/******************************************************************************* * This file is part of SWIFT. * Copyright (c) 2023 Yves Revaz (yves.revaz@epfl.ch) * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as published * by the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with this program. If not, see . * ******************************************************************************/ #ifndef SWIFT_CHEMISTRY_IO_AGORA_H #define SWIFT_CHEMISTRY_IO_AGORA_H #include "io_properties.h" /** * @brief Specifies which particle fields to read from a dataset * * @param parts The particle array. * @param list The list of i/o properties to read. * * @return Returns the number of fields to write. */ INLINE static int chemistry_read_particles(struct part* parts, struct io_props* list) { /* List what we want to read */ list[0] = io_make_input_field( "MetalMassFraction", DOUBLE, AGORA_CHEMISTRY_ELEMENT_COUNT, OPTIONAL, UNIT_CONV_NO_UNITS, parts, chemistry_data.metal_mass); return 1; } INLINE static void convert_gas_metals(const struct engine* e, const struct part* p, const struct xpart* xp, double* ret) { for (int i = 0; i < AGORA_CHEMISTRY_ELEMENT_COUNT; i++) { ret[i] = p->chemistry_data.metal_mass[i] / hydro_get_mass(p); } } /** * @brief Specifies which particle fields to write to a dataset * * @param parts The particle array. * @param xparts The extra particle array. * @param list The list of i/o properties to write. * @param with_cosmology Are we running with cosmology? * * @return Returns the number of fields to write. */ INLINE static int chemistry_write_particles(const struct part* parts, const struct xpart* xparts, struct io_props* list, const int with_cosmology) { /* List what we want to write */ list[0] = io_make_output_field( "SmoothedMetalMassFractions", DOUBLE, AGORA_CHEMISTRY_ELEMENT_COUNT, UNIT_CONV_NO_UNITS, 0.f, parts, chemistry_data.smoothed_metal_mass_fraction, "Mass fraction of each element smoothed over the neighbors"); list[1] = io_make_output_field_convert_part( "MetalMassFractions", DOUBLE, AGORA_CHEMISTRY_ELEMENT_COUNT, UNIT_CONV_NO_UNITS, 0.f, parts, xparts, convert_gas_metals, "Mass fraction of each element"); return 2; } /** * @brief Specifies which sparticle fields to write to a dataset * * @param sparts The sparticle array. * @param list The list of i/o properties to write. * * @return Returns the number of fields to write. */ INLINE static int chemistry_write_sparticles(const struct spart* sparts, struct io_props* list) { /* List what we want to write */ list[0] = io_make_output_field( "MetalMassFractions", DOUBLE, AGORA_CHEMISTRY_ELEMENT_COUNT, UNIT_CONV_NO_UNITS, 0.f, sparts, chemistry_data.metal_mass_fraction, "Mass fraction of each element"); return 1; } /** * @brief Specifies which sink fields to write to a dataset * * @param sinks The #sink array. * @param list The list of i/o properties to write. * * @return Returns the number of fields to write. */ INLINE static int chemistry_write_sinkparticles(const struct sink* sinks, struct io_props* list) { return 0; } /** * @brief Specifies which bparticle fields to write to a dataset * * @param bparts The bparticle array. * @param list The list of i/o properties to write. * * @return Returns the number of fields to write. */ INLINE static int chemistry_write_bparticles(const struct bpart* bparts, struct io_props* list) { /* update list according to hydro_io */ /* Return the number of fields to write */ return 0; } #ifdef HAVE_HDF5 /** * @brief Writes the current model of chemistry to the file * @param h_grp The HDF5 group in which to write * @param h_grp_columns The HDF5 group containing named columns * @param e The #engine. */ INLINE static void chemistry_write_flavour(hid_t h_grp, hid_t h_grp_columns, const struct engine* e) { io_write_attribute_s(h_grp, "Chemistry Model", "AGORA"); const char* element_names = e->chemistry->elements_name; /* Add to the named columns */ hsize_t dims[1] = {AGORA_CHEMISTRY_ELEMENT_COUNT}; hid_t type = H5Tcopy(H5T_C_S1); H5Tset_size(type, AGORA_LABELS_SIZE); hid_t space = H5Screate_simple(1, dims, NULL); hid_t dset = H5Dcreate(h_grp_columns, "MetalMassFractions", type, space, H5P_DEFAULT, H5P_DEFAULT, H5P_DEFAULT); H5Dwrite(dset, type, H5S_ALL, H5S_ALL, H5P_DEFAULT, element_names); H5Dclose(dset); dset = H5Dcreate(h_grp_columns, "SmoothedMetalMassFractions", type, space, H5P_DEFAULT, H5P_DEFAULT, H5P_DEFAULT); H5Dwrite(dset, type, H5S_ALL, H5S_ALL, H5P_DEFAULT, element_names); H5Dclose(dset); H5Tclose(type); /* Write the solar abundances and the elements */ /* Create the group */ hid_t h_sol_ab = H5Gcreate(h_grp, "SolarAbundances", H5P_DEFAULT, H5P_DEFAULT, H5P_DEFAULT); if (h_sol_ab < 0) error("Error while creating the SolarAbundances group\n"); /* Write all the elements as attributes */ for (int i = 0; i < AGORA_CHEMISTRY_ELEMENT_COUNT; i++) { const char* name = chemistry_get_element_name(e->chemistry, i); io_write_attribute_f(h_sol_ab, name, e->chemistry->solar_abundances[i]); } /* Close group */ H5Gclose(h_sol_ab); } #endif #endif /* SWIFT_CHEMISTRY_IO_AGORA_H */