static void merge_sort_vector(vector<T> *vect) { if (vect->size() <= 1) { return; } typename std::vector<T>::size_type mid = vect->size() / 2; typename std::vector<T> left(vect->begin(), vect->begin() + mid); typename std::vector<T> right(vect->begin() + mid, vect->end()); merge_sort_vector(&left); merge_sort_vector(&right); merge( left.begin(), left.end(), right.begin(), right.end(), vect->begin()); }
property_t(const std::vector<std::vector<T> >& mtx) { vector matrix; for(typename std::vector<std::vector<T> >::const_iterator i = mtx.begin(); i != mtx.end(); ++i) { vector row; for(typename std::vector<T>::const_iterator j = i->begin(); j != i->end(); ++j) row.push_back(*j); matrix.push_back(row); } property_base::operator= <vector>(matrix); }
void shiftGrid( std::vector<std::vector<Point2> >& grid, const Point2& shift ) { for( typename std::vector<std::vector<Point2> >::iterator itv = grid.begin(), itvEnd = grid.end(); itv != itvEnd; ++itv ) { for( typename std::vector<Point2>::iterator it = itv->begin(), itEnd = itv->end(); it != itEnd; ++it ) { *it += shift; } } }
void fillImageWithDecompostion(const std::vector<Curve> & contours, png::image<png::rgb_pixel> & output) { // Color map for the DLL const png::rgb_pixel pixelColors[4] = { // redPixel png::rgb_pixel(255,0,0), // greenPixel png::rgb_pixel(0,255,0), // bluePixel png::rgb_pixel(0,0,255), // yellowPixel png::rgb_pixel(255,255,0) }; typedef typename DLL::Segment<DLL_Type> DLLSegment; Utils::GreedyDecomposition<DLLSegment> decompositor; unsigned int nbDLL = 0; for (typename std::vector<Curve>::const_iterator contourItor = contours.begin(); contourItor != contours.end(); ++contourItor) { // decompose the current contour typename std::vector<DLLSegment> dlls = decompositor.decomposeCurve(*contourItor); // color each DLL segment into the output image // and display the points coordinates of the DLL segment on the console unsigned int colorIndex = 3; for (typename std::vector<DLLSegment>::const_iterator dllItor = dlls.begin(); dllItor != dlls.end(); ++dllItor) { const Curve & curve = dllItor->getCurve(); if (verbose) std::cout << "DLL " << ++nbDLL << ":\t" << *dllItor << "\n\tPoints: "; for(typename Curve::const_iterator coordItor = curve.begin(); coordItor != curve.end(); ++coordItor) { output.set_pixel(coordItor->first, coordItor->second, pixelColors[colorIndex]); if (verbose) std::cout << "(" << coordItor->first << "," << coordItor->second << ") "; } if (verbose) std::cout << std::endl; colorIndex = (colorIndex + 1) % 3; } } }
void Datasegments<Scalar>:: buildList ( M3& KMat, Scalar* centers, int nSegments, typename std::vector< PatchCenter<Scalar> >& projPatchCenters) { projPatchCenters.clear(); projPatchCenters.resize( nSegments ); // first project current solutions: for (int i=0;i<nSegments;i++) { P3 p0 = KMat * P3( ¢ers[3*i] );// center is in camera coords p0 /= p0[2]; // projPatchCenters[i] = PatchCenter<Scalar>( int(p0[0]-0.5), int (p0[1]-0.5), P3( ¢ers[3*i] ), i ); projPatchCenters[i] = PatchCenter<Scalar>( int(floor(p0[0]-0.5)), int (floor(p0[1]-0.5)), p0, i ); } std::sort( projPatchCenters.begin(), projPatchCenters.end() ); // need also a map where a certain segment is now, to start searching }
template<class T> void ArgvToString(const std::vector<T> &argv, T &args) { // Clear the string args.clear(); typename std::vector<T>::const_iterator i; typename T::const_iterator j; int ch; for(i = argv.begin(); i != argv.end(); ++i) { for(j = i->begin(); j != i->end(); ++j) { ch = *j; // No quoting, only escaping // Handle \, ", ', \n, \r, \t., ' ' if (ch == '\\' || ch == '\"' || ch == '\'' || ch == ' ') { args += '\\'; } else if (ch == '\n') { args += '\\'; ch = 'n'; } else if (ch == '\r') { args += '\\'; ch = 'r'; } else if (ch == '\t') { args += '\\'; ch = 't'; } args += ch; } args += ' '; } }
template < typename IN_PORT_TYPE > int file_descriptor_sink_i_base::_forecastAndProcess( bool &eos, typename std::vector< gr_istream< IN_PORT_TYPE > > &istreams ) { typedef typename std::vector< gr_istream< IN_PORT_TYPE > > _IStreamList; typename _IStreamList::iterator istream = istreams.begin(); int nout = 0; bool dataReady = false; if ( !eos ) { uint64_t max_items_avail = 0; for ( int idx=0 ; istream != istreams.end() && serviceThread->threadRunning() ; idx++, istream++ ) { LOG_TRACE( file_descriptor_sink_i_base, "GET MAX ITEMS: STREAM:" << idx << " NITEMS/SCALARS:" << istream->nitems() << "/" << istream->_data.size() ); max_items_avail = std::max( istream->nitems(), max_items_avail ); } // // calc number of output items to produce // noutput_items = (int) (max_items_avail * gr_sptr->relative_rate ()); noutput_items = round_down (noutput_items, gr_sptr->output_multiple ()); if ( noutput_items <= 0 ) { LOG_TRACE( file_descriptor_sink_i_base, "DATA CHECK - MAX ITEMS NOUTPUT/MAX_ITEMS:" << noutput_items << "/" << max_items_avail); return -1; } if ( gr_sptr->fixed_rate() ) { istream = istreams.begin(); for ( int i=0; istream != istreams.end(); i++, istream++ ) { int t_noutput_items = gr_sptr->fixed_rate_ninput_to_noutput( istream->nitems() ); if ( gr_sptr->output_multiple_set() ) { t_noutput_items = round_up(t_noutput_items, gr_sptr->output_multiple()); } if ( t_noutput_items > 0 ) { if ( noutput_items == 0 ) { noutput_items = t_noutput_items; } if ( t_noutput_items <= noutput_items ) { noutput_items = t_noutput_items; } } } LOG_TRACE( file_descriptor_sink_i_base, " FIXED FORECAST NOUTPUT/output_multiple == " << noutput_items << "/" << gr_sptr->output_multiple()); } // // ask the block how much input they need to produce noutput_items... // if enough data is available to process then set the dataReady flag // int32_t outMultiple = gr_sptr->output_multiple(); while ( !dataReady && noutput_items >= outMultiple ) { // // ask the