/*M/////////////////////////////////////////////////////////////////////////////////////// // // IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. // // By downloading, copying, installing or using the software you agree to this license. // If you do not agree to this license, do not download, install, // copy or use the software. // // // Intel License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2000, Intel Corporation, all rights reserved. // Third party copyrights are property of their respective owners. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // // * Redistribution's of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // * Redistribution's in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // // * The name of Intel Corporation may not be used to endorse or promote products // derived from this software without specific prior written permission. // // This software is provided by the copyright holders and contributors "as is" and // any express or implied warranties, including, but not limited to, the implied // warranties of merchantability and fitness for a particular purpose are disclaimed. // In no event shall the Intel Corporation or contributors be liable for any direct, // indirect, incidental, special, exemplary, or consequential damages // (including, but not limited to, procurement of substitute goods or services; // loss of use, data, or profits; or business interruption) however caused // and on any theory of liability, whether in contract, strict liability, // or tort (including negligence or otherwise) arising in any way out of // the use of this software, even if advised of the possibility of such damage. // //M*/ /* Hybrid linear-contour model reconstruction */ #include "precomp.hpp" #define CV_IMPL CV_EXTERN_C const float LCM_CONST_ZERO = 1e-6f; /****************************************************************************************\ * Auxiliary struct definitions * \****************************************************************************************/ typedef struct CvLCM { CvGraph* Graph; CvVoronoiDiagram2D* VoronoiDiagram; CvMemStorage* ContourStorage; CvMemStorage* EdgeStorage; float maxWidth; } CvLCM; typedef struct CvLCMComplexNodeData { CvVoronoiNode2D edge_node; CvPoint2D32f site_first_pt; CvPoint2D32f site_last_pt; CvVoronoiSite2D* site_first; CvVoronoiSite2D* site_last; CvVoronoiEdge2D* edge; } CvLCMComplexNodeData; typedef struct CvLCMData { CvVoronoiNode2D* pnode; CvVoronoiSite2D* psite; CvVoronoiEdge2D* pedge; } CvLCMData; /****************************************************************************************\ * Function definitions * \****************************************************************************************/ #define _CV_READ_SEQ_ELEM( elem, reader, type ) \ { \ assert( (reader).seq->elem_size == sizeof(*elem)); \ elem = (type)(reader).ptr; \ CV_NEXT_SEQ_ELEM( sizeof(*elem), reader ) \ } #define _CV_IS_SITE_REFLEX( SITE ) ((SITE) ->node[0] == (SITE) ->node[1]) #define _CV_IS_EDGE_REFLEX( EDGE ) (( (EDGE)->site[0]->node[0] == (EDGE)->site[0]->node[0] ) || \ ( (EDGE)->site[1]->node[0] == (EDGE)->site[1]->node[0] ) ) #define _CV_INITIALIZE_CVLCMDATA(STRUCT,SITE,EDGE,NODE)\ { (STRUCT)->psite = SITE ; (STRUCT)->pedge = EDGE; (STRUCT)->pnode = NODE;} /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvConstructLCM // Purpose: Function constructs hybrid model // Context: // Parameters: // LCM : in&out. // Returns: 1, if hybrid model was succesfully constructed // 0, if some error occures //F*/ CV_IMPL int _cvConstructLCM(CvLCM* LCM); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvConstructLCMComplexNode // Purpose: Function constructs Complex Node (node, which consists of // two points and more) of hybrid model // Context: // Parameters: // pLCM : in&out. // pLCMEdge: in, input edge of hybrid model // pLCMInputData: in, input parameters // Returns: pointer to constructed node //F*/ CV_IMPL CvLCMNode* _cvConstructLCMComplexNode(CvLCM* pLCM, CvLCMEdge* pLCMEdge, CvLCMData* pLCMInputData); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvConstructLCMSimpleNode // Purpose: Function constructs Simple Node (node, which consists of // one point) of hybrid model // Context: // Parameters: // pLCM : in&out. // pLCMEdge: in, input edge of hybrid model // pLCMInputData: in, input parameters // Returns: pointer to constructed node //F*/ CV_IMPL CvLCMNode* _cvConstructLCMSimpleNode(CvLCM* pLCM, CvLCMEdge* pLCMEdge, CvLCMData* pLCMInputData); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvConstructLCMSimpleNode // Purpose: Function constructs Edge of hybrid model // Context: // Parameters: // pLCM : in&out. // pLCMInputData: in, input parameters // Returns: pointer to constructed edge //F*/ CV_IMPL CvLCMEdge* _cvConstructLCMEdge(CvLCM* pLCM, CvLCMData* pLCMInputData); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvTreatExeptionalCase // Purpose: Function treats triangles and regular polygons // Context: // Parameters: // pLCM : in, information about graph // pLCMInputData: in, input parameters // Returns: pointer to graph node //F*/ CV_IMPL CvLCMNode* _cvTreatExeptionalCase(CvLCM* pLCM, CvLCMData* pLCMInputData); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvNodeMultyplicity // Purpose: Function seeks all non-boundary edges incident to // given node and correspondent incident sites // Context: // Parameters: // pEdge : in, original edge // pNode : in, given node // LinkedEdges : out, matrix of incident edges // LinkedSites : out, matrix of incident sites // pSite: in, original site (pNode must be the begin point of pEdge // for this pSite, this property hold out far all edges) // Returns: number of incident edges (must be less than 10) //F*/ CV_IMPL int _cvNodeMultyplicity(CvVoronoiSite2D* pSite, CvVoronoiEdge2D* pEdge, CvVoronoiNode2D* pNode, CvVoronoiEdge2D** LinkedEdges, CvVoronoiSite2D** LinkedSites); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvCreateLCMNode // Purpose: Function create graph node // Context: // Parameters: // pLCM : in, information about graph // Returns: pointer to graph node //F*/ CV_IMPL CvLCMNode* _cvCreateLCMNode(CvLCM* pLCM); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvCreateLCMEdge // Purpose: Function create graph edge // Context: // Parameters: // pLCM : in, information about graph // Returns: pointer to graph edge //F*/ CV_IMPL CvLCMEdge* _cvCreateLCMEdge(CvLCM* pLCM); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvCreateLCMNode // Purpose: Function establishs the connection between node and ege // Context: // Parameters: // LCMNode : in, graph node // LCMEdge : in, graph edge // LCMEdge_prev : in&out, previous edge, connected with given node // index: in, // i : =0, if node is initial for edge // =1, if node is terminal for edge // Returns: //F*/ CV_IMPL void _cvAttachLCMEdgeToLCMNode(CvLCMNode* LCMNode, CvLCMEdge* LCMEdge, CvLCMEdge* &LCMEdge_prev, int index, int i); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvProjectionPointToSegment // Purpose: Function computes the ortogonal projection of PointO to // to segment[PointA, PointB] // Context: // Parameters: // PointO, PointA,PointB: in, given points // PrPoint : out, projection // dist : distance from PointO to PrPoint // Returns: //F*/ CV_IMPL void _cvProjectionPointToSegment(CvPoint2D32f* PointO, CvPoint2D32f* PointA, CvPoint2D32f* PointB, CvPoint2D32f* PrPoint, float* dist); /*F/////////////////////////////////////////////////////////////////////////////////////// // Author: Andrey Sobolev // Name: _cvPrepareData // Purpose: Function fills up the struct CvLCMComplexNodeData // Context: // Parameters: // pLCMData : in // pLCMCCNData : out // Returns: //F*/ CV_IMPL void _cvPrepareData(CvLCMComplexNodeData* pLCMCCNData, CvLCMData* pLCMData); /****************************************************************************************\ * Function realization * \****************************************************************************************/ CV_IMPL CvGraph* cvLinearContorModelFromVoronoiDiagram(CvVoronoiDiagram2D* VoronoiDiagram, float maxWidth) { CvMemStorage* LCMstorage; CvSet* SiteSet; CvLCM LCM = {NULL, VoronoiDiagram,NULL,NULL,maxWidth}; CV_FUNCNAME( "cvLinearContorModelFromVoronoiDiagram" ); __BEGIN__; if( !VoronoiDiagram ) CV_ERROR( CV_StsBadArg,"Voronoi Diagram is not defined" ); if( maxWidth < 0 ) CV_ERROR( CV_StsBadArg,"Treshold parameter must be non negative" ); for(SiteSet = VoronoiDiagram->sites; SiteSet != NULL; SiteSet = (CvSet*)SiteSet->h_next) { if(SiteSet->v_next) CV_ERROR( CV_StsBadArg,"Can't operate with multiconnected domains" ); if(SiteSet->total > 70000) CV_ERROR( CV_StsBadArg,"Can't operate with large domains" ); } LCMstorage = cvCreateMemStorage(0); LCM.EdgeStorage = cvCreateChildMemStorage(LCMstorage); LCM.ContourStorage = cvCreateChildMemStorage(LCMstorage); LCM.Graph = cvCreateGraph(CV_SEQ_KIND_GRAPH|CV_GRAPH_FLAG_ORIENTED, sizeof(CvGraph), sizeof(CvLCMNode), sizeof(CvLCMEdge), LCMstorage); if(!