splash/SplashXPath.cc - third_party/poppler - Git at Google

 //========================================================================
 //
 // SplashXPath.cc
 //
 //========================================================================

 //========================================================================
 //
 // Modified under the Poppler project - http://poppler.freedesktop.org
 //
 // All changes made under the Poppler project to this file are licensed
 // under GPL version 2 or later
 //
 // Copyright (C) 2010 Paweł Wiejacha <pawel.wiejacha@gmail.com>
 // Copyright (C) 2010, 2011, 2018, 2019, 2021 Albert Astals Cid <aacid@kde.org>
 // Copyright (C) 2013 Thomas Freitag <Thomas.Freitag@alfa.de>
 // Copyright (C) 2017 Adrian Johnson <ajohnson@redneon.com>
 //
 // To see a description of the changes please see the Changelog file that
 // came with your tarball or type make ChangeLog if you are building from git
 //
 //========================================================================

 #include <config.h>

 #include <cstdlib>
 #include <cstring>
 #include <algorithm>
 #include "goo/gmem.h"
 #include "goo/GooLikely.h"
 #include "SplashMath.h"
 #include "SplashPath.h"
 #include "SplashXPath.h"

 //------------------------------------------------------------------------

 struct SplashXPathPoint
 {
     SplashCoord x, y;
 };

 struct SplashXPathAdjust
 {
     int firstPt, lastPt; // range of points
     bool vert; // vertical or horizontal hint
     SplashCoord x0a, x0b, // hint boundaries
             xma, xmb, x1a, x1b;
     SplashCoord x0, x1, xm; // adjusted coordinates
 };

 //------------------------------------------------------------------------

 // Transform a point from user space to device space.
 inline void SplashXPath::transform(SplashCoord *matrix, SplashCoord xi, SplashCoord yi, SplashCoord *xo, SplashCoord *yo)
 {
     //                          [ m[0] m[1] 0 ]
     // [xo yo 1] = [xi yi 1] *  [ m[2] m[3] 0 ]
     //                          [ m[4] m[5] 1 ]
     *xo = xi * matrix[0] + yi * matrix[2] + matrix[4];
     *yo = xi * matrix[1] + yi * matrix[3] + matrix[5];
 }

 //------------------------------------------------------------------------
 // SplashXPath
 //------------------------------------------------------------------------

 SplashXPath::SplashXPath(SplashPath *path, SplashCoord *matrix, SplashCoord flatness, bool closeSubpaths, bool adjustLines, int linePosI)
 {
     SplashPathHint *hint;
     SplashXPathPoint *pts;
     SplashXPathAdjust *adjusts, *adjust;
     SplashCoord x0, y0, x1, y1, x2, y2, x3, y3, xsp, ysp;
     SplashCoord adj0, adj1;
     int curSubpath, i, j;

     // transform the points
     pts = (SplashXPathPoint *)gmallocn(path->length, sizeof(SplashXPathPoint));
     for (i = 0; i < path->length; ++i) {
         transform(matrix, path->pts[i].x, path->pts[i].y, &pts[i].x, &pts[i].y);
     }

