/************************************************************** * * 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 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. * *************************************************************/ // MARKER(update_precomp.py): autogen include statement, do not remove #include "precompiled_sdext.hxx" #include "PresenterGeometryHelper.hxx" #include #include using namespace ::com::sun::star; using namespace ::com::sun::star::uno; namespace { sal_Int32 Right (const awt::Rectangle& rBox) { return rBox.X + rBox.Width - 1; } sal_Int32 Bottom (const awt::Rectangle& rBox) { return rBox.Y + rBox.Height - 1; } sal_Int32 Width (const sal_Int32 nLeft, const sal_Int32 nRight) { return nRight - nLeft + 1; } sal_Int32 Height (const sal_Int32 nTop, const sal_Int32 nBottom) { return nBottom - nTop + 1; } } // end of anonymous namespace namespace sdext { namespace presenter { sal_Int32 PresenterGeometryHelper::Floor (const double nValue) { return sal::static_int_cast(floor(nValue)); } sal_Int32 PresenterGeometryHelper::Ceil (const double nValue) { return sal::static_int_cast(ceil(nValue)); } sal_Int32 PresenterGeometryHelper::Round (const double nValue) { return sal::static_int_cast(floor(0.5 + nValue)); } awt::Rectangle PresenterGeometryHelper::ConvertRectangle ( const geometry::RealRectangle2D& rBox) { const sal_Int32 nLeft (Floor(rBox.X1)); const sal_Int32 nTop (Floor(rBox.Y1)); const sal_Int32 nRight (Ceil(rBox.X2)); const sal_Int32 nBottom (Ceil(rBox.Y2)); return awt::Rectangle (nLeft,nTop,nRight-nLeft,nBottom-nTop); } awt::Rectangle PresenterGeometryHelper::ConvertRectangleWithConstantSize ( const geometry::RealRectangle2D& rBox) { return awt::Rectangle ( Round(rBox.X1), Round(rBox.Y1), Round(rBox.X2 - rBox.X1), Round(rBox.Y2 - rBox.Y1)); } geometry::RealRectangle2D PresenterGeometryHelper::ConvertRectangle ( const css::awt::Rectangle& rBox) { return geometry::RealRectangle2D( rBox.X, rBox.Y, rBox.X + rBox.Width, rBox.Y + rBox.Height); } awt::Rectangle PresenterGeometryHelper::TranslateRectangle ( const css::awt::Rectangle& rBox, const sal_Int32 nXOffset, const sal_Int32 nYOffset) { return awt::Rectangle(rBox.X + nXOffset, rBox.Y + nYOffset, rBox.Width, rBox.Height); } awt::Rectangle PresenterGeometryHelper::Intersection ( const css::awt::Rectangle& rBox1, const css::awt::Rectangle& rBox2) { const sal_Int32 nLeft (::std::max(rBox1.X, rBox2.X)); const sal_Int32 nTop (::std::max(rBox1.Y, rBox2.Y)); const sal_Int32 nRight (::std::min(Right(rBox1), Right(rBox2))); const sal_Int32 nBottom (::std::min(Bottom(rBox1), Bottom(rBox2))); if (nLeft >= nRight || nTop >= nBottom) return awt::Rectangle(); else return awt::Rectangle(nLeft,nTop, Width(nLeft,nRight), Height(nTop,nBottom)); } geometry::RealRectangle2D PresenterGeometryHelper::Intersection ( const geometry::RealRectangle2D& rBox1, const geometry::RealRectangle2D& rBox2) { const double nLeft (::std::max(rBox1.X1, rBox2.X1)); const double nTop (::std::max(rBox1.Y1, rBox2.Y1)); const double nRight (::std::min(rBox1.X2, rBox2.X2)); const double nBottom (::std::min(rBox1.Y2, rBox2.Y2)); if (nLeft >= nRight || nTop >= nBottom) return geometry::RealRectangle2D(0,0,0,0); else return geometry::RealRectangle2D(nLeft,nTop, nRight, nBottom); } bool PresenterGeometryHelper::IsInside ( const css::geometry::RealRectangle2D& rBox, const css::geometry::RealPoint2D& rPoint) { return rBox.X1 <= rPoint.X && rBox.Y1 <= rPoint.Y && rBox.X2 >= rPoint.X && rBox.Y2 >= rPoint.Y; } bool PresenterGeometryHelper::IsInside ( const css::awt::Rectangle& rBox1, const