src/gpu/geometry/GrPathUtils.cpp - skia - Git at Google

 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/geometry/GrPathUtils.h"

 #include "include/gpu/GrTypes.h"
 #include "src/core/SkMathPriv.h"
 #include "src/core/SkPointPriv.h"
 #include "src/core/SkUtils.h"
 #include "src/gpu/tessellate/WangsFormula.h"

 static const SkScalar kMinCurveTol = 0.0001f;

 static float tolerance_to_wangs_precision(float srcTol) {
     // You should have called scaleToleranceToSrc, which guarantees this
     SkASSERT(srcTol >= kMinCurveTol);

     // The GrPathUtil API defines tolerance as the max distance the linear segment can be from
     // the real curve. Wang's formula guarantees the linear segments will be within 1/precision
     // of the true curve, so precision = 1/srcTol
     return 1.f / srcTol;
 }

 uint32_t max_bezier_vertices(uint32_t chopCount) {
     static constexpr uint32_t kMaxChopsPerCurve = 10;
     static_assert((1 << kMaxChopsPerCurve) == GrPathUtils::kMaxPointsPerCurve);
     return 1 << std::min(chopCount, kMaxChopsPerCurve);
 }

 SkScalar GrPathUtils::scaleToleranceToSrc(SkScalar devTol,
                                           const SkMatrix& viewM,
                                           const SkRect& pathBounds) {
     // In order to tesselate the path we get a bound on how much the matrix can
     // scale when mapping to screen coordinates.
     SkScalar stretch = viewM.getMaxScale();

     if (stretch < 0) {
         // take worst case mapRadius amoung four corners.
         // (less than perfect)
         for (int i = 0; i < 4; ++i) {
             SkMatrix mat;
             mat.setTranslate((i % 2) ? pathBounds.fLeft : pathBounds.fRight,
                              (i < 2) ? pathBounds.fTop : pathBounds.fBottom);
             mat.postConcat(viewM);
             stretch = std::max(stretch, mat.mapRadius(SK_Scalar1));
         }
     }
     SkScalar srcTol = 0;
     if (stretch <= 0) {
         // We have degenerate bounds or some degenerate matrix. Thus we set the tolerance to be the
         // max of the path pathBounds width and height.
         srcTol = std::max(pathBounds.width(), pathBounds.height());
     } else {
         srcTol = devTol / stretch;
     }
     if (srcTol < kMinCurveTol) {
         srcTol = kMinCurveTol;
     }
     return srcTol;
 }

 uint32_t GrPathUtils::quadraticPointCount(const SkPoint points[], SkScalar tol) {
     return max_bezier_vertices(skgpu::wangs_formula::quadratic_log2(
             tolerance_to_wangs_precision(tol), points));
 }

 uint32_t GrPathUtils::generateQuadraticPoints(const SkPoint& p0,
                                               const SkPoint& p1,
                                               const SkPoint& p2,
                                               SkScalar tolSqd,
                                               SkPoint** points,
                                               uint32_t pointsLeft) {
     if (pointsLeft < 2 ||
         (SkPointPriv::DistanceToLineSegmentBetweenSqd(p1, p0, p2)) < tolSqd) {
         (*points)[0] = p2;
         *points += 1;
         return 1;
     }

     SkPoint q[] = {
         { SkScalarAve(p0.fX, p1.fX), SkScalarAve(p0.fY, p1.fY) },
         { SkScalarAve(p1.fX, p2.fX), SkScalarAve(p1.fY, p2.fY) },
     };
     SkPoint r = { SkScalarAve(q[0].fX, q[1].fX), SkScalarAve(q[0].fY, q[1].fY) };

     pointsLeft >>= 1;
     uint32_t a = generateQuadraticPoints(p0, q[0], r, tolSqd, points, pointsLeft);
     uint32_t b = generateQuadraticPoints(r, q[1], p2, tolSqd, points, pointsLeft);
     return a + b;
 }

 uint32_t GrPathUtils::cubicPointCount(const SkPoint points[], SkScalar tol) {
     return max_bezier_vertices(skgpu::wangs_formula::cubic_log2(
             tolerance_to_wangs_precision(tol), points));
 }

 uint32_t GrPathUtils::generateCubicPoints(const SkPoint& p0,
                                           const SkPoint& p1,
                                           const SkPoint& p2,
                                           const SkPoint& p3,
                                           SkScalar tolSqd,
                                           SkPoint** points,
                                           uint32_t pointsLeft) {
     if (pointsLeft < 2 ||
         (SkPointPriv::DistanceToLineSegmentBetweenSqd(p1, p0, p3) < tolSqd &&
          SkPointPriv::DistanceToLineSegmentBetweenSqd(p2, p0, p3) < tolSqd)) {
         (*points)[0] = p3;
         *points += 1;
         return 1;
     }
     SkPoint q[] = {
         { SkScalarAve(p0.fX, p1.fX), SkScalarAve(p0.fY, p1.fY) },
         { SkScalarAve(p1.fX, p2.fX), SkScalarAve(p1.fY, p2.fY) },
         { SkScalarAve(p2.fX, p3.fX), SkScalarAve(p2.fY, p3.fY) }
     };
     SkPoint r[] = {
         { SkScalarAve(q[0].fX, q[1].fX), SkScalarAve(q[0].fY, q[1].fY) },
         { SkScalarAve(q[1].fX, q[2].fX), SkScalarAve(q[1].fY, q[2].fY) }
     };
     SkPoint s = { SkScalarAve(r[0].fX, r[1].fX), SkScalarAve(r[0].fY, r[1].fY) };
     pointsLeft >>= 1;
     uint32_t a = generateCubicPoints(p0, q[0], r[0], s, tolSqd, points, pointsLeft);
     uint32_t b = generateCubicPoints(s, r[1], q[2], p3, tolSqd, points, pointsLeft);
     return a + b;
 }

 void GrPathUtils::QuadUVMatrix::set(const SkPoint qPts[3]) {
     SkMatrix m;
     // We want M such that M * xy_pt = uv_pt
     // We know M * control_pts = [0  1/2 1]
     //                           [0  0   1]
     //                           [1  1   1]
     // And control_pts = [x0 x1 x2]
     //                   [y0 y1 y2]
     //                   [1  1  1 ]
     // We invert the control pt matrix and post concat to both sides to get M.
     // Using the known form of the control point matrix and the result, we can
     // optimize and improve precision.

