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655 lines
23 KiB
C++
655 lines
23 KiB
C++
/*
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* output_arepo.cc - This file is part of MUSIC -
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* a code to generate multi-scale initial conditions
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* for cosmological simulations
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*
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* Copyright (C) 2010 Oliver Hahn
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*
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* Plugin: Dylan Nelson (dnelson@cfa.harvard.edu)
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*/
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#ifdef HAVE_HDF5
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#define GAS_PARTTYPE 0
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#define HIGHRES_DM_PARTTYPE 1
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#define COARSE_DM_DEFAULT_PARTTYPE 2
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#define STAR_PARTTYPE 4
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#define NTYPES 6
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#include <sstream>
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#include <string>
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#include <algorithm>
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#include "output.hh"
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#include "HDF_IO.hh"
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class arepo_output_plugin : public output_plugin
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{
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protected:
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// header/config
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std::vector<int> nPart;
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std::vector<int> nPartTotal;
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std::vector<double> massTable;
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double time, redshift, boxSize;
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int numFiles, doublePrec;
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double omega0, omega_L, hubbleParam;
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// configuration
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double UnitLength_in_cm, UnitMass_in_g, UnitVelocity_in_cm_per_s;
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double omega_b, rhoCrit;
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double posFac, velFac;
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int coarsePartType, nPartTotAllTypes;
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bool doBaryons, useLongIDs;
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size_t npfine, npart, npcoarse;
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std::vector<size_t> levelcounts;
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// parameter file hints
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int pmgrid, gridboost;
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float softening, Tini;
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using output_plugin::cf_;
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// Nx1 vector (e.g. masses,particleids)
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template< typename T >
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void writeHDF5_a( std::string fieldName, int partTypeNum, const std::vector<T> &data )
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{
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hid_t HDF_FileID, HDF_GroupID, HDF_DatasetID, HDF_DataspaceID, HDF_Type;
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hsize_t HDF_Dims;
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std::stringstream GrpName;
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GrpName << "PartType" << partTypeNum;
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HDF_FileID = H5Fopen( fname_.c_str(), H5F_ACC_RDWR, H5P_DEFAULT );
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HDF_GroupID = H5Gopen( HDF_FileID, GrpName.str().c_str() );
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HDF_Type = GetDataType<T>();
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HDF_Dims = data.size();
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HDF_DataspaceID = H5Screate_simple(1, &HDF_Dims, NULL);
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HDF_DatasetID = H5Dcreate( HDF_GroupID, fieldName.c_str(), HDF_Type, HDF_DataspaceID, H5P_DEFAULT );
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// write and close
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H5Dwrite( HDF_DatasetID, HDF_Type, H5S_ALL, H5S_ALL, H5P_DEFAULT, &data[0] );
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H5Dclose( HDF_DatasetID );
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H5Sclose( HDF_DataspaceID );
