/* -*- 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 . */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace { /** Return when the given polygon is rectiliner and oriented so that all sides are either horizontal or vertical. */ bool ImplIsPolygonRectilinear (const tools::PolyPolygon& rPolyPoly) { // Iterate over all polygons. const sal_uInt16 nPolyCount = rPolyPoly.Count(); for (sal_uInt16 nPoly = 0; nPoly < nPolyCount; ++nPoly) { const Polygon& aPoly = rPolyPoly.GetObject(nPoly); // Iterate over all edges of the current polygon. const sal_uInt16 nSize = aPoly.GetSize(); if (nSize < 2) continue; Point aPoint (aPoly.GetPoint(0)); const Point aLastPoint (aPoint); for (sal_uInt16 nPoint = 1; nPoint < nSize; ++nPoint) { const Point aNextPoint (aPoly.GetPoint(nPoint)); // When there is at least one edge that is neither vertical nor // horizontal then the entire polygon is not rectilinear (and // oriented along primary axes.) if (aPoint.X() != aNextPoint.X() && aPoint.Y() != aNextPoint.Y()) return false; aPoint = aNextPoint; } // Compare closing edge. if (aLastPoint.X() != aPoint.X() && aLastPoint.Y() != aPoint.Y()) return false; } return true; } /** Convert a rectilinear polygon (that is oriented along the primary axes) to a list of bands. For this special form of polygon we can use an optimization that prevents the creation of one band per y value. However, it still is possible that some temporary bands are created that later can be optimized away. @param rPolyPolygon A set of zero, one, or more polygons, nested or not, that are converted into a list of bands. @return A new RegionBand object is returned that contains the bands that represent the given poly-polygon. */ RegionBand* ImplRectilinearPolygonToBands(const tools::PolyPolygon& rPolyPoly) { OSL_ASSERT(ImplIsPolygonRectilinear (rPolyPoly)); // Create a new RegionBand object as container of the bands. RegionBand* pRegionBand = new RegionBand(); long nLineId = 0L; // Iterate over all polygons. const sal_uInt16 nPolyCount = rPolyPoly.Count(); for (sal_uInt16 nPoly = 0; nPoly < nPolyCount; ++nPoly) { const Polygon& aPoly = rPolyPoly.GetObject(nPoly); // Iterate over all edges of the current polygon. const sal_uInt16 nSize = aPoly.GetSize(); if (nSize < 2) continue; // Avoid fetching every point twice (each point is the start point // of one and the end point of another edge.) Point aStart (aPoly.GetPoint(0)); Point aEnd; for (sal_uInt16 nPoint = 1; nPoint <= nSize; ++nPoint, aStart=aEnd) { // We take the implicit closing edge into account by mapping // index nSize to 0. aEnd = aPoly.GetPoint(nPoint%nSize); if (aStart.Y() == aEnd.Y()) { // Horizontal lines are ignored. continue; } // At this point the line has to be vertical. OSL_ASSERT(aStart.X() == aEnd.X()); // Sort y-coordinates to simplify the algorithm and store the // direction separately. The direction is calculated as it is // in other places (but seems to be the wrong way.) const long nTop (::std::min(aStart.Y(), aEnd.Y())); const long nBottom (::std::max(aStart.Y(), aEnd.Y())); const LineType eLineType (aStart.Y() > aEnd.Y() ? LINE_DESCENDING : LINE_ASCENDING); // Make sure that the current line is covered by bands. pRegionBand->ImplAddMissingBands(nTop,nBottom); // Find top-most band that may contain nTop. ImplRegionBand* pBand = pRegionBand->ImplGetFirstRegionBand(); while (pBand!=NULL && pBand->mnYBottom < nTop) pBand = pBand->mpNextBand; ImplRegionBand* pTopBand = pBand; // If necessary split the band at nTop so that nTop is contained // in the lower band. if (pBand!=NULL // Prevent the current band from becoming 0 pixel high && pBand->mnYTopmnYBottom>=nTop // do not split a band that is just one pixel high && pBand->mnYTopmnYBottom) { // Split the top band. pTopBand = pBand->SplitBand(nTop); } // Advance to band that may contain nBottom. while (pBand!=NULL && pBand->mnYBottom < nBottom) pBand = pBand->mpNextBand; // The lowest band may have to be split at nBottom so that // nBottom itself remains in the upper band. if (pBand!=NULL // allow the current band becoming 1 pixel high && pBand->mnYTop<=nBottom // prevent splitting off a band that is 0 pixel high && pBand->mnYBottom>nBottom // do not split a band that is just one pixel high && pBand->mnYTopmnYBottom) { // Split the bottom band. pBand->SplitBand(nBottom+1); } // Note that we remember the top band (in pTopBand) but not the // bottom band. The later can be determined by comparing y // coordinates. // Add the x-value as point to all bands in the nTop->nBottom range. for (pBand=pTopBand; pBand!