csiborgtools/scripts/match_overlap_single.py
Richard Stiskalek 9e4b34f579
Overlap fixing and more (#107)
* Update README

* Update density field reader

* Update name of SDSSxALFAFA

* Fix quick bug

* Add little fixes

* Update README

* Put back fit_init

* Add paths to initial snapshots

* Add export

* Remove some choices

* Edit README

* Add Jens' comments

* Organize imports

* Rename snapshot

* Add additional print statement

* Add paths to initial snapshots

* Add masses to the initial files

* Add normalization

* Edit README

* Update README

* Fix bug in CSiBORG1 so that does not read fof_00001

* Edit README

* Edit README

* Overwrite comments

* Add paths to init lag

* Fix Quijote path

* Add lagpatch

* Edit submits

* Update README

* Fix numpy int problem

* Update README

* Add a flag to keep the snapshots open when fitting

* Add a flag to keep snapshots open

* Comment out some path issue

* Keep snapshots open

* Access directly snasphot

* Add lagpatch for CSiBORG2

* Add treatment of x-z coordinates flipping

* Add radial velocity field loader

* Update README

* Add lagpatch to Quijote

* Fix typo

* Add setter

* Fix typo

* Update README

* Add output halo cat as ASCII

* Add import

* Add halo plot

* Update README

* Add evaluating field at radial distanfe

* Add field shell evaluation

* Add enclosed mass computation

* Add BORG2 import

* Add BORG boxsize

* Add BORG paths

* Edit run

* Add BORG2 overdensity field

* Add bulk flow clauclation

* Update README

* Add new plots

* Add nbs

* Edit paper

* Update plotting

* Fix overlap paths to contain simname

* Add normalization of positions

* Add default paths to CSiBORG1

* Add overlap path simname

* Fix little things

* Add CSiBORG2 catalogue

* Update README

* Add import

* Add TNG density field constructor

* Add TNG density

* Add draft of calculating BORG ACL

* Fix bug

* Add ACL of enclosed density

* Add nmean acl

* Add galaxy bias calculation

* Add BORG acl notebook

* Add enclosed mass calculation

* Add TNG300-1 dir

* Add TNG300 and BORG1 dir

* Update nb
2024-01-30 16:14:07 +00:00

218 lines
8.5 KiB
Python

# This program is free software; you can redistribute it and/or modify it
# under the terms of the GNU 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 General Public License along
# with this program; if not, write to the Free Software Foundation, Inc.,
# 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
"""
A script to calculate overlap between two IC realisations of the same
simulation.
"""
from argparse import ArgumentParser
from copy import deepcopy
from datetime import datetime
from distutils.util import strtobool
import numpy
from scipy.ndimage import gaussian_filter
import csiborgtools
def pair_match_max(nsim0, nsimx, simname, min_logmass, mult, verbose):
"""
Match a pair of simulations using the Max method.
Parameters
----------
nsim0, nsimx : int
The reference and cross simulation IC index.
simname : str
Simulation name.
min_logmass : float
Minimum log halo mass.
mult : float
Multiplicative factor for search radius.
verbose : bool
Verbosity flag.
"""
if simname == "csiborg1":
maxdist = 155
periodic = False
bounds = {"dist": (0, maxdist), "totmass": (10**min_logmass, None)}
cat0 = csiborgtools.read.CSiBORG1Catalogue(nsim0, bounds=bounds)
catx = csiborgtools.read.CSiBORG1Catalogue(nsimx, bounds=bounds)
elif "csiborg2" in simname:
raise RuntimeError("CSiBORG2 currently not implemented..")
elif simname == "quijote":
maxdist = None
periodic = True
bounds = {"totmass": (10**min_logmass, None)}
cat0 = csiborgtools.read.QuijoteCatalogue(nsim0, bounds=bounds)
catx = csiborgtools.read.QuijoteHaloCatalogue(nsimx, bounds=bounds)
else:
raise ValueError(f"Unknown simulation `{simname}`.")
reader = csiborgtools.summary.PairOverlap(cat0, catx, min_logmass, maxdist)
out = csiborgtools.match.matching_max(
cat0, catx, "totmass", mult=mult, periodic=periodic,
overlap=reader.overlap(from_smoothed=True),
match_indxs=reader["match_indxs"], verbose=verbose)
fout = cat0.paths.match_max(simname, nsim0, nsimx, min_logmass, mult)
if verbose:
print(f"{datetime.now()}: saving to ... `{fout}`.", flush=True)
numpy.savez(fout, **{p: out[p] for p in out.dtype.names})
def pair_match(nsim0, nsimx, simname, min_logmass, sigma, verbose):
"""
Calculate overlaps between two simulations.
Parameters
----------
nsim0 : int
The reference simulation IC index.
nsimx : int
The cross simulation IC index.
simname : str
Simulation name.
min_logmass : float
Minimum log halo mass.