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H5Gclose( HDF_GroupID );
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H5Fclose( HDF_FileID );
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}
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// Nx3 vector (e.g. positions,velocities), where coord = index of the second dimension (writen one at a time)
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void writeHDF5_b( std::string fieldName, int coord, int partTypeNum, std::vector<float> &data, bool readFlag = false )
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{
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hid_t HDF_FileID, HDF_GroupID, HDF_DatasetID, HDF_DataspaceID, HDF_Type;
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hsize_t HDF_Dims[2], HDF_DimsMem[2];
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std::stringstream GrpName;
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GrpName << "PartType" << partTypeNum;
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HDF_FileID = H5Fopen( fname_.c_str(), H5F_ACC_RDWR, H5P_DEFAULT );
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HDF_GroupID = H5Gopen( HDF_FileID, GrpName.str().c_str() );
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HDF_Type = GetDataType<float>();
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HDF_Dims[0] = data.size();
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HDF_Dims[1] = 3;
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// if dataset does not yet exist, create it (on first coord call)
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if( !(H5Lexists(HDF_GroupID, fieldName.c_str(), H5P_DEFAULT)) )
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{
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HDF_DataspaceID = H5Screate_simple(2, HDF_Dims, NULL);
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HDF_DatasetID = H5Dcreate( HDF_GroupID, fieldName.c_str(), HDF_Type, HDF_DataspaceID, H5P_DEFAULT );
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H5Sclose( HDF_DataspaceID );
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H5Dclose( HDF_DatasetID );
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}
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// make memory space (just indicates the size/shape of data)
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HDF_DimsMem[0] = HDF_Dims[0];
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HDF_DimsMem[1] = 1;
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hid_t HDF_MemoryspaceID = H5Screate_simple(2, HDF_DimsMem, NULL);
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// open hyperslab
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hsize_t count[2]={1,1}, stride[2]={1,1}, offset[2]={0,0};
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offset[1] = coord; // set where in the second dimension to write
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count[0] = HDF_Dims[0]; // set size in the first dimension (num particles of this type)
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HDF_DatasetID = H5Dopen(HDF_GroupID, fieldName.c_str());
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HDF_DataspaceID = H5Dget_space(HDF_DatasetID);
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H5Sselect_hyperslab(HDF_DataspaceID, H5S_SELECT_SET, offset, stride, count, NULL /*, HDF_Dims*/); //HDF_DimsMem
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// write (or read) and close
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if( readFlag )
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H5Dread( HDF_DatasetID, HDF_Type, HDF_MemoryspaceID, HDF_DataspaceID, H5P_DEFAULT, &data[0] );
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else
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H5Dwrite( HDF_DatasetID, HDF_Type, HDF_MemoryspaceID, HDF_DataspaceID, H5P_DEFAULT, &data[0] );
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H5Dclose( HDF_DatasetID );
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H5Gclose( HDF_GroupID );
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H5Fclose( HDF_FileID );
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}
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// called from finalize()
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void generateAndWriteIDs( void )
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{
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long long offset = 0;
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nPartTotAllTypes = 0;
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for( size_t i=0; i < nPartTotal.size(); i++ )
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{
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if( !nPartTotal[i] )
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continue;
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nPartTotAllTypes += nPartTotal[i];
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if( !useLongIDs )
