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** General Public License version 2.1 as published by the Free Software
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#include "qpolygon.h"
#include "qrect.h"
#include "qdatastream.h"
#include "qmatrix.h"
#include "qdebug.h"
#include "qpainterpath.h"
#include "qvariant.h"
#include "qpainterpath_p.h"
#include "qbezier_p.h"
#include <stdarg.h>
QT_BEGIN_NAMESPACE
//same as qt_painterpath_isect_line in qpainterpath.cpp
static void qt_polygon_isect_line(const QPointF &p1, const QPointF &p2, const QPointF &pos,
int *winding)
{
qreal x1 = p1.x();
qreal y1 = p1.y();
qreal x2 = p2.x();
qreal y2 = p2.y();
qreal y = pos.y();
int dir = 1;
if (qFuzzyCompare(y1, y2)) {
// ignore horizontal lines according to scan conversion rule
return;
} else if (y2 < y1) {
qreal x_tmp = x2; x2 = x1; x1 = x_tmp;
qreal y_tmp = y2; y2 = y1; y1 = y_tmp;
dir = -1;
}
if (y >= y1 && y < y2) {
qreal x = x1 + ((x2 - x1) / (y2 - y1)) * (y - y1);
// count up the winding number if we're
if (x<=pos.x()) {
(*winding) += dir;
}
}
}
/*!
\class QPolygon
\brief The QPolygon class provides a vector of points using
integer precision.
\reentrant
\ingroup painting
\ingroup shared
A QPolygon object is a QVector<QPoint>. The easiest way to add
points to a QPolygon is to use QVector's streaming operator, as
illustrated below:
\snippet doc/src/snippets/polygon/polygon.cpp 0
In addition to the functions provided by QVector, QPolygon
provides some point-specific functions.
Each point in a polygon can be retrieved by passing its index to
the point() function. To populate the polygon, QPolygon provides
the setPoint() function to set the point at a given index, the
setPoints() function to set all the points in the polygon
(resizing it to the given number of points), and the putPoints()
function which copies a number of given points into the polygon
from a specified index (resizing the polygon if necessary).
QPolygon provides the boundingRect() and translate() functions for
geometry functions. Use the QMatrix::map() function for more
general transformations of QPolygons.
The QPolygon class is \l {Implicit Data Sharing}{implicitly
shared}.
\sa QVector, QPolygonF, QLine
*/
/*****************************************************************************
QPolygon member functions
*****************************************************************************/
/*!
\fn QPolygon::QPolygon()
Constructs a polygon with no points.
\sa QVector::isEmpty()
*/
/*!
\fn QPolygon::QPolygon(int size)
Constructs a polygon of the given \a size. Creates an empty
polygon if \a size == 0.
\sa QVector::isEmpty()
*/
/*!
\fn QPolygon::QPolygon(const QPolygon &polygon)
Constructs a copy of the given \a polygon.
\sa setPoints()
*/
/*!
\fn QPolygon::QPolygon(const QVector<QPoint> &points)
Constructs a polygon containing the specified \a points.
\sa setPoints()
*/
/*!
\fn QPolygon::QPolygon(const QRect &rectangle, bool closed)
Constructs a polygon from the given \a rectangle. If \a closed is
false, the polygon just contains the four points of the rectangle
ordered clockwise, otherwise the polygon's fifth point is set to
\a {rectangle}.topLeft().
Note that the bottom-right corner of the rectangle is located at
(rectangle.x() + rectangle.width(), rectangle.y() +
rectangle.height()).
\sa setPoints()
*/
QPolygon::QPolygon(const QRect &r, bool closed)
{
reserve(closed ? 5 : 4);
*this << QPoint(r.x(), r.y())
<< QPoint(r.x() + r.width(), r.y())
<< QPoint(r.x() + r.width(), r.y() + r.height())
<< QPoint(r.x(), r.y() + r.height());
if (closed)
*this << QPoint(r.left(), r.top());
}
/*!
\internal
Constructs a point array with \a nPoints points, taken from the
\a points array.
Equivalent to setPoints(nPoints, points).
*/
QPolygon::QPolygon(int nPoints, const int *points)
{
setPoints(nPoints, points);
}
/*!
\fn QPolygon::~QPolygon()
Destroys the polygon.
*/
/*!
Translates all points in the polygon by (\a{dx}, \a{dy}).
\sa translated()
*/
void QPolygon::translate(int dx, int dy)
{
if (dx == 0 && dy == 0)
return;
register QPoint *p = data();
register int i = size();
QPoint pt(dx, dy);
while (i--) {
*p += pt;
++p;
}
}
/*!