     // set up the stroke adjustment hints
     if (path->hints) {
         adjusts = (SplashXPathAdjust *)gmallocn_checkoverflow(path->hintsLength, sizeof(SplashXPathAdjust));
         if (adjusts) {
             for (i = 0; i < path->hintsLength; ++i) {
                 hint = &path->hints[i];
                 if (hint->ctrl0 + 1 >= path->length || hint->ctrl1 + 1 >= path->length) {
                     gfree(adjusts);
                     adjusts = nullptr;
                     break;
                 }
                 x0 = pts[hint->ctrl0].x;
                 y0 = pts[hint->ctrl0].y;
                 x1 = pts[hint->ctrl0 + 1].x;
                 y1 = pts[hint->ctrl0 + 1].y;
                 x2 = pts[hint->ctrl1].x;
                 y2 = pts[hint->ctrl1].y;
                 x3 = pts[hint->ctrl1 + 1].x;
                 y3 = pts[hint->ctrl1 + 1].y;
                 if (x0 == x1 && x2 == x3) {
                     adjusts[i].vert = true;
                     adj0 = x0;
                     adj1 = x2;
                 } else if (y0 == y1 && y2 == y3) {
                     adjusts[i].vert = false;
                     adj0 = y0;
                     adj1 = y2;
                 } else {
                     gfree(adjusts);
                     adjusts = nullptr;
                     break;
                 }
                 if (adj0 > adj1) {
                     x0 = adj0;
                     adj0 = adj1;
                     adj1 = x0;
                 }
                 adjusts[i].x0a = adj0 - 0.01;
                 adjusts[i].x0b = adj0 + 0.01;
                 adjusts[i].xma = (SplashCoord)0.5 * (adj0 + adj1) - 0.01;
                 adjusts[i].xmb = (SplashCoord)0.5 * (adj0 + adj1) + 0.01;
                 adjusts[i].x1a = adj1 - 0.01;
                 adjusts[i].x1b = adj1 + 0.01;
                 // rounding both edge coordinates can result in lines of
                 // different widths (e.g., adj=10.1, adj1=11.3 --> x0=10, x1=11;
                 // adj0=10.4, adj1=11.6 --> x0=10, x1=12), but it has the
                 // benefit of making adjacent strokes/fills line up without any
                 // gaps between them
                 x0 = splashRound(adj0);
                 x1 = splashRound(adj1);
                 if (x1 == x0) {
                     if (adjustLines) {
                         // the adjustment moves thin lines (clip rectangle with
                         // empty width or height) out of clip area, here we need
                         // a special adjustment:
                         x0 = linePosI;
                         x1 = x0 + 1;
                     } else {
                         x1 = x1 + 1;
                     }
                 }
                 adjusts[i].x0 = (SplashCoord)x0;
                 adjusts[i].x1 = (SplashCoord)x1 - 0.01;
                 adjusts[i].xm = (SplashCoord)0.5 * (adjusts[i].x0 + adjusts[i].x1);
                 adjusts[i].firstPt = hint->firstPt;
                 adjusts[i].lastPt = hint->lastPt;
             }
         }

     } else {
         adjusts = nullptr;
     }

     // perform stroke adjustment
     if (adjusts) {
         for (i = 0, adjust = adjusts; i < path->hintsLength; ++i, ++adjust) {
             for (j = adjust->firstPt; j <= adjust->lastPt; ++j) {
                 strokeAdjust(adjust, &pts[j].x, &pts[j].y);
             }
         }
         gfree(adjusts);
     }

     segs = nullptr;
     length = size = 0;

     x0 = y0 = xsp = ysp = 0; // make gcc happy
     adj0 = adj1 = 0; // make gcc happy
     curSubpath = 0;
     i = 0;
     while (i < path->length) {

         // first point in subpath - skip it
         if (path->flags[i] & splashPathFirst) {
             x0 = pts[i].x;
             y0 = pts[i].y;
             xsp = x0;
             ysp = y0;
             curSubpath = i;
             ++i;

         } else {

             // curve segment
             if (path->flags[i] & splashPathCurve) {
                 x1 = pts[i].x;
                 y1 = pts[i].y;
                 x2 = pts[i + 1].x;
                 y2 = pts[i + 1].y;
                 x3 = pts[i + 2].x;
                 y3 = pts[i + 2].y;
                 addCurve(x0, y0, x1, y1, x2, y2, x3, y3, flatness, (path->flags[i - 1] & splashPathFirst), (path->flags[i + 2] & splashPathLast),
                          !closeSubpaths && (path->flags[i - 1] & splashPathFirst) && !(path->flags[i - 1] & splashPathClosed), !closeSubpaths && (path->flags[i + 2] & splashPathLast) && !(path->flags[i + 2] & splashPathClosed));
                 x0 = x3;
                 y0 = y3;
                 i += 3;

                 // line segment
             } else {
                 x1 = pts[i].x;
                 y1 = pts[i].y;
                 addSegment(x0, y0, x1, y1);
                 x0 = x1;
                 y0 = y1;
                 ++i;
             }

