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/*
Copyright (C) 2007 Krzysztof Kowalczyk <kkowalczyk@gmail.com>
Copyright (C) 2004, 2005, 2006 Nikolas Zimmermann <wildfox@kde.org>
2004, 2005, 2006 Rob Buis <buis@kde.org>
2005, 2007 Apple Inc. All Rights reserved.
2007 Alp Toker <alp@atoker.com>
2008 Dirk Schulze <krit@webkit.org>
2011 Igalia S.L.
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
aint with this library; see the file COPYING.LIB. If not, write to
the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
Boston, MA 02110-1301, USA.
*/
#include "config.h"
#include "Path.h"
#include "AffineTransform.h"
#include "CairoPath.h"
#include "FloatRect.h"
#include "GraphicsContext.h"
#include "OwnPtrCairo.h"
#include "PlatformString.h"
#include "StrokeStyleApplier.h"
#include <cairo.h>
#include <math.h>
#include <wtf/MathExtras.h>
namespace WebCore {
Path::Path()
: m_path(new CairoPath())
{
}
Path::~Path()
{
delete m_path;
}
Path::Path(const Path& other)
: m_path(new CairoPath())
{
cairo_t* cr = platformPath()->context();
OwnPtr<cairo_path_t> p(cairo_copy_path(other.platformPath()->context()));
cairo_append_path(cr, p.get());
}
Path& Path::operator=(const Path& other)
{
if (&other == this)
return *this;
clear();
cairo_t* cr = platformPath()->context();
OwnPtr<cairo_path_t> p(cairo_copy_path(other.platformPath()->context()));
cairo_append_path(cr, p.get());
return *this;
}
void Path::clear()
{
cairo_t* cr = platformPath()->context();
cairo_new_path(cr);
}
bool Path::isEmpty() const
{
return !cairo_has_current_point(platformPath()->context());
}
bool Path::hasCurrentPoint() const
{
return !isEmpty();
}
FloatPoint Path::currentPoint() const
{
// FIXME: Is this the correct way?
double x;
double y;
cairo_get_current_point(platformPath()->context(), &x, &y);
return FloatPoint(x, y);
}
void Path::translate(const FloatSize& p)
{
cairo_t* cr = platformPath()->context();
cairo_translate(cr, -p.width(), -p.height());
}
void Path::moveTo(const FloatPoint& p)
{
cairo_t* cr = platformPath()->context();
cairo_move_to(cr, p.x(), p.y());
}
void Path::addLineTo(const FloatPoint& p)
{
cairo_t* cr = platformPath()->context();
cairo_line_to(cr, p.x(), p.y());
}
void Path::addRect(const FloatRect& rect)
{
cairo_t* cr = platformPath()->context();
cairo_rectangle(cr, rect.x(), rect.y(), rect.width(), rect.height());
}
/*
* inspired by libsvg-cairo
*/
void Path::addQuadCurveTo(const FloatPoint& controlPoint, const FloatPoint& point)
{
cairo_t* cr = platformPath()->context();
double x, y;
double x1 = controlPoint.x();
double y1 = controlPoint.y();
double x2 = point.x();
double y2 = point.y();
cairo_get_current_point(cr, &x, &y);
cairo_curve_to(cr,
x + 2.0 / 3.0 * (x1 - x), y + 2.0 / 3.0 * (y1 - y),
x2 + 2.0 / 3.0 * (x1 - x2), y2 + 2.0 / 3.0 * (y1 - y2),
x2, y2);
}
void Path::addBezierCurveTo(const FloatPoint& controlPoint1, const FloatPoint& controlPoint2, const FloatPoint& controlPoint3)
{
cairo_t* cr = platformPath()->context();
cairo_curve_to(cr, controlPoint1.x(), controlPoint1.y(),
controlPoint2.x(), controlPoint2.y(),
controlPoint3.x(), controlPoint3.y());
}
void Path::addArc(const FloatPoint& p, float r, float startAngle, float endAngle, bool anticlockwise)
{
// http://bugs.webkit.org/show_bug.cgi?id=16449
// cairo_arc() functions hang or crash when passed inf as radius or start/end angle