_cvConstructLCM(&LCM)) cvReleaseLinearContorModelStorage(&LCM.Graph); __END__; return LCM.Graph; }//end of cvLinearContorModelFromVoronoiDiagram CV_IMPL int cvReleaseLinearContorModelStorage(CvGraph** Graph) { CvSeq* LCMNodeSeq, *LCMEdgeSeq; CvLCMNode* pLCMNode; CvLCMEdge* pLCMEdge; /*CV_FUNCNAME( "cvReleaseLinearContorModelStorage" );*/ __BEGIN__; if(!Graph || !(*Graph)) return 0; LCMNodeSeq = (CvSeq*)(*Graph); LCMEdgeSeq = (CvSeq*)(*Graph)->edges; if(LCMNodeSeq->total > 0) { pLCMNode = (CvLCMNode*)cvGetSeqElem(LCMNodeSeq,0); if(pLCMNode->contour->storage) cvReleaseMemStorage(&pLCMNode->contour->storage); } if(LCMEdgeSeq->total > 0) { pLCMEdge = (CvLCMEdge*)cvGetSeqElem(LCMEdgeSeq,0); if(pLCMEdge->chain->storage) cvReleaseMemStorage(&pLCMEdge->chain->storage); } if((*Graph)->storage) cvReleaseMemStorage(&(*Graph)->storage); *Graph = NULL; __END__; return 1; }//end of cvReleaseLinearContorModelStorage int _cvConstructLCM(CvLCM* LCM) { CvVoronoiSite2D* pSite = 0; CvVoronoiEdge2D* pEdge = 0, *pEdge1; CvVoronoiNode2D* pNode, *pNode1; CvVoronoiEdge2D* LinkedEdges[10]; CvVoronoiSite2D* LinkedSites[10]; CvSeqReader reader; CvLCMData LCMdata; int i; for(CvSet* SiteSet = LCM->VoronoiDiagram->sites; SiteSet != NULL; SiteSet = (CvSet*)SiteSet->h_next) { cvStartReadSeq((CvSeq*)SiteSet, &reader); for(i = 0; i < SiteSet->total; i++) { _CV_READ_SEQ_ELEM(pSite,reader,CvVoronoiSite2D*); if(pSite->node[0] == pSite->node[1]) continue; pEdge = CV_LAST_VORONOIEDGE2D(pSite); pNode = CV_VORONOIEDGE2D_BEGINNODE(pEdge,pSite); if(pNode->radius > LCM->maxWidth) goto PREPARECOMPLEXNODE; pEdge1 = CV_PREV_VORONOIEDGE2D(pEdge,pSite); pNode1 = CV_VORONOIEDGE2D_BEGINNODE(pEdge1,pSite); if(pNode1->radius > LCM->maxWidth) goto PREPARECOMPLEXNODE; if(pNode1->radius == 0) continue; if(_cvNodeMultyplicity(pSite, pEdge,pNode,LinkedEdges,LinkedSites) == 1) goto PREPARESIMPLENODE; } // treate triangle or regular polygon _CV_INITIALIZE_CVLCMDATA(&LCMdata,pSite,pEdge,CV_VORONOIEDGE2D_ENDNODE(pEdge,pSite)); if(!_cvTreatExeptionalCase(LCM,&LCMdata)) return 0; continue; PREPARECOMPLEXNODE: _CV_INITIALIZE_CVLCMDATA(&LCMdata,pSite,pEdge,CV_VORONOIEDGE2D_ENDNODE(pEdge,pSite)); if(!_cvConstructLCMComplexNode(LCM,NULL,&LCMdata)) return 0; continue; PREPARESIMPLENODE: _CV_INITIALIZE_CVLCMDATA(&LCMdata,pSite,pEdge,CV_VORONOIEDGE2D_ENDNODE(pEdge,pSite)); if(!