=NULL&&pBand->mnYTop<=nBottom; pBand=pBand->mpNextBand) pBand->InsertPoint(aStart.X(), nLineId++, true, eLineType); } } return pRegionBand; } /** Convert a general polygon (one for which ImplIsPolygonRectilinear() returns ) to bands. */ RegionBand* ImplGeneralPolygonToBands(const tools::PolyPolygon& rPolyPoly, const Rectangle& rPolygonBoundingBox) { long nLineID = 0L; // initialisation and creation of Bands RegionBand* pRegionBand = new RegionBand(); pRegionBand->CreateBandRange(rPolygonBoundingBox.Top(), rPolygonBoundingBox.Bottom()); // insert polygons const sal_uInt16 nPolyCount = rPolyPoly.Count(); for ( sal_uInt16 nPoly = 0; nPoly < nPolyCount; nPoly++ ) { // get reference to current polygon const Polygon& aPoly = rPolyPoly.GetObject( nPoly ); const sal_uInt16 nSize = aPoly.GetSize(); // not enough points ( <= 2 )? -> nothing to do! if ( nSize <= 2 ) continue; // band the polygon for ( sal_uInt16 nPoint = 1; nPoint < nSize; nPoint++ ) { pRegionBand->InsertLine( aPoly.GetPoint(nPoint-1), aPoly.GetPoint(nPoint), nLineID++ ); } // close polygon with line from first point to last point, if necessary const Point rLastPoint = aPoly.GetPoint(nSize-1); const Point rFirstPoint = aPoly.GetPoint(0); if ( rLastPoint != rFirstPoint ) { pRegionBand->InsertLine( rLastPoint, rFirstPoint, nLineID++ ); } } return pRegionBand; } } // end of anonymous namespace namespace vcl { bool vcl::Region::IsEmpty() const { return !mbIsNull && !mpB2DPolyPolygon.get() && !mpPolyPolygon.get() && !mpRegionBand.get(); } RegionBand* ImplCreateRegionBandFromPolyPolygon(const tools::PolyPolygon& rPolyPolygon) { RegionBand* pRetval = 0; if(rPolyPolygon.Count()) { // ensure to subdivide when bezier segemnts are used, it's going to // be expanded to rectangles tools::PolyPolygon aPolyPolygon; rPolyPolygon.AdaptiveSubdivide(aPolyPolygon); if(aPolyPolygon.Count()) { const Rectangle aRect(aPolyPolygon.GetBoundRect()); if(!aRect.IsEmpty()) { if(ImplIsPolygonRectilinear(aPolyPolygon)) { // For rectilinear polygons there is an optimized band conversion. pRetval = ImplRectilinearPolygonToBands(aPolyPolygon); } else { pRetval = ImplGeneralPolygonToBands(aPolyPolygon, aRect); } // Convert points into seps. if(pRetval) { pRetval->processPoints(); // Optimize list of bands. Adjacent bands with identical lists // of seps are joined. if(!pRetval->OptimizeBandList()) { delete pRetval; pRetval = 0; } } } } } return pRetval; } tools::PolyPolygon vcl::Region::ImplCreatePolyPolygonFromRegionBand() const { tools::PolyPolygon aRetval; if(getRegionBand()) { RectangleVector aRectangles; GetRegionRectangles(aRectangles); for(RectangleVector::const_iterator aRectIter(aRectangles.begin()); aRectIter != aRectangles.end(); ++aRectIter) { aRetval.Insert(Polygon(*aRectIter)); } } else { OSL_ENSURE(false, "Called with no local RegionBand (!)"); } return aRetval; } basegfx::B2DPolyPolygon vcl::Region::ImplCreateB2DPolyPolygonFromRegionBand() const { tools::PolyPolygon aPoly(ImplCreatePolyPolygonFromRegionBand()); return aPoly.getB2DPolyPolygon(); } Region::Region(bool bIsNull) : mpB2DPolyPolygon(), mpPolyPolygon(), mpRegionBand(), mbIsNull(bIsNull) { } Region::Region(const Rectangle& rRect) : mpB2DPolyPolygon(), mpPolyPolygon(), mpRegionBand(), mbIsNull(false) { mpRegionBand.reset(rRect.IsEmpty() ? 0 : new RegionBand(rRect)); } Region::Region(const Polygon& rPolygon) : mpB2DPolyPolygon(), mpPolyPolygon(), mpRegionBand(), mbIsNull(false) { if(rPolygon.GetSize()) { ImplCreatePolyPolyRegion(rPolygon); } } Region::Region(const tools::PolyPolygon& rPolyPoly) : mpB2DPolyPolygon(), mpPolyPolygon(), mpRegionBand(), mbIsNull(false) { if(rPolyPoly.Count()) { ImplCreatePolyPolyRegion(rPolyPoly); } } Region::Region(const basegfx::B2DPolyPolygon& rPolyPoly) : mpB2DPolyPolygon(), mpPolyPolygon(), mpRegionBand(), mbIsNull(false) { if(rPolyPoly.count()) { ImplCreatePolyPolyRegion(rPolyPoly); } } Region::Region(const vcl::Region& rRegion) : mpB2DPolyPolygon(rRegion.mpB2DPolyPolygon), mpPolyPolygon(rRegion.mpPolyPolygon), mpRegionBand(rRegion.mpRegionBand), mbIsNull(rRegion.mbIsNull) { } Region::~Region() { } void vcl::Region::ImplCreatePolyPolyRegion( const tools::PolyPolygon& rPolyPoly ) { const sal_uInt16 nPolyCount = rPolyPoly.Count(); if(nPolyCount) { // polypolygon empty? -> empty region const Rectangle aRect(rPolyPoly.GetBoundRect()); if(!aRect.IsEmpty()) { // width OR height == 1 ? => Rectangular region if((1 == aRect.GetWidth()) || (1 == aRect.GetHeight()) || rPolyPoly.IsRect()) { mpRegionBand.reset(new RegionBand(aRect)); } else { mpPolyPolygon.reset(new tools::PolyPolygon(rPolyPoly)); } mbIsNull = false; } } } void vcl::Region::ImplCreatePolyPolyRegion( const basegfx::B2DPolyPolygon& rPolyPoly ) { if(rPolyPoly.count() && !rPolyPoly.getB2DRange().isEmpty()) { mpB2DPolyPolygon.reset(new basegfx::B2DPolyPolygon(rPolyPoly)); mbIsNull = false; } } void vcl::Region::Move( long nHorzMove, long nVertMove ) { if(IsNull() || IsEmpty()) { // empty or null need no move return; } if(!nHorzMove && !nVertMove) { // no move defined