             // close a subpath
             if (closeSubpaths && (path->flags[i - 1] & splashPathLast) && (pts[i - 1].x != pts[curSubpath].x || pts[i - 1].y != pts[curSubpath].y)) {
                 addSegment(x0, y0, xsp, ysp);
             }
         }
     }

     gfree(pts);
 }

 // Apply the stroke adjust hints to point <pt>: (*<xp>, *<yp>).
 void SplashXPath::strokeAdjust(SplashXPathAdjust *adjust, SplashCoord *xp, SplashCoord *yp)
 {
     SplashCoord x, y;

     if (adjust->vert) {
         x = *xp;
         if (x > adjust->x0a && x < adjust->x0b) {
             *xp = adjust->x0;
         } else if (x > adjust->xma && x < adjust->xmb) {
             *xp = adjust->xm;
         } else if (x > adjust->x1a && x < adjust->x1b) {
             *xp = adjust->x1;
         }
     } else {
         y = *yp;
         if (y > adjust->x0a && y < adjust->x0b) {
             *yp = adjust->x0;
         } else if (y > adjust->xma && y < adjust->xmb) {
             *yp = adjust->xm;
         } else if (y > adjust->x1a && y < adjust->x1b) {
             *yp = adjust->x1;
         }
     }
 }

 SplashXPath::~SplashXPath()
 {
     gfree(segs);
 }

 // Add space for <nSegs> more segments
 void SplashXPath::grow(int nSegs)
 {
     if (length + nSegs > size) {
         if (size == 0) {
             size = 32;
         }
         while (size < length + nSegs) {
             size *= 2;
         }
         segs = (SplashXPathSeg *)greallocn_checkoverflow(segs, size, sizeof(SplashXPathSeg));
         if (unlikely(!segs)) {
             length = 0;
             size = 0;
         }
     }
 }

 void SplashXPath::addCurve(SplashCoord x0, SplashCoord y0, SplashCoord x1, SplashCoord y1, SplashCoord x2, SplashCoord y2, SplashCoord x3, SplashCoord y3, SplashCoord flatness, bool first, bool last, bool end0, bool end1)
 {
     SplashCoord *cx = new SplashCoord[(splashMaxCurveSplits + 1) * 3];
     SplashCoord *cy = new SplashCoord[(splashMaxCurveSplits + 1) * 3];
     int *cNext = new int[splashMaxCurveSplits + 1];
     SplashCoord xl0, xl1, xl2, xr0, xr1, xr2, xr3, xx1, xx2, xh;
     SplashCoord yl0, yl1, yl2, yr0, yr1, yr2, yr3, yy1, yy2, yh;
     SplashCoord dx, dy, mx, my, d1, d2, flatness2;
     int p1, p2, p3;

     flatness2 = flatness * flatness;

     // initial segment
     p1 = 0;
     p2 = splashMaxCurveSplits;

     *(cx + p1 * 3 + 0) = x0;
     *(cx + p1 * 3 + 1) = x1;
     *(cx + p1 * 3 + 2) = x2;
     *(cx + p2 * 3 + 0) = x3;

     *(cy + p1 * 3 + 0) = y0;
     *(cy + p1 * 3 + 1) = y1;
     *(cy + p1 * 3 + 2) = y2;
     *(cy + p2 * 3 + 0) = y3;

     *(cNext + p1) = p2;

     while (p1 < splashMaxCurveSplits) {

         // get the next segment
         xl0 = *(cx + p1 * 3 + 0);
         xx1 = *(cx + p1 * 3 + 1);
         xx2 = *(cx + p1 * 3 + 2);

         yl0 = *(cy + p1 * 3 + 0);
         yy1 = *(cy + p1 * 3 + 1);
         yy2 = *(cy + p1 * 3 + 2);

         p2 = *(cNext + p1);

         xr3 = *(cx + p2 * 3 + 0);
         yr3 = *(cy + p2 * 3 + 0);

