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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*
* This file is part of the LibreOffice project.
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*
* This file incorporates work covered by the following license notice:
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed
* with this work for additional information regarding copyright
* ownership. The ASF licenses this file to you under the Apache
* License, Version 2.0 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy of
* the License at http://www.apache.org/licenses/LICENSE-2.0 .
*/
#pragma once
#include <basegfx/range/basicrange.hxx>
#include <basegfx/tuple/Tuple2D.hxx>
namespace basegfx
{
template <typename TYPE, typename TRAITS> class Range2D
{
protected:
basegfx::BasicRange<TYPE, TRAITS> maRangeX;
basegfx::BasicRange<TYPE, TRAITS> maRangeY;
public:
typedef TYPE ValueType;
typedef TRAITS TraitsType;
Range2D() = default;
/// Create degenerate interval consisting of a single point
explicit Range2D(const Tuple2D<TYPE>& rTuple)
: maRangeX(rTuple.getX())
, maRangeY(rTuple.getY())
{
}
/// Create proper interval between the two given points
Range2D(const Tuple2D<TYPE>& rTuple1, const Tuple2D<TYPE>& rTuple2)
: maRangeX(rTuple1.getX())
, maRangeY(rTuple1.getY())
{
expand(rTuple2);
}
/// Create proper interval between the two given pairs
Range2D(TYPE x1, TYPE y1, TYPE x2, TYPE y2)
: maRangeX(x1)
, maRangeY(y1)
{
maRangeX.expand(x2);
maRangeY.expand(y2);
}
/** Check if the interval set is empty
@return false, if no value is in this set - having a
single point included will already return true.
*/
bool isEmpty() const { return maRangeX.isEmpty() || maRangeY.isEmpty(); }
/// reset the object to empty state again, clearing all values
void reset()
{
maRangeX.reset();
maRangeY.reset();
}
bool operator==(const Range2D& rRange) const
{
return maRangeX == rRange.maRangeX && maRangeY == rRange.maRangeY;
}
bool operator!=(const Range2D& rRange) const
{
return maRangeX != rRange.maRangeX || maRangeY != rRange.maRangeY;
}
bool equal(const Range2D& rRange) const
{
return maRangeX.equal(rRange.maRangeX) && maRangeY.equal(rRange.maRangeY);
}
/// get lower bound of the set. returns arbitrary values for empty sets.
TYPE getMinX() const { return maRangeX.getMinimum(); }
/// get lower bound of the set. returns arbitrary values for empty sets.
TYPE getMinY() const { return maRangeY.getMinimum(); }
/// get upper bound of the set. returns arbitrary values for empty sets.
TYPE getMaxX() const { return maRangeX.getMaximum(); }
/// get upper bound of the set. returns arbitrary values for empty sets.
TYPE getMaxY() const { return maRangeY.getMaximum(); }
/// return difference between upper and lower X value. returns 0 for empty sets.
TYPE getWidth() const { return maRangeX.getRange(); }
/// return difference between upper and lower Y value. returns 0 for empty sets.
TYPE getHeight() const { return maRangeY.getRange(); }
/// return center X value of set. returns 0 for empty sets.
double getCenterX() const { return maRangeX.getCenter(); }
/// return center Y value of set. returns 0 for empty sets.
double getCenterY() const { return maRangeY.getCenter(); }
/// yields true if given point is contained in set
bool isInside(const Tuple2D<TYPE>& rTuple) const
{
return maRangeX.isInside(rTuple.getX()) && maRangeY.isInside(rTuple.getY());
}
/// yields true if rRange is inside, or equal to set
bool isInside(const Range2D& rRange) const
{
return maRangeX.isInside(rRange.maRangeX) && maRangeY.isInside(rRange.maRangeY);
}
/// yields true if rRange at least partly inside set
bool overlaps(const Range2D& rRange) const
{
return maRangeX.overlaps(rRange.maRangeX) && maRangeY.overlaps(rRange.maRangeY);
}
/// yields true if overlaps(rRange) does, and the overlap is larger than infinitesimal
bool overlapsMore(const Range2D& rRange) const
{
return maRangeX.overlapsMore(rRange.maRangeX) && maRangeY.overlapsMore(rRange.maRangeY);
}
/// add point to the set, expanding as necessary
void expand(const Tuple2D<TYPE>& rTuple)
{
maRangeX.expand(rTuple.getX());
maRangeY.expand(rTuple.getY());
}
/// add rRange to the set, expanding as necessary
void expand(const Range2D& rRange)
{
maRangeX.expand(rRange.maRangeX);
maRangeY.expand(rRange.maRangeY);
}
/// calc set intersection
void intersect(const Range2D& rRange)
{
maRangeX.intersect(rRange.maRangeX);
maRangeY.intersect(rRange.maRangeY);
}
/// grow set by fValue on all sides
void grow(TYPE fValue)
{
maRangeX.grow(fValue);
maRangeY.grow(fValue);
}
/// grow set by axis aware values from rTuple
void grow(const Tuple2D<TYPE>& rTuple)
{
maRangeX.grow(rTuple.getX());
maRangeY.grow(rTuple.getY());
}
/// clamp value on range
Tuple2D<TYPE> clamp(const Tuple2D<TYPE>& rTuple) const
{
return Tuple2D<TYPE>(maRangeX.clamp(rTuple.getX()), maRangeY.clamp(rTuple.getY()));
}
};
} // end of namespace basegfx
/* vim:set shiftwidth=4 softtabstop=4 expandtab: */
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