mirror of
https://github.com/Richard-Sti/csiborgtools.git
synced 2024-12-23 00:58:02 +00:00
1d847cbd06
* Rename paths object * Remove redshift calculation * Explicit keywrod arg * Rename box units * Basic renaming * Little docs * Rename paths * add imports * Sort imports * Add Quijote cat * Split boxes * add Quijote path * Add origin argument * Update nbs
158 lines
5.7 KiB
Python
158 lines
5.7 KiB
Python
# Copyright (C) 2022 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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#
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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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A script to fit halos (concentration, ...). The particle array of each CSiBORG
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realisation must have been split in advance by `runsplit_halos`.
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"""
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from argparse import ArgumentParser
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from datetime import datetime
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import numpy
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from mpi4py import MPI
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from tqdm import tqdm
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try:
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import csiborgtools
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except ModuleNotFoundError:
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import sys
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sys.path.append("../")
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import csiborgtools
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# Get MPI things
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comm = MPI.COMM_WORLD
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rank = comm.Get_rank()
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nproc = comm.Get_size()
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verbose = nproc == 1
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parser = ArgumentParser()
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parser.add_argument("--kind", type=str, choices=["halos", "clumps"])
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parser.add_argument("--ics", type=int, nargs="+", default=None,
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help="IC realisations. If `-1` processes all simulations.")
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args = parser.parse_args()
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paths = csiborgtools.read.Paths(**csiborgtools.paths_glamdring)
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partreader = csiborgtools.read.ParticleReader(paths)
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nfwpost = csiborgtools.fits.NFWPosterior()
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if args.ics is None or args.ics[0] == -1:
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ics = paths.get_ics()
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else:
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ics = args.ics
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cols_collect = [
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("index", numpy.int32),
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("npart", numpy.int32),
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("totpartmass", numpy.float32),
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("vx", numpy.float32),
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("vy", numpy.float32),
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("vz", numpy.float32),
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("conc", numpy.float32),
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("rho0", numpy.float32),
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("r200c", numpy.float32),
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("r500c", numpy.float32),
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("m200c", numpy.float32),
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("m500c", numpy.float32),
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("lambda200c", numpy.float32),
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("r200m", numpy.float32),
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("m200m", numpy.float32),
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]
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def fit_clump(particles, clump_info, box):
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"""
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Fit an object. Can be eithe a clump or a parent halo.
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"""
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obj = csiborgtools.fits.Clump(particles, clump_info, box)
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out = {}
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out["npart"] = len(obj)
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out["totpartmass"] = numpy.sum(obj["M"])
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for i, v in enumerate(["vx", "vy", "vz"]):
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out[v] = numpy.average(obj.vel[:, i], weights=obj["M"])
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# Overdensity masses
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out["r200c"], out["m200c"] = obj.spherical_overdensity_mass(200,
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kind="crit")
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out["r500c"], out["m500c"] = obj.spherical_overdensity_mass(500,
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kind="crit")
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out["r200m"], out["m200m"] = obj.spherical_overdensity_mass(200,
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kind="matter")
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# NFW fit
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if out["npart"] > 10 and numpy.isfinite(out["r200c"]):
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Rs, rho0 = nfwpost.fit(obj)
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out["conc"] = Rs / out["r200c"]
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out["rho0"] = rho0
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# Spin within R200c
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if numpy.isfinite(out["r200c"]):
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out["lambda200c"] = obj.lambda_bullock(out["r200c"])
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return out
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# We MPI loop over all simulations.
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jobs = csiborgtools.fits.split_jobs(len(ics), nproc)[rank]
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for nsim in [ics[i] for i in jobs]:
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print(f"{datetime.now()}: rank {rank} calculating simulation `{nsim}`.",
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flush=True)
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nsnap = max(paths.get_snapshots(nsim))
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box = csiborgtools.read.CSiBORGBox(nsnap, nsim, paths)
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# Particle archive
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f = csiborgtools.read.read_h5(paths.particles_path(nsim))
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particles = f["particles"]
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clump_map = f["clumpmap"]
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clid2map = {clid: i for i, clid in enumerate(clump_map[:, 0])}
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clumps_cat = csiborgtools.read.ClumpsCatalogue(nsim, paths, rawdata=True,
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load_fitted=False)
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# We check whether we fit halos or clumps, will be indexing over different
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# iterators.
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if args.kind == "halos":
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ismain = clumps_cat.ismain
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else:
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ismain = numpy.ones(len(clumps_cat), dtype=bool)
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# Even if we are calculating parent halo this index runs over all clumps.
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out = csiborgtools.read.cols_to_structured(len(clumps_cat), cols_collect)
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indxs = clumps_cat["index"]
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for i, clid in enumerate(tqdm(indxs)) if verbose else enumerate(indxs):
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clid = clumps_cat["index"][i]
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out["index"][i] = clid
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# If we are fitting halos and this clump is not a main, then continue.
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if args.kind == "halos" and not ismain[i]:
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continue
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if args.kind == "halos":
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part = csiborgtools.read.load_parent_particles(
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clid, particles, clump_map, clid2map, clumps_cat)
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else:
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part = csiborgtools.read.load_clump_particles(clid, particles,
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clump_map, clid2map)
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# We fit the particles if there are any. If not we assign the index,
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# otherwise it would be NaN converted to integers (-2147483648) and
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# yield an error further down.
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if part is None:
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continue
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_out = fit_clump(part, clumps_cat[i], box)
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for key in _out.keys():
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out[key][i] = _out[key]
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# Finally, we save the results. If we were analysing main halos, then
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# remove array indices that do not correspond to parent halos.
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if args.kind == "halos":
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out = out[ismain]
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fout = paths.structfit_path(nsnap, nsim, args.kind)
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print(f"Saving to `{fout}`.", flush=True)
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numpy.save(fout, out)
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