/* * Copyright 2014 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkPatchUtils.h" #include "SkColorData.h" #include "SkColorSpacePriv.h" #include "SkGeometry.h" #include "SkPM4f.h" #include "SkTo.h" namespace { enum CubicCtrlPts { kTopP0_CubicCtrlPts = 0, kTopP1_CubicCtrlPts = 1, kTopP2_CubicCtrlPts = 2, kTopP3_CubicCtrlPts = 3, kRightP0_CubicCtrlPts = 3, kRightP1_CubicCtrlPts = 4, kRightP2_CubicCtrlPts = 5, kRightP3_CubicCtrlPts = 6, kBottomP0_CubicCtrlPts = 9, kBottomP1_CubicCtrlPts = 8, kBottomP2_CubicCtrlPts = 7, kBottomP3_CubicCtrlPts = 6, kLeftP0_CubicCtrlPts = 0, kLeftP1_CubicCtrlPts = 11, kLeftP2_CubicCtrlPts = 10, kLeftP3_CubicCtrlPts = 9, }; // Enum for corner also clockwise. enum Corner { kTopLeft_Corner = 0, kTopRight_Corner, kBottomRight_Corner, kBottomLeft_Corner }; } /** * Evaluator to sample the values of a cubic bezier using forward differences. * Forward differences is a method for evaluating a nth degree polynomial at a uniform step by only * adding precalculated values. * For a linear example we have the function f(t) = m*t+b, then the value of that function at t+h * would be f(t+h) = m*(t+h)+b. If we want to know the uniform step that we must add to the first * evaluation f(t) then we need to substract f(t+h) - f(t) = m*t + m*h + b - m*t + b = mh. After * obtaining this value (mh) we could just add this constant step to our first sampled point * to compute the next one. * * For the cubic case the first difference gives as a result a quadratic polynomial to which we can * apply again forward differences and get linear function to which we can apply again forward * differences to get a constant difference. This is why we keep an array of size 4, the 0th * position keeps the sampled value while the next ones keep the quadratic, linear and constant * difference values. */ class FwDCubicEvaluator { public: /** * Receives the 4 control points of the cubic bezier. */ explicit FwDCubicEvaluator(const SkPoint points[4]) : fCoefs(points) { memcpy(fPoints, points, 4 * sizeof(SkPoint)); this->restart(1); } /** * Restarts the forward differences evaluator to the first value of t = 0. */ void restart(int divisions) { fDivisions = divisions; fCurrent = 0; fMax = fDivisions + 1; Sk2s h = Sk2s(1.f / fDivisions); Sk2s h2 = h * h; Sk2s h3 = h2 * h; Sk2s fwDiff3 = Sk2s(6) * fCoefs.fA * h3; fFwDiff[3] = to_point(fwDiff3); fFwDiff[2] = to_point(fwDiff3 + times_2(fCoefs.fB) * h2); fFwDiff[1] = to_point(fCoefs.fA * h3 + fCoefs.fB * h2 + fCoefs.fC * h); fFwDiff[0] = to_point(fCoefs.fD); } /** * Check if the evaluator is still within the range of 0<=t<=1 */ bool done() const { return fCurrent > fMax; } /** * Call next to obtain the SkPoint sampled and move to the next one. */ SkPoint next() { SkPoint point = fFwDiff[0]; fFwDiff[0] += fFwDiff[1]; fFwDiff[1] += fFwDiff[2]; fFwDiff[2] += fFwDiff[3]; fCurrent++; return point; } const SkPoint* getCtrlPoints() const { return fPoints; } private: SkCubicCoeff fCoefs; int fMax, fCurrent, fDivisions; SkPoint fFwDiff[4], fPoints[4]; }; //////////////////////////////////////////////////////////////////////////////// // size in pixels of each partition per axis, adjust this knob