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#include "qpoint.h"

#include "qdatastream.h"

#include "qdebug.h"

QT_BEGIN_NAMESPACE

/*!

    \class QPoint

    \ingroup painting

    \brief The QPoint class defines a point in the plane using integer

    precision.

    A point is specified by a x coordinate and an y coordinate which

    can be accessed using the x() and y() functions. The isNull()

    function returns true if both x and y are set to 0. The

    coordinates can be set (or altered) using the setX() and setY()

    functions, or alternatively the rx() and ry() functions which

    return references to the coordinates (allowing direct

    manipulation).

    Given a point \e p, the following statements are all equivalent:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 0

    A QPoint object can also be used as a vector: Addition and

    subtraction are defined as for vectors (each component is added

    separately). A QPoint object can also be divided or multiplied by

    an \c int or a \c qreal.

    In addition, the QPoint class provides the manhattanLength()

    function which gives an inexpensive approximation of the length of

    the QPoint object interpreted as a vector. Finally, QPoint objects

    can be streamed as well as compared.

    \sa QPointF, QPolygon

*/

/*****************************************************************************

  QPoint member functions

 *****************************************************************************/

/*!

    \fn QPoint::QPoint()

    Constructs a null point, i.e. with coordinates (0, 0)

    \sa isNull()

*/

/*!

    \fn QPoint::QPoint(int x, int y)

    Constructs a point with the given coordinates (\a x, \a  y).

    \sa setX(), setY()

*/

/*!

    \fn bool QPoint::isNull() const

    Returns true if both the x and y coordinates are set to 0,

    otherwise returns false.

*/

/*!

    \fn int QPoint::x() const

    Returns the x coordinate of this point.

    \sa setX(), rx()

*/

/*!

    \fn int QPoint::y() const

    Returns the y coordinate of this point.

    \sa setY(), ry()

*/

/*!

    \fn void QPoint::setX(int x)

    Sets the x coordinate of this point to the given \a x coordinate.

    \sa x() setY()

*/

/*!

    \fn void QPoint::setY(int y)

    Sets the y coordinate of this point to the given \a y coordinate.

    \sa y() setX()

*/

/*!

    \fn int &QPoint::rx()

    Returns a reference to the x coordinate of this point.

    Using a reference makes it possible to directly manipulate x. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 1

    \sa x() setX()

*/

/*!

    \fn int &QPoint::ry()

    Returns a reference to the y coordinate of this point.

    Using a reference makes it possible to directly manipulate y. For

    example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 2

    \sa y(), setY()

*/

/*!

    \fn QPoint &QPoint::operator+=(const QPoint &point)

    Adds the given \a point to this point and returns a reference to

    this point. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 3

    \sa operator-=()

*/

/*!

    \fn QPoint &QPoint::operator-=(const QPoint &point)

    Subtracts the given \a point from this point and returns a

    reference to this point. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 4

    \sa operator+=()

*/

/*!

    \fn QPoint &QPoint::operator*=(qreal factor)

    Multiplies this point's coordinates by the given \a factor, and

    returns a reference to this point. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 5

    Note that the result is rounded to the nearest integer as points are held as

    integers. Use QPointF for floating point accuracy.

    \sa operator/=()

*/

/*!

    \fn bool operator==(const QPoint &p1, const QPoint &p2)

    \relates QPoint

    Returns true if \a p1 and \a p2 are equal; otherwise returns

    false.

*/

/*!

    \fn bool operator!=(const QPoint &p1, const QPoint &p2)

    \relates QPoint

    Returns true if \a p1 and \a p2 are not equal; otherwise returns false.

*/

/*!

    \fn const QPoint operator+(const QPoint &p1, const QPoint &p2)

    \relates QPoint

    Returns a QPoint object that is the sum of the given points, \a p1

    and \a p2; each component is added separately.

    \sa QPoint::operator+=()

*/

/*!

    \fn const QPoint operator-(const QPoint &p1, const QPoint &p2)

    \relates QPoint

    Returns a QPoint object that is formed by subtracting \a p2 from

    \a p1; each component is subtracted separately.

    \sa QPoint::operator-=()

*/

/*!

    \fn const QPoint operator*(const QPoint &point, qreal factor)

    \relates QPoint

    Returns a copy of the given \a point multiplied by the given \a factor.

    Note that the result is rounded to the nearest integer as points

    are held as integers. Use QPointF for floating point accuracy.

    \sa QPoint::operator*=()

*/

/*!

    \fn const QPoint operator*(qreal factor, const QPoint &point)

    \overload

    \relates QPoint

    Returns a copy of the given \a point multiplied by the given \a factor.

*/

/*!

    \fn const QPoint operator-(const QPoint &point)

    \overload

    \relates QPoint

    Returns a QPoint object that is formed by changing the sign of

    both components of the given \a point.

    Equivalent to \c{QPoint(0,0) - point}.

*/

/*!

    \fn QPoint &QPoint::operator/=(qreal divisor)

    \overload

    Divides both x and y by the given \a divisor, and returns a reference to this

    point. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 6

    Note that the result is rounded to the nearest integer as points are held as

    integers. Use QPointF for floating point accuracy.

    \sa operator*=()

*/

/*!

    \fn const QPoint operator/(const QPoint &point, qreal divisor)

    \relates QPoint

    Returns the QPoint formed by dividing both components of the given \a point

    by the given \a divisor.

    Note that the result is rounded to the nearest integer as points are held as

    integers. Use QPointF for floating point accuracy.