\fn void QPolygon::translate(const QPoint &offset)
\overload
Translates all points in the polygon by the given \a offset.
\sa translated()
*/
/*!
Returns a copy of the polygon that is translated by (\a{dx}, \a{dy}).
\since 4.6
\sa translate()
*/
QPolygon QPolygon::translated(int dx, int dy) const
{
QPolygon copy(*this);
copy.translate(dx, dy);
return copy;
}
/*!
\fn void QPolygon::translated(const QPoint &offset) const
\overload
\since 4.6
Returns a copy of the polygon that is translated by the given \a offset.
\sa translate()
*/
/*!
Extracts the coordinates of the point at the given \a index to
*\a{x} and *\a{y} (if they are valid pointers).
\sa setPoint()
*/
void QPolygon::point(int index, int *x, int *y) const
{
QPoint p = at(index);
if (x)
*x = (int)p.x();
if (y)
*y = (int)p.y();
}
/*!
\fn QPoint QPolygon::point(int index) const
\overload
Returns the point at the given \a index.
*/
/*!
\fn void QPolygon::setPoint(int index, const QPoint &point)
\overload
Sets the point at the given \a index to the given \a point.
*/
/*!
\fn void QPolygon::setPoint(int index, int x, int y)
Sets the point at the given \a index to the point specified by
(\a{x}, \a{y}).
\sa point(), putPoints(), setPoints(),
*/
/*!
Resizes the polygon to \a nPoints and populates it with the given
\a points.
The example code creates a polygon with two points (10, 20) and
(30, 40):
\snippet doc/src/snippets/polygon/polygon.cpp 2
\sa setPoint() putPoints()
*/
void QPolygon::setPoints(int nPoints, const int *points)
{
resize(nPoints);
int i = 0;
while (nPoints--) {
setPoint(i++, *points, *(points+1));
points += 2;
}
}
/*!
\overload
Resizes the polygon to \a nPoints and populates it with the points
specified by the variable argument list. The points are given as a
sequence of integers, starting with \a firstx then \a firsty, and
so on.
The example code creates a polygon with two points (10, 20) and
(30, 40):
\snippet doc/src/snippets/polygon/polygon.cpp 3
*/
void QPolygon::setPoints(int nPoints, int firstx, int firsty, ...)
{
va_list ap;
resize(nPoints);
setPoint(0, firstx, firsty);
int i = 0, x, y;
va_start(ap, firsty);
while (--nPoints) {
x = va_arg(ap, int);
y = va_arg(ap, int);
setPoint(++i, x, y);
}
va_end(ap);
}
/*!
\overload
\internal
Copies \a nPoints points from the \a points coord array into this
point array, and resizes the point array if \c{index+nPoints}
exceeds the size of the array.
\sa setPoint()
*/
void QPolygon::putPoints(int index, int nPoints, const int *points)
{
if (index + nPoints > size())
resize(index + nPoints);
int i = index;
while (nPoints--) {
setPoint(i++, *points, *(points+1));
points += 2;
}
}
/*!
Copies \a nPoints points from the variable argument list into this
polygon from the given \a index.
The points are given as a sequence of integers, starting with \a
firstx then \a firsty, and so on. The polygon is resized if
\c{index+nPoints} exceeds its current size.
The example code creates a polygon with three points (4,5), (6,7)
and (8,9), by expanding the polygon from 1 to 3 points:
\snippet doc/src/snippets/polygon/polygon.cpp 4
The following code has the same result, but here the putPoints()
function overwrites rather than extends:
\snippet doc/src/snippets/polygon/polygon.cpp 5
\sa setPoints()
*/
void QPolygon::putPoints(int index, int nPoints, int firstx, int firsty, ...)
{
va_list ap;
if (index + nPoints > size())
resize(index + nPoints);
if (nPoints <= 0)
return;
setPoint(index, firstx, firsty);
int i = index, x, y;
va_start(ap, firsty);
while (--nPoints) {
x = va_arg(ap, int);
y = va_arg(ap, int);
setPoint(++i, x, y);
}
va_end(ap);
}
/*!
\fn void QPolygon::putPoints(int index, int nPoints, const QPolygon &fromPolygon, int fromIndex)
\overload
Copies \a nPoints points from the given \a fromIndex ( 0 by
default) in \a fromPolygon into this polygon, starting at the
specified \a index. For example:
\snippet doc/src/snippets/polygon/polygon.cpp 6
*/
void QPolygon::putPoints(int index, int nPoints, const QPolygon & from, int fromIndex)
{
if (index + nPoints > size())
resize(index + nPoints);
if (nPoints <= 0)
return;
int n = 0;
while(n < nPoints) {
setPoint(index + n, from[fromIndex+n]);
++n;
}
}
/*!