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{
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std::vector<int> ids = std::vector<int>(nPartTotal[i]);
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for( int j=0; j < nPartTotal[i]; j++ )
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ids[j] = offset + j;
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writeHDF5_a( "ParticleIDs", i, ids );
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}
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else
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{
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std::vector<long long> ids = std::vector<long long>(nPartTotal[i]);
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for( long long j=0; j < nPartTotal[i]; j++ )
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ids[j] = offset + j;
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writeHDF5_a( "ParticleIDs", i, ids );
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}
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// make IDs of all particle types sequential (unique) = unnecessary, but consistent with gadget output format
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offset += nPartTotal[i];
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}
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}
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void countLeafCells( const grid_hierarchy& gh )
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{
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npfine = 0; npart = 0; npcoarse = 0;
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npfine = gh.count_leaf_cells(gh.levelmax(), gh.levelmax());
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npart = gh.count_leaf_cells(gh.levelmin(), gh.levelmax());
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if( levelmax_ != levelmin_ ) // multimass
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npcoarse = gh.count_leaf_cells(gh.levelmin(), gh.levelmax()-1);
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}
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public:
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arepo_output_plugin( config_file& cf ) : output_plugin( cf )
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{
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// ensure that everyone knows we want to do SPH, implies: bsph=1, bbshift=1, decic_baryons=1
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// -> instead of just writing gas densities (which are here ignored), the gas displacements are also written
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cf.insertValue("setup","do_SPH","yes");
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// init header and config parameters
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nPart = std::vector<int>(NTYPES,0);
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nPartTotal = std::vector<int>(NTYPES,0);
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massTable = std::vector<double>(NTYPES,0.0);
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coarsePartType = cf.getValueSafe<unsigned>("output","arepo_coarsetype",COARSE_DM_DEFAULT_PARTTYPE);
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UnitLength_in_cm = cf.getValueSafe<double>("output","arepo_unitlength",3.085678e21); // 1.0 kpc
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UnitMass_in_g = cf.getValueSafe<double>("output","arepo_unitmass",1.989e43); // 1.0e10 solar masses
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UnitVelocity_in_cm_per_s = cf.getValueSafe<double>("output","arepo_unitvel",1e5); // 1 km/sec
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omega0 = cf.getValue<double>("cosmology","Omega_m");
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omega_b = cf.getValue<double>("cosmology","Omega_b");
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omega_L = cf.getValue<double>("cosmology","Omega_L");
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redshift = cf.getValue<double>("setup","zstart");
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boxSize = cf.getValue<double>("setup","boxlength");
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doBaryons = cf.getValueSafe<bool>("setup","baryons",false);
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useLongIDs = cf.getValueSafe<bool>("output","arepo_longids",false);
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numFiles = cf.getValueSafe<unsigned>("output","arepo_num_files",1);
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doublePrec = cf.getValueSafe<int>("output","arepo_doubleprec",0);
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if( numFiles != 1 )
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throw std::runtime_error("Error: arepo_num_files>1 not yet supported.");
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if( doublePrec )
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throw std::runtime_error("Error: arepo_doubleprec not yet supported.");