sigma : float
Smoothing scale in number of grid cells.
verbose : bool
Verbosity flag.
Returns
-------
None
"""
paths = csiborgtools.read.Paths(**csiborgtools.paths_glamdring)
smooth_kwargs = {"sigma": sigma, "mode": "constant", "cval": 0}
bounds = {"lagpatch_radius": (0, None)}
if simname == "csiborg1":
overlapper_kwargs = {"box_size": 2048, "bckg_halfsize": 512}
bounds |= {"dist": (0, 135), "totmass": (10**min_logmass, None)}
# Reference simulation.
snap0 = csiborgtools.read.CSiBORG1Snapshot(
nsim0, 1, keep_snapshot_open=True)
cat0 = csiborgtools.read.CSiBORG1Catalogue(
nsim0, snapshot=snap0, bounds=bounds)
# Cross simulation.
snapx = csiborgtools.read.CSiBORG1Snapshot(
nsimx, 1, keep_snapshot_open=True)
catx = csiborgtools.read.CSiBORG1Catalogue(
nsimx, snapshot=snapx, bounds=bounds)
elif "csiborg2" in simname:
kind = simname.split("_")[-1]
overlapper_kwargs = {"box_size": 2048, "bckg_halfsize": 512}
bounds |= {"dist": (0, 135), "totmass": (10**min_logmass, None)}
# Reference simulation.
snap0 = csiborgtools.read.CSiBORG2Snapshot(
nsim0, 99, kind, keep_snapshot_open=True)
cat0 = csiborgtools.read.CSiBORG2Catalogue(
nsim0, 99, kind, snapshot=snap0, bounds=bounds)
# Cross simulation.
snapx = csiborgtools.read.CSiBORG2Snapshot(
nsimx, 99, kind, keep_snapshot_open=True)
catx = csiborgtools.read.CSiBORG2Catalogue(
nsimx, 99, kind, snapshot=snapx, bounds=bounds)
elif simname == "quijote":
overlapper_kwargs = {"box_size": 512, "bckg_halfsize": 256}
bounds |= {"totmass": (10**min_logmass, None)}
# Reference simulation.
snap0 = csiborgtools.read.QuijoteSnapshot(
nsim0, "ICs", keep_snapshot_open=True)
cat0 = csiborgtools.read.QuijoteCatalogue(
nsim0, snapshot=snap0, bounds=bounds)
# Cross simulation.
snapx = csiborgtools.read.QuijoteSnapshot(
nsimx, "ICs", keep_snapshot_open=True)
catx = csiborgtools.read.QuijoteCatalogue(
nsimx, snapshot=snapx, bounds=bounds)
else:
raise ValueError(f"Unknown simulation name: `{simname}`.")
overlapper = csiborgtools.match.ParticleOverlap(**overlapper_kwargs)
delta_bckg = overlapper.make_bckg_delta(cat0, verbose=verbose)
delta_bckg = overlapper.make_bckg_delta(catx, delta=delta_bckg,
verbose=verbose)
matcher = csiborgtools.match.RealisationsMatcher(**overlapper_kwargs)
match_indxs, ngp_overlap = matcher.cross(cat0, catx, delta_bckg,
verbose=verbose)
# We want to store the halo IDs of the matches, not their array positions
# in the catalogues.
match_hids = deepcopy(match_indxs)
for i, matches in enumerate(match_indxs):
for j, match in enumerate(matches):
match_hids[i][j] = catx["index"][match]
fout = paths.overlap(simname, nsim0, nsimx, min_logmass, smoothed=False)
if verbose:
print(f"{datetime.now()}: saving to ... `{fout}`.", flush=True)
numpy.savez(fout, ref_hids=cat0["index"], match_hids=match_hids,
ngp_overlap=ngp_overlap)
if not sigma > 0:
return
if verbose:
print(f"{datetime.now()}: smoothing the background field.", flush=True)
gaussian_filter(delta_bckg, output=delta_bckg, **smooth_kwargs)
# We calculate the smoothed overlap for the pairs whose NGP overlap is > 0.
smoothed_overlap = matcher.smoothed_cross(cat0, catx, delta_bckg,
match_indxs, smooth_kwargs,
verbose=verbose)
fout = paths.overlap(simname, nsim0, nsimx, min_logmass, smoothed=True)
if verbose:
print(f"{datetime.now()}: saving to ... `{fout}`.", flush=True)
numpy.savez(fout, smoothed_overlap=smoothed_overlap, sigma=sigma)
if __name__ == "__main__":
parser = ArgumentParser()
parser.add_argument("--kind", type=str, required=True,
choices=["overlap", "max"], help="Kind of matching.")
parser.add_argument("--nsim0", type=int, required=True,
help="Reference simulation IC index.")
parser.add_argument("--nsimx", type=int, required=True,
help="Cross simulation IC index.")
parser.add_argument("--simname", type=str, required=True,
help="Simulation name.")
parser.add_argument("--min_logmass", type=float, required=True,
help="Minimum log halo mass.")
parser.add_argument("--mult", type=float, default=5,
help="Search radius multiplier for Max's method.")
parser.add_argument("--sigma", type=float, default=0,
help="Smoothing scale in number of grid cells.")
parser.add_argument("--verbose", type=lambda x: bool(strtobool(x)),
default=False, help="Verbosity flag.")
args = parser.parse_args()
if args.kind == "overlap":
pair_match(args.nsim0, args.nsimx, args.simname, args.min_logmass,
args.sigma, args.verbose)
elif args.kind == "max":
pair_match_max(args.nsim0, args.nsimx, args.simname, args.min_logmass,
args.mult, args.verbose)
else:
raise ValueError(f"Unknown matching kind: `{args.kind}`.")