if (!isfinite(r) || !isfinite(startAngle) || !isfinite(endAngle))
return;
cairo_t* cr = platformPath()->context();
float sweep = endAngle - startAngle;
const float twoPI = 2 * piFloat;
if ((sweep <= -twoPI || sweep >= twoPI)
&& ((anticlockwise && (endAngle < startAngle)) || (!anticlockwise && (startAngle < endAngle)))) {
if (anticlockwise)
cairo_arc_negative(cr, p.x(), p.y(), r, startAngle, startAngle - twoPI);
else
cairo_arc(cr, p.x(), p.y(), r, startAngle, startAngle + twoPI);
cairo_new_sub_path(cr);
cairo_arc(cr, p.x(), p.y(), r, endAngle, endAngle);
} else {
if (anticlockwise)
cairo_arc_negative(cr, p.x(), p.y(), r, startAngle, endAngle);
else
cairo_arc(cr, p.x(), p.y(), r, startAngle, endAngle);
}
}
static inline float areaOfTriangleFormedByPoints(const FloatPoint& p1, const FloatPoint& p2, const FloatPoint& p3)
{
return p1.x() * (p2.y() - p3.y()) + p2.x() * (p3.y() - p1.y()) + p3.x() * (p1.y() - p2.y());
}
void Path::addArcTo(const FloatPoint& p1, const FloatPoint& p2, float radius)
{
if (isEmpty())
return;
cairo_t* cr = platformPath()->context();
double x0, y0;
cairo_get_current_point(cr, &x0, &y0);
FloatPoint p0(x0, y0);
// Draw only a straight line to p1 if any of the points are equal or the radius is zero
// or the points are collinear (triangle that the points form has area of zero value).
if ((p1.x() == p0.x() && p1.y() == p0.y()) || (p1.x() == p2.x() && p1.y() == p2.y()) || !radius
|| !areaOfTriangleFormedByPoints(p0, p1, p2)) {
cairo_line_to(cr, p1.x(), p1.y());
return;
}
FloatPoint p1p0((p0.x() - p1.x()),(p0.y() - p1.y()));
FloatPoint p1p2((p2.x() - p1.x()),(p2.y() - p1.y()));
float p1p0_length = sqrtf(p1p0.x() * p1p0.x() + p1p0.y() * p1p0.y());
float p1p2_length = sqrtf(p1p2.x() * p1p2.x() + p1p2.y() * p1p2.y());
double cos_phi = (p1p0.x() * p1p2.x() + p1p0.y() * p1p2.y()) / (p1p0_length * p1p2_length);
// all points on a line logic
if (cos_phi == -1) {
cairo_line_to(cr, p1.x(), p1.y());
return;
}
if (cos_phi == 1) {
// add infinite far away point
unsigned int max_length = 65535;
double factor_max = max_length / p1p0_length;
FloatPoint ep((p0.x() + factor_max * p1p0.x()), (p0.y() + factor_max * p1p0.y()));
cairo_line_to(cr, ep.x(), ep.y());
return;
}
float tangent = radius / tan(acos(cos_phi) / 2);
float factor_p1p0 = tangent / p1p0_length;
FloatPoint t_p1p0((p1.x() + factor_p1p0 * p1p0.x()), (p1.y() + factor_p1p0 * p1p0.y()));
FloatPoint orth_p1p0(p1p0.y(), -p1p0.x());
float orth_p1p0_length = sqrt(orth_p1p0.x() * orth_p1p0.x() + orth_p1p0.y() * orth_p1p0.y());
float factor_ra = radius / orth_p1p0_length;
// angle between orth_p1p0 and p1p2 to get the right vector orthographic to p1p0
double cos_alpha = (orth_p1p0.x() * p1p2.x() + orth_p1p0.y() * p1p2.y()) / (orth_p1p0_length * p1p2_length);
if (cos_alpha < 0.f)
orth_p1p0 = FloatPoint(-orth_p1p0.x(), -orth_p1p0.y());
FloatPoint p((t_p1p0.x() + factor_ra * orth_p1p0.x()), (t_p1p0.y() + factor_ra * orth_p1p0.y()));
// calculate angles for addArc
orth_p1p0 = FloatPoint(-orth_p1p0.x(), -orth_p1p0.y());
float sa = acos(orth_p1p0.x() / orth_p1p0_length);
if (orth_p1p0.y() < 0.f)
sa = 2 * piDouble - sa;
// anticlockwise logic
bool anticlockwise = false;
float factor_p1p2 = tangent / p1p2_length;
FloatPoint t_p1p2((p1.x() + factor_p1p2 * p1p2.x()), (p1.y() + factor_p1p2 * p1p2.y()));
FloatPoint orth_p1p2((t_p1p2.x() - p.x()),(t_p1p2.y() - p.y()));