block how much input they need to produce noutput_items... // gr_sptr->forecast(noutput_items, _ninput_items_required); LOG_TRACE( file_descriptor_sink_i_base, "--> FORECAST IN/OUT " << _ninput_items_required[0] << "/" << noutput_items ); istream = istreams.begin(); uint32_t dr_cnt=0; for ( int idx=0 ; noutput_items > 0 && istream != istreams.end(); idx++, istream++ ) { // check if buffer has enough elements _input_ready[idx] = false; if ( istream->nitems() >= (uint64_t)_ninput_items_required[idx] ) { _input_ready[idx] = true; dr_cnt++; } LOG_TRACE( file_descriptor_sink_i_base, "ISTREAM DATACHECK NELMS/NITEMS/REQ/READY:" << istream->nelems() << "/" << istream->nitems() << "/" << _ninput_items_required[idx] << "/" << _input_ready[idx]); } if ( dr_cnt < istreams.size() ) { if ( outMultiple > 1 ) { noutput_items -= outMultiple; } else { noutput_items /= 2; } } else { dataReady = true; } LOG_TRACE( file_descriptor_sink_i_base, " TRIM FORECAST NOUTPUT/READY " << noutput_items << "/" << dataReady ); } // check if data is ready... if ( !dataReady ) { LOG_TRACE( file_descriptor_sink_i_base, "DATA CHECK - NOT ENOUGH DATA AVAIL/REQ:" << _istreams[0].nitems() << "/" << _ninput_items_required[0] ); return -1; } // reset looping variables int ritems = 0; int nitems = 0; // reset caching vectors _output_items.clear(); _input_items.clear(); _ninput_items.clear(); istream = istreams.begin(); for ( int idx=0 ; istream != istreams.end(); idx++, istream++ ) { // check if the stream is ready if ( !_input_ready[idx] ) continue; // get number of items remaining try { ritems = gr_sptr->nitems_read( idx ); } catch(...){ // something bad has happened, we are missing an input stream LOG_ERROR( file_descriptor_sink_i_base, "MISSING INPUT STREAM FOR GR BLOCK, STREAM ID:" << istream->streamID ); return -2; } nitems = istream->nitems() - ritems; LOG_TRACE( file_descriptor_sink_i_base, " ISTREAM: IDX:" << idx << " ITEMS AVAIL/READ/REQ " << nitems << "/" << ritems << "/" << _ninput_items_required[idx] ); if ( nitems >= _ninput_items_required[idx] && nitems > 0 ) { //remove eos checks ...if ( nitems < _ninput_items_required[idx] ) nitems=0; _ninput_items.push_back( nitems ); _input_items.push_back( (const void *) (istream->read_pointer(ritems)) ); } } nout=0; if ( _input_items.size() != 0 && serviceThread->threadRunning() ) { LOG_TRACE( file_descriptor_sink_i_base, " CALLING WORK.....N_OUT:" << noutput_items << " N_IN:" << nitems << " ISTREAMS:" << _input_items.size() << " OSTREAMS:" << _output_items.size()); nout = gr_sptr->general_work( noutput_items, _ninput_items, _input_items, _output_items); // sink/analyzer patterns do not return items, so consume_each is not called in Gnu Radio BLOCK if ( nout == 0 ) { gr_sptr->consume_each(nitems); } LOG_TRACE( file_descriptor_sink_i_base, "RETURN WORK ..... N_OUT:" << nout); } // check for stop condition from work method if ( nout < gr_block::WORK_DONE ) { LOG_WARN( file_descriptor_sink_i_base, "WORK RETURNED STOP CONDITION..." << nout ); nout=0; eos = true; } } return nout; }
template < typename IN_PORT_TYPE > int vector_sink_s_base::_analyzerServiceFunction( typename std::vector< gr_istream< IN_PORT_TYPE > > &istreams ) { typedef typename std::vector< gr_istream< IN_PORT_TYPE > > _IStreamList; boost::mutex::scoped_lock lock(serviceThreadLock); if ( validGRBlock() == false ) { // create our processing block createBlock(); LOG_DEBUG( vector_sink_s_base, " FINISHED BUILDING GNU RADIO BLOCK"); } // process any Stream ID changes this could affect number of io streams processStreamIdChanges(); if ( !validGRBlock() || istreams.size() == 0 ) { LOG_WARN(vector_sink_s_base, "NO STREAMS ATTACHED TO BLOCK..." ); return NOOP; } // resize data vectors for passing data to GR_BLOCK object _input_ready.resize( istreams.size() ); _ninput_items_required.resize( istreams.size()); _ninput_items.resize( istreams.size()); _input_items.resize(istreams.size()); _output_items.resize(0); // // RESOLVE: need to look at forecast strategy, // 1) see how many read items are necessary for N number of outputs // 2) read input data and see how much output we can produce // // // Grab available data from input streams // typename _IStreamList::iterator istream = istreams.begin(); int nitems=0; for ( int idx=0 ; istream != istreams.end() && serviceThread->threadRunning() ; idx++, istream++ ) { // note this a blocking read that can cause deadlocks nitems = istream->read(); if ( istream->overrun() ) { LOG_WARN( vector_sink_s_base, " NOT KEEPING UP WITH STREAM ID:" << istream->streamID ); } // RESOLVE issue when SRI changes that could affect the GNU Radio BLOCK if ( istream->sriChanged() ) { LOG_DEBUG( vector_sink_s_base, "SRI CHANGED, STREAMD IDX/ID: " << idx << "/" << istream->pkt->streamID ); } } LOG_TRACE( vector_sink_s_base, "READ NITEMS: " << nitems ); if ( nitems <= 0 && !_istreams[0].eos() ) return NOOP; bool exitServiceFunction = false; bool eos = false; int nout = 0; while ( nout > -1 && !exitServiceFunction && serviceThread->threadRunning() ) { eos = false; nout = _forecastAndProcess( eos, istreams ); if ( nout > -1 ) { // we chunked on data so move read pointer.. istream = istreams.begin(); for ( ; istream != istreams.end(); istream++ ) { int idx=std::distance( istreams.begin(), istream ); // if we processed data for this stream if ( _input_ready[idx] ) { size_t nitems = 0; try { nitems = gr_sptr->nitems_read( idx ); } catch(...){} if ( nitems > istream->nitems() ) { LOG_WARN( vector_sink_s_base, "WORK CONSUMED MORE DATA THAN AVAILABLE, READ/AVAILABLE " << nitems << "/" << istream->nitems() ); nitems = istream->nitems(); } istream->consume( nitems ); LOG_TRACE( vector_sink_s_base, " CONSUME READ DATA ITEMS/REMAIN " << nitems << "/" << istream->nitems()); } } gr_sptr->reset_read_index(); } // check