/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /************************************************************************* * * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * Copyright 2000, 2010 Oracle and/or its affiliates. * * OpenOffice.org - a multi-platform office productivity suite * * This file is part of OpenOffice.org. * * OpenOffice.org is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License version 3 * only, as published by the Free Software Foundation. * * OpenOffice.org is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Lesser General Public License version 3 for more details * (a copy is included in the LICENSE file that accompanied this code). * * You should have received a copy of the GNU Lesser General Public License * version 3 along with OpenOffice.org. If not, see * * for a copy of the LGPLv3 License. * ************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // for the object conversion #include // for dragging (Ortho) #include "svx/svdglob.hxx" // StringCache #include "svx/svdstr.hrc" // the object's name #include #include #include #include #include #include #include #include ////////////////////////////////////////////////////////////////////////////// Point GetWinkPnt(const Rectangle& rR, long nWink) { Point aCenter(rR.Center()); long nWdt=rR.Right()-rR.Left(); long nHgt=rR.Bottom()-rR.Top(); long nMaxRad=((nWdt>nHgt ? nWdt : nHgt)+1) /2; double a; a=nWink*nPi180; Point aRetval(Round(cos(a)*nMaxRad),-Round(sin(a)*nMaxRad)); if (nWdt==0) aRetval.X()=0; if (nHgt==0) aRetval.Y()=0; if (nWdt!=nHgt) { if (nWdt>nHgt) { if (nWdt!=0) { // stop possible overruns for very large objects if (Abs(nHgt)>32767 || Abs(aRetval.Y())>32767) { aRetval.Y()=BigMulDiv(aRetval.Y(),nHgt,nWdt); } else { aRetval.Y()=aRetval.Y()*nHgt/nWdt; } } } else { if (nHgt!=0) { // stop possible overruns for very large objects if (Abs(nWdt)>32767 || Abs(aRetval.X())>32767) { aRetval.X()=BigMulDiv(aRetval.X(),nWdt,nHgt); } else { aRetval.X()=aRetval.X()*nWdt/nHgt; } } } } aRetval+=aCenter; return aRetval; } ////////////////////////////////////////////////////////////////////////////// // BaseProperties section sdr::properties::BaseProperties* SdrCircObj::CreateObjectSpecificProperties() { return new sdr::properties::CircleProperties(*this); } ////////////////////////////////////////////////////////////////////////////// // DrawContact section sdr::contact::ViewContact* SdrCircObj::CreateObjectSpecificViewContact() { return new sdr::contact::ViewContactOfSdrCircObj(*this); } ////////////////////////////////////////////////////////////////////////////// TYPEINIT1(SdrCircObj,SdrRectObj); SdrCircObj::SdrCircObj(SdrObjKind eNewKind) { nStartWink=0; nEndWink=36000; meCircleKind=eNewKind; bClosedObj=eNewKind!=OBJ_CARC; } SdrCircObj::SdrCircObj(SdrObjKind eNewKind, const Rectangle& rRect): SdrRectObj(rRect) { nStartWink=0; nEndWink=36000; meCircleKind=eNewKind; bClosedObj=eNewKind!=OBJ_CARC; } SdrCircObj::SdrCircObj(SdrObjKind eNewKind, const Rectangle& rRect, long nNewStartWink, long nNewEndWink): SdrRectObj(rRect) { long nWinkDif=nNewEndWink-nNewStartWink; nStartWink=NormAngle360(nNewStartWink); nEndWink=NormAngle360(nNewEndWink); if (nWinkDif==36000) nEndWink+=nWinkDif; // full circle meCircleKind=eNewKind; bClosedObj=eNewKind!