third_party/skia/src/core/SkEdge.cpp - cobalt - Git at Google

 /*
  * Copyright 2006 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 "src/core/SkEdge.h"

 #include "include/private/SkTo.h"
 #include "src/core/SkFDot6.h"
 #include "src/core/SkMathPriv.h"

 #include <utility>

 /*
     In setLine, setQuadratic, setCubic, the first thing we do is to convert
     the points into FDot6. This is modulated by the shift parameter, which
     will either be 0, or something like 2 for antialiasing.

     In the float case, we want to turn the float into .6 by saying pt * 64,
     or pt * 256 for antialiasing. This is implemented as 1 << (shift + 6).

     In the fixed case, we want to turn the fixed into .6 by saying pt >> 10,
     or pt >> 8 for antialiasing. This is implemented as pt >> (10 - shift).
 */

 static inline SkFixed SkFDot6ToFixedDiv2(SkFDot6 value) {
     // we want to return SkFDot6ToFixed(value >> 1), but we don't want to throw
     // away data in value, so just perform a modify up-shift
     return SkLeftShift(value, 16 - 6 - 1);
 }

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

 int SkEdge::setLine(const SkPoint& p0, const SkPoint& p1, const SkIRect* clip,
                     int shift) {
     SkFDot6 x0, y0, x1, y1;

     {
 #ifdef SK_RASTERIZE_EVEN_ROUNDING
         x0 = SkScalarRoundToFDot6(p0.fX, shift);
         y0 = SkScalarRoundToFDot6(p0.fY, shift);
         x1 = SkScalarRoundToFDot6(p1.fX, shift);
         y1 = SkScalarRoundToFDot6(p1.fY, shift);
 #else
         float scale = float(1 << (shift + 6));
         x0 = int(p0.fX * scale);
         y0 = int(p0.fY * scale);
         x1 = int(p1.fX * scale);
         y1 = int(p1.fY * scale);
 #endif
     }

     int winding = 1;

     if (y0 > y1) {
         using std::swap;
         swap(x0, x1);
         swap(y0, y1);
         winding = -1;
     }

     int top = SkFDot6Round(y0);
     int bot = SkFDot6Round(y1);

     // are we a zero-height line?
     if (top == bot) {
         return 0;
     }
     // are we completely above or below the clip?
     if (clip && (top >= clip->fBottom || bot <= clip->fTop)) {
         return 0;
     }

     SkFixed slope = SkFDot6Div(x1 - x0, y1 - y0);
     const SkFDot6 dy  = SkEdge_Compute_DY(top, y0);

     fX          = SkFDot6ToFixed(x0 + SkFixedMul(slope, dy));   // + SK_Fixed1/2
     fDX         = slope;
     fFirstY     = top;
     fLastY      = bot - 1;
     fCurveCount = 0;
     fWinding    = SkToS8(winding);
     fCurveShift = 0;

     if (clip) {
         this->chopLineWithClip(*clip);
     }
     return 1;
 }

 // called from a curve subclass
 int SkEdge::updateLine(SkFixed x0, SkFixed y0, SkFixed x1, SkFixed y1)
 {
     SkASSERT(fWinding == 1 || fWinding == -1);
     SkASSERT(fCurveCount != 0);
 //    SkASSERT(fCurveShift != 0);

     y0 >>= 10;
     y1 >>= 10;

     SkASSERT(y0 <= y1);

     int top = SkFDot6Round(y0);
     int bot = SkFDot6Round(y1);

 //  SkASSERT(top >= fFirstY);

     // are we a zero-height line?
     if (top == bot)
         return 0;

     x0 >>= 10;
     x1 >>= 10;

     SkFixed slope = SkFDot6Div(x1 - x0, y1 - y0);
     const SkFDot6 dy  = SkEdge_Compute_DY(top, y0);

     fX          = SkFDot6ToFixed(x0 + SkFixedMul(slope, dy));   // + SK_Fixed1/2
     fDX         = slope;
     fFirstY     = top;
     fLastY      = bot - 1;

     return 1;
 }

 void SkEdge::chopLineWithClip(const SkIRect& clip)
 {
     int top = fFirstY;

     SkASSERT(top < clip.fBottom);

     // clip the line to the top
     if (top < clip.fTop)
     {
         SkASSERT(fLastY >= clip.fTop);
         fX += fDX * (clip.fTop - top);
         fFirstY = clip.fTop;
     }
 }

