mirror of
https://github.com/Richard-Sti/csiborgtools.git
synced 2024-12-22 18:08:03 +00:00
4fa0e04f6e
* Add path to fields * Add new Manticore field support * Downsample Manticore to 20 snapshots * Add manticore snapshot * Remove downsampling * Add Manticore * Add names of manti * Add manti * Simplify * Update script * Update CF4 ICs * Updaet LOS settings * Update nb * Update imports * Reorganise funcs * Update script * Add basic void model
471 lines
16 KiB
Python
471 lines
16 KiB
Python
# Copyright (C) 2024 Richard Stiskalek
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# This program is free software; you can redistribute it and/or modify it
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# under the terms of the GNU General Public License as published by the
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# Free Software Foundation; either version 3 of the License, or (at your
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# option) any later version.
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# This program is distributed in the hope that it will be useful, but
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# WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General
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# Public License for more details.
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#
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# You should have received a copy of the GNU General Public License along
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# with this program; if not, write to the Free Software Foundation, Inc.,
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# 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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"""
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MPI script to interpolate the density and velocity fields along the line of
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sight.
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"""
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import sys
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from argparse import ArgumentParser
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from datetime import datetime
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from gc import collect
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from os import makedirs, remove, rmdir
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from os.path import exists, join
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from warnings import warn
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import numpy as np
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from astropy import units as u
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from astropy.coordinates import SkyCoord
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from astropy.cosmology import FlatLambdaCDM
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from astropy.io import fits
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from h5py import File
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from mpi4py import MPI
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from numba import jit
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from scipy.interpolate import interp1d
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from taskmaster import work_delegation # noqa
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import csiborgtools
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sys.path.append("../")
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from utils import get_nsims # noqa
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###############################################################################
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# I/O functions #
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###############################################################################
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def make_spacing(rmax, dr, dense_mu_min, dense_mu_max, dmu, Om0):
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"""
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Make radial spacing that at low distance is with constant spacing in
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distance modulus and at higher distances is with constant spacing in
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comoving distance.
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"""
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# Create interpolant to go from distance modulus to comoving distance.
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cosmo = FlatLambdaCDM(H0=100, Om0=Om0)
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z_range = np.linspace(0, 0.1, 1000000)[1:]
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r_range = cosmo.comoving_distance(z_range).value
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mu_range = cosmo.distmod(z_range).value
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mu2r = interp1d(mu_range, r_range, kind='cubic')
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# Create the spacing in distance modulus.
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mu = np.arange(dense_mu_min, dense_mu_max, dmu)
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rmin_dense = mu2r(np.min(mu))
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rmax_dense = mu2r(np.max(mu))
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# Create the spacing in comoving distance below and above.
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rlow = np.arange(0, rmin_dense, dr)
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rmed = mu2r(mu)
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rhigh = np.arange(rmax_dense, rmax, dr)[1:]
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# Combine the spacings.
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return np.hstack([rlow, rmed, rhigh])
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def get_los(catalogue_name, simname, comm):
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"""
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Get the line of sight RA/dec coordinates for the given catalogue.
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Parameters
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----------
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catalogue_name : str
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Catalogue name.
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simname : str
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Simulation name.
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comm : mpi4py.MPI.Comm
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MPI communicator.
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Returns
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-------
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pos : 2-dimensional array
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RA/dec coordinates of the line of sight.
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"""
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if comm.Get_rank() == 0:
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folder = "/mnt/extraspace/rstiskalek/catalogs"
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if catalogue_name in ["LOSS", "Foundation", "SFI_gals",
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"SFI_gals_masked", "SFI_groups", "2MTF",
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"Pantheon+"]:
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fpath = join(folder, "PV_compilation.hdf5")
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with File(fpath, 'r') as f:
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grp = f[catalogue_name]
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RA = grp["RA"][:]
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dec = grp["DEC"][:]
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elif catalogue_name == "A2":
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fpath = join(folder, "A2.h5")
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with File(fpath, 'r') as f:
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RA = f["RA"][:]
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dec = f["DEC"][:]
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elif "CB2_" in catalogue_name:
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kind = catalogue_name.split("_")[-1]
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fname = f"/mnt/extraspace/rstiskalek/catalogs/PV_mock_CB2_17417_{kind}.hdf5" # noqa
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with File(fname, 'r') as f:
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RA = f["RA"][:]
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dec = f["DEC"][:]
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elif catalogue_name == "UPGLADE":
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fname = "/mnt/users/rstiskalek/csiborgtools/data/upglade_all_z0p05_new_PROCESSED.h5" # noqa
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with File(fname, 'r') as f:
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RA = f["RA"][:]
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dec = f["DEC"][:]
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elif catalogue_name == "CF4_GroupAll":
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fname = "/mnt/extraspace/rstiskalek/catalogs/PV/CF4/CF4_GroupAll.hdf5" # noqa
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with File(fname, 'r') as f:
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RA = f["RA"][:]
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dec = f["DE"][:]
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elif catalogue_name == "CF4_TFR":
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fname = "/mnt/extraspace/rstiskalek/catalogs/PV/CF4/CF4_TF-distances.hdf5" # noqa
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with File(fname, 'r') as f:
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RA = f["RA"][:] * 360 / 24 # Convert to degrees from hours.