    \sa QPoint::operator/=()

*/

/*****************************************************************************

  QPoint stream functions

 *****************************************************************************/

#ifndef QT_NO_DATASTREAM

/*!

    \fn QDataStream &operator<<(QDataStream &stream, const QPoint &point)

    \relates QPoint

    Writes the given \a point to the given \a stream and returns a

    reference to the stream.

    \sa {Format of the QDataStream Operators}

*/

QDataStream &operator<<(QDataStream &s, const QPoint &p)

{

    if (s.version() == 1)

        s << (qint16)p.x() << (qint16)p.y();

    else

        s << (qint32)p.x() << (qint32)p.y();

    return s;

}

/*!

    \fn QDataStream &operator>>(QDataStream &stream, QPoint &point)

    \relates QPoint

    Reads a point from the given \a stream into the given \a point

    and returns a reference to the stream.

    \sa {Format of the QDataStream Operators}

*/

QDataStream &operator>>(QDataStream &s, QPoint &p)

{

    if (s.version() == 1) {

        qint16 x, y;

        s >> x;  p.rx() = x;

        s >> y;  p.ry() = y;

    }

    else {

        qint32 x, y;

        s >> x;  p.rx() = x;

        s >> y;  p.ry() = y;

    }

    return s;

}

#endif // QT_NO_DATASTREAM

/*!

    Returns the sum of the absolute values of x() and y(),

    traditionally known as the "Manhattan length" of the vector from

    the origin to the point. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 7

    This is a useful, and quick to calculate, approximation to the

    true length:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 8

    The tradition of "Manhattan length" arises because such distances

    apply to travelers who can only travel on a rectangular grid, like

    the streets of Manhattan.

*/

int QPoint::manhattanLength() const

{

    return qAbs(x())+qAbs(y());

}

#ifndef QT_NO_DEBUG_STREAM

QDebug operator<<(QDebug dbg, const QPoint &p) {

    dbg.nospace() << "QPoint(" << p.x() << ',' << p.y() << ')';

    return dbg.space();

}

QDebug operator<<(QDebug d, const QPointF &p)

{

    d.nospace() << "QPointF(" << p.x() << ", " << p.y() << ')';

    return d;

}

#endif

/*!

    \class QPointF

    \ingroup painting

    \brief The QPointF class defines a point in the plane using

    floating point precision.

    A point is specified by a x coordinate and an y coordinate which

    can be accessed using the x() and y() functions. The coordinates

    of the point are specified using floating point numbers for

    accuracy. The isNull() function returns true if both x and y are

    set to 0.0. The coordinates can be set (or altered) using the setX()

    and setY() functions, or alternatively the rx() and ry() functions which

    return references to the coordinates (allowing direct

    manipulation).

    Given a point \e p, the following statements are all equivalent:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 9

    A QPointF object can also be used as a vector: Addition and

    subtraction are defined as for vectors (each component is added

    separately). A QPointF object can also be divided or multiplied by

    an \c int or a \c qreal.

    In addition, the QPointF class provides a constructor converting a

    QPoint object into a QPointF object, and a corresponding toPoint()

    function which returns a QPoint copy of \e this point. Finally,

    QPointF objects can be streamed as well as compared.

    \sa QPoint, QPolygonF

*/

/*!

    \fn QPointF::QPointF()

    Constructs a null point, i.e. with coordinates (0.0, 0.0)

    \sa isNull()

*/

/*!

    \fn QPointF::QPointF(const QPoint &point)

    Constructs a copy of the given \a point.

    \sa toPoint()

*/

/*!

    \fn QPointF::QPointF(qreal x, qreal y)

    Constructs a point with the given coordinates (\a x, \a y).

    \sa setX(), setY()

*/

/*!

    \fn bool QPointF::isNull() const

    Returns true if both the x and y coordinates are set to 0.0,

    otherwise returns false.

*/

/*!

    \since 4.6

    Returns the sum of the absolute values of x() and y(),

    traditionally known as the "Manhattan length" of the vector from

    the origin to the point.

    \sa QPoint::manhattanLength()

*/

qreal QPointF::manhattanLength() const

{

    return qAbs(x())+qAbs(y());

}

/*!

    \fn qreal QPointF::x() const

    Returns the x-coordinate of this point.

    \sa setX(), rx()

*/

/*!

    \fn qreal QPointF::y() const

    Returns the y-coordinate of this point.

    \sa setY(), ry()

*/

/*!

    \fn void QPointF::setX(qreal x)

    Sets the x coordinate of this point to the given \a x coordinate.

    \sa x() setY()

*/

/*!

    \fn void QPointF::setY(qreal y)

    Sets the y coordinate of this point to the given \a y coordinate.

    \sa  y(), setX()

*/

/*!

    \fn qreal& QPointF::rx()

    Returns a reference to the x coordinate of this point.

    Using a reference makes it possible to directly manipulate x. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 10

    \sa x(), setX()

*/

/*!

    \fn qreal& QPointF::ry()

    Returns a reference to the y coordinate of this point.

    Using a reference makes it possible to directly manipulate y. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 11

    \sa y() setY()

*/

/*!

    \fn QPointF& QPointF::operator+=(const QPointF &point)

    Adds the given \a point to this point and returns a reference to

    this point. For example:

    \snippet doc/src/snippets/code/src_corelib_tools_qpoint.cpp 12

    \sa operator-=()

*/

/*!

    \fn QPointF& QPointF::operator-=(const QPointF &point)