     double x0 = qPts[0].fX;
     double y0 = qPts[0].fY;
     double x1 = qPts[1].fX;
     double y1 = qPts[1].fY;
     double x2 = qPts[2].fX;
     double y2 = qPts[2].fY;
     double det = x0*y1 - y0*x1 + x2*y0 - y2*x0 + x1*y2 - y1*x2;

     if (!sk_float_isfinite(det)
         || SkScalarNearlyZero((float)det, SK_ScalarNearlyZero * SK_ScalarNearlyZero)) {
         // The quad is degenerate. Hopefully this is rare. Find the pts that are
         // farthest apart to compute a line (unless it is really a pt).
         SkScalar maxD = SkPointPriv::DistanceToSqd(qPts[0], qPts[1]);
         int maxEdge = 0;
         SkScalar d = SkPointPriv::DistanceToSqd(qPts[1], qPts[2]);
         if (d > maxD) {
             maxD = d;
             maxEdge = 1;
         }
         d = SkPointPriv::DistanceToSqd(qPts[2], qPts[0]);
         if (d > maxD) {
             maxD = d;
             maxEdge = 2;
         }
         // We could have a tolerance here, not sure if it would improve anything
         if (maxD > 0) {
             // Set the matrix to give (u = 0, v = distance_to_line)
             SkVector lineVec = qPts[(maxEdge + 1)%3] - qPts[maxEdge];
             // when looking from the point 0 down the line we want positive
             // distances to be to the left. This matches the non-degenerate
             // case.
             lineVec = SkPointPriv::MakeOrthog(lineVec, SkPointPriv::kLeft_Side);
             // first row
             fM[0] = 0;
             fM[1] = 0;
             fM[2] = 0;
             // second row
             fM[3] = lineVec.fX;
             fM[4] = lineVec.fY;
             fM[5] = -lineVec.dot(qPts[maxEdge]);
         } else {
             // It's a point. It should cover zero area. Just set the matrix such
             // that (u, v) will always be far away from the quad.
             fM[0] = 0; fM[1] = 0; fM[2] = 100.f;
             fM[3] = 0; fM[4] = 0; fM[5] = 100.f;
         }
     } else {
         double scale = 1.0/det;

         // compute adjugate matrix
         double a2, a3, a4, a5, a6, a7, a8;
         a2 = x1*y2-x2*y1;

         a3 = y2-y0;
         a4 = x0-x2;
         a5 = x2*y0-x0*y2;

         a6 = y0-y1;
         a7 = x1-x0;
         a8 = x0*y1-x1*y0;

         // this performs the uv_pts*adjugate(control_pts) multiply,
         // then does the scale by 1/det afterwards to improve precision
         m[SkMatrix::kMScaleX] = (float)((0.5*a3 + a6)*scale);
         m[SkMatrix::kMSkewX]  = (float)((0.5*a4 + a7)*scale);
         m[SkMatrix::kMTransX] = (float)((0.5*a5 + a8)*scale);

         m[SkMatrix::kMSkewY]  = (float)(a6*scale);
         m[SkMatrix::kMScaleY] = (float)(a7*scale);
         m[SkMatrix::kMTransY] = (float)(a8*scale);

         // kMPersp0 & kMPersp1 should algebraically be zero
         m[SkMatrix::kMPersp0] = 0.0f;
         m[SkMatrix::kMPersp1] = 0.0f;
         m[SkMatrix::kMPersp2] = (float)((a2 + a5 + a8)*scale);

         // It may not be normalized to have 1.0 in the bottom right
         float m33 = m.get(SkMatrix::kMPersp2);
         if (1.f != m33) {
             m33 = 1.f / m33;
             fM[0] = m33 * m.get(SkMatrix::kMScaleX);
             fM[1] = m33 * m.get(SkMatrix::kMSkewX);
             fM[2] = m33 * m.get(SkMatrix::kMTransX);
             fM[3] = m33 * m.get(SkMatrix::kMSkewY);
             fM[4] = m33 * m.get(SkMatrix::kMScaleY);
             fM[5] = m33 * m.get(SkMatrix::kMTransY);
         } else {
             fM[0] = m.get(SkMatrix::kMScaleX);
             fM[1] = m.get(SkMatrix::kMSkewX);
             fM[2] = m.get(SkMatrix::kMTransX);
             fM[3] = m.get(SkMatrix::kMSkewY);
             fM[4] = m.get(SkMatrix::kMScaleY);
             fM[5] = m.get(SkMatrix::kMTransY);
         }
     }
 }

 ////////////////////////////////////////////////////////////////////////////////

 // k = (y2 - y0, x0 - x2, x2*y0 - x0*y2)
 // l = (y1 - y0, x0 - x1, x1*y0 - x0*y1) * 2*w
 // m = (y2 - y1, x1 - x2, x2*y1 - x1*y2) * 2*w
 void GrPathUtils::getConicKLM(const SkPoint p[3], const SkScalar weight, SkMatrix* out) {
     SkMatrix& klm = *out;
     const SkScalar w2 = 2.f * weight;
     klm[0] = p[2].fY - p[0].fY;
     klm[1] = p[0].fX - p[2].fX;
     klm[2] = p[2].fX * p[0].fY - p[0].fX * p[2].fY;

     klm[3] = w2 * (p[1].fY - p[0].fY);
     klm[4] = w2 * (p[0].fX - p[1].fX);
     klm[5] = w2 * (p[1].fX * p[0].fY - p[0].fX * p[1].fY);

     klm[6] = w2 * (p[2].fY - p[1].fY);
     klm[7] = w2 * (p[1].fX - p[2].fX);
     klm[8] = w2 * (p[2].fX * p[1].fY - p[1].fX * p[2].fY);

