/* * Copyright 2012 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "Simplify.h" #undef SkASSERT #define SkASSERT(cond) while (!(cond)) { sk_throw(); } // Terminology: // A Path contains one of more Contours // A Contour is made up of Segment array // A Segment is described by a Verb and a Point array with 2, 3, or 4 points // A Verb is one of Line, Quad(ratic), or Cubic // A Segment contains a Span array // A Span is describes a portion of a Segment using starting and ending T // T values range from 0 to 1, where 0 is the first Point in the Segment // FIXME: remove once debugging is complete #if 0 // set to 1 for no debugging whatsoever //const bool gxRunTestsInOneThread = false; #define DEBUG_ADD_INTERSECTING_TS 0 #define DEBUG_BRIDGE 0 #define DEBUG_CROSS 0 #define DEBUG_DUMP 0 #define DEBUG_PATH_CONSTRUCTION 0 #define DEBUG_ACTIVE_SPANS 0 #define DEBUG_WINDING 0 #define DEBUG_UNUSED 0 // set to expose unused functions #define DEBUG_MARK_DONE 0 #else //const bool gRunTestsInOneThread = true; #define DEBUG_ADD_INTERSECTING_TS 0 #define DEBUG_BRIDGE 1 #define DEBUG_CROSS 1 #define DEBUG_DUMP 1 #define DEBUG_PATH_CONSTRUCTION 1 #define DEBUG_ACTIVE_SPANS 01 #define DEBUG_WINDING 01 #define DEBUG_UNUSED 0 // set to expose unused functions #define DEBUG_MARK_DONE 01 #endif #if DEBUG_ACTIVE_SPANS && !DEBUG_DUMP #undef DEBUG_DUMP #define DEBUG_DUMP 1 #endif #if DEBUG_DUMP static const char* kLVerbStr[] = {"", "line", "quad", "cubic"}; // static const char* kUVerbStr[] = {"", "Line", "Quad", "Cubic"}; static int gContourID; static int gSegmentID; #endif #ifndef DEBUG_TEST #define DEBUG_TEST 0 #endif static int LineIntersect(const SkPoint a[2], const SkPoint b[2], Intersections& intersections) { const _Line aLine = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; const _Line bLine = {{b[0].fX, b[0].fY}, {b[1].fX, b[1].fY}}; return intersect(aLine, bLine, intersections.fT[0], intersections.fT[1]); } static int QuadLineIntersect(const SkPoint a[3], const SkPoint b[2], Intersections& intersections) { const Quadratic aQuad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; const _Line bLine = {{b[0].fX, b[0].fY}, {b[1].fX, b[1].fY}}; intersect(aQuad, bLine, intersections); return intersections.fUsed; } static int CubicLineIntersect(const SkPoint a[2], const SkPoint b[3], Intersections& intersections) { const Cubic aCubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; const _Line bLine = {{b[0].fX, b[0].fY}, {b[1].fX, b[1].fY}}; return intersect(aCubic, bLine, intersections.fT[0], intersections.fT[1]); } static int QuadIntersect(const SkPoint a[3], const SkPoint b[3], Intersections& intersections) { const Quadratic aQuad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; const Quadratic bQuad = {{b[0].fX, b[0].fY}, {b[1].fX, b[1].fY}, {b[2].fX, b[2].fY}}; intersect(aQuad, bQuad, intersections); return intersections.fUsed; } static int CubicIntersect(const SkPoint a[4], const SkPoint b[4], Intersections& intersections) { const Cubic aCubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; const Cubic bCubic = {{b[0].fX, b[0].fY}, {b[1].fX, b[1].fY}, {b[2].fX, b[2].fY}, {b[3].fX, b[3].fY}}; intersect(aCubic, bCubic, intersections); return intersections.fUsed; } static int HLineIntersect(const SkPoint a[2], SkScalar left, SkScalar right, SkScalar y, bool flipped, Intersections& intersections) { const _Line aLine = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; return horizontalIntersect(aLine, left, right, y, flipped, intersections); } static int HQuadIntersect(const SkPoint a[3], SkScalar left, SkScalar right, SkScalar y, bool flipped, Intersections& intersections) { const Quadratic aQuad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; return horizontalIntersect(aQuad, left, right, y, flipped, intersections); } static int HCubicIntersect(const SkPoint a[4], SkScalar left, SkScalar right, SkScalar y, bool flipped, Intersections& intersections) { const Cubic aCubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; return horizontalIntersect(aCubic, left, right, y, flipped, intersections); } static int VLineIntersect(const SkPoint a[2], SkScalar top, SkScalar bottom, SkScalar x, bool flipped, Intersections& intersections) { const _Line aLine = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; return verticalIntersect(aLine, top, bottom, x, flipped, intersections); } static int VQuadIntersect(const SkPoint a[3], SkScalar top, SkScalar bottom, SkScalar x, bool flipped, Intersections& intersections) { const Quadratic aQuad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; return verticalIntersect(aQuad, top, bottom, x, flipped, intersections); } static int VCubicIntersect(const SkPoint a[4], SkScalar top, SkScalar bottom, SkScalar x, bool flipped, Intersections& intersections) { const Cubic aCubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; return verticalIntersect(aCubic, top, bottom, x, flipped, intersections); } static int (* const VSegmentIntersect[])(const SkPoint [], SkScalar , SkScalar , SkScalar , bool , Intersections& ) = { NULL, VLineIntersect, VQuadIntersect, VCubicIntersect }; static void LineXYAtT(const SkPoint a[2], double t, SkPoint* out) { const _Line line = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; double x, y; xy_at_t(line, t, x, y); out->fX = SkDoubleToScalar(x); out->fY = SkDoubleToScalar(y); } static void QuadXYAtT(const SkPoint a[3], double t, SkPoint* out) { const Quadratic quad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; double x, y; xy_at_t(quad, t, x, y); out->fX = SkDoubleToScalar(x); out->fY = SkDoubleToScalar(y); } static void CubicXYAtT(const SkPoint a[4], double t, SkPoint* out) { const Cubic cubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; double x, y; xy_at_t(cubic, t, x, y); out->fX = SkDoubleToScalar(x); out->fY = SkDoubleToScalar(y); } static void (* const SegmentXYAtT[])(const SkPoint [], double , SkPoint* ) = { NULL, LineXYAtT, QuadXYAtT, CubicXYAtT }; static SkScalar LineXAtT(const SkPoint a[2], double t) { const _Line aLine = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; double x; xy_at_t(aLine, t, x, *(double*) 0); return SkDoubleToScalar(x); } static SkScalar QuadXAtT(const SkPoint a[3], double t) { const Quadratic quad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; double x; xy_at_t(quad, t, x, *(double*) 0); return SkDoubleToScalar(x); } static SkScalar CubicXAtT(const SkPoint a[4], double t) { const Cubic cubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; double x; xy_at_t(cubic, t, x, *(double*) 0); return SkDoubleToScalar(x); } static SkScalar (* const SegmentXAtT[])(const SkPoint [], double ) = { NULL, LineXAtT, QuadXAtT, CubicXAtT }; static SkScalar LineYAtT(const SkPoint a[2], double t) { const _Line aLine = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; double y; xy_at_t(aLine, t, *(double*) 0, y); return SkDoubleToScalar(y); } static SkScalar QuadYAtT(const SkPoint a[3], double t) { const Quadratic quad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; double y; xy_at_t(quad, t, *(double*) 0, y); return SkDoubleToScalar(y); } static SkScalar CubicYAtT(const SkPoint a[4], double t) { const Cubic cubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; double y; xy_at_t(cubic, t, *(double*) 0, y); return SkDoubleToScalar(y); } static SkScalar (* const SegmentYAtT[])(const SkPoint [], double ) = { NULL, LineYAtT, QuadYAtT, CubicYAtT }; static SkScalar LineDXAtT(const SkPoint a[2], double ) { return a[1].fX - a[0].fX; } static SkScalar QuadDXAtT(const SkPoint a[3], double t) { const Quadratic quad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; double x; dxdy_at_t(quad, t, x, *(double*) 0); return SkDoubleToScalar(x); } static SkScalar CubicDXAtT(const SkPoint a[4], double t) { const Cubic cubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; double x; dxdy_at_t(cubic, t, x, *(double*) 0); return SkDoubleToScalar(x); } static SkScalar (* const SegmentDXAtT[])(const SkPoint [], double ) = { NULL, LineDXAtT, QuadDXAtT, CubicDXAtT }; static void LineSubDivide(const SkPoint a[2], double startT, double endT, SkPoint sub[2]) { const _Line aLine = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; _Line dst; sub_divide(aLine, startT, endT, dst); sub[0].fX = SkDoubleToScalar(dst[0].x); sub[0].fY = SkDoubleToScalar(dst[0].y); sub[1].fX = SkDoubleToScalar(dst[1].x); sub[1].fY = SkDoubleToScalar(dst[1].y); } static void QuadSubDivide(const SkPoint a[3], double startT, double endT, SkPoint sub[3]) { const Quadratic aQuad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; Quadratic dst; sub_divide(aQuad, startT, endT, dst); sub[0].fX = SkDoubleToScalar(dst[0].x); sub[0].fY = SkDoubleToScalar(dst[0].y); sub[1].fX = SkDoubleToScalar(dst[1].x); sub[1].fY = SkDoubleToScalar(dst[1].y); sub[2].fX = SkDoubleToScalar(dst[2].x); sub[2].fY = SkDoubleToScalar(dst[2].y); } static void CubicSubDivide(const SkPoint a[4], double startT, double endT, SkPoint sub[4]) { const Cubic aCubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; Cubic dst; sub_divide(aCubic, startT, endT, dst); sub[0].fX = SkDoubleToScalar(dst[0].x); sub[0].fY = SkDoubleToScalar(dst[0].y); sub[1].fX = SkDoubleToScalar(dst[1].x); sub[1].fY = SkDoubleToScalar(dst[1].y); sub[2].fX = SkDoubleToScalar(dst[2].x); sub[2].fY = SkDoubleToScalar(dst[2].y); sub[3].fX = SkDoubleToScalar(dst[3].x); sub[3].fY = SkDoubleToScalar(dst[3].y); } static void (* const SegmentSubDivide[])(const SkPoint [], double , double , SkPoint []) = { NULL, LineSubDivide, QuadSubDivide, CubicSubDivide }; #if DEBUG_UNUSED static void QuadSubBounds(const SkPoint a[3], double startT, double endT, SkRect& bounds) { SkPoint dst[3]; QuadSubDivide(a, startT, endT, dst); bounds.fLeft = bounds.fRight = dst[0].fX; bounds.fTop = bounds.fBottom = dst[0].fY; for (int index = 1; index < 3; ++index) { bounds.growToInclude(dst[index].fX, dst[index].fY); } } static void CubicSubBounds(const SkPoint a[4], double startT, double endT, SkRect& bounds) { SkPoint dst[4]; CubicSubDivide(a, startT, endT, dst); bounds.fLeft = bounds.fRight = dst[0].fX; bounds.fTop = bounds.fBottom = dst[0].fY; for (int index = 1; index < 4; ++index) { bounds.growToInclude(dst[index].fX, dst[index].fY); } } #endif static SkPath::Verb QuadReduceOrder(const SkPoint a[3], SkTDArray& reducePts) { const Quadratic