Neurons Neurons::operator & (const Circle<Micron> & circle) { CHECK_CONTAINER_MICROCIRCUIT_POINTER(*this); Neurons result(_microcircuit.lock()); //! \todo Fix commented out code below. (TT) //result._description = _description + " within a radius of " + // boost::lexical_cast<const Word>(radius) + " from the center point (" // + // boost::lexical_cast<const Word>(circle.center().x()) + ", " + // boost::lexical_cast<const Word>(circle.center().z()) + ")"; for (Neurons::iterator i = begin(); i != end(); ++i ) { const Neuron & neuron = * i; Micron distance = std::sqrt((neuron.position().x() - circle.center().x()) * (neuron.position().x() - circle.center().x()) + (neuron.position().z() - circle.center().z()) * (neuron.position().z() - circle.center().z())); #ifndef NDEBUG std::cout << "Distance:" << distance << std::endl; #endif if (distance <= circle.radius()) { #ifndef NDEBUG std::cout << "Neuron a" << neuron.gid() << " at position " << neuron.position() << " is within a radius of " << circle.radius() << std::endl; #endif result.insert(i.ptr()); } #ifndef NDEBUG else { std::cout << "Neuron a" << neuron.gid() << " at position " << neuron.position() << " is NOT within a radius of " << circle.radius() << std::endl; } #endif } return result; }
int main(int argc, const char* argv[]) { /* * Build 48 Index with Links */ // Load Circuit Experiment experiment; experiment.open(blue_config_filename); Microcircuit & microcircuit = experiment.microcircuit(); const Targets & targets = experiment.targets(); const Cell_Target target = targets.cell_target("Column"); microcircuit.load(target, NEURONS | MORPHOLOGIES); //Make Neuron Rtrees ISpatialIndex *neuronTrees[MORPHOLOGIES_COUNT]; string *morphologyLabels[MORPHOLOGIES_COUNT]; int cm=0; Morphologies & myMorphologies = microcircuit.morphologies(); Morphologies::iterator myMorphologiesEnd = myMorphologies.end(); for (Morphologies::iterator i = myMorphologies.begin(); i != myMorphologiesEnd; ++i) { morphologyLabels[cm] = i->label(); neuronTrees[cm] = RTree::createNewRTree (createNewMemoryStorageManager(), 0.7, 127, 127, 3,RTree::RV_RSTAR,indexIdentifier); cm++; } Neurons & myNeurons = microcircuit.neurons(); Neurons::iterator myNeuronsEnd = myNeurons.end(); for (Neurons::iterator i = myNeurons.begin(); i != myNeuronsEnd; ++i) { cm=0; for (cm=0;cm<MORPHOLOGIES_COUNT;cm++) if (strcmp(i->morphology().label(),morphologyLabels[cm])==0) break; Transform_3D<Micron> trafo = i->global_transform(); Sections mySections = i->morphology().all_sections(); Sections::iterator mySectionsEnd = mySections.end(); for (Sections::iterator s = mySections.begin(); s != mySectionsEnd; ++s) { Segments segments = s->segments(); Segments::const_iterator segments_end = segments.end(); for (Segments::const_iterator j = segments.begin(); j != segments_end ; ++j) { vect plow, phigh; get_segment_mbr (*j, trafo, &plow, &phigh); SpatialIndex::Region mbr = SpatialIndex::Region(plow.data(),phigh.data(),3); std::stringstream strStream; strStream << i->gid() <<"-"<< s->id()<< "-" << j->id(); neuronTrees[cm]->insertData (strStream.str().length(), (byte*)(strStream.str().c_str()), mbr, segmentid); } } } // Make Morphology Rtrees Morphologies & myMorphologies = microcircuit.morphologies(); Morphologies::iterator myMorphologiesEnd = myMorphologies.end(); for (Morphologies::iterator i = myMorphologies.begin(); i != myMorphologiesEnd; ++i) { cout << "Indexing Morphology: " << i->label(); string baseName = i->label(); IStorageManager* diskfile = StorageManager::createNewDiskStorageManager(baseName, 4096); ISpatialIndex *tree = RTree::createNewRTree (*diskfile, 0.7, 127, 127, 3,RTree::RV_RSTAR,indexIdentifier); indexIdentifier++; segmentid=0; Sections mySections = i->all_sections(); Sections::iterator mySectionsEnd = mySections.end(); for (Sections::iterator s = mySections.begin(); s != mySectionsEnd; ++s) { Segments segments = s->segments(); Segments::const_iterator segments_end = segments.end(); for (Segments::const_iterator j = segments.begin(); j != segments_end ; ++j) { Box<bbp::Micron> Mbr = AABBCylinder::calculateAABBForCylinder(j->begin().center(), j->begin().radius(),j->end().center(),j->begin().radius()); vect plow, phigh; plow[0] = Mbr.center().x() - Mbr.dimensions().x() / 2; phigh[0] = Mbr.center().x() + Mbr.dimensions().x() / 2; plow[1] = Mbr.center().y() - Mbr.dimensions().y() / 2; phigh[1] = Mbr.center().y() + Mbr.dimensions().y() / 2; plow[2] = Mbr.center().z() - Mbr.dimensions().z() / 2; phigh[2] = Mbr.center().z() + Mbr.dimensions().z() / 2; SpatialIndex::Region mbr = SpatialIndex::Region(plow.data(),phigh.data(),3); std::stringstream strStream; strStream << s->id()<< "-" << j->id(); tree->insertData (strStream.str().length(), (byte*)(strStream.str().c_str()), mbr, segmentid); segmentid++; } } cout << ".. Total Segments: " << segmentid << "\n"; tree->~ISpatialIndex(); diskfile->~IStorageManager(); } // PRELOAD the Trees amd Neuron Morphology Mapping ISpatialIndex *neurons[NEURONS_COUNT]; global_transformer *transforms[NEURONS_COUNT]; int cm=0; int cn=0; string baseName = ""; Morphologies & myMorphologies = microcircuit.morphologies(); Neurons & myNeurons = microcircuit.neurons(); cout << "PreLoading Mappings \n"; Morphologies::iterator myMorphologiesEnd = myMorphologies.end(); for (Morphologies::iterator m = myMorphologies.begin(); m != myMorphologiesEnd; ++m) { baseName = m->label(); m-> IStorageManager* diskfile = StorageManager::loadDiskStorageManager(baseName); trees[cm] = RTree::loadRTree(*diskfile, 1); std::cout << "Checking R-tree structure... "; if (!trees[cm]->isIndexValid()) std::cerr << "R-tree internal checks failed!\n"; else std::cout << "OK\n"; IStatistics * tree_stats; trees[cm]->getStatistics (&tree_stats); cout << *tree_stats; Neurons::iterator myNeuronsEnd = myNeurons.end(); for (Neurons::iterator n = myNeurons.begin(); n != myNeuronsEnd; ++n) { if (strcmp(n->morphology().label().c_str(),m->label().c_str())==0) { transforms[cn] = n->global_transform().inverse(); neurons[cn] = trees[cm]; } cn++; if (cn>=NEURONS_COUNT) break; } cn=0;cm++; } /* * Query the Index */ }
int main(int argc, const char* argv[]) { const URI blue_config_filename(argv[1]); try { // LOADING CURCUIT Experiment experiment; experiment.open(blue_config_filename); Microcircuit & microcircuit = experiment.microcircuit(); const Targets & targets = experiment.targets(); const Cell_Target target = targets.cell_target("Column"); microcircuit.load(target, NEURONS | MORPHOLOGIES); // PRELOAD the Trees amd Neuron Morphology Mapping ISpatialIndex *trees[MORPHOLOGIES_COUNT]; ISpatialIndex *neurons[NEURONS_COUNT]; global_transformer *transforms[NEURONS_COUNT]; int cm=0; int cn=0; string baseName = ""; Morphologies & myMorphologies = microcircuit.morphologies(); Neurons & myNeurons = microcircuit.neurons(); cout << "PreLoading Mappings \n"; Morphologies::iterator myMorphologiesEnd = myMorphologies.end(); for (Morphologies::iterator m = myMorphologies.begin(); m != myMorphologiesEnd; ++m) { baseName = m->label(); IStorageManager* diskfile = StorageManager::loadDiskStorageManager(baseName); trees[cm] = RTree::loadRTree(*diskfile, 1); std::cout << "Checking R-tree structure... "; if (!trees[cm]->isIndexValid()) std::cerr << "R-tree internal checks failed!