     // scale the max absolute value of coeffs to 10
     SkScalar scale = 0.f;
     for (int i = 0; i < 9; ++i) {
        scale = std::max(scale, SkScalarAbs(klm[i]));
     }
     SkASSERT(scale > 0.f);
     scale = 10.f / scale;
     for (int i = 0; i < 9; ++i) {
         klm[i] *= scale;
     }
 }

 ////////////////////////////////////////////////////////////////////////////////

 namespace {

 // a is the first control point of the cubic.
 // ab is the vector from a to the second control point.
 // dc is the vector from the fourth to the third control point.
 // d is the fourth control point.
 // p is the candidate quadratic control point.
 // this assumes that the cubic doesn't inflect and is simple
 bool is_point_within_cubic_tangents(const SkPoint& a,
                                     const SkVector& ab,
                                     const SkVector& dc,
                                     const SkPoint& d,
                                     SkPathFirstDirection dir,
                                     const SkPoint p) {
     SkVector ap = p - a;
     SkScalar apXab = ap.cross(ab);
     if (SkPathFirstDirection::kCW == dir) {
         if (apXab > 0) {
             return false;
         }
     } else {
         SkASSERT(SkPathFirstDirection::kCCW == dir);
         if (apXab < 0) {
             return false;
         }
     }

     SkVector dp = p - d;
     SkScalar dpXdc = dp.cross(dc);
     if (SkPathFirstDirection::kCW == dir) {
         if (dpXdc < 0) {
             return false;
         }
     } else {
         SkASSERT(SkPathFirstDirection::kCCW == dir);
         if (dpXdc > 0) {
             return false;
         }
     }
     return true;
 }

 void convert_noninflect_cubic_to_quads(const SkPoint p[4],
                                        SkScalar toleranceSqd,
                                        SkTArray<SkPoint, true>* quads,
                                        int sublevel = 0,
                                        bool preserveFirstTangent = true,
                                        bool preserveLastTangent = true) {
     // Notation: Point a is always p[0]. Point b is p[1] unless p[1] == p[0], in which case it is
     // p[2]. Point d is always p[3]. Point c is p[2] unless p[2] == p[3], in which case it is p[1].
     SkVector ab = p[1] - p[0];
     SkVector dc = p[2] - p[3];

     if (SkPointPriv::LengthSqd(ab) < SK_ScalarNearlyZero) {
         if (SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero) {
             SkPoint* degQuad = quads->push_back_n(3);
             degQuad[0] = p[0];
             degQuad[1] = p[0];
             degQuad[2] = p[3];
             return;
         }
         ab = p[2] - p[0];
     }
     if (SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero) {
         dc = p[1] - p[3];
     }

     static const SkScalar kLengthScale = 3 * SK_Scalar1 / 2;
     static const int kMaxSubdivs = 10;

     ab.scale(kLengthScale);
     dc.scale(kLengthScale);

     // c0 and c1 are extrapolations along vectors ab and dc.
     SkPoint c0 = p[0] + ab;
     SkPoint c1 = p[3] + dc;

     SkScalar dSqd = sublevel > kMaxSubdivs ? 0 : SkPointPriv::DistanceToSqd(c0, c1);
     if (dSqd < toleranceSqd) {
         SkPoint newC;
         if (preserveFirstTangent == preserveLastTangent) {
             // We used to force a split when both tangents need to be preserved and c0 != c1.
             // This introduced a large performance regression for tiny paths for no noticeable
             // quality improvement. However, we aren't quite fulfilling our contract of guaranteeing
             // the two tangent vectors and this could introduce a missed pixel in
             // AAHairlinePathRenderer.
             newC = (c0 + c1) * 0.5f;
         } else if (preserveFirstTangent) {
             newC = c0;
         } else {
             newC = c1;
         }

         SkPoint* pts = quads->push_back_n(3);
         pts[0] = p[0];
         pts[1] = newC;
         pts[2] = p[3];
         return;
     }
     SkPoint choppedPts[7];
     SkChopCubicAtHalf(p, choppedPts);
     convert_noninflect_cubic_to_quads(
             choppedPts + 0, toleranceSqd, quads, sublevel + 1, preserveFirstTangent, false);
     convert_noninflect_cubic_to_quads(
             choppedPts + 3, toleranceSqd, quads, sublevel + 1, false, preserveLastTangent);
 }

 void convert_noninflect_cubic_to_quads_with_constraint(const SkPoint p[4],
                                                        SkScalar toleranceSqd,
                                                        SkPathFirstDirection dir,
                                                        SkTArray<SkPoint, true>* quads,
                                                        int sublevel = 0) {
     // Notation: Point a is always p[0]. Point b is p[1] unless p[1] == p[0], in which case it is
     // p[2]. Point d is always p[3]. Point c is p[2] unless p[2] == p[3], in which case it is p[1].

     SkVector ab = p[1] - p[0];
     SkVector dc = p[2] - p[3];

     if (SkPointPriv::LengthSqd(ab) < SK_ScalarNearlyZero) {
         if (SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero) {
             SkPoint* degQuad = quads->push_back_n(3);
             degQuad[0] = p[0];
             degQuad[1] = p[0];
             degQuad[2] = p[3];
             return;
         }
         ab = p[2] - p[0];
     }
     if (SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero) {
         dc = p[1] - p[3];
     }

     // When the ab and cd tangents are degenerate or nearly parallel with vector from d to a the
     // constraint that the quad point falls between the tangents becomes hard to enforce and we are
     // likely to hit the max subdivision count. However, in this case the cubic is approaching a
     // line and the accuracy of the quad point isn't so important. We check if the two middle cubic
     // control points are very close to the baseline vector. If so then we just pick quadratic
     // points on the control polygon.