aQuad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; Quadratic dst; int order = reduceOrder(aQuad, dst); if (order == 3) { return SkPath::kQuad_Verb; } for (int index = 0; index < order; ++index) { SkPoint* pt = reducePts.append(); pt->fX = SkDoubleToScalar(dst[index].x); pt->fY = SkDoubleToScalar(dst[index].y); } return (SkPath::Verb) (order - 1); } static SkPath::Verb CubicReduceOrder(const SkPoint a[4], SkTDArray& reducePts) { const Cubic aCubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; Cubic dst; int order = reduceOrder(aCubic, dst, kReduceOrder_QuadraticsAllowed); if (order == 4) { return SkPath::kCubic_Verb; } for (int index = 0; index < order; ++index) { SkPoint* pt = reducePts.append(); pt->fX = SkDoubleToScalar(dst[index].x); pt->fY = SkDoubleToScalar(dst[index].y); } return (SkPath::Verb) (order - 1); } static bool QuadIsLinear(const SkPoint a[3]) { const Quadratic aQuad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; return isLinear(aQuad, 0, 2); } static bool CubicIsLinear(const SkPoint a[4]) { const Cubic aCubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; return isLinear(aCubic, 0, 3); } static SkScalar LineLeftMost(const SkPoint a[2], double startT, double endT) { const _Line aLine = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; double x[2]; xy_at_t(aLine, startT, x[0], *(double*) 0); xy_at_t(aLine, endT, x[1], *(double*) 0); return SkMinScalar((float) x[0], (float) x[1]); } static SkScalar QuadLeftMost(const SkPoint a[3], double startT, double endT) { const Quadratic aQuad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; return (float) leftMostT(aQuad, startT, endT); } static SkScalar CubicLeftMost(const SkPoint a[4], double startT, double endT) { const Cubic aCubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; return (float) leftMostT(aCubic, startT, endT); } static SkScalar (* const SegmentLeftMost[])(const SkPoint [], double , double) = { NULL, LineLeftMost, QuadLeftMost, CubicLeftMost }; #if DEBUG_UNUSED static bool IsCoincident(const SkPoint a[2], const SkPoint& above, const SkPoint& below) { const _Line aLine = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}}; const _Line bLine = {{above.fX, above.fY}, {below.fX, below.fY}}; return implicit_matches_ulps(aLine, bLine, 32); } #endif class Segment; // sorting angles // given angles of {dx dy ddx ddy dddx dddy} sort them class Angle { public: // FIXME: this is bogus for quads and cubics // if the quads and cubics' line from end pt to ctrl pt are coincident, // there's no obvious way to determine the curve ordering from the // derivatives alone. In particular, if one quadratic's coincident tangent // is longer than the other curve, the final control point can place the // longer curve on either side of the shorter one. // Using Bezier curve focus http://cagd.cs.byu.edu/~tom/papers/bezclip.pdf // may provide some help, but nothing has been figured out yet. bool operator<(const Angle& rh) const { if ((fDy < 0) ^ (rh.fDy < 0)) { return fDy < 0; } if (fDy == 0 && rh.fDy == 0 && fDx != rh.fDx) { return fDx < rh.fDx; } SkScalar cmp = fDx * rh.fDy - rh.fDx * fDy; if (cmp) { return cmp < 0; } if ((fDDy < 0) ^ (rh.fDDy < 0)) { return fDDy < 0; } if (fDDy == 0 && rh.fDDy == 0 && fDDx != rh.fDDx) { return fDDx < rh.fDDx; } cmp = fDDx * rh.fDDy - rh.fDDx * fDDy; if (cmp) { return cmp < 0; } if ((fDDDy < 0) ^ (rh.fDDDy < 0)) { return fDDDy < 0; } if (fDDDy == 0 && rh.fDDDy == 0) { return fDDDx < rh.fDDDx; } return fDDDx * rh.fDDDy < rh.fDDDx * fDDDy; } int end() const { return fEnd; } bool isHorizontal() const { return fDy == 0 && fDDy == 0 && fDDDy == 0; } // since all angles share a point, this needs to know which point // is the common origin, i.e., whether the center is at pts[0] or pts[verb] // practically, this should only be called by addAngle void set(const SkPoint* pts, SkPath::Verb verb, const Segment* segment, int start, int end) { SkASSERT(start != end); fSegment = segment; fStart = start; fEnd = end; fDx = pts[1].fX - pts[0].fX; // b - a fDy = pts[1].fY - pts[0].fY; if (verb == SkPath::kLine_Verb) { fDDx = fDDy = fDDDx = fDDDy = 0; return; } fDDx = pts[2].fX - pts[1].fX - fDx; // a - 2b + c fDDy = pts[2].fY - pts[1].fY - fDy; if (verb == SkPath::kQuad_Verb) { fDDDx = fDDDy = 0; return; } fDDDx = pts[3].fX + 3 * (pts[1].fX - pts[2].fX) - pts[0].fX; fDDDy = pts[3].fY + 3 * (pts[1].fY - pts[2].fY) - pts[0].fY; } // noncoincident quads/cubics may have the same initial angle // as lines, so must sort by derivatives as well // if flatness turns out to be a reasonable way to sort, use the below: void setFlat(const SkPoint* pts, SkPath::Verb verb, Segment* segment, int start, int end) { fSegment = segment; fStart = start; fEnd = end; fDx = pts[1].fX - pts[0].fX; // b - a fDy = pts[1].fY - pts[0].fY; if (verb == SkPath::kLine_Verb) { fDDx = fDDy = fDDDx = fDDDy = 0; return; } if (verb == SkPath::kQuad_Verb) { int uplsX = FloatAsInt(pts[2].fX - pts[1].fY - fDx); int uplsY = FloatAsInt(pts[2].fY - pts[1].fY - fDy); int larger = std::max(abs(uplsX), abs(uplsY)); int shift = 0; double flatT; SkPoint ddPt; // FIXME: get rid of copy (change fDD_ to point) LineParameters implicitLine; _Line tangent = {{pts[0].fX, pts[0].fY}, {pts[1].fX, pts[1].fY}}; implicitLine.lineEndPoints(tangent); implicitLine.normalize(); while (larger > UlpsEpsilon * 1024) { larger >>= 2; ++shift; flatT = 0.5 / (1 << shift); QuadXYAtT(pts, flatT, &ddPt); _Point _pt = {ddPt.fX, ddPt.fY}; double distance = implicitLine.pointDistance(_pt); if (approximately_zero(distance)) { SkDebugf("%s ulps too small %1.9g\n", __FUNCTION__, distance); break; } } flatT = 0.5 / (1 << shift); QuadXYAtT(pts, flatT, &ddPt); fDDx = ddPt.fX - pts[0].fX; fDDy = ddPt.fY - pts[0].fY; SkASSERT(fDDx != 0 || fDDy != 0); fDDDx = fDDDy = 0; return; } SkASSERT(0); // FIXME: add cubic case } Segment* segment() const { return const_cast(fSegment); } int sign() const { return SkSign32(fStart - fEnd); } int start() const { return fStart; } private: SkScalar fDx; SkScalar fDy; SkScalar fDDx; SkScalar fDDy; SkScalar fDDDx; SkScalar fDDDy; const Segment* fSegment; int fStart; int fEnd; }; static void sortAngles(SkTDArray& angles, SkTDArray& angleList) { int angleCount = angles.count(); int angleIndex; angleList.setReserve(angleCount); for (angleIndex = 0; angleIndex < angleCount; ++angleIndex) { *angleList.append() = &angles[angleIndex]; } QSort(angleList.begin(), angleList.end() - 1); } // Bounds, unlike Rect, does not consider a line to be empty. struct Bounds : public SkRect { static bool Intersects(const Bounds& a, const Bounds& b) { return a.fLeft <= b.fRight && b.fLeft <= a.fRight && a.fTop <= b.fBottom && b.fTop <= a.fBottom; } void add(SkScalar left, SkScalar top, SkScalar right, SkScalar bottom) { if (left < fLeft) { fLeft = left; } if (top < fTop) { fTop = top; } if (right > fRight) { fRight = right; } if (bottom > fBottom) { fBottom = bottom; } } void add(const Bounds& toAdd) { add(toAdd.fLeft, toAdd.fTop, toAdd.fRight, toAdd.fBottom); } bool isEmpty() { return fLeft > fRight || fTop > fBottom || fLeft == fRight && fTop == fBottom || isnan(fLeft) || isnan(fRight) || isnan(fTop) || isnan(fBottom); } void setCubicBounds(const SkPoint a[4]) { _Rect dRect; Cubic cubic = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}, {a[3].fX, a[3].fY}}; dRect.setBounds(cubic); set((float) dRect.left, (float) dRect.top, (float) dRect.right, (float) dRect.bottom); } void setQuadBounds(const SkPoint a[3]) { const Quadratic quad = {{a[0].fX, a[0].fY}, {a[1].fX, a[1].fY}, {a[2].fX, a[2].fY}}; _Rect dRect; dRect.setBounds(quad); set((float) dRect.left, (float) dRect.top, (float) dRect.right, (float) dRect.bottom); } }; struct Span { Segment* fOther; mutable SkPoint const* fPt; // lazily computed as needed double fT; double fOtherT; // value at fOther[fOtherIndex].fT int fOtherIndex; // can't be used during intersection int fWindSum; // accumulated from contours surrounding this one int fWindValue; // 0 == canceled; 1 == normal; >1 == coincident bool fDone; // if set, this span to next higher T has been processed }; class Segment { public: Segment() { #if DEBUG_DUMP fID = ++gSegmentID; #endif } bool activeAngle(int index, int& done, SkTDArray& angles) const { if (activeAngleInner(index, done, angles)) { return true; } double referenceT = fTs[index].fT; int lesser = index; while (--lesser >= 0 && referenceT - fTs[lesser].fT < FLT_EPSILON) { if (activeAngleOther(lesser, done, angles)) { return true; } } do { if (activeAngleOther(index, done, angles)) { return true; } } while (++index < fTs.count() && fTs[index].fT - referenceT < FLT_EPSILON); return false; } bool activeAngleOther(int index, int& done, SkTDArray& angles) const { Span* span = &fTs[index]; Segment* other = span->fOther; int oIndex = span->fOtherIndex; return other->activeAngleInner(oIndex, done, angles); } bool activeAngleInner(int index, int& done, SkTDArray& angles) const { int next = nextSpan(index, 1); if (next > 0) { const Span& upSpan = fTs[index]; if (upSpan.fWindValue) { addAngle(angles, index, next); if (upSpan.fDone) { done++; } else if (upSpan.fWindSum != SK_MinS32) { return true; } } } int prev = nextSpan(index, -1); // edge leading into junction if (prev >= 0) { const Span& downSpan = fTs[prev]; if (downSpan.fWindValue) { addAngle(angles, index, prev); if (downSpan.fDone) { done++; } else if (downSpan.fWindSum != SK_MinS32) { return true; } } } return false; } SkScalar activeTop() const { SkASSERT(!done()); int count = fTs.count(); SkScalar result = SK_ScalarMax; bool lastDone = true; for (int index = 0; index < count; ++index) { bool done = fTs[index].fDone; if (!done || !lastDone) { SkScalar y = yAtT(index); if (result > y) { result = y; } } lastDone = done; } SkASSERT(result < SK_ScalarMax); return result; } void addAngle(SkTDArray& angles, int start, int end) const { SkASSERT(start != end); SkPoint edge[4]; (*SegmentSubDivide[fVerb])(fPts, fTs[start].fT, fTs[end].fT, edge); Angle* angle = angles.append(); angle->set(edge, fVerb, this, start, end); } void addCubic(const SkPoint pts[4]) { init(pts, SkPath::kCubic_Verb); fBounds.setCubicBounds(pts); } // FIXME: this needs to defer add for aligned consecutive line segments SkPoint addCurveTo(int start, int end, SkPath& path, bool active) { SkPoint edge[4]; // OPTIMIZE? if not active, skip remainder and return