return; } if(getB2DPolyPolygon()) { basegfx::B2DPolyPolygon aPoly(*getB2DPolyPolygon()); aPoly.transform(basegfx::tools::createTranslateB2DHomMatrix(nHorzMove, nVertMove)); mpB2DPolyPolygon.reset(aPoly.count() ? new basegfx::B2DPolyPolygon(aPoly) : 0); mpPolyPolygon.reset(); mpRegionBand.reset(); } else if(getPolyPolygon()) { tools::PolyPolygon aPoly(*getPolyPolygon()); aPoly.Move(nHorzMove, nVertMove); mpB2DPolyPolygon.reset(); mpPolyPolygon.reset(aPoly.Count() ? new tools::PolyPolygon(aPoly) : 0); mpRegionBand.reset(); } else if(getRegionBand()) { RegionBand* pNew = new RegionBand(*getRegionBand()); pNew->Move(nHorzMove, nVertMove); mpB2DPolyPolygon.reset(); mpPolyPolygon.reset(); mpRegionBand.reset(pNew); } else { OSL_ENSURE(false, "Region::Move error: impossible combination (!)"); } } void vcl::Region::Scale( double fScaleX, double fScaleY ) { if(IsNull() || IsEmpty()) { // empty or null need no scale return; } if(basegfx::fTools::equalZero(fScaleX) && basegfx::fTools::equalZero(fScaleY)) { // no scale defined return; } if(getB2DPolyPolygon()) { basegfx::B2DPolyPolygon aPoly(*getB2DPolyPolygon()); aPoly.transform(basegfx::tools::createScaleB2DHomMatrix(fScaleX, fScaleY)); mpB2DPolyPolygon.reset(aPoly.count() ? new basegfx::B2DPolyPolygon(aPoly) : 0); mpPolyPolygon.reset(); mpRegionBand.reset(); } else if(getPolyPolygon()) { tools::PolyPolygon aPoly(*getPolyPolygon()); aPoly.Scale(fScaleX, fScaleY); mpB2DPolyPolygon.reset(); mpPolyPolygon.reset(aPoly.Count() ? new tools::PolyPolygon(aPoly) : 0); mpRegionBand.reset(); } else if(getRegionBand()) { RegionBand* pNew = new RegionBand(*getRegionBand()); pNew->Scale(fScaleX, fScaleY); mpB2DPolyPolygon.reset(); mpPolyPolygon.reset(); mpRegionBand.reset(pNew); } else { OSL_ENSURE(false, "Region::Scale error: impossible combination (!)"); } } bool vcl::Region::Union( const Rectangle& rRect ) { if(rRect.IsEmpty()) { // empty rectangle will not expand the existing union, nothing to do return true; } if(IsEmpty()) { // no local data, the union will be equal to source. Create using rectangle *this = rRect; return true; } if(HasPolyPolygonOrB2DPolyPolygon()) { // get this B2DPolyPolygon, solve on polygon base basegfx::B2DPolyPolygon aThisPolyPoly(GetAsB2DPolyPolygon()); aThisPolyPoly = basegfx::tools::prepareForPolygonOperation(aThisPolyPoly); if(!aThisPolyPoly.count()) { // no local polygon, use the rectangle as new region *this = rRect; } else { // get the other B2DPolyPolygon and use logical Or-Operation const basegfx::B2DPolygon aRectPoly( basegfx::tools::createPolygonFromRect( basegfx::B2DRectangle( rRect.Left(), rRect.Top(), rRect.Right(), rRect.Bottom()))); const basegfx::B2DPolyPolygon aClip( basegfx::tools::solvePolygonOperationOr( aThisPolyPoly, basegfx::B2DPolyPolygon(aRectPoly))); *this = vcl::Region(aClip); } return true; } // only region band mode possibility left here or null/empty const RegionBand* pCurrent = getRegionBand(); if(!pCurrent) { // no region band, create using the rectangle *this = rRect; return true; } RegionBand* pNew = new RegionBand(*pCurrent); // get justified rectangle const long nLeft(std::min(rRect.Left(), rRect.Right())); const long nTop(std::min(rRect.Top(), rRect.Bottom())); const long nRight(std::max(rRect.Left(), rRect.Right())); const long nBottom(std::max(rRect.Top(), rRect.Bottom())); // insert bands if the boundaries are not already in the list pNew->InsertBands(nTop, nBottom); // process union pNew->Union(nLeft, nTop, nRight, nBottom); // cleanup if(!pNew->OptimizeBandList()) { delete pNew; pNew = 0; } mpRegionBand.reset(pNew); return true; } bool vcl::Region::Intersect( const Rectangle& rRect ) { if ( rRect.IsEmpty() ) { // empty rectangle will create empty region SetEmpty(); return true; } if(IsNull()) { // null region (everything) intersect with rect will give rect *this = rRect; return true; } if(IsEmpty()) { // no content, cannot get more empty return true; } if(HasPolyPolygonOrB2DPolyPolygon()) { // if polygon data prefer double precision, the other will be lost (if buffered) if(getB2DPolyPolygon()) { const basegfx::B2DPolyPolygon aPoly( basegfx::tools::clipPolyPolygonOnRange( *getB2DPolyPolygon(), basegfx::B2DRange( rRect.Left(), rRect.Top(), rRect.Right() + 1, rRect.Bottom() + 1), true, false)); mpB2DPolyPolygon.reset(aPoly.count() ? new basegfx::B2DPolyPolygon(aPoly) : 0); mpPolyPolygon.reset(); mpRegionBand.reset(); } else // if(getPolyPolygon()) { tools::PolyPolygon aPoly(*getPolyPolygon()); // use the PolyPolygon::Clip method for rectangles, this is // fairly simple (does not even use GPC) and saves us from // unnecessary banding aPoly.Clip(rRect); mpB2DPolyPolygon.reset(); mpPolyPolygon.reset(aPoly.Count() ? new tools::PolyPolygon(aPoly) : 0); mpRegionBand.reset(); } return true; } // only region band mode possibility left here or