/* -*- 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 #include #include #include #include #include #include namespace basegfx { class B2IRange; class B2DHomMatrix; /** A two-dimensional interval over doubles This is a set of real numbers, bounded by a lower and an upper pair. All inbetween values are included in the set (see also http://en.wikipedia.org/wiki/Interval_%28mathematics%29). The set is closed, i.e. the upper and the lower bound are included (if you're used to the notation - we're talking about [a,b] here, compared to half-open [a,b) or open intervals (a,b)). That means, isInside(val) will return true also for values of val=a or val=b. @see B1DRange */ class SAL_WARN_UNUSED B2DRange { public: typedef double ValueType; typedef DoubleTraits TraitsType; B2DRange() {} /// Create degenerate interval consisting of a single point explicit B2DRange(const B2DTuple& rTuple) : maRangeX(rTuple.getX()), maRangeY(rTuple.getY()) { } /// Create proper interval between the two given double pairs B2DRange(double x1, double y1, double x2, double y2) : maRangeX(x1), maRangeY(y1) { maRangeX.expand(x2); maRangeY.expand(y2); } /// Create proper interval between the two given points B2DRange(const B2DTuple& rTuple1, const B2DTuple& rTuple2) : maRangeX(rTuple1.getX()), maRangeY(rTuple1.getY()) { expand( rTuple2 ); } BASEGFX_DLLPUBLIC explicit B2DRange(const B2IRange& rRange); /** 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 B2DRange& rRange ) const { return (maRangeX == rRange.maRangeX && maRangeY == rRange.maRangeY); } bool operator!=( const B2DRange& rRange ) const { return (maRangeX != rRange.maRangeX || maRangeY != rRange.maRangeY); } bool equal(const B2DRange& rRange) const { return (maRangeX.equal(rRange.maRangeX) && maRangeY.equal(rRange.maRangeY)); } /// get lower bound of the set. returns arbitrary values for empty sets. double getMinX() const { return maRangeX.getMinimum(); } /// get lower bound of the set. returns arbitrary values for empty sets. double getMinY() const { return maRangeY.getMinimum(); } /// get upper bound of the set. returns arbitrary values for empty sets. double getMaxX() const { return maRangeX.getMaximum(); } /// get upper bound of the set. returns arbitrary values for empty sets. double getMaxY() const { return maRangeY.getMaximum(); } /// return difference between upper and lower X value. returns 0 for empty sets. double getWidth() const { return maRangeX.getRange(); } /// return difference between upper and lower Y value. returns 0 for empty sets. double getHeight() const { return maRangeY.getRange(); } /// get lower bound of the set. returns arbitrary values for empty sets. B2DPoint getMinimum() const { return B2DPoint( maRangeX.getMinimum(), maRangeY.getMinimum() ); } /// get upper bound of the set. returns arbitrary values for empty sets. B2DPoint getMaximum() const { return B2DPoint( maRangeX.getMaximum(), maRangeY.getMaximum() ); } /// return difference between upper and lower point. returns (0,0) for empty sets. B2DVector getRange() const { return B2DVector( maRangeX.getRange(), maRangeY.getRange() ); } /// return center point of set. returns (0,0) for empty sets. B2DPoint getCenter() const { return B2DPoint( maRangeX.getCenter(), maRangeY.getCenter() ); } /// 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 B2DTuple& rTuple) const { return ( maRangeX.isInside(rTuple.getX()) && maRangeY.isInside(rTuple.getY()) ); } /// yields true if rRange is inside, or equal to set bool isInside(const B2DRange& rRange) const { return ( maRangeX.isInside(rRange.maRangeX) && maRangeY.isInside(rRange.maRangeY) ); } /// yields true if rRange at least partly inside set bool overlaps(const B2DRange& 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 B2DRange& rRange) const { return ( maRangeX.overlapsMore(rRange.maRangeX) && maRangeY.overlapsMore(rRange.maRangeY) ); } /// add point to the set, expanding as necessary void expand(const B2DTuple& rTuple) { maRangeX.expand(rTuple.getX()); maRangeY.expand(rTuple.getY()); } /// add rRange to the set, expanding as necessary void expand(const B2DRange& rRange) { maRangeX.expand(rRange.maRangeX); maRangeY.expand(rRange.maRangeY); } /// calc set intersection void intersect(const B2DRange& rRange) { maRangeX.intersect(rRange.maRangeX); maRangeY.intersect(rRange.maRangeY); } /// grow set by fValue on all sides void grow(double fValue) { maRangeX.grow(fValue); maRangeY.grow(fValue); } /// clamp value on range B2DTuple clamp(const B2DTuple& rTuple) const { return B2DTuple( maRangeX.clamp(rTuple.getX()), maRangeY.clamp(rTuple.getY())); } /** Transform Range by given transformation matrix. */ BASEGFX_DLLPUBLIC void transform(const B2DHomMatrix& rMatrix); /** Transform Range by given transformation matrix. This operation transforms the Range by transforming all four possible extrema points (corners) of the given range and building a new one. This means that the range will grow evtl. when a shear and/or rotation is part of the transformation. */ BASEGFX_DLLPUBLIC B2DRange& operator*=( const ::basegfx::B2DHomMatrix& rMat ); /** Get a range filled with (0.0, 0.0, 1.0, 1.0) */ static const B2DRange& getUnitB2DRange(); private: typedef ::basegfx::BasicRange< ValueType, TraitsType > MyBasicRange; MyBasicRange maRangeX; MyBasicRange maRangeY; }; /** Transform B2DRange by given transformation matrix (see operator*=()) */ B2DRange operator*( const B2DHomMatrix& rMat, const B2DRange& rB2DRange ); /** Round double to nearest integer for 2D range @return the nearest integer for this range */ BASEGFX_DLLPUBLIC B2IRange fround(const B2DRange& rRange); /** Compute the set difference of the two given ranges This method calculates the symmetric difference (aka XOR) between the two given ranges, and returning the resulting ranges. Thus, the result will contain all areas where one, but not both ranges lie. @param o_rResult Result vector. The up to four difference ranges are returned within this vector @param rFirst The first range @param rSecond The second range @return the input vector */ BASEGFX_DLLPUBLIC ::std::vector< B2DRange >& computeSetDifference( ::std::vector< B2DRange >& o_rResult, const B2DRange& rFirst, const B2DRange& rSecond ); template< typename charT, typename traits > inline std::basic_ostream & operator <<( std::basic_ostream & stream, const B2DRange& range ) { return stream << range.getWidth() << "x" << range.getHeight() << "@" << range.getMinimum(); } } // end of namespace basegfx /* vim:set shiftwidth=4 softtabstop=4 expandtab: */