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dec = f["DE"][:]
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else:
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raise ValueError(f"Unknown catalogue name: `{catalogue_name}`.")
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if comm.Get_rank() == 0:
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print(f"The dataset contains {len(RA)} objects.")
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if simname in ["Carrick2015", "Lilow2024"]:
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# The Carrick+2015 and Lilow+2024 are in galactic coordinates, so
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# we need to convert the RA/dec to galactic coordinates.
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c = SkyCoord(ra=RA*u.degree, dec=dec*u.degree, frame='icrs')
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pos = np.vstack((c.galactic.l, c.galactic.b)).T
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elif simname in ["CF4", "CLONES"]:
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# CF4 and CLONES fields are in supergalactic coordinates.
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c = SkyCoord(ra=RA*u.degree, dec=dec*u.degree, frame='icrs')
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pos = np.vstack((c.supergalactic.sgl, c.supergalactic.sgb)).T
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else:
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pos = np.vstack((RA, dec)).T
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else:
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pos = None
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return comm.bcast(pos, root=0)
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def get_field(simname, nsim, kind, MAS, grid):
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"""
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Get the field from the simulation.
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Parameters
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----------
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simname : str
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Simulation name.
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nsim : int
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IC realisation index.
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kind : str
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Field kind. Either `density` or `velocity`.
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MAS : str
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Mass assignment scheme.
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grid : int
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Grid resolution.
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Returns
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-------
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field : n-dimensional array
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"""
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# Open the field reader.
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if simname == "csiborg1":
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field_reader = csiborgtools.read.CSiBORG1Field(nsim)
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elif "csiborg2_" in simname:
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simkind = simname.split("_")[-1]
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field_reader = csiborgtools.read.CSiBORG2Field(nsim, simkind)
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elif simname == "csiborg2X":
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field_reader = csiborgtools.read.CSiBORG2XField(nsim, version=0)
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elif simname == "manticore_2MPP_N128_DES_V1":
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field_reader = csiborgtools.read.CSiBORG2XField(nsim, version=1)
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elif simname == "CLONES":
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field_reader = csiborgtools.read.CLONESField(nsim)
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elif simname == "Carrick2015":
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folder = "/mnt/extraspace/rstiskalek/catalogs"
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warn(f"Using local paths from `{folder}`.", RuntimeWarning)
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if kind == "density":
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fpath = join(folder, "twompp_density_carrick2015.npy")
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return np.load(fpath).astype(np.float32)
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elif kind == "velocity":
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fpath = join(folder, "twompp_velocity_carrick2015.npy")
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field = np.load(fpath).astype(np.float32)
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# Because the Carrick+2015 data is in the following form:
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# "The velocities are predicted peculiar velocities in the CMB
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# frame in Galactic Cartesian coordinates, generated from the
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# \(\delta_g^*\) field with \(\beta^* = 0.43\) and an external
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# dipole \(V_\mathrm{ext} = [89,-131,17]\) (Carrick et al Table 3)
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# has already been added.""
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field[0] -= 89
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field[1] -= -131
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field[2] -= 17
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field /= 0.43
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return field
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else:
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raise ValueError(f"Unknown field kind: `{kind}`.")
