src/core/SkCubicClipper.cpp - platform/external/skia - Git at Google


 /*
  * Copyright 2009 The Android Open Source Project
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */


 #include "SkCubicClipper.h"
 #include "SkGeometry.h"

 SkCubicClipper::SkCubicClipper() {}

 void SkCubicClipper::setClip(const SkIRect& clip) {
     // conver to scalars, since that's where we'll see the points
     fClip.set(clip);
 }


 static bool chopMonoCubicAtY(SkPoint pts[4], SkScalar y, SkScalar* t) {
     SkScalar ycrv[4];
     ycrv[0] = pts[0].fY - y;
     ycrv[1] = pts[1].fY - y;
     ycrv[2] = pts[2].fY - y;
     ycrv[3] = pts[3].fY - y;

 #ifdef NEWTON_RAPHSON    // Quadratic convergence, typically <= 3 iterations.
     // Initial guess.
     // TODO(turk): Check for zero denominator? Shouldn't happen unless the curve
     // is not only monotonic but degenerate.
 #ifdef SK_SCALAR_IS_FLOAT
     SkScalar t1 = ycrv[0] / (ycrv[0] - ycrv[3]);
 #else  // !SK_SCALAR_IS_FLOAT
     SkScalar t1 = SkDivBits(ycrv[0], ycrv[0] - ycrv[3], 16);
 #endif  // !SK_SCALAR_IS_FLOAT

     // Newton's iterations.
     const SkScalar tol = SK_Scalar1 / 16384;  // This leaves 2 fixed noise bits.
     SkScalar t0;
     const int maxiters = 5;
     int iters = 0;
     bool converged;
     do {
         t0 = t1;
         SkScalar y01   = SkScalarInterp(ycrv[0], ycrv[1], t0);
         SkScalar y12   = SkScalarInterp(ycrv[1], ycrv[2], t0);
         SkScalar y23   = SkScalarInterp(ycrv[2], ycrv[3], t0);
         SkScalar y012  = SkScalarInterp(y01,  y12,  t0);
         SkScalar y123  = SkScalarInterp(y12,  y23,  t0);
         SkScalar y0123 = SkScalarInterp(y012, y123, t0);
         SkScalar yder  = (y123 - y012) * 3;
         // TODO(turk): check for yder==0: horizontal.
 #ifdef SK_SCALAR_IS_FLOAT
         t1 -= y0123 / yder;
 #else  // !SK_SCALAR_IS_FLOAT
         t1 -= SkDivBits(y0123, yder, 16);
 #endif  // !SK_SCALAR_IS_FLOAT
         converged = SkScalarAbs(t1 - t0) <= tol;  // NaN-safe
         ++iters;
     } while (!converged && (iters < maxiters));
     *t = t1;                  // Return the result.

     // The result might be valid, even if outside of the range [0, 1], but
     // we never evaluate a Bezier outside this interval, so we return false.
     if (t1 < 0 || t1 > SK_Scalar1)
         return false;         // This shouldn't happen, but check anyway.
     return converged;

 #else  // BISECTION    // Linear convergence, typically 16 iterations.

     // Check that the endpoints straddle zero.
     SkScalar tNeg, tPos;    // Negative and positive function parameters.
     if (ycrv[0] < 0) {
         if (ycrv[3] < 0)
             return false;
         tNeg = 0;
         tPos = SK_Scalar1;
     } else if (ycrv[0] > 0) {
         if (ycrv[3] > 0)
             return false;
         tNeg = SK_Scalar1;
         tPos = 0;
     } else {
         *t = 0;
         return true;
     }

     const SkScalar tol = SK_Scalar1 / 65536;  // 1 for fixed, 1e-5 for float.
     int iters = 0;
     do {
         SkScalar tMid = (tPos + tNeg) / 2;
         SkScalar y01   = SkScalarInterp(ycrv[0], ycrv[1], tMid);
         SkScalar y12   = SkScalarInterp(ycrv[1], ycrv[2], tMid);
         SkScalar y23   = SkScalarInterp(ycrv[2], ycrv[3], tMid);
         SkScalar y012  = SkScalarInterp(y01,     y12,     tMid);
         SkScalar y123  = SkScalarInterp(y12,     y23,     tMid);
         SkScalar y0123 = SkScalarInterp(y012,    y123,    tMid);
         if (y0123 == 0) {
             *t = tMid;
             return true;
         }
         if (y0123 < 0)  tNeg = tMid;
         else            tPos = tMid;
         ++iters;
     } while (!(SkScalarAbs(tPos - tNeg) <= tol));   // Nan-safe