         // compute the distances from the control points to the
         // midpoint of the straight line (this is a bit of a hack, but
         // it's much faster than computing the actual distances to the
         // line)
         mx = (xl0 + xr3) * 0.5;
         my = (yl0 + yr3) * 0.5;
         dx = xx1 - mx;
         dy = yy1 - my;
         d1 = dx * dx + dy * dy;
         dx = xx2 - mx;
         dy = yy2 - my;
         d2 = dx * dx + dy * dy;

         // if the curve is flat enough, or no more subdivisions are
         // allowed, add the straight line segment
         if (p2 - p1 == 1 || (d1 <= flatness2 && d2 <= flatness2)) {
             addSegment(xl0, yl0, xr3, yr3);
             p1 = p2;

             // otherwise, subdivide the curve
         } else {
             xl1 = (xl0 + xx1) * 0.5;
             yl1 = (yl0 + yy1) * 0.5;
             xh = (xx1 + xx2) * 0.5;
             yh = (yy1 + yy2) * 0.5;
             xl2 = (xl1 + xh) * 0.5;
             yl2 = (yl1 + yh) * 0.5;
             xr2 = (xx2 + xr3) * 0.5;
             yr2 = (yy2 + yr3) * 0.5;
             xr1 = (xh + xr2) * 0.5;
             yr1 = (yh + yr2) * 0.5;
             xr0 = (xl2 + xr1) * 0.5;
             yr0 = (yl2 + yr1) * 0.5;
             // add the new subdivision points
             p3 = (p1 + p2) / 2;

             *(cx + p1 * 3 + 1) = xl1;
             *(cx + p1 * 3 + 2) = xl2;

             *(cy + p1 * 3 + 1) = yl1;
             *(cy + p1 * 3 + 2) = yl2;

             *(cNext + p1) = p3;

             *(cx + p3 * 3 + 0) = xr0;
             *(cx + p3 * 3 + 1) = xr1;
             *(cx + p3 * 3 + 2) = xr2;

             *(cy + p3 * 3 + 0) = yr0;
             *(cy + p3 * 3 + 1) = yr1;
             *(cy + p3 * 3 + 2) = yr2;

             *(cNext + p3) = p2;
         }
     }

     delete[] cx;
     delete[] cy;
     delete[] cNext;
 }

 void SplashXPath::addSegment(SplashCoord x0, SplashCoord y0, SplashCoord x1, SplashCoord y1)
 {
     grow(1);
     if (unlikely(!segs)) {
         return;
     }
     segs[length].x0 = x0;
     segs[length].y0 = y0;
     segs[length].x1 = x1;
     segs[length].y1 = y1;
     segs[length].flags = 0;
     if (y1 == y0) {
         segs[length].dxdy = segs[length].dydx = 0;
         segs[length].flags |= splashXPathHoriz;
         if (x1 == x0) {
             segs[length].flags |= splashXPathVert;
         }
     } else if (x1 == x0) {
         segs[length].dxdy = segs[length].dydx = 0;
         segs[length].flags |= splashXPathVert;
     } else {
         segs[length].dxdy = (x1 - x0) / (y1 - y0);
         segs[length].dydx = (SplashCoord)1 / segs[length].dxdy;
     }
     if (y0 > y1) {
         segs[length].flags |= splashXPathFlip;
     }
     ++length;
 }

 struct cmpXPathSegsFunctor
 {
     bool operator()(const SplashXPathSeg &seg0, const SplashXPathSeg &seg1)
     {
         SplashCoord x0, y0, x1, y1;

         if (seg0.flags & splashXPathFlip) {
             x0 = seg0.x1;
             y0 = seg0.y1;
         } else {
             x0 = seg0.x0;
             y0 = seg0.y0;
         }
         if (seg1.flags & splashXPathFlip) {
             x1 = seg1.x1;
             y1 = seg1.y1;
         } else {
             x1 = seg1.x0;
             y1 = seg1.y0;
         }
         return (y0 != y1) ? (y0 < y1) : (x0 < x1);
     }
 };

 void SplashXPath::aaScale()
 {
     SplashXPathSeg *seg;
     int i;

     for (i = 0, seg = segs; i < length; ++i, ++seg) {
         seg->x0 *= splashAASize;
         seg->y0 *= splashAASize;
         seg->x1 *= splashAASize;
         seg->y1 *= splashAASize;
     }
 }

 void SplashXPath::sort()
 {
     std::sort(segs, segs + length, cmpXPathSegsFunctor());
 }
	//========================================================================
	//
	// SplashXPath.cc
	//
	//========================================================================