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

 /*  We store 1<<shift in a (signed) byte, so its maximum value is 1<<6 == 64.
     Note that this limits the number of lines we use to approximate a curve.
     If we need to increase this, we need to store fCurveCount in something
     larger than int8_t.
 */
 #define MAX_COEFF_SHIFT     6

 static inline SkFDot6 cheap_distance(SkFDot6 dx, SkFDot6 dy)
 {
     dx = SkAbs32(dx);
     dy = SkAbs32(dy);
     // return max + min/2
     if (dx > dy)
         dx += dy >> 1;
     else
         dx = dy + (dx >> 1);
     return dx;
 }

 static inline int diff_to_shift(SkFDot6 dx, SkFDot6 dy, int shiftAA = 2)
 {
     // cheap calc of distance from center of p0-p2 to the center of the curve
     SkFDot6 dist = cheap_distance(dx, dy);

     // shift down dist (it is currently in dot6)
     // down by 3 should give us 1/8 pixel accuracy (assuming our dist is accurate...)
     // this is chosen by heuristic: make it as big as possible (to minimize segments)
     // ... but small enough so that our curves still look smooth
     // When shift > 0, we're using AA and everything is scaled up so we can
     // lower the accuracy.
     dist = (dist + (1 << 4)) >> (3 + shiftAA);

     // each subdivision (shift value) cuts this dist (error) by 1/4
     return (32 - SkCLZ(dist)) >> 1;
 }

 bool SkQuadraticEdge::setQuadraticWithoutUpdate(const SkPoint pts[3], int shift) {
     SkFDot6 x0, y0, x1, y1, x2, y2;

     {
 #ifdef SK_RASTERIZE_EVEN_ROUNDING
         x0 = SkScalarRoundToFDot6(pts[0].fX, shift);
         y0 = SkScalarRoundToFDot6(pts[0].fY, shift);
         x1 = SkScalarRoundToFDot6(pts[1].fX, shift);
         y1 = SkScalarRoundToFDot6(pts[1].fY, shift);
         x2 = SkScalarRoundToFDot6(pts[2].fX, shift);
         y2 = SkScalarRoundToFDot6(pts[2].fY, shift);
 #else
         float scale = float(1 << (shift + 6));
         x0 = int(pts[0].fX * scale);
         y0 = int(pts[0].fY * scale);
         x1 = int(pts[1].fX * scale);
         y1 = int(pts[1].fY * scale);
         x2 = int(pts[2].fX * scale);
         y2 = int(pts[2].fY * scale);
 #endif
     }

     int winding = 1;
     if (y0 > y2)
     {
         using std::swap;
         swap(x0, x2);
         swap(y0, y2);
         winding = -1;
     }
     SkASSERT(y0 <= y1 && y1 <= y2);

     int top = SkFDot6Round(y0);
     int bot = SkFDot6Round(y2);

     // are we a zero-height quad (line)?
     if (top == bot)
         return 0;

     // compute number of steps needed (1 << shift)
     {
         SkFDot6 dx = (SkLeftShift(x1, 1) - x0 - x2) >> 2;
         SkFDot6 dy = (SkLeftShift(y1, 1) - y0 - y2) >> 2;
         // This is a little confusing:
         // before this line, shift is the scale up factor for AA;
         // after this line, shift is the fCurveShift.
         shift = diff_to_shift(dx, dy, shift);
         SkASSERT(shift >= 0);
     }
     // need at least 1 subdivision for our bias trick
     if (shift == 0) {
         shift = 1;
     } else if (shift > MAX_COEFF_SHIFT) {
         shift = MAX_COEFF_SHIFT;
     }

     fWinding    = SkToS8(winding);
     //fCubicDShift only set for cubics
     fCurveCount = SkToS8(1 << shift);

     /*
      *  We want to reformulate into polynomial form, to make it clear how we
      *  should forward-difference.
      *
      *  p0 (1 - t)^2 + p1 t(1 - t) + p2 t^2 ==> At^2 + Bt + C
      *
      *  A = p0 - 2p1 + p2
      *  B = 2(p1 - p0)
      *  C = p0
      *
      *  Our caller must have constrained our inputs (p0..p2) to all fit into
      *  16.16. However, as seen above, we sometimes compute values that can be
      *  larger (e.g. B = 2*(p1 - p0)). To guard against overflow, we will store
      *  A and B at 1/2 of their actual value, and just apply a 2x scale during
      *  application in updateQuadratic(). Hence we store (shift - 1) in
      *  fCurveShift.
      */

     fCurveShift = SkToU8(shift - 1);

