src/core/SkAnalyticEdge.cpp - skia - 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 "SkAnalyticEdge.h"
 #include "SkFDot6.h"
 #include "SkMathPriv.h"

 // This will become a bottleneck for small ovals rendering if we call SkFixedDiv twice here.
 // Therefore, we'll let the outter function compute the slope once and send in the value.
 // Moreover, we'll compute fDY by quickly lookup the inverse table (if possible).
 bool SkAnalyticEdge::updateLine(SkFixed x0, SkFixed y0, SkFixed x1, SkFixed y1, SkFixed slope) {
     // Since we send in the slope, we can no longer snap y inside this function.
     // If we don't send in the slope, or we do some more sophisticated snapping, this function
     // could be a performance bottleneck.
     SkASSERT(fWinding == 1 || fWinding == -1);
     SkASSERT(fCurveCount != 0);

     SkASSERT(y0 <= y1);

     SkFDot6 dx = SkFixedToFDot6(x1 - x0);
     SkFDot6 dy = SkFixedToFDot6(y1 - y0);

     // are we a zero-height line?
     if (dy == 0) {
         return false;
     }

     SkASSERT(slope < SK_MaxS32);

     SkFDot6     absSlope = SkAbs32(SkFixedToFDot6(slope));
     fX          = x0;
     fDX         = slope;
     fUpperX     = x0;
     fY          = y0;
     fUpperY     = y0;
     fLowerY     = y1;
     fDY         = (dx == 0 || slope == 0)
                   ? SK_MaxS32
                   : absSlope < kInverseTableSize
                     ? QuickFDot6Inverse::Lookup(absSlope)
                     : SkAbs32(QuickSkFDot6Div(dy, dx));

     return true;
 }

 bool SkAnalyticQuadraticEdge::setQuadratic(const SkPoint pts[3]) {
     fRiteE = nullptr;

     if (!fQEdge.setQuadraticWithoutUpdate(pts, kDefaultAccuracy)) {
         return false;
     }
     fQEdge.fQx >>= kDefaultAccuracy;
     fQEdge.fQy >>= kDefaultAccuracy;
     fQEdge.fQDx >>= kDefaultAccuracy;
     fQEdge.fQDy >>= kDefaultAccuracy;
     fQEdge.fQDDx >>= kDefaultAccuracy;
     fQEdge.fQDDy >>= kDefaultAccuracy;
     fQEdge.fQLastX >>= kDefaultAccuracy;
     fQEdge.fQLastY >>= kDefaultAccuracy;
     fQEdge.fQy = SnapY(fQEdge.fQy);
     fQEdge.fQLastY = SnapY(fQEdge.fQLastY);

     fWinding = fQEdge.fWinding;
     fCurveCount = fQEdge.fCurveCount;
     fCurveShift = fQEdge.fCurveShift;

     fSnappedX = fQEdge.fQx;
     fSnappedY = fQEdge.fQy;

     return this->updateQuadratic();
 }

 bool SkAnalyticQuadraticEdge::updateQuadratic() {
     int     success = 0; // initialize to fail!
     int     count = fCurveCount;
     SkFixed oldx = fQEdge.fQx;
     SkFixed oldy = fQEdge.fQy;
     SkFixed dx = fQEdge.fQDx;
     SkFixed dy = fQEdge.fQDy;
     SkFixed newx, newy, newSnappedX, newSnappedY;
     int     shift = fCurveShift;

     SkASSERT(count > 0);