     *t = (tNeg + tPos) / 2;
     return true;
 #endif  // BISECTION
 }


 bool SkCubicClipper::clipCubic(const SkPoint srcPts[4], SkPoint dst[4]) {
     bool reverse;

     // we need the data to be monotonically descending in Y
     if (srcPts[0].fY > srcPts[3].fY) {
         dst[0] = srcPts[3];
         dst[1] = srcPts[2];
         dst[2] = srcPts[1];
         dst[3] = srcPts[0];
         reverse = true;
     } else {
         memcpy(dst, srcPts, 4 * sizeof(SkPoint));
         reverse = false;
     }

     // are we completely above or below
     const SkScalar ctop = fClip.fTop;
     const SkScalar cbot = fClip.fBottom;
     if (dst[3].fY <= ctop || dst[0].fY >= cbot) {
         return false;
     }

     SkScalar t;
     SkPoint tmp[7]; // for SkChopCubicAt

     // are we partially above
     if (dst[0].fY < ctop && chopMonoCubicAtY(dst, ctop, &t)) {
         SkChopCubicAt(dst, tmp, t);
         dst[0] = tmp[3];
         dst[1] = tmp[4];
         dst[2] = tmp[5];
     }

     // are we partially below
     if (dst[3].fY > cbot && chopMonoCubicAtY(dst, cbot, &t)) {
         SkChopCubicAt(dst, tmp, t);
         dst[1] = tmp[1];
         dst[2] = tmp[2];
         dst[3] = tmp[3];
     }

     if (reverse) {
         SkTSwap<SkPoint>(dst[0], dst[3]);
         SkTSwap<SkPoint>(dst[1], dst[2]);
     }
     return true;
 }

	/*
	* Copyright 2009 The Android Open Source Project
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/


	#include "SkCubicClipper.h"
	#include "SkGeometry.h"

	SkCubicClipper::SkCubicClipper() {}

	void SkCubicClipper::setClip(const SkIRect& clip) {
	// conver to scalars, since that's where we'll see the points
	fClip.set(clip);
	}


	static bool chopMonoCubicAtY(SkPoint pts[4], SkScalar y, SkScalar* t) {
	SkScalar ycrv[4];
	ycrv[0] = pts[0].fY - y;
	ycrv[1] = pts[1].fY - y;
	ycrv[2] = pts[2].fY - y;
	ycrv[3] = pts[3].fY - y;

	#ifdef NEWTON_RAPHSON // Quadratic convergence, typically <= 3 iterations.
	// Initial guess.
	// TODO(turk): Check for zero denominator? Shouldn't happen unless the curve
	// is not only monotonic but degenerate.
	#ifdef SK_SCALAR_IS_FLOAT
	SkScalar t1 = ycrv[0] / (ycrv[0] - ycrv[3]);
	#else // !SK_SCALAR_IS_FLOAT
	SkScalar t1 = SkDivBits(ycrv[0], ycrv[0] - ycrv[3], 16);
	#endif // !SK_SCALAR_IS_FLOAT

	// Newton's iterations.
	const SkScalar tol = SK_Scalar1 / 16384; // This leaves 2 fixed noise bits.
	SkScalar t0;
	const int maxiters = 5;
	int iters = 0;
	bool converged;
	do {
	t0 = t1;
	SkScalar y01 = SkScalarInterp(ycrv[0], ycrv[1], t0);
	SkScalar y12 = SkScalarInterp(ycrv[1], ycrv[2], t0);
	SkScalar y23 = SkScalarInterp(ycrv[2], ycrv[3], t0);
	SkScalar y012 = SkScalarInterp(y01, y12, t0);
	SkScalar y123 = SkScalarInterp(y12, y23, t0);
	SkScalar y0123 = SkScalarInterp(y012, y123, t0);
	SkScalar yder = (y123 - y012) * 3;
	// TODO(turk): check for yder==0: horizontal.
	#ifdef SK_SCALAR_IS_FLOAT
	t1 -= y0123 / yder;
	#else // !SK_SCALAR_IS_FLOAT
	t1 -= SkDivBits(y0123, yder, 16);
	#endif // !SK_SCALAR_IS_FLOAT
	converged = SkScalarAbs(t1 - t0) <= tol; // NaN-safe
	++iters;
	} while (!converged && (iters < maxiters));
	*t = t1; // Return the result.

