src/pathops/SkIntersections.cpp - platform/external/skia - Gitiles

 /*
  * 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 "SkIntersections.h"

 int (SkIntersections::*CurveVertical[])(const SkPoint[], SkScalar, SkScalar, SkScalar, bool) = {
     NULL,
     &SkIntersections::verticalLine,
     &SkIntersections::verticalQuad,
     &SkIntersections::verticalCubic
 };

 int (SkIntersections::*CurveRay[])(const SkPoint[], const SkDLine&) = {
     NULL,
     NULL,
     &SkIntersections::quadRay,
     &SkIntersections::cubicRay
 };

 int SkIntersections::coincidentUsed() const {
     if (!fIsCoincident[0]) {
         SkASSERT(!fIsCoincident[0]);
         return 0;
     }
     int count = 0;
     SkDEBUGCODE(int count2 = 0;)
     for (int index = 0; index < fUsed; ++index) {
         if (fIsCoincident[0] & (1 << index)) {
             ++count;
         }
 #ifdef SK_DEBUG
         if (fIsCoincident[1] & (1 << index)) {
             ++count2;
         }
 #endif
     }
     SkASSERT(count == count2);
     return count;
 }

 int SkIntersections::cubicRay(const SkPoint pts[4], const SkDLine& line) {
     SkDCubic cubic;
     cubic.set(pts);
     return intersectRay(cubic, line);
 }

 void SkIntersections::flip() {
     for (int index = 0; index < fUsed; ++index) {
         fT[1][index] = 1 - fT[1][index];
     }
 }

 void SkIntersections::insertCoincidentPair(double s1, double e1, double s2, double e2,
         const SkDPoint& startPt, const SkDPoint& endPt) {
     if (fSwap) {
         remove(s2, e2, startPt, endPt);
     } else {
         remove(s1, e1, startPt, endPt);
     }
     SkASSERT(coincidentUsed() == fUsed);
     SkASSERT((coincidentUsed() & 1) != 1);
     int i1 = 0;
     int i2 = 0;
     do {
         while (i1 < fUsed && !(fIsCoincident[fSwap] & (1 << i1))) {
             ++i1;
         }
         if (i1 == fUsed) {
             break;
         }
         SkASSERT(i1 < fUsed);
         int iEnd1 = i1 + 1;
         while (!(fIsCoincident[fSwap] & (1 << iEnd1))) {
             ++iEnd1;
         }
         SkASSERT(iEnd1 < fUsed);
         double cs1 = fT[fSwap][i1];
         double ce1 = fT[fSwap][iEnd1];
         bool s1in = between(cs1, s1, ce1) || startPt.approximatelyEqual(fPt[i1])
                 || startPt.approximatelyEqual(fPt[iEnd1]);
         bool e1in = between(cs1, e1, ce1) || endPt.approximatelyEqual(fPt[i1])
                 || endPt.approximatelyEqual(fPt[iEnd1]);
         while (i2 < fUsed && !(fIsCoincident[fSwap ^ 1] & (1 << i2))) {
             ++i2;
         }
         int iEnd2 = i2 + 1;
         while (!(fIsCoincident[fSwap ^ 1] & (1 << iEnd2))) {
             ++iEnd2;
         }
         SkASSERT(iEnd2 < fUsed);
         double cs2 = fT[fSwap ^ 1][i2];
         double ce2 = fT[fSwap ^ 1][iEnd2];
         bool s2in = between(cs2, s2, ce2) || startPt.approximatelyEqual(fPt[i2])
                 || startPt.approximatelyEqual(fPt[iEnd2]);
         bool e2in = between(cs2, e2, ce2) || endPt.approximatelyEqual(fPt[i2])
                 || endPt.approximatelyEqual(fPt[iEnd2]);
         if ((s1in | e1in) & (s2in | e2in)) {
             if (s1 < cs1) {
                 fT[fSwap][i1] = s1;
                 fPt[i1] = startPt;
             } else if (e1 < cs1) {
                 fT[fSwap][i1] = e1;
                 fPt[i1] = endPt;
             }
             if (s1 > ce1) {
                 fT[fSwap][iEnd1] = s1;
                 fPt[iEnd1] = startPt;
             } else if (e1 > ce1) {
                 fT[fSwap][iEnd1] = e1;
                 fPt[iEnd1] = endPt;
             }
             if (s2 > e2) {
                 SkTSwap(cs2, ce2);
                 SkTSwap(i2, iEnd2);
             }
             if (s2 < cs2) {
                 fT[fSwap ^ 1][i2] = s2;
             } else if (e2 < cs2) {
                 fT[fSwap ^ 1][i2] = e2;
             }
             if (s2 > ce2) {
                 fT[fSwap ^ 1][iEnd2] = s2;
             } else if (e2 > ce2) {
                 fT[fSwap ^ 1][iEnd2] = e2;
             }
             return;
         }
     } while (true);
     SkASSERT(fUsed < 9);
     insertCoincident(s1, s2, startPt);
     insertCoincident(e1, e2, endPt);
 }

