mirror of
https://github.com/Richard-Sti/csiborgtools.git
synced 2024-12-23 08:48:02 +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
299 lines
12 KiB
Python
299 lines
12 KiB
Python
# Copyright (C) 2023 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 calculate the enclosed mass or bulk flow at different distances
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from the center of the box directly from the particles. Note that the velocity
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of an observer is not being subtracted from the bulk flow.
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The script is not parallelized in any way but it should not take very long, the
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main bottleneck is reading the data from disk.
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"""
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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.path import join
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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 CartesianRepresentation, SkyCoord
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from tqdm import tqdm
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import csiborgtools
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from csiborgtools import fprint
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from csiborgtools.field import (field_enclosed_mass, particles_enclosed_mass,
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particles_enclosed_momentum)
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###############################################################################
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# Read in information about the simulation #
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###############################################################################
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def t():
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return datetime.now()
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def get_reader(simname, paths, nsim):
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"""Get the appropriate snapshot reader for the simulation."""
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if simname == "csiborg1":
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nsnap = max(paths.get_snapshots(nsim, simname))
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reader = csiborgtools.read.CSiBORG1Snapshot(nsim, nsnap, paths,
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flip_xz=True)
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elif "csiborg2" in simname:
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kind = simname.split("_")[-1]
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reader = csiborgtools.read.CSiBORG2Snapshot(nsim, 99, kind, paths,
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flip_xz=True)
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elif simname == "manticore_2MPP_N128_DES_V1":
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reader = csiborgtools.read.CSiBORG2XSnapshot(nsim)
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else:
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raise ValueError(f"Unknown simname: `{simname}`.")
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return reader
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def get_particles(reader, boxsize, get_velocity=True, verbose=True):
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"""Get the snapshot particles."""
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fprint("reading coordinates and calculating radial distance.", verbose)
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pos = reader.coordinates()
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dtype = pos.dtype
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pos -= boxsize / 2
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dist = np.linalg.norm(pos, axis=1).astype(dtype)
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collect()
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if get_velocity:
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fprint("reading velocities.", verbose)
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vel = reader.velocities().astype(dtype)
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vrad = np.sum(pos * vel, axis=1) / dist
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del pos
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collect()
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fprint("reading masses.")
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mass = reader.masses()
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fprint("sorting arrays.")
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indxs = np.argsort(dist)
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dist = dist[indxs]
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mass = mass[indxs]
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if get_velocity:
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vel = vel[indxs]
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del indxs
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collect()
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if get_velocity:
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return dist, mass, vel, vrad
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return dist, mass
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###############################################################################
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# Main #
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###############################################################################
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def main_borg(args, folder):
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paths = csiborgtools.read.Paths(**csiborgtools.paths_glamdring)
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boxsize = csiborgtools.simname2boxsize(args.simname)
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nsims = paths.get_ics(args.simname)
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distances = np.linspace(0, boxsize / 2, 101)
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cumulative_mass = np.zeros((len(nsims), len(distances)))
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cumulative_volume = np.zeros((len(nsims), len(distances)))
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for i, nsim in enumerate(tqdm(nsims, desc="Simulations")):
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if args.simname == "borg1":
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reader = csiborgtools.read.BORG1Field(nsim)
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field = reader.density_field()
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elif args.simname == "borg2" or args.simname == "borg2_all":
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reader = csiborgtools.read.BORG2Field(nsim)
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field = reader.density_field()
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else:
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raise ValueError(f"Unknown simname: `{args.simname}`.")