	//========================================================================
	//
	// Modified under the Poppler project - http://poppler.freedesktop.org
	//
	// All changes made under the Poppler project to this file are licensed
	// under GPL version 2 or later
	//
	// Copyright (C) 2010 Paweł Wiejacha <pawel.wiejacha@gmail.com>
	// Copyright (C) 2010, 2011, 2018, 2019, 2021 Albert Astals Cid <aacid@kde.org>
	// Copyright (C) 2013 Thomas Freitag <Thomas.Freitag@alfa.de>
	// Copyright (C) 2017 Adrian Johnson <ajohnson@redneon.com>
	//
	// To see a description of the changes please see the Changelog file that
	// came with your tarball or type make ChangeLog if you are building from git
	//
	//========================================================================

	#include <config.h>

	#include <cstdlib>
	#include <cstring>
	#include <algorithm>
	#include "goo/gmem.h"
	#include "goo/GooLikely.h"
	#include "SplashMath.h"
	#include "SplashPath.h"
	#include "SplashXPath.h"

	//------------------------------------------------------------------------

	struct SplashXPathPoint
	{
	SplashCoord x, y;
	};

	struct SplashXPathAdjust
	{
	int firstPt, lastPt; // range of points
	bool vert; // vertical or horizontal hint
	SplashCoord x0a, x0b, // hint boundaries
	xma, xmb, x1a, x1b;
	SplashCoord x0, x1, xm; // adjusted coordinates
	};

	//------------------------------------------------------------------------

	// Transform a point from user space to device space.
	inline void SplashXPath::transform(SplashCoord matrix, SplashCoord xi, SplashCoord yi, SplashCoord xo, SplashCoord *yo)
	{
	// [ m[0] m[1] 0 ]
	// [xo yo 1] = [xi yi 1] * [ m[2] m[3] 0 ]
	// [ m[4] m[5] 1 ]
	xo = xi matrix[0] + yi * matrix[2] + matrix[4];
	yo = xi matrix[1] + yi * matrix[3] + matrix[5];
	}

	//------------------------------------------------------------------------
	// SplashXPath
	//------------------------------------------------------------------------

	SplashXPath::SplashXPath(SplashPath path, SplashCoord matrix, SplashCoord flatness, bool closeSubpaths, bool adjustLines, int linePosI)
	{
	SplashPathHint *hint;
	SplashXPathPoint *pts;
	SplashXPathAdjust adjusts, adjust;
	SplashCoord x0, y0, x1, y1, x2, y2, x3, y3, xsp, ysp;
	SplashCoord adj0, adj1;
	int curSubpath, i, j;

	// transform the points
	pts = (SplashXPathPoint *)gmallocn(path->length, sizeof(SplashXPathPoint));
	for (i = 0; i < path->length; ++i) {
	transform(matrix, path->pts[i].x, path->pts[i].y, &pts[i].x, &pts[i].y);
	}

	// set up the stroke adjustment hints
	if (path->hints) {
	adjusts = (SplashXPathAdjust *)gmallocn_checkoverflow(path->hintsLength, sizeof(SplashXPathAdjust));
	if (adjusts) {
	for (i = 0; i < path->hintsLength; ++i) {
	hint = &path->hints[i];
	if (hint->ctrl0 + 1 >= path->length \|\| hint->ctrl1 + 1 >= path->length) {
	gfree(adjusts);
	adjusts = nullptr;
	break;
	}
	x0 = pts[hint->ctrl0].x;
	y0 = pts[hint->ctrl0].y;
	x1 = pts[hint->ctrl0 + 1].x;
	y1 = pts[hint->ctrl0 + 1].y;
	x2 = pts[hint->ctrl1].x;
	y2 = pts[hint->ctrl1].y;
	x3 = pts[hint->ctrl1 + 1].x;
	y3 = pts[hint->ctrl1 + 1].y;
	if (x0 == x1 && x2 == x3) {
	adjusts[i].vert = true;
	adj0 = x0;
	adj1 = x2;
	} else if (y0 == y1 && y2 == y3) {
	adjusts[i].vert = false;
	adj0 = y0;
	adj1 = y2;
	} else {
	gfree(adjusts);
	adjusts = nullptr;
	break;
	}
	if (adj0 > adj1) {
	x0 = adj0;
	adj0 = adj1;
	adj1 = x0;
	}
	adjusts[i].x0a = adj0 - 0.01;
	adjusts[i].x0b = adj0 + 0.01;
	adjusts[i].xma = (SplashCoord)0.5 * (adj0 + adj1) - 0.01;
	adjusts[i].xmb = (SplashCoord)0.5 * (adj0 + adj1) + 0.01;
	adjusts[i].x1a = adj1 - 0.01;
	adjusts[i].x1b = adj1 + 0.01;
	// rounding both edge coordinates can result in lines of
	// different widths (e.g., adj=10.1, adj1=11.3 --> x0=10, x1=11;
	// adj0=10.4, adj1=11.6 --> x0=10, x1=12), but it has the
	// benefit of making adjacent strokes/fills line up without any
	// gaps between them
	x0 = splashRound(adj0);
	x1 = splashRound(adj1);
	if (x1 == x0) {
	if (adjustLines) {
	// the adjustment moves thin lines (clip rectangle with
	// empty width or height) out of clip area, here we need
	// a special adjustment:
	x0 = linePosI;
	x1 = x0 + 1;
	} else {
	x1 = x1 + 1;
	}
	}
	adjusts[i].x0 = (SplashCoord)x0;
	adjusts[i].x1 = (SplashCoord)x1 - 0.01;
	adjusts[i].xm = (SplashCoord)0.5 * (adjusts[i].x0 + adjusts[i].x1);
	adjusts[i].firstPt = hint->firstPt;
	adjusts[i].lastPt = hint->lastPt;
	}
	}

	} else {
	adjusts = nullptr;
	}

	// perform stroke adjustment
	if (adjusts) {
	for (i = 0, adjust = adjusts; i < path->hintsLength; ++i, ++adjust) {
	for (j = adjust->firstPt; j <= adjust->lastPt; ++j) {
	strokeAdjust(adjust, &pts[j].x, &pts[j].y);
	}
	}
	gfree(adjusts);
	}

	segs = nullptr;
	length = size = 0;

	x0 = y0 = xsp = ysp = 0; // make gcc happy
	adj0 = adj1 = 0; // make gcc happy
	curSubpath = 0;
	i = 0;
	while (i < path->length) {

	// first point in subpath - skip it
	if (path->flags[i] & splashPathFirst) {
	x0 = pts[i].x;
	y0 = pts[i].y;
	xsp = x0;
	ysp = y0;
	curSubpath = i;
	++i;

	} else {

	// curve segment
	if (path->flags[i] & splashPathCurve) {
	x1 = pts[i].x;
	y1 = pts[i].y;
	x2 = pts[i + 1].x;
	y2 = pts[i + 1].y;
	x3 = pts[i + 2].x;
	y3 = pts[i + 2].y;
	addCurve(x0, y0, x1, y1, x2, y2, x3, y3, flatness, (path->flags[i - 1] & splashPathFirst), (path->flags[i + 2] & splashPathLast),
	!closeSubpaths && (path->flags[i - 1] & splashPathFirst) && !(path->flags[i - 1] & splashPathClosed), !closeSubpaths && (path->flags[i + 2] & splashPathLast) && !(path->flags[i + 2] & splashPathClosed));
	x0 = x3;
	y0 = y3;
	i += 3;

	// line segment
	} else {
	x1 = pts[i].x;
	y1 = pts[i].y;
	addSegment(x0, y0, x1, y1);
	x0 = x1;
	y0 = y1;
	++i;
	}

