def test_pySpec(pt, space):
# read test data
fbox = h5py.File(os.path.join(dat_dir(), 'test_box.hdf5'), 'r')
xyz = fbox['xyz'][...]
vxyz = fbox['vxyz'][...]
Lbox = 2600. # box size
Ngrid = 360 # fft grid size
if space == 'rsd':
xyz_s = pySpec.applyRSD(xyz.T, vxyz.T, 0.5, h=0.7, omega0_m=0.3, LOS='z', Lbox=Lbox)
if pt == 2: # 2pt (power spectrum)
if space == 'real':
spec = pySpec.Pk_periodic(xyz.T, Lbox=Lbox, Ngrid=Ngrid, silent=False)
elif space == 'rsd':
spec = pySpec.Pk_periodic(xyz_s, Lbox=Lbox, Ngrid=Ngrid, silent=False)
assert spec['p0k'].mean() > 0.
elif pt == 3: # 3pt (bispectrum)
if space == 'real':
spec = pySpec.Bk_periodic(xyz.T, Lbox=Lbox, Ngrid=Ngrid, silent=False)
elif space == 'rsd':
spec = pySpec.Bk_periodic(xyz_s, Lbox=Lbox, Ngrid=Ngrid, silent=False)
print(spec['p0k1'])
print(spec['counts'])
print(spec['b123'])
assert spec['b123'].mean() > 0.
def egBk():
''' calculate example Bk
'''
Lbox = 2600. # box size
Ngrid = 360 # fft grid size
fnbox = h5py.File(os.path.join(UT.dat_dir(), 'BoxN1.hdf5'), 'r')
xyz = fnbox['xyz'].value
vxyz = fnbox['vxyz'].value
xyz_s = pySpec.applyRSD(xyz.T, vxyz.T, 0.5, h=0.7, omega0_m=0.3, LOS='z', Lbox=2600.)
bisp = pySpec.Bk_periodic(xyz_s, Lbox=Lbox, Ngrid=Ngrid, step=3, Ncut=3, Nmax=40, fft='pyfftw')
pickle.dump(bisp, open(os.path.join(UT.dat_dir(), 'egBk.p'), 'wb'))
return None
def QPMspectra(rsd=False):
''' calculate the powerspectrum and bispectrum of the QPM
catalog.
:param rsd: (default: False)
if True calculate in redshift space. Otherwise, real-space
'''
str_rsd = ''
if rsd: str_rsd = '.rsd'
f_halo = ''.join([dir_dat, 'halo_ascii.dat'])
f_hdf5 = ''.join([dir_dat, 'halo.mlim1e13.Lbox1050.hdf5'])
f_pell = ''.join([
dir_dat, 'pySpec.Plk.halo.mlim1e13.Lbox1050', '.Ngrid360', str_rsd,
'.dat'
])
f_pnkt = ''.join([
dir_dat, 'pySpec.Plk.halo.mlim1e13.Lbox1050', '.Ngrid360', '.nbodykit',
str_rsd, '.dat'
])
f_b123 = ''.join([
dir_dat, 'pySpec.B123.halo.mlim1e13.Lbox1050', '.Ngrid360', '.Nmax40',
'.Ncut3', '.step3', '.pyfftw', str_rsd, '.dat'
])
Lbox = 1050.
