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/* This file is part of the KDE project
Copyright (C) 2002, 2003 The Karbon Developers
2006 Alexander Kellett <lypanov@kde.org>
2006, 2007 Rob Buis <buis@kde.org>
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public
License as published by the Free Software Foundation; either
version 2 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Library General Public License for more details.
You should have received a copy of the GNU Library General Public License
along with this library; see the file COPYING.LIB. If not, write to
the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA.
*/
#include "config.h"
#if ENABLE(SVG)
#include "SVGParserUtilities.h"
#include "FloatConversion.h"
#include "PlatformString.h"
#include <math.h>
#include <wtf/MathExtras.h>
namespace WebCore {
bool parseNumber(const UChar*& ptr, const UChar* end, double& number, bool skip)
{
int integer, exponent;
double decimal, frac;
int sign, expsign;
const UChar* start = ptr;
exponent = 0;
integer = 0;
frac = 1.0;
decimal = 0;
sign = 1;
expsign = 1;
// read the sign
if (ptr < end && *ptr == '+')
ptr++;
else if (ptr < end && *ptr == '-') {
ptr++;
sign = -1;
}
// read the integer part
while (ptr < end && *ptr >= '0' && *ptr <= '9')
integer = (integer * 10) + *(ptr++) - '0';
if (ptr < end && *ptr == '.') { // read the decimals
ptr++;
while(ptr < end && *ptr >= '0' && *ptr <= '9')
decimal += (*(ptr++) - '0') * (frac *= 0.1);
}
if (ptr < end && (*ptr == 'e' || *ptr == 'E')) { // read the exponent part
ptr++;
// read the sign of the exponent
if (ptr < end && *ptr == '+')
ptr++;
else if (ptr < end && *ptr == '-') {
ptr++;
expsign = -1;
}
while (ptr < end && *ptr >= '0' && *ptr <= '9') {
exponent *= 10;
exponent += *ptr - '0';
ptr++;
}
}
number = integer + decimal;
number *= sign * pow(10.0, expsign * exponent);
if (start == ptr)
return false;
if (skip)
skipOptionalSpacesOrDelimiter(ptr, end);
return true;
}
bool parseNumberOptionalNumber(const String& s, double& x, double& y)
{
if (s.isEmpty())
return false;
const UChar* cur = s.characters();
const UChar* end = cur + s.length();
if (!parseNumber(cur, end, x))
return false;
if (cur == end)
y = x;
else if (!parseNumber(cur, end, y, false))
return false;
return cur == end;
}
bool SVGPolyParser::parsePoints(const String& s) const
{
if (s.isEmpty())
return true;
const UChar* cur = s.characters();
const UChar* end = cur + s.length();
skipOptionalSpaces(cur, end);
bool delimParsed = false;
int segmentNum = 0;
while (cur < end) {
delimParsed = false;
double xPos = 0;
if (!parseNumber(cur, end, xPos))
return false;
double yPos = 0;
if (!parseNumber(cur, end, yPos, false))
return false;
skipOptionalSpaces(cur, end);
if (cur < end && *cur == ',') {
delimParsed = true;
cur++;
}
skipOptionalSpaces(cur, end);
svgPolyTo(xPos, yPos, segmentNum++);
}
return cur == end && !delimParsed;
}
bool SVGPathParser::parseSVG(const String& s, bool process)
{
if (s.isEmpty())
return false;
const UChar* ptr = s.characters();
const UChar* end = ptr + s.length();
double contrlx, contrly, curx, cury, subpathx, subpathy, tox, toy, x1, y1, x2, y2, xc, yc;