for not enough data return if ( nout == -1 ) { // check for end of stream istream = istreams.begin(); for ( ; istream != istreams.end() ; istream++) if ( istream->eos() ) eos=true; if ( eos ) { LOG_TRACE( vector_sink_s_base, " DATA NOT READY, EOS:" << eos ); _forecastAndProcess( eos, istreams ); } exitServiceFunction = true; } } if ( eos ) { istream = istreams.begin(); for ( ; istream != istreams.end() ; istream++) { int idx=std::distance( istreams.begin(), istream ); LOG_TRACE( vector_sink_s_base, " CLOSING INPUT STREAM IDX:" << idx ); istream->close(); } } // // set the read pointers of the GNU Radio Block to start at the beginning of the // supplied buffers // gr_sptr->reset_read_index(); LOG_TRACE( vector_sink_s_base, " END OF ANALYZER SERVICE FUNCTION....." << noutput_items ); if ( nout == -1 && eos == false ) return NOOP; else return NORMAL; }
int main() { using namespace boost; //=========================================================================== // Declare the graph type and object, and some property maps. typedef adjacency_list<vecS, vecS, directedS, property<vertex_name_t, std::string, property<vertex_color_t, default_color_type> >, property<edge_name_t, std::string, property<edge_weight_t, int> > > Graph; typedef graph_traits<Graph> Traits; typedef Traits::vertex_descriptor Vertex; typedef Traits::edge_descriptor Edge; typedef Traits::vertices_size_type size_type; typedef std::map<std::string, Vertex> NameVertexMap; NameVertexMap name2vertex; Graph g; typedef property_map<Graph, vertex_name_t>::type NameMap; property_map<Graph, edge_name_t>::type link_name = get(edge_name, g); //=========================================================================== // Read the data file and construct the graph. Edge edge; bool inserted; tie(edge, inserted) = add_edge(0,1,g); put(vertex_name, g, source(edge,g),"0"); put(vertex_name, g, target(edge,g),"1"); tie(edge, inserted) = add_edge(1,2,g); put(vertex_name, g, source(edge,g),"1"); put(vertex_name, g, target(edge,g),"2"); tie(edge, inserted) = add_edge(1,3,g); put(vertex_name, g, source(edge,g),"1"); put(vertex_name, g, target(edge,g),"3"); tie(edge, inserted) = add_edge(3,4,g); put(vertex_name, g, source(edge,g),"3"); put(vertex_name, g, target(edge,g),"4"); tie(edge, inserted) = add_edge(3,5,g); put(vertex_name, g, source(edge,g),"3"); put(vertex_name, g, target(edge,g),"5"); tie(edge, inserted) = add_edge(2,4,g); put(vertex_name, g, source(edge,g),"2"); put(vertex_name, g, target(edge,g),"4"); tie(edge, inserted) = add_edge(4,6,g); put(vertex_name, g, source(edge,g),"4"); put(vertex_name, g, target(edge,g),"6"); //=========================================================================== std::vector< std::vector<Edge> > paths; Graph tmp_g = g; Vertex src = 0; Vertex goal = 6; bool more = true; do { std::vector<Edge> path; OptSolPathEstimator<Graph> ospe(goal,&path); try { depth_first_visit(tmp_g,src,ospe,get(vertex_color,tmp_g)); } catch(FoundGoalSignal fgs) { }; if( !path.empty() ) { more = true;// possible there are more goal-reached paths paths.push_back(path); // Delete the last edge of path in the tmp_g remove_edge(path.back(),tmp_g); // Reset all vertex_color in tmp_g to white boost::graph_traits<Graph>::vertex_iterator vi, vi_end; for (boost::tie(vi,vi_end) = vertices(tmp_g); vi != vi_end; ++vi) put(vertex_color,tmp_g,*vi,color_traits<boost::default_color_type>::white()); } else { more = false; } } while(more); cerr << "paths.size()= " << paths.size() << endl; for(typename std::vector< std::vector<Edge> >::const_iterator i=paths.begin(); i!=paths.end(); ++i) { cerr << "Path " << i-paths.begin() << endl; for(std::vector<Edge>::const_iterator j=i->begin(); j!=i->end(); ++j) { cout << "e(" << source(*j,g) << "," << target(*j,g) << "), "; } cout << endl; } // boost::graph_traits<Graph>::vertex_iterator vi, vi_end; // for (boost::tie(vi,vi_end) = vertices(g); vi != vi_end; ++vi) // { // if( get(vertex_color,g,*vi)==color_traits<boost::default_color_type>::gray() ) // cerr << *vi << "= gray" << endl; // else if( get(vertex_color,g,*vi)==color_traits<boost::default_color_type>::black() ) // cerr << *vi << "= black" << endl; // else // cerr << *vi << "= white" << endl; // } // cerr << "============================================================================================" << endl; // for (boost::tie(vi,vi_end) = vertices(tmp_g); vi != vi_end; ++vi) // { // if( get(vertex_color,tmp_g,*vi)==color_traits<boost::default_color_type>::gray() ) // cerr << *vi << "= gray" << endl; // else if( get(vertex_color,tmp_g,*vi)==color_traits<boost::default_color_type>::black() ) // cerr << *vi << "= black" << endl; // else // cerr << *vi << "= white" << endl; // } // // // cerr << "============================================================================================" << endl; // // src = 1; // paths.clear(); // // depth_first_visit(g,src,ospe,get(vertex_color, g)); // // cerr << "paths.size()= " << paths.size() << endl; // for(typename std::vector< std::vector<Edge> >::const_iterator i=paths.begin(); i!=paths.end(); ++i) // { // cerr << "Path " << i-paths.begin() << endl; // for(std::vector<Edge>::const_iterator j=i->begin(); j!=i->end(); ++j) // { // cout << "e(" << source(*j,g) << "," << target(*j,g) << "), "; // } // cout << endl; // } return EXIT_SUCCESS; }