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cumulative_mass[i, :], cumulative_volume[i, :] = field_enclosed_mass(
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field, distances, boxsize)
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# Finally save the output
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fname = f"enclosed_mass_{args.simname}.npz"
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fname = join(folder, fname)
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np.savez(fname, enclosed_mass=cumulative_mass, distances=distances,
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enclosed_volume=cumulative_volume)
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def main_csiborg(args, folder):
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paths = csiborgtools.read.Paths(**csiborgtools.paths_glamdring)
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boxsize = csiborgtools.simname2boxsize(args.simname)
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nsims = paths.get_ics(args.simname)
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distances = np.linspace(0, boxsize / 2, 501)[1:]
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# Initialize arrays to store the results
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cumulative_mass = np.zeros((len(nsims), len(distances)))
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mass135 = np.zeros(len(nsims))
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masstot = np.zeros(len(nsims))
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cumulative_vel_mono = np.zeros((len(nsims), len(distances)))
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cumulative_velocity = np.zeros((len(nsims), len(distances), 3))
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for i, nsim in enumerate(tqdm(nsims, desc="Simulations")):
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reader = get_reader(args.simname, paths, nsim)
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rdist, mass, vel, vrad = get_particles(reader, boxsize, verbose=True)
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# Calculate masses
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cumulative_mass[i, :] = particles_enclosed_mass(rdist, mass, distances)
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mass135[i] = particles_enclosed_mass(rdist, mass, [135])[0]
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masstot[i] = np.sum(mass)
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# Calculate monopole momentum
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cumulative_vel_mono[i] = particles_enclosed_mass(
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rdist, vrad * mass, distances)
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# Calculate velocities
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cumulative_velocity[i, ...] = particles_enclosed_momentum(
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rdist, mass, vel, distances)
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# Normalize the momentum to get velocity out of it.
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for j in range(3):
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cumulative_velocity[i, :, j] /= cumulative_mass[i, :]
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cumulative_vel_mono[i, ...] /= cumulative_mass[i, ...]
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# Finally save the output
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fname = f"enclosed_mass_{args.simname}.npz"
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fname = join(folder, fname)
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np.savez(fname, enclosed_mass=cumulative_mass, mass135=mass135,
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masstot=masstot, distances=distances,
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cumulative_velocity=cumulative_velocity,
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cumulative_velocity_mono=cumulative_vel_mono)
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def main_from_field(args, folder):
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"""Bulk flows in 3D fields"""
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paths = csiborgtools.read.Paths(**csiborgtools.paths_glamdring)
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boxsize = csiborgtools.simname2boxsize(args.simname)
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nsims = paths.get_ics(args.simname)
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distances = np.linspace(0, boxsize / 2, 101)[1:]
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cumulative_mass = np.zeros((len(nsims), len(distances)))
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cumulative_volume = np.zeros((len(nsims), len(distances)))
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cumulative_vel_mono = np.zeros((len(nsims), len(distances)))
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cumulative_vel_x = np.zeros((len(nsims), len(distances)))
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cumulative_vel_y = np.zeros_like(cumulative_vel_x)
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cumulative_vel_z = np.zeros_like(cumulative_vel_x)
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for i, nsim in enumerate(tqdm(nsims, desc="Simulations")):
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if args.simname == "csiborg2X":
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reader = csiborgtools.read.CSiBORG2XField(nsim, paths)
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kwargs = {}
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elif args.simname == "CF4":
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reader = csiborgtools.read.CF4Field(nsim, paths)
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kwargs = {}
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elif args.simname == "CLONES":
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reader = csiborgtools.read.CLONESField(nsim, paths)
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kwargs = {"MAS": "SPH", "grid": 1024}
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elif args.simname == "Carrick2015":
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reader = csiborgtools.read.Carrick2015Field(paths)
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kwargs = {}
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elif args.simname == "Lilow2024":
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reader = csiborgtools.read.Lilow2024Field(paths)
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kwargs = {}
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else:
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raise ValueError(f"Unknown simname: `{args.simname}`.")
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density_field = reader.density_field(**kwargs)
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cumulative_mass[i, :], cumulative_volume[i, :] = field_enclosed_mass(
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density_field, distances, boxsize, verbose=False)
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del density_field
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collect()
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velocity_field = reader.velocity_field(**kwargs)
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radial_velocity_field = csiborgtools.field.radial_velocity(
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velocity_field, [0., 0., 0.])