 int SkIntersections::insert(double one, double two, const SkDPoint& pt) {
     if (fIsCoincident[0] == 3 && between(fT[0][0], one, fT[0][1])) {
         // For now, don't allow a mix of coincident and non-coincident intersections
         return -1;
     }
     SkASSERT(fUsed <= 1 || fT[0][0] <= fT[0][1]);
     int index;
     for (index = 0; index < fUsed; ++index) {
         double oldOne = fT[0][index];
         double oldTwo = fT[1][index];
         if (roughly_equal(oldOne, one) && roughly_equal(oldTwo, two)) {
             if ((precisely_zero(one) && !precisely_zero(oldOne))
                     || (precisely_equal(one, 1) && !precisely_equal(oldOne, 1))
                     || (precisely_zero(two) && !precisely_zero(oldTwo))
                     || (precisely_equal(two, 1) && !precisely_equal(oldTwo, 1))) {
                 fT[0][index] = one;
                 fT[1][index] = two;
                 fPt[index] = pt;
             }
             return -1;
         }
     #if ONE_OFF_DEBUG
         if (pt.roughlyEqual(fPt[index])) {
             SkDebugf("%s t=%1.9g pts roughly equal\n", __FUNCTION__, one);
         }
     #endif
         if (fT[0][index] > one) {
             break;
         }
     }
     SkASSERT(fUsed < 9);
     int remaining = fUsed - index;
     if (remaining > 0) {
         memmove(&fPt[index + 1], &fPt[index], sizeof(fPt[0]) * remaining);
         memmove(&fT[0][index + 1], &fT[0][index], sizeof(fT[0][0]) * remaining);
         memmove(&fT[1][index + 1], &fT[1][index], sizeof(fT[1][0]) * remaining);
         fIsCoincident[0] += fIsCoincident[0] & ~((1 << index) - 1);
         fIsCoincident[1] += fIsCoincident[1] & ~((1 << index) - 1);
     }
     fPt[index] = pt;
     fT[0][index] = one;
     fT[1][index] = two;
     ++fUsed;
     return index;
 }

 void SkIntersections::insertCoincident(double one, double two, const SkDPoint& pt) {
     int index = insertSwap(one, two, pt);
     int bit = 1 << index;
     fIsCoincident[0] |= bit;
     fIsCoincident[1] |= bit;
 }

 void SkIntersections::offset(int base, double start, double end) {
     for (int index = base; index < fUsed; ++index) {
         double val = fT[fSwap][index];
         val *= end - start;
         val += start;
         fT[fSwap][index] = val;
     }
 }

 int SkIntersections::quadRay(const SkPoint pts[3], const SkDLine& line) {
     SkDQuad quad;
     quad.set(pts);
     return intersectRay(quad, line);
 }

 void SkIntersections::quickRemoveOne(int index, int replace) {
     if (index < replace) {
         fT[0][index] = fT[0][replace];
     }
 }

 void SkIntersections::remove(double one, double two, const SkDPoint& startPt,
         const SkDPoint& endPt) {
     for (int index = fUsed - 1; index >= 0; --index) {
         if (!(fIsCoincident[0] & (1 << index)) && (between(one, fT[fSwap][index], two)
                 || startPt.approximatelyEqual(fPt[index])
                 || endPt.approximatelyEqual(fPt[index]))) {
             SkASSERT(fUsed > 0);
             removeOne(index);
         }
     }
 }