=OBJ_CARC; } SdrCircObj::~SdrCircObj() { } void SdrCircObj::TakeObjInfo(SdrObjTransformInfoRec& rInfo) const { bool bCanConv=!HasText() || ImpCanConvTextToCurve(); rInfo.bEdgeRadiusAllowed = sal_False; rInfo.bCanConvToPath=bCanConv; rInfo.bCanConvToPoly=bCanConv; rInfo.bCanConvToContour = !IsFontwork() && (rInfo.bCanConvToPoly || LineGeometryUsageIsNecessary()); } sal_uInt16 SdrCircObj::GetObjIdentifier() const { return sal_uInt16(meCircleKind); } bool SdrCircObj::PaintNeedsXPolyCirc() const { // XPoly is necessary for all rotated ellipse objects, circle and // ellipse segments. // If not WIN, then (for now) also for circle/ellipse segments and circle/ // ellipse arcs (for precision) bool bNeed=aGeo.nDrehWink!=0 || aGeo.nShearWink!=0 || meCircleKind==OBJ_CCUT; // If not WIN, then for everything except full circle (for now!) if (meCircleKind!=OBJ_CIRC) bNeed = true; const SfxItemSet& rSet = GetObjectItemSet(); if(!bNeed) { // XPoly is necessary for everything that isn't LineSolid or LineNone XLineStyle eLine = ((XLineStyleItem&)(rSet.Get(XATTR_LINESTYLE))).GetValue(); bNeed = eLine != XLINE_NONE && eLine != XLINE_SOLID; // XPoly is necessary for thick lines if(!bNeed && eLine != XLINE_NONE) bNeed = ((XLineWidthItem&)(rSet.Get(XATTR_LINEWIDTH))).GetValue() != 0; // XPoly is necessary for circle arcs with line ends if(!bNeed && meCircleKind == OBJ_CARC) { // start of the line is here if StartPolygon, StartWidth!=0 bNeed=((XLineStartItem&)(rSet.Get(XATTR_LINESTART))).GetLineStartValue().count() != 0L && ((XLineStartWidthItem&)(rSet.Get(XATTR_LINESTARTWIDTH))).GetValue() != 0; if(!bNeed) { // end of the line is here if EndPolygon, EndWidth!=0 bNeed = ((XLineEndItem&)(rSet.Get(XATTR_LINEEND))).GetLineEndValue().count() != 0L && ((XLineEndWidthItem&)(rSet.Get(XATTR_LINEENDWIDTH))).GetValue() != 0; } } } // XPoly is necessary if Fill !=None and !=Solid if(!bNeed && meCircleKind != OBJ_CARC) { XFillStyle eFill=((XFillStyleItem&)(rSet.Get(XATTR_FILLSTYLE))).GetValue(); bNeed = eFill != XFILL_NONE && eFill != XFILL_SOLID; } if(!bNeed && meCircleKind != OBJ_CIRC && nStartWink == nEndWink) bNeed = true; // otherwise we're drawing a full circle return bNeed; } basegfx::B2DPolygon SdrCircObj::ImpCalcXPolyCirc(const SdrObjKind eCicrleKind, const Rectangle& rRect1, long nStart, long nEnd) const { const basegfx::B2DRange aRange(rRect1.Left(), rRect1.Top(), rRect1.Right(), rRect1.Bottom()); basegfx::B2DPolygon aCircPolygon; if(OBJ_CIRC == eCicrleKind) { // create full circle. Do not use createPolygonFromEllipse; it's necessary // to get the start point to the bottom of the circle to keep compatible to // old geometry creation aCircPolygon = basegfx::tools::createPolygonFromUnitCircle(1); // needs own scaling and translation from unit circle to target size (same as // would be in createPolygonFromEllipse) const basegfx::B2DPoint aCenter(aRange.getCenter()); const basegfx::B2DHomMatrix aMatrix(basegfx::tools::createScaleTranslateB2DHomMatrix( aRange.getWidth() / 2.0, aRange.getHeight() / 2.0, aCenter.getX(), aCenter.getY())); aCircPolygon.transform(aMatrix); } else { // mirror start, end for geometry creation since model coordinate system is mirrored in Y // #i111715# increase numerical correctness by first dividing and not using F_PI1800 const double fStart((((36000 - nEnd) % 36000) / 18000.0) * F_PI); const double fEnd((((36000 - nStart) % 36000) / 18000.0) * F_PI); // create circle segment. This is not closed by default aCircPolygon = basegfx::tools::createPolygonFromEllipseSegment( aRange.getCenter(), aRange.getWidth() / 2.0, aRange.getHeight() / 2.0, fStart, fEnd); // check closing states const