     SkFixed A = SkFDot6ToFixedDiv2(x0 - x1 - x1 + x2);  // 1/2 the real value
     SkFixed B = SkFDot6ToFixed(x1 - x0);                // 1/2 the real value

     fQx     = SkFDot6ToFixed(x0);
     fQDx    = B + (A >> shift);     // biased by shift
     fQDDx   = A >> (shift - 1);     // biased by shift

     A = SkFDot6ToFixedDiv2(y0 - y1 - y1 + y2);  // 1/2 the real value
     B = SkFDot6ToFixed(y1 - y0);                // 1/2 the real value

     fQy     = SkFDot6ToFixed(y0);
     fQDy    = B + (A >> shift);     // biased by shift
     fQDDy   = A >> (shift - 1);     // biased by shift

     fQLastX = SkFDot6ToFixed(x2);
     fQLastY = SkFDot6ToFixed(y2);

     return true;
 }

 int SkQuadraticEdge::setQuadratic(const SkPoint pts[3], int shift) {
     if (!setQuadraticWithoutUpdate(pts, shift)) {
         return 0;
     }
     return this->updateQuadratic();
 }

 int SkQuadraticEdge::updateQuadratic()
 {
     int     success;
     int     count = fCurveCount;
     SkFixed oldx = fQx;
     SkFixed oldy = fQy;
     SkFixed dx = fQDx;
     SkFixed dy = fQDy;
     SkFixed newx, newy;
     int     shift = fCurveShift;

     SkASSERT(count > 0);

     do {
         if (--count > 0)
         {
             newx    = oldx + (dx >> shift);
             dx    += fQDDx;
             newy    = oldy + (dy >> shift);
             dy    += fQDDy;
         }
         else    // last segment
         {
             newx    = fQLastX;
             newy    = fQLastY;
         }
         success = this->updateLine(oldx, oldy, newx, newy);
         oldx = newx;
         oldy = newy;
     } while (count > 0 && !success);

     fQx         = newx;
     fQy         = newy;
     fQDx        = dx;
     fQDy        = dy;
     fCurveCount = SkToS8(count);
     return success;
 }

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

 static inline int SkFDot6UpShift(SkFDot6 x, int upShift) {
     SkASSERT((SkLeftShift(x, upShift) >> upShift) == x);
     return SkLeftShift(x, upShift);
 }

 /*  f(1/3) = (8a + 12b + 6c + d) / 27
     f(2/3) = (a + 6b + 12c + 8d) / 27

     f(1/3)-b = (8a - 15b + 6c + d) / 27
     f(2/3)-c = (a + 6b - 15c + 8d) / 27

     use 16/512 to approximate 1/27
 */
 static SkFDot6 cubic_delta_from_line(SkFDot6 a, SkFDot6 b, SkFDot6 c, SkFDot6 d)
 {
     // since our parameters may be negative, we don't use << to avoid ASAN warnings
     SkFDot6 oneThird = (a*8 - b*15 + 6*c + d) * 19 >> 9;
     SkFDot6 twoThird = (a + 6*b - c*15 + d*8) * 19 >> 9;

     return SkMax32(SkAbs32(oneThird), SkAbs32(twoThird));
 }

 bool SkCubicEdge::setCubicWithoutUpdate(const SkPoint pts[4], int shift, bool sortY) {
     SkFDot6 x0, y0, x1, y1, x2, y2, x3, y3;

     {
 #ifdef SK_RASTERIZE_EVEN_ROUNDING
         x0 = SkScalarRoundToFDot6(pts[0].fX, shift);
         y0 = SkScalarRoundToFDot6(pts[0].fY, shift);
         x1 = SkScalarRoundToFDot6(pts[1].fX, shift);
         y1 = SkScalarRoundToFDot6(pts[1].fY, shift);
         x2 = SkScalarRoundToFDot6(pts[2].fX, shift);
         y2 = SkScalarRoundToFDot6(pts[2].fY, shift);
         x3 = SkScalarRoundToFDot6(pts[3].fX, shift);
         y3 = SkScalarRoundToFDot6(pts[3].fY, shift);
 #else
         float scale = float(1 << (shift + 6));
         x0 = int(pts[0].fX * scale);
         y0 = int(pts[0].fY * scale);
         x1 = int(pts[1].fX * scale);
         y1 = int(pts[1].fY * scale);
         x2 = int(pts[2].fX * scale);
         y2 = int(pts[2].fY * scale);
         x3 = int(pts[3].fX * scale);
         y3 = int(pts[3].fY * scale);
 #endif
     }

     int winding = 1;
     if (sortY && y0 > y3)
     {
         using std::swap;
         swap(x0, x3);
         swap(x1, x2);
         swap(y0, y3);
         swap(y1, y2);
         winding = -1;
     }

     int top = SkFDot6Round(y0);
     int bot = SkFDot6Round(y3);

