mirror of
https://github.com/Richard-Sti/csiborgtools.git
synced 2024-12-23 02:38:02 +00:00
9e4b34f579
* 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
234 lines
7.8 KiB
Python
234 lines
7.8 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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Utility functions for scripts.
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"""
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from datetime import datetime
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import numpy
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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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###############################################################################
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# Reading functions #
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###############################################################################
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def get_nsims(args, paths):
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"""
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Get simulation indices from the command line arguments.
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"""
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if args.nsims is None or args.nsims[0] == -1:
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nsims = paths.get_ics(args.simname)
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else:
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nsims = args.nsims
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return list(nsims)
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def read_single_catalogue(args, config, nsim, run, rmax, paths, nobs=None):
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"""
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Read a single halo catalogue and apply selection criteria to it.
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Parameters
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----------
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args : argparse.Namespace
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Command line arguments. Must include `simname`.
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config : dict
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Configuration dictionary.
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nsim : int
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Simulation index.
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run : str
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Run name.
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rmax : float
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Maximum radial distance of the halo catalogue.
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paths : csiborgtools.paths.Paths
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Paths object.
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nobs : int, optional
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Fiducial Quijote observer index.
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Returns
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-------
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instance of `csiborgtools.read.BaseCatalogue`
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"""
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selection = config.get(run, None)
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if selection is None:
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raise KeyError(f"No configuration for run {run}.")
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# We first read the full catalogue without applying any bounds.
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if args.simname == "csiborg":
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cat = csiborgtools.read.CSiBORGHaloCatalogue(
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nsim, paths, load_fitted=True, load_inital=True,
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with_lagpatch=False)
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else:
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if args.from_quijote_backup:
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load_fitted = False
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load_initial = False
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cat = csiborgtools.read.QuijoteHaloCatalogue(
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nsim, paths, nsnap=4, load_fitted=load_fitted,
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load_initial=load_initial, with_lagpatch=False,
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load_backup=args.from_quijote_backup)
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if nobs is not None:
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# We may optionally already here pick a fiducial observer.
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cat = cat.pick_fiducial_observer(nobs, args.Rmax)
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cat.apply_bounds({"dist": (0, rmax)})
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# We then first read off the primary selection bounds.
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sel = selection["primary"]
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pname = None
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xs = sel["name"] if isinstance(sel["name"], list) else [sel["name"]]
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for _name in xs:
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if _name in cat.keys:
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pname = _name
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if pname is None:
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raise KeyError(f"Invalid names `{sel['name']}`.")
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xmin = sel.get("min", None)
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xmax = sel.get("max", None)
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if sel.get("islog", False):
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xmin = 10**xmin if xmin is not None else None
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xmax = 10**xmax if xmax is not None else None
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cat.apply_bounds({pname: (xmin, xmax)})
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# Now the secondary selection bounds. If needed transfrom the secondary
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# property before applying the bounds.
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if "secondary" in selection:
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sel = selection["secondary"]
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sname = None
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xs = sel["name"] if isinstance(sel["name"], list) else [sel["name"]]
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for _name in xs:
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if _name in cat.keys:
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sname = _name
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if sname is None:
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raise KeyError(f"Invalid names `{sel['name']}`.")
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if sel.get("toperm", False):
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cat[sname] = numpy.random.permutation(cat[sname])
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if sel.get("marked", False):
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cat[sname] = csiborgtools.clustering.normalised_marks(
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cat[pname], cat[sname], nbins=config["nbins_marks"])
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cat.apply_bounds({sname: (sel.get("min", None), sel.get("max", None))})
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return cat
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def open_catalogues(args, config, paths, comm):
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"""
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Read all halo catalogues on the zeroth rank and broadcast them to all
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higher ranks.
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Parameters
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----------
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args : argparse.Namespace
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Command line arguments.
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config : dict
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Configuration dictionary.
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paths : csiborgtools.paths.Paths
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Paths object.
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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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cats : dict
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Dictionary of halo catalogues. Keys are simulation indices, values are
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the catalogues.
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"""
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nsims = get_nsims(args, paths)
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rank = comm.Get_rank()
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nproc = comm.Get_size()
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if args.verbose and rank == 0:
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print(f"{datetime.now()}: opening catalogues.", flush=True)
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# We first load all catalogues on the zeroth rank and broadcast their
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# names.
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if rank == 0:
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cats = {}
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if args.simname == "csiborg":
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for nsim in tqdm(nsims) if args.verbose else nsims:
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cat = read_single_catalogue(args, config, nsim, args.run,
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rmax=args.Rmax, paths=paths)
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cats.update({nsim: cat})
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else:
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for nsim in tqdm(nsims) if args.verbose else nsims:
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ref_cat = read_single_catalogue(args, config, nsim, args.run,
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rmax=None, paths=paths)
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nmax = int(ref_cat.box.boxsize // (2 * args.Rmax))**3
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for nobs in range(nmax):
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name = paths.quijote_fiducial_nsim(nsim, nobs)
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cat = ref_cat.pick_fiducial_observer(nobs, rmax=args.Rmax)
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cats.update({name: cat})
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names = list(cats.keys())
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if nproc > 1:
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for i in range(1, nproc):
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comm.send(names, dest=i, tag=nproc + i)
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else:
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names = comm.recv(source=0, tag=nproc + rank)
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comm.Barrier()
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# We then broadcast the catalogues to all ranks, one-by-one as MPI can
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# only pass messages smaller than 2GB.
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if nproc == 1:
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return cats
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if rank > 0:
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cats = {}
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for name in names:
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if rank == 0:
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for i in range(1, nproc):
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comm.send(cats[name], dest=i, tag=nproc + i)
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else:
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cats.update({name: comm.recv(source=0, tag=nproc + rank)})
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return cats
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###############################################################################
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# Clusters #
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###############################################################################
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_coma = {"RA": (12 + 59 / 60 + 48.7 / 60**2) * 15,
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"DEC": 27 + 58 / 60 + 50 / 60**2,
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"COMDIST": 102.975}
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_virgo = {"RA": (12 + 27 / 60) * 15,
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"DEC": 12 + 43 / 60,
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"COMDIST": 16.5}
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specific_clusters = {"Coma": _coma, "Virgo": _virgo}
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###############################################################################
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# Surveys #
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###############################################################################
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class SDSS:
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@staticmethod
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def steps(cls):
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return [(lambda x: cls[x], ("IN_DR7_LSS",)),
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(lambda x: cls[x] < 17.6, ("ELPETRO_APPMAG_r", )),
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(lambda x: cls[x] < 155, ("DIST", ))
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]
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def __call__(self):
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return csiborgtools.read.SDSS(h=1, sel_steps=self.steps)
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