static const int kPartitionSize = 10; /** * Calculate the approximate arc length given a bezier curve's control points. * Returns -1 if bad calc (i.e. non-finite) */ static SkScalar approx_arc_length(const SkPoint points[], int count) { if (count < 2) { return 0; } SkScalar arcLength = 0; for (int i = 0; i < count - 1; i++) { arcLength += SkPoint::Distance(points[i], points[i + 1]); } return SkScalarIsFinite(arcLength) ? arcLength : -1; } static SkScalar bilerp(SkScalar tx, SkScalar ty, SkScalar c00, SkScalar c10, SkScalar c01, SkScalar c11) { SkScalar a = c00 * (1.f - tx) + c10 * tx; SkScalar b = c01 * (1.f - tx) + c11 * tx; return a * (1.f - ty) + b * ty; } static Sk4f bilerp(SkScalar tx, SkScalar ty, const Sk4f& c00, const Sk4f& c10, const Sk4f& c01, const Sk4f& c11) { Sk4f a = c00 * (1.f - tx) + c10 * tx; Sk4f b = c01 * (1.f - tx) + c11 * tx; return a * (1.f - ty) + b * ty; } SkISize SkPatchUtils::GetLevelOfDetail(const SkPoint cubics[12], const SkMatrix* matrix) { // Approximate length of each cubic. SkPoint pts[kNumPtsCubic]; SkPatchUtils::GetTopCubic(cubics, pts); matrix->mapPoints(pts, kNumPtsCubic); SkScalar topLength = approx_arc_length(pts, kNumPtsCubic); SkPatchUtils::GetBottomCubic(cubics, pts); matrix->mapPoints(pts, kNumPtsCubic); SkScalar bottomLength = approx_arc_length(pts, kNumPtsCubic); SkPatchUtils::GetLeftCubic(cubics, pts); matrix->mapPoints(pts, kNumPtsCubic); SkScalar leftLength = approx_arc_length(pts, kNumPtsCubic); SkPatchUtils::GetRightCubic(cubics, pts); matrix->mapPoints(pts, kNumPtsCubic); SkScalar rightLength = approx_arc_length(pts, kNumPtsCubic); if (topLength < 0 || bottomLength < 0 || leftLength < 0 || rightLength < 0) { return {0, 0}; // negative length is a sentinel for bad length (i.e. non-finite) } // Level of detail per axis, based on the larger side between top and bottom or left and right int lodX = static_cast(SkMaxScalar(topLength, bottomLength) / kPartitionSize); int lodY = static_cast(SkMaxScalar(leftLength, rightLength) / kPartitionSize); return SkISize::Make(SkMax32(8, lodX), SkMax32(8, lodY)); } void SkPatchUtils::GetTopCubic(const SkPoint cubics[12], SkPoint points[4]) { points[0] = cubics[kTopP0_CubicCtrlPts]; points[1] = cubics[kTopP1_CubicCtrlPts]; points[2] = cubics[kTopP2_CubicCtrlPts]; points[3] = cubics[kTopP3_CubicCtrlPts]; } void SkPatchUtils::GetBottomCubic(const SkPoint cubics[12], SkPoint points[4]) { points[0] = cubics[kBottomP0_CubicCtrlPts]; points[1] = cubics[kBottomP1_CubicCtrlPts]; points[2] = cubics[kBottomP2_CubicCtrlPts]; points[3] = cubics[kBottomP3_CubicCtrlPts]; } void SkPatchUtils::GetLeftCubic(const SkPoint cubics[12], SkPoint points[4]) { points[0] = cubics[kLeftP0_CubicCtrlPts]; points[1] = cubics[kLeftP1_CubicCtrlPts]; points[2] = cubics[kLeftP2_CubicCtrlPts]; points[3] = cubics[kLeftP3_CubicCtrlPts]; } void SkPatchUtils::GetRightCubic(const SkPoint cubics[12], SkPoint points[4]) { points[0] = cubics[kRightP0_CubicCtrlPts]; points[1] = cubics[kRightP1_CubicCtrlPts]; points[2] = cubics[kRightP2_CubicCtrlPts]; points[3] = cubics[kRightP3_CubicCtrlPts]; } #include "SkPM4fPriv.h" #include "SkColorSpaceXform.h" struct SkRGBAf { float fVec[4]; static