 void SkIntersections::removeOne(int index) {
     int remaining = --fUsed - index;
     if (remaining <= 0) {
         return;
     }
     memmove(&fPt[index], &fPt[index + 1], sizeof(fPt[0]) * remaining);
     memmove(&fT[0][index], &fT[0][index + 1], sizeof(fT[0][0]) * remaining);
     memmove(&fT[1][index], &fT[1][index + 1], sizeof(fT[1][0]) * remaining);
     SkASSERT(fIsCoincident[0] == 0);
     int coBit = fIsCoincident[0] & (1 << index);
     fIsCoincident[0] -= ((fIsCoincident[0] >> 1) & ~((1 << index) - 1)) + coBit;
     SkASSERT(!(coBit ^ (fIsCoincident[1] & (1 << index))));
     fIsCoincident[1] -= ((fIsCoincident[1] >> 1) & ~((1 << index) - 1)) + coBit;
 }

 void SkIntersections::swapPts() {
     int index;
     for (index = 0; index < fUsed; ++index) {
         SkTSwap(fT[0][index], fT[1][index]);
     }
 }

 int SkIntersections::verticalLine(const SkPoint a[2], SkScalar top, SkScalar bottom,
         SkScalar x, bool flipped) {
     SkDLine line;
     line.set(a);
     return vertical(line, top, bottom, x, flipped);
 }

 int SkIntersections::verticalQuad(const SkPoint a[3], SkScalar top, SkScalar bottom,
         SkScalar x, bool flipped) {
     SkDQuad quad;
     quad.set(a);
     return vertical(quad, top, bottom, x, flipped);
 }

 int SkIntersections::verticalCubic(const SkPoint a[4], SkScalar top, SkScalar bottom,
         SkScalar x, bool flipped) {
     SkDCubic cubic;
     cubic.set(a);
     return vertical(cubic, top, bottom, x, flipped);
 }
	/*
	* 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 "SkIntersections.h"

	int (SkIntersections::*CurveVertical[])(const SkPoint[], SkScalar, SkScalar, SkScalar, bool) = {
	NULL,
	&SkIntersections::verticalLine,
	&SkIntersections::verticalQuad,
	&SkIntersections::verticalCubic
	};

	int (SkIntersections::*CurveRay[])(const SkPoint[], const SkDLine&) = {
	NULL,
	NULL,
	&SkIntersections::quadRay,
	&SkIntersections::cubicRay
	};

	int SkIntersections::coincidentUsed() const {
	if (!fIsCoincident[0]) {
	SkASSERT(!fIsCoincident[0]);
	return 0;
	}
	int count = 0;
	SkDEBUGCODE(int count2 = 0;)
	for (int index = 0; index < fUsed; ++index) {
	if (fIsCoincident[0] & (1 << index)) {
	++count;
	}
	#ifdef SK_DEBUG
	if (fIsCoincident[1] & (1 << index)) {
	++count2;
	}
	#endif
	}
	SkASSERT(count == count2);
	return count;
	}

	int SkIntersections::cubicRay(const SkPoint pts[4], const SkDLine& line) {
	SkDCubic cubic;
	cubic.set(pts);
	return intersectRay(cubic, line);
	}

	void SkIntersections::flip() {
	for (int index = 0; index < fUsed; ++index) {
	fT[1][index] = 1 - fT[1][index];
	}
	}