\n"; else std::cout << "OK\n"; IStatistics * tree_stats; trees[cm]->getStatistics (&tree_stats); cout << *tree_stats; Neurons::iterator myNeuronsEnd = myNeurons.end(); for (Neurons::iterator n = myNeurons.begin(); n != myNeuronsEnd; ++n) { if (strcmp(n->morphology().label().c_str(),m->label().c_str())==0) { transforms[cn] = n->global_transform().inverse(); neurons[cn] = trees[cm]; } cn++; if (cn>=NEURONS_COUNT) break; } cn=0;cm++; } /* // SINGLE QUERY cout << "Start Querying \n"; range_query_visitor visitor; SpatialIndex::Region query; micron_vector plow,phigh; plow[0] = 0; plow[1] = 0; plow[2] = 0; phigh[0]=90; phigh[1]=90; phigh[2]=90; for (int i=0;i<NEURONS_COUNT;i++) { get_transformed_cube_mbr(plow,phigh,*transforms[i],&query); neurons[i]->intersectsWithQuery(query,visitor); visitor.inc_neuron(); } visitor.print_stats(); */ // PERFORMANCE EVALUATION RANDOM RANGE QUERIES { cout << "Start Range Query Analysis \n"; range_query_visitor visitor; double plow[3],phigh[3]; plow[0] = 98.2538; plow[1] = 1005.14; plow[2] = 92.9046; phigh[0] = 452.301; phigh[1] = 1385.56; phigh[2] = 456.743; //plow[0] = -1698.38; plow[1] = -1065.03; plow[2] = -1724.75; // phigh[0] = 2248.56; phigh[1]= 1894.28; phigh[2]= 2276.71; SpatialIndex::Region query_region = SpatialIndex::Region(plow,phigh,3); boost::mt11213b generator (42u); const double x[3] = {0.0, 0.0, 0.0}; SpatialIndex::Point rnd_point1 (x, query_region.m_dimension); SpatialIndex::Point rnd_point2 (x, query_region.m_dimension); SpatialIndex::Region query; for (int j=0;j<QUERIES_FOR_ANALYSIS;j++) { for (size_t i = 0; i < query_region.m_dimension; i++) { boost::uniform_real<> uni_dist (query_region.m_pLow[i],query_region.m_pHigh[i]); boost::variate_generator<boost::mt11213b &,boost::uniform_real<> > uni(generator, uni_dist); rnd_point1.m_pCoords[i] = uni(); boost::uniform_real<> uni_dist1 (rnd_point1.m_pCoords[i],query_region.m_pHigh[i]); boost::variate_generator<boost::mt11213b &,boost::uniform_real<> > uni1(generator, uni_dist1); rnd_point2.m_pCoords[i] = uni1(); } visitor.new_query(); visitor.reset_neuron(); for (int i=0;i<NEURONS_COUNT;i++) { Vector_3D<Micron> low = Vector_3D<Micron>((Micron)rnd_point1.m_pCoords[0],(Micron)rnd_point1.m_pCoords[1],(Micron)rnd_point1.m_pCoords[2]); Vector_3D<Micron> high = Vector_3D<Micron>((Micron)rnd_point2.m_pCoords[0],(Micron)rnd_point2.m_pCoords[1],(Micron)rnd_point2.m_pCoords[2]); get_transformed_cube_mbr(low,high,*transforms[i],&query); neurons[i]->intersectsWithQuery(query,visitor); } if (j%100==0) cout << "Queries Done: " << j << "\n"; } visitor.print_stats(); } /* { // PERFORMANCE EVALUATION RANDOM POINT QUERIES cout << "Start Point Query Analysis \n"; range_query_visitor visitor; double plow[3],phigh[3]; //plow[0] = 98.2538; plow[1] = 1005.14; plow[2] = 92.9046; // phigh[0] = 452.301; phigh[1] = 1385.56; phigh[2] = 456.743; plow[0] = -1698.38; plow[1] = -1065.03; plow[2] = -1724.75; phigh[0] = 2248.56; phigh[1]= 1894.28; phigh[2]= 2276.71; SpatialIndex::Region query_region = SpatialIndex::Region(plow,phigh,3); boost::mt11213b generator (42u); for (int j=0;j<QUERIES_FOR_ANALYSIS;j++) { const double x[3] = {0.0, 0.0, 0.0}; SpatialIndex::Point rnd_point (x, query_region.m_dimension); SpatialIndex::Point tmp_point (x, query_region.m_dimension); for (size_t i = 0; i < query_region.m_dimension; i++) { boost::uniform_real<> uni_dist (query_region.m_pLow[i],query_region.m_pHigh[i]); boost::variate_generator<boost::mt11213b &,boost::uniform_real<> > uni(generator, uni_dist); rnd_point.m_pCoords[i] = uni(); } visitor.new_query(); visitor.reset_neuron(); //visitor.reset_stats(); for (int i=0;i<NEURONS_COUNT;i++) { // cout << "Point Query: (" << rnd_point.m_pCoords[0] << "," << rnd_point.m_pCoords[1] << "," << rnd_point.m_pCoords[2] << ") Transformed to: ("; Vector_3D<Micron> v = Vector_3D<Micron>((Micron)rnd_point.m_pCoords[0],(Micron)rnd_point.m_pCoords[1],(Micron)rnd_point.m_pCoords[2]); v = *transforms[i]*v; tmp_point.m_pCoords[0] = (double)v.x(); tmp_point.m_pCoords[1] = (double)v.y(); tmp_point.m_pCoords[2] = (double)v.z(); // cout << tmp_point.m_pCoords[0] << "," << tmp_point.m_pCoords[1] << "," << tmp_point.m_pCoords[2] << ")\n"; neurons[i]->pointLocationQuery(tmp_point,visitor); } } visitor.print_stats(); } */ // PERFORMANCE EVALUATION RANDOM RANGE QUERIES } catch (Tools::Exception& e) { cout << e.what() << endl; exit(0); } // delete tree_stats; return 0; }