     // are we a zero-height cubic (line)?
     if (sortY && top == bot)
         return 0;

     // compute number of steps needed (1 << shift)
     {
         // Can't use (center of curve - center of baseline), since center-of-curve
         // need not be the max delta from the baseline (it could even be coincident)
         // so we try just looking at the two off-curve points
         SkFDot6 dx = cubic_delta_from_line(x0, x1, x2, x3);
         SkFDot6 dy = cubic_delta_from_line(y0, y1, y2, y3);
         // add 1 (by observation)
         shift = diff_to_shift(dx, dy) + 1;
     }
     // need at least 1 subdivision for our bias trick
     SkASSERT(shift > 0);
     if (shift > MAX_COEFF_SHIFT) {
         shift = MAX_COEFF_SHIFT;
     }

     /*  Since our in coming data is initially shifted down by 10 (or 8 in
         antialias). That means the most we can shift up is 8. However, we
         compute coefficients with a 3*, so the safest upshift is really 6
     */
     int upShift = 6;    // largest safe value
     int downShift = shift + upShift - 10;
     if (downShift < 0) {
         downShift = 0;
         upShift = 10 - shift;
     }

     fWinding    = SkToS8(winding);
     fCurveCount = SkToS8(SkLeftShift(-1, shift));
     fCurveShift = SkToU8(shift);
     fCubicDShift = SkToU8(downShift);

     SkFixed B = SkFDot6UpShift(3 * (x1 - x0), upShift);
     SkFixed C = SkFDot6UpShift(3 * (x0 - x1 - x1 + x2), upShift);
     SkFixed D = SkFDot6UpShift(x3 + 3 * (x1 - x2) - x0, upShift);

     fCx     = SkFDot6ToFixed(x0);
     fCDx    = B + (C >> shift) + (D >> 2*shift);    // biased by shift
     fCDDx   = 2*C + (3*D >> (shift - 1));           // biased by 2*shift
     fCDDDx  = 3*D >> (shift - 1);                   // biased by 2*shift

     B = SkFDot6UpShift(3 * (y1 - y0), upShift);
     C = SkFDot6UpShift(3 * (y0 - y1 - y1 + y2), upShift);
     D = SkFDot6UpShift(y3 + 3 * (y1 - y2) - y0, upShift);

     fCy     = SkFDot6ToFixed(y0);
     fCDy    = B + (C >> shift) + (D >> 2*shift);    // biased by shift
     fCDDy   = 2*C + (3*D >> (shift - 1));           // biased by 2*shift
     fCDDDy  = 3*D >> (shift - 1);                   // biased by 2*shift

     fCLastX = SkFDot6ToFixed(x3);
     fCLastY = SkFDot6ToFixed(y3);

     return true;
 }

 int SkCubicEdge::setCubic(const SkPoint pts[4], int shift) {
     if (!this->setCubicWithoutUpdate(pts, shift)) {
         return 0;
     }
     return this->updateCubic();
 }

 int SkCubicEdge::updateCubic()
 {
     int     success;
     int     count = fCurveCount;
     SkFixed oldx = fCx;
     SkFixed oldy = fCy;
     SkFixed newx, newy;
     const int ddshift = fCurveShift;
     const int dshift = fCubicDShift;

     SkASSERT(count < 0);

     do {
         if (++count < 0)
         {
             newx    = oldx + (fCDx >> dshift);
             fCDx    += fCDDx >> ddshift;
             fCDDx   += fCDDDx;

             newy    = oldy + (fCDy >> dshift);
             fCDy    += fCDDy >> ddshift;
             fCDDy   += fCDDDy;
         }
         else    // last segment
         {
         //  SkDebugf("LastX err=%d, LastY err=%d\n", (oldx + (fCDx >> shift) - fLastX), (oldy + (fCDy >> shift) - fLastY));
             newx    = fCLastX;
             newy    = fCLastY;
         }

         // we want to say SkASSERT(oldy <= newy), but our finite fixedpoint
         // doesn't always achieve that, so we have to explicitly pin it here.
         if (newy < oldy) {
             newy = oldy;
         }

         success = this->updateLine(oldx, oldy, newx, newy);
         oldx = newx;
         oldy = newy;
     } while (count < 0 && !success);

     fCx         = newx;
     fCy         = newy;
     fCurveCount = SkToS8(count);
     return success;
 }
	/*
	* Copyright 2006 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 "src/core/SkEdge.h"

	#include "include/private/SkTo.h"
	#include "src/core/SkFDot6.h"
	#include "src/core/SkMathPriv.h"

	#include <utility>

	/*
	In setLine, setQuadratic, setCubic, the first thing we do is to convert
	the points into FDot6. This is modulated by the shift parameter, which
	will either be 0, or something like 2 for antialiasing.