double px1, py1, px2, py2, px3, py3;
bool closed = true;
if (!skipOptionalSpaces(ptr, end)) // skip any leading spaces
return false;
char command = *(ptr++), lastCommand = ' ';
if (command != 'm' && command != 'M') // path must start with moveto
return false;
subpathx = subpathy = curx = cury = contrlx = contrly = 0.0;
while (1) {
skipOptionalSpaces(ptr, end); // skip spaces between command and first coord
bool relative = false;
switch(command)
{
case 'm':
relative = true;
case 'M':
{
if (!parseNumber(ptr, end, tox) || !parseNumber(ptr, end, toy))
return false;
if (process) {
subpathx = curx = relative ? curx + tox : tox;
subpathy = cury = relative ? cury + toy : toy;
svgMoveTo(narrowPrecisionToFloat(curx), narrowPrecisionToFloat(cury), closed);
} else
svgMoveTo(narrowPrecisionToFloat(tox), narrowPrecisionToFloat(toy), closed, !relative);
closed = false;
break;
}
case 'l':
relative = true;
case 'L':
{
if (!parseNumber(ptr, end, tox) || !parseNumber(ptr, end, toy))
return false;
if (process) {
curx = relative ? curx + tox : tox;
cury = relative ? cury + toy : toy;
svgLineTo(narrowPrecisionToFloat(curx), narrowPrecisionToFloat(cury));
}
else
svgLineTo(narrowPrecisionToFloat(tox), narrowPrecisionToFloat(toy), !relative);
break;
}
case 'h':
{
if (!parseNumber(ptr, end, tox))
return false;
if (process) {
curx = curx + tox;
svgLineTo(narrowPrecisionToFloat(curx), narrowPrecisionToFloat(cury));
}
else
svgLineToHorizontal(narrowPrecisionToFloat(tox), false);
break;
}
case 'H':
{
if (!parseNumber(ptr, end, tox))
return false;
if (process) {
curx = tox;
svgLineTo(narrowPrecisionToFloat(curx), narrowPrecisionToFloat(cury));
}
else
svgLineToHorizontal(narrowPrecisionToFloat(tox));
break;
}
case 'v':
{
if (!parseNumber(ptr, end, toy))
return false;
if (process) {
cury = cury + toy;
svgLineTo(narrowPrecisionToFloat(curx), narrowPrecisionToFloat(cury));
}
else
svgLineToVertical(narrowPrecisionToFloat(toy), false);
break;
}
case 'V':
{
if (!parseNumber(ptr, end, toy))
return false;
if (process) {
cury = toy;
svgLineTo(narrowPrecisionToFloat(curx), narrowPrecisionToFloat(cury));
}
else
svgLineToVertical(narrowPrecisionToFloat(toy));
break;
}
case 'z':
case 'Z':
{
// reset curx, cury for next path
if (process) {
curx = subpathx;
cury = subpathy;
}
closed = true;
svgClosePath();
break;
}
case 'c':
relative = true;
case 'C':
{
if (!parseNumber(ptr, end, x1) || !parseNumber(ptr, end, y1) ||
!parseNumber(ptr, end, x2) || !parseNumber(ptr, end, y2) ||
!parseNumber(ptr, end, tox) || !parseNumber(ptr, end, toy))
return false;
if (process) {
px1 = relative ? curx + x1 : x1;
py1 = relative ? cury + y1 : y1;
px2 = relative ? curx + x2 : x2;
py2 = relative ? cury + y2 : y2;
px3 = relative ? curx + tox : tox;
py3 = relative ? cury + toy : toy;
svgCurveToCubic(narrowPrecisionToFloat(px1), narrowPrecisionToFloat(py1), narrowPrecisionToFloat(px2),
narrowPrecisionToFloat(py2), narrowPrecisionToFloat(px3), narrowPrecisionToFloat(py3));
contrlx = relative ? curx + x2 : x2;
contrly = relative ? cury + y2 : y2;
curx = relative ? curx + tox : tox;
cury = relative ? cury + toy : toy;
}
else