	void SkIntersections::insertCoincidentPair(double s1, double e1, double s2, double e2,
	const SkDPoint& startPt, const SkDPoint& endPt) {
	if (fSwap) {
	remove(s2, e2, startPt, endPt);
	} else {
	remove(s1, e1, startPt, endPt);
	}
	SkASSERT(coincidentUsed() == fUsed);
	SkASSERT((coincidentUsed() & 1) != 1);
	int i1 = 0;
	int i2 = 0;
	do {
	while (i1 < fUsed && !(fIsCoincident[fSwap] & (1 << i1))) {
	++i1;
	}
	if (i1 == fUsed) {
	break;
	}
	SkASSERT(i1 < fUsed);
	int iEnd1 = i1 + 1;
	while (!(fIsCoincident[fSwap] & (1 << iEnd1))) {
	++iEnd1;
	}
	SkASSERT(iEnd1 < fUsed);
	double cs1 = fT[fSwap][i1];
	double ce1 = fT[fSwap][iEnd1];
	bool s1in = between(cs1, s1, ce1) \|\| startPt.approximatelyEqual(fPt[i1])
	\|\| startPt.approximatelyEqual(fPt[iEnd1]);
	bool e1in = between(cs1, e1, ce1) \|\| endPt.approximatelyEqual(fPt[i1])
	\|\| endPt.approximatelyEqual(fPt[iEnd1]);
	while (i2 < fUsed && !(fIsCoincident[fSwap ^ 1] & (1 << i2))) {
	++i2;
	}
	int iEnd2 = i2 + 1;
	while (!(fIsCoincident[fSwap ^ 1] & (1 << iEnd2))) {
	++iEnd2;
	}
	SkASSERT(iEnd2 < fUsed);
	double cs2 = fT[fSwap ^ 1][i2];
	double ce2 = fT[fSwap ^ 1][iEnd2];
	bool s2in = between(cs2, s2, ce2) \|\| startPt.approximatelyEqual(fPt[i2])
	\|\| startPt.approximatelyEqual(fPt[iEnd2]);
	bool e2in = between(cs2, e2, ce2) \|\| endPt.approximatelyEqual(fPt[i2])
	\|\| endPt.approximatelyEqual(fPt[iEnd2]);
	if ((s1in \| e1in) & (s2in \| e2in)) {
	if (s1 < cs1) {
	fT[fSwap][i1] = s1;
	fPt[i1] = startPt;
	} else if (e1 < cs1) {
	fT[fSwap][i1] = e1;
	fPt[i1] = endPt;
	}
	if (s1 > ce1) {
	fT[fSwap][iEnd1] = s1;
	fPt[iEnd1] = startPt;
	} else if (e1 > ce1) {
	fT[fSwap][iEnd1] = e1;
	fPt[iEnd1] = endPt;
	}
	if (s2 > e2) {
	SkTSwap(cs2, ce2);
	SkTSwap(i2, iEnd2);
	}
	if (s2 < cs2) {
	fT[fSwap ^ 1][i2] = s2;
	} else if (e2 < cs2) {
	fT[fSwap ^ 1][i2] = e2;
	}
	if (s2 > ce2) {
	fT[fSwap ^ 1][iEnd2] = s2;
	} else if (e2 > ce2) {
	fT[fSwap ^ 1][iEnd2] = e2;
	}
	return;
	}
	} while (true);
	SkASSERT(fUsed < 9);
	insertCoincident(s1, s2, startPt);
	insertCoincident(e1, e2, endPt);
	}

	int SkIntersections::insert(double one, double two, const SkDPoint& pt) {
	if (fIsCoincident[0] == 3 && between(fT[0][0], one, fT[0][1])) {
	// For now, don't allow a mix of coincident and non-coincident intersections
	return -1;
	}
	SkASSERT(fUsed <= 1 \|\| fT[0][0] <= fT[0][1]);
	int index;
	for (index = 0; index < fUsed; ++index) {
	double oldOne = fT[0][index];
	double oldTwo = fT[1][index];
	if (roughly_equal(oldOne, one) && roughly_equal(oldTwo, two)) {
	if ((precisely_zero(one) && !precisely_zero(oldOne))
	\|\| (precisely_equal(one, 1) && !precisely_equal(oldOne, 1))
	\|\| (precisely_zero(two) && !precisely_zero(oldTwo))
	\|\| (precisely_equal(two, 1) && !precisely_equal(oldTwo, 1))) {
	fT[0][index] = one;
	fT[1][index] = two;
	fPt[index] = pt;
	}
	return -1;
	}
	#if ONE_OFF_DEBUG
	if (pt.roughlyEqual(fPt[index])) {
	SkDebugf("%s t=%1.9g pts roughly equal\n", __FUNCTION__, one);
	}
	#endif
	if (fT[0][index] > one) {
	break;
	}
	}
	SkASSERT(fUsed < 9);
	int remaining = fUsed - index;
	if (remaining > 0) {
	memmove(&fPt[index + 1], &fPt[index], sizeof(fPt[0]) * remaining);
	memmove(&fT[0][index + 1], &fT[0][index], sizeof(fT[0][0]) * remaining);
	memmove(&fT[1][index + 1], &fT[1][index], sizeof(fT[1][0]) * remaining);
	fIsCoincident[0] += fIsCoincident[0] & ~((1 << index) - 1);
	fIsCoincident[1] += fIsCoincident[1] & ~((1 << index) - 1);
	}
	fPt[index] = pt;
	fT[0][index] = one;
	fT[1][index] = two;
	++fUsed;
	return index;
	}