kf = 2. * np.pi / Lbox
# 1. read in ascii file
# 2. impose 10^13 halo mass limit
# 3. calculate RSD positions
# 4. write to hdf5 file
if not os.path.isfile(f_hdf5):
mh, x, y, z, vx, vy, vz = np.loadtxt(f_halo,
unpack=True,
skiprows=1,
usecols=[0, 1, 2, 3, 4, 5, 6])
xyz = np.zeros((len(x), 3))
xyz[:, 0] = x
xyz[:, 1] = y
xyz[:, 2] = z
vxyz = np.zeros((len(x), 3))
vxyz[:, 0] = vx
vxyz[:, 1] = vy
vxyz[:, 2] = vz
# RSD along the z axis
xyz_s = pySpec.applyRSD(xyz.T,
vxyz.T,
0.55,
h=0.7,
omega0_m=0.340563,
LOS='z',
Lbox=Lbox)
mlim = (mh > 1e13)
mh = mh[mlim]
xyz = xyz[mlim, :]
vxyz = vxyz[mlim, :]
xyz_s = xyz_s.T[mlim, :]
f = h5py.File(f_hdf5, 'w')
f.create_dataset('xyz', data=xyz)
f.create_dataset('vxyz', data=vxyz)
f.create_dataset('xyz_s', data=xyz_s)
f.create_dataset('mhalo', data=mh)
f.close()
else:
f = h5py.File(f_hdf5, 'r')
xyz = f['xyz'].value
xyz_s = f['xyz_s'].value
vxyz = f['vxyz'].value
mh = f['mhalo'].value
Nhalo = xyz.shape[0]
print('# halos = %i in %.1f box' % (Nhalo, Lbox))
nhalo = float(Nhalo) / Lbox**3
print('number density = %f' % nhalo)
print('1/nbar = %f' % (1. / nhalo))
# calculate powerspectrum
if not os.path.isfile(f_pell):
# calculate powerspectrum monopole
if not rsd:
spec = pySpec.Pk_periodic(xyz.T,
Lbox=Lbox,
Ngrid=360,
silent=False)
else:
spec = pySpec.Pk_periodic(xyz_s.T,
Lbox=Lbox,
Ngrid=360,
silent=False)
k = spec['k']
p0k = spec['p0k']
cnts = spec['counts']
# save to file
hdr = (
'pyspectrum P_l=0(k) calculation. Lbox=%.1f, k_f=%.5e, SN=%.5e' %
(Lbox, kf, 1. / nhalo))
np.savetxt(f_pell,
np.array([k, p0k, cnts]).T,
fmt='%.5e %.5e %.5e',
delimiter='\t',
header=hdr)
else:
k, p0k, cnts = np.loadtxt(f_pell,
skiprows=1,
unpack=True,
usecols=[0, 1, 2])
# calculate P(k) using nbodykit for santiy check
if not os.path.isfile(f_pnkt):
# get cosmology from header
Omega_m = 0.3175
Omega_b = 0.049 # fixed baryon
h = 0.6711
cosmo = NBlab.cosmology.Planck15.clone(Omega_cdm=Omega_m - Omega_b,
h=h,
Omega_b=Omega_b)
halo_data = {}
if not rsd: halo_data['Position'] = xyz
else: halo_data['Position'] = xyz_s
halo_data['Velocity'] = vxyz
halo_data['Mass'] = mh
print("putting it into array catalog")
halos = NBlab.ArrayCatalog(halo_data,
BoxSize=np.array([Lbox, Lbox, Lbox]))
print("putting it into halo catalog")
halos = NBlab.HaloCatalog(halos, cosmo=cosmo, redshift=0., mdef='vir')
print("putting it into mesh")
mesh = halos.to_mesh(window='tsc',
Nmesh=360,
compensated=True,
position='Position')
print("calculating powerspectrum")
r = NBlab.FFTPower(mesh, mode='1d', dk=kf, kmin=kf, poles=[0, 2, 4])
poles = r.poles
plk = {'k': poles['k']}
for ell in [0, 2, 4]:
P = (poles['power_%d' % ell].real)