css::awt::Rectangle& rBox2) { return rBox1.X >= rBox2.X && rBox1.Y >= rBox2.Y && rBox1.X+rBox1.Width <= rBox2.X+rBox2.Width && rBox1.Y+rBox1.Height <= rBox2.Y+rBox2.Height; } awt::Rectangle PresenterGeometryHelper::Union ( const css::awt::Rectangle& rBox1, const css::awt::Rectangle& rBox2) { if (rBox1.Width<=0 || rBox1.Height<=0) return rBox2; else if (rBox2.Width<=0 || rBox2.Height<=0) return rBox1; const sal_Int32 nLeft (::std::min(rBox1.X, rBox2.X)); const sal_Int32 nTop (::std::min(rBox1.Y, rBox2.Y)); const sal_Int32 nRight (::std::max(Right(rBox1), Right(rBox2))); const sal_Int32 nBottom (::std::max(Bottom(rBox1), Bottom(rBox2))); if (nLeft >= nRight || nTop >= nBottom) return awt::Rectangle(); else return awt::Rectangle(nLeft,nTop, Width(nLeft,nRight), Height(nTop,nBottom)); } geometry::RealRectangle2D PresenterGeometryHelper::Union ( const geometry::RealRectangle2D& rBox1, const geometry::RealRectangle2D& rBox2) { const double nLeft (::std::min(rBox1.X1, rBox2.X1)); const double nTop (::std::min(rBox1.Y1, rBox2.Y1)); const double nRight (::std::max(rBox1.X2, rBox2.X2)); const double nBottom (::std::max(rBox1.Y2, rBox2.Y2)); if (nLeft >= nRight || nTop >= nBottom) return geometry::RealRectangle2D(0,0,0,0); else return geometry::RealRectangle2D(nLeft,nTop, nRight, nBottom); } bool PresenterGeometryHelper::AreRectanglesDisjoint ( const css::awt::Rectangle& rBox1, const css::awt::Rectangle& rBox2) { return rBox1.X+rBox1.Width <= rBox2.X || rBox1.Y+rBox1.Height <= rBox2.Y || rBox1.X >= rBox2.X+rBox2.Width || rBox1.Y >= rBox2.Y+rBox2.Height; } Reference PresenterGeometryHelper::CreatePolygon( const awt::Rectangle& rBox, const Reference& rxDevice) { if ( ! rxDevice.is()) return NULL; Sequence > aPoints(1); aPoints[0] = Sequence(4); aPoints[0][0] = geometry::RealPoint2D(rBox.X, rBox.Y); aPoints[0][1] = geometry::RealPoint2D(rBox.X, rBox.Y+rBox.Height); aPoints[0][2] = geometry::RealPoint2D(rBox.X+rBox.Width, rBox.Y+rBox.Height); aPoints[0][3] = geometry::RealPoint2D(rBox.X+rBox.Width, rBox.Y); Reference xPolygon ( rxDevice->createCompatibleLinePolyPolygon(aPoints)); Reference xRectangle (xPolygon, UNO_QUERY); if (xRectangle.is()) xRectangle->setClosed(0, sal_True); return xRectangle; } Reference PresenterGeometryHelper::CreatePolygon( const geometry::RealRectangle2D& rBox, const Reference& rxDevice) { if ( ! rxDevice.is()) return NULL; Sequence > aPoints(1); aPoints[0] = Sequence(4); aPoints[0][0] = geometry::RealPoint2D(rBox.X1, rBox.Y1); aPoints[0][1] = geometry::RealPoint2D(rBox.X1, rBox.Y2); aPoints[0][2] = geometry::RealPoint2D(rBox.X2, rBox.Y2); aPoints[0][3] = geometry::RealPoint2D(rBox.X2, rBox.Y1); Reference xPolygon ( rxDevice->createCompatibleLinePolyPolygon(aPoints)); Reference xRectangle (xPolygon, UNO_QUERY); if (xRectangle.is()) xRectangle->setClosed(0, sal_True); return xRectangle; } Reference PresenterGeometryHelper::CreatePolygon( const ::std::vector& rBoxes, const Reference& rxDevice) { if ( ! rxDevice.is()) return NULL; const sal_Int32 nCount (rBoxes.size()); Sequence > aPoints(nCount); for (sal_Int32 nIndex=0; nIndex(4); aPoints[nIndex][0] = geometry::RealPoint2D(rBox.X, rBox.Y); aPoints[nIndex][1] = geometry::RealPoint2D(rBox.X, rBox.Y+rBox.Height); aPoints[nIndex][2] = geometry::RealPoint2D(rBox.X+rBox.Width, rBox.Y+rBox.Height); aPoints[nIndex][3] = geometry::RealPoint2D(rBox.X+rBox.Width, rBox.Y); } Reference xPolygon ( rxDevice->createCompatibleLinePolyPolygon(aPoints)); Reference xRectangle (xPolygon, UNO_QUERY); if (xRectangle.is()) for (sal_Int32 nIndex=0; nIndexsetClosed(nIndex, sal_True); return xRectangle; } } }