_cvConstructLCMSimpleNode(LCM,NULL,&LCMdata)) return 0; continue; } return 1; }//end of _cvConstructLCM CvLCMNode* _cvConstructLCMComplexNode(CvLCM* pLCM, CvLCMEdge* pLCMEdge, CvLCMData* pLCMInputData) { CvLCMNode* pLCMNode; CvLCMEdge* pLCMEdge_prev = NULL; CvSeqWriter writer; CvVoronoiSite2D* pSite, *pSite_first, *pSite_last; CvVoronoiEdge2D* pEdge, *pEdge_stop; CvVoronoiNode2D* pNode0, *pNode1; CvLCMData LCMOutputData; CvLCMComplexNodeData LCMCCNData; int index = 0; _cvPrepareData(&LCMCCNData,pLCMInputData); pLCMNode = _cvCreateLCMNode(pLCM); _cvAttachLCMEdgeToLCMNode(pLCMNode,pLCMEdge,pLCMEdge_prev,1,1); cvStartAppendToSeq((CvSeq*)pLCMNode->contour,&writer); CV_WRITE_SEQ_ELEM(LCMCCNData.site_last_pt, writer); index++; if(pLCMEdge) { CV_WRITE_SEQ_ELEM(LCMCCNData.edge_node.pt, writer ); CV_WRITE_SEQ_ELEM(LCMCCNData.site_first_pt, writer ); index+=2; } pSite_first = LCMCCNData.site_first; pSite_last = LCMCCNData.site_last; pEdge = LCMCCNData.edge; for(pSite = pSite_first; pSite != pSite_last; pSite = CV_NEXT_VORONOISITE2D(pSite), pEdge = CV_PREV_VORONOIEDGE2D(CV_LAST_VORONOIEDGE2D(pSite),pSite)) { pEdge_stop = CV_FIRST_VORONOIEDGE2D(pSite); for(;pEdge && pEdge != pEdge_stop; pEdge = CV_PREV_VORONOIEDGE2D(pEdge,pSite)) { pNode0 = CV_VORONOIEDGE2D_BEGINNODE(pEdge,pSite); pNode1 = CV_VORONOIEDGE2D_ENDNODE(pEdge,pSite); if(pNode0->radius <= pLCM->maxWidth && pNode1->radius <= pLCM->maxWidth) { _CV_INITIALIZE_CVLCMDATA(&LCMOutputData,pSite,pEdge,pNode1); _cvPrepareData(&LCMCCNData,&LCMOutputData); CV_WRITE_SEQ_ELEM(LCMCCNData.site_first_pt, writer); CV_WRITE_SEQ_ELEM(LCMCCNData.edge_node.pt, writer ); index+=2; pLCMEdge = _cvConstructLCMEdge(pLCM,&LCMOutputData); _cvAttachLCMEdgeToLCMNode(pLCMNode,pLCMEdge,pLCMEdge_prev,index - 1,0); CV_WRITE_SEQ_ELEM(LCMCCNData.site_last_pt, writer); index++; pSite = CV_TWIN_VORONOISITE2D(pSite,pEdge); pEdge_stop = CV_FIRST_VORONOIEDGE2D(pSite); if(pSite == pSite_last) break; } } if(pSite == pSite_last) break; CV_WRITE_SEQ_ELEM(pSite->node[1]->pt, writer); index++; } if(pLCMEdge_prev) pLCMEdge_prev->next[(pLCMEdge_prev == (CvLCMEdge*)pLCMNode->first)] = pLCMNode->first; cvEndWriteSeq(&writer); return pLCMNode; }//end of _cvConstructLCMComplexNode CvLCMNode* _cvConstructLCMSimpleNode(CvLCM* pLCM, CvLCMEdge* pLCMEdge, CvLCMData* pLCMInputData) { CvVoronoiEdge2D* pEdge = pLCMInputData->pedge; CvVoronoiSite2D* pSite = pLCMInputData->psite; CvVoronoiNode2D* pNode = CV_VORONOIEDGE2D_BEGINNODE(pEdge,pSite); CvVoronoiEdge2D* LinkedEdges[10]; CvVoronoiSite2D* LinkedSites[10]; int multyplicity = _cvNodeMultyplicity(pSite,pEdge,pNode,LinkedEdges,LinkedSites); if(multyplicity == 2) { pLCMInputData->pedge = LinkedEdges[1]; pLCMInputData->psite = CV_TWIN_VORONOISITE2D(LinkedSites[1],LinkedEdges[1]); return NULL; } CvLCMEdge* pLCMEdge_prev = NULL; CvLCMNode* pLCMNode; CvLCMData LCMOutputData; pLCMNode = _cvCreateLCMNode(pLCM); cvSeqPush((CvSeq*)pLCMNode->contour,&pNode->pt); _cvAttachLCMEdgeToLCMNode(pLCMNode,pLCMEdge,pLCMEdge_prev,0,1); for(int i = (int)(pLCMEdge != NULL);i < multyplicity; i++) { pEdge = LinkedEdges[i]; pSite = LinkedSites[i]; _CV_INITIALIZE_CVLCMDATA(&LCMOutputData,CV_TWIN_VORONOISITE2D(pSite,pEdge),pEdge,pNode); pLCMEdge = _cvConstructLCMEdge(pLCM,&LCMOutputData); _cvAttachLCMEdgeToLCMNode(pLCMNode,pLCMEdge,pLCMEdge_prev,0,0); } pLCMEdge_prev->next[(pLCMEdge_prev == (CvLCMEdge*)pLCMNode->first)] = pLCMNode->first; return pLCMNode; }//end of _cvConstructLCMSimpleNode CvLCMEdge* _cvConstructLCMEdge(CvLCM* pLCM, CvLCMData* pLCMInputData) { CvVoronoiEdge2D* pEdge = pLCMInputData->pedge; CvVoronoiSite2D* pSite = pLCMInputData->psite; float width = 0; CvLCMData LCMData; CvVoronoiNode2D* pNode0,*pNode1; CvLCMEdge* pLCMEdge = _cvCreateLCMEdge(pLCM); CvSeqWriter writer; cvStartAppendToSeq(pLCMEdge->chain,&writer ); pNode0 = pNode1 = pLCMInputData->pnode; CV_WRITE_SEQ_ELEM(pNode0->pt, writer); width += pNode0->radius; for(int counter = 0; counter < pLCM->VoronoiDiagram->edges->total; counter++) { pNode1 = CV_VORONOIEDGE2D_BEGINNODE(pEdge,pSite); if(pNode1->radius >= pLCM->maxWidth) goto CREATECOMPLEXNODE; CV_WRITE_SEQ_ELEM(pNode1->pt,writer); width += pNode1->radius; _CV_INITIALIZE_CVLCMDATA(&LCMData,pSite,pEdge,pNode1); if(_cvConstructLCMSimpleNode(pLCM,pLCMEdge,&LCMData)) goto LCMEDGEEXIT; pEdge = LCMData.pedge; pSite = LCMData.psite; pNode0 = pNode1; } return NULL; CREATECOMPLEXNODE: _CV_INITIALIZE_CVLCMDATA(&LCMData,pSite,pEdge,pNode0); CV_WRITE_SEQ_ELEM(LCMData.pnode->pt,writer); width += LCMData.pnode->radius; _cvConstructLCMComplexNode(pLCM,pLCMEdge,&LCMData); LCMEDGEEXIT: cvEndWriteSeq(&writer); pLCMEdge->width = width/pLCMEdge->chain->total; return pLCMEdge; }//end of _cvConstructLCMEdge CvLCMNode* _cvTreatExeptionalCase(CvLCM* pLCM, CvLCMData* pLCMInputData) { CvVoronoiEdge2D* pEdge = pLCMInputData->pedge; CvVoronoiSite2D* pSite = pLCMInputData->psite; CvVoronoiNode2D* pNode = CV_VORONOIEDGE2D_BEGINNODE(pEdge,pSite); CvLCMNode* pLCMNode = _cvCreateLCMNode(pLCM); cvSeqPush((CvSeq*)pLCMNode->contour,&pNode->pt); return pLCMNode; }//end of _cvConstructLCMEdge CV_INLINE CvLCMNode* _cvCreateLCMNode(CvLCM* pLCM) { CvLCMNode* pLCMNode; cvSetAdd((CvSet*)pLCM->Graph, NULL, (CvSetElem**)&pLCMNode ); pLCMNode->contour = (CvContour*)cvCreateSeq(0, sizeof(CvContour), sizeof(CvPoint2D32f),pLCM->ContourStorage); pLCMNode->first = NULL; return pLCMNode; }//end of _cvCreateLCMNode CV_INLINE CvLCMEdge* _cvCreateLCMEdge(CvLCM* pLCM) { CvLCMEdge* pLCMEdge; cvSetAdd( (CvSet*)(pLCM->Graph->edges), 0, (CvSetElem**)&pLCMEdge ); pLCMEdge->chain = cvCreateSeq(0, sizeof(CvSeq),sizeof(CvPoint2D32f),pLCM->EdgeStorage); pLCMEdge->next[0] = pLCMEdge->next[1] = NULL; pLCMEdge->vtx[0] = pLCMEdge->vtx[1] = NULL; pLCMEdge->index1 = pLCMEdge->index2 = -1; return pLCMEdge; }//end of _cvCreateLCMEdge CV_INLINE void _cvAttachLCMEdgeToLCMNode(CvLCMNode* LCMNode, CvLCMEdge* LCMEdge, CvLCMEdge* &LCMEdge_prev, int index, int i) { if(!LCMEdge) return; if(i==0) LCMEdge->index1 = index; else LCMEdge->index2 = index; LCMEdge->vtx[i] = (CvGraphVtx*)LCMNode; if(!LCMEdge_prev) LCMNode->first = (CvGraphEdge*)LCMEdge; else // LCMEdge_prev->next[(LCMEdge_prev == (CvLCMEdge*)LCMNode->first)] = (CvGraphEdge*)LCMEdge; LCMEdge_prev->next[(LCMEdge_prev->vtx[0] != (CvGraphVtx*)LCMNode)] = (CvGraphEdge*)LCMEdge; LCMEdge->next[i] = LCMNode->first; LCMEdge_prev = LCMEdge; }//end of _cvAttachLCMEdgeToLCMNode int _cvNodeMultyplicity(CvVoronoiSite2D* pSite, CvVoronoiEdge2D* pEdge, CvVoronoiNode2D* pNode, CvVoronoiEdge2D** LinkedEdges, CvVoronoiSite2D** LinkedSites) { if(!pNode->radius) return -1; assert(pNode == CV_VORONOIEDGE2D_BEGINNODE(pEdge,pSite)); int multyplicity = 0; CvVoronoiEdge2D* pEdge_cur = pEdge; do { if(pEdge_cur->node[0]->radius && pEdge_cur->node[1]->radius) { LinkedEdges[multyplicity] = pEdge_cur; LinkedSites[multyplicity] = pSite; multyplicity++; } pEdge_cur = CV_PREV_VORONOIEDGE2D(pEdge_cur,pSite); pSite = CV_TWIN_VORONOISITE2D(pSite,pEdge_cur); }while(pEdge_cur != pEdge); return multyplicity; }//end of _cvNodeMultyplicity CV_INLINE void _cvPrepareData(CvLCMComplexNodeData* pLCMCCNData, CvLCMData* pLCMData) { pLCMCCNData->site_first = pLCMData->psite; pLCMCCNData->site_last = CV_TWIN_VORONOISITE2D(pLCMData->psite,pLCMData->pedge); if(pLCMData->pedge == CV_LAST_VORONOIEDGE2D(pLCMData->psite)) { pLCMCCNData->edge = CV_PREV_VORONOIEDGE2D(pLCMData->pedge,pLCMData->psite); pLCMCCNData->edge_node = *pLCMData->pnode; pLCMCCNData->site_first_pt = pLCMData->psite->node[0]->pt; pLCMCCNData->site_last_pt = pLCMData->psite->node[0]->pt; } else { pLCMCCNData->edge = pLCMData->pedge; pLCMCCNData->edge_node = *pLCMData->pnode; _cvProjectionPointToSegment(&pLCMCCNData->edge_node.pt, &pLCMCCNData->site_first->node[0]->pt, &pLCMCCNData->site_first->node[1]->pt, &pLCMCCNData->site_first_pt, NULL); _cvProjectionPointToSegment(&pLCMCCNData->edge_node.pt, &pLCMCCNData->site_last->node[0]->pt, &pLCMCCNData->site_last->node[1]->pt, &pLCMCCNData->site_last_pt, NULL); } }//end of _cvPrepareData void _cvProjectionPointToSegment(CvPoint2D32f* PointO, CvPoint2D32f* PointA, CvPoint2D32f* PointB, CvPoint2D32f* PrPoint, float* dist) { float scal_AO_AB, scal_AB_AB; CvPoint2D32f VectorAB = {PointB->x - PointA->x, PointB->y - PointA->y}; scal_AB_AB = VectorAB.x*VectorAB.x + VectorAB.y*VectorAB.y; if(scal_AB_AB < LCM_CONST_ZERO) { *PrPoint = *PointA; if(dist) *dist = (float)sqrt( (double)(PointO->x -PointA->x)*(PointO->x -PointA->x) + (PointO->y - PointA->y)*(PointO->y - PointA->y)); return; } CvPoint2D32f VectorAO = {PointO->x - PointA->x, PointO->y - PointA->y}; scal_AO_AB = VectorAO.x*VectorAB.x + VectorAO.y*VectorAB.y; if(dist) { float vector_AO_AB = (float)fabs(VectorAO.x*VectorAB.y - VectorAO.y*VectorAB.x); *dist = (float)(vector_AO_AB/sqrt((double)scal_AB_AB)); } float alfa = scal_AO_AB/scal_AB_AB; PrPoint->x = PointO->x - VectorAO.x + alfa*VectorAB.x; PrPoint->y = PointO->y - VectorAO.y + alfa*VectorAB.y; return; }//end of _cvProjectionPointToSegment