xy_at_t(end) (*SegmentSubDivide[fVerb])(fPts, fTs[start].fT, fTs[end].fT, edge); if (active) { #if DEBUG_PATH_CONSTRUCTION SkDebugf("%s %s (%1.9g,%1.9g)", __FUNCTION__, kLVerbStr[fVerb], edge[1].fX, edge[1].fY); if (fVerb > 1) { SkDebugf(" (%1.9g,%1.9g)", edge[2].fX, edge[2].fY); } if (fVerb > 2) { SkDebugf(" (%1.9g,%1.9g)", edge[3].fX, edge[3].fY); } SkDebugf("\n"); #endif switch (fVerb) { case SkPath::kLine_Verb: path.lineTo(edge[1].fX, edge[1].fY); break; case SkPath::kQuad_Verb: path.quadTo(edge[1].fX, edge[1].fY, edge[2].fX, edge[2].fY); break; case SkPath::kCubic_Verb: path.cubicTo(edge[1].fX, edge[1].fY, edge[2].fX, edge[2].fY, edge[3].fX, edge[3].fY); break; } } return edge[fVerb]; } void addLine(const SkPoint pts[2]) { init(pts, SkPath::kLine_Verb); fBounds.set(pts, 2); } const SkPoint& addMoveTo(int tIndex, SkPath& path, bool active) { const SkPoint& pt = xyAtT(tIndex); if (active) { #if DEBUG_PATH_CONSTRUCTION SkDebugf("%s (%1.9g,%1.9g)\n", __FUNCTION__, pt.fX, pt.fY); #endif path.moveTo(pt.fX, pt.fY); } return pt; } // add 2 to edge or out of range values to get T extremes void addOtherT(int index, double otherT, int otherIndex) { Span& span = fTs[index]; span.fOtherT = otherT; span.fOtherIndex = otherIndex; } void addQuad(const SkPoint pts[3]) { init(pts, SkPath::kQuad_Verb); fBounds.setQuadBounds(pts); } // Defer all coincident edge processing until // after normal intersections have been computed // no need to be tricky; insert in normal T order // resolve overlapping ts when considering coincidence later // add non-coincident intersection. Resulting edges are sorted in T. int addT(double newT, Segment* other) { // FIXME: in the pathological case where there is a ton of intercepts, // binary search? int insertedAt = -1; size_t tCount = fTs.count(); for (size_t index = 0; index < tCount; ++index) { // OPTIMIZATION: if there are three or more identical Ts, then // the fourth and following could be further insertion-sorted so // that all the edges are clockwise or counterclockwise. // This could later limit segment tests to the two adjacent // neighbors, although it doesn't help with determining which // circular direction to go in. if (newT < fTs[index].fT) { insertedAt = index; break; } } Span* span; if (insertedAt >= 0) { span = fTs.insert(insertedAt); } else { insertedAt = tCount; span = fTs.append(); } span->fT = newT; span->fOther = other; span->fPt = NULL; span->fWindSum = SK_MinS32; span->fWindValue = 1; if ((span->fDone = newT == 1)) { ++fDoneSpans; } return insertedAt; } // set spans from start to end to decrement by one // note this walks other backwards // FIMXE: there's probably an edge case that can be constructed where // two span in one segment are separated by float epsilon on one span but // not the other, if one segment is very small. For this // case the counts asserted below may or may not be enough to separate the // spans. Even if the counts work out, what if the spanw aren't correctly // sorted? It feels better in such a case to match the span's other span // pointer since both coincident segments must contain the same spans. void addTCancel(double startT, double endT, Segment& other, double oStartT, double oEndT) { SkASSERT(endT - startT >= FLT_EPSILON); SkASSERT(oEndT - oStartT >= FLT_EPSILON); int index = 0; while (startT - fTs[index].fT >= FLT_EPSILON) { ++index; } int oIndex = other.fTs.count(); while (other.fTs[--oIndex].fT - oEndT > -FLT_EPSILON) ; Span* test = &fTs[index]; Span* oTest = &other.fTs[oIndex]; do { bool decrement = test->fWindValue && oTest->fWindValue; Span* end = test; do { if (decrement) { SkASSERT(end->fWindValue > 0); if (--(end->fWindValue) == 0) { end->fDone = true; ++fDoneSpans; } } end = &fTs[++index]; } while (end->fT - test->fT < FLT_EPSILON); Span* oTestStart = oTest; do { if (decrement) { SkASSERT(oTestStart->fWindValue > 0); if (--(oTestStart->fWindValue) == 0) { oTestStart->fDone = true; ++other.fDoneSpans; } } if (!oIndex) { break; } oTestStart = &other.fTs[--oIndex]; } while (oTest->fT - oTestStart->fT < FLT_EPSILON); test = end; oTest = oTestStart; } while (test->fT < endT - FLT_EPSILON); SkASSERT(!oIndex || oTest->fT <= oStartT - FLT_EPSILON); } // set spans from start to end to increment the greater by one and decrement // the lesser void addTCoincident(double startT, double endT, Segment& other, double oStartT, double oEndT) { SkASSERT(endT - startT >= FLT_EPSILON); SkASSERT(oEndT - oStartT >= FLT_EPSILON); int index = 0; while (startT - fTs[index].fT >= FLT_EPSILON) { ++index; } int oIndex = 0; while (oStartT - other.fTs[oIndex].fT >= FLT_EPSILON) { ++oIndex; } Span* test = &fTs[index]; Span* oTest = &other.fTs[oIndex]; SkTDArray outsideTs; SkTDArray oOutsideTs; do { bool transfer = test->fWindValue && oTest->fWindValue; bool decrementOther = test->fWindValue >= oTest->fWindValue; Span* end = test; double startT = end->fT; double oStartT = oTest->fT; do { if (transfer) { if (decrementOther) { ++(end->fWindValue); } else { SkASSERT(end->fWindValue > 0); if (--(end->fWindValue) == 0) { end->fDone = true; ++fDoneSpans; int outCount = outsideTs.count(); if (outCount == 0 || end->fT - outsideTs[outCount - 2] >= FLT_EPSILON) { *outsideTs.append() = end->fT; *outsideTs.append() = oStartT; } } } } end = &fTs[++index]; } while (end->fT - test->fT < FLT_EPSILON); Span* oEnd = oTest; do { if (transfer) { if (decrementOther) { SkASSERT(oEnd->fWindValue > 0); if (--(oEnd->fWindValue) == 0) { oEnd->fDone = true; ++other.fDoneSpans; int oOutCount = oOutsideTs.count(); if (oOutCount == 0 || oEnd->fT - oOutsideTs[oOutCount - 2] >= FLT_EPSILON) { *oOutsideTs.append() = oEnd->fT; *oOutsideTs.append() = startT; } } } else { ++(oEnd->fWindValue); } } oEnd = &other.fTs[++oIndex]; } while (oEnd->fT - oTest->fT < FLT_EPSILON); test = end; oTest = oEnd; } while (test->fT < endT - FLT_EPSILON); SkASSERT(oTest->fT < oEndT + FLT_EPSILON); SkASSERT(oTest->fT > oEndT - FLT_EPSILON); if (!done() && outsideTs.count()) { addTOutsides(outsideTs, other, oEndT); } if (!other.done() && oOutsideTs.count()) { other.addTOutsides(oOutsideTs, *this, endT); } } void addTOutsides(const SkTDArray& outsideTs, Segment& other, double otherEnd) { int count = outsideTs.count(); double endT = 0; int endSpan = 0; for (int index = 0; index < count; index += 2) { double t = outsideTs[index]; double otherT = outsideTs[index + 1]; if (t > 1 - FLT_EPSILON) { return; } if (t - endT > FLT_EPSILON) { endSpan = addTDonePair(t, other, otherT); } do { endT = fTs[++endSpan].fT; } while (endT - t < FLT_EPSILON); } addTPair(endT, other, otherEnd); } // match the other.fWindValue to its mates int addTDonePair(double t, Segment& other, double otherT) { int insertedAt = addTPair(t, other, otherT); Span& end = fTs[insertedAt]; SkASSERT(end.fWindValue == 1); end.fWindValue = 0; end.fDone = true; ++fDoneSpans; Span& otherEnd = other.fTs[end.fOtherIndex]; Span* match = NULL; if (end.fOtherIndex > 0) { match = &other.fTs[end.fOtherIndex - 1]; } if (!match || match->fT < otherT) { match = &other.fTs[end.fOtherIndex + 1]; } otherEnd.fWindValue = match->fWindValue; return insertedAt; } int addTPair(double t, Segment& other, double otherT) { int insertedAt = addT(t, &other); int otherInsertedAt = other.addT(otherT, this); addOtherT(insertedAt, otherT, otherInsertedAt); other.addOtherT(otherInsertedAt, t, insertedAt); return insertedAt; } void addTwoAngles(int start, int end, SkTDArray& angles) const { // add edge leading into junction if (fTs[SkMin32(end, start)].fWindValue > 0) { addAngle(angles, end, start); } // add edge leading away from junction int step = SkSign32(end - start); int tIndex = nextSpan(end, step); if (tIndex >= 0 && fTs[SkMin32(end, tIndex)].fWindValue > 0) { addAngle(angles, end, tIndex); } } const Bounds& bounds() const { return fBounds; } void buildAngles(int index, SkTDArray& angles) const { double referenceT = fTs[index].fT; int lesser = index; while (--lesser >= 0 && referenceT - fTs[lesser].fT < FLT_EPSILON) { buildAnglesInner(lesser, angles); } do { buildAnglesInner(index, angles); } while (++index < fTs.count() && fTs[index].fT - referenceT < FLT_EPSILON); } void buildAnglesInner(int index, SkTDArray& angles) const { Span* span = &fTs[index]; Segment* other = span->fOther; // if there is only one live crossing, and no coincidence, continue // in the same direction // if there is coincidence, the only choice may be to reverse direction // find edge on either side of intersection int oIndex = span->fOtherIndex; // if done == -1, prior span has already been processed int step = 1; int next = other->nextSpan(oIndex, step); if (next < 0) { step = -step; next = other->nextSpan(oIndex, step); } // add candidate into and away from junction other->addTwoAngles(next, oIndex, angles); } bool cancels(const Segment& other) const { SkASSERT(fVerb == SkPath::kLine_Verb); SkASSERT(other.fVerb == SkPath::kLine_Verb); SkPoint dxy = fPts[0] - fPts[1]; SkPoint odxy = other.fPts[0] - other.fPts[1]; return dxy.fX * odxy.fX < 0 || dxy.fY * odxy.fY < 0; } // figure out if the segment's ascending T goes clockwise or not // not enough context to write this as shown // instead, add all segments meeting at the top // sort them using buildAngleList // find the first in the sort // see if ascendingT goes to top bool clockwise(int /* tIndex */) const { SkASSERT(0); // incomplete return false; } int crossedSpan(const SkPoint& basePt, SkScalar& bestY, double& hitT) const { int bestT = -1; SkScalar top = bounds().fTop; SkScalar bottom = bounds().fBottom; int end = 0; do { int start = end; end = nextSpan(start, 1); SkPoint edge[4]; // OPTIMIZE: wrap this so that if start==0 end==fTCount-1 we can // work with the original data directly (*SegmentSubDivide[fVerb])(fPts, fTs[start].fT, fTs[end].fT, edge); // intersect ray starting at basePt with edge Intersections intersections; int pts = (*VSegmentIntersect[fVerb])(edge, top, bottom, basePt.fX, false, intersections); if (pts == 0) { continue; } if (pts > 1 && fVerb == SkPath::kLine_Verb) { // if the intersection is edge on, wait for another one continue; } SkASSERT(pts == 1); // FIXME: more code required to disambiguate SkPoint pt; double foundT = intersections.fT[0][0]; (*SegmentXYAtT[fVerb])(fPts, foundT, &pt); if (bestY < pt.fY) { bestY = pt.fY; bestT = foundT < 1 ? start : end; hitT = foundT; } } while (fTs[end].fT != 1); return bestT; } bool done() const { SkASSERT(fDoneSpans <= fTs.count()); return fDoneSpans == fTs.count(); } // so the span needs to contain the pairing info found here // this should include the winding computed for the edge, and // what edge it connects to, and whether it is discarded // (maybe discarded == abs(winding) > 1) ? // only need derivatives for duration of sorting, add a new struct // for pairings, remove extra spans that have zero length and // reference an unused other // for coincident, the last span on the other may be marked done // (always?) // if loop is exhausted, contour may be closed. // FIXME: pass in close point so we can check for closure // given a segment, and a sense of where 'inside' is, return the next // segment. If this segment has an intersection, or ends in multiple // segments, find the mate that continues the outside. // note that if there are multiples, but no coincidence, we can limit // choices to connections in the correct direction // mark found segments as done // start is the index of the beginning T of this edge // it is guaranteed to have an end which describes a non-zero length (?) // winding -1 means ccw, 1 means cw // firstFind allows coincident edges to be treated differently Segment* findNext(SkTDArray& chase, int winding, const int startIndex, const int endIndex, int& nextStart, int& nextEnd, int& flipped, bool firstFind, bool active) { SkASSERT(startIndex != endIndex); int count = fTs.count(); SkASSERT(startIndex < endIndex ? startIndex < count - 1 : startIndex > 0); int step = SkSign32(endIndex - startIndex); int end = nextSpan(startIndex, step); SkASSERT(end >= 0); Span* endSpan = &fTs[end]; Segment* other; if (isSimple(end)) { // mark the smaller of startIndex, endIndex done, and all adjacent // spans with the same T value (but not 'other' spans) markDone(SkMin32(startIndex, endIndex), winding); other = endSpan->fOther; nextStart = endSpan->fOtherIndex; nextEnd = nextStart + step; SkASSERT(step < 0 ? nextEnd >= 0 : nextEnd < other->fTs.count()); return other; } // more than one viable candidate -- measure angles to find best SkTDArray angles; SkASSERT(startIndex - endIndex != 0); SkASSERT((startIndex - endIndex < 0) ^ (step < 0)); addTwoAngles(startIndex, end, angles); buildAngles(end, angles); SkTDArray sorted; sortAngles(angles, sorted); int angleCount = angles.count(); int firstIndex = findStartingEdge(sorted, startIndex, end); SkASSERT(firstIndex >= 0); #if DEBUG_WINDING SkDebugf("%s (first) winding=%d sign=%d\n", __FUNCTION__, winding, sorted[firstIndex]->sign()); #endif bool innerSwap = false; int startWinding = winding; if (winding * sorted[firstIndex]->sign() > 0 && active) { // FIXME: this means winding was computed wrong by caller ? winding = 0; innerSwap = true; } int nextIndex = firstIndex + 1; int lastIndex = firstIndex != 0 ? firstIndex : angleCount; const Angle* foundAngle = NULL; // iterate through the angle, and compute everyone's winding bool firstEdge = true; do { if (nextIndex == angleCount) { nextIndex = 0; } const Angle* nextAngle = sorted[nextIndex]; int maxWinding = winding; Segment* nextSegment = nextAngle->segment(); int windValue = nextSegment->windValue(nextAngle); SkASSERT(windValue > 0); winding -= nextAngle->sign() * windValue; #if DEBUG_WINDING SkDebugf("%s maxWinding=%d winding=%d sign=%d\n", __FUNCTION__, maxWinding, winding, nextAngle->sign()); #endif if (maxWinding * winding < 0) { flipped = -flipped; SkDebugf("flipped sign %d %d\n", maxWinding, winding); } firstEdge = false; if (!winding) { if (!active) { SkASSERT(nextAngle->segment() == this); markWinding(SkMin32(nextAngle->start(), nextAngle->end()), maxWinding); #if DEBUG_WINDING SkDebugf("%s inactive\n", __FUNCTION__); #endif return NULL; } if (!foundAngle) { foundAngle = nextAngle; } continue; } if (!maxWinding && innerSwap && !foundAngle) { foundAngle = nextAngle; } if (nextSegment->done()) { continue; } // if the winding is non-zero, nextAngle does not connect to // current chain. If we haven't done so already, mark the angle // as done, record the winding value, and mark connected unambiguous // segments as well. if (nextSegment->windSum(nextAngle) == SK_MinS32) { if (abs(maxWinding) < abs(winding)) { maxWinding = winding; } Span* last; if (foundAngle || innerSwap) { last = nextSegment->markAndChaseWinding(nextAngle, maxWinding); } else { last = nextSegment->markAndChaseDone(nextAngle, maxWinding); } if (last) { *chase.append() = last; } } } while (++nextIndex != lastIndex); sorted[firstIndex]->segment()-> markDone(SkMin32(startIndex, endIndex), startWinding); if (!foundAngle) { return NULL; } nextStart = foundAngle->start(); nextEnd = foundAngle->end(); return foundAngle->segment(); } int findStartingEdge(SkTDArray& sorted, int start, int end) { int angleCount = sorted.count(); int firstIndex = -1; for (int angleIndex = 0; angleIndex < angleCount; ++angleIndex) { const Angle* angle = sorted[angleIndex]; if (angle->segment() == this && angle->start() == end && angle->end() == start) { firstIndex = angleIndex; break; } } return firstIndex; } // FIXME: this is tricky code; needs its own unit test void findTooCloseToCall(int /* winding */ ) { // FIXME: winding should be considered int count = fTs.count(); if (count < 3) { // require t=0, x, 1 at minimum return; } int matchIndex = 0; int moCount; Span* match; Segment* mOther; do { match = &fTs[matchIndex]; mOther = match->fOther; moCount = mOther->fTs.count(); if (moCount >= 3) { break; } if (++matchIndex >= count) { return; } } while (true); // require t=0, x, 1 at minimum // OPTIMIZATION: defer matchPt until qualifying toCount is found? const SkPoint* matchPt = &xyAtT(match); // look for a pair of nearby T values that map to the same (x,y) value // if found, see if the pair of other segments share a common point. If // so, the span from here to there is coincident. for (int index = matchIndex + 1; index < count; ++index) { Span* test = &fTs[index]; if (test->fDone) { continue; } Segment* tOther = test->fOther; int toCount = tOther->fTs.count(); if (toCount < 3) { // require t=0, x, 1 at minimum continue; } const SkPoint* testPt = &xyAtT(test); if (*matchPt != *testPt) { matchIndex = index; moCount = toCount; match = test; mOther = tOther; matchPt = testPt; continue; } int moStart = -1; int moEnd = -1; double moStartT, moEndT; for (int moIndex = 0; moIndex < moCount; ++moIndex) { Span& moSpan = mOther->fTs[moIndex]; if (moSpan.fDone) { continue; } if (moSpan.fOther == this) { if (moSpan.fOtherT == match->fT) { moStart = moIndex; moStartT = moSpan.fT; } continue; } if (moSpan.fOther == tOther) { SkASSERT(moEnd == -1); moEnd = moIndex; moEndT = moSpan.fT; } } if (moStart < 0 || moEnd < 0) { continue; } // FIXME: if moStartT, moEndT are initialized to NaN, can skip this test if (moStartT == moEndT) { continue; } int toStart = -1; int toEnd = -1; double toStartT, toEndT; for (int toIndex = 0; toIndex < toCount; ++toIndex) { Span& toSpan = tOther->fTs[toIndex]; if (toSpan.fOther == this) { if (toSpan.fOtherT == test->fT) { toStart = toIndex; toStartT = toSpan.fT; } continue; } if (toSpan.fOther == mOther && toSpan.fOtherT == moEndT) { SkASSERT(toEnd == -1); toEnd = toIndex; toEndT = toSpan.fT; } } // FIXME: if toStartT, toEndT are initialized to NaN, can skip this test if (toStart <= 0 || toEnd <= 0) { continue; } if (toStartT == toEndT) { continue; } // test to see if the segment between there and here is linear if (!mOther->isLinear(moStart, moEnd) || !tOther->isLinear(toStart, toEnd)) { continue; } // FIXME: defer implementation until the rest works // this may share code with regular coincident detection SkASSERT(0); #if 0 if (flipped) { mOther->addTCancel(moStart, moEnd, tOther, tStart, tEnd); } else { mOther->addTCoincident(moStart, moEnd, tOther, tStart, tEnd); } #endif } } // OPTIMIZATION : for a pair of lines, can we compute points at T (cached) // and use more concise logic like the old edge walker code? // FIXME: this needs to deal with coincident edges Segment* findTop(int& tIndex, int& endIndex) { // iterate through T intersections and return topmost // topmost tangent from y-min to first pt is closer to horizontal SkASSERT(!done()); int firstT; int lastT; SkPoint topPt; topPt.fY = SK_ScalarMax; int count = fTs.count(); // see if either end is not done since we want smaller Y of the pair bool lastDone = true; for (int index = 0; index < count; ++index) { const Span& span = fTs[index]; if (!span.fDone || !lastDone) { const SkPoint& intercept = xyAtT(&span); if (topPt.fY > intercept.fY || (topPt.fY == intercept.fY && topPt.fX > intercept.fX)) { topPt = intercept; firstT = lastT = index; } else if (topPt == intercept) { lastT = index; } } lastDone = span.fDone; } // sort the edges to find the leftmost int step = 1; int end = nextSpan(firstT, step); if (end == -1) { step = -1; end = nextSpan(firstT, step); SkASSERT(end != -1); } // if the topmost T is not on end, or is three-way or more, find left // look for left-ness from tLeft to firstT (matching y of other) SkTDArray angles; SkASSERT(firstT - end != 0); addTwoAngles(end, firstT, angles); buildAngles(firstT, angles); SkTDArray sorted; sortAngles(angles, sorted); // skip edges that have already been processed firstT = -1; Segment* leftSegment; do { const Angle* angle = sorted[++firstT]; leftSegment = angle->segment(); tIndex = angle->end(); endIndex = angle->start(); } while (leftSegment->fTs[SkMin32(tIndex, endIndex)].fDone); return leftSegment; } // FIXME: not crazy about this // when the intersections are performed, the other index is into an // incomplete array. as the array grows, the indices become incorrect // while the following fixes the indices up again, it isn't smart about // skipping segments whose indices are already correct // assuming we leave the code that wrote the index in the first place void fixOtherTIndex() { int iCount = fTs.count(); for (int i = 0; i < iCount; ++i) { Span& iSpan = fTs[i]; double oT = iSpan.fOtherT; Segment* other = iSpan.fOther; int oCount = other->fTs.count(); for (int o = 0; o < oCount; ++o) { Span& oSpan = other->fTs[o]; if (oT == oSpan.fT && this == oSpan.fOther) { iSpan.fOtherIndex = o; break; } } } } // OPTIMIZATION: uses tail recursion. Unwise? Span* innerChaseDone(int index, int step, int winding) { int end = nextSpan(index, step); SkASSERT(end >= 0); if (multipleSpans(end)) { return &fTs[end]; } const Span& endSpan = fTs[end]; Segment* other = endSpan.fOther; index = endSpan.fOtherIndex; int otherEnd = other->nextSpan(index, step); Span* last = other->innerChaseDone(index, step, winding); other->markDone(SkMin32(index, otherEnd), winding); return last; } Span* innerChaseWinding(int index, int step, int winding) { int end = nextSpan(index, step); SkASSERT(end >= 0); if (multipleSpans(end)) { return &fTs[end]; } const Span& endSpan = fTs[end]; Segment* other = endSpan.fOther; index = endSpan.fOtherIndex; int otherEnd = other->nextSpan(index, step); int min = SkMin32(index, otherEnd); if (other->fTs[min].fWindSum != SK_MinS32) { SkASSERT(other->fTs[min].fWindSum == winding); return NULL; } Span* last = other->innerChaseWinding(index, step, winding); other->markWinding(min, winding); return last; } void init(const SkPoint pts[], SkPath::Verb verb) { fPts = pts; fVerb = verb; fDoneSpans = 0; } bool intersected() const { return fTs.count() > 0; } bool isLinear(int start, int end) const { if (fVerb == SkPath::kLine_Verb) { return true; } if (fVerb == SkPath::kQuad_Verb) { SkPoint qPart[3]; QuadSubDivide(fPts, fTs[start].fT, fTs[end].fT, qPart); return QuadIsLinear(qPart); } else { SkASSERT(fVerb == SkPath::kCubic_Verb); SkPoint cPart[4]; CubicSubDivide(fPts, fTs[start].fT, fTs[end].fT, cPart); return CubicIsLinear(cPart); } } // OPTIMIZE: successive calls could start were the last leaves off // or calls could specialize to walk forwards or backwards bool isMissing(double startT) const { size_t tCount = fTs.count(); for (size_t index = 0; index < tCount; ++index) { if (fabs(startT - fTs[index].fT) < FLT_EPSILON) { return false; } } return true; } bool isSimple(int end) const { int count = fTs.count(); if (count == 2) { return true; } double t = fTs[end].fT; if (t < FLT_EPSILON) { return fTs[1].fT >= FLT_EPSILON; } if (t > 1 - FLT_EPSILON) { return fTs[count - 2].fT <= 1 - FLT_EPSILON; } return false; } bool isHorizontal() const { return fBounds.fTop == fBounds.fBottom; } bool isVertical() const { return fBounds.fLeft == fBounds.fRight; } SkScalar leftMost(int start, int end) const { return (*SegmentLeftMost[fVerb])(fPts, fTs[start].fT, fTs[end].fT); } // this span is excluded by the winding rule -- chase the ends // as long as they are unambiguous to mark connections as done // and give them the same winding value Span* markAndChaseDone(const Angle* angle, int winding) { int index = angle->start(); int endIndex = angle->end(); int step = SkSign32(endIndex - index); Span* last = innerChaseDone(index, step, winding); markDone(SkMin32(index, endIndex), winding); return last; } Span* markAndChaseWinding(const Angle* angle, int winding) { int index = angle->start(); int endIndex = angle->end(); int min = SkMin32(index, endIndex); int step = SkSign32(endIndex - index); Span* last = innerChaseWinding(index, step, winding); markWinding(min, winding); return last; } // FIXME: this should also mark spans with equal (x,y) // This may be called when the segment is already marked done. While this // wastes time, it shouldn't do any more than spin through the T spans. // OPTIMIZATION: abort on first done found (assuming that this code is // always called to mark segments done). void markDone(int index, int winding) { // SkASSERT(!done()); double referenceT = fTs[index].fT; int lesser = index; while (--lesser >= 0 && referenceT - fTs[lesser].fT < FLT_EPSILON) { Span& span = fTs[lesser]; if (span.fDone) { continue; } #if DEBUG_MARK_DONE const SkPoint& pt = xyAtT(&span); SkDebugf("%s segment=%d index=%d t=%1.9g pt=(%1.9g,%1.9g) wind=%d\n", __FUNCTION__, fID, lesser, span.fT, pt.fX, pt.fY, winding); #endif span.fDone = true; SkASSERT(span.fWindSum == SK_MinS32 || span.fWindSum == winding); span.fWindSum = winding; fDoneSpans++; } do { Span& span = fTs[index]; // SkASSERT(!span.fDone); if (span.fDone) { continue; } #if DEBUG_MARK_DONE const SkPoint& pt = xyAtT(&span); SkDebugf("%s segment=%d index=%d t=%1.9g pt=(%1.9g,%1.9g) wind=%d\n", __FUNCTION__, fID, index, span.fT, pt.fX, pt.fY, winding); #endif span.fDone = true; SkASSERT(span.fWindSum == SK_MinS32 || span.fWindSum == winding); span.fWindSum = winding; fDoneSpans++; } while (++index < fTs.count() && fTs[index].fT - referenceT < FLT_EPSILON); } void markWinding(int index, int winding) { SkASSERT(!done()); double referenceT = fTs[index].fT; int lesser = index; while (--lesser >= 0 && referenceT - fTs[lesser].fT < FLT_EPSILON) { Span& span = fTs[lesser]; if (span.fDone) { continue; } SkASSERT(span.fWindValue == 1 || winding == 0); SkASSERT(span.fWindSum == SK_MinS32 || span.fWindSum == winding); #if DEBUG_MARK_DONE const SkPoint& pt = xyAtT(&span); SkDebugf("%s segment=%d index=%d t=%1.9g pt=(%1.9g,%1.9g) wind=%d\n", __FUNCTION__, fID, lesser, span.fT, pt.fX, pt.fY, winding); #endif span.fWindSum = winding; } do { Span& span = fTs[index]; // SkASSERT(!span.fDone || span.fCoincident); if (span.fDone) { continue; } SkASSERT(span.fWindValue == 1 || winding == 0); SkASSERT(span.fWindSum == SK_MinS32 || span.fWindSum == winding); #if DEBUG_MARK_DONE const SkPoint& pt = xyAtT(&span); SkDebugf("%s segment=%d index=%d t=%1.9g pt=(%1.9g,%1.9g) wind=%d\n", __FUNCTION__, fID, index, span.fT, pt.fX, pt.fY, winding); #endif span.fWindSum = winding; } while (++index < fTs.count() && fTs[index].fT - referenceT < FLT_EPSILON); } // return span if when chasing, two or more radiating spans are not done // OPTIMIZATION: ? multiple spans is detected when there is only one valid // candidate and the remaining spans have windValue == 0 (canceled by // coincidence). The coincident edges could either be removed altogether, // or this code could be more complicated in detecting this case. Worth it? bool multipleSpans(int end) const { return end > 0 && end < fTs.count() - 1; } // This has callers for two different situations: one establishes the end // of the current span, and one establishes the beginning of the next span // (thus the name). When this is looking for the end of the current span, // coincidence is found when the beginning Ts contain -step and the end // contains step. When it is looking for the beginning of the next, the // first Ts found can be ignored and the last Ts should contain -step. // OPTIMIZATION: probably should split into two functions int nextSpan(int from, int step) const { const Span& fromSpan = fTs[from]; int count = fTs.count(); int to = from; while (step > 0 ? ++to < count : --to >= 0) { const Span& span = fTs[to]; if ((step > 0 ? span.fT - fromSpan.fT : fromSpan.fT - span.fT) < FLT_EPSILON) { continue; } return to; } return -1; } const SkPoint* pts() const { return fPts; } void reset() { init(NULL, (SkPath::Verb) -1); fBounds.set(SK_ScalarMax, SK_ScalarMax, SK_ScalarMax, SK_ScalarMax); fTs.reset(); } // OPTIMIZATION: mark as debugging only if used solely by tests const Span& span(int tIndex) const { return fTs[tIndex]; } int spanSign(int startIndex, int endIndex) const { return startIndex < endIndex ? -fTs[startIndex].fWindValue : fTs[endIndex].fWindValue; } // OPTIMIZATION: mark as debugging only if used solely by tests double t(int tIndex) const { return fTs[tIndex].fT; } void updatePts(const SkPoint pts[]) { fPts = pts; } SkPath::Verb verb() const { return fVerb; } int windSum(int tIndex) const { return fTs[tIndex].fWindSum; } int windSum(const Angle* angle) const { int start = angle->start(); int end = angle->end(); int index = SkMin32(start, end); return windSum(index); } int windValue(int tIndex) const { return fTs[tIndex].fWindValue; } int windValue(const Angle* angle) const { int start = angle->start(); int end = angle->end(); int index = SkMin32(start, end); return windValue(index); } SkScalar xAtT(const Span* span) const { return xyAtT(span).fX; } const SkPoint& xyAtT(int index) const { return xyAtT(&fTs[index]); } const SkPoint& xyAtT(const Span* span) const { if (!span->fPt) { if (span->fT == 0) { span->fPt = &fPts[0]; } else if (span->fT == 1) { span->fPt = &fPts[fVerb]; } else { SkPoint* pt = fIntersections.append(); (*SegmentXYAtT[fVerb])(fPts, span->fT, pt); span->fPt = pt; } } return *span->fPt; } SkScalar yAtT(int index) const { return yAtT(&fTs[index]); } SkScalar yAtT(const Span* span) const { return xyAtT(span).fY; } #if DEBUG_DUMP void dump() const { const char className[] = "Segment"; const int tab = 4; for (int i = 0; i < fTs.count(); ++i) { SkPoint out; (*SegmentXYAtT[fVerb])(fPts, t(i), &out); SkDebugf("%*s [%d] %s.fTs[%d]=%1.9g (%1.9g,%1.9g) other=%d" " otherT=%1.9g windSum=%d\n", tab + sizeof(className), className, fID, kLVerbStr[fVerb], i, fTs[i].fT, out.fX, out.fY, fTs[i].fOther->fID, fTs[i].fOtherT, fTs[i].fWindSum); } SkDebugf("%*s [%d] fBounds=(l:%1.9g, t:%1.9g r:%1.9g, b:%1.9g)", tab + sizeof(className), className, fID, fBounds.fLeft, fBounds.fTop, fBounds.fRight, fBounds.fBottom); } #endif #if DEBUG_ACTIVE_SPANS void debugShowActiveSpans(int contourID, int segmentIndex) { if (done()) { return; } for (int i = 0; i < fTs.count(); ++i) { if (fTs[i].fDone) { continue; } SkDebugf("%s contour=%d segment=%d (%d)", __FUNCTION__, contourID, segmentIndex, fID); SkDebugf(" (%1.9g,%1.9g", fPts[0].fX, fPts[0].fY); for (int vIndex = 1; vIndex <= fVerb; ++vIndex) { SkDebugf(" %1.9g,%1.9g", fPts[vIndex].fX, fPts[vIndex].fY); } const Span* span = &fTs[i]; SkDebugf(") fT=%d (%1.9g) (%1.9g,%1.9g)", i, fTs[i].fT, xAtT(span), yAtT(i)); const Segment* other = fTs[i].fOther; SkDebugf(" other=%d otherT=%1.9g otherIndex=%d", other->fID, fTs[i].fOtherT, fTs[i].fOtherIndex); SkDebugf(" windSum=%d windValue=%d\n", fTs[i].fWindSum, fTs[i].fWindValue); } } #endif private: const SkPoint* fPts; SkPath::Verb fVerb; Bounds fBounds; SkTDArray fTs; // two or more (always includes t=0 t=1) // OPTIMIZATION:if intersections array is a pointer, the it could only // be allocated as needed instead of always initialized -- though maybe // the initialization is lightweight enough that it hardly matters mutable SkTDArray fIntersections; int fDoneSpans; // used for quick check that segment is finished #if DEBUG_DUMP int fID; #endif }; class Contour; struct Coincidence { Contour* fContours[2]; int fSegments[2]; double fTs[2][2]; }; class Contour { public: Contour() { reset(); #if DEBUG_DUMP fID = ++gContourID; #endif } bool operator<(const Contour& rh) const { return fBounds.fTop == rh.fBounds.fTop ? fBounds.fLeft < rh.fBounds.fLeft : fBounds.fTop < rh.fBounds.fTop; } void addCoincident(int index, Contour* other, int otherIndex, const Intersections& ts, bool swap) { Coincidence& coincidence = *fCoincidences.append(); coincidence.fContours[0] = this; coincidence.fContours[1] = other; coincidence.fSegments[0] = index; coincidence.fSegments[1] = otherIndex; coincidence.fTs[swap][0] = ts.fT[0][0]; coincidence.fTs[swap][1] = ts.fT[0][1]; coincidence.fTs[!swap][0] = ts.fT[1][0]; coincidence.fTs[!swap][1] = ts.fT[1][1]; } void addCross(const Contour* crosser) { #ifdef DEBUG_CROSS for (int index = 0; index < fCrosses.count(); ++index) { SkASSERT(fCrosses[index] != crosser); } #endif *fCrosses.append() = crosser; } void addCubic(const SkPoint pts[4]) { fSegments.push_back().addCubic(pts); fContainsCurves = true; } int addLine(const SkPoint pts[2]) { fSegments.push_back().addLine(pts); return fSegments.count(); } void addOtherT(int segIndex, int tIndex, double otherT, int otherIndex) { fSegments[segIndex].addOtherT(tIndex, otherT, otherIndex); } int addQuad(const SkPoint pts[3]) { fSegments.push_back().addQuad(pts); fContainsCurves = true; return fSegments.count(); } int addT(int segIndex, double newT, Contour* other, int otherIndex) { containsIntercepts(); return fSegments[segIndex].addT(newT, &other->fSegments[otherIndex]); } const Bounds& bounds() const { return fBounds; } void complete() { setBounds(); fContainsIntercepts = false; } void containsIntercepts() { fContainsIntercepts = true; } const Segment* crossedSegment(const SkPoint& basePt, SkScalar& bestY, int &tIndex, double& hitT) { int segmentCount = fSegments.count(); const Segment* bestSegment = NULL; for (int test = 0; test < segmentCount; ++test) { Segment* testSegment = &fSegments[test]; const SkRect& bounds = testSegment->bounds(); if (bounds.fTop < bestY) { continue; } if (bounds.fTop > basePt.fY) { continue; } if (bounds.fLeft > basePt.fX) { continue; } if (bounds.fRight < basePt.fX) { continue; } double testHitT; int testT = testSegment->crossedSpan(basePt, bestY, testHitT); if (testT >= 0) { bestSegment = testSegment; tIndex = testT; hitT = testHitT; } } return bestSegment; } bool crosses(const Contour* crosser) const { if (this == crosser) { return true; } for (int index = 0; index < fCrosses.count(); ++index) { if (fCrosses[index] == crosser) { return true; } } return false; } void findTooCloseToCall(int winding) { int segmentCount = fSegments.count(); for (int sIndex = 0; sIndex < segmentCount; ++sIndex) { fSegments[sIndex].findTooCloseToCall(winding); } } void fixOtherTIndex() { int segmentCount = fSegments.count(); for (int sIndex = 0; sIndex < segmentCount; ++sIndex) { fSegments[sIndex].fixOtherTIndex(); } } void reset() { fSegments.reset(); fBounds.set(SK_ScalarMax, SK_ScalarMax, SK_ScalarMax, SK_ScalarMax); fContainsCurves = fContainsIntercepts = false; fWindingSum = SK_MinS32; } void resolveCoincidence(int winding) { int count = fCoincidences.count(); for (int index = 0; index < count; ++index) { Coincidence& coincidence = fCoincidences[index]; Contour* thisContour = coincidence.fContours[0]; Contour* otherContour = coincidence.fContours[1]; int thisIndex = coincidence.fSegments[0]; int otherIndex = coincidence.fSegments[1]; Segment& thisOne = thisContour->fSegments[thisIndex]; Segment& other = otherContour->fSegments[otherIndex]; double startT = coincidence.fTs[0][0]; double endT = coincidence.fTs[0][1]; if (startT > endT) { SkTSwap(startT, endT); } SkASSERT(endT - startT >= FLT_EPSILON); double oStartT = coincidence.fTs[1][0]; double oEndT = coincidence.fTs[1][1]; if (oStartT > oEndT) { SkTSwap(oStartT, oEndT); } SkASSERT(oEndT - oStartT >= FLT_EPSILON); if (winding > 0 || thisOne.cancels(other)) { // make sure startT and endT have t entries if (thisOne.isMissing(startT) || other.isMissing(oEndT)) { thisOne.addTPair(startT, other, oEndT); } if (thisOne.isMissing(endT) || other.isMissing(oStartT)) { other.addTPair(oStartT, thisOne, endT); } thisOne.addTCancel(startT, endT, other, oStartT, oEndT); } else { if (thisOne.isMissing(startT) || other.isMissing(oStartT)) { thisOne.addTPair(startT, other, oStartT); } if (thisOne.isMissing(endT) || other.isMissing(oEndT)) { other.addTPair(oEndT, thisOne, endT); } thisOne.addTCoincident(startT, endT, other, oStartT, oEndT); } } } const SkTArray& segments() { return fSegments; } void setWinding(int winding) { SkASSERT(fWindingSum < 0); fWindingSum = winding; } // OPTIMIZATION: feel pretty uneasy about this. It seems like once again // we need to sort and walk edges in y, but that on the surface opens the // same can of worms as before. But then, this is a rough sort based on // segments' top, and not a true sort, so it could be ameniable to regular // sorting instead of linear searching. Still feel like I'm missing something Segment* topSegment(SkScalar& bestY) { int segmentCount = fSegments.count(); SkASSERT(segmentCount > 0); int best = -1; Segment* bestSegment = NULL; while (++best < segmentCount) { Segment* testSegment = &fSegments[best]; if (testSegment->done()) { continue; } bestSegment = testSegment; break; } if (!bestSegment) { return NULL; } SkScalar bestTop = bestSegment->activeTop(); for (int test = best + 1; test < segmentCount; ++test) { Segment* testSegment = &fSegments[test]; if (testSegment->done()) { continue; } if (testSegment->bounds().fTop > bestTop) { continue; } SkScalar testTop = testSegment->activeTop(); if (bestTop > testTop) { bestTop = testTop; bestSegment = testSegment; } } bestY = bestTop; return bestSegment; } int updateSegment(int index, const SkPoint* pts) { Segment& segment = fSegments[index]; segment.updatePts(pts); return segment.verb() + 1; } int windSum() { if (fWindingSum >= 0) { return fWindingSum; } // check peers int count = fCrosses.count(); for (int index = 0; index < count; ++index) { const Contour* crosser = fCrosses[index]; if (0 <= crosser->fWindingSum) { fWindingSum = crosser->fWindingSum; break; } } return fWindingSum; } #if DEBUG_TEST SkTArray& debugSegments() { return fSegments; } #endif #if DEBUG_DUMP void dump() { int i; const char className[] = "Contour"; const int tab = 4; SkDebugf("%s %p (contour=%d)\n", className, this, fID); for (i = 0; i < fSegments.count(); ++i) { SkDebugf("%*s.fSegments[%d]:\n", tab + sizeof(className), className, i); fSegments[i].dump(); } SkDebugf("%*s.fBounds=(l:%1.9g, t:%1.9g r:%1.9g, b:%1.9g)\n", tab + sizeof(className), className, fBounds.fLeft, fBounds.fTop, fBounds.fRight, fBounds.fBottom); SkDebugf("%*s.fContainsIntercepts=%d\n", tab + sizeof(className), className, fContainsIntercepts); SkDebugf("%*s.fContainsCurves=%d\n", tab + sizeof(className), className, fContainsCurves); } #endif #if DEBUG_ACTIVE_SPANS void debugShowActiveSpans() { for (int index = 0; index < fSegments.count(); ++index) { fSegments[index].debugShowActiveSpans(fID, index); } } #endif protected: void setBounds() { int count = fSegments.count(); if (count == 0) { SkDebugf("%s empty contour\n", __FUNCTION__); SkASSERT(0); // FIXME: delete empty contour? return; } fBounds = fSegments.front().bounds(); for (int index = 1; index < count; ++index) { fBounds.add(fSegments[index].bounds()); } } private: SkTArray fSegments; SkTDArray fCoincidences; SkTDArray fCrosses; Bounds fBounds; bool fContainsIntercepts; bool fContainsCurves; int fWindingSum; // initial winding number outside #if DEBUG_DUMP int fID; #endif }; class EdgeBuilder { public: EdgeBuilder(const SkPath& path, SkTArray& contours) : fPath(path) , fCurrentContour(NULL) , fContours(contours) { #if DEBUG_DUMP gContourID = 0; gSegmentID = 0; #endif walk(); } protected: void complete() { if (fCurrentContour && fCurrentContour->segments().count()) { fCurrentContour->complete(); fCurrentContour = NULL; } } void walk() { // FIXME:remove once we can access path pts directly SkPath::RawIter iter(fPath); // FIXME: access path directly when allowed SkPoint pts[4]; SkPath::Verb verb; do { verb = iter.next(pts); *fPathVerbs.append() = verb; if (verb == SkPath::kMove_Verb) { *fPathPts.append() = pts[0]; } else if (verb >= SkPath::kLine_Verb && verb <= SkPath::kCubic_Verb) { fPathPts.append(verb, &pts[1]); } } while (verb != SkPath::kDone_Verb); // FIXME: end of section to remove once path pts are accessed directly SkPath::Verb reducedVerb; uint8_t* verbPtr = fPathVerbs.begin(); const SkPoint* pointsPtr = fPathPts.begin(); const SkPoint* finalCurveStart = NULL; const SkPoint* finalCurveEnd = NULL; while ((verb = (SkPath::Verb) *verbPtr++) != SkPath::kDone_Verb) { switch (verb) { case SkPath::kMove_Verb: complete(); if (!fCurrentContour) { fCurrentContour = fContours.push_back_n(1); finalCurveEnd = pointsPtr++; *fExtra.append() = -1; // start new contour } continue; case SkPath::kLine_Verb: // skip degenerate points if (pointsPtr[-1].fX != pointsPtr[0].fX || pointsPtr[-1].fY != pointsPtr[0].fY) { fCurrentContour->addLine(&pointsPtr[-1]); } break; case SkPath::kQuad_Verb: reducedVerb = QuadReduceOrder(&pointsPtr[-1], fReducePts); if (reducedVerb == 0) { break; // skip degenerate points } if (reducedVerb == 1) { *fExtra.append() = fCurrentContour->addLine(fReducePts.end() - 2); break; } fCurrentContour->addQuad(&pointsPtr[-1]); break; case SkPath::kCubic_Verb: reducedVerb = CubicReduceOrder(&pointsPtr[-1], fReducePts); if (reducedVerb == 0) { break; // skip degenerate points } if (reducedVerb == 1) { *fExtra.append() = fCurrentContour->addLine(fReducePts.end() - 2); break; } if (reducedVerb == 2) { *fExtra.append() = fCurrentContour->addQuad(fReducePts.end() - 3); break; } fCurrentContour->addCubic(&pointsPtr[-1]); break; case SkPath::kClose_Verb: SkASSERT(fCurrentContour); if (finalCurveStart && finalCurveEnd && *finalCurveStart != *finalCurveEnd) { *fReducePts.append() = *finalCurveStart; *fReducePts.append() = *finalCurveEnd; *fExtra.append() = fCurrentContour->addLine(fReducePts.end() - 2); } complete(); continue; default: SkDEBUGFAIL("bad verb"); return; } finalCurveStart = &pointsPtr[verb - 1]; pointsPtr += verb; SkASSERT(fCurrentContour); } complete(); if (fCurrentContour && !fCurrentContour->segments().count()) { fContours.pop_back(); } // correct pointers in contours since fReducePts may have moved as it grew int cIndex = 0; int extraCount = fExtra.count(); SkASSERT(extraCount == 0 || fExtra[0] == -1); int eIndex = 0; int rIndex = 0; while (++eIndex < extraCount) { int offset = fExtra[eIndex]; if (offset < 0) { ++cIndex; continue; } fCurrentContour = &fContours[cIndex]; rIndex += fCurrentContour->updateSegment(offset - 1, &fReducePts[rIndex]); } fExtra.reset(); // we're done with this } private: const SkPath& fPath; SkTDArray fPathPts; // FIXME: point directly to path pts instead SkTDArray fPathVerbs; // FIXME: remove Contour* fCurrentContour; SkTArray& fContours; SkTDArray fReducePts; // segments created on the fly SkTDArray fExtra; // -1 marks new contour, > 0 offsets into contour }; class Work { public: enum SegmentType { kHorizontalLine_Segment = -1, kVerticalLine_Segment = 0, kLine_Segment = SkPath::kLine_Verb, kQuad_Segment = SkPath::kQuad_Verb, kCubic_Segment = SkPath::kCubic_Verb, }; void addCoincident(Work& other, const Intersections& ts, bool swap) { fContour->addCoincident(fIndex, other.fContour, other.fIndex, ts, swap); } // FIXME: does it make sense to write otherIndex now if we're going to // fix it up later? void addOtherT(int index, double otherT, int otherIndex) { fContour->addOtherT(fIndex, index, otherT, otherIndex); } // Avoid collapsing t values that are close to the same since // we walk ts to describe consecutive intersections. Since a pair of ts can // be nearly equal, any problems caused by this should be taken care // of later. // On the edge or out of range values are negative; add 2 to get end int addT(double newT, const Work& other) { return fContour->addT(fIndex, newT, other.fContour, other.fIndex); } bool advance() { return ++fIndex < fLast; } SkScalar bottom() const { return bounds().fBottom; } const Bounds& bounds() const { return fContour->segments()[fIndex].bounds(); } const SkPoint* cubic() const { return fCubic; } void init(Contour* contour) { fContour = contour; fIndex = 0; fLast = contour->segments().count(); } bool isAdjacent(const Work& next) { return fContour == next.fContour && fIndex + 1 == next.fIndex; } bool isFirstLast(const Work& next) { return fContour == next.fContour && fIndex == 0 && next.fIndex == fLast - 1; } SkScalar left() const { return bounds().fLeft; } void promoteToCubic() { fCubic[0] = pts()[0]; fCubic[2] = pts()[1]; fCubic[3] = pts()[2]; fCubic[1].fX = (fCubic[0].fX + fCubic[2].fX * 2) / 3; fCubic[1].fY = (fCubic[0].fY + fCubic[2].fY * 2) / 3; fCubic[2].fX = (fCubic[3].fX + fCubic[2].fX * 2) / 3; fCubic[2].fY = (fCubic[3].fY + fCubic[2].fY * 2) / 3; } const SkPoint* pts() const { return fContour->segments()[fIndex].pts(); } SkScalar right() const { return bounds().fRight; } ptrdiff_t segmentIndex() const { return fIndex; } SegmentType segmentType() const { const Segment& segment = fContour->segments()[fIndex]; SegmentType type = (SegmentType) segment.verb(); if (type != kLine_Segment) { return type; } if (segment.isHorizontal()) { return kHorizontalLine_Segment; } if (segment.isVertical()) { return kVerticalLine_Segment; } return kLine_Segment; } bool startAfter(const Work& after) { fIndex = after.fIndex; return advance(); } SkScalar top() const { return bounds().fTop; } SkPath::Verb verb() const { return fContour->segments()[fIndex].verb(); } SkScalar x() const { return bounds().fLeft; } bool xFlipped() const { return x() != pts()[0].fX; } SkScalar y() const { return bounds().fTop; } bool yFlipped() const { return y() != pts()[0].fY; } protected: Contour* fContour; SkPoint fCubic[4]; int fIndex; int fLast; }; #if DEBUG_ADD_INTERSECTING_TS static void debugShowLineIntersection(int pts, const Work& wt, const Work& wn, const double wtTs[2], const double wnTs[2]) { if (!pts) { SkDebugf("%s no intersect (%1.9g,%1.9g %1.9g,%1.9g) (%1.9g,%1.9g %1.9g,%1.9g)\n", __FUNCTION__, wt.pts()[0].fX, wt.pts()[0].fY, wt.pts()[1].fX, wt.pts()[1].fY, wn.pts()[0].fX, wn.pts()[0].fY, wn.pts()[1].fX, wn.pts()[1].fY); return; } SkPoint wtOutPt, wnOutPt; LineXYAtT(wt.pts(), wtTs[0], &wtOutPt); LineXYAtT(wn.pts(), wnTs[0], &wnOutPt); SkDebugf("%s wtTs[0]=%g (%g,%g, %g,%g) (%g,%g)", __FUNCTION__, wtTs[0], wt.pts()[0].fX, wt.pts()[0].fY, wt.pts()[1].fX, wt.pts()[1].fY, wtOutPt.fX, wtOutPt.fY); if (pts == 2) { SkDebugf(" wtTs[1]=%g", wtTs[1]); } SkDebugf(" wnTs[0]=%g (%g,%g, %g,%g) (%g,%g)", wnTs[0], wn.pts()[0].fX, wn.pts()[0].fY, wn.pts()[1].fX, wn.pts()[1].fY, wnOutPt.fX, wnOutPt.fY); if (pts == 2) { SkDebugf(" wnTs[1]=%g", wnTs[1]); } SkDebugf("\n"); } #else static void debugShowLineIntersection(int , const Work& , const Work& , const double [2], const double [2]) { } #endif static bool addIntersectTs(Contour* test, Contour* next) { if (test != next) { if (test->bounds().fBottom < next->bounds().fTop) { return false; } if (!Bounds::Intersects(test->bounds(), next->bounds())) { return true; } } Work wt; wt.init(test); bool foundCommonContour = test == next; do { Work wn; wn.init(next); if (test == next && !wn.startAfter(wt)) { continue; } do { if (!Bounds::Intersects(wt.bounds(), wn.bounds())) { continue; } int pts; Intersections ts; bool swap = false; switch (wt.segmentType()) { case Work::kHorizontalLine_Segment: swap = true; switch (wn.segmentType()) { case Work::kHorizontalLine_Segment: case Work::kVerticalLine_Segment: case Work::kLine_Segment: { pts = HLineIntersect(wn.pts(), wt.left(), wt.right(), wt.y(), wt.xFlipped(), ts); debugShowLineIntersection(pts, wt, wn, ts.fT[1], ts.fT[0]); break; } case Work::kQuad_Segment: { pts = HQuadIntersect(wn.pts(), wt.left(), wt.right(), wt.y(), wt.xFlipped(), ts); break; } case Work::kCubic_Segment: { pts = HCubicIntersect(wn.pts(), wt.left(), wt.right(), wt.y(), wt.xFlipped(), ts); break; } default: SkASSERT(0); } break; case Work::kVerticalLine_Segment: swap = true; switch (wn.segmentType()) { case Work::kHorizontalLine_Segment: case Work::kVerticalLine_Segment: case Work::kLine_Segment: { pts = VLineIntersect(wn.pts(), wt.top(), wt.bottom(), wt.x(), wt.yFlipped(), ts); debugShowLineIntersection(pts, wt, wn, ts.fT[1], ts.fT[0]); break; } case Work::kQuad_Segment: { pts = VQuadIntersect(wn.pts(), wt.top(), wt.bottom(), wt.x(), wt.yFlipped(), ts); break; } case Work::kCubic_Segment: { pts = VCubicIntersect(wn.pts(), wt.top(), wt.bottom(), wt.x(), wt.yFlipped(), ts); break; } default: SkASSERT(0); } break; case Work::kLine_Segment: switch (wn.segmentType()) { case Work::kHorizontalLine_Segment: pts = HLineIntersect(wt.pts(), wn.left(), wn.right(), wn.y(), wn.xFlipped(), ts); debugShowLineIntersection(pts, wt, wn, ts.fT[1], ts.fT[0]); break; case Work::kVerticalLine_Segment: pts = VLineIntersect(wt.pts(), wn.top(), wn.bottom(), wn.x(), wn.yFlipped(), ts); debugShowLineIntersection(pts, wt, wn, ts.fT[1], ts.fT[0]); break; case Work::kLine_Segment: { pts = LineIntersect(wt.pts(), wn.pts(), ts); debugShowLineIntersection(pts, wt, wn, ts.fT[1], ts.fT[0]); break; } case Work::kQuad_Segment: { swap = true; pts = QuadLineIntersect(wn.pts(), wt.pts(), ts); break; } case Work::kCubic_Segment: { swap = true; pts = CubicLineIntersect(wn.pts(), wt.pts(), ts); break; } default: SkASSERT(0); } break; case Work::kQuad_Segment: switch (wn.segmentType()) { case Work::kHorizontalLine_Segment: pts = HQuadIntersect(wt.pts(), wn.left(), wn.right(), wn.y(), wn.xFlipped(), ts); break; case Work::kVerticalLine_Segment: pts = VQuadIntersect(wt.pts(), wn.top(), wn.bottom(), wn.x(), wn.yFlipped(), ts); break; case Work::kLine_Segment: { pts = QuadLineIntersect(wt.pts(), wn.pts(), ts); break; } case Work::kQuad_Segment: { pts = QuadIntersect(wt.pts(), wn.pts(), ts); break; } case Work::kCubic_Segment: { wt.promoteToCubic(); pts = CubicIntersect(wt.cubic(), wn.pts(), ts); break; } default: SkASSERT(0); } break; case Work::kCubic_Segment: switch (wn.segmentType()) { case Work::kHorizontalLine_Segment: pts = HCubicIntersect(wt.pts(), wn.left(), wn.right(), wn.y(), wn.xFlipped(), ts); break; case Work::kVerticalLine_Segment: pts = VCubicIntersect(wt.pts(), wn.top(), wn.bottom(), wn.x(), wn.yFlipped(), ts); break; case Work::kLine_Segment: { pts = CubicLineIntersect(wt.pts(), wn.pts(), ts); break; } case Work::kQuad_Segment: { wn.promoteToCubic(); pts = CubicIntersect(wt.pts(), wn.cubic(), ts); break; } case Work::kCubic_Segment: { pts = CubicIntersect(wt.pts(), wn.pts(), ts); break; } default: SkASSERT(0); } break; default: SkASSERT(0); } if (!foundCommonContour && pts > 0) { test->addCross(next); next->addCross(test); foundCommonContour = true; } // in addition to recording T values, record matching segment if (pts == 2 && wn.segmentType() <= Work::kLine_Segment && wt.segmentType() <= Work::kLine_Segment) { wt.addCoincident(wn, ts, swap); continue; } for (int pt = 0; pt < pts; ++pt) { SkASSERT(ts.fT[0][pt] >= 0 && ts.fT[0][pt] <= 1); SkASSERT(ts.fT[1][pt] >= 0 && ts.fT[1][pt] <= 1); int testTAt = wt.addT(ts.fT[swap][pt], wn); int nextTAt = wn.addT(ts.fT[!swap][pt], wt); wt.addOtherT(testTAt, ts.fT[!swap][pt], nextTAt); wn.addOtherT(nextTAt, ts.fT[swap][pt], testTAt); } } while (wn.advance()); } while (wt.advance()); return true; } // resolve any coincident pairs found while intersecting, and // see if coincidence is formed by clipping non-concident segments static void coincidenceCheck(SkTDArray& contourList, int winding) { int contourCount = contourList.count(); for (int cIndex = 0; cIndex < contourCount; ++cIndex) { Contour* contour = contourList[cIndex]; contour->findTooCloseToCall(winding); } for (int cIndex = 0; cIndex < contourCount; ++cIndex) { Contour* contour = contourList[cIndex]; contour->resolveCoincidence(winding); } } // project a ray from the top of the contour up and see if it hits anything // note: when we compute line intersections, we keep track of whether // two contours touch, so we need only look at contours not touching this one. // OPTIMIZATION: sort contourList vertically to avoid linear walk static int innerContourCheck(SkTDArray& contourList, Contour* baseContour, const SkPoint& basePt) { int contourCount = contourList.count(); int winding = 0; SkScalar bestY = SK_ScalarMin; for (int cTest = 0; cTest < contourCount; ++cTest) { Contour* contour = contourList[cTest]; if (basePt.fY < contour->bounds().fTop) { continue; } if (bestY > contour->bounds().fBottom) { continue; } if (baseContour->crosses(contour)) { continue; } int tIndex; double tHit; const Segment* test = contour->crossedSegment(basePt, bestY, tIndex, tHit); if (!test) { continue; } // If the ray hit the