SkRGBAf From4f(const Sk4f& x) { SkRGBAf c; x.store(c.fVec); return c; } static SkRGBAf FromBGRA32(SkColor c) { return From4f(swizzle_rb(SkNx_cast(Sk4b::Load(&c)) * (1/255.0f))); } Sk4f to4f() const { return Sk4f::Load(fVec); } SkColor toBGRA32() const { SkColor color; SkNx_cast(swizzle_rb(this->to4f()) * Sk4f(255) + Sk4f(0.5f)).store(&color); return color; } SkRGBAf premul() const { float a = fVec[3]; return From4f(this->to4f() * Sk4f(a, a, a, 1)); } SkRGBAf unpremul() const { float a = fVec[3]; float inv = a ? 1/a : 0; return From4f(this->to4f() * Sk4f(inv, inv, inv, 1)); } }; static void skcolor_to_float(SkRGBAf dst[], const SkColor src[], int count, SkColorSpace* dstCS, bool doPremul) { // Source is always sRGB SkColor. auto srcCS = sk_srgb_singleton(); auto op = doPremul ? SkColorSpaceXform::kPremul_AlphaOp : SkColorSpaceXform::kPreserve_AlphaOp; SkAssertResult(SkColorSpaceXform::Apply(dstCS, SkColorSpaceXform::kRGBA_F32_ColorFormat, dst, srcCS, SkColorSpaceXform::kBGRA_8888_ColorFormat, src, count, op)); } static void float_to_skcolor(SkColor dst[], const SkRGBAf src[], int count, SkColorSpace* srcCS) { // Destination is always sRGB SkColor. auto dstCS = sk_srgb_singleton(); SkAssertResult(SkColorSpaceXform::Apply(dstCS, SkColorSpaceXform::kBGRA_8888_ColorFormat, dst, srcCS, SkColorSpaceXform::kRGBA_F32_ColorFormat, src, count, SkColorSpaceXform::kPreserve_AlphaOp)); } static void unpremul(SkRGBAf array[], int count) { for (int i = 0; i < count; ++i) { array[i] = array[i].unpremul(); } } sk_sp SkPatchUtils::MakeVertices(const SkPoint cubics[12], const SkColor srcColors[4], const SkPoint srcTexCoords[4], int lodX, int lodY, SkColorSpace* colorSpace) { if (lodX < 1 || lodY < 1 || nullptr == cubics) { return nullptr; } // check for overflow in multiplication const int64_t lodX64 = (lodX + 1), lodY64 = (lodY + 1), mult64 = lodX64 * lodY64; if (mult64 > SK_MaxS32) { return nullptr; } // Treat null interpolation space as sRGB. if (!colorSpace) { colorSpace = sk_srgb_singleton(); } int vertexCount = SkToS32(mult64); // it is recommended to generate draw calls of no more than 65536 indices, so we never generate // more than 60000 indices. To accomplish that we resize the LOD and vertex count if (vertexCount > 10000 || lodX > 200 || lodY > 200) { float weightX = static_cast(lodX) / (lodX + lodY); float weightY = static_cast(lodY) / (lodX + lodY); // 200 comes from the 100 * 2 which is the max value of vertices because of the limit of // 60000 indices ( sqrt(60000 / 6) that comes from data->fIndexCount = lodX * lodY * 6) // Need a min of 1 since we later divide by lod lodX = std::max(1, sk_float_floor2int_no_saturate(weightX * 200)); lodY = std::max(1, sk_float_floor2int_no_saturate(weightY * 200)); vertexCount = (lodX + 1) * (lodY + 1); } const int indexCount = lodX * lodY * 6; uint32_t flags = 0; if (srcTexCoords) { flags |= SkVertices::kHasTexCoords_BuilderFlag; } if (srcColors) { flags |= SkVertices::kHasColors_BuilderFlag; } SkSTArenaAlloc<2048> alloc; SkRGBAf* cornerColors = srcColors ? alloc.makeArray(4) : nullptr; SkRGBAf* tmpColors = srcColors ? alloc.makeArray(vertexCount) : nullptr; SkVertices::Builder