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elif simname == "CF4":
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folder = "/mnt/extraspace/rstiskalek/catalogs/CF4"
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warn(f"Using local paths from `{folder}`.", RuntimeWarning)
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if kind == "density":
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fpath = join(folder, f"CF4_new_128-z008_realization{nsim}_delta.fits") # noqa
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elif kind == "velocity":
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fpath = join(folder, f"CF4_new_128-z008_realization{nsim}_velocity.fits") # noqa
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else:
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raise ValueError(f"Unknown field kind: `{kind}`.")
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field = fits.open(fpath)[0].data
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# https://projets.ip2i.in2p3.fr//cosmicflows/ says to multiply by 52
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if kind == "velocity":
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field *= 52
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return field.astype(np.float32)
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elif simname == "Lilow2024":
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folder = "/mnt/extraspace/rstiskalek/catalogs"
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warn(f"Using local paths from `{folder}`.", RuntimeWarning)
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if kind == "density":
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fpath = join(folder, "Lilow2024_density.npy")
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field = np.load(fpath)
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elif kind == "velocity":
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field = []
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for p in ["x", "y", "z"]:
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fpath = join(folder, f"Lilow2024_{p}Velocity.npy")
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field.append(np.load(fpath).astype(np.float32))
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field = np.stack(field)
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return field.astype(np.float32)
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else:
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raise ValueError(f"Unknown simulation name: `{simname}`.")
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# Read in the field.
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if kind == "density":
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field = field_reader.density_field(MAS=MAS, grid=grid)
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elif kind == "velocity":
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field = field_reader.velocity_field(MAS=MAS, grid=grid)
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else:
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raise ValueError(f"Unknown field kind: `{kind}`.")
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return field
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def combine_from_simulations(catalogue_name, simname, nsims, outfolder,
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dumpfolder):
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"""
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Combine the results from individual simulations into a single file.
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Parameters
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----------
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catalogue_name : str
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Catalogue name.
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simname : str
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Simulation name.
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nsims : list
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List of IC realisations.
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outfolder : str
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Output folder.
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dumpfolder : str
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Dumping folder where the temporary files are stored.
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Returns
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-------
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None
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"""
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fname_out = join(outfolder, f"los_{catalogue_name}_{simname}.hdf5")
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print(f"Combining results from invidivual simulations to `{fname_out}`.")
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if exists(fname_out):
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remove(fname_out)
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for nsim in nsims:
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fname = join(dumpfolder, f"los_{simname}_{nsim}.hdf5")
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with File(fname, 'r') as f, File(fname_out, 'a') as f_out:
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f_out.create_dataset(f"rdist_{nsim}", data=f["rdist"][:])
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f_out.create_dataset(f"density_{nsim}", data=f["density"][:])
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f_out.create_dataset(f"velocity_{nsim}", data=f["velocity"][:])
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f_out.create_dataset(f"rmax_{nsim}", data=f["rmax"][:])
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# Remove the temporary file.
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remove(fname)
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# Remove the dumping folder.
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rmdir(dumpfolder)
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print("Finished combining results.")
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###############################################################################
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# Main interpolating function #
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###############################################################################
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@jit(nopython=True)
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def find_index_of_first_nan(y):
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for n in range(1, len(y)):
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if np.isnan(y[n]):
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return n
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return None
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def replace_nan_with_last_finite(x, y, apply_decay):
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n = find_index_of_first_nan(y)
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if n is None:
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return y, x[-1]
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y[n:] = y[n-1]
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rmax = x[n-1]
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if apply_decay:
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# Optionally aply 1 / r decay
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y[n:] *= rmax / x[n:]
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return y, rmax
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def interpolate_field(pos, simname, nsim, MAS, grid, dump_folder, r,
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smooth_scales, verbose=False):
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"""
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Interpolate the density and velocity fields along the line of sight.
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Parameters
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----------
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pos : 2-dimensional array
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RA/dec coordinates of the line of sight.
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simname : str
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Simulation name.
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nsim : int
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IC realisation index.
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MAS : str
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Mass assignment scheme.
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grid : int
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Grid resolution.
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dump_folder : str
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Folder where the temporary files are stored.
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r : 1-dimensional array
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Radial spacing.
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smooth_scales : list
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Smoothing scales.
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Returns
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-------
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None
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"""
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boxsize = csiborgtools.simname2boxsize(simname)
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fname_out = join(dump_folder, f"los_{simname}_{nsim}.hdf5")
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# First do the density field.
