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# Copyright (c) 2017-2018 Weitian LI <weitian@aaronly.me>
# MIT license
"""
Press-Schechter (PS) formalism
First determine the number of clusters within a sky patch (i.e., sky
coverage) according to the cluster distribution predicted by the PS
formalism; then sampling from the mass function to derive the mass
and redshift for each cluster.
"""
import logging
import random
from functools import lru_cache
import numpy as np
import hmf
from ...share import CONFIGS, COSMO
from ...utils.units import UnitConversions as AUC
from ...utils.io import write_dndlnm
logger = logging.getLogger(__name__)
class PSFormalism:
"""
Press-Schechter (PS) formalism
Calculate the mass distribution with respect to mass and redshift,
determine the clusters number counts and generate their distribution
(mass and z) within a sky patch of certain coverage.
"""
def __init__(self, configs=CONFIGS):
self.configs = configs
self._set_configs()
def _set_configs(self):
"""
Load the required configurations and set them.
"""
comp = "extragalactic/psformalism"
self.model = self.configs.getn(comp+"/model")
self.M_min = self.configs.getn(comp+"/M_min")
self.M_max = self.configs.getn(comp+"/M_max")
self.M_step = self.configs.getn(comp+"/M_step")
self.z_min = self.configs.getn(comp+"/z_min")
self.z_max = self.configs.getn(comp+"/z_max")
self.z_step = self.configs.getn(comp+"/z_step")
self.dndlnm_outfile = self.configs.get_path(comp+"/dndlnm_outfile")
comp = "extragalactic/clusters"
self.Mmin = self.configs.getn(comp+"/mass_min") # [Msun]
self.boost = self.configs.getn(comp+"/boost")
self.clobber = self.configs.getn("output/clobber")
@property
def hmf_model(self):
return {"PS": "PS",
"SMT": "SMT",
"JENKINS": "Jenkins"}[self.model.upper()]
def hmf_massfunc(self, z=0.0):
"""
Halo mass function as a `~hmf.MassFunction` instance.
"""
if not hasattr(self, "_hmf_massfunc"):
h = COSMO.h
cosmo = COSMO._cosmo
self._hmf_massfunc = hmf.MassFunction(
Mmin=np.log10(self.M_min*h),
Mmax=np.log10(self.M_max*h),
dlog10m=self.M_step,
hmf_model=self.hmf_model,
cosmo_model=cosmo,
n=COSMO.ns,
sigma_8=COSMO.sigma8)
logger.info("Initialized '%s' halo mass function." %
self.hmf_model)
massfunc = self._hmf_massfunc
massfunc.update(z=z)
return massfunc
@property
@lru_cache()
def z(self):
"""
The redshift points where to calculate the dndlnm data.
"""
return np.arange(self.z_min, self.z_max+self.z_step/2, self.z_step)
@property
@lru_cache()
def mass(self):
"""
The mass points where to calculate the dndlnm data.
NOTE:
The maximum mass end is exclusive, to be consistent with hmf's
mass function!
"""
return 10 ** np.arange(np.log10(self.M_min),
np.log10(self.M_max),
self.M_step)
@property
def dndlnm(self):
"""
The calculated halo mass distributions data.
"""
if not hasattr(self, "_dndlnm"):
self._dndlnm = self.calc_dndlnm()
return self._dndlnm
def calc_dndlnm(self):
"""
Calculate the halo mass distributions expressed in ``dndlnm``,
the differential mass distribution in terms of natural log of
masses.
Unit: [Mpc^-3] (the little "h" is folded into the values)
NOTE
----
dndlnm = d n(M,z) / d ln(M); [Mpc^-3]
describes the number of halos per comoving volume (Mpc^3) at
redshift z per unit logarithmic mass interval at mass M.
"""
logger.info("Calculating dndlnm data ...")
dndlnm = []
h = COSMO.h
for z_ in self.z:
massfunc = self.hmf_massfunc(z_)
dndlnm.append(massfunc.dndlnm * h**3)
self._dndlnm = np.array(dndlnm)
logger.info("Calculated dndlnm within redshift: %.1f - %.1f" %
(self.z_min, self.z_max))
return self._dndlnm
def write(self, outfile=None):
"""
Write the calculate dndlnm data into file as NumPy ".npz" format.
"""
if outfile is None:
outfile = self.dndlnm_outfile
write_dndlnm(outfile, dndlnm=self.dndlnm, z=self.z, mass=self.mass,
clobber=self.clobber)
logger.info("Wrote dndlnm data into file: %s" % outfile)
@staticmethod
def delta(x, logeven=False):
"""
Calculate the delta values for each element of a vector,
assuming they are evenly or log-evenly distributed,
by extrapolating.
