void bench_fr_front_to_surf ( Flux_Pts front, Im2D_U_INT1 i0, Neighbourhood v ) { Pt2di sz (i0.tx(),i0.ty()); Im2D_U_INT1 i1(sz.x,sz.y,0); ELISE_COPY(i0.all_pts(),i0.in(),i1.out()); ELISE_COPY ( dilate ( select ( i1.all_pts(), i1.in()==1 ), sel_func(v,i1.in()==0) ), 2, i1.out() ); ELISE_COPY(front,2,i0.out()); INT dif; ELISE_COPY ( i1.all_pts(), Abs(i1.in()-i0.in()), sigma(dif) ); BENCH_ASSERT(dif == 0); }
void cMMTP::ContAndBoucheTrou() { int aDist32Close = 6; int aNbErod = 6; // 1- Quelques fitre morpho de base, pour calculer les points eligibles au bouche-trou int aLabelOut = 0; //int aLabelIn = 1; int aLabelClose = 2; int aLabelFront = 3; ELISE_COPY(mImMasqInit.all_pts(),mImMasqInit.in(),mImLabel.out()); ELISE_COPY(mImLabel.border(2),aLabelOut,mImLabel.out()); // 1.1 calcul des point dans le fermeture ELISE_COPY ( select ( mImLabel.all_pts(), close_32(mImLabel.in(0),aDist32Close) && (mImLabel.in()==aLabelOut) ), aLabelClose, mImLabel.out() ); ELISE_COPY(mImLabel.border(2),aLabelOut,mImLabel.out()); // 1.2 erosion de ces points Neighbourhood V4 = Neighbourhood::v4(); Neighbourhood V8 = Neighbourhood::v8(); Neigh_Rel aRelV4(V4); Liste_Pts_U_INT2 aLFront(2); ELISE_COPY ( select ( mImLabel.all_pts(), (mImLabel.in(0)==aLabelClose) && (aRelV4.red_max(mImLabel.in(0)==aLabelOut)) ), aLabelFront, mImLabel.out() | aLFront ); for (int aK=0 ; aK<aNbErod ; aK++) { Liste_Pts_U_INT2 aLNew(2); ELISE_COPY ( dilate ( aLFront.all_pts(), mImLabel.neigh_test_and_set(Neighbourhood::v4(),2,3,20) ), aLabelFront, aLNew ); aLFront = aLNew; } ELISE_COPY(select(mImLabel.all_pts(),mImLabel.in()==aLabelFront),0,mImLabel.out()); // Au cas ou on ferait un export premature ELISE_COPY(mImMasqFinal.all_pts(),mImLabel.in()!=0,mImMasqFinal.out()); int aSomMaskF; ELISE_COPY(mImMasqFinal.all_pts(),mImLabel.in()==1,sigma(aSomMaskF)); if (aSomMaskF < 100) return; // std::cout << "aSomMaskFaSomMaskF " << aSomMaskF << "\n"; // 2- Dequantifiication, adaptee au image a trou Im2D_REAL4 aProfCont(mSzTiep.x,mSzTiep.y,0.0); { Im2D_INT2 aPPV = BouchePPV(mImProf,mImLabel.in()==1); ElImplemDequantifier aDeq(mSzTiep); aDeq.DoDequantif(mSzTiep,aPPV.in()); ELISE_COPY(aProfCont.all_pts(),aDeq.ImDeqReelle(),aProfCont.out()); ELISE_COPY(select(aProfCont.all_pts(),mImLabel.in()!=1),0,aProfCont.out()); } //Im2D_REAL4 aImInterp(mSzTiep.x,mSzTiep.y); TIm2D<REAL4,REAL8> aTInterp(mContBT); // 3- Bouchage "fin" des trour par moinde L2 // 3.1 Valeur initial // Filtrage gaussien Fonc_Num aFMasq = (mImLabel.in(0)==1); Fonc_Num aFProf = (aProfCont.in(0) * aFMasq); for (int aK=0 ; aK<3 ; aK++) { aFMasq = rect_som(aFMasq,1) /9.0; aFProf = rect_som(aFProf,1) /9.0; } ELISE_COPY ( mContBT.all_pts(), aFProf / Max(aFMasq,1e-9), mContBT.out() ); // On remet la valeur init au point ayant un valeur propre ELISE_COPY ( select(mContBT.all_pts(),mImLabel.in()==1), aProfCont.in(), mContBT.out() ); // Et rien en dehors de l'image ELISE_COPY ( select(mContBT.all_pts(),mImLabel.in()==0), 