builder(SkVertices::kTriangles_VertexMode, vertexCount, indexCount, flags); SkPoint* pos = builder.positions(); SkPoint* texs = builder.texCoords(); uint16_t* indices = builder.indices(); bool is_opaque = false; /* * 1. Should we offer this as a runtime choice, as we do in gradients? * 2. Since drawing the vertices wants premul, shoudl we extend SkVertices to store * premul colors (as floats, w/ a colorspace)? */ bool doPremul = true; if (cornerColors) { SkColor c = ~0; for (int i = 0; i < kNumCorners; i++) { c &= srcColors[i]; } is_opaque = (SkColorGetA(c) == 0xFF); if (is_opaque) { doPremul = false; // no need } skcolor_to_float(cornerColors, srcColors, kNumCorners, colorSpace, doPremul); } SkPoint pts[kNumPtsCubic]; SkPatchUtils::GetBottomCubic(cubics, pts); FwDCubicEvaluator fBottom(pts); SkPatchUtils::GetTopCubic(cubics, pts); FwDCubicEvaluator fTop(pts); SkPatchUtils::GetLeftCubic(cubics, pts); FwDCubicEvaluator fLeft(pts); SkPatchUtils::GetRightCubic(cubics, pts); FwDCubicEvaluator fRight(pts); fBottom.restart(lodX); fTop.restart(lodX); SkScalar u = 0.0f; int stride = lodY + 1; for (int x = 0; x <= lodX; x++) { SkPoint bottom = fBottom.next(), top = fTop.next(); fLeft.restart(lodY); fRight.restart(lodY); SkScalar v = 0.f; for (int y = 0; y <= lodY; y++) { int dataIndex = x * (lodY + 1) + y; SkPoint left = fLeft.next(), right = fRight.next(); SkPoint s0 = SkPoint::Make((1.0f - v) * top.x() + v * bottom.x(), (1.0f - v) * top.y() + v * bottom.y()); SkPoint s1 = SkPoint::Make((1.0f - u) * left.x() + u * right.x(), (1.0f - u) * left.y() + u * right.y()); SkPoint s2 = SkPoint::Make( (1.0f - v) * ((1.0f - u) * fTop.getCtrlPoints()[0].x() + u * fTop.getCtrlPoints()[3].x()) + v * ((1.0f - u) * fBottom.getCtrlPoints()[0].x() + u * fBottom.getCtrlPoints()[3].x()), (1.0f - v) * ((1.0f - u) * fTop.getCtrlPoints()[0].y() + u * fTop.getCtrlPoints()[3].y()) + v * ((1.0f - u) * fBottom.getCtrlPoints()[0].y() + u * fBottom.getCtrlPoints()[3].y())); pos[dataIndex] = s0 + s1 - s2; if (cornerColors) { bilerp(u, v, cornerColors[kTopLeft_Corner].to4f(), cornerColors[kTopRight_Corner].to4f(), cornerColors[kBottomLeft_Corner].to4f(), cornerColors[kBottomRight_Corner].to4f()).store(tmpColors[dataIndex].fVec); if (is_opaque) { tmpColors[dataIndex].fVec[3] = 1; } } if (texs) { texs[dataIndex] = SkPoint::Make(bilerp(u, v, srcTexCoords[kTopLeft_Corner].x(), srcTexCoords[kTopRight_Corner].x(), srcTexCoords[kBottomLeft_Corner].x(), srcTexCoords[kBottomRight_Corner].x()), bilerp(u, v, srcTexCoords[kTopLeft_Corner].y(), srcTexCoords[kTopRight_Corner].y(), srcTexCoords[kBottomLeft_Corner].y(), srcTexCoords[kBottomRight_Corner].y())); } if(x < lodX && y < lodY) { int i = 6 * (x * lodY + y); indices[i] = x * stride + y; indices[i + 1] = x * stride + 1 + y; indices[i + 2] = (x + 1) * stride + 1 + y; indices[i + 3] = indices[i]; indices[i + 4] = indices[i + 2]; indices[i + 5] = (x + 1) * stride + y; } v = SkScalarClampMax(v + 1.f / lodY, 1); } u = SkScalarClampMax(u + 1.f / lodX, 1); } if (tmpColors) { if (doPremul) { unpremul(tmpColors, vertexCount); } float_to_skcolor(builder.colors(), tmpColors, vertexCount, colorSpace); } return builder.detach(); }