bool bCloseSegment(OBJ_CARC != eCicrleKind); const bool bCloseUsingCenter(OBJ_SECT == eCicrleKind); if(bCloseSegment) { if(bCloseUsingCenter) { // add center point at start (for historical reasons) basegfx::B2DPolygon aSector; aSector.append(aRange.getCenter()); aSector.append(aCircPolygon); aCircPolygon = aSector; } // close aCircPolygon.setClosed(true); } } // #i76950# if(aGeo.nShearWink || aGeo.nDrehWink) { // translate top left to (0,0) const basegfx::B2DPoint aTopLeft(aRange.getMinimum()); basegfx::B2DHomMatrix aMatrix(basegfx::tools::createTranslateB2DHomMatrix( -aTopLeft.getX(), -aTopLeft.getY())); // shear, rotate and back to top left (if needed) aMatrix = basegfx::tools::createShearXRotateTranslateB2DHomMatrix( aGeo.nShearWink ? tan((36000 - aGeo.nShearWink) * F_PI18000) : 0.0, aGeo.nDrehWink ? (36000 - aGeo.nDrehWink) * F_PI18000 : 0.0, aTopLeft) * aMatrix; // apply transformation aCircPolygon.transform(aMatrix); } return aCircPolygon; } void SdrCircObj::RecalcXPoly() { const basegfx::B2DPolygon aPolyCirc(ImpCalcXPolyCirc(meCircleKind, aRect, nStartWink, nEndWink)); mpXPoly = new XPolygon(aPolyCirc); } void SdrCircObj::TakeObjNameSingul(XubString& rName) const { sal_uInt16 nID=STR_ObjNameSingulCIRC; if (aRect.GetWidth()==aRect.GetHeight() && aGeo.nShearWink==0) { switch (meCircleKind) { case OBJ_CIRC: nID=STR_ObjNameSingulCIRC; break; case OBJ_SECT: nID=STR_ObjNameSingulSECT; break; case OBJ_CARC: nID=STR_ObjNameSingulCARC; break; case OBJ_CCUT: nID=STR_ObjNameSingulCCUT; break; default: break; } } else { switch (meCircleKind) { case OBJ_CIRC: nID=STR_ObjNameSingulCIRCE; break; case OBJ_SECT: nID=STR_ObjNameSingulSECTE; break; case OBJ_CARC: nID=STR_ObjNameSingulCARCE; break; case OBJ_CCUT: nID=STR_ObjNameSingulCCUTE; break; default: break; } } rName=ImpGetResStr(nID); String aName( GetName() ); if(aName.Len()) { rName += sal_Unicode(' '); rName += sal_Unicode('\''); rName += aName; rName += sal_Unicode('\''); } } void SdrCircObj::TakeObjNamePlural(XubString& rName) const { sal_uInt16 nID=STR_ObjNamePluralCIRC; if (aRect.GetWidth()==aRect.GetHeight() && aGeo.nShearWink==0) { switch (meCircleKind) { case OBJ_CIRC: nID=STR_ObjNamePluralCIRC; break; case OBJ_SECT: nID=STR_ObjNamePluralSECT; break; case OBJ_CARC: nID=STR_ObjNamePluralCARC; break; case OBJ_CCUT: nID=STR_ObjNamePluralCCUT; break; default: break; } } else { switch (meCircleKind) { case OBJ_CIRC: nID=STR_ObjNamePluralCIRCE; break; case OBJ_SECT: nID=STR_ObjNamePluralSECTE; break; case OBJ_CARC: nID=STR_ObjNamePluralCARCE; break; case OBJ_CCUT: nID=STR_ObjNamePluralCCUTE; break; default: break; } } rName=ImpGetResStr(nID); } SdrCircObj* SdrCircObj::Clone() const { return CloneHelper< SdrCircObj >(); } basegfx::B2DPolyPolygon SdrCircObj::TakeXorPoly() const { const basegfx::B2DPolygon aCircPolygon(ImpCalcXPolyCirc(meCircleKind, aRect, nStartWink, nEndWink)); return basegfx::B2DPolyPolygon(aCircPolygon); } struct ImpCircUser : public SdrDragStatUserData { Rectangle aR; Point aCenter; Point aRadius; Point aP1; Point aP2; long nMaxRad; long nHgt; long nWdt; long nStart; long nEnd; long nWink; bool bRight; // not yet implemented public: ImpCircUser() : nMaxRad(0), nHgt(0), nWdt(0), nStart(0), nEnd(0), nWink(0), bRight(sal_False) {} void SetCreateParams(SdrDragStat& rStat); }; sal_uInt32 SdrCircObj::GetHdlCount() const { if(OBJ_CIRC != meCircleKind) { return 10L; } else { return 8L; } } SdrHdl* SdrCircObj::GetHdl(sal_uInt32 nHdlNum) const { if (meCircleKind==OBJ_CIRC) { nHdlNum += 2L; } SdrHdl* pH = NULL; Point aPnt; SdrHdlKind eLocalKind(HDL_MOVE); sal_uInt32 nPNum(0); switch (nHdlNum) { case 0: aPnt = GetWinkPnt(aRect,nStartWink); eLocalKind = HDL_CIRC; nPNum = 1; break; case 1: aPnt = GetWinkPnt(aRect,nEndWink); eLocalKind = HDL_CIRC; nPNum = 2L; break; case 2: aPnt = aRect.TopLeft(); eLocalKind = HDL_UPLFT; break; case 3: aPnt = aRect.TopCenter(); eLocalKind = HDL_UPPER; break; case 4: aPnt = aRect.TopRight(); eLocalKind = HDL_UPRGT; break; case 5: aPnt = aRect.LeftCenter(); eLocalKind = HDL_LEFT; break; case 6: aPnt = aRect.RightCenter(); eLocalKind = HDL_RIGHT; break; case 7: aPnt = aRect.BottomLeft(); eLocalKind = HDL_LWLFT; break; case 8: aPnt = aRect.BottomCenter(); eLocalKind = HDL_LOWER; break; case 9: aPnt = aRect.BottomRight(); eLocalKind = HDL_LWRGT; break; } if (aGeo.nShearWink) { ShearPoint(aPnt,aRect.TopLeft(),aGeo.nTan); } if (aGeo.nDrehWink) { RotatePoint(aPnt,aRect.TopLeft(),aGeo.nSin,aGeo.nCos); } if (eLocalKind != HDL_MOVE) { pH = new SdrHdl(aPnt,eLocalKind); pH->SetPointNum(nPNum); pH->SetObj((SdrObject*)this); pH->SetDrehWink(aGeo.nDrehWink); } return pH; } //////////////////////////////////////////////////////////////////////////////////////////////////// bool SdrCircObj::hasSpecialDrag() const { return true; } bool SdrCircObj::beginSpecialDrag(SdrDragStat& rDrag) const { const bool bWink(rDrag.GetHdl() && HDL_CIRC == rDrag.GetHdl()->GetKind()); if(bWink) { if(1 == rDrag.GetHdl()->GetPointNum() || 2 == rDrag.GetHdl()->GetPointNum()) { rDrag.SetNoSnap(true); } return true; } return SdrTextObj::beginSpecialDrag(rDrag); } bool SdrCircObj::applySpecialDrag(SdrDragStat& rDrag) { const bool bWink(rDrag.GetHdl() && HDL_CIRC == rDrag.GetHdl()->GetKind()); if(bWink) { Point aPt(rDrag.GetNow()); if (aGeo.nDrehWink!=0) RotatePoint(aPt,aRect.TopLeft(),-aGeo.nSin,aGeo.nCos); if (aGeo.nShearWink!=0) ShearPoint(aPt,aRect.TopLeft(),-aGeo.nTan); aPt-=aRect.Center(); long nWdt=aRect.Right()-aRect.Left(); long nHgt=aRect.Bottom()-aRect.Top(); if(nWdt>=nHgt) { aPt.Y()=BigMulDiv(aPt.Y(),nWdt,nHgt); } else { aPt.X()=BigMulDiv(aPt.X(),nHgt,nWdt); } long nWink=NormAngle360(GetAngle(aPt)); if (rDrag.GetView() && rDrag.GetView()->IsAngleSnapEnabled()) { long nSA=rDrag.GetView()->GetSnapAngle(); if (nSA!=0) { nWink+=nSA/2; nWink/=nSA; nWink*=nSA; nWink=NormAngle360(nWink); } } if(1 == rDrag.GetHdl()->GetPointNum()) { nStartWink = nWink; } else if(2 == rDrag.GetHdl()->GetPointNum()) { nEndWink = nWink; } SetRectsDirty(); SetXPolyDirty(); ImpSetCircInfoToAttr(); SetChanged(); return true; } else { return SdrTextObj::applySpecialDrag(rDrag); } } String SdrCircObj::getSpecialDragComment(const SdrDragStat& rDrag) const { const bool bCreateComment(rDrag.GetView() && this == rDrag.GetView()->GetCreateObj()); if(bCreateComment) { rtl::OUString aStr; ImpTakeDescriptionStr(STR_ViewCreateObj, aStr); rtl::OUStringBuffer aBuf(aStr); const sal_uInt32 nPntAnz(rDrag.GetPointAnz()); if(OBJ_CIRC != meCircleKind && nPntAnz > 2) { ImpCircUser* pU = (ImpCircUser*)rDrag.GetUser(); sal_Int32 nWink; aBuf.appendAscii(" ("); if(3 == nPntAnz) { nWink = pU->nStart; } else { nWink = pU->nEnd; } aBuf.append(GetWinkStr(nWink,false)); aBuf.append(sal_Unicode(')')); } return aBuf.makeStringAndClear(); } else { const bool bWink(rDrag.GetHdl() && HDL_CIRC == rDrag.GetHdl()->GetKind()); if(bWink) { const sal_Int32 nWink(1 == rDrag.GetHdl()->GetPointNum() ? nStartWink : nEndWink); rtl::OUString