"""
x = np.asarray(x)
if logeven:
ratio = x[1] / x[0]
x_left = x[0] / ratio
x_right = x[-1] * ratio
else:
step = x[1] - x[0]
x_left = x[0] - step
x_right = x[-1] + step
x2 = np.concatenate([[x_left], x, [x_right]])
dx = (x2[2:] - x2[:-2]) / 2
return dx
@property
def number_grid(self):
"""
The halo number per unit solid angle [sr] distribution w.r.t.
mass and redshift.
Unit: [/sr]
"""
if not hasattr(self, "_number_grid"):
dz = self.delta(self.z)
dM = self.delta(self.mass, logeven=True)
dlnM = dM / self.mass
dlnMgrid, dzgrid = np.meshgrid(dlnM, dz)
__, zgrid = np.meshgrid(self.mass, self.z)
dVcgrid = COSMO.dVc(zgrid) # [Mpc^3/sr]
self._number_grid = self.dndlnm * dlnMgrid * (dVcgrid*dzgrid)
return self._number_grid
def calc_cluster_counts(self, coverage):
"""
Calculate the total number of clusters (>= minimum mass) within
the FoV coverage according to the halo number density distribution.
Parameters
----------
coverage : float
The coverage of the sky patch within which to determine the
total number of clusters.
Unit: [deg^2]
Returns
-------
counts : int
The total number of clusters within the sky patch.
"""
logger.info("Calculating the total number of clusters within "
"sky patch of coverage %.1f [deg^2]" % coverage)
logger.info("Minimum cluster mass: %.2e [Msun]" % self.Mmin)
coverage *= AUC.deg2rad**2 # [deg^2] -> [rad^2] = [sr]
midx = (self.mass >= self.Mmin)
numgrid = self.number_grid
counts = np.sum(numgrid[:, midx]) * coverage * self.boost
counts = int(np.round(counts))
logger.info("Total number of clusters: %d" % counts)
return counts
def sample_z_m(self, counts):
"""
Randomly generate the requested number of pairs of (z, M) following
the halo number distribution.
NOTE
----
First derive the cluster (M>=Mmin) number distribution w.r.t.
redshifts, from which the redshift for each cluster is sampled
using the acceptance-rejection algorithm. Then for each cluster
at redshift z, the corresponding halo mass distribution is used
to generate the cluster mass using the same algorithm.
NOTE
----
Sampling masses in logarithmic scale improve the speed very
significantly (~30x)!
Parameters
----------
counts : int, optional
The number of (z, mass) pairs to be sampled.
Returns
-------
df : `~pandas.DataFrame`
A Pandas data frame with 2 columns, i.e., ``z`` and ``mass``.
comment : list[str]
Comments to the above data frame.
"""
logger.info("Sampling (z, mass) pairs for %d clusters ..." % counts)
z = self.z
zmin = z.min()
zmax = z.max()
log10mass = np.log10(self.mass)
log10Mmin = np.log10(self.Mmin)
log10Mmax = log10mass.max()
midx = (log10mass >= log10Mmin)
log10mass = log10mass[midx]
Ngrid = self.number_grid[:, midx]
logger.info("Sampling redshifts ...")
z_list = []
zi_list = []
Nzdist = Ngrid.sum(axis=1)
NMax = Nzdist.max()
i = 0
while i < counts:
zc = random.uniform(zmin, zmax)
zi = (z < zc).sum()
Nzc = Nzdist[zi]
r = random.random()
if r < Nzc/NMax:
z_list.append(zc)
zi_list.append(zi)
i += 1
logger.info("Sampling masses ...")
mass_list = []
NMax_list = Ngrid.max(axis=1)
i = 0
while i < counts:
zi = zi_list[i]
NMax = NMax_list[zi]
Nmassdist = Ngrid[zi, :]
log10Mc = random.uniform(log10Mmin, log10Mmax)
Mi = (log10mass < log10Mc).sum()
NMc = Nmassdist[Mi]
r = random.random()
if r < NMc/NMax:
mass_list.append(10**log10Mc)
i += 1
logger.info("Sampled %d pairs of (z, mass) for each cluster" % counts)
z = np.array(z_list)
mass = np.array(mass_list)
comment = [
"halo mass function model: %s" % self.hmf_model,
"cluster minimum mass: %.2e [Msun]" % self.Mmin,
"cluster counts: %d" % counts,
"boost factor for cluster counts: %s" % self.boost,
]
return (z, mass, comment)
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