     SkVector da = p[0] - p[3];
     bool doQuads = SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero ||
                    SkPointPriv::LengthSqd(ab) < SK_ScalarNearlyZero;
     if (!doQuads) {
         SkScalar invDALengthSqd = SkPointPriv::LengthSqd(da);
         if (invDALengthSqd > SK_ScalarNearlyZero) {
             invDALengthSqd = SkScalarInvert(invDALengthSqd);
             // cross(ab, da)^2/length(da)^2 == sqd distance from b to line from d to a.
             // same goes for point c using vector cd.
             SkScalar detABSqd = ab.cross(da);
             detABSqd = SkScalarSquare(detABSqd);
             SkScalar detDCSqd = dc.cross(da);
             detDCSqd = SkScalarSquare(detDCSqd);
             if (detABSqd * invDALengthSqd < toleranceSqd &&
                 detDCSqd * invDALengthSqd < toleranceSqd) {
                 doQuads = true;
             }
         }
     }
     if (doQuads) {
         SkPoint b = p[0] + ab;
         SkPoint c = p[3] + dc;
         SkPoint mid = b + c;
         mid.scale(SK_ScalarHalf);
         // Insert two quadratics to cover the case when ab points away from d and/or dc
         // points away from a.
         if (SkVector::DotProduct(da, dc) < 0 || SkVector::DotProduct(ab, da) > 0) {
             SkPoint* qpts = quads->push_back_n(6);
             qpts[0] = p[0];
             qpts[1] = b;
             qpts[2] = mid;
             qpts[3] = mid;
             qpts[4] = c;
             qpts[5] = p[3];
         } else {
             SkPoint* qpts = quads->push_back_n(3);
             qpts[0] = p[0];
             qpts[1] = mid;
             qpts[2] = p[3];
         }
         return;
     }

     static const SkScalar kLengthScale = 3 * SK_Scalar1 / 2;
     static const int kMaxSubdivs = 10;

     ab.scale(kLengthScale);
     dc.scale(kLengthScale);

     // c0 and c1 are extrapolations along vectors ab and dc.
     SkVector c0 = p[0] + ab;
     SkVector c1 = p[3] + dc;

     SkScalar dSqd = sublevel > kMaxSubdivs ? 0 : SkPointPriv::DistanceToSqd(c0, c1);
     if (dSqd < toleranceSqd) {
         SkPoint cAvg = (c0 + c1) * 0.5f;
         bool subdivide = false;

         if (!is_point_within_cubic_tangents(p[0], ab, dc, p[3], dir, cAvg)) {
             // choose a new cAvg that is the intersection of the two tangent lines.
             ab = SkPointPriv::MakeOrthog(ab);
             SkScalar z0 = -ab.dot(p[0]);
             dc = SkPointPriv::MakeOrthog(dc);
             SkScalar z1 = -dc.dot(p[3]);
             cAvg.fX = ab.fY * z1 - z0 * dc.fY;
             cAvg.fY = z0 * dc.fX - ab.fX * z1;
             SkScalar z = ab.fX * dc.fY - ab.fY * dc.fX;
             z = SkScalarInvert(z);
             cAvg.fX *= z;
             cAvg.fY *= z;
             if (sublevel <= kMaxSubdivs) {
                 SkScalar d0Sqd = SkPointPriv::DistanceToSqd(c0, cAvg);
                 SkScalar d1Sqd = SkPointPriv::DistanceToSqd(c1, cAvg);
                 // We need to subdivide if d0 + d1 > tolerance but we have the sqd values. We know
                 // the distances and tolerance can't be negative.
                 // (d0 + d1)^2 > toleranceSqd
                 // d0Sqd + 2*d0*d1 + d1Sqd > toleranceSqd
                 SkScalar d0d1 = SkScalarSqrt(d0Sqd * d1Sqd);
                 subdivide = 2 * d0d1 + d0Sqd + d1Sqd > toleranceSqd;
             }
         }
         if (!subdivide) {
             SkPoint* pts = quads->push_back_n(3);
             pts[0] = p[0];
             pts[1] = cAvg;
             pts[2] = p[3];
             return;
         }
     }
     SkPoint choppedPts[7];
     SkChopCubicAtHalf(p, choppedPts);
     convert_noninflect_cubic_to_quads_with_constraint(
             choppedPts + 0, toleranceSqd, dir, quads, sublevel + 1);
     convert_noninflect_cubic_to_quads_with_constraint(
             choppedPts + 3, toleranceSqd, dir, quads, sublevel + 1);
 }
 }  // namespace

 void GrPathUtils::convertCubicToQuads(const SkPoint p[4],
                                       SkScalar tolScale,
                                       SkTArray<SkPoint, true>* quads) {
     if (!p[0].isFinite() || !p[1].isFinite() || !p[2].isFinite() || !p[3].isFinite()) {
         return;
     }
     if (!SkScalarIsFinite(tolScale)) {
         return;
     }
     SkPoint chopped[10];
     int count = SkChopCubicAtInflections(p, chopped);

     const SkScalar tolSqd = SkScalarSquare(tolScale);

     for (int i = 0; i < count; ++i) {
         SkPoint* cubic = chopped + 3*i;
         convert_noninflect_cubic_to_quads(cubic, tolSqd, quads);
     }
 }

 void GrPathUtils::convertCubicToQuadsConstrainToTangents(const SkPoint p[4],
                                                          SkScalar tolScale,
                                                          SkPathFirstDirection dir,
                                                          SkTArray<SkPoint, true>* quads) {
     if (!p[0].isFinite() || !p[1].isFinite() || !p[2].isFinite() || !p[3].isFinite()) {
         return;
     }
     if (!SkScalarIsFinite(tolScale)) {
         return;
     }
     SkPoint chopped[10];
     int count = SkChopCubicAtInflections(p, chopped);

     const SkScalar tolSqd = SkScalarSquare(tolScale);

     for (int i = 0; i < count; ++i) {
         SkPoint* cubic = chopped + 3*i;
         convert_noninflect_cubic_to_quads_with_constraint(cubic, tolSqd, dir, quads);
     }
 }
	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/geometry/GrPathUtils.h"