null/empty const RegionBand* pCurrent = getRegionBand(); if(!pCurrent) { // region is empty -> nothing to do! return true; } RegionBand* pNew = new RegionBand(*pCurrent); // get justified rectangle const long nLeft(std::min(rRect.Left(), rRect.Right())); const long nTop(std::min(rRect.Top(), rRect.Bottom())); const long nRight(std::max(rRect.Left(), rRect.Right())); const long nBottom(std::max(rRect.Top(), rRect.Bottom())); // insert bands if the boundaries are not already in the list pNew->InsertBands(nTop, nBottom); // process intersect pNew->Intersect(nLeft, nTop, nRight, nBottom); // cleanup if(!pNew->OptimizeBandList()) { delete pNew; pNew = 0; } mpRegionBand.reset(pNew); return true; } bool vcl::Region::Exclude( const Rectangle& rRect ) { if ( rRect.IsEmpty() ) { // excluding nothing will do no change return true; } if(IsEmpty()) { // cannot exclude from empty, done return true; } if(IsNull()) { // error; cannot exclude from null region since this is not representable // in the data OSL_ENSURE(false, "Region::Exclude error: Cannot exclude from null region (!)"); return true; } if( HasPolyPolygonOrB2DPolyPolygon() ) { // get this B2DPolyPolygon basegfx::B2DPolyPolygon aThisPolyPoly(GetAsB2DPolyPolygon()); aThisPolyPoly = basegfx::tools::prepareForPolygonOperation(aThisPolyPoly); if(!aThisPolyPoly.count()) { // when local polygon is empty, nothing can be excluded return true; } // get the other B2DPolyPolygon const basegfx::B2DPolygon aRectPoly( basegfx::tools::createPolygonFromRect( basegfx::B2DRectangle(rRect.Left(), rRect.Top(), rRect.Right(), rRect.Bottom()))); const basegfx::B2DPolyPolygon aOtherPolyPoly(aRectPoly); const basegfx::B2DPolyPolygon aClip = basegfx::tools::solvePolygonOperationDiff(aThisPolyPoly, aOtherPolyPoly); *this = vcl::Region(aClip); return true; } // only region band mode possibility left here or null/empty const RegionBand* pCurrent = getRegionBand(); if(!pCurrent) { // empty? -> done! return true; } RegionBand* pNew = new RegionBand(*pCurrent); // get justified rectangle const long nLeft(std::min(rRect.Left(), rRect.Right())); const long nTop(std::min(rRect.Top(), rRect.Bottom())); const long nRight(std::max(rRect.Left(), rRect.Right())); const long nBottom(std::max(rRect.Top(), rRect.Bottom())); // insert bands if the boundaries are not already in the list pNew->InsertBands(nTop, nBottom); // process exclude pNew->Exclude(nLeft, nTop, nRight, nBottom); // cleanup if(!pNew->OptimizeBandList()) { delete pNew; pNew = 0; } mpRegionBand.reset(pNew); return true; } bool vcl::Region::XOr( const Rectangle& rRect ) { if ( rRect.IsEmpty() ) { // empty rectangle will not change local content return true; } if(IsEmpty()) { // rRect will be the xored-form (local off, rect on) *this = rRect; return true; } if(IsNull()) { // error; cannot exclude from null region since this is not representable // in the data OSL_ENSURE(false, "Region::XOr error: Cannot XOr with null region (!)"); return true; } if( HasPolyPolygonOrB2DPolyPolygon() ) { // get this B2DPolyPolygon basegfx::B2DPolyPolygon aThisPolyPoly(GetAsB2DPolyPolygon()); aThisPolyPoly = basegfx::tools::prepareForPolygonOperation( aThisPolyPoly ); if(!aThisPolyPoly.count()) { // no local content, XOr will be equal to rectangle *this = rRect; return true; } // get the other B2DPolyPolygon const basegfx::B2DPolygon aRectPoly( basegfx::tools::createPolygonFromRect( basegfx::B2DRectangle(rRect.Left(), rRect.Top(), rRect.Right(), rRect.Bottom()))); const basegfx::B2DPolyPolygon aOtherPolyPoly(aRectPoly); const basegfx::B2DPolyPolygon aClip = basegfx::tools::solvePolygonOperationXor(aThisPolyPoly, aOtherPolyPoly); *this = vcl::Region(aClip); return true; } // only region band mode possibility left here or null/empty const RegionBand* pCurrent = getRegionBand(); if(!pCurrent) { // rRect will be the xored-form (local off, rect on) *this = rRect; return true; } // only region band mode possibility left here or null/empty RegionBand* pNew = new RegionBand(*getRegionBand()); // get justified rectangle const long nLeft(std::min(rRect.Left(), rRect.Right())); const long nTop(std::min(rRect.Top(), rRect.Bottom())); const long nRight(std::max(rRect.Left(), rRect.Right())); const long nBottom(std::max(rRect.Top(), rRect.Bottom())); // insert bands if the boundaries are not already in the list pNew->InsertBands(nTop, nBottom); // process xor pNew->XOr(nLeft, nTop, nRight, nBottom); // cleanup if(!pNew->OptimizeBandList()) { delete pNew; pNew = 0; } mpRegionBand.reset(pNew); return true; } bool vcl::Region::Union( const vcl::Region& rRegion ) { if(rRegion.IsEmpty()) { // no extension at all return true; } if(rRegion.IsNull()) { // extending with null region -> null region *this = vcl::Region(true); return true; } if(IsEmpty()) { // local is empty, union will give