svgCurveToCubic(narrowPrecisionToFloat(x1), narrowPrecisionToFloat(y1), narrowPrecisionToFloat(x2),
narrowPrecisionToFloat(y2), narrowPrecisionToFloat(tox), narrowPrecisionToFloat(toy), !relative);
break;
}
case 's':
relative = true;
case 'S':
{
if (!parseNumber(ptr, end, x2) || !parseNumber(ptr, end, y2) ||
!parseNumber(ptr, end, tox) || !parseNumber(ptr, end, toy))
return false;
if (!(lastCommand == 'c' || lastCommand == 'C' ||
lastCommand == 's' || lastCommand == 'S')) {
contrlx = curx;
contrly = cury;
}
if (process) {
px1 = 2 * curx - contrlx;
py1 = 2 * cury - contrly;
px2 = relative ? curx + x2 : x2;
py2 = relative ? cury + y2 : y2;
px3 = relative ? curx + tox : tox;
py3 = relative ? cury + toy : toy;
svgCurveToCubic(narrowPrecisionToFloat(px1), narrowPrecisionToFloat(py1), narrowPrecisionToFloat(px2),
narrowPrecisionToFloat(py2), narrowPrecisionToFloat(px3), narrowPrecisionToFloat(py3));
contrlx = relative ? curx + x2 : x2;
contrly = relative ? cury + y2 : y2;
curx = relative ? curx + tox : tox;
cury = relative ? cury + toy : toy;
}
else
svgCurveToCubicSmooth(narrowPrecisionToFloat(x2), narrowPrecisionToFloat(y2),
narrowPrecisionToFloat(tox), narrowPrecisionToFloat(toy), !relative);
break;
}
case 'q':
relative = true;
case 'Q':
{
if (!parseNumber(ptr, end, x1) || !parseNumber(ptr, end, y1) ||
!parseNumber(ptr, end, tox) || !parseNumber(ptr, end, toy))
return false;
if (process) {
px1 = relative ? (curx + 2 * (x1 + curx)) * (1.0 / 3.0) : (curx + 2 * x1) * (1.0 / 3.0);
py1 = relative ? (cury + 2 * (y1 + cury)) * (1.0 / 3.0) : (cury + 2 * y1) * (1.0 / 3.0);
px2 = relative ? ((curx + tox) + 2 * (x1 + curx)) * (1.0 / 3.0) : (tox + 2 * x1) * (1.0 / 3.0);
py2 = relative ? ((cury + toy) + 2 * (y1 + cury)) * (1.0 / 3.0) : (toy + 2 * y1) * (1.0 / 3.0);
px3 = relative ? curx + tox : tox;
py3 = relative ? cury + toy : toy;
svgCurveToCubic(narrowPrecisionToFloat(px1), narrowPrecisionToFloat(py1), narrowPrecisionToFloat(px2),
narrowPrecisionToFloat(py2), narrowPrecisionToFloat(px3), narrowPrecisionToFloat(py3));
contrlx = relative ? curx + x1 : x1;
contrly = relative ? cury + y1 : y1;
curx = relative ? curx + tox : tox;
cury = relative ? cury + toy : toy;
}
else
svgCurveToQuadratic(narrowPrecisionToFloat(x1), narrowPrecisionToFloat(y1),
narrowPrecisionToFloat(tox), narrowPrecisionToFloat(toy), !relative);
break;
}
case 't':
relative = true;
case 'T':
{
if (!parseNumber(ptr, end, tox) || !parseNumber(ptr, end, toy))
return false;
if (!(lastCommand == 'q' || lastCommand == 'Q' ||
lastCommand == 't' || lastCommand == 'T')) {
contrlx = curx;
contrly = cury;
}
if (process) {
xc = 2 * curx - contrlx;
yc = 2 * cury - contrly;
px1 = relative ? (curx + 2 * xc) * (1.0 / 3.0) : (curx + 2 * xc) * (1.0 / 3.0);
py1 = relative ? (cury + 2 * yc) * (1.0 / 3.0) : (cury + 2 * yc) * (1.0 / 3.0);
px2 = relative ? ((curx + tox) + 2 * xc) * (1.0 / 3.0) : (tox + 2 * xc) * (1.0 / 3.0);
py2 = relative ? ((cury + toy) + 2 * yc) * (1.0 / 3.0) : (toy + 2 * yc) * (1.0 / 3.0);
px3 = relative ? curx + tox : tox;
py3 = relative ? cury + toy : toy;
svgCurveToCubic(narrowPrecisionToFloat(px1), narrowPrecisionToFloat(py1), narrowPrecisionToFloat(px2),