aStr; ImpTakeDescriptionStr(STR_DragCircAngle, aStr); rtl::OUStringBuffer aBuf(aStr); aBuf.appendAscii(" ("); aBuf.append(GetWinkStr(nWink,false)); aBuf.append(sal_Unicode(')')); return aBuf.makeStringAndClear(); } else { return SdrTextObj::getSpecialDragComment(rDrag); } } } //////////////////////////////////////////////////////////////////////////////////////////////////// void ImpCircUser::SetCreateParams(SdrDragStat& rStat) { rStat.TakeCreateRect(aR); aR.Justify(); aCenter=aR.Center(); nWdt=aR.Right()-aR.Left(); nHgt=aR.Bottom()-aR.Top(); nMaxRad=((nWdt>nHgt ? nWdt : nHgt)+1) /2; nStart=0; nEnd=36000; if (rStat.GetPointAnz()>2) { Point aP(rStat.GetPoint(2)-aCenter); if (nWdt==0) aP.X()=0; if (nHgt==0) aP.Y()=0; if (nWdt>=nHgt) { if (nHgt!=0) aP.Y()=aP.Y()*nWdt/nHgt; } else { if (nWdt!=0) aP.X()=aP.X()*nHgt/nWdt; } nStart=NormAngle360(GetAngle(aP)); if (rStat.GetView()!=NULL && rStat.GetView()->IsAngleSnapEnabled()) { long nSA=rStat.GetView()->GetSnapAngle(); if (nSA!=0) { // angle snapping nStart+=nSA/2; nStart/=nSA; nStart*=nSA; nStart=NormAngle360(nStart); } } aP1 = GetWinkPnt(aR,nStart); nEnd=nStart; aP2=aP1; } else aP1=aCenter; if (rStat.GetPointAnz()>3) { Point aP(rStat.GetPoint(3)-aCenter); if (nWdt>=nHgt) { aP.Y()=BigMulDiv(aP.Y(),nWdt,nHgt); } else { aP.X()=BigMulDiv(aP.X(),nHgt,nWdt); } nEnd=NormAngle360(GetAngle(aP)); if (rStat.GetView()!=NULL && rStat.GetView()->IsAngleSnapEnabled()) { long nSA=rStat.GetView()->GetSnapAngle(); if (nSA!=0) { // angle snapping nEnd+=nSA/2; nEnd/=nSA; nEnd*=nSA; nEnd=NormAngle360(nEnd); } } aP2 = GetWinkPnt(aR,nEnd); } else aP2=aCenter; } void SdrCircObj::ImpSetCreateParams(SdrDragStat& rStat) const { ImpCircUser* pU=(ImpCircUser*)rStat.GetUser(); if (pU==NULL) { pU=new ImpCircUser; rStat.SetUser(pU); } pU->SetCreateParams(rStat); } bool SdrCircObj::BegCreate(SdrDragStat& rStat) { rStat.SetOrtho4Possible(); Rectangle aRect1(rStat.GetStart(), rStat.GetNow()); aRect1.Justify(); rStat.SetActionRect(aRect1); aRect = aRect1; ImpSetCreateParams(rStat); return sal_True; } bool SdrCircObj::MovCreate(SdrDragStat& rStat) { ImpSetCreateParams(rStat); ImpCircUser* pU=(ImpCircUser*)rStat.GetUser(); rStat.SetActionRect(pU->aR); aRect=pU->aR; // for ObjName ImpJustifyRect(aRect); nStartWink=pU->nStart; nEndWink=pU->nEnd; SetBoundRectDirty(); bSnapRectDirty=sal_True; SetXPolyDirty(); // #i103058# push current angle settings to ItemSet to // allow FullDrag visualisation if(rStat.GetPointAnz() >= 4) { ImpSetCircInfoToAttr(); } return sal_True; } bool SdrCircObj::EndCreate(SdrDragStat& rStat, SdrCreateCmd eCmd) { ImpSetCreateParams(rStat); ImpCircUser* pU=(ImpCircUser*)rStat.GetUser(); bool bRet = false; if (eCmd==SDRCREATE_FORCEEND && rStat.GetPointAnz()<4) meCircleKind=OBJ_CIRC; if (meCircleKind==OBJ_CIRC) { bRet=rStat.GetPointAnz()>=2; if (bRet) { aRect=pU->aR; ImpJustifyRect(aRect); } } else { rStat.SetNoSnap(rStat.GetPointAnz()>=2); rStat.SetOrtho4Possible(rStat.GetPointAnz()<2); bRet=rStat.GetPointAnz()>=4; if (bRet) { aRect=pU->aR; ImpJustifyRect(aRect); nStartWink=pU->nStart; nEndWink=pU->nEnd; } } bClosedObj=meCircleKind!=OBJ_CARC; SetRectsDirty(); SetXPolyDirty(); ImpSetCircInfoToAttr(); if (bRet) { delete pU; rStat.SetUser(NULL); } return bRet; } void SdrCircObj::BrkCreate(SdrDragStat& rStat) { ImpCircUser* pU=(ImpCircUser*)rStat.GetUser(); delete pU; rStat.SetUser(NULL); } bool SdrCircObj::BckCreate(SdrDragStat& rStat) { rStat.SetNoSnap(rStat.GetPointAnz()>=3); rStat.SetOrtho4Possible(rStat.GetPointAnz()<3); return meCircleKind!