void FilterFeatureAlignment::setAlignmentParameters(typename ALIGNER_TYPE::MeshType& mFix, typename ALIGNER_TYPE::MeshType& mMov, FilterParameterSet& par, typename ALIGNER_TYPE::Parameters& param) { typedef ALIGNER_TYPE AlignerType; typedef typename AlignerType::MeshType MeshType; if(par.hasParameter("samplingStrategy")) param.samplingStrategy = par.getEnum("samplingStrategy"); if(par.hasParameter("numMovFeatureSelected")) param.numMovFeatureSelected = math::Clamp(par.getInt("numMovFeatureSelected"),0,mMov.VertexNumber()); if(par.hasParameter("nBase")){ param.nBase = par.getInt("nBase"); if(param.nBase<4) param.nBase=4; } if(par.hasParameter("k")){ param.k = par.getInt("k"); if(param.k<1) param.k=1; } if(par.hasParameter("ransacIter")){ param.ransacIter = par.getInt("ransacIter"); if(param.ransacIter<0) param.ransacIter = 0;} if(par.hasParameter("fullConsensusSamples")) param.fullConsensusSamples = math::Clamp(par.getInt("fullConsensusSamples"),1,mMov.VertexNumber()); if(par.hasParameter("overlap")) param.overlap = math::Clamp<float>(par.getFloat("overlap"),0.0f,100.0f); if(par.hasParameter("consensusDist")) param.consensusDist = math::Clamp<float>(par.getFloat("consensusDist"),0.0f,100.0f); if(par.hasParameter("pickPoints")) param.pickPoints = par.getBool("pickPoints"); if(par.hasParameter("normEq")) param.normalEqualization = par.getBool("normEq"); if(par.hasParameter("paint")) param.paint = par.getBool("paint"); }
// The Real Core Function doing the actual mesh processing. // Move Vertex of a random quantity bool SlidingCurvaturePlugin::applyFilter(QAction *filter, MeshModel &m, FilterParameterSet & par, vcg::CallBackPos *cb) { if( ID(filter)== FP_COMPUTE_PRINC_CURV_DIR_FROM_SLIDING){ vcg::Histogramf hi; vcg::CurvatureFromSliding<CMeshO> cfs; vcg::tri::UpdateBounding<CMeshO>::Box(m.cm); // update bounding box vcg::tri::UpdateNormals<CMeshO>::PerVertexNormalizedPerFaceNormalized(m.cm); // update Normals vcg::tri::Stat<CMeshO>::ComputeEdgeHistogram(m.cm,hi); float radius = hi.Avg()*par.getFloat("radius"); cfs.Compute(m.cm,radius, cb );} return true; }
void PhotoTexturingWidget::saveDefaultBakeSettings(FilterParameterSet pset){ QSettings ptSettings; ptSettings.setValue(PhotoTexturer::TEXTURE_SIZE_WIDTH,pset.getInt(PhotoTexturer::TEXTURE_SIZE_WIDTH)); ptSettings.setValue(PhotoTexturer::TEXTURE_SIZE_HEIGHT,pset.getInt(PhotoTexturer::TEXTURE_SIZE_HEIGHT)); ptSettings.setValue(PhotoTexturer::UNPROJECT_ENABLE_ANGLE,pset.getBool(PhotoTexturer::UNPROJECT_ENABLE_ANGLE)); ptSettings.setValue(PhotoTexturer::UNPROJECT_ANGLE_WEIGHT,pset.getInt(PhotoTexturer::UNPROJECT_ANGLE_WEIGHT)); ptSettings.setValue(PhotoTexturer::UNPROJECT_ANGLE,pset.getFloat(PhotoTexturer::UNPROJECT_ANGLE)); ptSettings.setValue(PhotoTexturer::UNPROJECT_ANGLE_SHARPNESS,pset.getInt(PhotoTexturer::UNPROJECT_ANGLE_SHARPNESS)); ptSettings.setValue(PhotoTexturer::UNPROJECT_ENABLE_DISTANCE,pset.getBool(PhotoTexturer::UNPROJECT_ENABLE_DISTANCE)); ptSettings.setValue(PhotoTexturer::UNPROJECT_DISTANCE_WEIGHT,pset.getInt(PhotoTexturer::UNPROJECT_DISTANCE_WEIGHT)); ptSettings.setValue(PhotoTexturer::BAKE_SAVE_UNPROJECT,pset.getBool(PhotoTexturer::BAKE_SAVE_UNPROJECT)); ptSettings.setValue(PhotoTexturer::UNPROJECT_ENABLE_EDGE_STRETCHING,pset.getBool(PhotoTexturer::UNPROJECT_ENABLE_EDGE_STRETCHING)); ptSettings.setValue(PhotoTexturer::UNPROJECT_EDGE_STRETCHING_PASS,pset.getInt(PhotoTexturer::UNPROJECT_EDGE_STRETCHING_PASS)); ptSettings.setValue(PhotoTexturer::BAKE_MERGE_TEXTURES,pset.getBool(PhotoTexturer::BAKE_MERGE_TEXTURES)); ptSettings.setValue(PhotoTexturer::BAKE_MERGE_TYPE,pset.getEnum(PhotoTexturer::BAKE_MERGE_TYPE)); ptSettings.setValue(PhotoTexturer::BAKE_SMARTBLEND,pset.getString(PhotoTexturer::BAKE_SMARTBLEND)); }