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// factors which multiply positions and velocities
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time = 1.0/(1.0+redshift);
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posFac = 3.085678e24 / UnitLength_in_cm; // MUSIC uses Mpc internally, i.e. posFac=1e3 for kpc output
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velFac = ( 1.0f / sqrt(time) ) * boxSize; // TODO: should be normalized by posFac?
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// critical density
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rhoCrit = 27.7519737e-9; // in h^2 1e10 M_sol / kpc^3
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rhoCrit *= pow(UnitLength_in_cm/3.085678e21, 3.0);
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rhoCrit *= (1.989e43/UnitMass_in_g);
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// calculate PMGRID suggestion
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pmgrid = pow(2,levelmin_) * 2; // unigrid
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gridboost = 1;
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if( levelmin_ != levelmax_ )
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{
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double lxref[3], x0ref[3], x1ref[3];
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double pmgrid_new;
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the_region_generator->get_AABB(x0ref,x1ref,levelmax_); // generalized beyond box
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for (int i=0; i < 3; i++)
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lxref[i] = x1ref[i] - x0ref[i];
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// fraction box length of the zoom region
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lxref[0] = pow( (lxref[0]*lxref[1]*lxref[2]),0.333 );
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pmgrid_new = pow(2,levelmax_) * 2; // to cover entire box at highest resolution
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pmgrid_new *= lxref[0]; // only need to cover a fraction
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if( (gridboost=round(pmgrid_new/pmgrid)) > 1 )
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gridboost = pow(2, ceil(log(gridboost)/log(2.0))); // round to nearest, higher power of 2
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}
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// calculate Tini for gas
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hubbleParam = cf.getValue<double>("cosmology","H0")/100.0;
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double astart = 1.0/(1.0+redshift);
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double h2 = hubbleParam*hubbleParam;
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double adec = 1.0/( 160.0*pow(omega_b*h2/0.022,2.0/5.0) );
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double Tcmb0 = 2.726;
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Tini = astart<adec? Tcmb0/astart : Tcmb0/astart/astart*adec;
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// calculate softening suggestion
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softening = (boxSize * posFac) / pow(2,levelmax_) / 40.0;
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// header and sanity checks
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if ( !doBaryons )
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massTable[HIGHRES_DM_PARTTYPE] = omega0 * rhoCrit * pow(boxSize*posFac,3.0)/pow(2,3*levelmax_);
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else
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massTable[HIGHRES_DM_PARTTYPE] = (omega0-omega_b) * rhoCrit * pow(boxSize*posFac,3.0)/pow(2,3*levelmax_);
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if ( coarsePartType == GAS_PARTTYPE || coarsePartType == HIGHRES_DM_PARTTYPE)
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throw std::runtime_error("Error: Specified illegal Arepo particle type for coarse particles.");
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if ( coarsePartType == STAR_PARTTYPE )
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LOGWARN("WARNING: Specified coarse particle type will collide with stars if USE_SFR enabled.");
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// create file
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HDFCreateFile(fname_);
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// create particle type groups
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std::stringstream GrpName;
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GrpName << "PartType" << HIGHRES_DM_PARTTYPE;
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HDFCreateGroup(fname_, GrpName.str().c_str()); // highres or unigrid DM
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if( doBaryons )
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{
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GrpName.str("");