=OBJ_CIRC; } basegfx::B2DPolyPolygon SdrCircObj::TakeCreatePoly(const SdrDragStat& rDrag) const { ImpCircUser* pU = (ImpCircUser*)rDrag.GetUser(); if(rDrag.GetPointAnz() < 4L) { // force to OBJ_CIRC to get full visualisation basegfx::B2DPolyPolygon aRetval(ImpCalcXPolyCirc(OBJ_CIRC, pU->aR, pU->nStart, pU->nEnd)); if(3L == rDrag.GetPointAnz()) { // add edge to first point on ellipse basegfx::B2DPolygon aNew; aNew.append(basegfx::B2DPoint(pU->aCenter.X(), pU->aCenter.Y())); aNew.append(basegfx::B2DPoint(pU->aP1.X(), pU->aP1.Y())); aRetval.append(aNew); } return aRetval; } else { return basegfx::B2DPolyPolygon(ImpCalcXPolyCirc(meCircleKind, pU->aR, pU->nStart, pU->nEnd)); } } Pointer SdrCircObj::GetCreatePointer() const { switch (meCircleKind) { case OBJ_CIRC: return Pointer(POINTER_DRAW_ELLIPSE); case OBJ_SECT: return Pointer(POINTER_DRAW_PIE); case OBJ_CARC: return Pointer(POINTER_DRAW_ARC); case OBJ_CCUT: return Pointer(POINTER_DRAW_CIRCLECUT); default: break; } // switch return Pointer(POINTER_CROSS); } void SdrCircObj::NbcMove(const Size& aSiz) { MoveRect(aRect,aSiz); MoveRect(aOutRect,aSiz); MoveRect(maSnapRect,aSiz); SetXPolyDirty(); SetRectsDirty(sal_True); } void SdrCircObj::NbcResize(const Point& rRef, const Fraction& xFact, const Fraction& yFact) { long nWink0=aGeo.nDrehWink; bool bNoShearRota=(aGeo.nDrehWink==0 && aGeo.nShearWink==0); SdrTextObj::NbcResize(rRef,xFact,yFact); bNoShearRota|=(aGeo.nDrehWink==0 && aGeo.nShearWink==0); if (meCircleKind!=OBJ_CIRC) { bool bXMirr=(xFact.GetNumerator()<0) != (xFact.GetDenominator()<0); bool bYMirr=(yFact.GetNumerator()<0) != (yFact.GetDenominator()<0); if (bXMirr || bYMirr) { // At bXMirr!=bYMirr we should actually swap both line ends. // That, however, is pretty bad (because of forced "hard" formatting). // Alternatively, we could implement a bMirrored flag (maybe even // a more general one, e. g. for mirrored text, ...). long nS0=nStartWink; long nE0=nEndWink; if (bNoShearRota) { // the RectObj already mirrors at VMirror because of a 180deg rotation if (! (bXMirr && bYMirr)) { long nTmp=nS0; nS0=18000-nE0; nE0=18000-nTmp; } } else { // mirror contorted ellipses if (bXMirr!=bYMirr) { nS0+=nWink0; nE0+=nWink0; if (bXMirr) { long nTmp=nS0; nS0=18000-nE0; nE0=18000-nTmp; } if (bYMirr) { long nTmp=nS0; nS0=-nE0; nE0=-nTmp; } nS0-=aGeo.nDrehWink; nE0-=aGeo.nDrehWink; } } long nWinkDif=nE0-nS0; nStartWink=NormAngle360(nS0); nEndWink =NormAngle360(nE0); if (nWinkDif==36000) nEndWink+=nWinkDif; // full circle } } SetXPolyDirty(); ImpSetCircInfoToAttr(); } void SdrCircObj::NbcShear(const Point& rRef, long nWink, double tn, bool bVShear) { SdrTextObj::NbcShear(rRef,nWink,tn,bVShear); SetXPolyDirty(); ImpSetCircInfoToAttr(); } void SdrCircObj::NbcMirror(const Point& rRef1, const Point& rRef2) { bool bFreeMirr=meCircleKind!=OBJ_CIRC; Point aTmpPt1; Point aTmpPt2; if (bFreeMirr) { // some preparations for using an arbitrary axis of reflection Point aCenter(aRect.Center()); long nWdt=aRect.GetWidth()-1; long nHgt=aRect.GetHeight()-1; long nMaxRad=((nWdt>nHgt ? nWdt : nHgt)+1) /2; double a; // starting point a=nStartWink*nPi180; aTmpPt1=Point(Round(cos(a)*nMaxRad),-Round(sin(a)*nMaxRad)); if (nWdt==0) aTmpPt1.X()=0; if (nHgt==0) aTmpPt1.Y()=0; aTmpPt1+=aCenter; // finishing point a=nEndWink*nPi180; aTmpPt2=Point(Round(cos(a)*nMaxRad),-Round(sin(a)*nMaxRad)); if (nWdt==0) aTmpPt2.X()=0; if (nHgt==0) aTmpPt2.Y()=0; aTmpPt2+=aCenter; if (aGeo.nDrehWink!