	#include "include/gpu/GrTypes.h"
	#include "src/core/SkMathPriv.h"
	#include "src/core/SkPointPriv.h"
	#include "src/core/SkUtils.h"
	#include "src/gpu/tessellate/WangsFormula.h"

	static const SkScalar kMinCurveTol = 0.0001f;

	static float tolerance_to_wangs_precision(float srcTol) {
	// You should have called scaleToleranceToSrc, which guarantees this
	SkASSERT(srcTol >= kMinCurveTol);

	// The GrPathUtil API defines tolerance as the max distance the linear segment can be from
	// the real curve. Wang's formula guarantees the linear segments will be within 1/precision
	// of the true curve, so precision = 1/srcTol
	return 1.f / srcTol;
	}

	uint32_t max_bezier_vertices(uint32_t chopCount) {
	static constexpr uint32_t kMaxChopsPerCurve = 10;
	static_assert((1 << kMaxChopsPerCurve) == GrPathUtils::kMaxPointsPerCurve);
	return 1 << std::min(chopCount, kMaxChopsPerCurve);
	}

	SkScalar GrPathUtils::scaleToleranceToSrc(SkScalar devTol,
	const SkMatrix& viewM,
	const SkRect& pathBounds) {
	// In order to tesselate the path we get a bound on how much the matrix can
	// scale when mapping to screen coordinates.
	SkScalar stretch = viewM.getMaxScale();

	if (stretch < 0) {
	// take worst case mapRadius amoung four corners.
	// (less than perfect)
	for (int i = 0; i < 4; ++i) {
	SkMatrix mat;
	mat.setTranslate((i % 2) ? pathBounds.fLeft : pathBounds.fRight,
	(i < 2) ? pathBounds.fTop : pathBounds.fBottom);
	mat.postConcat(viewM);
	stretch = std::max(stretch, mat.mapRadius(SK_Scalar1));
	}
	}
	SkScalar srcTol = 0;
	if (stretch <= 0) {
	// We have degenerate bounds or some degenerate matrix. Thus we set the tolerance to be the
	// max of the path pathBounds width and height.
	srcTol = std::max(pathBounds.width(), pathBounds.height());
	} else {
	srcTol = devTol / stretch;
	}
	if (srcTol < kMinCurveTol) {
	srcTol = kMinCurveTol;
	}
	return srcTol;
	}

	uint32_t GrPathUtils::quadraticPointCount(const SkPoint points[], SkScalar tol) {
	return max_bezier_vertices(skgpu::wangs_formula::quadratic_log2(
	tolerance_to_wangs_precision(tol), points));
	}

	uint32_t GrPathUtils::generateQuadraticPoints(const SkPoint& p0,
	const SkPoint& p1,
	const SkPoint& p2,
	SkScalar tolSqd,
	SkPoint** points,
	uint32_t pointsLeft) {
	if (pointsLeft < 2 \|\|
	(SkPointPriv::DistanceToLineSegmentBetweenSqd(p1, p0, p2)) < tolSqd) {
	(*points)[0] = p2;
	*points += 1;
	return 1;
	}

	SkPoint q[] = {
	{ SkScalarAve(p0.fX, p1.fX), SkScalarAve(p0.fY, p1.fY) },
	{ SkScalarAve(p1.fX, p2.fX), SkScalarAve(p1.fY, p2.fY) },
	};
	SkPoint r = { SkScalarAve(q[0].fX, q[1].fX), SkScalarAve(q[0].fY, q[1].fY) };

	pointsLeft >>= 1;
	uint32_t a = generateQuadraticPoints(p0, q[0], r, tolSqd, points, pointsLeft);
	uint32_t b = generateQuadraticPoints(r, q[1], p2, tolSqd, points, pointsLeft);
	return a + b;
	}

	uint32_t GrPathUtils::cubicPointCount(const SkPoint points[], SkScalar tol) {
	return max_bezier_vertices(skgpu::wangs_formula::cubic_log2(
	tolerance_to_wangs_precision(tol), points));
	}

	uint32_t GrPathUtils::generateCubicPoints(const SkPoint& p0,
	const SkPoint& p1,
	const SkPoint& p2,
	const SkPoint& p3,
	SkScalar tolSqd,
	SkPoint** points,
	uint32_t pointsLeft) {
	if (pointsLeft < 2 \|\|
	(SkPointPriv::DistanceToLineSegmentBetweenSqd(p1, p0, p3) < tolSqd &&
	SkPointPriv::DistanceToLineSegmentBetweenSqd(p2, p0, p3) < tolSqd)) {
	(*points)[0] = p3;
	*points += 1;
	return 1;
	}
	SkPoint q[] = {
	{ SkScalarAve(p0.fX, p1.fX), SkScalarAve(p0.fY, p1.fY) },
	{ SkScalarAve(p1.fX, p2.fX), SkScalarAve(p1.fY, p2.fY) },
	{ SkScalarAve(p2.fX, p3.fX), SkScalarAve(p2.fY, p3.fY) }
	};
	SkPoint r[] = {
	{ SkScalarAve(q[0].fX, q[1].fX), SkScalarAve(q[0].fY, q[1].fY) },
	{ SkScalarAve(q[1].fX, q[2].fX), SkScalarAve(q[1].fY, q[2].fY) }
	};
	SkPoint s = { SkScalarAve(r[0].fX, r[1].fX), SkScalarAve(r[0].fY, r[1].fY) };
	pointsLeft >>= 1;
	uint32_t a = generateCubicPoints(p0, q[0], r[0], s, tolSqd, points, pointsLeft);
	uint32_t b = generateCubicPoints(s, r[1], q[2], p3, tolSqd, points, pointsLeft);
	return a + b;
	}

	void GrPathUtils::QuadUVMatrix::set(const SkPoint qPts[3]) {
	SkMatrix m;
	// We want M such that M * xy_pt = uv_pt
	// We know M * control_pts = [0 1/2 1]
	// [0 0 1]
	// [1 1 1]
	// And control_pts = [x0 x1 x2]
	// [y0 y1 y2]
	// [1 1 1 ]
	// We invert the control pt matrix and post concat to both sides to get M.
	// Using the known form of the control point matrix and the result, we can
	// optimize and improve precision.