	In the float case, we want to turn the float into .6 by saying pt * 64,
	or pt * 256 for antialiasing. This is implemented as 1 << (shift + 6).

	In the fixed case, we want to turn the fixed into .6 by saying pt >> 10,
	or pt >> 8 for antialiasing. This is implemented as pt >> (10 - shift).
	*/

	static inline SkFixed SkFDot6ToFixedDiv2(SkFDot6 value) {
	// we want to return SkFDot6ToFixed(value >> 1), but we don't want to throw
	// away data in value, so just perform a modify up-shift
	return SkLeftShift(value, 16 - 6 - 1);
	}

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

	int SkEdge::setLine(const SkPoint& p0, const SkPoint& p1, const SkIRect* clip,
	int shift) {
	SkFDot6 x0, y0, x1, y1;

	{
	#ifdef SK_RASTERIZE_EVEN_ROUNDING
	x0 = SkScalarRoundToFDot6(p0.fX, shift);
	y0 = SkScalarRoundToFDot6(p0.fY, shift);
	x1 = SkScalarRoundToFDot6(p1.fX, shift);
	y1 = SkScalarRoundToFDot6(p1.fY, shift);
	#else
	float scale = float(1 << (shift + 6));
	x0 = int(p0.fX * scale);
	y0 = int(p0.fY * scale);
	x1 = int(p1.fX * scale);
	y1 = int(p1.fY * scale);
	#endif
	}

	int winding = 1;

	if (y0 > y1) {
	using std::swap;
	swap(x0, x1);
	swap(y0, y1);
	winding = -1;
	}

	int top = SkFDot6Round(y0);
	int bot = SkFDot6Round(y1);

	// are we a zero-height line?
	if (top == bot) {
	return 0;
	}
	// are we completely above or below the clip?
	if (clip && (top >= clip->fBottom \|\| bot <= clip->fTop)) {
	return 0;
	}

	SkFixed slope = SkFDot6Div(x1 - x0, y1 - y0);
	const SkFDot6 dy = SkEdge_Compute_DY(top, y0);

	fX = SkFDot6ToFixed(x0 + SkFixedMul(slope, dy)); // + SK_Fixed1/2
	fDX = slope;
	fFirstY = top;
	fLastY = bot - 1;
	fCurveCount = 0;
	fWinding = SkToS8(winding);
	fCurveShift = 0;

	if (clip) {
	this->chopLineWithClip(*clip);
	}
	return 1;
	}

	// called from a curve subclass
	int SkEdge::updateLine(SkFixed x0, SkFixed y0, SkFixed x1, SkFixed y1)
	{
	SkASSERT(fWinding == 1 \|\| fWinding == -1);
	SkASSERT(fCurveCount != 0);
	// SkASSERT(fCurveShift != 0);

	y0 >>= 10;
	y1 >>= 10;

	SkASSERT(y0 <= y1);

	int top = SkFDot6Round(y0);
	int bot = SkFDot6Round(y1);

	// SkASSERT(top >= fFirstY);

	// are we a zero-height line?
	if (top == bot)
	return 0;

	x0 >>= 10;
	x1 >>= 10;

	SkFixed slope = SkFDot6Div(x1 - x0, y1 - y0);
	const SkFDot6 dy = SkEdge_Compute_DY(top, y0);

	fX = SkFDot6ToFixed(x0 + SkFixedMul(slope, dy)); // + SK_Fixed1/2
	fDX = slope;
	fFirstY = top;
	fLastY = bot - 1;

	return 1;
	}

	void SkEdge::chopLineWithClip(const SkIRect& clip)
	{
	int top = fFirstY;

	SkASSERT(top < clip.fBottom);

	// clip the line to the top
	if (top < clip.fTop)
	{
	SkASSERT(fLastY >= clip.fTop);
	fX += fDX * (clip.fTop - top);
	fFirstY = clip.fTop;
	}
	}