0, mContBT.out() ); // 3.2 Iteration pour regulariser les points interpoles { std::vector<Pt2di> aVInterp; { Pt2di aP; for (aP.x=0 ; aP.x<mSzTiep.x ; aP.x++) { for (aP.y=0 ; aP.y<mSzTiep.y ; aP.y++) { if (mTLab.get(aP)==aLabelClose) aVInterp.push_back(aP); } } } for (int aKIter=0 ; aKIter<20 ; aKIter++) { std::vector<double> aVVals; for (int aKP=0 ; aKP<int(aVInterp.size()) ; aKP++) { double aSom=0; double aSomPds = 0; Pt2di aPK = aVInterp[aKP]; for (int aKV=0 ; aKV<9 ; aKV++) { Pt2di aVois = aPK+TAB_9_NEIGH[aKV]; if (mTLab.get(aVois)!=0) { int aPds = PdsGaussl9NEIGH[aKV]; aSom += aTInterp.get(aVois) * aPds; aSomPds += aPds; } } ELISE_ASSERT(aSomPds!=0,"Assert P!=0"); aVVals.push_back(aSom/aSomPds); } for (int aKP=0 ; aKP<int(aVInterp.size()) ; aKP++) { aTInterp.oset(aVInterp[aKP],aVVals[aKP]); } } } /* */ #ifdef ELISE_X11 if(0 && TheWTiePCor) { ELISE_COPY ( mImLabel.all_pts(), mContBT.in()*7, TheWTiePCor->ocirc() ); TheWTiePCor->clik_in(); ELISE_COPY ( mImLabel.all_pts(), nflag_close_sym(flag_front4(mImLabel.in(0)==1)), TheWTiePCor->out_graph(Line_St(TheWTiePCor->pdisc()(P8COL::black))) ); TheWTiePCor->clik_in(); ELISE_COPY ( mImLabel.all_pts(), mImLabel.in(0), TheWTiePCor->odisc() ); TheWTiePCor->clik_in(); ELISE_COPY ( mImLabel.all_pts(), mImMasqFinal.in(0), TheWTiePCor->odisc() ); TheWTiePCor->clik_in(); } #endif }
static void Set(Im2D_U_INT1 I,Box2di box,INT val) { ELISE_COPY ( rectangle(box), val, I.out()); }
void FiltreRemoveBorderHeter(Im2D_REAL4 anIm,Im2D_U_INT1 aImMasq,double aCostRegul,double aCostTrans) { Pt2di aSz = anIm.sz(); double aVMax,aVMin; ELISE_COPY(aImMasq.border(1),0,aImMasq.out()); ELISE_COPY(aImMasq.all_pts(),aImMasq.in()!=0,aImMasq.out()); ELISE_COPY(anIm.all_pts(),anIm.in(),VMax(aVMax)|VMin(aVMin)); Video_Win * aW = Video_Win::PtrWStd(aSz); ELISE_COPY(anIm.all_pts(),(anIm.in()-aVMin) * (255.0/(aVMax-aVMin)),aW->ogray()); std::cout << "VMAX " << aVMax << "\n"; //ELISE_COPY(aW->all_pts(),aImMasq.in(),aW->odisc()); //aW->clik_in(); ELISE_COPY ( aW->all_pts(), nflag_close_sym(flag_front8(aImMasq.in_proj()!=0)), aW->out_graph(Line_St(aW->pdisc()(P8COL::red))) ); cParamFiltreDepthByPrgDyn aParam = StdGetFromSI(Basic_XML_MM_File("DefFiltrPrgDyn.xml"),ParamFiltreDepthByPrgDyn); aParam.CostTrans() = aCostTrans; aParam.CostRegul() = aCostRegul; Im2D_Bits<1> aNewMasq = FiltrageDepthByProgDyn(anIm,aImMasq,aParam); ELISE_COPY ( select(aNewMasq.all_pts(),aNewMasq.in()), 2, aImMasq.out() ); TIm2D<U_INT1,INT> aTMasq(aImMasq); FiltrageCardCC(false,aTMasq,2,0,100); Neighbourhood aNV4=Neighbourhood::v4(); Neigh_Rel aNrV4 (aNV4); ELISE_COPY ( conc ( select(select(aImMasq.all_pts(),aImMasq.in()==1),aNrV4.red_sum(aImMasq.in()==0)), aImMasq.neigh_test_and_set(aNV4,1,0,256) ), 3, Output::onul() ); ELISE_COPY ( aNewMasq.all_pts(), aImMasq.in(), aW->odisc() ); /* ELISE_COPY ( aW->all_pts(), nflag_close_sym(flag_front8(aNewMasq.in_proj())), aW->out_graph(Line_St(aW->pdisc()(P8COL::green))) ); */ aW->clik_in(); }