void FindPeaksMD::findPeaks(typename MDEventWorkspace<MDE, nd>::sptr ws) { if (nd < 3) throw std::invalid_argument("Workspace must have at least 3 dimensions."); progress(0.01, "Refreshing Centroids"); // TODO: This might be slow, progress report? // Make sure all centroids are fresh ws->getBox()->refreshCentroid(); typedef IMDBox<MDE,nd>* boxPtr; if (ws->getNumExperimentInfo() == 0) throw std::runtime_error("No instrument was found in the MDEventWorkspace. Cannot find peaks."); // TODO: Do we need to pick a different instrument info? ExperimentInfo_sptr ei = ws->getExperimentInfo(0); // Instrument associated with workspace Geometry::Instrument_const_sptr inst = ei->getInstrument(); // Find the run number int runNumber = ei->getRunNumber(); // Check that the workspace dimensions are in Q-sample-frame or Q-lab-frame. eDimensionType dimType; std::string dim0 = ws->getDimension(0)->getName(); if (dim0 == "H") { dimType = HKL; throw std::runtime_error("Cannot find peaks in a workspace that is already in HKL space."); } else if (dim0 == "Q_lab_x") { dimType = QLAB; } else if (dim0 == "Q_sample_x") dimType = QSAMPLE; else throw std::runtime_error("Unexpected dimensions: need either Q_lab_x or Q_sample_x."); // Find the goniometer rotation matrix Mantid::Kernel::Matrix<double> goniometer(3,3, true); // Default IDENTITY matrix try { goniometer = ei->mutableRun().getGoniometerMatrix(); } catch (std::exception & e) { g_log.warning() << "Error finding goniometer matrix. It will not be set in the peaks found." << std::endl; g_log.warning() << e.what() << std::endl; } /// Arbitrary scaling factor for density to make more manageable numbers, especially for older file formats. signal_t densityScalingFactor = 1e-6; // Calculate a threshold below which a box is too diffuse to be considered a peak. signal_t thresholdDensity = 0.0; thresholdDensity = ws->getBox()->getSignalNormalized() * DensityThresholdFactor * densityScalingFactor; g_log.notice() << "Threshold signal density: " << thresholdDensity << std::endl; // We will fill this vector with pointers to all the boxes (up to a given depth) typename std::vector<boxPtr> boxes; // Get all the MDboxes progress(0.10, "Getting Boxes"); ws->getBox()->getBoxes(boxes, 1000, true); // TODO: Here keep only the boxes > e.g. 3 * mean. typedef std::pair<double, boxPtr> dens_box; // Map that will sort the boxes by increasing density. The key = density; value = box *. typename std::multimap<double, boxPtr> sortedBoxes; progress(0.20, "Sorting Boxes by Density"); typename std::vector<boxPtr>::iterator it1; typename std::vector<boxPtr>::iterator it1_end = boxes.end(); for (it1 = boxes.begin(); it1 != it1_end; it1++) { boxPtr box = *it1; double density = box->getSignalNormalized() * densityScalingFactor; // Skip any boxes with too small a signal density. if (density > thresholdDensity) sortedBoxes.insert(dens_box(density,box)); } // List of chosen possible peak boxes. std::vector<boxPtr> peakBoxes; prog = new Progress(this, 0.30, 0.95, MaxPeaks); int64_t numBoxesFound = 0; // Now we go (backwards) through the map // e.g. from highest density down to lowest density. typename std::multimap<double, boxPtr>::reverse_iterator it2; typename std::multimap<double, boxPtr>::reverse_iterator it2_end = sortedBoxes.rend(); for (it2 = sortedBoxes.rbegin(); it2 != it2_end; it2++) { signal_t density = it2->first; boxPtr box = it2->second; #ifndef MDBOX_TRACK_CENTROID coord_t boxCenter[nd]; box->calculateCentroid(boxCenter); #else const coord_t * boxCenter = box->getCentroid(); #endif // Compare to all boxes already picked. bool badBox = false; for (typename std::vector<boxPtr>::iterator it3=peakBoxes.begin(); it3 != peakBoxes.end(); it3++) { #ifndef MDBOX_TRACK_CENTROID coord_t otherCenter[nd]; (*it3)->calculateCentroid(otherCenter); #else const coord_t * otherCenter = (*it3)->getCentroid(); #endif // Distance between this box and a box we already put in. coord_t distSquared = 0.0; for (size_t d=0; d<nd; d++) { coord_t dist = otherCenter[d] - boxCenter[d]; distSquared += (dist * dist); } // Reject this box if it is too close to another previously found box. if (distSquared < peakRadiusSquared) { badBox = true; break; } } // The box was not rejected for another reason. if (!badBox) { if (numBoxesFound++ >= MaxPeaks) { g_log.notice() << "Number of peaks found exceeded the limit of " << MaxPeaks << ". Stopping peak finding." << std::endl; break; } peakBoxes.push_back(box); g_log.information() << "Found box at "; for (size_t d=0; d<nd; d++) g_log.information() << (d>0?",":"") << boxCenter[d]; g_log.information() << "; Density = " << density << std::endl; // Report progres for each box found. prog->report("Finding Peaks"); } } prog->resetNumSteps(numBoxesFound, 0.95, 1.0); // Copy the instrument, sample, run to the peaks workspace. peakWS->copyExperimentInfoFrom(ei.get()); // --- Convert the "boxes" to peaks ---- for (typename std::vector<boxPtr>::iterator it3=peakBoxes.begin(); it3 != peakBoxes.end(); it3++) { // The center of the box = Q in the lab frame boxPtr box = *it3; #ifndef MDBOX_TRACK_CENTROID coord_t boxCenter[nd]; box->calculateCentroid(boxCenter); #else const coord_t * boxCenter = box->getCentroid(); #endif V3D Q(boxCenter[0], boxCenter[1], boxCenter[2]); // Create a peak and add it // Empty starting peak. Peak p; try { if (dimType == QLAB) { // Build using the Q-lab-frame constructor p = Peak(inst, Q); // Save gonio matrix for later p.setGoniometerMatrix(goniometer); } else if (dimType == QSAMPLE) { // Build using the Q-sample-frame constructor p = Peak(inst, Q, goniometer); } } catch (std::exception &e) { g_log.notice() << "Error creating peak at " << Q << " because of '" << e.what() << "'. Peak will be skipped." << std::endl; continue; } try { // Look for a detector p.findDetector(); } catch (...) { /* Ignore errors in ray-tracer TODO: Handle for WISH data later */ } // The "bin count" used will be the box density. p.setBinCount( box->getSignalNormalized() * densityScalingFactor); // Save the run number found before. p.setRunNumber(runNumber); peakWS->addPeak(p); // Report progres for each box found. prog->report("Adding Peaks"); } // for each box found }