narrowPrecisionToFloat(py2), narrowPrecisionToFloat(px3), narrowPrecisionToFloat(py3));
contrlx = xc;
contrly = yc;
curx = relative ? curx + tox : tox;
cury = relative ? cury + toy : toy;
}
else
svgCurveToQuadraticSmooth(narrowPrecisionToFloat(tox), narrowPrecisionToFloat(toy), !relative);
break;
}
case 'a':
relative = true;
case 'A':
{
bool largeArc, sweep;
double angle, rx, ry;
if (!parseNumber(ptr, end, rx) || !parseNumber(ptr, end, ry) ||
!parseNumber(ptr, end, angle) || !parseNumber(ptr, end, tox))
return false;
largeArc = tox == 1;
if (!parseNumber(ptr, end, tox))
return false;
sweep = tox == 1;
if (!parseNumber(ptr, end, tox) || !parseNumber(ptr, end, toy))
return false;
// Spec: radii are nonnegative numbers
rx = fabs(rx);
ry = fabs(ry);
if (process)
calculateArc(relative, curx, cury, angle, tox, toy, rx, ry, largeArc, sweep);
else
svgArcTo(narrowPrecisionToFloat(tox), narrowPrecisionToFloat(toy), narrowPrecisionToFloat(rx), narrowPrecisionToFloat(ry),
narrowPrecisionToFloat(angle), largeArc, sweep, !relative);
break;
}
default:
// FIXME: An error should go to the JavaScript console, or the like.
return false;
}
lastCommand = command;
if (ptr >= end)
return true;
// Check for remaining coordinates in the current command.
if ((*ptr == '+' || *ptr == '-' || (*ptr >= '0' && *ptr <= '9')) &&
(command != 'z' && command !='a' && command != 'A')) {
if (command == 'M')
command = 'L';
else if (command == 'm')
command = 'l';
} else
command = *(ptr++);
if (lastCommand != 'C' && lastCommand != 'c' &&
lastCommand != 'S' && lastCommand != 's' &&
lastCommand != 'Q' && lastCommand != 'q' &&
lastCommand != 'T' && lastCommand != 't') {
contrlx = curx;
contrly = cury;
}
}
return false;
}
// This works by converting the SVG arc to "simple" beziers.
// For each bezier found a svgToCurve call is done.
// Adapted from Niko's code in kdelibs/kdecore/svgicons.
// Maybe this can serve in some shared lib? (Rob)
void SVGPathParser::calculateArc(bool relative, double& curx, double& cury, double angle, double x, double y, double r1, double r2, bool largeArcFlag, bool sweepFlag)
{
double sin_th, cos_th;
double a00, a01, a10, a11;
double x0, y0, x1, y1, xc, yc;
double d, sfactor, sfactor_sq;
double th0, th1, th_arc;
int i, n_segs;
sin_th = sin(angle * (piDouble / 180.0));
cos_th = cos(angle * (piDouble / 180.0));
double dx;
if (!relative)
dx = (curx - x) / 2.0;
else
dx = -x / 2.0;
double dy;
if (!relative)
dy = (cury - y) / 2.0;
else
dy = -y / 2.0;
double _x1 = cos_th * dx + sin_th * dy;
double _y1 = -sin_th * dx + cos_th * dy;
double Pr1 = r1 * r1;
double Pr2 = r2 * r2;
double Px = _x1 * _x1;
double Py = _y1 * _y1;
// Spec : check if radii are large enough
double check = Px / Pr1 + Py / Pr2;
if (check > 1) {
r1 = r1 * sqrt(check);
r2 = r2 * sqrt(check);
}
a00 = cos_th / r1;
a01 = sin_th / r1;
a10 = -sin_th / r2;
a11 = cos_th / r2;
x0 = a00 * curx + a01 * cury;
y0 = a10 * curx + a11 * cury;
if (!relative)
x1 = a00 * x + a01 * y;
else
x1 = a00 * (curx + x) + a01 * (cury + y);
if (!relative)
y1 = a10 * x + a11 * y;
else
y1 = a10 * (curx + x) + a11 * (cury + y);
/* (x0, y0) is current point in transformed coordinate space.