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cumulative_vel_mono[i, :], __ = field_enclosed_mass(
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radial_velocity_field, distances, boxsize, verbose=False)
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del radial_velocity_field
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collect()
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cumulative_vel_x[i, :], __ = field_enclosed_mass(
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velocity_field[0], distances, boxsize, verbose=False)
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cumulative_vel_y[i, :], __ = field_enclosed_mass(
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velocity_field[1], distances, boxsize, verbose=False)
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cumulative_vel_z[i, :], __ = field_enclosed_mass(
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velocity_field[2], distances, boxsize, verbose=False)
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del velocity_field
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collect()
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if args.simname in ["Carrick2015", "Lilow2024"]:
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# Carrick+2015 and Lilow+2024 box is in galactic coordinates, so we
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# need to convert the bulk flow vector to RA/dec Cartesian
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# representation.
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galactic_cartesian = CartesianRepresentation(
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cumulative_vel_x, cumulative_vel_y, cumulative_vel_z,
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unit=u.km/u.s)
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galactic_coord = SkyCoord(galactic_cartesian, frame='galactic')
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icrs_cartesian = galactic_coord.icrs.cartesian
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cumulative_vel_x = icrs_cartesian.x.to(u.km/u.s).value
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cumulative_vel_y = icrs_cartesian.y.to(u.km/u.s).value
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cumulative_vel_z = icrs_cartesian.z.to(u.km/u.s).value
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if args.simname in ["CLONES", "CF4"]:
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# CLONES is in supergalactic coordinates.
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supergalactic_cartesian = CartesianRepresentation(
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cumulative_vel_x, cumulative_vel_y, cumulative_vel_z,
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unit=u.km/u.s)
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supergalactic_coord = SkyCoord(
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supergalactic_cartesian, frame='supergalactic')
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icrs_cartesian = supergalactic_coord.icrs.cartesian
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cumulative_vel_x = icrs_cartesian.x.to(u.km/u.s).value
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cumulative_vel_y = icrs_cartesian.y.to(u.km/u.s).value
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cumulative_vel_z = icrs_cartesian.z.to(u.km/u.s).value
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cumulative_vel = np.stack(
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[cumulative_vel_x, cumulative_vel_y, cumulative_vel_z], axis=-1)
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cumulative_vel /= cumulative_volume[..., None]
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cumulative_vel_mono /= cumulative_volume
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# Finally save the output
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fname = f"enclosed_mass_{args.simname}.npz"
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fname = join(folder, fname)
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print(f"Saving to `{fname}`.")
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np.savez(fname, enclosed_mass=cumulative_mass, distances=distances,
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cumulative_velocity_mono=cumulative_vel_mono,
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cumulative_velocity=cumulative_vel,
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enclosed_volume=cumulative_volume)
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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("--simname", type=str, help="Simulation name.",
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choices=["csiborg1", "csiborg2_main", "csiborg2_varysmall", "csiborg2_random", # noqa
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"borg1", "borg2", "borg2_all", "csiborg2X", "Carrick2015", # noqa
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"Lilow2024", "CLONES", "CF4", "manticore_2MPP_N128_DES_V1"]) # noqa
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args = parser.parse_args()
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folder = "/mnt/extraspace/rstiskalek/csiborg_postprocessing/field_shells"
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if args.simname in ["csiborg2X", "Carrick2015", "Lilow2024",
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"CLONES", "CF4"]:
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main_from_field(args, folder)
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elif "csiborg" in args.simname or args.simname == "manticore_2MPP_N128_DES_V1": # noqa
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main_csiborg(args, folder)
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elif "borg" in args.simname:
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main_borg(args, folder)
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else:
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raise ValueError(f"Unknown simname: `{args.simname}`.")
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