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

	/* We store 1<<shift in a (signed) byte, so its maximum value is 1<<6 == 64.
	Note that this limits the number of lines we use to approximate a curve.
	If we need to increase this, we need to store fCurveCount in something
	larger than int8_t.
	*/
	#define MAX_COEFF_SHIFT 6

	static inline SkFDot6 cheap_distance(SkFDot6 dx, SkFDot6 dy)
	{
	dx = SkAbs32(dx);
	dy = SkAbs32(dy);
	// return max + min/2
	if (dx > dy)
	dx += dy >> 1;
	else
	dx = dy + (dx >> 1);
	return dx;
	}

	static inline int diff_to_shift(SkFDot6 dx, SkFDot6 dy, int shiftAA = 2)
	{
	// cheap calc of distance from center of p0-p2 to the center of the curve
	SkFDot6 dist = cheap_distance(dx, dy);

	// shift down dist (it is currently in dot6)
	// down by 3 should give us 1/8 pixel accuracy (assuming our dist is accurate...)
	// this is chosen by heuristic: make it as big as possible (to minimize segments)
	// ... but small enough so that our curves still look smooth
	// When shift > 0, we're using AA and everything is scaled up so we can
	// lower the accuracy.
	dist = (dist + (1 << 4)) >> (3 + shiftAA);

	// each subdivision (shift value) cuts this dist (error) by 1/4
	return (32 - SkCLZ(dist)) >> 1;
	}

	bool SkQuadraticEdge::setQuadraticWithoutUpdate(const SkPoint pts[3], int shift) {
	SkFDot6 x0, y0, x1, y1, x2, y2;

	{
	#ifdef SK_RASTERIZE_EVEN_ROUNDING
	x0 = SkScalarRoundToFDot6(pts[0].fX, shift);
	y0 = SkScalarRoundToFDot6(pts[0].fY, shift);
	x1 = SkScalarRoundToFDot6(pts[1].fX, shift);
	y1 = SkScalarRoundToFDot6(pts[1].fY, shift);
	x2 = SkScalarRoundToFDot6(pts[2].fX, shift);
	y2 = SkScalarRoundToFDot6(pts[2].fY, shift);
	#else
	float scale = float(1 << (shift + 6));
	x0 = int(pts[0].fX * scale);
	y0 = int(pts[0].fY * scale);
	x1 = int(pts[1].fX * scale);
	y1 = int(pts[1].fY * scale);
	x2 = int(pts[2].fX * scale);
	y2 = int(pts[2].fY * scale);
	#endif
	}

	int winding = 1;
	if (y0 > y2)
	{
	using std::swap;
	swap(x0, x2);
	swap(y0, y2);
	winding = -1;
	}
	SkASSERT(y0 <= y1 && y1 <= y2);

	int top = SkFDot6Round(y0);
	int bot = SkFDot6Round(y2);

	// are we a zero-height quad (line)?
	if (top == bot)
	return 0;

	// compute number of steps needed (1 << shift)
	{
	SkFDot6 dx = (SkLeftShift(x1, 1) - x0 - x2) >> 2;
	SkFDot6 dy = (SkLeftShift(y1, 1) - y0 - y2) >> 2;
	// This is a little confusing:
	// before this line, shift is the scale up factor for AA;
	// after this line, shift is the fCurveShift.
	shift = diff_to_shift(dx, dy, shift);
	SkASSERT(shift >= 0);
	}
	// need at least 1 subdivision for our bias trick
	if (shift == 0) {
	shift = 1;
	} else if (shift > MAX_COEFF_SHIFT) {
	shift = MAX_COEFF_SHIFT;
	}

	fWinding = SkToS8(winding);
	//fCubicDShift only set for cubics
	fCurveCount = SkToS8(1 << shift);

	/*
	* We want to reformulate into polynomial form, to make it clear how we
	* should forward-difference.
	*
	* p0 (1 - t)^2 + p1 t(1 - t) + p2 t^2 ==> At^2 + Bt + C
	*
	* A = p0 - 2p1 + p2
	* B = 2(p1 - p0)
	* C = p0
	*
	* Our caller must have constrained our inputs (p0..p2) to all fit into
	* 16.16. However, as seen above, we sometimes compute values that can be
	* larger (e.g. B = 2*(p1 - p0)). To guard against overflow, we will store
	* A and B at 1/2 of their actual value, and just apply a 2x scale during
	* application in updateQuadratic(). Hence we store (shift - 1) in
	* fCurveShift.
	*/

	fCurveShift = SkToU8(shift - 1);