Returns the bounding rectangle of the polygon, or QRect(0, 0, 0,
0) if the polygon is empty.
\sa QVector::isEmpty()
*/
QRect QPolygon::boundingRect() const
{
if (isEmpty())
return QRect(0, 0, 0, 0);
register const QPoint *pd = constData();
int minx, maxx, miny, maxy;
minx = maxx = pd->x();
miny = maxy = pd->y();
++pd;
for (int i = 1; i < size(); ++i) {
if (pd->x() < minx)
minx = pd->x();
else if (pd->x() > maxx)
maxx = pd->x();
if (pd->y() < miny)
miny = pd->y();
else if (pd->y() > maxy)
maxy = pd->y();
++pd;
}
return QRect(QPoint(minx,miny), QPoint(maxx,maxy));
}
#ifndef QT_NO_DEBUG_STREAM
QDebug operator<<(QDebug dbg, const QPolygon &a)
{
#ifndef Q_BROKEN_DEBUG_STREAM
dbg.nospace() << "QPolygon(";
for (int i = 0; i < a.count(); ++i)
dbg.nospace() << a.at(i);
dbg.nospace() << ')';
return dbg.space();
#else
qWarning("This compiler doesn't support streaming QPolygon to QDebug");
return dbg;
Q_UNUSED(a);
#endif
}
#endif
/*!
\class QPolygonF
\brief The QPolygonF class provides a vector of points using
floating point precision.
\reentrant
\ingroup painting
\ingroup shared
A QPolygonF is a QVector<QPointF>. The easiest way to add points
to a QPolygonF is to use its streaming operator, as illustrated
below:
\snippet doc/src/snippets/polygon/polygon.cpp 1
In addition to the functions provided by QVector, QPolygonF
provides the boundingRect() and translate() functions for geometry
operations. Use the QMatrix::map() function for more general
transformations of QPolygonFs.
QPolygonF also provides the isClosed() function to determine
whether a polygon's start and end points are the same, and the
toPolygon() function returning an integer precision copy of this
polygon.
The QPolygonF class is \l {Implicit Data Sharing}{implicitly
shared}.
\sa QVector, QPolygon, QLineF
*/
/*****************************************************************************
QPolygonF member functions
*****************************************************************************/
/*!
\fn QPolygonF::QPolygonF()
Constructs a polygon with no points.
\sa QVector::isEmpty()
*/
/*!
\fn QPolygonF::QPolygonF(int size)
Constructs a polygon of the given \a size. Creates an empty
polygon if \a size == 0.
\sa QVector::isEmpty()
*/
/*!
\fn QPolygonF::QPolygonF(const QPolygonF &polygon)
Constructs a copy of the given \a polygon.
*/
/*!
\fn QPolygonF::QPolygonF(const QVector<QPointF> &points)
Constructs a polygon containing the specified \a points.
*/
/*!
\fn QPolygonF::QPolygonF(const QRectF &rectangle)
Constructs a closed polygon from the specified \a rectangle.
The polygon contains the four vertices of the rectangle in
clockwise order starting and ending with the top-left vertex.
\sa isClosed()
*/
QPolygonF::QPolygonF(const QRectF &r)
{
reserve(5);
append(QPointF(r.x(), r.y()));
append(QPointF(r.x() + r.width(), r.y()));
append(QPointF(r.x() + r.width(), r.y() + r.height()));
append(QPointF(r.x(), r.y() + r.height()));
append(QPointF(r.x(), r.y()));
}
/*!
\fn QPolygonF::QPolygonF(const QPolygon &polygon)
Constructs a float based polygon from the specified integer based
\a polygon.
\sa toPolygon()
*/
QPolygonF::QPolygonF(const QPolygon &a)
{
reserve(a.size());
for (int i=0; i<a.size(); ++i)
append(a.at(i));
}
/*!
\fn QPolygonF::~QPolygonF()
Destroys the polygon.
*/
/*!
Translate all points in the polygon by the given \a offset.
\sa translated()
*/
void QPolygonF::translate(const QPointF &offset)
{
if (offset.isNull())
return;
register QPointF *p = data();
register int i = size();
while (i--) {
*p += offset;
++p;
}
}
/*!
\fn void QPolygonF::translate(qreal dx, qreal dy)
\overload
Translates all points in the polygon by (\a{dx}, \a{dy}).
\sa translated()
*/
/*!