if ell == 0:
P = P - poles.attrs[
'shotnoise'] # subtract shotnoise from monopole
plk['p%dk' % ell] = P
plk['shotnoise'] = poles.attrs['shotnoise'] # save shot noise term
# header
hdr = 'pyspectrum P_l(k) calculation. k_f = 2pi/%.1f; P_shotnoise %f' % (
Lbox, plk['shotnoise'])
# write to file
np.savetxt(f_pnkt,
np.array([plk['k'], plk['p0k'], plk['p2k'], plk['p4k']]).T,
header=hdr)
else:
_k, _p0k, _p2k, _p4k = np.loadtxt(f_pnkt,
skiprows=1,
unpack=True,
usecols=[0, 1, 2, 3])
plk = {}
plk['k'] = _k
plk['p0k'] = _p0k
plk['p2k'] = _p2k
plk['p4k'] = _p4k
# calculate bispectrum
if not os.path.isfile(f_b123):
# calculate bispectrum
if not rsd:
bispec = pySpec.Bk_periodic(xyz.T,
Lbox=Lbox,
Ngrid=360,
Nmax=40,
Ncut=3,
step=3,
fft='pyfftw',
nthreads=1,
silent=False)
else:
bispec = pySpec.Bk_periodic(xyz_s.T,
Lbox=Lbox,
Ngrid=360,
Nmax=40,
Ncut=3,
step=3,
fft='pyfftw',
nthreads=1,
silent=False)
i_k = bispec['i_k1']
j_k = bispec['i_k2']
l_k = bispec['i_k3']
p0k1 = bispec['p0k1']
p0k2 = bispec['p0k2']
p0k3 = bispec['p0k3']
b123 = bispec['b123']
b123_sn = bispec['b123_sn']
q123 = bispec['q123']
counts = bispec['counts']
# save to file
hdr = 'pyspectrum bispectrum calculation test. k_f = 2pi/%.1f' % Lbox
np.savetxt(f_b123,
np.array([
i_k, j_k, l_k, p0k1, p0k2, p0k3, b123, q123, counts,
b123_sn
]).T,
fmt='%i %i %i %.5e %.5e %.5e %.5e %.5e %.5e %.5e',
delimiter='\t',
header=hdr)
else:
i_k, j_k, l_k, p0k1, p0k2, p0k3, b123, q123, counts, b123_sn = np.loadtxt(
f_b123, skiprows=1, unpack=True, usecols=range(10))
# plot powerspecrtrum shape triangle plot
fig = plt.figure(figsize=(5, 5))
sub = fig.add_subplot(111)
sub.plot(k, p0k, c='k', lw=1, label='pySpectrum')
sub.plot(plk['k'], plk['p0k'], c='C1', lw=1, label='nbodykit')
sub.plot(i_k * kf, p0k1, c='k', lw=1, ls='--', label='bispectrum code')
sub.legend(loc='lower left', fontsize=20)
sub.set_ylabel('$P_0(k)$', fontsize=25)
#sub.set_ylim([1e2, 3e4])
sub.set_yscale('log')
sub.set_xlabel('$k$', fontsize=25)
sub.set_xlim([3e-3, 1.])
sub.set_xscale('log')
fig.savefig(''.join([dir_dat, 'qpm_p0k', str_rsd, '.png']),
bbox_inches='tight')
# plot bispectrum shape triangle plot
nbin = 31
x_bins = np.linspace(0., 1., nbin + 1)
y_bins = np.linspace(0.5, 1., (nbin // 2) + 1)
fig = plt.figure(figsize=(10, 5))
sub = fig.add_subplot(111)
Bgrid = Plots._BorQgrid(
l_k.astype(float) / i_k.astype(float),
j_k.astype(float) / i_k.astype(float), q123, counts, x_bins, y_bins)
bplot = plt.pcolormesh(x_bins,
y_bins,
Bgrid.T,
vmin=0,
vmax=1,
cmap='RdBu')
cbar = plt.colorbar(bplot, orientation='vertical')
sub.set_title(r'$Q(k_1, k_2, k_3)$ QPM halo catalog', fontsize=25)