(x1, y1) is new point in transformed coordinate space.
The arc fits a unit-radius circle in this space.
*/
d = (x1 - x0) * (x1 - x0) + (y1 - y0) * (y1 - y0);
sfactor_sq = 1.0 / d - 0.25;
if (sfactor_sq < 0)
sfactor_sq = 0;
sfactor = sqrt(sfactor_sq);
if (sweepFlag == largeArcFlag)
sfactor = -sfactor;
xc = 0.5 * (x0 + x1) - sfactor * (y1 - y0);
yc = 0.5 * (y0 + y1) + sfactor * (x1 - x0);
/* (xc, yc) is center of the circle. */
th0 = atan2(y0 - yc, x0 - xc);
th1 = atan2(y1 - yc, x1 - xc);
th_arc = th1 - th0;
if (th_arc < 0 && sweepFlag)
th_arc += 2 * piDouble;
else if (th_arc > 0 && !sweepFlag)
th_arc -= 2 * piDouble;
n_segs = (int) (int) ceil(fabs(th_arc / (piDouble * 0.5 + 0.001)));
for(i = 0; i < n_segs; i++) {
double sin_th, cos_th;
double a00, a01, a10, a11;
double x1, y1, x2, y2, x3, y3;
double t;
double th_half;
double _th0 = th0 + i * th_arc / n_segs;
double _th1 = th0 + (i + 1) * th_arc / n_segs;
sin_th = sin(angle * (piDouble / 180.0));
cos_th = cos(angle * (piDouble / 180.0));
/* inverse transform compared with rsvg_path_arc */
a00 = cos_th * r1;
a01 = -sin_th * r2;
a10 = sin_th * r1;
a11 = cos_th * r2;
th_half = 0.5 * (_th1 - _th0);
t = (8.0 / 3.0) * sin(th_half * 0.5) * sin(th_half * 0.5) / sin(th_half);
x1 = xc + cos(_th0) - t * sin(_th0);
y1 = yc + sin(_th0) + t * cos(_th0);
x3 = xc + cos(_th1);
y3 = yc + sin(_th1);
x2 = x3 + t * sin(_th1);
y2 = y3 - t * cos(_th1);
svgCurveToCubic(narrowPrecisionToFloat(a00 * x1 + a01 * y1), narrowPrecisionToFloat(a10 * x1 + a11 * y1),
narrowPrecisionToFloat(a00 * x2 + a01 * y2), narrowPrecisionToFloat(a10 * x2 + a11 * y2),
narrowPrecisionToFloat(a00 * x3 + a01 * y3), narrowPrecisionToFloat(a10 * x3 + a11 * y3));
}
if (!relative)
curx = x;
else
curx += x;
if (!relative)
cury = y;
else
cury += y;
}
void SVGPathParser::svgLineToHorizontal(float, bool)
{
}
void SVGPathParser::svgLineToVertical(float, bool)
{
}
void SVGPathParser::svgCurveToCubicSmooth(float, float, float, float, bool)
{
}
void SVGPathParser::svgCurveToQuadratic(float, float, float, float, bool)
{
}
void SVGPathParser::svgCurveToQuadraticSmooth(float, float, bool)
{
}
void SVGPathParser::svgArcTo(float, float, float, float, float, bool, bool, bool)
{
}
}
// vim:ts=4:noet
#endif // ENABLE(SVG)
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