	void SkIntersections::insertCoincident(double one, double two, const SkDPoint& pt) {
	int index = insertSwap(one, two, pt);
	int bit = 1 << index;
	fIsCoincident[0] \|= bit;
	fIsCoincident[1] \|= bit;
	}

	void SkIntersections::offset(int base, double start, double end) {
	for (int index = base; index < fUsed; ++index) {
	double val = fT[fSwap][index];
	val *= end - start;
	val += start;
	fT[fSwap][index] = val;
	}
	}

	int SkIntersections::quadRay(const SkPoint pts[3], const SkDLine& line) {
	SkDQuad quad;
	quad.set(pts);
	return intersectRay(quad, line);
	}

	void SkIntersections::quickRemoveOne(int index, int replace) {
	if (index < replace) {
	fT[0][index] = fT[0][replace];
	}
	}

	void SkIntersections::remove(double one, double two, const SkDPoint& startPt,
	const SkDPoint& endPt) {
	for (int index = fUsed - 1; index >= 0; --index) {
	if (!(fIsCoincident[0] & (1 << index)) && (between(one, fT[fSwap][index], two)
	\|\| startPt.approximatelyEqual(fPt[index])
	\|\| endPt.approximatelyEqual(fPt[index]))) {
	SkASSERT(fUsed > 0);
	removeOne(index);
	}
	}
	}

	void SkIntersections::removeOne(int index) {
	int remaining = --fUsed - index;
	if (remaining <= 0) {
	return;
	}
	memmove(&fPt[index], &fPt[index + 1], sizeof(fPt[0]) * remaining);
	memmove(&fT[0][index], &fT[0][index + 1], sizeof(fT[0][0]) * remaining);
	memmove(&fT[1][index], &fT[1][index + 1], sizeof(fT[1][0]) * remaining);
	SkASSERT(fIsCoincident[0] == 0);
	int coBit = fIsCoincident[0] & (1 << index);
	fIsCoincident[0] -= ((fIsCoincident[0] >> 1) & ~((1 << index) - 1)) + coBit;
	SkASSERT(!(coBit ^ (fIsCoincident[1] & (1 << index))));
	fIsCoincident[1] -= ((fIsCoincident[1] >> 1) & ~((1 << index) - 1)) + coBit;
	}

	void SkIntersections::swapPts() {
	int index;
	for (index = 0; index < fUsed; ++index) {
	SkTSwap(fT[0][index], fT[1][index]);
	}
	}

	int SkIntersections::verticalLine(const SkPoint a[2], SkScalar top, SkScalar bottom,
	SkScalar x, bool flipped) {
	SkDLine line;
	line.set(a);
	return vertical(line, top, bottom, x, flipped);
	}

	int SkIntersections::verticalQuad(const SkPoint a[3], SkScalar top, SkScalar bottom,
	SkScalar x, bool flipped) {
	SkDQuad quad;
	quad.set(a);
	return vertical(quad, top, bottom, x, flipped);
	}

	int SkIntersections::verticalCubic(const SkPoint a[4], SkScalar top, SkScalar bottom,
	SkScalar x, bool flipped) {
	SkDCubic cubic;
	cubic.set(a);
	return vertical(cubic, top, bottom, x, flipped);
	}