=0) { RotatePoint(aTmpPt1,aRect.TopLeft(),aGeo.nSin,aGeo.nCos); RotatePoint(aTmpPt2,aRect.TopLeft(),aGeo.nSin,aGeo.nCos); } if (aGeo.nShearWink!=0) { ShearPoint(aTmpPt1,aRect.TopLeft(),aGeo.nTan); ShearPoint(aTmpPt2,aRect.TopLeft(),aGeo.nTan); } } SdrTextObj::NbcMirror(rRef1,rRef2); if (meCircleKind!=OBJ_CIRC) { // adapt starting and finishing angle MirrorPoint(aTmpPt1,rRef1,rRef2); MirrorPoint(aTmpPt2,rRef1,rRef2); // unrotate: if (aGeo.nDrehWink!=0) { RotatePoint(aTmpPt1,aRect.TopLeft(),-aGeo.nSin,aGeo.nCos); // -sin for reversion RotatePoint(aTmpPt2,aRect.TopLeft(),-aGeo.nSin,aGeo.nCos); // -sin for reversion } // unshear: if (aGeo.nShearWink!=0) { ShearPoint(aTmpPt1,aRect.TopLeft(),-aGeo.nTan); // -tan for reversion ShearPoint(aTmpPt2,aRect.TopLeft(),-aGeo.nTan); // -tan for reversion } Point aCenter(aRect.Center()); aTmpPt1-=aCenter; aTmpPt2-=aCenter; // because it's mirrored, the angles are swapped, too nStartWink=GetAngle(aTmpPt2); nEndWink =GetAngle(aTmpPt1); long nWinkDif=nEndWink-nStartWink; nStartWink=NormAngle360(nStartWink); nEndWink =NormAngle360(nEndWink); if (nWinkDif==36000) nEndWink+=nWinkDif; // full circle } SetXPolyDirty(); ImpSetCircInfoToAttr(); } SdrObjGeoData* SdrCircObj::NewGeoData() const { return new SdrCircObjGeoData; } void SdrCircObj::SaveGeoData(SdrObjGeoData& rGeo) const { SdrRectObj::SaveGeoData(rGeo); SdrCircObjGeoData& rCGeo=(SdrCircObjGeoData&)rGeo; rCGeo.nStartWink=nStartWink; rCGeo.nEndWink =nEndWink; } void SdrCircObj::RestGeoData(const SdrObjGeoData& rGeo) { SdrRectObj::RestGeoData(rGeo); SdrCircObjGeoData& rCGeo=(SdrCircObjGeoData&)rGeo; nStartWink=rCGeo.nStartWink; nEndWink =rCGeo.nEndWink; SetXPolyDirty(); ImpSetCircInfoToAttr(); } void Union(Rectangle& rR, const Point& rP) { if (rP.X()rR.Right ()) rR.Right ()=rP.X(); if (rP.Y()rR.Bottom()) rR.Bottom()=rP.Y(); } void SdrCircObj::TakeUnrotatedSnapRect(Rectangle& rRect) const { rRect=aRect; if (meCircleKind!=OBJ_CIRC) { const Point aPntStart(GetWinkPnt(aRect,nStartWink)); const Point aPntEnd(GetWinkPnt(aRect,nEndWink)); long a=nStartWink; long e=nEndWink; rRect.Left ()=aRect.Right(); rRect.Right ()=aRect.Left(); rRect.Top ()=aRect.Bottom(); rRect.Bottom()=aRect.Top(); Union(rRect,aPntStart); Union(rRect,aPntEnd); if ((a<=18000 && e>=18000) || (a>e && (a<=18000 || e>=18000))) { Union(rRect,aRect.LeftCenter()); } if ((a<=27000 && e>=27000) || (a>e && (a<=27000 || e>=27000))) { Union(rRect,aRect.BottomCenter()); } if (a>e) { Union(rRect,aRect.RightCenter()); } if ((a<=9000 && e>=9000) || (a>e && (a<=9000 || e>=9000))) { Union(rRect,aRect.TopCenter()); } if (meCircleKind==OBJ_SECT) { Union(rRect,aRect.Center()); } if (aGeo.nDrehWink!=0) { Point aDst(rRect.TopLeft()); aDst-=aRect.TopLeft(); Point aDst0(aDst); RotatePoint(aDst,Point(),aGeo.nSin,aGeo.nCos); aDst-=aDst0; rRect.Move(aDst.X(),aDst.Y()); } } if (aGeo.nShearWink!=0) { long nDst=Round((rRect.Bottom()-rRect.Top())*aGeo.nTan); if (aGeo.nShearWink>0) { Point aRef(rRect.TopLeft()); rRect.Left()-=nDst; Point aTmpPt(rRect.TopLeft()); RotatePoint(aTmpPt,aRef,aGeo.nSin,aGeo.nCos); aTmpPt-=rRect.TopLeft(); rRect.Move(aTmpPt.X(),aTmpPt.Y()); } else { rRect.Right()-=nDst; } } } void SdrCircObj::RecalcSnapRect() { if (PaintNeedsXPolyCirc()) { maSnapRect=GetXPoly().GetBoundRect(); } else { TakeUnrotatedSnapRect(maSnapRect); } } void SdrCircObj::NbcSetSnapRect(const Rectangle& rRect) { if (aGeo.nDrehWink!=0 || aGeo.nShearWink!