void GrDefaultPathRenderer::onDrawPath(GrDrawTarget::StageBitfield stages, bool stencilOnly) { GrMatrix viewM = fTarget->getViewMatrix(); GrScalar tol = GR_Scalar1; tol = GrPathUtils::scaleToleranceToSrc(tol, viewM, fPath->getBounds()); // FIXME: It's really dumb that we recreate the verts for a new vertex // layout. We only do that because the GrDrawTarget API doesn't allow // us to change the vertex layout after reserveVertexSpace(). We won't // actually change the vertex data when the layout changes since all the // stages reference the positions (rather than having separate tex coords) // and we don't ever have per-vert colors. In practice our call sites // won't change the stages in use inside a setPath / removePath pair. But // it is a silly limitation of the GrDrawTarget design that should be fixed. if (tol != fPreviousSrcTol || stages != fPreviousStages) { if (!this->createGeom(tol, stages)) { return; } } GrAssert(NULL != fTarget); GrDrawTarget::AutoStateRestore asr(fTarget); bool colorWritesWereDisabled = fTarget->isColorWriteDisabled(); // face culling doesn't make sense here GrAssert(GrDrawTarget::kBoth_DrawFace == fTarget->getDrawFace()); int passCount = 0; const GrStencilSettings* passes[3]; GrDrawTarget::DrawFace drawFace[3]; bool reverse = false; bool lastPassIsBounds; if (kHairLine_PathFill == fFill) { passCount = 1; if (stencilOnly) { passes[0] = &gDirectToStencil; } else { passes[0] = NULL; } lastPassIsBounds = false; drawFace[0] = GrDrawTarget::kBoth_DrawFace; } else { if (single_pass_path(*fTarget, *fPath, fFill)) { passCount = 1; if (stencilOnly) { passes[0] = &gDirectToStencil; } else { passes[0] = NULL; } drawFace[0] = GrDrawTarget::kBoth_DrawFace; lastPassIsBounds = false; } else { switch (fFill) { case kInverseEvenOdd_PathFill: reverse = true; // fallthrough case kEvenOdd_PathFill: passes[0] = &gEOStencilPass; if (stencilOnly) { passCount = 1; lastPassIsBounds = false; } else { passCount = 2; lastPassIsBounds = true; if (reverse) { passes[1] = &gInvEOColorPass; } else { passes[1] = &gEOColorPass; } } drawFace[0] = drawFace[1] = GrDrawTarget::kBoth_DrawFace; break; case kInverseWinding_PathFill: reverse = true; // fallthrough case kWinding_PathFill: if (fSeparateStencil) { if (fStencilWrapOps) { passes[0] = &gWindStencilSeparateWithWrap; } else { passes[0] = &gWindStencilSeparateNoWrap; } passCount = 2; drawFace[0] = GrDrawTarget::kBoth_DrawFace; } else { if (fStencilWrapOps) { passes[0] = &gWindSingleStencilWithWrapInc; passes[1] = &gWindSingleStencilWithWrapDec; } else { passes[0] = &gWindSingleStencilNoWrapInc; passes[1] = &gWindSingleStencilNoWrapDec; } // which is cw and which is ccw is arbitrary. drawFace[0] = GrDrawTarget::kCW_DrawFace; drawFace[1] = GrDrawTarget::kCCW_DrawFace; passCount = 3; } if (stencilOnly) { lastPassIsBounds = false; --passCount; } else { lastPassIsBounds = true; drawFace[passCount-1] = GrDrawTarget::kBoth_DrawFace; if (reverse) { passes[passCount-1] = &gInvWindColorPass; } else { passes[passCount-1] = &gWindColorPass; } } break; default: GrAssert(!"Unknown path fFill!"); return; } } } { for (int p = 0; p < passCount; ++p) { fTarget->setDrawFace(drawFace[p]); if (NULL != passes[p]) { fTarget->setStencil(*passes[p]); } if (lastPassIsBounds && (p == passCount-1)) { if (!colorWritesWereDisabled) { fTarget->disableState(GrDrawTarget::kNoColorWrites_StateBit); } GrRect bounds; if (reverse) { GrAssert(NULL != fTarget->getRenderTarget()); // draw over the whole world. bounds.setLTRB(0, 0, GrIntToScalar(fTarget->getRenderTarget()->width()), GrIntToScalar(fTarget->getRenderTarget()->height())); GrMatrix vmi; // mapRect through persp matrix may not be correct if (!fTarget->getViewMatrix().hasPerspective() && fTarget->getViewInverse(&vmi)) { vmi.mapRect(&bounds); } else { if (stages) { if (!fTarget->getViewInverse(&vmi)) { GrPrintf("Could not invert matrix."); return; } fTarget->preConcatSamplerMatrices(stages, vmi); } fTarget->setViewMatrix(GrMatrix::I()); } } else { bounds = fPath->getBounds(); bounds.offset(fTranslate); } GrDrawTarget::AutoGeometryPush agp(fTarget); fTarget->drawSimpleRect(bounds, NULL, stages); } else { if (passCount > 1) { fTarget->enableState(GrDrawTarget::kNoColorWrites_StateBit); } if (fUseIndexedDraw) { fTarget->drawIndexed(fPrimitiveType, 0, 0, fVertexCnt, fIndexCnt); } else { int baseVertex = 0; for (int sp = 0; sp < fSubpathCount; ++sp) { fTarget->drawNonIndexed(fPrimitiveType, baseVertex, fSubpathVertCount[sp]); baseVertex += fSubpathVertCount[sp]; } } } } } }
bool GrTesselatedPathRenderer::onDrawPath(const SkPath& path, GrPathFill fill, const GrVec* translate, GrDrawTarget* target, GrDrawState::StageMask stageMask, bool antiAlias) { GrDrawTarget::AutoStateRestore asr(target); GrDrawState* drawState = target->drawState(); // face culling doesn't make sense here GrAssert(GrDrawState::kBoth_DrawFace == drawState->getDrawFace()); GrMatrix viewM = drawState->getViewMatrix(); GrScalar tol = GR_Scalar1; tol = GrPathUtils::scaleToleranceToSrc(tol, viewM, path.getBounds()); GrScalar tolSqd = GrMul(tol, tol); int subpathCnt; int maxPts = GrPathUtils::worstCasePointCount(path, &subpathCnt, tol); GrVertexLayout layout = 0; for (int s = 0; s < GrDrawState::kNumStages; ++s) { if ((1 << s) & stageMask) { layout |= GrDrawTarget::StagePosAsTexCoordVertexLayoutBit(s); } } bool inverted = GrIsFillInverted(fill); if (inverted) { maxPts += 4; subpathCnt++; } if (maxPts > USHRT_MAX) { return false; } SkAutoSTMalloc<8, GrPoint> baseMem(maxPts); GrPoint* base = baseMem; GrPoint* vert = base; GrPoint* subpathBase = base; SkAutoSTMalloc<8, uint16_t> subpathVertCount(subpathCnt); GrPoint pts[4]; SkPath::Iter iter(path, false); bool first = true; int subpath = 0; for (;;) { switch (iter.next(pts)) { case kMove_PathCmd: if (!first) { subpathVertCount[subpath] = vert-subpathBase; subpathBase = vert; ++subpath; } *vert = pts[0]; vert++; break; case kLine_PathCmd: *vert = pts[1]; vert++; break; case kQuadratic_PathCmd: { GrPathUtils::generateQuadraticPoints(pts[0], pts[1], pts[2], tolSqd, &vert, GrPathUtils::quadraticPointCount(pts, tol)); break; } case kCubic_PathCmd: { GrPathUtils::generateCubicPoints(pts[0], pts[1], pts[2], pts[3], tolSqd, &vert, GrPathUtils::cubicPointCount(pts, tol)); break; } case kClose_PathCmd: break; case kEnd_PathCmd: subpathVertCount[subpath] = vert-subpathBase; ++subpath; // this could be only in debug goto FINISHED; } first = false; } FINISHED: if (NULL != translate && 0 != translate->fX && 0 != translate->fY) { for (int i = 0; i < vert - base; i++) { base[i].offset(translate->fX, translate->fY); } } if (inverted) { GrRect bounds; GrAssert(NULL != drawState->getRenderTarget()); bounds.setLTRB(0, 0, GrIntToScalar(drawState->getRenderTarget()->width()), GrIntToScalar(drawState->getRenderTarget()->height())); GrMatrix vmi; if (drawState->getViewInverse(&vmi)) { vmi.mapRect(&bounds); } *vert++ = GrPoint::Make(bounds.fLeft, bounds.fTop); *vert++ = GrPoint::Make(bounds.fLeft, bounds.fBottom); *vert++ = GrPoint::Make(bounds.fRight, bounds.fBottom); *vert++ = GrPoint::Make(bounds.fRight, bounds.fTop); subpathVertCount[subpath++] = 4; } GrAssert(subpath == subpathCnt); GrAssert((vert - base) <= maxPts); size_t count = vert - base; if (count < 3) { return true; } if (subpathCnt == 1 && !inverted && path.isConvex()) { if (antiAlias) { GrEdgeArray edges; GrMatrix inverse, matrix = drawState->getViewMatrix(); drawState->getViewInverse(&inverse); count = computeEdgesAndIntersect(matrix, inverse, base, count, &edges, 0.0f); size_t maxEdges = target->getMaxEdges(); if (count == 0) { return true; } if (count <= maxEdges) { // All edges fit; upload all edges and draw all verts as a fan target->setVertexSourceToArray(layout, base, count); drawState->setEdgeAAData(&edges[0], count); target->drawNonIndexed(kTriangleFan_PrimitiveType, 0, count); } else { // Upload "maxEdges" edges and verts at a time, and draw as // separate fans for (size_t i = 0; i < count - 2; i += maxEdges - 2) { edges[i] = edges[0]; base[i] = base[0]; int size = GR_CT_MIN(count - i, maxEdges); target->setVertexSourceToArray(layout, &base[i], size); drawState->setEdgeAAData(&edges[i], size); target->drawNonIndexed(kTriangleFan_PrimitiveType, 0, size); } } drawState->setEdgeAAData(NULL, 0); } else { target->setVertexSourceToArray(layout, base, count); target->drawNonIndexed(kTriangleFan_PrimitiveType, 0, count); } return true; } if (antiAlias) { // Run the tesselator once to get the boundaries. GrBoundaryTess btess(count, fill_type_to_glu_winding_rule(fill)); btess.addVertices(base, subpathVertCount, subpathCnt); GrMatrix inverse, matrix = drawState->getViewMatrix(); if (!drawState->getViewInverse(&inverse)) { return false; } if (btess.vertices().count() > USHRT_MAX) { return false; } // Inflate the boundary, and run the tesselator again to generate // interior polys. const GrPointArray& contourPoints = btess.contourPoints(); const GrIndexArray& contours = btess.contours(); GrEdgePolygonTess ptess(contourPoints.count(), GLU_TESS_WINDING_NONZERO, matrix); size_t i = 0; Sk_gluTessBeginPolygon(ptess.tess(), &ptess); for (int contour = 0; contour < contours.count(); ++contour) { int count = contours[contour]; GrEdgeArray edges; int newCount = computeEdgesAndIntersect(matrix, inverse, &btess.contourPoints()[i], count, &edges, 1.0f); Sk_gluTessBeginContour(ptess.tess()); for (int j = 0; j < newCount; j++) { ptess.addVertex(contourPoints[i + j], ptess.vertices().count()); } i += count; Sk_gluTessEndContour(ptess.tess()); } Sk_gluTessEndPolygon(ptess.tess()); if (ptess.vertices().count() > USHRT_MAX) { return false; } // Draw the resulting polys and upload their edge data. drawState->enableState(GrDrawState::kEdgeAAConcave_StateBit); const GrPointArray& vertices = ptess.vertices(); const GrIndexArray& indices = ptess.indices(); const GrDrawState::Edge* edges = ptess.edges(); GR_DEBUGASSERT(indices.count() % 