	// The result might be valid, even if outside of the range [0, 1], but
	// we never evaluate a Bezier outside this interval, so we return false.
	if (t1 < 0 \|\| t1 > SK_Scalar1)
	return false; // This shouldn't happen, but check anyway.
	return converged;

	#else // BISECTION // Linear convergence, typically 16 iterations.

	// Check that the endpoints straddle zero.
	SkScalar tNeg, tPos; // Negative and positive function parameters.
	if (ycrv[0] < 0) {
	if (ycrv[3] < 0)
	return false;
	tNeg = 0;
	tPos = SK_Scalar1;
	} else if (ycrv[0] > 0) {
	if (ycrv[3] > 0)
	return false;
	tNeg = SK_Scalar1;
	tPos = 0;
	} else {
	*t = 0;
	return true;
	}

	const SkScalar tol = SK_Scalar1 / 65536; // 1 for fixed, 1e-5 for float.
	int iters = 0;
	do {
	SkScalar tMid = (tPos + tNeg) / 2;
	SkScalar y01 = SkScalarInterp(ycrv[0], ycrv[1], tMid);
	SkScalar y12 = SkScalarInterp(ycrv[1], ycrv[2], tMid);
	SkScalar y23 = SkScalarInterp(ycrv[2], ycrv[3], tMid);
	SkScalar y012 = SkScalarInterp(y01, y12, tMid);
	SkScalar y123 = SkScalarInterp(y12, y23, tMid);
	SkScalar y0123 = SkScalarInterp(y012, y123, tMid);
	if (y0123 == 0) {
	*t = tMid;
	return true;
	}
	if (y0123 < 0) tNeg = tMid;
	else tPos = tMid;
	++iters;
	} while (!(SkScalarAbs(tPos - tNeg) <= tol)); // Nan-safe

	*t = (tNeg + tPos) / 2;
	return true;
	#endif // BISECTION
	}


	bool SkCubicClipper::clipCubic(const SkPoint srcPts[4], SkPoint dst[4]) {
	bool reverse;

	// we need the data to be monotonically descending in Y
	if (srcPts[0].fY > srcPts[3].fY) {
	dst[0] = srcPts[3];
	dst[1] = srcPts[2];
	dst[2] = srcPts[1];
	dst[3] = srcPts[0];
	reverse = true;
	} else {
	memcpy(dst, srcPts, 4 * sizeof(SkPoint));
	reverse = false;
	}

	// are we completely above or below
	const SkScalar ctop = fClip.fTop;
	const SkScalar cbot = fClip.fBottom;
	if (dst[3].fY <= ctop \|\| dst[0].fY >= cbot) {
	return false;
	}

	SkScalar t;
	SkPoint tmp[7]; // for SkChopCubicAt

	// are we partially above
	if (dst[0].fY < ctop && chopMonoCubicAtY(dst, ctop, &t)) {
	SkChopCubicAt(dst, tmp, t);
	dst[0] = tmp[3];
	dst[1] = tmp[4];
	dst[2] = tmp[5];
	}

	// are we partially below
	if (dst[3].fY > cbot && chopMonoCubicAtY(dst, cbot, &t)) {
	SkChopCubicAt(dst, tmp, t);
	dst[1] = tmp[1];
	dst[2] = tmp[2];
	dst[3] = tmp[3];
	}

	if (reverse) {
	SkTSwap<SkPoint>(dst[0], dst[3]);
	SkTSwap<SkPoint>(dst[1], dst[2]);
	}
	return true;
	}