     do {
         SkFixed slope;
         if (--count > 0)
         {
             newx    = oldx + (dx >> shift);
             newy    = oldy + (dy >> shift);
             if (SkAbs32(dy >> shift) >= SK_Fixed1 * 2) { // only snap when dy is large enough
                 SkFDot6 diffY = SkFixedToFDot6(newy - fSnappedY);
                 slope = diffY ? QuickSkFDot6Div(SkFixedToFDot6(newx - fSnappedX), diffY)
                               : SK_MaxS32;
                 newSnappedY = SkTMin<SkFixed>(fQEdge.fQLastY, SkFixedRoundToFixed(newy));
                 newSnappedX = newx - SkFixedMul(slope, newy - newSnappedY);
             } else {
                 newSnappedY = SkTMin(fQEdge.fQLastY, SnapY(newy));
                 newSnappedX = newx;
                 SkFDot6 diffY = SkFixedToFDot6(newSnappedY - fSnappedY);
                 slope = diffY ? QuickSkFDot6Div(SkFixedToFDot6(newx - fSnappedX), diffY)
                               : SK_MaxS32;
             }
             dx += fQEdge.fQDDx;
             dy += fQEdge.fQDDy;
         }
         else    // last segment
         {
             newx    = fQEdge.fQLastX;
             newy    = fQEdge.fQLastY;
             newSnappedY = newy;
             newSnappedX = newx;
             SkFDot6 diffY = (newy - fSnappedY) >> 10;
             slope = diffY ? QuickSkFDot6Div((newx - fSnappedX) >> 10, diffY) : SK_MaxS32;
         }
         if (slope < SK_MaxS32) {
             success = this->updateLine(fSnappedX, fSnappedY, newSnappedX, newSnappedY, slope);
         }
         oldx = newx;
         oldy = newy;
     } while (count > 0 && !success);

     SkASSERT(newSnappedY <= fQEdge.fQLastY);

     fQEdge.fQx  = newx;
     fQEdge.fQy  = newy;
     fQEdge.fQDx = dx;
     fQEdge.fQDy = dy;
     fSnappedX   = newSnappedX;
     fSnappedY   = newSnappedY;
     fCurveCount = SkToS8(count);
     return success;
 }

 bool SkAnalyticCubicEdge::setCubic(const SkPoint pts[4]) {
     fRiteE = nullptr;

     if (!fCEdge.setCubicWithoutUpdate(pts, kDefaultAccuracy)) {
         return false;
     }

     fCEdge.fCx >>= kDefaultAccuracy;
     fCEdge.fCy >>= kDefaultAccuracy;
     fCEdge.fCDx >>= kDefaultAccuracy;
     fCEdge.fCDy >>= kDefaultAccuracy;
     fCEdge.fCDDx >>= kDefaultAccuracy;
     fCEdge.fCDDy >>= kDefaultAccuracy;
     fCEdge.fCDDDx >>= kDefaultAccuracy;
     fCEdge.fCDDDy >>= kDefaultAccuracy;
     fCEdge.fCLastX >>= kDefaultAccuracy;
     fCEdge.fCLastY >>= kDefaultAccuracy;
     fCEdge.fCy = SnapY(fCEdge.fCy);
     fCEdge.fCLastY = SnapY(fCEdge.fCLastY);

     fWinding = fCEdge.fWinding;
     fCurveCount = fCEdge.fCurveCount;
     fCurveShift = fCEdge.fCurveShift;
     fCubicDShift = fCEdge.fCubicDShift;

     fSnappedY = fCEdge.fCy;

     return this->updateCubic();
 }

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

     SkASSERT(count < 0);

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

             newy    = oldy + (fCEdge.fCDy >> dshift);
             fCEdge.fCDy    += fCEdge.fCDDy >> ddshift;
             fCEdge.fCDDy   += fCEdge.fCDDDy;
         }
         else {    // last segment
             newx    = fCEdge.fCLastX;
             newy    = fCEdge.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;
         }

         SkFixed newSnappedY = SnapY(newy);
         // we want to SkASSERT(snappedNewY <= fCEdge.fCLastY), but our finite fixedpoint
         // doesn't always achieve that, so we have to explicitly pin it here.
         if (fCEdge.fCLastY < newSnappedY) {
             newSnappedY = fCEdge.fCLastY;
             count = 0;
         }

         SkFixed slope = SkFixedToFDot6(newSnappedY - fSnappedY) == 0
                         ? SK_MaxS32
                         : SkFDot6Div(SkFixedToFDot6(newx - oldx),
                                      SkFixedToFDot6(newSnappedY - fSnappedY));

         success = this->updateLine(oldx, fSnappedY, newx, newSnappedY, slope);

         oldx = newx;
         oldy = newy;
         fSnappedY = newSnappedY;
     } while (count < 0 && !success);

     fCEdge.fCx  = newx;
     fCEdge.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 "SkAnalyticEdge.h"
	#include "SkFDot6.h"
	#include "SkMathPriv.h"