	double x0 = qPts[0].fX;
	double y0 = qPts[0].fY;
	double x1 = qPts[1].fX;
	double y1 = qPts[1].fY;
	double x2 = qPts[2].fX;
	double y2 = qPts[2].fY;
	double det = x0y1 - y0x1 + x2y0 - y2x0 + x1y2 - y1x2;

	if (!sk_float_isfinite(det)
	\|\| SkScalarNearlyZero((float)det, SK_ScalarNearlyZero * SK_ScalarNearlyZero)) {
	// The quad is degenerate. Hopefully this is rare. Find the pts that are
	// farthest apart to compute a line (unless it is really a pt).
	SkScalar maxD = SkPointPriv::DistanceToSqd(qPts[0], qPts[1]);
	int maxEdge = 0;
	SkScalar d = SkPointPriv::DistanceToSqd(qPts[1], qPts[2]);
	if (d > maxD) {
	maxD = d;
	maxEdge = 1;
	}
	d = SkPointPriv::DistanceToSqd(qPts[2], qPts[0]);
	if (d > maxD) {
	maxD = d;
	maxEdge = 2;
	}
	// We could have a tolerance here, not sure if it would improve anything
	if (maxD > 0) {
	// Set the matrix to give (u = 0, v = distance_to_line)
	SkVector lineVec = qPts[(maxEdge + 1)%3] - qPts[maxEdge];
	// when looking from the point 0 down the line we want positive
	// distances to be to the left. This matches the non-degenerate
	// case.
	lineVec = SkPointPriv::MakeOrthog(lineVec, SkPointPriv::kLeft_Side);
	// first row
	fM[0] = 0;
	fM[1] = 0;
	fM[2] = 0;
	// second row
	fM[3] = lineVec.fX;
	fM[4] = lineVec.fY;
	fM[5] = -lineVec.dot(qPts[maxEdge]);
	} else {
	// It's a point. It should cover zero area. Just set the matrix such
	// that (u, v) will always be far away from the quad.
	fM[0] = 0; fM[1] = 0; fM[2] = 100.f;
	fM[3] = 0; fM[4] = 0; fM[5] = 100.f;
	}
	} else {
	double scale = 1.0/det;

	// compute adjugate matrix
	double a2, a3, a4, a5, a6, a7, a8;
	a2 = x1y2-x2y1;

	a3 = y2-y0;
	a4 = x0-x2;
	a5 = x2y0-x0y2;

	a6 = y0-y1;
	a7 = x1-x0;
	a8 = x0y1-x1y0;

	// this performs the uv_pts*adjugate(control_pts) multiply,
	// then does the scale by 1/det afterwards to improve precision
	m[SkMatrix::kMScaleX] = (float)((0.5a3 + a6)scale);
	m[SkMatrix::kMSkewX] = (float)((0.5a4 + a7)scale);
	m[SkMatrix::kMTransX] = (float)((0.5a5 + a8)scale);

	m[SkMatrix::kMSkewY] = (float)(a6*scale);
	m[SkMatrix::kMScaleY] = (float)(a7*scale);
	m[SkMatrix::kMTransY] = (float)(a8*scale);

	// kMPersp0 & kMPersp1 should algebraically be zero
	m[SkMatrix::kMPersp0] = 0.0f;
	m[SkMatrix::kMPersp1] = 0.0f;
	m[SkMatrix::kMPersp2] = (float)((a2 + a5 + a8)*scale);

	// It may not be normalized to have 1.0 in the bottom right
	float m33 = m.get(SkMatrix::kMPersp2);
	if (1.f != m33) {
	m33 = 1.f / m33;
	fM[0] = m33 * m.get(SkMatrix::kMScaleX);
	fM[1] = m33 * m.get(SkMatrix::kMSkewX);
	fM[2] = m33 * m.get(SkMatrix::kMTransX);
	fM[3] = m33 * m.get(SkMatrix::kMSkewY);
	fM[4] = m33 * m.get(SkMatrix::kMScaleY);
	fM[5] = m33 * m.get(SkMatrix::kMTransY);
	} else {
	fM[0] = m.get(SkMatrix::kMScaleX);
	fM[1] = m.get(SkMatrix::kMSkewX);
	fM[2] = m.get(SkMatrix::kMTransX);
	fM[3] = m.get(SkMatrix::kMSkewY);
	fM[4] = m.get(SkMatrix::kMScaleY);
	fM[5] = m.get(SkMatrix::kMTransY);
	}
	}
	}

	////////////////////////////////////////////////////////////////////////////////

	// k = (y2 - y0, x0 - x2, x2y0 - x0y2)
	// l = (y1 - y0, x0 - x1, x1y0 - x0y1) * 2*w
	// m = (y2 - y1, x1 - x2, x2y1 - x1y2) * 2*w
	void GrPathUtils::getConicKLM(const SkPoint p[3], const SkScalar weight, SkMatrix* out) {
	SkMatrix& klm = *out;
	const SkScalar w2 = 2.f * weight;
	klm[0] = p[2].fY - p[0].fY;
	klm[1] = p[0].fX - p[2].fX;
	klm[2] = p[2].fX * p[0].fY - p[0].fX * p[2].fY;

	klm[3] = w2 * (p[1].fY - p[0].fY);
	klm[4] = w2 * (p[0].fX - p[1].fX);
	klm[5] = w2 * (p[1].fX * p[0].fY - p[0].fX * p[1].fY);

	klm[6] = w2 * (p[2].fY - p[1].fY);
	klm[7] = w2 * (p[1].fX - p[2].fX);
	klm[8] = w2 * (p[2].fX * p[1].fY - p[1].fX * p[2].fY);