=0 || meCircleKind!=OBJ_CIRC) { Rectangle aSR0(GetSnapRect()); long nWdt0=aSR0.Right()-aSR0.Left(); long nHgt0=aSR0.Bottom()-aSR0.Top(); long nWdt1=rRect.Right()-rRect.Left(); long nHgt1=rRect.Bottom()-rRect.Top(); NbcResize(maSnapRect.TopLeft(),Fraction(nWdt1,nWdt0),Fraction(nHgt1,nHgt0)); NbcMove(Size(rRect.Left()-aSR0.Left(),rRect.Top()-aSR0.Top())); } else { aRect=rRect; ImpJustifyRect(aRect); } SetRectsDirty(); SetXPolyDirty(); ImpSetCircInfoToAttr(); } sal_uInt32 SdrCircObj::GetSnapPointCount() const { if (meCircleKind==OBJ_CIRC) { return 1L; } else { return 3L; } } Point SdrCircObj::GetSnapPoint(sal_uInt32 i) const { switch (i) { case 1 : return GetWinkPnt(aRect,nStartWink); case 2 : return GetWinkPnt(aRect,nEndWink); default: return aRect.Center(); } } void SdrCircObj::Notify(SfxBroadcaster& rBC, const SfxHint& rHint) { SetXPolyDirty(); SdrRectObj::Notify(rBC,rHint); ImpSetAttrToCircInfo(); } //////////////////////////////////////////////////////////////////////////////////////////////////// void SdrCircObj::ImpSetAttrToCircInfo() { const SfxItemSet& rSet = GetObjectItemSet(); SdrCircKind eNewKindA = ((SdrCircKindItem&)rSet.Get(SDRATTR_CIRCKIND)).GetValue(); SdrObjKind eNewKind = meCircleKind; if(eNewKindA == SDRCIRC_FULL) eNewKind = OBJ_CIRC; else if(eNewKindA == SDRCIRC_SECT) eNewKind = OBJ_SECT; else if(eNewKindA == SDRCIRC_ARC) eNewKind = OBJ_CARC; else if(eNewKindA == SDRCIRC_CUT) eNewKind = OBJ_CCUT; sal_Int32 nNewStart = ((SdrCircStartAngleItem&)rSet.Get(SDRATTR_CIRCSTARTANGLE)).GetValue(); sal_Int32 nNewEnd = ((SdrCircEndAngleItem&)rSet.Get(SDRATTR_CIRCENDANGLE)).GetValue(); sal_Bool bKindChg = meCircleKind != eNewKind; sal_Bool bWinkChg = nNewStart != nStartWink || nNewEnd != nEndWink; if(bKindChg || bWinkChg) { meCircleKind = eNewKind; nStartWink = nNewStart; nEndWink = nNewEnd; if(bKindChg || (meCircleKind != OBJ_CIRC && bWinkChg)) { SetXPolyDirty(); SetRectsDirty(); } } } void SdrCircObj::ImpSetCircInfoToAttr() { SdrCircKind eNewKindA = SDRCIRC_FULL; const SfxItemSet& rSet = GetObjectItemSet(); if(meCircleKind == OBJ_SECT) eNewKindA = SDRCIRC_SECT; else if(meCircleKind == OBJ_CARC) eNewKindA = SDRCIRC_ARC; else if(meCircleKind == OBJ_CCUT) eNewKindA = SDRCIRC_CUT; SdrCircKind eOldKindA = ((SdrCircKindItem&)rSet.Get(SDRATTR_CIRCKIND)).GetValue(); sal_Int32 nOldStartWink = ((SdrCircStartAngleItem&)rSet.Get(SDRATTR_CIRCSTARTANGLE)).GetValue(); sal_Int32 nOldEndWink = ((SdrCircEndAngleItem&)rSet.Get(SDRATTR_CIRCENDANGLE)).GetValue(); if(eNewKindA != eOldKindA || nStartWink != nOldStartWink || nEndWink != nOldEndWink) { // since SetItem() implicitly calls ImpSetAttrToCircInfo() // setting the item directly is necessary here. if(eNewKindA != eOldKindA) { GetProperties().SetObjectItemDirect(SdrCircKindItem(eNewKindA)); } if(nStartWink != nOldStartWink) { GetProperties().SetObjectItemDirect(SdrCircStartAngleItem(nStartWink)); } if(nEndWink != nOldEndWink) { GetProperties().SetObjectItemDirect(SdrCircEndAngleItem(nEndWink)); } SetXPolyDirty(); ImpSetAttrToCircInfo(); } } SdrObject* SdrCircObj::DoConvertToPolyObj(sal_Bool bBezier) const { const sal_Bool bFill(OBJ_CARC == meCircleKind ? sal_False : sal_True); const basegfx::B2DPolygon aCircPolygon(ImpCalcXPolyCirc(meCircleKind, aRect, nStartWink, nEndWink)); SdrObject* pRet = ImpConvertMakeObj(basegfx::B2DPolyPolygon(aCircPolygon), bFill, bBezier); pRet = ImpConvertAddText(pRet, bBezier); return pRet; } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */