src/animator/SkParseSVGPath.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 <ctype.h>
 #include "SkDrawPath.h"
 #include "SkParse.h"
 #include "SkPoint.h"
 #include "SkUtils.h"
 #define QUADRATIC_APPROXIMATION 1

 #if QUADRATIC_APPROXIMATION
 ////////////////////////////////////////////////////////////////////////////////////
 //functions to approximate a cubic using two quadratics

 //      midPt sets the first argument to be the midpoint of the other two
 //      it is used by quadApprox
 static inline void midPt(SkPoint& dest,const SkPoint& a,const SkPoint& b)
 {
     dest.set(SkScalarAve(a.fX, b.fX),SkScalarAve(a.fY, b.fY));
 }
 //      quadApprox - makes an approximation, which we hope is faster
 static void quadApprox(SkPath &fPath, const SkPoint &p0, const SkPoint &p1, const SkPoint &p2)
 {
     //divide the cubic up into two cubics, then convert them into quadratics
     //define our points
     SkPoint c,j,k,l,m,n,o,p,q, mid;
     fPath.getLastPt(&c);
     midPt(j, p0, c);
     midPt(k, p0, p1);
     midPt(l, p1, p2);
     midPt(o, j, k);
     midPt(p, k, l);
     midPt(q, o, p);
     //compute the first half
     m.set(SkScalarHalf(3*j.fX - c.fX), SkScalarHalf(3*j.fY - c.fY));
     n.set(SkScalarHalf(3*o.fX -q.fX), SkScalarHalf(3*o.fY - q.fY));
     midPt(mid,m,n);
     fPath.quadTo(mid,q);
     c = q;
     //compute the second half
     m.set(SkScalarHalf(3*p.fX - c.fX), SkScalarHalf(3*p.fY - c.fY));
     n.set(SkScalarHalf(3*l.fX -p2.fX),SkScalarHalf(3*l.fY -p2.fY));
     midPt(mid,m,n);
     fPath.quadTo(mid,p2);
 }
 #endif


 static inline bool is_between(int c, int min, int max)
 {
     return (unsigned)(c - min) <= (unsigned)(max - min);
 }

 static inline bool is_ws(int c)
 {
     return is_between(c, 1, 32);
 }

 static inline bool is_digit(int c)
 {
     return is_between(c, '0', '9');
 }

 static inline bool is_sep(int c)
 {
     return is_ws(c) || c == ',';
 }

 static const char* skip_ws(const char str[])
 {
     SkASSERT(str);
     while (is_ws(*str))
         str++;
     return str;
 }

 static const char* skip_sep(const char str[])
 {
     SkASSERT(str);
     while (is_sep(*str))
         str++;
     return str;
 }

 static const char* find_points(const char str[], SkPoint value[], int count,
      bool isRelative, SkPoint* relative)
 {
     str = SkParse::FindScalars(str, &value[0].fX, count * 2);
     if (isRelative) {
         for (int index = 0; index < count; index++) {
             value[index].fX += relative->fX;
             value[index].fY += relative->fY;
         }
     }
     return str;
 }

 static const char* find_scalar(const char str[], SkScalar* value,
     bool isRelative, SkScalar relative)
 {
     str = SkParse::FindScalar(str, value);
     if (isRelative)
         *value += relative;
     return str;
 }

 void SkDrawPath::parseSVG() {
     fPath.reset();
     const char* data = d.c_str();
     SkPoint f = {0, 0};
     SkPoint c = {0, 0};
     SkPoint lastc = {0, 0};
     SkPoint points[3];
     char op = '\0';
     char previousOp = '\0';
     bool relative = false;
     do {
         data = skip_ws(data);
         if (data[0] == '\0')
             break;
         char ch = data[0];
         if (is_digit(ch) || ch == '-' || ch == '+') {
             if (op == '\0')
                 return;
         }
         else {
             op = ch;
             relative = false;
             if (islower(op)) {
                 op = (char) toupper(op);
                 relative = true;
             }
             data++;
             data = skip_sep(data);
         }
         switch (op) {
             case 'M':
                 data = find_points(data, points, 1, relative, &c);
                 fPath.moveTo(points[0]);
                 op = 'L';
                 c = points[0];
                 break;
             case 'L':
                 data = find_points(data, points, 1, relative, &c);
                 fPath.lineTo(points[0]);
                 c = points[0];
                 break;
             case 'H': {
                 SkScalar x;
                 data = find_scalar(data, &x, relative, c.fX);
                 fPath.lineTo(x, c.fY);
                 c.fX = x;
             }
                 break;
             case 'V': {
                 SkScalar y;
                 data = find_scalar(data, &y, relative, c.fY);
                 fPath.lineTo(c.fX, y);
                 c.fY = y;
             }
                 break;
             case 'C':
                 data = find_points(data, points, 3, relative, &c);
                 goto cubicCommon;
             case 'S':
                 data = find_points(data, &points[1], 2, relative, &c);
                 points[0] = c;
                 if (previousOp == 'C' || previousOp == 'S') {
                     points[0].fX -= lastc.fX - c.fX;
                     points[0].fY -= lastc.fY - c.fY;
                 }
             cubicCommon:
     //          if (data[0] == '\0')
     //              return;
 #if QUADRATIC_APPROXIMATION
                     quadApprox(fPath, points[0], points[1], points[2]);
 #else   //this way just does a boring, slow old cubic
                     fPath.cubicTo(points[0], points[1], points[2]);
 #endif
         //if we are using the quadApprox, lastc is what it would have been if we had used
         //cubicTo
                     lastc = points[1];
                     c = points[2];
                 break;
             case 'Q':  // Quadratic Bezier Curve
                 data = find_points(data, points, 2, relative, &c);
                 goto quadraticCommon;
             case 'T':
                 data = find_points(data, &points[1], 1, relative, &c);
                 points[0] = points[1];
                 if (previousOp == 'Q' || previousOp == 'T') {
                     points[0].fX = c.fX * 2 - lastc.fX;
                     points[0].fY = c.fY * 2 - lastc.fY;
                 }
             quadraticCommon:
                 fPath.quadTo(points[0], points[1]);
                 lastc = points[0];
                 c = points[1];
                 break;
             case 'Z':
                 fPath.close();
 #if 0   // !!! still a bug?
                 if (fPath.isEmpty() && (f.fX != 0 || f.fY != 0)) {
                     c.fX -= SkScalar.Epsilon;   // !!! enough?
                     fPath.moveTo(c);
                     fPath.lineTo(f);
                     fPath.close();
                 }
 #endif
                 c = f;
                 op = '\0';
                 break;
             case '~': {
                 SkPoint args[2];
                 data = find_points(data, args, 2, false, NULL);
                 fPath.moveTo(args[0].fX, args[0].fY);
                 fPath.lineTo(args[1].fX, args[1].fY);
             }
                 break;
             default:
                 SkASSERT(0);
                 return;
         }
         if (previousOp == 0)
             f = c;
         previousOp = op;
     } while (data[0] > 0);
 }

	/*
	* 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 <ctype.h>
	#include "SkDrawPath.h"
	#include "SkParse.h"
	#include "SkPoint.h"
	#include "SkUtils.h"
	#define QUADRATIC_APPROXIMATION 1

	#if QUADRATIC_APPROXIMATION
	////////////////////////////////////////////////////////////////////////////////////
	//functions to approximate a cubic using two quadratics

	// midPt sets the first argument to be the midpoint of the other two
	// it is used by quadApprox
	static inline void midPt(SkPoint& dest,const SkPoint& a,const SkPoint& b)
	{
	dest.set(SkScalarAve(a.fX, b.fX),SkScalarAve(a.fY, b.fY));
	}
	// quadApprox - makes an approximation, which we hope is faster
	static void quadApprox(SkPath &fPath, const SkPoint &p0, const SkPoint &p1, const SkPoint &p2)
	{
	//divide the cubic up into two cubics, then convert them into quadratics
	//define our points
	SkPoint c,j,k,l,m,n,o,p,q, mid;
	fPath.getLastPt(&c);
	midPt(j, p0, c);
	midPt(k, p0, p1);
	midPt(l, p1, p2);
	midPt(o, j, k);
	midPt(p, k, l);
	midPt(q, o, p);
	//compute the first half
	m.set(SkScalarHalf(3j.fX - c.fX), SkScalarHalf(3j.fY - c.fY));
	n.set(SkScalarHalf(3o.fX -q.fX), SkScalarHalf(3o.fY - q.fY));
	midPt(mid,m,n);
	fPath.quadTo(mid,q);
	c = q;
	//compute the second half
	m.set(SkScalarHalf(3p.fX - c.fX), SkScalarHalf(3p.fY - c.fY));
	n.set(SkScalarHalf(3l.fX -p2.fX),SkScalarHalf(3l.fY -p2.fY));
	midPt(mid,m,n);
	fPath.quadTo(mid,p2);
	}
	#endif


	static inline bool is_between(int c, int min, int max)
	{
	return (unsigned)(c - min) <= (unsigned)(max - min);
	}