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GrpName << "PartType" << GAS_PARTTYPE;
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HDFCreateGroup(fname_, GrpName.str().c_str()); // gas
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}
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if( levelmax_ != levelmin_ ) // multimass
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{
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GrpName.str("");
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GrpName << "PartType" << coarsePartType;
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HDFCreateGroup(fname_, "PartType2"); // coarse DM
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}
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}
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~arepo_output_plugin()
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{ }
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/* ------------------------------------------------------------------------------- */
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void write_dm_mass( const grid_hierarchy& gh )
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{
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countLeafCells(gh);
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// fill levelcount for header
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levelcounts = std::vector<size_t>(levelmax_-levelmin_+1);
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for( int ilevel=gh.levelmax(); ilevel>=(int)gh.levelmin(); --ilevel )
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levelcounts[gh.levelmax()-ilevel] = gh.count_leaf_cells(ilevel, ilevel);
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if( levelmax_ > levelmin_ +1 ) // morethan2bnd
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{
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// DM particles will have variable masses
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size_t count = 0;
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std::vector<float> data(npcoarse);
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for( int ilevel=gh.levelmax()-1; ilevel>=(int)gh.levelmin(); --ilevel )
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{
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// baryon particles live only on finest grid, these particles here are total matter particles
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float pmass = omega0 * rhoCrit * pow(boxSize*posFac,3.0)/pow(2,3*ilevel);
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for( unsigned i=0; i<gh.get_grid(ilevel)->size(0); ++i )
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for( unsigned j=0; j<gh.get_grid(ilevel)->size(1); ++j )
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for( unsigned k=0; k<gh.get_grid(ilevel)->size(2); ++k )
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if( gh.is_in_mask(ilevel,i,j,k) && !gh.is_refined(ilevel,i,j,k) )
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{
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data[count++] = pmass;
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}
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}
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if( count != npcoarse )
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throw std::runtime_error("Internal consistency error while writing masses");
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writeHDF5_a( "Masses", coarsePartType, data ); // write DM
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}
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else
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{
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// DM particles will all have the same mass, just write to massTable
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if( levelmax_ != levelmin_ ) // multimass
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massTable[coarsePartType] = omega0 * rhoCrit * pow(boxSize*posFac,3.0)/pow(2,3*levelmin_);
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}
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}
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void write_dm_position( int coord, const grid_hierarchy& gh )
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{
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countLeafCells(gh);
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// update header
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nPart[HIGHRES_DM_PARTTYPE] = npfine;
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nPart[coarsePartType] = npcoarse;
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nPartTotal[HIGHRES_DM_PARTTYPE] = npfine;
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nPartTotal[coarsePartType] = npcoarse;
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// FINE: collect displacements and convert to absolute coordinates with correct units