	// This will become a bottleneck for small ovals rendering if we call SkFixedDiv twice here.
	// Therefore, we'll let the outter function compute the slope once and send in the value.
	// Moreover, we'll compute fDY by quickly lookup the inverse table (if possible).
	bool SkAnalyticEdge::updateLine(SkFixed x0, SkFixed y0, SkFixed x1, SkFixed y1, SkFixed slope) {
	// Since we send in the slope, we can no longer snap y inside this function.
	// If we don't send in the slope, or we do some more sophisticated snapping, this function
	// could be a performance bottleneck.
	SkASSERT(fWinding == 1 \|\| fWinding == -1);
	SkASSERT(fCurveCount != 0);

	SkASSERT(y0 <= y1);

	SkFDot6 dx = SkFixedToFDot6(x1 - x0);
	SkFDot6 dy = SkFixedToFDot6(y1 - y0);

	// are we a zero-height line?
	if (dy == 0) {
	return false;
	}

	SkASSERT(slope < SK_MaxS32);

	SkFDot6 absSlope = SkAbs32(SkFixedToFDot6(slope));
	fX = x0;
	fDX = slope;
	fUpperX = x0;
	fY = y0;
	fUpperY = y0;
	fLowerY = y1;
	fDY = (dx == 0 \|\| slope == 0)
	? SK_MaxS32
	: absSlope < kInverseTableSize
	? QuickFDot6Inverse::Lookup(absSlope)
	: SkAbs32(QuickSkFDot6Div(dy, dx));

	return true;
	}

	bool SkAnalyticQuadraticEdge::setQuadratic(const SkPoint pts[3]) {
	fRiteE = nullptr;

	if (!fQEdge.setQuadraticWithoutUpdate(pts, kDefaultAccuracy)) {
	return false;
	}
	fQEdge.fQx >>= kDefaultAccuracy;
	fQEdge.fQy >>= kDefaultAccuracy;
	fQEdge.fQDx >>= kDefaultAccuracy;
	fQEdge.fQDy >>= kDefaultAccuracy;
	fQEdge.fQDDx >>= kDefaultAccuracy;
	fQEdge.fQDDy >>= kDefaultAccuracy;
	fQEdge.fQLastX >>= kDefaultAccuracy;
	fQEdge.fQLastY >>= kDefaultAccuracy;
	fQEdge.fQy = SnapY(fQEdge.fQy);
	fQEdge.fQLastY = SnapY(fQEdge.fQLastY);

	fWinding = fQEdge.fWinding;
	fCurveCount = fQEdge.fCurveCount;
	fCurveShift = fQEdge.fCurveShift;

	fSnappedX = fQEdge.fQx;
	fSnappedY = fQEdge.fQy;

	return this->updateQuadratic();
	}

	bool SkAnalyticQuadraticEdge::updateQuadratic() {
	int success = 0; // initialize to fail!
	int count = fCurveCount;
	SkFixed oldx = fQEdge.fQx;
	SkFixed oldy = fQEdge.fQy;
	SkFixed dx = fQEdge.fQDx;
	SkFixed dy = fQEdge.fQDy;
	SkFixed newx, newy, newSnappedX, newSnappedY;
	int shift = fCurveShift;

	SkASSERT(count > 0);