void fromPointCloud( const typename std::vector<Celer::Vector4<Real> >& points, const Celer::Vector3<Real>& first_basis, const Celer::Vector3<Real>& second_basis, const Celer::Vector3<Real>& third_basis ) { // Reference : // Geometric Tools, LLC // Copyright (c) 1998-2012 // Distributed under the Boost Software License, Version 1.0. // Wm5ContBox3.cpp basis_[0] = first_basis; basis_[1] = second_basis; basis_[2] = third_basis; for ( typename std::vector<Celer::Vector4<Real> >::const_iterator new_point = points.begin(); new_point != points.end(); new_point++) { BoundingBox3<Real> box( std::min ( min_.x , new_point->x ) , std::min ( min_.y , new_point->y ) , std::min ( min_.z , new_point->z ) , std::max ( max_.x , new_point->x ) , std::max ( max_.y , new_point->y ) , std::max ( max_.z , new_point->z ) ); // std::cout << min( ); // std::cout << max( ); // std::cout << " new_point " << *new_point; *this = *this + box; } Celer::Vector3<Real> diff = points[0].toVector3() - this->center(); Celer::Vector3<Real> pmin ( ( diff * basis_[0] ) , ( diff * basis_[1] ) , (diff * basis_[2]) ); Celer::Vector3<Real> pmax = pmin; for ( typename std::vector<Celer::Vector4<Real> >::const_iterator new_point = points.begin(); new_point != points.end(); new_point++) { // diff = points[i] - box.Center; // for ( int j = 0; j < 3; ++j ) // { // Real dot = diff.Dot ( box.Axis[j] ); // if ( dot < pmin[j] ) // { // pmin[j] = dot; // } // else if ( dot > pmax[j] ) // { // pmax[j] = dot; // } // } } // for ( int i = 1; i < numPoints; ++i ) // { // } // min_ += ( ( (Real) 0.5 ) * ( pmin[0] + pmax[0] ) ) * box.Axis[0] + ( ( (Real) 0.5 ) * ( pmin[1] + pmax[1] ) ) * box.Axis[1] + ( ( (Real) 0.5 ) * ( pmin[2] + pmax[2] ) ) * box.Axis[2]; }
void VisusIndexedData::addText(XMLNode& node, const std::vector<std::vector<T > >* items) const { // Count max number of items int maxitems = 0; for (typename std::vector<std::vector<T> >::const_iterator iiter=items->begin(); iiter!=items->end(); ++iiter) maxitems += iiter->size() + 1; // Construct contiguous buffer const int bufsize = sizeof(T) * maxitems; unsigned char* buffer = new unsigned char[bufsize+1]; node.addAttribute("numItems", (long) items->size()); node.addAttribute("bufsize", bufsize); int position = 0; // Copy non-contiguous data into contiguous buffer for (typename std::vector<std::vector<T> >::const_iterator iiter=items->begin(); iiter!=items->end(); ++iiter) { // Save Num Items T value = items->size(); memcpy(&buffer[position], &value, sizeof(T)); position += sizeof(T); // Load Vector's Vector of items into buffer for (typename std::vector<T>::const_iterator idtIter=iiter->begin(); idtIter!=iiter->end(); ++idtIter) { vassert(position < bufsize); memcpy(&buffer[position], &(*idtIter), sizeof(T)); position += sizeof(T); } } vassert(position == bufsize); // Save Buffer out to XML switch (VisusXMLInterface::sWriteXMLDataStorage) { case BASE64: { // Save data as BASE64 XMLParserBase64Tool base64; XMLSTR encoded = base64.encode(buffer, bufsize); node.addText(encoded); } break; case EXTERNAL_FILE: { vwarning("saving data to external file is not yet supported"); } break; case ASCII: { vwarning("saving data to external file is not yet supported"); } break; } delete [] buffer; }
void write( OutputIterator result ) const { const CharT dquo = widen< CharT >( '\"' ); const CharT comma = widen< CharT >( ',' ); const CharT lf = widen< CharT >( '\n' ); for ( typename std::vector< std::vector< string_type > >::const_iterator r_iter( records_.begin() ), r_last( records_.end() ); r_iter != r_last; ++r_iter ) { for ( typename std::vector< string_type >::const_iterator f_iter( r_iter->begin() ), f_last( r_iter->end() ); f_iter != f_last; ++f_iter ) { std::string field; bool need_escape = false; for ( typename string_type::const_iterator s_iter( f_iter->begin() ), s_last( f_iter->end() ); s_iter != s_last; ++s_iter ) { CharT ch = *s_iter; if ( ch == dquo ) { field.push_back( dquo ); need_escape = true; } else if ( ch == comma || ch == lf ) { need_escape = true; } field.push_back( ch ); } if ( need_escape ) { field = dquo + field + dquo; } result = std::copy( field.begin(), field.end(), result ); if ( boost::next( f_iter ) != f_last ) { *result++ = comma; } } *result++ = lf; } }
void generatePartitionSizeHistogram(typename std::vector<T>& localVector, std::string filename, MPI_Comm comm = MPI_COMM_WORLD) { /* * Approach : * 1. Do a global sort by keyLayer (Partition id). * 2. Compute the information Partition_Id:Size for boundary partitions (Avoid duplication). * 3. Do an all_gather of boundary values plugged with ranks. * 4. All boundary partitions should be owned by minimum rank that shares it. * 5. Locally compute the largest partition size and do MPI_Allreduce * with MPI_MAX. * 6. Build the histogram locally. * 7. Finally do MPI_Reduce over whole histogram to root node. * 8. Write the output to file */ int p; int rank; MPI_Comm_size(comm, &p); MPI_Comm_rank(comm, &rank); static layer_comparator<keyLayer, T> pccomp; //Sort the vector by each tuple's keyLayer element mxx::sort(localVector.begin(), localVector.end(), pccomp, comm, false); //Iterate over tuples to compute boundary information bool iownLeftBucket, iownRightBucket, onlySingleLocalPartition; //Type of tuple to communicate : (Partition Id, rank, size) typedef std::tuple<uint32_t, int, uint64_t> tupletypeforbucketSize; std::vector<tupletypeforbucketSize> toSend; toSend.resize(2); //Find the left most bucket auto leftBucketRange = findRange(localVector.begin(), localVector.end(), *(localVector.begin()), pccomp); std::get<0>(toSend[0]) = std::get<keyLayer>(*localVector.begin()); std::get<1>(toSend[0]) = rank; std::get<2>(toSend[0]) = leftBucketRange.second - leftBucketRange.first; //Find the right most bucket auto rightBucketRange = findRange(localVector.rbegin(), localVector.rend(), *(localVector.rbegin()), pccomp); std::get<0>(toSend[1]) = std::get<keyLayer>(*localVector.rbegin()); std::get<1>(toSend[1]) = rank; std::get<2>(toSend[1]) = rightBucketRange.second - rightBucketRange.first; //If we have only single partition, make sure we are not creating duplicates if(std::get<0>(toSend[0]) == std::get<0>(toSend[1])) { //Make second send element's size zero std::get<2>(toSend[1]) = 0; onlySingleLocalPartition = true; } else onlySingleLocalPartition = false; //Gather all the boundary information auto allBoundaryPartitionSizes = mxx::allgather_vectors(toSend, comm); uint64_t leftBucketSize = 0; uint64_t rightBucketSize = 0; //Need to parse boundary information that matches the partitionIds we have static layer_comparator<0, tupletypeforbucketSize> pccomp2; auto leftBucketBoundaryRange = std::equal_range(allBoundaryPartitionSizes.begin(), allBoundaryPartitionSizes.end(), toSend[0], pccomp2); //Check if this processor owns this bucket if(std::get<1>(*(leftBucketBoundaryRange.first)) == rank) { iownLeftBucket = true; for(auto it = leftBucketBoundaryRange.first; it != leftBucketBoundaryRange.second; it++) { leftBucketSize += std::get<2>(*it); } } else iownLeftBucket = false; auto rightBucketBoundaryRange = std::equal_range(allBoundaryPartitionSizes.begin(), allBoundaryPartitionSizes.end(), toSend[1], pccomp2); //Check if this processor owns right partition if(std::get<1>(*rightBucketBoundaryRange.first) == rank && !onlySingleLocalPartition) { iownRightBucket = true; for(auto it = rightBucketBoundaryRange.first; it != rightBucketBoundaryRange.second; it++) { rightBucketSize += std::get<2>(*it); } } else iownRightBucket = false; //Map from partition size to count typedef std::map <uint64_t, uint32_t> MapType; MapType localHistMap; for(auto it = localVector.begin(); it!= localVector.end();) // iterate over all segments. { auto innerLoopBound = findRange(it, localVector.end(), *it, pccomp); //Left most bucket if (innerLoopBound.first == localVector.begin()) // first { if(iownLeftBucket) insertToHistogram(localHistMap, leftBucketSize); } //Right most bucket else if (innerLoopBound.second == localVector.end()) // first { if(iownRightBucket) insertToHistogram(localHistMap, rightBucketSize); } //Inner buckets else { insertToHistogram(localHistMap, innerLoopBound.second - innerLoopBound.first); } it = innerLoopBound.second; } //Convert map to vector using tupleTypeforHist = std::tuple<uint64_t, uint32_t>; std::vector<tupleTypeforHist> localHistVector; for(MapType::iterator it = localHistMap.begin(); it != localHistMap.end(); ++it ) { localHistVector.push_back(std::make_tuple(it->first, it->second)); } //Gather vector from all processors to root auto globalHistVector = mxx::gather_vectors(localHistVector, comm); static layer_comparator<0, tupleTypeforHist> partition_size_cmp; //Write to file if(rank == 0) { //Sort the vector to bring counts with same size adjacent (default comparator will work) std::sort(globalHistVector.begin(), globalHistVector.end()); std::ofstream ofs; ofs.open(filename, std::ios_base::out); //Iterate over the global vector for(auto it = globalHistVector.begin(); it != globalHistVector.end();) { //Range of counts belonging to same partition size auto innerLoopRange = findRange(it, globalHistVector.end(), *it, partition_size_cmp); auto p_size = std::get<0>(*it); uint32_t sum = 0; //Loop over the range for(auto it2 = innerLoopRange.first; it2 != innerLoopRange.second; it2++) sum += std::get<1>(*it2); ofs << p_size << " " << sum <<"\n"; it = innerLoopRange.second; } ofs.close(); } }
template < typename IN_PORT_TYPE, typename OUT_PORT_TYPE > int randomizer_base::_transformerServiceFunction( typename std::vector< gr_istream< IN_PORT_TYPE > > &istreams , typename std::vector< gr_ostream< OUT_PORT_TYPE > > &ostreams ) { typedef typename std::vector< gr_istream< IN_PORT_TYPE > > _IStreamList; typedef typename std::vector< gr_ostream< OUT_PORT_TYPE > > _OStreamList; boost::mutex::scoped_lock lock(serviceThreadLock); if ( validGRBlock() == false ) { // create our processing block, and setup property notifiers createBlock(); LOG_DEBUG( randomizer_base, " FINISHED BUILDING GNU RADIO BLOCK"); } //process any Stream ID changes this could affect number of io streams processStreamIdChanges(); if ( !validGRBlock() || istreams.size() == 0 || ostreams.size() == 0 ) { LOG_WARN( randomizer_base, "NO STREAMS ATTACHED TO BLOCK..." ); return NOOP; } _input_ready.resize( istreams.size() ); _ninput_items_required.resize( istreams.size() ); _ninput_items.resize( istreams.size() ); _input_items.resize( istreams.size() ); _output_items.resize( ostreams.size() ); // // RESOLVE: need to look at forecast strategy, // 1) see how many read items are necessary for N number of outputs // 2) read input data and see how much output we can produce // // // Grab available data from input streams // typename _OStreamList::iterator ostream; typename _IStreamList::iterator istream = istreams.begin(); int nitems=0; for ( int idx=0 ; istream != istreams.end() && serviceThread->threadRunning() ; idx++, istream++ ) { // note this a blocking read that can cause deadlocks nitems = istream->read(); if ( istream->overrun() ) { LOG_WARN( randomizer_base, " NOT KEEPING UP WITH STREAM ID:" << istream->streamID ); } if ( istream->sriChanged() ) { // RESOLVE - need to look at how SRI changes can affect Gnu Radio BLOCK state LOG_DEBUG( randomizer_base, "SRI CHANGED, STREAMD IDX/ID: " << idx << "/" << istream->pkt->streamID ); setOutputStreamSRI( idx, istream->pkt->SRI ); } } LOG_TRACE( randomizer_base, "READ NITEMS: " << nitems ); if ( nitems <= 0 && !