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int ilevel = gh.levelmax();
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std::vector<float> data(npfine);
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size_t count = 0;
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for( unsigned i=0; i<gh.get_grid(ilevel)->size(0); ++i )
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for( unsigned j=0; j<gh.get_grid(ilevel)->size(1); ++j )
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for( unsigned k=0; k<gh.get_grid(ilevel)->size(2); ++k )
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if( gh.is_in_mask(ilevel,i,j,k) && !gh.is_refined(ilevel,i,j,k) )
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{
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double xx[3];
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gh.cell_pos(ilevel, i, j, k, xx);
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xx[coord] = (xx[coord] + (*gh.get_grid(ilevel))(i,j,k)) * boxSize;
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xx[coord] = fmod( xx[coord] + boxSize,boxSize );
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data[count++] = (float) (xx[coord] * posFac);
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}
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writeHDF5_b( "Coordinates", coord, HIGHRES_DM_PARTTYPE, data ); // write fine DM
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if( count != npfine )
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throw std::runtime_error("Internal consistency error while writing fine DM pos");
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// COARSE: collect displacements and convert to absolute coordinates with correct units
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if( levelmax_ != levelmin_ ) // multimass
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{
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data = std::vector<float> (npcoarse,0.0);
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count = 0;
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for( int ilevel=gh.levelmax()-1; ilevel>=(int)gh.levelmin(); --ilevel )
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for( unsigned i=0; i<gh.get_grid(ilevel)->size(0); ++i )
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for( unsigned j=0; j<gh.get_grid(ilevel)->size(1); ++j )
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for( unsigned k=0; k<gh.get_grid(ilevel)->size(2); ++k )
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if( gh.is_in_mask(ilevel,i,j,k) && !gh.is_refined(ilevel,i,j,k) )
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{
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double xx[3];
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gh.cell_pos(ilevel, i, j, k, xx);
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xx[coord] = (xx[coord] + (*gh.get_grid(ilevel))(i,j,k)) * boxSize;
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if ( !doBaryons ) // if so, we will handle the mod in write_gas_position
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xx[coord] = fmod( xx[coord] + boxSize,boxSize ) * posFac;
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data[count++] = (float) xx[coord];
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}
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if( count != npcoarse )
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throw std::runtime_error("Internal consistency error while writing coarse DM pos");
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writeHDF5_b( "Coordinates", coord, coarsePartType, data ); // write coarse DM
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}
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}
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void write_dm_velocity( int coord, const grid_hierarchy& gh )
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{
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countLeafCells(gh);
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// FINE: collect velocities and convert to correct units
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int ilevel = gh.levelmax();
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std::vector<float> data(npfine);
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size_t count = 0;
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for( unsigned i=0; i<gh.get_grid(ilevel)->size(0); ++i )
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for( unsigned j=0; j<gh.get_grid(ilevel)->size(1); ++j )
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for( unsigned k=0; k<gh.get_grid(ilevel)->size(2); ++k )
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if( gh.is_in_mask(ilevel,i,j,k) && !gh.is_refined(ilevel,i,j,k) )
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{
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data[count++] = (*gh.get_grid(ilevel))(i,j,k) * velFac;
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}