	SkFixed A = SkFDot6ToFixedDiv2(x0 - x1 - x1 + x2); // 1/2 the real value
	SkFixed B = SkFDot6ToFixed(x1 - x0); // 1/2 the real value

	fQx = SkFDot6ToFixed(x0);
	fQDx = B + (A >> shift); // biased by shift
	fQDDx = A >> (shift - 1); // biased by shift

	A = SkFDot6ToFixedDiv2(y0 - y1 - y1 + y2); // 1/2 the real value
	B = SkFDot6ToFixed(y1 - y0); // 1/2 the real value

	fQy = SkFDot6ToFixed(y0);
	fQDy = B + (A >> shift); // biased by shift
	fQDDy = A >> (shift - 1); // biased by shift

	fQLastX = SkFDot6ToFixed(x2);
	fQLastY = SkFDot6ToFixed(y2);

	return true;
	}

	int SkQuadraticEdge::setQuadratic(const SkPoint pts[3], int shift) {
	if (!setQuadraticWithoutUpdate(pts, shift)) {
	return 0;
	}
	return this->updateQuadratic();
	}

	int SkQuadraticEdge::updateQuadratic()
	{
	int success;
	int count = fCurveCount;
	SkFixed oldx = fQx;
	SkFixed oldy = fQy;
	SkFixed dx = fQDx;
	SkFixed dy = fQDy;
	SkFixed newx, newy;
	int shift = fCurveShift;

	SkASSERT(count > 0);

	do {
	if (--count > 0)
	{
	newx = oldx + (dx >> shift);
	dx += fQDDx;
	newy = oldy + (dy >> shift);
	dy += fQDDy;
	}
	else // last segment
	{
	newx = fQLastX;
	newy = fQLastY;
	}
	success = this->updateLine(oldx, oldy, newx, newy);
	oldx = newx;
	oldy = newy;
	} while (count > 0 && !success);

	fQx = newx;
	fQy = newy;
	fQDx = dx;
	fQDy = dy;
	fCurveCount = SkToS8(count);
	return success;
	}

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

	static inline int SkFDot6UpShift(SkFDot6 x, int upShift) {
	SkASSERT((SkLeftShift(x, upShift) >> upShift) == x);
	return SkLeftShift(x, upShift);
	}

	/* f(1/3) = (8a + 12b + 6c + d) / 27
	f(2/3) = (a + 6b + 12c + 8d) / 27

	f(1/3)-b = (8a - 15b + 6c + d) / 27
	f(2/3)-c = (a + 6b - 15c + 8d) / 27

	use 16/512 to approximate 1/27
	*/
	static SkFDot6 cubic_delta_from_line(SkFDot6 a, SkFDot6 b, SkFDot6 c, SkFDot6 d)
	{
	// since our parameters may be negative, we don't use << to avoid ASAN warnings
	SkFDot6 oneThird = (a8 - b15 + 6c + d) 19 >> 9;
	SkFDot6 twoThird = (a + 6b - c15 + d8) 19 >> 9;

	return SkMax32(SkAbs32(oneThird), SkAbs32(twoThird));
	}

	bool SkCubicEdge::setCubicWithoutUpdate(const SkPoint pts[4], int shift, bool sortY) {
	SkFDot6 x0, y0, x1, y1, x2, y2, x3, y3;

	{
	#ifdef SK_RASTERIZE_EVEN_ROUNDING
	x0 = SkScalarRoundToFDot6(pts[0].fX, shift);
	y0 = SkScalarRoundToFDot6(pts[0].fY, shift);
	x1 = SkScalarRoundToFDot6(pts[1].fX, shift);
	y1 = SkScalarRoundToFDot6(pts[1].fY, shift);
	x2 = SkScalarRoundToFDot6(pts[2].fX, shift);
	y2 = SkScalarRoundToFDot6(pts[2].fY, shift);
	x3 = SkScalarRoundToFDot6(pts[3].fX, shift);
	y3 = SkScalarRoundToFDot6(pts[3].fY, shift);
	#else
	float scale = float(1 << (shift + 6));
	x0 = int(pts[0].fX * scale);
	y0 = int(pts[0].fY * scale);
	x1 = int(pts[1].fX * scale);
	y1 = int(pts[1].fY * scale);
	x2 = int(pts[2].fX * scale);
	y2 = int(pts[2].fY * scale);
	x3 = int(pts[3].fX * scale);
	y3 = int(pts[3].fY * scale);
	#endif
	}

	int winding = 1;
	if (sortY && y0 > y3)
	{
	using std::swap;
	swap(x0, x3);
	swap(x1, x2);
	swap(y0, y3);
	swap(y1, y2);
	winding = -1;
	}

	int top = SkFDot6Round(y0);
	int bot = SkFDot6Round(y3);