	do {
	SkFixed slope;
	if (--count > 0)
	{
	newx = oldx + (dx >> shift);
	newy = oldy + (dy >> shift);
	if (SkAbs32(dy >> shift) >= SK_Fixed1 * 2) { // only snap when dy is large enough
	SkFDot6 diffY = SkFixedToFDot6(newy - fSnappedY);
	slope = diffY ? QuickSkFDot6Div(SkFixedToFDot6(newx - fSnappedX), diffY)
	: SK_MaxS32;
	newSnappedY = SkTMin<SkFixed>(fQEdge.fQLastY, SkFixedRoundToFixed(newy));
	newSnappedX = newx - SkFixedMul(slope, newy - newSnappedY);
	} else {
	newSnappedY = SkTMin(fQEdge.fQLastY, SnapY(newy));
	newSnappedX = newx;
	SkFDot6 diffY = SkFixedToFDot6(newSnappedY - fSnappedY);
	slope = diffY ? QuickSkFDot6Div(SkFixedToFDot6(newx - fSnappedX), diffY)
	: SK_MaxS32;
	}
	dx += fQEdge.fQDDx;
	dy += fQEdge.fQDDy;
	}
	else // last segment
	{
	newx = fQEdge.fQLastX;
	newy = fQEdge.fQLastY;
	newSnappedY = newy;
	newSnappedX = newx;
	SkFDot6 diffY = (newy - fSnappedY) >> 10;
	slope = diffY ? QuickSkFDot6Div((newx - fSnappedX) >> 10, diffY) : SK_MaxS32;
	}
	if (slope < SK_MaxS32) {
	success = this->updateLine(fSnappedX, fSnappedY, newSnappedX, newSnappedY, slope);
	}
	oldx = newx;
	oldy = newy;
	} while (count > 0 && !success);

	SkASSERT(newSnappedY <= fQEdge.fQLastY);

	fQEdge.fQx = newx;
	fQEdge.fQy = newy;
	fQEdge.fQDx = dx;
	fQEdge.fQDy = dy;
	fSnappedX = newSnappedX;
	fSnappedY = newSnappedY;
	fCurveCount = SkToS8(count);
	return success;
	}

	bool SkAnalyticCubicEdge::setCubic(const SkPoint pts[4]) {
	fRiteE = nullptr;

	if (!fCEdge.setCubicWithoutUpdate(pts, kDefaultAccuracy)) {
	return false;
	}

	fCEdge.fCx >>= kDefaultAccuracy;
	fCEdge.fCy >>= kDefaultAccuracy;
	fCEdge.fCDx >>= kDefaultAccuracy;
	fCEdge.fCDy >>= kDefaultAccuracy;
	fCEdge.fCDDx >>= kDefaultAccuracy;
	fCEdge.fCDDy >>= kDefaultAccuracy;
	fCEdge.fCDDDx >>= kDefaultAccuracy;
	fCEdge.fCDDDy >>= kDefaultAccuracy;
	fCEdge.fCLastX >>= kDefaultAccuracy;
	fCEdge.fCLastY >>= kDefaultAccuracy;
	fCEdge.fCy = SnapY(fCEdge.fCy);
	fCEdge.fCLastY = SnapY(fCEdge.fCLastY);

	fWinding = fCEdge.fWinding;
	fCurveCount = fCEdge.fCurveCount;
	fCurveShift = fCEdge.fCurveShift;
	fCubicDShift = fCEdge.fCubicDShift;

	fSnappedY = fCEdge.fCy;

	return this->updateCubic();
	}

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

	SkASSERT(count < 0);

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

	newy = oldy + (fCEdge.fCDy >> dshift);
	fCEdge.fCDy += fCEdge.fCDDy >> ddshift;
	fCEdge.fCDDy += fCEdge.fCDDDy;
	}
	else { // last segment
	newx = fCEdge.fCLastX;
	newy = fCEdge.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;
	}

	SkFixed newSnappedY = SnapY(newy);
	// we want to SkASSERT(snappedNewY <= fCEdge.fCLastY), but our finite fixedpoint
	// doesn't always achieve that, so we have to explicitly pin it here.
	if (fCEdge.fCLastY < newSnappedY) {
	newSnappedY = fCEdge.fCLastY;
	count = 0;
	}

	SkFixed slope = SkFixedToFDot6(newSnappedY - fSnappedY) == 0
	? SK_MaxS32
	: SkFDot6Div(SkFixedToFDot6(newx - oldx),
	SkFixedToFDot6(newSnappedY - fSnappedY));

	success = this->updateLine(oldx, fSnappedY, newx, newSnappedY, slope);

	oldx = newx;
	oldy = newy;
	fSnappedY = newSnappedY;
	} while (count < 0 && !success);

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