	// scale the max absolute value of coeffs to 10
	SkScalar scale = 0.f;
	for (int i = 0; i < 9; ++i) {
	scale = std::max(scale, SkScalarAbs(klm[i]));
	}
	SkASSERT(scale > 0.f);
	scale = 10.f / scale;
	for (int i = 0; i < 9; ++i) {
	klm[i] *= scale;
	}
	}

	////////////////////////////////////////////////////////////////////////////////

	namespace {

	// a is the first control point of the cubic.
	// ab is the vector from a to the second control point.
	// dc is the vector from the fourth to the third control point.
	// d is the fourth control point.
	// p is the candidate quadratic control point.
	// this assumes that the cubic doesn't inflect and is simple
	bool is_point_within_cubic_tangents(const SkPoint& a,
	const SkVector& ab,
	const SkVector& dc,
	const SkPoint& d,
	SkPathFirstDirection dir,
	const SkPoint p) {
	SkVector ap = p - a;
	SkScalar apXab = ap.cross(ab);
	if (SkPathFirstDirection::kCW == dir) {
	if (apXab > 0) {
	return false;
	}
	} else {
	SkASSERT(SkPathFirstDirection::kCCW == dir);
	if (apXab < 0) {
	return false;
	}
	}

	SkVector dp = p - d;
	SkScalar dpXdc = dp.cross(dc);
	if (SkPathFirstDirection::kCW == dir) {
	if (dpXdc < 0) {
	return false;
	}
	} else {
	SkASSERT(SkPathFirstDirection::kCCW == dir);
	if (dpXdc > 0) {
	return false;
	}
	}
	return true;
	}

	void convert_noninflect_cubic_to_quads(const SkPoint p[4],
	SkScalar toleranceSqd,
	SkTArray<SkPoint, true>* quads,
	int sublevel = 0,
	bool preserveFirstTangent = true,
	bool preserveLastTangent = true) {
	// Notation: Point a is always p[0]. Point b is p[1] unless p[1] == p[0], in which case it is
	// p[2]. Point d is always p[3]. Point c is p[2] unless p[2] == p[3], in which case it is p[1].
	SkVector ab = p[1] - p[0];
	SkVector dc = p[2] - p[3];

	if (SkPointPriv::LengthSqd(ab) < SK_ScalarNearlyZero) {
	if (SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero) {
	SkPoint* degQuad = quads->push_back_n(3);
	degQuad[0] = p[0];
	degQuad[1] = p[0];
	degQuad[2] = p[3];
	return;
	}
	ab = p[2] - p[0];
	}
	if (SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero) {
	dc = p[1] - p[3];
	}

	static const SkScalar kLengthScale = 3 * SK_Scalar1 / 2;
	static const int kMaxSubdivs = 10;

	ab.scale(kLengthScale);
	dc.scale(kLengthScale);

	// c0 and c1 are extrapolations along vectors ab and dc.
	SkPoint c0 = p[0] + ab;
	SkPoint c1 = p[3] + dc;

	SkScalar dSqd = sublevel > kMaxSubdivs ? 0 : SkPointPriv::DistanceToSqd(c0, c1);
	if (dSqd < toleranceSqd) {
	SkPoint newC;
	if (preserveFirstTangent == preserveLastTangent) {
	// We used to force a split when both tangents need to be preserved and c0 != c1.
	// This introduced a large performance regression for tiny paths for no noticeable
	// quality improvement. However, we aren't quite fulfilling our contract of guaranteeing
	// the two tangent vectors and this could introduce a missed pixel in
	// AAHairlinePathRenderer.
	newC = (c0 + c1) * 0.5f;
	} else if (preserveFirstTangent) {
	newC = c0;
	} else {
	newC = c1;
	}

	SkPoint* pts = quads->push_back_n(3);
	pts[0] = p[0];
	pts[1] = newC;
	pts[2] = p[3];
	return;
	}
	SkPoint choppedPts[7];
	SkChopCubicAtHalf(p, choppedPts);
	convert_noninflect_cubic_to_quads(
	choppedPts + 0, toleranceSqd, quads, sublevel + 1, preserveFirstTangent, false);
	convert_noninflect_cubic_to_quads(
	choppedPts + 3, toleranceSqd, quads, sublevel + 1, false, preserveLastTangent);
	}

	void convert_noninflect_cubic_to_quads_with_constraint(const SkPoint p[4],
	SkScalar toleranceSqd,
	SkPathFirstDirection dir,
	SkTArray<SkPoint, true>* quads,
	int sublevel = 0) {
	// Notation: Point a is always p[0]. Point b is p[1] unless p[1] == p[0], in which case it is
	// p[2]. Point d is always p[3]. Point c is p[2] unless p[2] == p[3], in which case it is p[1].

	SkVector ab = p[1] - p[0];
	SkVector dc = p[2] - p[3];

	if (SkPointPriv::LengthSqd(ab) < SK_ScalarNearlyZero) {
	if (SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero) {
	SkPoint* degQuad = quads->push_back_n(3);
	degQuad[0] = p[0];
	degQuad[1] = p[0];
	degQuad[2] = p[3];
	return;
	}
	ab = p[2] - p[0];
	}
	if (SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero) {
	dc = p[1] - p[3];
	}

	// When the ab and cd tangents are degenerate or nearly parallel with vector from d to a the
	// constraint that the quad point falls between the tangents becomes hard to enforce and we are
	// likely to hit the max subdivision count. However, in this case the cubic is approaching a
	// line and the accuracy of the quad point isn't so important. We check if the two middle cubic
	// control points are very close to the baseline vector. If so then we just pick quadratic
	// points on the control polygon.