_istreams[0].eos() ) { return NOOP; } bool eos = false; int nout = 0; bool workDone = false; while ( nout > -1 && serviceThread->threadRunning() ) { eos = false; nout = _forecastAndProcess( eos, istreams, ostreams ); if ( nout > -1 ) { workDone = true; // we chunked on data so move read pointer.. istream = istreams.begin(); for ( ; istream != istreams.end(); istream++ ) { int idx=std::distance( istreams.begin(), istream ); // if we processed data for this stream if ( _input_ready[idx] ) { size_t nitems = 0; try { nitems = gr_sptr->nitems_read( idx ); } catch(...){} if ( nitems > istream->nitems() ) { LOG_WARN( randomizer_base, "WORK CONSUMED MORE DATA THAN AVAILABLE, READ/AVAILABLE " << nitems << "/" << istream->nitems() ); nitems = istream->nitems(); } istream->consume( nitems ); LOG_TRACE( randomizer_base, " CONSUME READ DATA ITEMS/REMAIN " << nitems << "/" << istream->nitems()); } } gr_sptr->reset_read_index(); } // check for not enough data return if ( nout == -1 ) { // check for end of stream istream = istreams.begin(); for ( ; istream != istreams.end() ; istream++) { if ( istream->eos() ) { eos=true; } } if ( eos ) { LOG_TRACE( randomizer_base, "EOS SEEN, SENDING DOWNSTREAM " ); _forecastAndProcess( eos, istreams, ostreams); } } } if ( eos ) { istream = istreams.begin(); for ( ; istream != istreams.end() ; istream++ ) { int idx=std::distance( istreams.begin(), istream ); LOG_DEBUG( randomizer_base, " CLOSING INPUT STREAM IDX:" << idx ); istream->close(); } // close remaining output streams ostream = ostreams.begin(); for ( ; eos && ostream != ostreams.end(); ostream++ ) { int idx=std::distance( ostreams.begin(), ostream ); LOG_DEBUG( randomizer_base, " CLOSING OUTPUT STREAM IDX:" << idx ); ostream->close(); } } // // set the read pointers of the GNU Radio Block to start at the beginning of the // supplied buffers // gr_sptr->reset_read_index(); LOG_TRACE( randomizer_base, " END OF TRANSFORM SERVICE FUNCTION....." << noutput_items ); if ( nout == -1 && eos == false && !workDone ) { return NOOP; } else { return NORMAL; } }
template < typename IN_PORT_TYPE, typename OUT_PORT_TYPE > int randomizer_base::_forecastAndProcess( bool &eos, typename std::vector< gr_istream< IN_PORT_TYPE > > &istreams , typename std::vector< gr_ostream< OUT_PORT_TYPE > > &ostreams ) { typedef typename std::vector< gr_istream< IN_PORT_TYPE > > _IStreamList; typedef typename std::vector< gr_ostream< OUT_PORT_TYPE > > _OStreamList; typename _OStreamList::iterator ostream; typename _IStreamList::iterator istream = istreams.begin(); int nout = 0; bool dataReady = false; if ( !eos ) { uint64_t max_items_avail = 0; for ( int idx=0 ; istream != istreams.end() && serviceThread->threadRunning() ; idx++, istream++ ) { LOG_TRACE( randomizer_base, "GET MAX ITEMS: STREAM:"<< idx << " NITEMS/SCALARS:" << istream->nitems() << "/" << istream->_data.size() ); max_items_avail = std::max( istream->nitems(), max_items_avail ); } if ( max_items_avail == 0 ) { LOG_TRACE( randomizer_base, "DATA CHECK - MAX ITEMS NOUTPUT/MAX_ITEMS:" << noutput_items << "/" << max_items_avail); return -1; } // // calc number of output elements based on input items available // noutput_items = 0; if ( !gr_sptr->fixed_rate() ) { noutput_items = round_down((int32_t) (max_items_avail * gr_sptr->relative_rate()), gr_sptr->output_multiple()); LOG_TRACE( randomizer_base, " VARIABLE FORECAST NOUTPUT == " << noutput_items ); } else { istream = istreams.begin(); for ( int i=0; istream != istreams.end(); i++, istream++ ) { int t_noutput_items = gr_sptr->fixed_rate_ninput_to_noutput( istream->nitems() ); if ( gr_sptr->output_multiple_set() ) { t_noutput_items = round_up(t_noutput_items, gr_sptr->output_multiple()); } if ( t_noutput_items > 0 ) { if ( noutput_items == 0 ) { noutput_items = t_noutput_items; } if ( t_noutput_items <= noutput_items ) { noutput_items = t_noutput_items; } } } LOG_TRACE( randomizer_base, " FIXED FORECAST NOUTPUT/output_multiple == " << noutput_items << "/" << gr_sptr->output_multiple()); } // // ask the block how much input they need to produce noutput_items... // if enough data is available to process then set the dataReady flag // int32_t outMultiple = gr_sptr->output_multiple(); while ( !dataReady && noutput_items >= outMultiple ) { // // ask the block how much input they need to produce noutput_items... // gr_sptr->forecast(noutput_items, _ninput_items_required); LOG_TRACE( randomizer_base, "--> FORECAST IN/OUT " << _ninput_items_required[0] << "/" << noutput_items ); istream = istreams.begin(); uint32_t dr_cnt=0; for ( int idx=0 ; noutput_items > 0 && istream != istreams.end(); idx++, istream++ ) { // check if buffer has enough elements _input_ready[idx] = false; if ( istream->nitems() >= (uint64_t)_ninput_items_required[idx] ) { _input_ready[idx] = true; dr_cnt++; } LOG_TRACE( randomizer_base, "ISTREAM DATACHECK NELMS/NITEMS/REQ/READY:" << istream->nelems() << "/" << istream->nitems() << "/" << _ninput_items_required[idx] << "/" << _input_ready[idx]); } if ( dr_cnt < istreams.size() ) { if ( outMultiple > 1 ) { noutput_items -= outMultiple; } else { noutput_items /= 2; } } else { dataReady = true; } LOG_TRACE( randomizer_base, " TRIM FORECAST NOUTPUT/READY " << noutput_items << "/" << dataReady ); } // check if data is ready... if ( !dataReady ) { LOG_TRACE( randomizer_base, "DATA CHECK - NOT ENOUGH DATA AVAIL/REQ:" << _istreams[0].nitems() << "/" << _ninput_items_required[0] ); return -1; } // reset looping variables int ritems = 0; int nitems = 0; // reset caching vectors _output_items.clear(); _input_items.clear(); _ninput_items.clear(); istream = istreams.begin(); for ( int idx=0 ; istream != istreams.end(); idx++, istream++ ) { // check if the stream is ready if ( !