end of a span, we need to construct the wheel of // angles to find the span closest to the ray -- even if there are just // two spokes on the wheel. if (tHit == test->t(tIndex)) { SkTDArray angles; int end = test->nextSpan(tIndex, 1); if (end < 0) { end = test->nextSpan(tIndex, -1); } test->addTwoAngles(tIndex, end, angles); // test->buildAnglesInner(tIndex, angles); test->buildAngles(tIndex, angles); SkTDArray sorted; sortAngles(angles, sorted); const Angle* angle = sorted[0]; test = angle->segment(); SkScalar testDx = (*SegmentDXAtT[test->verb()])(test->pts(), tHit); if (testDx == 0) { angle = *(sorted.end() - 1); test = angle->segment(); SkASSERT((*SegmentDXAtT[test->verb()])(test->pts(), tHit) != 0); } tIndex = angle->start(); // lesser Y winding = test->windSum(SkMin32(tIndex, angle->end())); #if DEBUG_WINDING SkDebugf("%s 1 winding=%d\n", __FUNCTION__, winding); #endif } else { winding = test->windSum(tIndex); #if DEBUG_WINDING SkDebugf("%s 2 winding=%d\n", __FUNCTION__, winding); #endif } // see if a + change in T results in a +/- change in X (compute x'(T)) SkScalar dx = (*SegmentDXAtT[test->verb()])(test->pts(), tHit); #if DEBUG_WINDING SkDebugf("%s dx=%1.9g\n", __FUNCTION__, dx); #endif SkASSERT(dx != 0); if (winding * dx > 0) { // if same signs, result is negative winding += dx > 0 ? -1 : 1; #if DEBUG_WINDING SkDebugf("%s 3 winding=%d\n", __FUNCTION__, winding); #endif } } baseContour->setWinding(winding); return winding; } // OPTIMIZATION: not crazy about linear search here to find top active y. // seems like we should break down and do the sort, or maybe sort each // contours' segments? // Once the segment array is built, there's no reason I can think of not to // sort it in Y. hmmm // FIXME: return the contour found to pass to inner contour check static Segment* findTopContour(SkTDArray& contourList, Contour*& topContour) { int contourCount = contourList.count(); int cIndex = 0; Segment* topStart; SkScalar bestY = SK_ScalarMax; Contour* contour; do { contour = contourList[cIndex]; topStart = contour->topSegment(bestY); } while (!topStart && ++cIndex < contourCount); if (!topStart) { return NULL; } topContour = contour; while (++cIndex < contourCount) { contour = contourList[cIndex]; if (bestY < contour->bounds().fTop) { continue; } SkScalar testY = SK_ScalarMax; Segment* test = contour->topSegment(testY); if (!test || bestY <= testY) { continue; } topContour = contour; topStart = test; bestY = testY; } return topStart; } static Segment* findChase(SkTDArray& chase, int& tIndex, int& endIndex) { while (chase.count()) { Span* span = chase[chase.count() - 1]; const Span& backPtr = span->fOther->span(span->fOtherIndex); Segment* segment = backPtr.fOther; tIndex = backPtr.fOtherIndex; SkTDArray angles; int done = 0; if (segment->activeAngle(tIndex, done, angles)) { Angle* last = angles.end() - 1; tIndex = last->start(); endIndex = last->end(); return last->segment(); } if (done == angles.count()) { chase.pop(&span); continue; } SkTDArray sorted; sortAngles(angles, sorted); // find first angle, initialize winding to computed fWindSum int firstIndex = -1; const Angle* angle; int winding; do { angle = sorted[++firstIndex]; winding = angle->segment()->windSum(angle); } while (winding == SK_MinS32); int firstSign = angle->sign(); if (firstSign * winding > 0) { winding -= firstSign; } // SkDebugf("%s firstSign=%d\n", __FUNCTION__, firstSign); // we care about first sign and whether wind sum indicates this // edge is inside or outside. Maybe need to pass span winding // or first winding or something into this function? // advance to first undone angle, then return it and winding // (to set whether edges are active or not) int nextIndex = firstIndex + 1; int angleCount = sorted.count(); int lastIndex = firstIndex != 0 ? firstIndex : angleCount; do { SkASSERT(nextIndex != firstIndex); if (nextIndex == angleCount) { nextIndex = 0; } const Angle* angle = sorted[nextIndex]; segment = angle->segment(); int windValue = segment->windValue(angle); SkASSERT(windValue > 0); int maxWinding = winding; winding -= angle->sign() * windValue; if (maxWinding * winding < 0) { SkDebugf("%s flipped sign %d %d\n", __FUNCTION__, maxWinding, winding); } tIndex = angle->start(); endIndex = angle->end(); int lesser = SkMin32(tIndex, endIndex); const Span& nextSpan = segment->span(lesser); if (!nextSpan.fDone) { // FIXME: this be wrong. assign startWinding if edge is in // same direction. If the direction is opposite, winding to // assign is flipped sign or +/- 1? if (abs(maxWinding) < abs(winding)) { maxWinding = winding; } segment->markWinding(lesser, maxWinding); break; } } while (++nextIndex != lastIndex); return segment; } return NULL; } #if DEBUG_ACTIVE_SPANS static void debugShowActiveSpans(SkTDArray& contourList) { for (int index = 0; index < contourList.count(); ++ index) { contourList[index]->debugShowActiveSpans(); } } #endif // Each segment may have an inside or an outside. Segments contained within // winding may have insides on either side, and form a contour that should be // ignored. Segments that are coincident with opposing direction segments may // have outsides on either side, and should also disappear. // 'Normal' segments will have one inside and one outside. Subsequent connections // when winding should follow the intersection direction. If more than one edge // is an option, choose first edge that continues the inside. // since we start with leftmost top edge, we'll traverse through a // smaller angle counterclockwise to get to the next edge. static void bridge(SkTDArray& contourList, SkPath& simple) { bool firstContour = true; do { Contour* topContour; Segment* topStart = findTopContour(contourList, topContour); if (!topStart) { break; } // Start at the top. Above the top is outside, below is inside. // follow edges to intersection by changing the index by direction. int index, endIndex; Segment* current = topStart->findTop(index, endIndex); int contourWinding; if (firstContour) { contourWinding = 0; firstContour = false; } else { const SkPoint& topPoint = current->xyAtT(endIndex); contourWinding = innerContourCheck(contourList, topContour, topPoint); #if DEBUG_WINDING SkDebugf("%s contourWinding=%d\n", __FUNCTION__, contourWinding); #endif } SkPoint lastPt; bool firstTime = true; int winding = contourWinding; int spanWinding = current->spanSign(index, endIndex); // int firstWinding = contourWinding + spanWinding; // FIXME: needs work. While it works in limited situations, it does // not always compute winding correctly. Active should be removed and instead // the initial winding should be correctly passed in so that if the // inner contour is wound the same way, it never finds an accumulated // winding of zero. Inside 'find next', we need to look for transitions // other than zero when resolving sorted angles. SkTDArray chaseArray; do { bool active = winding * spanWinding <= 0; #if DEBUG_WINDING if (!active) { SkDebugf("%s !active winding=%d spanWinding=%d\n", __FUNCTION__, winding, spanWinding); } #endif const SkPoint* firstPt = NULL; do { SkASSERT(!current->done()); int nextStart, nextEnd, flipped = 1; Segment* next = current->findNext(chaseArray, winding + spanWinding, index, endIndex, nextStart, nextEnd, flipped, firstTime, active); if (!next) { break; } if (!firstPt) { firstPt = ¤t->addMoveTo(index, simple, active); } lastPt = current->addCurveTo(index, endIndex, simple, active); current = next; index = nextStart; endIndex = nextEnd; spanWinding = SkSign32(spanWinding) * flipped * next->windValue( SkMin32(nextStart, nextEnd)); #if DEBUG_WINDING SkDebugf("%s spanWinding=%d\n", __FUNCTION__, spanWinding); #endif firstTime = false; } while (*firstPt != lastPt && (active || !current->done())); if (firstPt && active) { #if DEBUG_PATH_CONSTRUCTION SkDebugf("%s close\n", __FUNCTION__); #endif simple.close(); } current = findChase(chaseArray, index, endIndex); #if DEBUG_ACTIVE_SPANS debugShowActiveSpans(contourList); #endif if (!current) { break; } int lesser = SkMin32(index, endIndex); spanWinding = current->windSum(lesser); int spanValue = current->windValue(lesser); SkASSERT(spanWinding != SK_MinS32); int spanSign = current->spanSign(index, endIndex); #if DEBUG_WINDING SkDebugf("%s spanWinding=%d spanSign=%d winding=%d spanValue=%d\n", __FUNCTION__, spanWinding, spanSign, winding, spanValue); #endif if (spanWinding * spanSign < 0) { #if DEBUG_WINDING SkDebugf("%s spanWinding * spanSign < 0\n", __FUNCTION__); #endif // SkTSwap(index, endIndex); } if (abs(spanWinding) > spanValue) { winding = spanWinding; spanWinding = spanValue * SkSign32(spanWinding); winding -= spanWinding; #if DEBUG_WINDING SkDebugf("%s spanWinding=%d winding=%d\n", __FUNCTION__, spanWinding, winding); #endif } else { #if DEBUG_WINDING SkDebugf("%s ->0 contourWinding=%d winding=%d\n", __FUNCTION__, contourWinding, winding); #endif winding = 0; } } while (true); } while (true); } static void fixOtherTIndex(SkTDArray& contourList) { int contourCount = contourList.count(); for (int cTest = 0; cTest < contourCount; ++cTest) { Contour* contour = contourList[cTest]; contour->fixOtherTIndex(); } } static void makeContourList(SkTArray& contours, SkTDArray& list) { int count = contours.count(); if (count == 0) { return; } for (int index = 0; index < count; ++index) { *list.append() = &contours[index]; } QSort(list.begin(), list.end() - 1); } void simplifyx(const SkPath& path, SkPath& simple) { // returns 1 for evenodd, -1 for winding, regardless of inverse-ness int winding = (path.getFillType() & 1) ? 1 : -1; simple.reset(); simple.setFillType(SkPath::kEvenOdd_FillType); // turn path into list of segments SkTArray contours; // FIXME: add self-intersecting cubics' T values to segment EdgeBuilder builder(path, contours); SkTDArray contourList; makeContourList(contours, contourList); Contour** currentPtr = contourList.begin(); if (!currentPtr) { return; } Contour** listEnd = contourList.end(); // find all intersections between segments do { Contour** nextPtr = currentPtr; Contour* current = *currentPtr++; Contour* next; do { next = *nextPtr++; } while (addIntersectTs(current, next) && nextPtr != listEnd); } while (currentPtr != listEnd); // eat through coincident edges coincidenceCheck(contourList, winding); fixOtherTIndex(contourList); // construct closed contours bridge(contourList, simple); }