bool GrAAConvexPathRenderer::onDrawPath(const SkPath& origPath, GrPathFill fill, const GrVec* translate, GrDrawTarget* target, GrDrawState::StageMask stageMask, bool antiAlias) { const SkPath* path = &origPath; if (path->isEmpty()) { return true; } GrDrawTarget::AutoStateRestore asr(target, GrDrawTarget::kPreserve_ASRInit); GrDrawState* drawState = target->drawState(); GrMatrix vm = drawState->getViewMatrix(); if (NULL != translate) { vm.postTranslate(translate->fX, translate->fY); } GrMatrix ivm; if (vm.invert(&ivm)) { drawState->preConcatSamplerMatrices(stageMask, ivm); } drawState->viewMatrix()->reset(); GrVertexLayout layout = 0; for (int s = 0; s < GrDrawState::kNumStages; ++s) { if ((1 << s) & stageMask) { layout |= GrDrawTarget::StagePosAsTexCoordVertexLayoutBit(s); } } layout |= GrDrawTarget::kEdge_VertexLayoutBit; // We use the fact that SkPath::transform path does subdivision based on // perspective. Otherwise, we apply the view matrix when copying to the // segment representation. SkPath tmpPath; if (vm.hasPerspective()) { origPath.transform(vm, &tmpPath); path = &tmpPath; vm.reset(); } QuadVertex *verts; uint16_t* idxs; int vCount; int iCount; enum { kPreallocSegmentCnt = 512 / sizeof(Segment), }; SkSTArray<kPreallocSegmentCnt, Segment, true> segments; SkPoint fanPt; if (!get_segments(*path, vm, &segments, &fanPt, &vCount, &iCount)) { return false; } GrDrawTarget::AutoReleaseGeometry arg(target, layout, vCount, iCount); if (!arg.succeeded()) { return false; } verts = reinterpret_cast<QuadVertex*>(arg.vertices()); idxs = reinterpret_cast<uint16_t*>(arg.indices()); create_vertices(segments, fanPt, verts, idxs); drawState->setVertexEdgeType(GrDrawState::kQuad_EdgeType); target->drawIndexed(kTriangles_PrimitiveType, 0, // start vertex 0, // start index vCount, iCount); return true; }
bool GrAAHairLinePathRenderer::createGeom(GrDrawTarget::StageBitfield stages) { int rtHeight = fTarget->getRenderTarget()->height(); GrIRect clip; if (fTarget->getClip().hasConservativeBounds()) { GrRect clipRect = fTarget->getClip().getConservativeBounds(); clipRect.roundOut(&clip); } else { clip.setLargest(); } // If none of the inputs that affect generation of path geometry have // have changed since last previous path draw then we can reuse the // previous geoemtry. if (stages == fPreviousStages && fPreviousViewMatrix == fTarget->getViewMatrix() && fPreviousTranslate == fTranslate && rtHeight == fPreviousRTHeight && fClipRect == clip) { return true; } GrVertexLayout layout = GrDrawTarget::kEdge_VertexLayoutBit; for (int s = 0; s < GrDrawState::kNumStages; ++s) { if ((1 << s) & stages) { layout |= GrDrawTarget::StagePosAsTexCoordVertexLayoutBit(s); } } GrMatrix viewM = fTarget->getViewMatrix(); PREALLOC_PTARRAY(128) lines; PREALLOC_PTARRAY(128) quads; IntArray qSubdivs; fQuadCnt = generate_lines_and_quads(*fPath, viewM, fTranslate, clip, &lines, &quads, &qSubdivs); fLineSegmentCnt = lines.count() / 2; int vertCnt = kVertsPerLineSeg * fLineSegmentCnt + kVertsPerQuad * fQuadCnt; GrAssert(sizeof(Vertex) == GrDrawTarget::VertexSize(layout)); Vertex* verts; if (!fTarget->reserveVertexSpace(layout, vertCnt, (void**)&verts)) { return false; } Vertex* base = verts; const GrMatrix* toDevice = NULL; const GrMatrix* toSrc = NULL; GrMatrix ivm; if (viewM.hasPerspective()) { if (viewM.invert(&ivm)) { toDevice = &viewM; toSrc = &ivm; } } for (int i = 0; i < fLineSegmentCnt; ++i) { add_line(&lines[2*i], rtHeight, toSrc, &verts); } int unsubdivQuadCnt = quads.count() / 3; for (int i = 0; i < unsubdivQuadCnt; ++i) { GrAssert(qSubdivs[i] >= 0); add_quads(&quads[3*i], qSubdivs[i], toDevice, toSrc, &verts); } fPreviousStages = stages; fPreviousViewMatrix = fTarget->getViewMatrix(); fPreviousRTHeight = rtHeight; fClipRect = clip; fPreviousTranslate = fTranslate; return true; }
bool GrAAHairLinePathRenderer::createGeom( const SkPath& path, const GrVec* translate, GrDrawTarget* target, GrDrawState::StageMask stageMask, int* lineCnt, int* quadCnt, GrDrawTarget::AutoReleaseGeometry* arg) { const GrDrawState& drawState = target->getDrawState(); int rtHeight = drawState.getRenderTarget()->height(); GrIRect clip; if (target->getClip().hasConservativeBounds()) { GrRect clipRect = target->getClip().getConservativeBounds(); clipRect.roundOut(&clip); } else { clip.setLargest(); } GrVertexLayout layout = GrDrawTarget::kEdge_VertexLayoutBit; GrMatrix viewM = drawState.getViewMatrix(); PREALLOC_PTARRAY(128) lines; PREALLOC_PTARRAY(128) quads; IntArray qSubdivs; static const GrVec gZeroVec = {0, 0}; if (NULL == translate) { translate = &gZeroVec; } *quadCnt = generate_lines_and_quads(path, viewM, *translate, clip, &lines, &quads, &qSubdivs); *lineCnt = lines.count() / 2; int vertCnt = kVertsPerLineSeg * *lineCnt + kVertsPerQuad * *quadCnt; GrAssert(sizeof(Vertex) == GrDrawTarget::VertexSize(layout)); if (!arg->set(target, layout, vertCnt, 0)) { return false; } Vertex* verts = reinterpret_cast<Vertex*>(arg->vertices()); const GrMatrix* toDevice = NULL; const GrMatrix* toSrc = NULL; GrMatrix ivm; if (viewM.hasPerspective()) { if (viewM.invert(&ivm)) { toDevice = &viewM; toSrc = &ivm; } } for (int i = 0; i < *lineCnt; ++i) { add_line(&lines[2*i], rtHeight, toSrc, &verts); } int unsubdivQuadCnt = quads.count() / 3; for (int i = 0; i < unsubdivQuadCnt; ++i) { GrAssert(qSubdivs[i] >= 0); add_quads(&quads[3*i], qSubdivs[i], toDevice, toSrc, &verts); } return true; }