3 == 0); for (int i = 0; i < indices.count(); i += 3) { GrPoint tri_verts[3]; int index0 = indices[i]; int index1 = indices[i + 1]; int index2 = indices[i + 2]; tri_verts[0] = vertices[index0]; tri_verts[1] = vertices[index1]; tri_verts[2] = vertices[index2]; GrDrawState::Edge tri_edges[6]; int t = 0; const GrDrawState::Edge& edge0 = edges[index0 * 2]; const GrDrawState::Edge& edge1 = edges[index0 * 2 + 1]; const GrDrawState::Edge& edge2 = edges[index1 * 2]; const GrDrawState::Edge& edge3 = edges[index1 * 2 + 1]; const GrDrawState::Edge& edge4 = edges[index2 * 2]; const GrDrawState::Edge& edge5 = edges[index2 * 2 + 1]; if (validEdge(edge0) && validEdge(edge1)) { tri_edges[t++] = edge0; tri_edges[t++] = edge1; } if (validEdge(edge2) && validEdge(edge3)) { tri_edges[t++] = edge2; tri_edges[t++] = edge3; } if (validEdge(edge4) && validEdge(edge5)) { tri_edges[t++] = edge4; tri_edges[t++] = edge5; } drawState->setEdgeAAData(&tri_edges[0], t); target->setVertexSourceToArray(layout, &tri_verts[0], 3); target->drawNonIndexed(kTriangles_PrimitiveType, 0, 3); } drawState->setEdgeAAData(NULL, 0); drawState->disableState(GrDrawState::kEdgeAAConcave_StateBit); return true; } GrPolygonTess ptess(count, fill_type_to_glu_winding_rule(fill)); ptess.addVertices(base, subpathVertCount, subpathCnt); const GrPointArray& vertices = ptess.vertices(); const GrIndexArray& indices = ptess.indices(); if (indices.count() > 0) { target->setVertexSourceToArray(layout, vertices.begin(), vertices.count()); target->setIndexSourceToArray(indices.begin(), indices.count()); target->drawIndexed(kTriangles_PrimitiveType, 0, 0, vertices.count(), indices.count()); } return true; }
void GrDefaultPathRenderer::onDrawPath(GrDrawTarget* target, GrDrawTarget::StageBitfield stages, const GrPath& path, GrPathFill fill, const GrPoint* translate, bool stencilOnly) { GrDrawTarget::AutoStateRestore asr(target); bool colorWritesWereDisabled = target->isColorWriteDisabled(); // face culling doesn't make sense here GrAssert(GrDrawTarget::kBoth_DrawFace == target->getDrawFace()); GrMatrix viewM = target->getViewMatrix(); // In order to tesselate the path we get a bound on how much the matrix can // stretch when mapping to screen coordinates. GrScalar stretch = viewM.getMaxStretch(); bool useStretch = stretch > 0; GrScalar tol = fCurveTolerance; if (!useStretch) { // TODO: deal with perspective in some better way. tol /= 10; } else { tol = GrScalarDiv(tol, stretch); } GrScalar tolSqd = GrMul(tol, tol); int subpathCnt; int maxPts = GrPathUtils::worstCasePointCount(path, &subpathCnt, tol); GrVertexLayout layout = 0; for (int s = 0; s < GrDrawTarget::kNumStages; ++s) { if ((1 << s) & stages) { layout |= GrDrawTarget::StagePosAsTexCoordVertexLayoutBit(s); } } // add 4 to hold the bounding rect GrDrawTarget::AutoReleaseGeometry arg(target, layout, maxPts + 4, 0); GrPoint* base = (GrPoint*) arg.vertices(); GrPoint* vert = base; GrPoint* subpathBase = base; GrAutoSTMalloc<8, uint16_t> subpathVertCount(subpathCnt); // TODO: use primitve restart if available rather than multiple draws GrPrimitiveType type; int passCount = 0; const GrStencilSettings* passes[3]; GrDrawTarget::DrawFace drawFace[3]; bool reverse = false; bool lastPassIsBounds; if (kHairLine_PathFill == fill) { type = kLineStrip_PrimitiveType; passCount = 1; if (stencilOnly) { passes[0] = &gDirectToStencil; } else { passes[0] = NULL; } lastPassIsBounds = false; drawFace[0] = GrDrawTarget::kBoth_DrawFace; } else { type = kTriangleFan_PrimitiveType; if (single_pass_path(*target, path, fill)) { passCount = 1; if (stencilOnly) { passes[0] = &gDirectToStencil; } else { passes[0] = NULL; } drawFace[0] = GrDrawTarget::kBoth_DrawFace; lastPassIsBounds = false; } else { switch (fill) { case kInverseEvenOdd_PathFill: reverse = true; // fallthrough case kEvenOdd_PathFill: passes[0] = &gEOStencilPass; if (stencilOnly) { passCount = 1; lastPassIsBounds = false; } else { passCount = 2; lastPassIsBounds = true; if (reverse) { passes[1] = &gInvEOColorPass; } else { passes[1] = &gEOColorPass; } } drawFace[0] = drawFace[1] = GrDrawTarget::kBoth_DrawFace; break; case kInverseWinding_PathFill: reverse = true; // fallthrough case kWinding_PathFill: if (fSeparateStencil) { if (fStencilWrapOps) { passes[0] = &gWindStencilSeparateWithWrap; } else { passes[0] = &gWindStencilSeparateNoWrap; } passCount = 2; drawFace[0] = GrDrawTarget::kBoth_DrawFace; } else { if (fStencilWrapOps) { passes[0] = &gWindSingleStencilWithWrapInc; passes[1] = &gWindSingleStencilWithWrapDec; } else { passes[0] = &gWindSingleStencilNoWrapInc; passes[1] = &gWindSingleStencilNoWrapDec; } // which is cw and which is ccw is arbitrary. drawFace[0] = GrDrawTarget::kCW_DrawFace; drawFace[1] = GrDrawTarget::kCCW_DrawFace; passCount = 3; } if (stencilOnly) { lastPassIsBounds = false; --passCount; } else { lastPassIsBounds = true; drawFace[passCount-1] = GrDrawTarget::kBoth_DrawFace; if (reverse) { passes[passCount-1] = &gInvWindColorPass; } else { passes[passCount-1] = &gWindColorPass; } } break; default: GrAssert(!"Unknown path fill!"); return; } } } GrPoint pts[4]; bool first = true; int subpath = 0; SkPath::Iter iter(path, false); for (;;) { GrPathCmd cmd = (GrPathCmd)iter.next(pts); switch (cmd) { case kMove_PathCmd: if (!first) { subpathVertCount[subpath] = vert-subpathBase; subpathBase = vert; ++subpath; } *vert = pts[0]; vert++; break; case kLine_PathCmd: *vert = pts[1]; vert++; break; case kQuadratic_PathCmd: { GrPathUtils::generateQuadraticPoints(pts[0], pts[1], pts[2], tolSqd, &vert, GrPathUtils::quadraticPointCount(pts, tol)); break; } case kCubic_PathCmd: { GrPathUtils::generateCubicPoints(pts[0], pts[1], pts[2], pts[3], tolSqd, &vert, GrPathUtils::cubicPointCount(pts, tol)); break; } case kClose_PathCmd: break; case kEnd_PathCmd: subpathVertCount[subpath] = vert-subpathBase; ++subpath; // this could be only in debug goto FINISHED; } first = false; } FINISHED: GrAssert(subpath == subpathCnt); GrAssert((vert - base) <= maxPts); if (translate) { int count = vert - base; for (int i = 0; i < count; i++) { base[i].offset(translate->fX, translate->fY); } } // if we're stenciling we will follow with a pass that draws // a bounding rect to set the color. We're stenciling when // passCount > 1. const int& boundVertexStart = maxPts; GrPoint* boundsVerts = base + boundVertexStart; if (lastPassIsBounds) { GrRect bounds; if (reverse) { GrAssert(NULL != target->getRenderTarget()); // draw over the whole world. bounds.setLTRB(0, 0, GrIntToScalar(target->getRenderTarget()->width()), GrIntToScalar(target->getRenderTarget()->height())); GrMatrix