.push() = newPoint; *fColors.push() = fPenumbraColor; if (!duplicate) { *fIndices.push() = fPrevUmbraIndex; *fIndices.push() = prevPenumbraIndex; *fIndices.push() = currUmbraIndex; } *fIndices.push() = prevPenumbraIndex; *fIndices.push() = fPositions.count() - 1; *fIndices.push() = currUmbraIndex; fPrevUmbraIndex = currUmbraIndex; fPrevOutset = nextNormal; } /////////////////////////////////////////////////////////////////////////////////////////////////// sk_sp SkShadowTessellator::MakeAmbient(const SkPath& path, const SkMatrix& ctm, const SkPoint3& zPlane, bool transparent) { SkAmbientShadowTessellator ambientTess(path, ctm, zPlane, transparent); return ambientTess.releaseVertices(); } sk_sp SkShadowTessellator::MakeSpot(const SkPath& path, const SkMatrix& ctm, const SkPoint3& zPlane, const SkPoint3& lightPos, SkScalar lightRadius, bool transparent) { SkSpotShadowTessellator spotTess(path, ctm, zPlane, lightPos, lightRadius, transparent); return spotTess.releaseVertices(); }