	// are we a zero-height cubic (line)?
	if (sortY && top == bot)
	return 0;

	// compute number of steps needed (1 << shift)
	{
	// Can't use (center of curve - center of baseline), since center-of-curve
	// need not be the max delta from the baseline (it could even be coincident)
	// so we try just looking at the two off-curve points
	SkFDot6 dx = cubic_delta_from_line(x0, x1, x2, x3);
	SkFDot6 dy = cubic_delta_from_line(y0, y1, y2, y3);
	// add 1 (by observation)
	shift = diff_to_shift(dx, dy) + 1;
	}
	// need at least 1 subdivision for our bias trick
	SkASSERT(shift > 0);
	if (shift > MAX_COEFF_SHIFT) {
	shift = MAX_COEFF_SHIFT;
	}

	/* Since our in coming data is initially shifted down by 10 (or 8 in
	antialias). That means the most we can shift up is 8. However, we
	compute coefficients with a 3*, so the safest upshift is really 6
	*/
	int upShift = 6; // largest safe value
	int downShift = shift + upShift - 10;
	if (downShift < 0) {
	downShift = 0;
	upShift = 10 - shift;
	}

	fWinding = SkToS8(winding);
	fCurveCount = SkToS8(SkLeftShift(-1, shift));
	fCurveShift = SkToU8(shift);
	fCubicDShift = SkToU8(downShift);

	SkFixed B = SkFDot6UpShift(3 * (x1 - x0), upShift);
	SkFixed C = SkFDot6UpShift(3 * (x0 - x1 - x1 + x2), upShift);
	SkFixed D = SkFDot6UpShift(x3 + 3 * (x1 - x2) - x0, upShift);

	fCx = SkFDot6ToFixed(x0);
	fCDx = B + (C >> shift) + (D >> 2*shift); // biased by shift
	fCDDx = 2C + (3D >> (shift - 1)); // biased by 2*shift
	fCDDDx = 3D >> (shift - 1); // biased by 2shift

	B = SkFDot6UpShift(3 * (y1 - y0), upShift);
	C = SkFDot6UpShift(3 * (y0 - y1 - y1 + y2), upShift);
	D = SkFDot6UpShift(y3 + 3 * (y1 - y2) - y0, upShift);

	fCy = SkFDot6ToFixed(y0);
	fCDy = B + (C >> shift) + (D >> 2*shift); // biased by shift
	fCDDy = 2C + (3D >> (shift - 1)); // biased by 2*shift
	fCDDDy = 3D >> (shift - 1); // biased by 2shift

	fCLastX = SkFDot6ToFixed(x3);
	fCLastY = SkFDot6ToFixed(y3);

	return true;
	}

	int SkCubicEdge::setCubic(const SkPoint pts[4], int shift) {
	if (!this->setCubicWithoutUpdate(pts, shift)) {
	return 0;
	}
	return this->updateCubic();
	}

	int SkCubicEdge::updateCubic()
	{
	int success;
	int count = fCurveCount;
	SkFixed oldx = fCx;
	SkFixed oldy = fCy;
	SkFixed newx, newy;
	const int ddshift = fCurveShift;
	const int dshift = fCubicDShift;

	SkASSERT(count < 0);

	do {
	if (++count < 0)
	{
	newx = oldx + (fCDx >> dshift);
	fCDx += fCDDx >> ddshift;
	fCDDx += fCDDDx;

	newy = oldy + (fCDy >> dshift);
	fCDy += fCDDy >> ddshift;
	fCDDy += fCDDDy;
	}
	else // last segment
	{
	// SkDebugf("LastX err=%d, LastY err=%d\n", (oldx + (fCDx >> shift) - fLastX), (oldy + (fCDy >> shift) - fLastY));
	newx = fCLastX;
	newy = fCLastY;
	}

	// we want to say SkASSERT(oldy <= newy), but our finite fixedpoint
	// doesn't always achieve that, so we have to explicitly pin it here.
	if (newy < oldy) {
	newy = oldy;
	}

	success = this->updateLine(oldx, oldy, newx, newy);
	oldx = newx;
	oldy = newy;
	} while (count < 0 && !success);

	fCx = newx;
	fCy = newy;
	fCurveCount = SkToS8(count);
	return success;
	}