source region *this = rRegion; return true; } if(IsNull()) { // already fully expanded (is null region), cannot be extended return true; } if( rRegion.HasPolyPolygonOrB2DPolyPolygon() || HasPolyPolygonOrB2DPolyPolygon() ) { // get this B2DPolyPolygon basegfx::B2DPolyPolygon aThisPolyPoly(GetAsB2DPolyPolygon()); aThisPolyPoly = basegfx::tools::prepareForPolygonOperation(aThisPolyPoly); if(!aThisPolyPoly.count()) { // when no local content, union will be equal to rRegion *this = rRegion; return true; } // get the other B2DPolyPolygon basegfx::B2DPolyPolygon aOtherPolyPoly(rRegion.GetAsB2DPolyPolygon()); aOtherPolyPoly = basegfx::tools::prepareForPolygonOperation(aOtherPolyPoly); // use logical OR operation basegfx::B2DPolyPolygon aClip(basegfx::tools::solvePolygonOperationOr(aThisPolyPoly, aOtherPolyPoly)); *this = vcl::Region( aClip ); return true; } // only region band mode possibility left here or null/empty const RegionBand* pCurrent = getRegionBand(); if(!pCurrent) { // local is empty, union will give source region *this = rRegion; return true; } const RegionBand* pSource = rRegion.getRegionBand(); if(!pSource) { // no extension at all return true; } // prepare source and target RegionBand* pNew = new RegionBand(*pCurrent); // union with source pNew->Union(*pSource); // cleanup if(!pNew->OptimizeBandList()) { delete pNew; pNew = 0; } mpRegionBand.reset(pNew); return true; } bool vcl::Region::Intersect( const vcl::Region& rRegion ) { // same instance data? -> nothing to do! if(getB2DPolyPolygon() && getB2DPolyPolygon() == rRegion.getB2DPolyPolygon()) { return true; } if(getPolyPolygon() && getPolyPolygon() == rRegion.getPolyPolygon()) { return true; } if(getRegionBand() && getRegionBand() == rRegion.getRegionBand()) { return true; } if(rRegion.IsNull()) { // source region is null-region, intersect will not change local region return true; } if(IsNull()) { // when local region is null-region, intersect will be equal to source *this = rRegion; return true; } if(rRegion.IsEmpty()) { // source region is empty, intersection will always be empty SetEmpty(); return true; } if(IsEmpty()) { // local region is empty, cannot get more emty than that. Nothing to do return true; } if( rRegion.HasPolyPolygonOrB2DPolyPolygon() || HasPolyPolygonOrB2DPolyPolygon() ) { // get this B2DPolyPolygon basegfx::B2DPolyPolygon aThisPolyPoly(GetAsB2DPolyPolygon()); if(!aThisPolyPoly.count()) { // local region is empty, cannot get more emty than that. Nothing to do return true; } // get the other B2DPolyPolygon basegfx::B2DPolyPolygon aOtherPolyPoly(rRegion.GetAsB2DPolyPolygon()); if(!aOtherPolyPoly.count()) { // source region is empty, intersection will always be empty SetEmpty(); return true; } const basegfx::B2DPolyPolygon aClip( basegfx::tools::clipPolyPolygonOnPolyPolygon( aOtherPolyPoly, aThisPolyPoly, true, false)); *this = vcl::Region( aClip ); return true; } // only region band mode possibility left here or null/empty const RegionBand* pCurrent = getRegionBand(); if(!pCurrent) { // local region is empty, cannot get more emty than that. Nothing to do return true; } const RegionBand* pSource = rRegion.getRegionBand(); if(!pSource) { // source region is empty, intersection will always be empty SetEmpty(); return true; } // both RegionBands exist and are not empty if(pCurrent->getRectangleCount() + 2 < pSource->getRectangleCount()) { // when we have less rectangles, turn around the call vcl::Region aTempRegion = rRegion; aTempRegion.Intersect( *this ); *this = aTempRegion; } else { // prepare new regionBand RegionBand* pNew = new RegionBand(*pCurrent); // intersect with source pNew->Intersect(*pSource); // cleanup if(!pNew->OptimizeBandList()) { delete pNew; pNew = 0; } mpRegionBand.reset(pNew); } return true; } bool vcl::Region::Exclude( const vcl::Region& rRegion ) { if ( rRegion.IsEmpty() ) { // excluding nothing will do no change return true; } if ( rRegion.IsNull() ) { // excluding everything will create empty region SetEmpty(); return true; } if(IsEmpty()) { // cannot exclude from empty, done return true; } if(IsNull()) { // error; cannot exclude from null region since this is not representable // in the data OSL_ENSURE(false, "Region::Exclude error: Cannot exclude from null region (!)"); return true; } if( rRegion.HasPolyPolygonOrB2DPolyPolygon() || HasPolyPolygonOrB2DPolyPolygon() ) { // get this B2DPolyPolygon basegfx::B2DPolyPolygon aThisPolyPoly(GetAsB2DPolyPolygon()); if(!aThisPolyPoly.count()) { // cannot exclude from empty, done return true; } aThisPolyPoly = basegfx::tools::prepareForPolygonOperation( aThisPolyPoly ); // get the other B2DPolyPolygon basegfx::B2DPolyPolygon aOtherPolyPoly(rRegion.GetAsB2DPolyPolygon()); aOtherPolyPoly = basegfx::tools::prepareForPolygonOperation( aOtherPolyPoly ); basegfx::B2DPolyPolygon aClip = basegfx::tools::solvePolygonOperationDiff( aThisPolyPoly, aOtherPolyPoly ); *this = vcl::Region( aClip ); return true; } // only region band mode possibility left here or null/empty const RegionBand* pCurrent = getRegionBand(); if(!pCurrent) { // cannot exclude from empty, done return true; } const RegionBand* pSource = rRegion.getRegionBand(); if(!pSource) { // excluding nothing will do no change return true; } // prepare source and target RegionBand* pNew = new RegionBand(*pCurrent); // union with source const bool bSuccess(pNew->Exclude(*pSource)); // cleanup if(!bSuccess) { delete pNew; pNew = 0; } mpRegionBand.reset(pNew); return true; } bool vcl::Region::XOr( const vcl::Region& rRegion ) { if ( rRegion.IsEmpty() ) { // empty region will not change local content return true; } if ( rRegion.IsNull() ) { // error; cannot exclude null region from local since this is not representable // in the data OSL_ENSURE(false, "Region::XOr error: Cannot XOr with null region (!)"); return true; } if(IsEmpty()) { // rRect will be the xored-form (local off, rect on) *this = rRegion; return true; } if(IsNull()) { // error: cannot exclude from null region since this is not representable // in the data OSL_ENSURE(false, "Region::XOr error: Cannot XOr with null region (!)"); return false; } if( rRegion.HasPolyPolygonOrB2DPolyPolygon() || HasPolyPolygonOrB2DPolyPolygon() ) { // get this B2DPolyPolygon basegfx::B2DPolyPolygon aThisPolyPoly(GetAsB2DPolyPolygon()); if(!aThisPolyPoly.count()) { // rRect will be the xored-form (local off, rect on) *this = rRegion; return true; } aThisPolyPoly = basegfx::tools::prepareForPolygonOperation( aThisPolyPoly ); // get the other B2DPolyPolygon basegfx::B2DPolyPolygon aOtherPolyPoly(rRegion.GetAsB2DPolyPolygon()); aOtherPolyPoly = basegfx::tools::prepareForPolygonOperation( aOtherPolyPoly ); basegfx::B2DPolyPolygon aClip = basegfx::tools::solvePolygonOperationXor( aThisPolyPoly, aOtherPolyPoly ); *this = vcl::Region( aClip ); return true; } // only region band mode possibility left here or null/empty const RegionBand* pCurrent = getRegionBand(); if(!pCurrent) { // rRect will be the xored-form (local off, rect on) *this = rRegion; return true; } const RegionBand* pSource = rRegion.getRegionBand(); if(!pSource) { // empty region will not change local content return true; } // prepare source and target RegionBand* pNew = new RegionBand(*pCurrent); // union with source pNew->XOr(*pSource); // cleanup if(!pNew->OptimizeBandList()) { delete pNew; pNew = 0; } mpRegionBand.reset(pNew); return true; } Rectangle vcl::Region::GetBoundRect() const { if(IsEmpty()) { // no internal data? -> region is empty! return Rectangle(); } if(IsNull()) { // error; null region has no BoundRect // OSL_ENSURE(false, "Region::GetBoundRect error: null region has unlimitied bound rect, not representable (!)"); return Rectangle(); } // prefer double precision source if(getB2DPolyPolygon()) { const basegfx::B2DRange aRange(basegfx::tools::getRange(*getB2DPolyPolygon())); if(aRange.isEmpty()) { // emulate PolyPolygon::GetBoundRect() when empty polygon return Rectangle(); } else { // #i122149# corrected rounding, no need for ceil() and floor() here return Rectangle( basegfx::fround(aRange.getMinX()), basegfx::fround(aRange.getMinY()), basegfx::fround(aRange.getMaxX()), basegfx::fround(aRange.getMaxY())); } } if(getPolyPolygon()) { return getPolyPolygon()->GetBoundRect(); } if(getRegionBand()) { return getRegionBand()->GetBoundRect(); } return Rectangle(); } const tools::PolyPolygon vcl::Region::GetAsPolyPolygon() const { if(getPolyPolygon()) { return *getPolyPolygon(); } if(getB2DPolyPolygon()) { // the polygon needs to be converted, buffer the down converion const tools::PolyPolygon aPolyPolgon(*getB2DPolyPolygon()); const_cast< vcl::Region* >(this)->mpPolyPolygon.reset(new tools::PolyPolygon(aPolyPolgon)); return *getPolyPolygon(); } if(getRegionBand()) { // the BandRegion needs to be converted, buffer the converion const tools::PolyPolygon aPolyPolgon(ImplCreatePolyPolygonFromRegionBand()); const_cast< vcl::Region* >(this)->mpPolyPolygon.reset(new tools::PolyPolygon(aPolyPolgon)); return *getPolyPolygon(); } return tools::PolyPolygon(); } const basegfx::B2DPolyPolygon vcl::Region::GetAsB2DPolyPolygon() const { if(getB2DPolyPolygon()) { return *getB2DPolyPolygon(); } if(getPolyPolygon()) { // the polygon needs to be converted, buffer the up conversion. This will be preferred from now. const basegfx::B2DPolyPolygon aB2DPolyPolygon(getPolyPolygon()->getB2DPolyPolygon()); const_cast< vcl::Region* >(this)->mpB2DPolyPolygon.reset(new basegfx::B2DPolyPolygon(aB2DPolyPolygon)); return *getB2DPolyPolygon(); } if(getRegionBand()) { // the BandRegion needs to be converted, buffer the converion const basegfx::B2DPolyPolygon