Returns a copy of the polygon that is translated by the given \a offset.
\since 4.6
\sa translate()
*/
QPolygonF QPolygonF::translated(const QPointF &offset) const
{
QPolygonF copy(*this);
copy.translate(offset);
return copy;
}
/*!
\fn void QPolygonF::translated(qreal dx, qreal dy) const
\overload
\since 4.6
Returns a copy of the polygon that is translated by (\a{dx}, \a{dy}).
\sa translate()
*/
/*!
\fn bool QPolygonF::isClosed() const
Returns true if the polygon is closed; otherwise returns false.
A polygon is said to be closed if its start point and end point are equal.
\sa QVector::first(), QVector::last()
*/
/*!
Returns the bounding rectangle of the polygon, or QRectF(0,0,0,0)
if the polygon is empty.
\sa QVector::isEmpty()
*/
QRectF QPolygonF::boundingRect() const
{
if (isEmpty())
return QRectF(0, 0, 0, 0);
register const QPointF *pd = constData();
qreal minx, maxx, miny, maxy;
minx = maxx = pd->x();
miny = maxy = pd->y();
++pd;
for (int i = 1; i < size(); ++i) {
if (pd->x() < minx)
minx = pd->x();
else if (pd->x() > maxx)
maxx = pd->x();
if (pd->y() < miny)
miny = pd->y();
else if (pd->y() > maxy)
maxy = pd->y();
++pd;
}
return QRectF(minx,miny, maxx - minx, maxy - miny);
}
/*!
Creates and returns a QPolygon by converting each QPointF to a
QPoint.
\sa QPointF::toPoint()
*/
QPolygon QPolygonF::toPolygon() const
{
QPolygon a;
a.reserve(size());
for (int i=0; i<size(); ++i)
a.append(at(i).toPoint());
return a;
}
/*!
Returns the polygon as a QVariant
*/
QPolygon::operator QVariant() const
{
return QVariant(QVariant::Polygon, this);
}
/*****************************************************************************
QPolygon stream functions
*****************************************************************************/
#ifndef QT_NO_DATASTREAM
/*!
\fn QDataStream &operator<<(QDataStream &stream, const QPolygon &polygon)
\since 4.4
\relates QPolygon
Writes the given \a polygon to the given \a stream, and returns a
reference to the stream.
\sa {Format of the QDataStream Operators}
*/
QDataStream &operator<<(QDataStream &s, const QPolygon &a)
{
const QVector<QPoint> &v = a;
return s << v;
}
/*!
\fn QDataStream &operator>>(QDataStream &stream, QPolygon &polygon)
\since 4.4
\relates QPolygon
Reads a polygon from the given \a stream into the given \a
polygon, and returns a reference to the stream.
\sa {Format of the QDataStream Operators}
*/
QDataStream &operator>>(QDataStream &s, QPolygon &a)
{
QVector<QPoint> &v = a;
return s >> v;
}
#endif // QT_NO_DATASTREAM
/*****************************************************************************
QPolygonF stream functions
*****************************************************************************/
#ifndef QT_NO_DATASTREAM
/*!
\fn QDataStream &operator<<(QDataStream &stream, const QPolygonF &polygon)
\relates QPolygonF
Writes the given \a polygon to the given \a stream, and returns a
reference to the stream.
\sa {Format of the QDataStream Operators}
*/
QDataStream &operator<<(QDataStream &s, const QPolygonF &a)
{
quint32 len = a.size();
uint i;
s << len;
for (i = 0; i < len; ++i)
s << a.at(i);
return s;
}
/*!
\fn QDataStream &operator>>(QDataStream &stream, QPolygonF &polygon)
\relates QPolygonF
Reads a polygon from the given \a stream into the given \a
polygon, and returns a reference to the stream.
\sa {Format of the QDataStream Operators}
*/
QDataStream &operator>>(QDataStream &s, QPolygonF &a)
{
quint32 len;
uint i;
s >> len;
a.reserve(a.size() + (int)len);
QPointF p;
for (i = 0; i < len; ++i) {
s >> p;
a.insert(i, p);
}
return s;
}
#endif //QT_NO_DATASTREAM
#ifndef QT_NO_DEBUG_STREAM
QDebug operator<<(QDebug dbg, const QPolygonF &a)
{
#ifndef Q_BROKEN_DEBUG_STREAM
dbg.nospace() << "QPolygonF(";
for (int i = 0; i < a.count(); ++i)
dbg.nospace() << a.at(i);
dbg.nospace() << ')';
return dbg.space();
#else
qWarning("This compiler doesn't support streaming QPolygonF to QDebug");
return dbg;
Q_UNUSED(a);
#endif
}
#endif
/*!