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writeHDF5_b( "Velocities", coord, HIGHRES_DM_PARTTYPE, data ); // write fine DM
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if( count != npfine )
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throw std::runtime_error("Internal consistency error while writing fine DM pos");
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// COARSE: collect velocities and convert to correct units
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if( levelmax_ != levelmin_ ) // multimass
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{
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data = std::vector<float> (npcoarse,0.0);
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count = 0;
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for( int ilevel=gh.levelmax()-1; ilevel>=(int)gh.levelmin(); --ilevel )
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for( unsigned i=0; i<gh.get_grid(ilevel)->size(0); ++i )
|
|
for( unsigned j=0; j<gh.get_grid(ilevel)->size(1); ++j )
|
|
for( unsigned k=0; k<gh.get_grid(ilevel)->size(2); ++k )
|
|
if( gh.is_in_mask(ilevel,i,j,k) && !gh.is_refined(ilevel,i,j,k) )
|
|
{
|
|
data[count++] = (*gh.get_grid(ilevel))(i,j,k) * velFac;
|
|
}
|
|
|
|
if( count != npcoarse )
|
|
throw std::runtime_error("Internal consistency error while writing coarse DM pos");
|
|
|
|
writeHDF5_b( "Velocities", coord, coarsePartType, data ); // write coarse DM
|
|
}
|
|
|
|
}
|
|
|
|
void write_dm_density( const grid_hierarchy& gh )
|
|
{ /* skip */ }
|
|
|
|
void write_dm_potential( const grid_hierarchy& gh )
|
|
{ /* skip */ }
|
|
|
|
/* ------------------------------------------------------------------------------- */
|
|
|
|
void write_gas_velocity( int coord, const grid_hierarchy& gh )
|
|
{
|
|
countLeafCells(gh);
|
|
|
|
std::vector<float> gas_data(npart); // read/write gas at all levels from the gh
|
|
size_t count = 0;
|
|
|
|
for( int ilevel=levelmax_; ilevel>=(int)levelmin_; --ilevel )
|
|
for( unsigned i=0; i<gh.get_grid(ilevel)->size(0); ++i )
|
|
for( unsigned j=0; j<gh.get_grid(ilevel)->size(1); ++j )
|
|
for( unsigned k=0; k<gh.get_grid(ilevel)->size(2); ++k )
|
|
if( gh.is_in_mask(ilevel,i,j,k) && !gh.is_refined(ilevel,i,j,k) )
|
|
{
|
|
gas_data[count++] = (*gh.get_grid(ilevel))(i,j,k) * velFac;
|
|
}
|
|
|
|
if( count != npart )
|
|
throw std::runtime_error("Internal consistency error while writing GAS pos");
|
|
|
|
// calculate modified DM velocities if: multimass and baryons present
|
|
if( doBaryons && npcoarse )
|
|
{
|
|
double facb = omega_b / omega0;
|
|
double facc = (omega0 - omega_b) / omega0;
|
|
|
|
std::vector<float> dm_data(npcoarse);
|
|
|
|
writeHDF5_b( "Velocities", coord, coarsePartType, dm_data, true ); // read coarse DM vels
|
|
|
|
// overwrite
|
|
for( size_t i=0; i < npcoarse; i++ )
|
|
dm_data[i] = facc*dm_data[i] + facb*gas_data[npfine + i];
|
|
|
|
writeHDF5_b( "Velocities", coord, coarsePartType, dm_data ); // overwrite coarse DM vels
|
|
} // dm_data deallocated
|
|
|
|
// restrict gas_data to fine only and request write
|
|
std::vector<float> data( gas_data.begin() + 0, gas_data.begin() + npfine );
|
|
|
|
std::vector<float>().swap( gas_data ); // deallocate
|
|
|
|
writeHDF5_b( "Velocities", coord, GAS_PARTTYPE, data ); // write highres gas
|
|
}
|
|
|
|
void write_gas_position( int coord, const grid_hierarchy& gh )
|
|
{
|
|
countLeafCells(gh);
|
|
|
|
// update header (will actually write only gas at levelmax)
|
|
nPart[GAS_PARTTYPE] = npfine;
|
|
nPartTotal[GAS_PARTTYPE] = npfine;
|
|
|
|
std::vector<double> gas_data(npart); // read/write gas at all levels from the gh
|
|
size_t count = 0;
|
|
|
|
double h = 1.0/(1ul<<gh.levelmax());
|
|
|
|
for( int ilevel=gh.levelmax(); ilevel>=(int)gh.levelmin(); --ilevel )
|
|
for( unsigned i=0; i<gh.get_grid(ilevel)->size(0); ++i )
|
|
for( unsigned j=0; j<gh.get_grid(ilevel)->size(1); ++j )
|
|
for( unsigned k=0; k<gh.get_grid(ilevel)->size(2); ++k )
|
|
if( gh.is_in_mask(ilevel,i,j,k) && !gh.is_refined(ilevel,i,j,k) )
|
|
{
|
|
double xx[3];
|
|
gh.cell_pos(ilevel, i, j, k, xx);
|
|
|
|
// shift particle positions (this has to be done as the same shift
|
|
// is used when computing the convolution kernel for SPH baryons)
|
|
xx[coord] += 0.5*h;
|
|
|
|
xx[coord] = (xx[coord] + (*gh.get_grid(ilevel))(i,j,k)) * boxSize;
|
|
|
|
gas_data[count++] = xx[coord];
|
|
}
|
|
|
|
if( count != npart )
|
|
throw std::runtime_error("Internal consistency error while writing coarse DM pos");
|
|
|
|
// calculate modified DM coordinates if: multimass and baryons present
|
|
if( doBaryons && npcoarse )
|
|
{
|
|
double facb = omega_b / omega0;
|
|
double facc = (omega0 - omega_b) / omega0;
|
|
|
|
std::vector<float> dm_data(npcoarse);
|
|
|
|
writeHDF5_b( "Coordinates", coord, coarsePartType, dm_data, true ); // read coarse DM vels
|
|
|
|
// overwrite
|
|
for( size_t i=0; i < npcoarse; i++ ) {
|
|
dm_data[i] = facc*dm_data[i] + facb*gas_data[npfine + i];
|
|
dm_data[i] = fmod( dm_data[i] + boxSize, boxSize ) * posFac;
|
|
}
|
|
|
|
writeHDF5_b( "Coordinates", coord, coarsePartType, dm_data ); // overwrite coarse DM vels
|
|
}
|
|
|
|
// restrict gas_data to fine only and request write
|
|
//std::vector<float> data( gas_data.begin() + 0, gas_data.begin() + npfine );
|
|
|
|
std::vector<float> data(npfine);
|
|
|
|
for( size_t i = 0; i < npfine; i++ )
|
|
data[i] = (float) ( fmod( gas_data[i] + boxSize, boxSize ) * posFac );
|
|
|
|
std::vector<double>().swap( gas_data ); // deallocate
|
|
|
|
writeHDF5_b( "Coordinates", coord, GAS_PARTTYPE, data ); // write highres gas
|
|
|
|
}
|
|
|
|
void write_gas_density( const grid_hierarchy& gh )
|
|
{
|
|
// if only saving highres gas, then all gas cells have the same initial mass
|
|
// do not write out densities as we write out displacements
|
|
if( doBaryons )
|
|
massTable[GAS_PARTTYPE] = omega_b * rhoCrit * pow(boxSize*posFac,3.0)/pow(2,3*levelmax_);
|
|
}
|
|
|
|
void write_gas_potential( const grid_hierarchy& gh )
|
|
{ /* skip */ }
|
|
|
|
void finalize( void )
|
|
{
|
|
// generate and add contiguous IDs for each particle type we have written
|
|
generateAndWriteIDs();
|
|
|
|
// write final header (some of these fields are required, others are extra info)
|
|
HDFCreateGroup(fname_, "Header");
|
|
|
|
std::vector<unsigned int> nPartTotalHW(nPartTotal.size());
|
|
for( size_t i=0; i < nPartTotalHW.size(); i++ )
|
|
nPartTotalHW[i] = (unsigned)( (size_t)nPartTotal[i] >> 32 );
|
|
|
|
HDFWriteGroupAttribute(fname_, "Header", "NumPart_ThisFile", nPart );
|
|
HDFWriteGroupAttribute(fname_, "Header", "NumPart_Total", nPartTotal );
|
|
HDFWriteGroupAttribute(fname_, "Header", "NumPart_Total_HighWord", nPartTotalHW );
|
|
HDFWriteGroupAttribute(fname_, "Header", "MassTable", massTable );
|
|
HDFWriteGroupAttribute(fname_, "Header", "BoxSize", boxSize );
|
|
HDFWriteGroupAttribute(fname_, "Header", "NumFilesPerSnapshot", numFiles );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Time", time );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Redshift", redshift );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Omega0", omega0 );
|
|
HDFWriteGroupAttribute(fname_, "Header", "OmegaLambda", omega_L );
|
|
HDFWriteGroupAttribute(fname_, "Header", "OmegaBaryon", omega_b );
|
|
HDFWriteGroupAttribute(fname_, "Header", "HubbleParam", hubbleParam );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Flag_Sfr", 0 );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Flag_Cooling", 0 );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Flag_StellarAge", 0 );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Flag_Metals", 0 );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Flag_Feedback", 0 );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Flag_DoublePrecision", doublePrec );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Music_levelmin", levelmin_ );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Music_levelmax", levelmax_ );
|
|
HDFWriteGroupAttribute(fname_, "Header", "Music_levelcounts", levelcounts );
|
|
HDFWriteGroupAttribute(fname_, "Header", "haveBaryons", (int)doBaryons );
|
|
HDFWriteGroupAttribute(fname_, "Header", "longIDs", (int)useLongIDs );
|
|
HDFWriteGroupAttribute(fname_, "Header", "suggested_pmgrid", pmgrid );
|
|
HDFWriteGroupAttribute(fname_, "Header", "suggested_gridboost", gridboost );
|
|
HDFWriteGroupAttribute(fname_, "Header", "suggested_highressoft", softening );
|
|
HDFWriteGroupAttribute(fname_, "Header", "suggested_gas_Tinit", Tini );
|
|
|
|
// output particle counts
|
|
std::cout << " - Arepo : wrote " << nPartTotAllTypes << " particles to file..." << std::endl;
|
|
for( size_t i=0; i < nPartTotal.size(); i++ )
|
|
std::cout << " type [" << i << "] : " << std::setw(12) << nPartTotal[i] << std::endl;
|
|
|
|
// give config/parameter file hints
|
|
if( useLongIDs )
|
|
std::cout << " - Arepo: Wrote 64bit IDs, enable LONGIDS." << std::endl;
|
|
if( NTYPES > 6 )
|
|
std::cout << " - Arepo: Using [" << NTYPES << "] particle types, set NTYPES to match." << std::endl;
|
|
if( doBaryons )
|
|
std::cout << " - Arepo: Wrote gas, set REFINEMENT_HIGH_RES_GAS and GENERATE_GAS_IN_ICS with "
|
|
<< "SPLIT_PARTICLE_TYPE=" << pow(2,coarsePartType) << "." << std::endl;
|
|
if( levelmax_ != levelmin_ )
|
|
std::cout << " - Arepo: Have zoom type ICs, set PLACEHIGHRESREGION=" << pow(2,HIGHRES_DM_PARTTYPE)
|
|
<< " (suggest PMGRID=" << pmgrid << " with GRIDBOOST=" << gridboost << ")." << std::endl;
|
|
if( levelmax_ > levelmin_ + 1 )
|
|
std::cout << " - Arepo: More than one coarse DM mass using same type, set INDIVIDUAL_GRAVITY_SOFTENING="
|
|
<< pow(2,coarsePartType) << " (+" << pow(2,STAR_PARTTYPE) << " if including stars)." << std::endl;
|
|
if( doBaryons )
|
|
std::cout << " - Arepo: Set initial gas temperature to " << std::fixed << std::setprecision(3) << Tini << " K." << std::endl;
|
|
std::cout << " - Arepo: Suggest grav softening = " << std::setprecision(3) << softening << " for high res DM." << std::endl;
|
|
|
|
}
|
|
|
|
};
|
|
|
|
namespace{
|
|
output_plugin_creator_concrete< arepo_output_plugin > creator("arepo");
|
|
}
|
|
|
|
#endif // HAVE_HDF5
|