float orth_p1p2_length = sqrtf(orth_p1p2.x() * orth_p1p2.x() + orth_p1p2.y() * orth_p1p2.y());
float ea = acos(orth_p1p2.x() / orth_p1p2_length);
if (orth_p1p2.y() < 0)
ea = 2 * piDouble - ea;
if ((sa > ea) && ((sa - ea) < piDouble))
anticlockwise = true;
if ((sa < ea) && ((ea - sa) > piDouble))
anticlockwise = true;
cairo_line_to(cr, t_p1p0.x(), t_p1p0.y());
addArc(p, radius, sa, ea, anticlockwise);
}
void Path::addEllipse(const FloatRect& rect)
{
cairo_t* cr = platformPath()->context();
cairo_save(cr);
float yRadius = .5 * rect.height();
float xRadius = .5 * rect.width();
cairo_translate(cr, rect.x() + xRadius, rect.y() + yRadius);
cairo_scale(cr, xRadius, yRadius);
cairo_arc(cr, 0., 0., 1., 0., 2 * piDouble);
cairo_restore(cr);
}
void Path::closeSubpath()
{
cairo_t* cr = platformPath()->context();
cairo_close_path(cr);
}
FloatRect Path::boundingRect() const
{
cairo_t* cr = platformPath()->context();
double x0, x1, y0, y1;
cairo_path_extents(cr, &x0, &y0, &x1, &y1);
return FloatRect(x0, y0, x1 - x0, y1 - y0);
}
FloatRect Path::strokeBoundingRect(StrokeStyleApplier* applier)
{
cairo_t* cr = platformPath()->context();
if (applier) {
GraphicsContext gc(cr);
applier->strokeStyle(&gc);
}
double x0, x1, y0, y1;
cairo_stroke_extents(cr, &x0, &y0, &x1, &y1);
return FloatRect(x0, y0, x1 - x0, y1 - y0);
}
bool Path::contains(const FloatPoint& point, WindRule rule) const
{
if (!isfinite(point.x()) || !isfinite(point.y()))
return false;
cairo_t* cr = platformPath()->context();
cairo_fill_rule_t cur = cairo_get_fill_rule(cr);
cairo_set_fill_rule(cr, rule == RULE_EVENODD ? CAIRO_FILL_RULE_EVEN_ODD : CAIRO_FILL_RULE_WINDING);
bool contains = cairo_in_fill(cr, point.x(), point.y());
cairo_set_fill_rule(cr, cur);
return contains;
}
bool Path::strokeContains(StrokeStyleApplier* applier, const FloatPoint& point) const
{
ASSERT(applier);
cairo_t* cr = platformPath()->context();
GraphicsContext gc(cr);
applier->strokeStyle(&gc);
return cairo_in_stroke(cr, point.x(), point.y());
}
void Path::apply(void* info, PathApplierFunction function) const
{
cairo_t* cr = platformPath()->context();
OwnPtr<cairo_path_t> path(cairo_copy_path(cr));
cairo_path_data_t* data;
PathElement pelement;
FloatPoint points[3];
pelement.points = points;
for (int i = 0; i < path->num_data; i += path->data[i].header.length) {
data = &path->data[i];
switch (data->header.type) {
case CAIRO_PATH_MOVE_TO:
pelement.type = PathElementMoveToPoint;
pelement.points[0] = FloatPoint(data[1].point.x,data[1].point.y);
function(info, &pelement);
break;
case CAIRO_PATH_LINE_TO:
pelement.type = PathElementAddLineToPoint;
pelement.points[0] = FloatPoint(data[1].point.x,data[1].point.y);
function(info, &pelement);
break;
case CAIRO_PATH_CURVE_TO:
pelement.type = PathElementAddCurveToPoint;
pelement.points[0] = FloatPoint(data[1].point.x,data[1].point.y);
pelement.points[1] = FloatPoint(data[2].point.x,data[2].point.y);
pelement.points[2] = FloatPoint(data[3].point.x,data[3].point.y);
function(info, &pelement);
break;
case CAIRO_PATH_CLOSE_PATH:
pelement.type = PathElementCloseSubpath;
function(info, &pelement);
break;
}
}
}
void Path::transform(const AffineTransform& trans)
{
cairo_t* cr = platformPath()->context();
cairo_matrix_t c_matrix = cairo_matrix_t(trans);
cairo_matrix_invert(&c_matrix);
cairo_transform(cr, &c_matrix);
}
} // namespace WebCore
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