aB2DPolyPolygon(ImplCreateB2DPolyPolygonFromRegionBand()); const_cast< vcl::Region* >(this)->mpB2DPolyPolygon.reset(new basegfx::B2DPolyPolygon(aB2DPolyPolygon)); return *getB2DPolyPolygon(); } return basegfx::B2DPolyPolygon(); } const RegionBand* vcl::Region::GetAsRegionBand() const { if(!getRegionBand()) { if(getB2DPolyPolygon()) { // convert B2DPolyPolygon to RegionBand, buffer it and return it const_cast< vcl::Region* >(this)->mpRegionBand.reset(ImplCreateRegionBandFromPolyPolygon(tools::PolyPolygon(*getB2DPolyPolygon()))); } else if(getPolyPolygon()) { // convert B2DPolyPolygon to RegionBand, buffer it and return it const_cast< vcl::Region* >(this)->mpRegionBand.reset(ImplCreateRegionBandFromPolyPolygon(*getPolyPolygon())); } } return getRegionBand(); } bool vcl::Region::IsInside( const Point& rPoint ) const { if(IsEmpty()) { // no point can be in empty region return false; } if(IsNull()) { // all points are inside null-region return true; } // Too expensive (?) //if(mpImplRegion->getRegionPolyPoly()) //{ // return mpImplRegion->getRegionPolyPoly()->IsInside( rPoint ); //} // ensure RegionBand existence const RegionBand* pRegionBand = GetAsRegionBand(); if(pRegionBand) { return pRegionBand->IsInside(rPoint); } return false; } bool vcl::Region::IsInside( const Rectangle& rRect ) const { if(IsEmpty()) { // no rectangle can be in empty region return false; } if(IsNull()) { // rectangle always inside null-region return true; } if ( rRect.IsEmpty() ) { // is rectangle empty? -> not inside return false; } // create region from rectangle and intersect own region vcl::Region aRegion(rRect); aRegion.Exclude(*this); // rectangle is inside if exclusion is empty return aRegion.IsEmpty(); } bool vcl::Region::IsOver( const Rectangle& rRect ) const { if(IsEmpty()) { // nothing can be over something empty return false; } if(IsNull()) { // everything is over null region return true; } // Can we optimize this ??? - is used in StarDraw for brushes pointers // Why we have no IsOver for Regions ??? // create region from rectangle and intersect own region vcl::Region aRegion(rRect); aRegion.Intersect( *this ); // rectangle is over if include is not empty return !aRegion.IsEmpty(); } bool vcl::Region::IsRectangle() const { if( IsEmpty() || IsNull() ) return false; if( getB2DPolyPolygon() ) return basegfx::tools::isRectangle( *getB2DPolyPolygon() ); if( getPolyPolygon() ) return getPolyPolygon()->IsRect(); if( getRegionBand() ) return (getRegionBand()->getRectangleCount() == 1); return false; } void vcl::Region::SetNull() { // reset all content mpB2DPolyPolygon.reset(); mpPolyPolygon.reset(); mpRegionBand.reset(); mbIsNull = true; } void vcl::Region::SetEmpty() { // reset all content mpB2DPolyPolygon.reset(); mpPolyPolygon.reset(); mpRegionBand.reset(); mbIsNull = false; } Region& vcl::Region::operator=( const vcl::Region& rRegion ) { // reset all content mpB2DPolyPolygon = rRegion.mpB2DPolyPolygon; mpPolyPolygon = rRegion.mpPolyPolygon; mpRegionBand = rRegion.mpRegionBand; mbIsNull = rRegion.mbIsNull; return *this; } Region& vcl::Region::operator=( const Rectangle& rRect ) { mpB2DPolyPolygon.reset(); mpPolyPolygon.reset(); mpRegionBand.reset(rRect.IsEmpty() ? 0 : new RegionBand(rRect)); mbIsNull = false; return *this; } bool vcl::Region::operator==( const vcl::Region& rRegion ) const { if(IsNull() && rRegion.IsNull()) { // both are null region return true; } if(IsEmpty() && rRegion.IsEmpty()) { // both are empty return true; } if(getB2DPolyPolygon() && getB2DPolyPolygon() == rRegion.getB2DPolyPolygon()) { // same instance data? -> equal return true; } if(getPolyPolygon() && getPolyPolygon() == rRegion.getPolyPolygon()) { // same instance data? -> equal return true; } if(getRegionBand() && getRegionBand() == rRegion.getRegionBand()) { // same instance data? -> equal return true; } if(IsNull() || IsEmpty()) { return false; } if(rRegion.IsNull() || rRegion.IsEmpty()) { return false; } if(rRegion.getB2DPolyPolygon() || getB2DPolyPolygon()) { // one of both has a B2DPolyPolygon based region, ensure both have it // by evtl. conversion GetAsB2DPolyPolygon(); rRegion.GetAsB2DPolyPolygon(); return *rRegion.getB2DPolyPolygon() == *getB2DPolyPolygon(); } if(rRegion.getPolyPolygon() || getPolyPolygon()) { // one of both has a B2DPolyPolygon based region, ensure both have it // by evtl. conversion GetAsPolyPolygon(); rRegion.GetAsPolyPolygon(); return *rRegion.getPolyPolygon() == *getPolyPolygon(); } // both are not empty or null (see above) and if content supported polygon // data the comparison is already done. Only both on RegionBand base can be left, // but better check if(rRegion.getRegionBand() && getRegionBand()) { return *rRegion.getRegionBand() == *getRegionBand(); } // should not happen, but better deny equality return