	SkVector da = p[0] - p[3];
	bool doQuads = SkPointPriv::LengthSqd(dc) < SK_ScalarNearlyZero \|\|
	SkPointPriv::LengthSqd(ab) < SK_ScalarNearlyZero;
	if (!doQuads) {
	SkScalar invDALengthSqd = SkPointPriv::LengthSqd(da);
	if (invDALengthSqd > SK_ScalarNearlyZero) {
	invDALengthSqd = SkScalarInvert(invDALengthSqd);
	// cross(ab, da)^2/length(da)^2 == sqd distance from b to line from d to a.
	// same goes for point c using vector cd.
	SkScalar detABSqd = ab.cross(da);
	detABSqd = SkScalarSquare(detABSqd);
	SkScalar detDCSqd = dc.cross(da);
	detDCSqd = SkScalarSquare(detDCSqd);
	if (detABSqd * invDALengthSqd < toleranceSqd &&
	detDCSqd * invDALengthSqd < toleranceSqd) {
	doQuads = true;
	}
	}
	}
	if (doQuads) {
	SkPoint b = p[0] + ab;
	SkPoint c = p[3] + dc;
	SkPoint mid = b + c;
	mid.scale(SK_ScalarHalf);
	// Insert two quadratics to cover the case when ab points away from d and/or dc
	// points away from a.
	if (SkVector::DotProduct(da, dc) < 0 \|\| SkVector::DotProduct(ab, da) > 0) {
	SkPoint* qpts = quads->push_back_n(6);
	qpts[0] = p[0];
	qpts[1] = b;
	qpts[2] = mid;
	qpts[3] = mid;
	qpts[4] = c;
	qpts[5] = p[3];
	} else {
	SkPoint* qpts = quads->push_back_n(3);
	qpts[0] = p[0];
	qpts[1] = mid;
	qpts[2] = p[3];
	}
	return;
	}

	static const SkScalar kLengthScale = 3 * SK_Scalar1 / 2;
	static const int kMaxSubdivs = 10;

	ab.scale(kLengthScale);
	dc.scale(kLengthScale);

	// c0 and c1 are extrapolations along vectors ab and dc.
	SkVector c0 = p[0] + ab;
	SkVector c1 = p[3] + dc;

	SkScalar dSqd = sublevel > kMaxSubdivs ? 0 : SkPointPriv::DistanceToSqd(c0, c1);
	if (dSqd < toleranceSqd) {
	SkPoint cAvg = (c0 + c1) * 0.5f;
	bool subdivide = false;

	if (!is_point_within_cubic_tangents(p[0], ab, dc, p[3], dir, cAvg)) {
	// choose a new cAvg that is the intersection of the two tangent lines.
	ab = SkPointPriv::MakeOrthog(ab);
	SkScalar z0 = -ab.dot(p[0]);
	dc = SkPointPriv::MakeOrthog(dc);
	SkScalar z1 = -dc.dot(p[3]);
	cAvg.fX = ab.fY * z1 - z0 * dc.fY;
	cAvg.fY = z0 * dc.fX - ab.fX * z1;
	SkScalar z = ab.fX * dc.fY - ab.fY * dc.fX;
	z = SkScalarInvert(z);
	cAvg.fX *= z;
	cAvg.fY *= z;
	if (sublevel <= kMaxSubdivs) {
	SkScalar d0Sqd = SkPointPriv::DistanceToSqd(c0, cAvg);
	SkScalar d1Sqd = SkPointPriv::DistanceToSqd(c1, cAvg);
	// We need to subdivide if d0 + d1 > tolerance but we have the sqd values. We know
	// the distances and tolerance can't be negative.
	// (d0 + d1)^2 > toleranceSqd
	// d0Sqd + 2d0d1 + d1Sqd > toleranceSqd
	SkScalar d0d1 = SkScalarSqrt(d0Sqd * d1Sqd);
	subdivide = 2 * d0d1 + d0Sqd + d1Sqd > toleranceSqd;
	}
	}
	if (!subdivide) {
	SkPoint* pts = quads->push_back_n(3);
	pts[0] = p[0];
	pts[1] = cAvg;
	pts[2] = p[3];
	return;
	}
	}
	SkPoint choppedPts[7];
	SkChopCubicAtHalf(p, choppedPts);
	convert_noninflect_cubic_to_quads_with_constraint(
	choppedPts + 0, toleranceSqd, dir, quads, sublevel + 1);
	convert_noninflect_cubic_to_quads_with_constraint(
	choppedPts + 3, toleranceSqd, dir, quads, sublevel + 1);
	}
	} // namespace

	void GrPathUtils::convertCubicToQuads(const SkPoint p[4],
	SkScalar tolScale,
	SkTArray<SkPoint, true>* quads) {
	if (!p[0].isFinite() \|\| !p[1].isFinite() \|\| !p[2].isFinite() \|\| !p[3].isFinite()) {
	return;
	}
	if (!SkScalarIsFinite(tolScale)) {
	return;
	}
	SkPoint chopped[10];
	int count = SkChopCubicAtInflections(p, chopped);

	const SkScalar tolSqd = SkScalarSquare(tolScale);

	for (int i = 0; i < count; ++i) {
	SkPoint* cubic = chopped + 3*i;
	convert_noninflect_cubic_to_quads(cubic, tolSqd, quads);
	}
	}

	void GrPathUtils::convertCubicToQuadsConstrainToTangents(const SkPoint p[4],
	SkScalar tolScale,
	SkPathFirstDirection dir,
	SkTArray<SkPoint, true>* quads) {
	if (!p[0].isFinite() \|\| !p[1].isFinite() \|\| !p[2].isFinite() \|\| !p[3].isFinite()) {
	return;
	}
	if (!SkScalarIsFinite(tolScale)) {
	return;
	}
	SkPoint chopped[10];
	int count = SkChopCubicAtInflections(p, chopped);

	const SkScalar tolSqd = SkScalarSquare(tolScale);

	for (int i = 0; i < count; ++i) {
	SkPoint* cubic = chopped + 3*i;
	convert_noninflect_cubic_to_quads_with_constraint(cubic, tolSqd, dir, quads);
	}
	}