	// close a subpath
	if (closeSubpaths && (path->flags[i - 1] & splashPathLast) && (pts[i - 1].x != pts[curSubpath].x \|\| pts[i - 1].y != pts[curSubpath].y)) {
	addSegment(x0, y0, xsp, ysp);
	}
	}
	}

	gfree(pts);
	}

	// Apply the stroke adjust hints to point <pt>: (<xp>, <yp>).
	void SplashXPath::strokeAdjust(SplashXPathAdjust adjust, SplashCoord xp, SplashCoord *yp)
	{
	SplashCoord x, y;

	if (adjust->vert) {
	x = *xp;
	if (x > adjust->x0a && x < adjust->x0b) {
	*xp = adjust->x0;
	} else if (x > adjust->xma && x < adjust->xmb) {
	*xp = adjust->xm;
	} else if (x > adjust->x1a && x < adjust->x1b) {
	*xp = adjust->x1;
	}
	} else {
	y = *yp;
	if (y > adjust->x0a && y < adjust->x0b) {
	*yp = adjust->x0;
	} else if (y > adjust->xma && y < adjust->xmb) {
	*yp = adjust->xm;
	} else if (y > adjust->x1a && y < adjust->x1b) {
	*yp = adjust->x1;
	}
	}
	}

	SplashXPath::~SplashXPath()
	{
	gfree(segs);
	}

	// Add space for <nSegs> more segments
	void SplashXPath::grow(int nSegs)
	{
	if (length + nSegs > size) {
	if (size == 0) {
	size = 32;
	}
	while (size < length + nSegs) {
	size *= 2;
	}
	segs = (SplashXPathSeg *)greallocn_checkoverflow(segs, size, sizeof(SplashXPathSeg));
	if (unlikely(!segs)) {
	length = 0;
	size = 0;
	}
	}
	}

	void SplashXPath::addCurve(SplashCoord x0, SplashCoord y0, SplashCoord x1, SplashCoord y1, SplashCoord x2, SplashCoord y2, SplashCoord x3, SplashCoord y3, SplashCoord flatness, bool first, bool last, bool end0, bool end1)
	{
	SplashCoord cx = new SplashCoord[(splashMaxCurveSplits + 1) 3];
	SplashCoord cy = new SplashCoord[(splashMaxCurveSplits + 1) 3];
	int *cNext = new int[splashMaxCurveSplits + 1];
	SplashCoord xl0, xl1, xl2, xr0, xr1, xr2, xr3, xx1, xx2, xh;
	SplashCoord yl0, yl1, yl2, yr0, yr1, yr2, yr3, yy1, yy2, yh;
	SplashCoord dx, dy, mx, my, d1, d2, flatness2;
	int p1, p2, p3;

	flatness2 = flatness * flatness;

	// initial segment
	p1 = 0;
	p2 = splashMaxCurveSplits;

	(cx + p1 3 + 0) = x0;
	(cx + p1 3 + 1) = x1;
	(cx + p1 3 + 2) = x2;
	(cx + p2 3 + 0) = x3;

	(cy + p1 3 + 0) = y0;
	(cy + p1 3 + 1) = y1;
	(cy + p1 3 + 2) = y2;
	(cy + p2 3 + 0) = y3;

	*(cNext + p1) = p2;

	while (p1 < splashMaxCurveSplits) {

	// get the next segment
	xl0 = (cx + p1 3 + 0);
	xx1 = (cx + p1 3 + 1);
	xx2 = (cx + p1 3 + 2);

	yl0 = (cy + p1 3 + 0);
	yy1 = (cy + p1 3 + 1);
	yy2 = (cy + p1 3 + 2);

	p2 = *(cNext + p1);

	xr3 = (cx + p2 3 + 0);
	yr3 = (cy + p2 3 + 0);

	// compute the distances from the control points to the
	// midpoint of the straight line (this is a bit of a hack, but
	// it's much faster than computing the actual distances to the
	// line)
	mx = (xl0 + xr3) * 0.5;
	my = (yl0 + yr3) * 0.5;
	dx = xx1 - mx;
	dy = yy1 - my;
	d1 = dx * dx + dy * dy;
	dx = xx2 - mx;
	dy = yy2 - my;
	d2 = dx * dx + dy * dy;