_input_ready[idx] ) { continue; } // get number of items remaining try { ritems = gr_sptr->nitems_read( idx ); } catch(...){ // something bad has happened, we are missing an input stream LOG_ERROR( randomizer_base, "MISSING INPUT STREAM FOR GR BLOCK, STREAM ID:" << istream->streamID ); return -2; } nitems = istream->nitems() - ritems; LOG_TRACE( randomizer_base, " ISTREAM: IDX:" << idx << " ITEMS AVAIL/READ/REQ " << nitems << "/" << ritems << "/" << _ninput_items_required[idx] ); if ( nitems >= _ninput_items_required[idx] && nitems > 0 ) { //remove eos checks ...if ( nitems < _ninput_items_required[idx] ) nitems=0; _ninput_items.push_back( nitems ); _input_items.push_back( (const void *) (istream->read_pointer(ritems)) ); } } // // setup output buffer vector based on noutput.. // ostream = ostreams.begin(); for( ; ostream != ostreams.end(); ostream++ ) { ostream->resize(noutput_items); _output_items.push_back((void*)(ostream->write_pointer()) ); } nout=0; if ( _input_items.size() != 0 && serviceThread->threadRunning() ) { LOG_TRACE( randomizer_base, " CALLING WORK.....N_OUT:" << noutput_items << " N_IN:" << nitems << " ISTREAMS:" << _input_items.size() << " OSTREAMS:" << _output_items.size()); nout = gr_sptr->general_work( noutput_items, _ninput_items, _input_items, _output_items); LOG_TRACE( randomizer_base, "RETURN WORK ..... N_OUT:" << nout); } // check for stop condition from work method if ( nout < gr_block::WORK_DONE ) { LOG_WARN( randomizer_base, "WORK RETURNED STOP CONDITION..." << nout ); nout=0; eos = true; } } if (nout != 0 or eos ) { noutput_items = nout; LOG_TRACE( randomizer_base, " WORK RETURNED: NOUT : " << nout << " EOS:" << eos); ostream = ostreams.begin(); typename IN_PORT_TYPE::dataTransfer *pkt=NULL; for ( int idx=0 ; ostream != ostreams.end(); idx++, ostream++ ) { pkt=NULL; int inputIdx = idx; if ( (size_t)(inputIdx) >= istreams.size() ) { for ( inputIdx= istreams.size()-1; inputIdx > -1; inputIdx--) { if ( istreams[inputIdx].pkt != NULL ) { pkt = istreams[inputIdx].pkt; break; } } } else { pkt = istreams[inputIdx].pkt; } LOG_TRACE( randomizer_base, "PUSHING DATA ITEMS/STREAM_ID " << ostream->nitems() << "/" << ostream->streamID ); if ( _maintainTimeStamp ) { // set time stamp for output samples based on input time stamp if ( ostream->nelems() == 0 ) { #ifdef TEST_TIME_STAMP LOG_DEBUG( randomizer_base, "SEED - TS SRI: xdelta:" << std::setprecision(12) << ostream->sri.xdelta ); LOG_DEBUG( randomizer_base, "OSTREAM WRITE: maint:" << _maintainTimeStamp ); LOG_DEBUG( randomizer_base, " mode:" << ostream->tstamp.tcmode ); LOG_DEBUG( randomizer_base, " status:" << ostream->tstamp.tcstatus ); LOG_DEBUG( randomizer_base, " offset:" << ostream->tstamp.toff ); LOG_DEBUG( randomizer_base, " whole:" << std::setprecision(10) << ostream->tstamp.twsec ); LOG_DEBUG( randomizer_base, "SEED - TS frac:" << std::setprecision(12) << ostream->tstamp.tfsec ); #endif ostream->setTimeStamp( pkt->T, _maintainTimeStamp ); } // write out samples, and set next time stamp based on xdelta and noutput_items ostream->write ( noutput_items, eos ); } else { // use incoming packet's time stamp to forward if ( pkt ) { #ifdef TEST_TIME_STAMP LOG_DEBUG( randomizer_base, "OSTREAM SRI: items/xdelta:" << noutput_items << "/" << std::setprecision(12) << ostream->sri.xdelta ); LOG_DEBUG( randomizer_base, "PKT - TS maint:" << _maintainTimeStamp ); LOG_DEBUG( randomizer_base, " mode:" << pkt->T.tcmode ); LOG_DEBUG( randomizer_base, " status:" << pkt->T.tcstatus ); LOG_DEBUG( randomizer_base, " offset:" << pkt->T.toff ); LOG_DEBUG( randomizer_base, " whole:" << std::setprecision(10) << pkt->T.twsec ); LOG_DEBUG( randomizer_base, "PKT - TS frac:" << std::setprecision(12) << pkt->T.tfsec ); #endif ostream->write( noutput_items, eos, pkt->T ); } else { #ifdef TEST_TIME_STAMP LOG_DEBUG( randomizer_base, "OSTREAM SRI: items/xdelta:" << noutput_items << "/" << std::setprecision(12) << ostream->sri.xdelta ); LOG_DEBUG( randomizer_base, "OSTREAM TOD maint:" << _maintainTimeStamp ); LOG_DEBUG( randomizer_base, " mode:" << ostream->tstamp.tcmode ); LOG_DEBUG( randomizer_base, " status:" << ostream->tstamp.tcstatus ); LOG_DEBUG( randomizer_base, " offset:" << ostream->tstamp.toff ); LOG_DEBUG( randomizer_base, " whole:" << std::setprecision(10) << ostream->tstamp.twsec ); LOG_DEBUG( randomizer_base, "OSTREAM TOD frac:" << std::setprecision(12) << ostream->tstamp.tfsec ); #endif // use time of day as time stamp ostream->write( noutput_items, eos, _maintainTimeStamp ); } } } // for ostreams } return nout; }
bool VisusIndexedData::getText(XMLNode& node, std::vector<std::vector<T > >* items, XMLDataStorage storageType) { int numItems = xmltoi(node.getAttribute("numItems")); int bufsize = xmltoi(node.getAttribute("bufsize")); unsigned char* buffer = new unsigned char[bufsize+1]; switch (storageType) { case BASE64: { // Retrieve data as BASE64 XMLParserBase64Tool base64; base64.decode(node.getText(), buffer, bufsize); } break; case EXTERNAL_FILE: { vwarning("saving data to external file is not yet supported"); return false; } break; case ASCII: { vwarning("saving data to external file is not yet supported"); return false; } break; } // Ensure vector is appropriate size if ((int)items->capacity() < numItems) items->resize(numItems); // Copy from contiguous buffer into non-contiguous data int position = 0; for (typename std::vector<std::vector<T> >::iterator iiter=items->begin(); iiter!=items->end(); ++iiter) { T value; memcpy(&value, &buffer[position], sizeof(T)); position += sizeof(T); // Ensure item that is vector is appropriate size if ((int)iiter->capacity() < (long) value) iiter->resize((long)value); // Load up item that is vector for (typename std::vector<T>::iterator idtIter=iiter->begin(); idtIter!=iiter->end(); ++idtIter) { vassert(position < bufsize); memcpy(&(*idtIter), &buffer[position], sizeof(T)); position += sizeof(T); } } vassert(position == bufsize); delete [] buffer; return true; }