\since 4.3
\fn bool QPolygonF::containsPoint(const QPointF &point, Qt::FillRule fillRule) const
Returns true if the given \a point is inside the polygon according to
the specified \a fillRule; otherwise returns false.
*/
bool QPolygonF::containsPoint(const QPointF &pt, Qt::FillRule fillRule) const
{
if (isEmpty())
return false;
int winding_number = 0;
QPointF last_pt = at(0);
QPointF last_start = at(0);
for (int i = 1; i < size(); ++i) {
const QPointF &e = at(i);
qt_polygon_isect_line(last_pt, e, pt, &winding_number);
last_pt = e;
}
// implicitly close last subpath
if (last_pt != last_start)
qt_polygon_isect_line(last_pt, last_start, pt, &winding_number);
return (fillRule == Qt::WindingFill
? (winding_number != 0)
: ((winding_number % 2) != 0));
}
/*!
\since 4.3
\fn bool QPolygon::containsPoint(const QPoint &point, Qt::FillRule fillRule) const
Returns true if the given \a point is inside the polygon according to
the specified \a fillRule; otherwise returns false.
*/
bool QPolygon::containsPoint(const QPoint &pt, Qt::FillRule fillRule) const
{
if (isEmpty())
return false;
int winding_number = 0;
QPoint last_pt = at(0);
QPoint last_start = at(0);
for (int i = 1; i < size(); ++i) {
const QPoint &e = at(i);
qt_polygon_isect_line(last_pt, e, pt, &winding_number);
last_pt = e;
}
// implicitly close last subpath
if (last_pt != last_start)
qt_polygon_isect_line(last_pt, last_start, pt, &winding_number);
return (fillRule == Qt::WindingFill
? (winding_number != 0)
: ((winding_number % 2) != 0));
}
/*!
\since 4.3
Returns a polygon which is the union of this polygon and \a r.
Set operations on polygons, will treat the polygons as areas, and
implicitly close the polygon.
\sa intersected(), subtracted()
*/
QPolygon QPolygon::united(const QPolygon &r) const
{
QPainterPath subject; subject.addPolygon(*this);
QPainterPath clip; clip.addPolygon(r);
return subject.united(clip).toFillPolygon().toPolygon();
}
/*!
\since 4.3
Returns a polygon which is the intersection of this polygon and \a r.
Set operations on polygons will treat the polygons as
areas. Non-closed polygons will be treated as implicitly closed.
*/
QPolygon QPolygon::intersected(const QPolygon &r) const
{
QPainterPath subject; subject.addPolygon(*this);
QPainterPath clip; clip.addPolygon(r);
return subject.intersected(clip).toFillPolygon().toPolygon();
}
/*!
\since 4.3
Returns a polygon which is \a r subtracted from this polygon.
Set operations on polygons will treat the polygons as
areas. Non-closed polygons will be treated as implicitly closed.
*/
QPolygon QPolygon::subtracted(const QPolygon &r) const
{
QPainterPath subject; subject.addPolygon(*this);
QPainterPath clip; clip.addPolygon(r);
return subject.subtracted(clip).toFillPolygon().toPolygon();
}
/*!
\since 4.3
Returns a polygon which is the union of this polygon and \a r.
Set operations on polygons will treat the polygons as
areas. Non-closed polygons will be treated as implicitly closed.
\sa intersected(), subtracted()
*/
QPolygonF QPolygonF::united(const QPolygonF &r) const
{
QPainterPath subject; subject.addPolygon(*this);
QPainterPath clip; clip.addPolygon(r);
return subject.united(clip).toFillPolygon();
}
/*!
\since 4.3
Returns a polygon which is the intersection of this polygon and \a r.
Set operations on polygons will treat the polygons as
areas. Non-closed polygons will be treated as implicitly closed.
*/
QPolygonF QPolygonF::intersected(const QPolygonF &r) const
{
QPainterPath subject; subject.addPolygon(*this);
QPainterPath clip; clip.addPolygon(r);
return subject.intersected(clip).toFillPolygon();
}
/*!
\since 4.3
Returns a polygon which is \a r subtracted from this polygon.
Set operations on polygons will treat the polygons as
areas. Non-closed polygons will be treated as implicitly closed.
*/
QPolygonF QPolygonF::subtracted(const QPolygonF &r) const
{
QPainterPath subject; subject.addPolygon(*this);
QPainterPath clip; clip.addPolygon(r);
return subject.subtracted(clip).toFillPolygon();
}
QT_END_NAMESPACE