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if verbose:
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print(f"Interpolating density field for IC realisation `{nsim}`.",
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flush=True)
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density = get_field(simname, nsim, "density", MAS, grid)
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rdist, finterp = csiborgtools.field.evaluate_los(
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density, sky_pos=pos, boxsize=boxsize, rdist=r,
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smooth_scales=smooth_scales, verbose=verbose,
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interpolation_method="linear")
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rmax_density = np.full((len(pos), len(smooth_scales)), np.nan)
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for i in range(len(pos)):
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for j in range(len(smooth_scales)):
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y, current_rmax = replace_nan_with_last_finite(rdist, finterp[i, :, j], False) # noqa
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finterp[i, :, j] = y
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if current_rmax is not None:
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rmax_density[i, j] = current_rmax
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print(f"Writing temporary file `{fname_out}`.")
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with File(fname_out, 'w') as f:
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f.create_dataset("rdist", data=rdist)
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f.create_dataset("density", data=finterp)
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del density, rdist, finterp
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collect()
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if verbose:
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print(f"Interpolating velocity field for IC realisation `{nsim}`.",
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flush=True)
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velocity = get_field(simname, nsim, "velocity", MAS, grid)
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rdist, finterp = csiborgtools.field.evaluate_los(
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velocity[0], velocity[1], velocity[2],
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sky_pos=pos, boxsize=boxsize, rdist=r, smooth_scales=smooth_scales,
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verbose=verbose, interpolation_method="linear")
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rmax_velocity = np.full((3, len(pos), len(smooth_scales)), np.nan)
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for k in range(3):
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for i in range(len(pos)):
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for j in range(len(smooth_scales)):
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y, current_rmax = replace_nan_with_last_finite(rdist, finterp[k][i, :, j], True) # noqa
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finterp[k][i, :, j] = y
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if current_rmax is not None:
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rmax_velocity[k, i, j] = current_rmax
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rmax_velocity = np.min(rmax_velocity, axis=0)
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rmax = np.minimum(rmax_density, rmax_velocity)
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with File(fname_out, 'a') as f:
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f.create_dataset("velocity", data=finterp)
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f.create_dataset("rmax", data=rmax)
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###############################################################################
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# Command line interface #
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###############################################################################
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if __name__ == "__main__":
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parser = ArgumentParser()
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parser.add_argument("--catalogue", type=str, help="Catalogue name.")
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parser.add_argument("--nsims", type=int, nargs="+", default=None,
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help="IC realisations. `-1` for all simulations.")
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parser.add_argument("--simname", type=str, help="Simulation name.")
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parser.add_argument("--MAS", type=str,
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choices=["NGP", "CIC", "TSC", "PCS", "SPH"],
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help="Mass assignment scheme.")
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parser.add_argument("--grid", type=int, help="Grid resolution.")
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args = parser.parse_args()
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Om0 = csiborgtools.simname2Omega_m(args.simname)
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# r = make_spacing(200, 0.75, 23.25, 34, 0.01, Om0)
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r = np.arange(0, 200, 0.5)
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# smooth_scales = [0, 2, 4, 6, 8]
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smooth_scales = [0, 8]
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print(f"Running catalogue {args.catalogue} for simulation {args.simname} "
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f"with {len(r)} radial points.")
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comm = MPI.COMM_WORLD
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paths = csiborgtools.read.Paths(**csiborgtools.paths_glamdring)
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nsims = get_nsims(args, paths)
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out_folder = "/mnt/extraspace/rstiskalek/csiborg_postprocessing/field_los"
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# Create the dumping folder.
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if comm.Get_rank() == 0:
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dump_folder = join(out_folder,
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f"temp_{str(datetime.now())}".replace(" ", "_"))
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print(f"Creating folder `{dump_folder}`.")
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makedirs(dump_folder)
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else:
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dump_folder = None
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dump_folder = comm.bcast(dump_folder, root=0)
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# Get the line of sight sky coordinates.
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pos = get_los(args.catalogue, args.simname, comm)
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def main(nsim):
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interpolate_field(pos, args.simname, nsim, args.MAS, args.grid,
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dump_folder, r, smooth_scales,
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verbose=comm.Get_size() == 1)
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work_delegation(main, nsims, comm, master_verbose=True)
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comm.Barrier()
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if comm.Get_rank() == 0:
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combine_from_simulations(args.catalogue, args.simname, nsims,
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out_folder, dump_folder)
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print("All finished!")
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