vmi; if (target->getViewInverse(&vmi)) { vmi.mapRect(&bounds); } } else { bounds.setBounds((GrPoint*)base, vert - base); } boundsVerts[0].setRectFan(bounds.fLeft, bounds.fTop, bounds.fRight, bounds.fBottom); } for (int p = 0; p < passCount; ++p) { target->setDrawFace(drawFace[p]); if (NULL != passes[p]) { target->setStencil(*passes[p]); } if (lastPassIsBounds && (p == passCount-1)) { if (!colorWritesWereDisabled) { target->disableState(GrDrawTarget::kNoColorWrites_StateBit); } target->drawNonIndexed(kTriangleFan_PrimitiveType, boundVertexStart, 4); } else { if (passCount > 1) { target->enableState(GrDrawTarget::kNoColorWrites_StateBit); } int baseVertex = 0; for (int sp = 0; sp < subpathCnt; ++sp) { target->drawNonIndexed(type, baseVertex, subpathVertCount[sp]); baseVertex += subpathVertCount[sp]; } } } }
bool GrStencilAndCoverPathRenderer::onDrawPath(const SkPath& path, GrPathFill fill, GrDrawTarget* target, bool antiAlias) { GrAssert(!antiAlias); GrAssert(kHairLine_GrPathFill != fill); GrDrawState* drawState = target->drawState(); GrAssert(drawState->getStencil().isDisabled()); SkAutoTUnref<GrPath> p(fGpu->createPath(path)); GrPathFill nonInvertedFill = GrNonInvertedFill(fill); target->stencilPath(p, nonInvertedFill); // TODO: Use built in cover operation rather than a rect draw. This will require making our // fragment shaders be able to eat varyings generated by a matrix. // fill the path, zero out the stencil GrRect bounds = p->getBounds(); GrScalar bloat = drawState->getViewMatrix().getMaxStretch() * GR_ScalarHalf; GrDrawState::AutoDeviceCoordDraw adcd; if (nonInvertedFill == fill) { GR_STATIC_CONST_SAME_STENCIL(kStencilPass, kZero_StencilOp, kZero_StencilOp, kNotEqual_StencilFunc, 0xffff, 0x0000, 0xffff); *drawState->stencil() = kStencilPass; } else { GR_STATIC_CONST_SAME_STENCIL(kInvertedStencilPass, kZero_StencilOp, kZero_StencilOp, // We know our rect will hit pixels outside the clip and the user bits will be 0 // outside the clip. So we can't just fill where the user bits are 0. We also need to // check that the clip bit is set. kEqualIfInClip_StencilFunc, 0xffff, 0x0000, 0xffff); GrMatrix vmi; bounds.setLTRB(0, 0, GrIntToScalar(drawState->getRenderTarget()->width()), GrIntToScalar(drawState->getRenderTarget()->height())); // mapRect through persp matrix may not be correct if (!drawState->getViewMatrix().hasPerspective() && drawState->getViewInverse(&vmi)) { vmi.mapRect(&bounds); // theoretically could set bloat = 0, instead leave it because of matrix inversion // precision. } else { adcd.set(drawState); bloat = 0; } *drawState->stencil() = kInvertedStencilPass; } bounds.outset(bloat, bloat); target->drawSimpleRect(bounds, NULL); target->drawState()->stencil()->setDisabled(); return true; }
bool GrDefaultPathRenderer::internalDrawPath(const SkPath& path, GrPathFill fill, GrDrawTarget* target, bool stencilOnly) { GrMatrix viewM = target->getDrawState().getViewMatrix(); GrScalar tol = GR_Scalar1; tol = GrPathUtils::scaleToleranceToSrc(tol, viewM, path.getBounds()); int vertexCnt; int indexCnt; GrPrimitiveType primType; GrDrawTarget::AutoReleaseGeometry arg; if (!this->createGeom(path, fill, tol, target, &primType, &vertexCnt, &indexCnt, &arg)) { return false; } GrAssert(NULL != target); GrDrawTarget::AutoStateRestore