bool FilterFeatureAlignment::applyFilter(QAction *filter, MeshDocument &md, FilterParameterSet & par, vcg::CallBackPos * cb) { glLog=log; //assign log to a global variable. needed to write the log from everywhere in the code //define needed typedef MeshType typedef CMeshO MeshType; //declare variables for parameters int featureType, from, to, step, trials; MeshModel *mFix, *mMov, *currMesh; //read parameters currMesh = md.mm(); //get current mesh from document if(par.hasParameter("mFix")) mFix = par.getMesh("mFix"); else mFix = currMesh; if(par.hasParameter("mMov")) mMov = par.getMesh("mMov"); else mMov = currMesh; if(par.hasParameter("featureType")) featureType = par.getEnum("featureType"); else featureType = -1; if(par.hasParameter("trials")) trials = par.getInt("trials"); else trials = 100; if(par.hasParameter("from")) from = par.getInt("from"); else from = 1000; if(par.hasParameter("to")) to = par.getInt("to"); else to = 5000; if(par.hasParameter("step")) step = par.getInt("step"); else step = 1000; switch(ID(filter)) { case AF_COMPUTE_FEATURE: { switch(featureType){ case 0:{ typedef SmoothCurvatureFeature<MeshType, 6> FeatureType; //define needed typedef FeatureType FeatureType::Parameters param; FeatureType::SetupParameters(param); return ComputeFeatureOperation<MeshType,FeatureType>(*currMesh, param, cb); } case 1:{ typedef APSSCurvatureFeature<MeshType, 3> FeatureType; //define needed typedef FeatureType FeatureType::Parameters param; FeatureType::SetupParameters(param); return ComputeFeatureOperation<MeshType,FeatureType>(*currMesh, param, cb); } case 2:{ typedef FeatureRGB<MeshType, 3> FeatureType; //define needed typedef FeatureType FeatureType::Parameters param; FeatureType::SetupParameters(param); return ComputeFeatureOperation<MeshType,FeatureType>(*currMesh, param, cb); } default: assert(0); } //end switch(ftype) assert(0); } //end case AF_COMPUTE_FEATURE case AF_EXTRACTION: { switch(featureType){ case 0:{ typedef SmoothCurvatureFeature<MeshType, 6> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); bool ok = ExtractionOperation<AlignerType>(*currMesh, alignerParam, cb); return ok; } case 1:{ typedef FeatureRGB<MeshType, 3> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); bool ok = ExtractionOperation<AlignerType>(*currMesh, alignerParam, cb); return ok; } default: assert(0); } //end switch(ftype) assert(0); } //end case AF_EXTRACTION case AF_MATCHING : { switch(featureType) { case 0:{ typedef SmoothCurvatureFeature<MeshType, 6> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = MatchingOperation<AlignerType>(*mFix, *mMov, alignerParam, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } case 1:{ typedef FeatureRGB<MeshType, 3> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = MatchingOperation<AlignerType>(*mFix, *mMov, alignerParam, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } default: assert(0); } //end switch(ftype) assert(0); } //end case AF_MATCHING case AF_RIGID_TRANSFORMATION : { switch(featureType) { case 0:{ typedef SmoothCurvatureFeature<MeshType, 6> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = RigidTransformationOperation<AlignerType>(*mFix, *mMov, alignerParam, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } case 1:{ typedef FeatureRGB<MeshType, 3> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = RigidTransformationOperation<AlignerType>(*mFix, *mMov, alignerParam, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } default: assert(0); } //end switch(ftype) assert(0); } //end case AF_RIGID_TRANSFORMATION case AF_CONSENSUS : { typedef OverlapEstimation<CMeshO> ConsensusType; ConsensusType::Parameters consParam; //set up params for consensus consParam.samples = math::Clamp(par.getInt("fullConsensusSamples"),1,mMov->cm.VertexNumber()); consParam.consensusDist=math::Clamp<float>(par.getFloat("consensusDist"),0.0f,100.0f); consParam.paint = par.getBool("paint"); consParam.normalEqualization = par.getBool("normEq"); consParam.threshold = 0.0f; consParam.bestScore = 0; float result = ConsensusOperation<ConsensusType>(*mFix, *mMov, consParam, cb); if(result<0){ errorMessage = "Consensus Initialization fails."; return false; } Log("Consensus of %.2f%%", 100*result); return true; } case AF_RANSAC: { switch(featureType){ case 0:{ typedef SmoothCurvatureFeature<MeshType, 6> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = RansacOperation<AlignerType>(*mFix, *mMov, alignerParam, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } case 1:{ typedef APSSCurvatureFeature<MeshType, 3> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = RansacOperation<AlignerType>(*mFix, *mMov, alignerParam, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } case 2:{ typedef FeatureRGB<MeshType, 3> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = RansacOperation<AlignerType>(*mFix, *mMov, alignerParam, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } default: assert(0); } // end switch(ftype) assert(0); } //end case AF_RANSAC case AF_RANSAC_DIAGRAM: { switch(featureType){ case 0:{ typedef SmoothCurvatureFeature<MeshType, 6> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = RansacDiagramOperation<AlignerType>(*mFix, *mMov, alignerParam, trials, from, to, step, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } case 1:{ typedef APSSCurvatureFeature<MeshType, 3> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = RansacDiagramOperation<AlignerType>(*mFix, *mMov, alignerParam, trials, from, to, step, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } case 2:{ typedef FeatureRGB<MeshType, 3> FeatureType; //define needed typedef FeatureType typedef FeatureAlignment<MeshType, FeatureType> AlignerType; //define the Aligner class typedef AlignerType::Result ResultType; AlignerType::Parameters alignerParam(mFix->cm, mMov->cm); setAlignmentParameters<AlignerType>(mFix->cm, mMov->cm, par, alignerParam); ResultType res = RansacDiagramOperation<AlignerType>(*mFix, *mMov, alignerParam, trials, from, to, step, cb); return logResult<AlignerType>(ID(filter), res, errorMessage); } default: assert(0); } // end switch(ftype) assert(0); } //end case AF_RANSAC_DIAGRAM default: assert(0); } // end switch(ID(filter)) return false; }