	// if the curve is flat enough, or no more subdivisions are
	// allowed, add the straight line segment
	if (p2 - p1 == 1 \|\| (d1 <= flatness2 && d2 <= flatness2)) {
	addSegment(xl0, yl0, xr3, yr3);
	p1 = p2;

	// otherwise, subdivide the curve
	} else {
	xl1 = (xl0 + xx1) * 0.5;
	yl1 = (yl0 + yy1) * 0.5;
	xh = (xx1 + xx2) * 0.5;
	yh = (yy1 + yy2) * 0.5;
	xl2 = (xl1 + xh) * 0.5;
	yl2 = (yl1 + yh) * 0.5;
	xr2 = (xx2 + xr3) * 0.5;
	yr2 = (yy2 + yr3) * 0.5;
	xr1 = (xh + xr2) * 0.5;
	yr1 = (yh + yr2) * 0.5;
	xr0 = (xl2 + xr1) * 0.5;
	yr0 = (yl2 + yr1) * 0.5;
	// add the new subdivision points
	p3 = (p1 + p2) / 2;

	(cx + p1 3 + 1) = xl1;
	(cx + p1 3 + 2) = xl2;

	(cy + p1 3 + 1) = yl1;
	(cy + p1 3 + 2) = yl2;

	*(cNext + p1) = p3;

	(cx + p3 3 + 0) = xr0;
	(cx + p3 3 + 1) = xr1;
	(cx + p3 3 + 2) = xr2;

	(cy + p3 3 + 0) = yr0;
	(cy + p3 3 + 1) = yr1;
	(cy + p3 3 + 2) = yr2;

	*(cNext + p3) = p2;
	}
	}

	delete[] cx;
	delete[] cy;
	delete[] cNext;
	}

	void SplashXPath::addSegment(SplashCoord x0, SplashCoord y0, SplashCoord x1, SplashCoord y1)
	{
	grow(1);
	if (unlikely(!segs)) {
	return;
	}
	segs[length].x0 = x0;
	segs[length].y0 = y0;
	segs[length].x1 = x1;
	segs[length].y1 = y1;
	segs[length].flags = 0;
	if (y1 == y0) {
	segs[length].dxdy = segs[length].dydx = 0;
	segs[length].flags \|= splashXPathHoriz;
	if (x1 == x0) {
	segs[length].flags \|= splashXPathVert;
	}
	} else if (x1 == x0) {
	segs[length].dxdy = segs[length].dydx = 0;
	segs[length].flags \|= splashXPathVert;
	} else {
	segs[length].dxdy = (x1 - x0) / (y1 - y0);
	segs[length].dydx = (SplashCoord)1 / segs[length].dxdy;
	}
	if (y0 > y1) {
	segs[length].flags \|= splashXPathFlip;
	}
	++length;
	}

	struct cmpXPathSegsFunctor
	{
	bool operator()(const SplashXPathSeg &seg0, const SplashXPathSeg &seg1)
	{
	SplashCoord x0, y0, x1, y1;

	if (seg0.flags & splashXPathFlip) {
	x0 = seg0.x1;
	y0 = seg0.y1;
	} else {
	x0 = seg0.x0;
	y0 = seg0.y0;
	}
	if (seg1.flags & splashXPathFlip) {
	x1 = seg1.x1;
	y1 = seg1.y1;
	} else {
	x1 = seg1.x0;
	y1 = seg1.y0;
	}
	return (y0 != y1) ? (y0 < y1) : (x0 < x1);
	}
	};

	void SplashXPath::aaScale()
	{
	SplashXPathSeg *seg;
	int i;

	for (i = 0, seg = segs; i < length; ++i, ++seg) {
	seg->x0 *= splashAASize;
	seg->y0 *= splashAASize;
	seg->x1 *= splashAASize;
	seg->y1 *= splashAASize;
	}
	}

	void SplashXPath::sort()
	{
	std::sort(segs, segs + length, cmpXPathSegsFunctor());
	}