asr(target, GrDrawTarget::kPreserve_ASRInit); GrDrawState* drawState = target->drawState(); bool colorWritesWereDisabled = drawState->isColorWriteDisabled(); // face culling doesn't make sense here GrAssert(GrDrawState::kBoth_DrawFace == drawState->getDrawFace()); int passCount = 0; const GrStencilSettings* passes[3]; GrDrawState::DrawFace drawFace[3]; bool reverse = false; bool lastPassIsBounds; if (kHairLine_GrPathFill == fill) { passCount = 1; if (stencilOnly) { passes[0] = &gDirectToStencil; } else { passes[0] = NULL; } lastPassIsBounds = false; drawFace[0] = GrDrawState::kBoth_DrawFace; } else { if (single_pass_path(path, fill)) { passCount = 1; if (stencilOnly) { passes[0] = &gDirectToStencil; } else { passes[0] = NULL; } drawFace[0] = GrDrawState::kBoth_DrawFace; lastPassIsBounds = false; } else { switch (fill) { case kInverseEvenOdd_GrPathFill: reverse = true; // fallthrough case kEvenOdd_GrPathFill: passes[0] = &gEOStencilPass; if (stencilOnly) { passCount = 1; lastPassIsBounds = false; } else { passCount = 2; lastPassIsBounds = true; if (reverse) { passes[1] = &gInvEOColorPass; } else { passes[1] = &gEOColorPass; } } drawFace[0] = drawFace[1] = GrDrawState::kBoth_DrawFace; break; case kInverseWinding_GrPathFill: reverse = true; // fallthrough case kWinding_GrPathFill: if (fSeparateStencil) { if (fStencilWrapOps) { passes[0] = &gWindStencilSeparateWithWrap; } else { passes[0] = &gWindStencilSeparateNoWrap; } passCount = 2; drawFace[0] = GrDrawState::kBoth_DrawFace; } else { if (fStencilWrapOps) { passes[0] = &gWindSingleStencilWithWrapInc; passes[1] = &gWindSingleStencilWithWrapDec; } else { passes[0] = &gWindSingleStencilNoWrapInc; passes[1] = &gWindSingleStencilNoWrapDec; } // which is cw and which is ccw is arbitrary. drawFace[0] = GrDrawState::kCW_DrawFace; drawFace[1] = GrDrawState::kCCW_DrawFace; passCount = 3; } if (stencilOnly) { lastPassIsBounds = false; --passCount; } else { lastPassIsBounds = true; drawFace[passCount-1] = GrDrawState::kBoth_DrawFace; if (reverse) { passes[passCount-1] = &gInvWindColorPass; } else { passes[passCount-1] = &gWindColorPass; } } break; default: GrAssert(!"Unknown path fFill!"); return false; } } } { for (int p = 0; p < passCount; ++p) { drawState->setDrawFace(drawFace[p]); if (NULL != passes[p]) { *drawState->stencil() = *passes[p]; } if (lastPassIsBounds && (p == passCount-1)) { if (!colorWritesWereDisabled) { drawState->disableState(GrDrawState::kNoColorWrites_StateBit); } GrRect bounds; GrDrawState::AutoDeviceCoordDraw adcd; if (reverse) { GrAssert(NULL != drawState->getRenderTarget()); // draw over the whole world. bounds.setLTRB(0, 0, GrIntToScalar(drawState->getRenderTarget()->width()), GrIntToScalar(drawState->getRenderTarget()->height())); GrMatrix vmi; // mapRect through persp matrix may not be correct if (!drawState->getViewMatrix().hasPerspective() && drawState->getViewInverse(&vmi)) { vmi.mapRect(&bounds); } else { adcd.set(drawState); } } else { bounds = path.getBounds(); } GrDrawTarget::AutoGeometryPush agp(target); target->drawSimpleRect(bounds, NULL); } else { if (passCount > 1) { drawState->enableState(GrDrawState::kNoColorWrites_StateBit); } if (indexCnt) { target->drawIndexed(primType, 0, 0, vertexCnt, indexCnt); } else { target->drawNonIndexed(primType, 0, vertexCnt); } } } } return true; }