false; } SvStream& ReadRegion(SvStream& rIStrm, vcl::Region& rRegion) { VersionCompat aCompat(rIStrm, StreamMode::READ); sal_uInt16 nVersion(0); sal_uInt16 nTmp16(0); // clear region to be loaded rRegion.SetEmpty(); // get version of streamed region rIStrm.ReadUInt16( nVersion ); // get type of region rIStrm.ReadUInt16( nTmp16 ); enum RegionType { REGION_NULL, REGION_EMPTY, REGION_RECTANGLE, REGION_COMPLEX }; RegionType meStreamedType = (RegionType)nTmp16; switch(meStreamedType) { case REGION_NULL: { rRegion.SetNull(); break; } case REGION_EMPTY: { rRegion.SetEmpty(); break; } default: { RegionBand* pNewRegionBand = new RegionBand(); pNewRegionBand->load(rIStrm); rRegion.mpRegionBand.reset(pNewRegionBand); if(aCompat.GetVersion() >= 2) { bool bHasPolyPolygon(false); rIStrm.ReadCharAsBool( bHasPolyPolygon ); if(bHasPolyPolygon) { tools::PolyPolygon* pNewPoly = new tools::PolyPolygon(); ReadPolyPolygon( rIStrm, *pNewPoly ); rRegion.mpPolyPolygon.reset(pNewPoly); } } break; } } return rIStrm; } SvStream& WriteRegion( SvStream& rOStrm, const vcl::Region& rRegion ) { const sal_uInt16 nVersion(2); VersionCompat aCompat(rOStrm, StreamMode::WRITE, nVersion); // put version rOStrm.WriteUInt16( nVersion ); // put type enum RegionType { REGION_NULL, REGION_EMPTY, REGION_RECTANGLE, REGION_COMPLEX }; RegionType aRegionType(REGION_COMPLEX); bool bEmpty(rRegion.IsEmpty()); if(!bEmpty && rRegion.getB2DPolyPolygon() && 0 == rRegion.getB2DPolyPolygon()->count()) { OSL_ENSURE(false, "Region with empty B2DPolyPolygon, should not be created (!)"); bEmpty = true; } if(!bEmpty && rRegion.getPolyPolygon() && 0 == rRegion.getPolyPolygon()->Count()) { OSL_ENSURE(false, "Region with empty PolyPolygon, should not be created (!)"); bEmpty = true; } if(bEmpty) { aRegionType = REGION_EMPTY; } else if(rRegion.IsNull()) { aRegionType = REGION_NULL; } else if(rRegion.getRegionBand() && rRegion.getRegionBand()->isSingleRectangle()) { aRegionType = REGION_RECTANGLE; } rOStrm.WriteUInt16( aRegionType ); // get RegionBand const RegionBand* pRegionBand = rRegion.getRegionBand(); if(pRegionBand) { pRegionBand->save(rOStrm); } else { // for compatibility, write an empty RegionBand (will only write // the end marker STREAMENTRY_END, but this *is* needed) const RegionBand aRegionBand; aRegionBand.save(rOStrm); } // write polypolygon if available const bool bHasPolyPolygon(rRegion.HasPolyPolygonOrB2DPolyPolygon()); rOStrm.WriteUChar( bHasPolyPolygon ); if(bHasPolyPolygon) { // #i105373# tools::PolyPolygon aNoCurvePolyPolygon; rRegion.GetAsPolyPolygon().AdaptiveSubdivide(aNoCurvePolyPolygon); WritePolyPolygon( rOStrm, aNoCurvePolyPolygon ); } return rOStrm; } void vcl::Region::GetRegionRectangles(RectangleVector& rTarget) const { // clear returnvalues rTarget.clear(); // ensure RegionBand existence const RegionBand* pRegionBand = GetAsRegionBand(); if(pRegionBand) { pRegionBand->GetRegionRectangles(rTarget); } } static inline bool ImplPolygonRectTest( const Polygon& rPoly, Rectangle* pRectOut = NULL ) { bool bIsRect = false; const Point* pPoints = rPoly.GetConstPointAry(); sal_uInt16 nPoints = rPoly.GetSize(); if( nPoints == 4 || (nPoints == 5 && pPoints[0] == pPoints[4]) ) { long nX1 = pPoints[0].X(), nX2 = pPoints[2].X(), nY1 = pPoints[0].Y(), nY2 = pPoints[2].Y(); if( ( (pPoints[1].X() == nX1 && pPoints[3].X() == nX2) && (pPoints[1].Y() == nY2 && pPoints[3].Y() == nY1) ) || ( (pPoints[1].X() == nX2 && pPoints[3].X() == nX1) && (pPoints[1].Y() == nY1 && pPoints[3].Y() == nY2) ) ) { bIsRect = true; if( pRectOut ) { long nSwap; if( nX2 < nX1 ) { nSwap = nX2; nX2 = nX1; nX1 = nSwap; } if( nY2 < nY1 ) { nSwap = nY2; nY2 = nY1; nY1 = nSwap; } if( nX2 != nX1 ) { nX2--; } if( nY2 != nY1 ) { nY2--; } pRectOut->Left() = nX1; pRectOut->Right() = nX2; pRectOut->Top() = nY1; pRectOut->Bottom() = nY2; } } } return bIsRect; } vcl::Region vcl::Region::GetRegionFromPolyPolygon( const tools::PolyPolygon& rPolyPoly ) { //return vcl::Region( rPolyPoly ); // check if it's worth extracting the XOr'ing the Rectangles // empiricism shows that break even between XOr'ing rectangles separately // and ImplCreateRegionBandFromPolyPolygon is at half rectangles/half polygons int nPolygonRects = 0, nPolygonPolygons = 0; int nPolygons = rPolyPoly.Count(); for( sal_uInt16 i = 0; i < nPolygons; i++ ) { const Polygon& rPoly = rPolyPoly[i]; if( ImplPolygonRectTest( rPoly ) ) { nPolygonRects++; } else { nPolygonPolygons++; } } if( nPolygonPolygons > nPolygonRects ) { return vcl::Region( rPolyPoly ); } vcl::Region aResult; Rectangle aRect; for( sal_uInt16 i = 0; i < nPolygons; i++ ) { const Polygon& rPoly = rPolyPoly[i]; if( ImplPolygonRectTest( rPoly, &aRect ) ) { aResult.XOr( aRect ); } else { aResult.XOr( vcl::Region(rPoly) ); } } return aResult; } } /* namespace vcl */ /* vim:set shiftwidth=4 softtabstop=4 expandtab: */