	static inline bool is_ws(int c)
	{
	return is_between(c, 1, 32);
	}

	static inline bool is_digit(int c)
	{
	return is_between(c, '0', '9');
	}

	static inline bool is_sep(int c)
	{
	return is_ws(c) \|\| c == ',';
	}

	static const char* skip_ws(const char str[])
	{
	SkASSERT(str);
	while (is_ws(*str))
	str++;
	return str;
	}

	static const char* skip_sep(const char str[])
	{
	SkASSERT(str);
	while (is_sep(*str))
	str++;
	return str;
	}

	static const char* find_points(const char str[], SkPoint value[], int count,
	bool isRelative, SkPoint* relative)
	{
	str = SkParse::FindScalars(str, &value[0].fX, count * 2);
	if (isRelative) {
	for (int index = 0; index < count; index++) {
	value[index].fX += relative->fX;
	value[index].fY += relative->fY;
	}
	}
	return str;
	}

	static const char* find_scalar(const char str[], SkScalar* value,
	bool isRelative, SkScalar relative)
	{
	str = SkParse::FindScalar(str, value);
	if (isRelative)
	*value += relative;
	return str;
	}

	void SkDrawPath::parseSVG() {
	fPath.reset();
	const char* data = d.c_str();
	SkPoint f = {0, 0};
	SkPoint c = {0, 0};
	SkPoint lastc = {0, 0};
	SkPoint points[3];
	char op = '\0';
	char previousOp = '\0';
	bool relative = false;
	do {
	data = skip_ws(data);
	if (data[0] == '\0')
	break;
	char ch = data[0];
	if (is_digit(ch) \|\| ch == '-' \|\| ch == '+') {
	if (op == '\0')
	return;
	}
	else {
	op = ch;
	relative = false;
	if (islower(op)) {
	op = (char) toupper(op);
	relative = true;
	}
	data++;
	data = skip_sep(data);
	}
	switch (op) {
	case 'M':
	data = find_points(data, points, 1, relative, &c);
	fPath.moveTo(points[0]);
	op = 'L';
	c = points[0];
	break;
	case 'L':
	data = find_points(data, points, 1, relative, &c);
	fPath.lineTo(points[0]);
	c = points[0];
	break;
	case 'H': {
	SkScalar x;
	data = find_scalar(data, &x, relative, c.fX);
	fPath.lineTo(x, c.fY);
	c.fX = x;
	}
	break;
	case 'V': {
	SkScalar y;
	data = find_scalar(data, &y, relative, c.fY);
	fPath.lineTo(c.fX, y);
	c.fY = y;
	}
	break;
	case 'C':
	data = find_points(data, points, 3, relative, &c);
	goto cubicCommon;
	case 'S':
	data = find_points(data, &points[1], 2, relative, &c);
	points[0] = c;
	if (previousOp == 'C' \|\| previousOp == 'S') {
	points[0].fX -= lastc.fX - c.fX;
	points[0].fY -= lastc.fY - c.fY;
	}
	cubicCommon:
	// if (data[0] == '\0')
	// return;
	#if QUADRATIC_APPROXIMATION
	quadApprox(fPath, points[0], points[1], points[2]);
	#else //this way just does a boring, slow old cubic
	fPath.cubicTo(points[0], points[1], points[2]);
	#endif
	//if we are using the quadApprox, lastc is what it would have been if we had used
	//cubicTo
	lastc = points[1];
	c = points[2];
	break;
	case 'Q': // Quadratic Bezier Curve
	data = find_points(data, points, 2, relative, &c);
	goto quadraticCommon;
	case 'T':
	data = find_points(data, &points[1], 1, relative, &c);
	points[0] = points[1];
	if (previousOp == 'Q' \|\| previousOp == 'T') {
	points[0].fX = c.fX * 2 - lastc.fX;
	points[0].fY = c.fY * 2 - lastc.fY;
	}
	quadraticCommon:
	fPath.quadTo(points[0], points[1]);
	lastc = points[0];
	c = points[1];
	break;
	case 'Z':
	fPath.close();
	#if 0 // !!! still a bug?
	if (fPath.isEmpty() && (f.fX != 0 \|\| f.fY != 0)) {
	c.fX -= SkScalar.Epsilon; // !!! enough?
	fPath.moveTo(c);
	fPath.lineTo(f);
	fPath.close();
	}
	#endif
	c = f;
	op = '\0';
	break;
	case '~': {
	SkPoint args[2];
	data = find_points(data, args, 2, false, NULL);
	fPath.moveTo(args[0].fX, args[0].fY);
	fPath.lineTo(args[1].fX, args[1].fY);
	}
	break;
	default:
	SkASSERT(0);
	return;
	}
	if (previousOp == 0)
	f = c;
	previousOp = op;
	} while (data[0] > 0);
	}