sub.set_xlabel('$k_3/k_1$', fontsize=25)
sub.set_ylabel('$k_2/k_1$', fontsize=25)
fig.savefig(''.join([dir_dat, 'qpm_Q123_shape', str_rsd, '.png']),
bbox_inches='tight')
fig = plt.figure(figsize=(10, 5))
sub = fig.add_subplot(111)
Bgrid = Plots._BorQgrid(
l_k.astype(float) / i_k.astype(float),
j_k.astype(float) / i_k.astype(float), b123, counts, x_bins, y_bins)
bplot = plt.pcolormesh(x_bins,
y_bins,
Bgrid.T,
norm=LogNorm(vmin=1e6, vmax=1e8),
cmap='RdBu')
cbar = plt.colorbar(bplot, orientation='vertical')
sub.set_title(r'$B(k_1, k_2, k_3)$ QPM halo catalog', fontsize=25)
sub.set_xlabel('$k_3/k_1$', fontsize=25)
sub.set_ylabel('$k_2/k_1$', fontsize=25)
fig.savefig(''.join([dir_dat, 'qpm_B123_shape', str_rsd, '.png']),
bbox_inches='tight')
# plot bispectrum amplitude
fig = plt.figure(figsize=(10, 5))
sub = fig.add_subplot(111)
sub.scatter(range(len(b123)), q123, c='k', s=1)
sub.set_xlabel(r'$k_1 > k_2 > k_3$ triangle index', fontsize=25)
sub.set_xlim([0, len(b123)])
sub.set_ylabel(r'$Q(k_1, k_2, k_3)$', fontsize=25)
sub.set_ylim([0., 1.])
fig.savefig(''.join([dir_dat, 'qpm_Q123', str_rsd, '.png']),
bbox_inches='tight')
# plot bispectrum amplitude
fig = plt.figure(figsize=(10, 5))
sub = fig.add_subplot(111)
sub.scatter(range(len(b123)), b123, c='k', s=1)
sub.set_xlabel(r'$k_1 > k_2 > k_3$ triangle index', fontsize=25)
sub.set_xlim([0, len(b123)])
sub.set_ylabel(r'$B(k_1, k_2, k_3)$', fontsize=25)
sub.set_yscale('log')
fig.savefig(''.join([dir_dat, 'qpm_B123', str_rsd, '.png']),
bbox_inches='tight')
return None
def AEMspectra(rsd=False):
''' calculate the powerspectrum and bispectrum of the Aemulus simulation box
'''
str_rsd = ''
if rsd: str_rsd = '.rsd'
f_halo = ''.join(
[UT.dat_dir(), 'aemulus/aemulus_test002_halos.mlim1e13.hdf5'])
f_hdf5 = ''.join(
[UT.dat_dir(), 'aemulus/aemulus_test002_halos.mlim1e13.hdf5'])
f_pell = ''.join([
UT.dat_dir(), 'aemulus/pySpec.Plk.halo.mlim1e13.Ngrid360', str_rsd,
'.dat'
])
f_pnkt = ''.join([
UT.dat_dir(), 'aemulus/pySpec.Plk.halo.mlim1e13.Ngrid360.nbodykit',
str_rsd, '.dat'
])
f_b123 = ''.join([
UT.dat_dir(),
'aemulus/pySpec.B123.halo.mlim1e13.Ngrid360.Nmax40.Ncut3.step3.pyfftw',
str_rsd, '.dat'
])
Lbox = 1050.
kf = 2. * np.pi / Lbox
if not os.path.isfile(f_hdf5):
f = h5py.File(f_halo, 'r')
xyz = f['xyz'].value
vxyz = f['vxyz'].value
mh = f['mhalo'].value
xyz_s = pySpec.applyRSD(xyz.T,
vxyz.T,
0.55,
h=0.7,
omega0_m=0.340563,
LOS='z',
Lbox=Lbox)
xyz_s = xyz_s.T
f = h5py.File(f_hdf5, 'w')
f.create_dataset('xyz', data=xyz)
f.create_dataset('vxyz', data=vxyz)
f.create_dataset('xyz_s', data=xyz_s)
f.create_dataset('mhalo', data=mh)
f.close()
else:
f = h5py.File(f_hdf5, 'r')
xyz = f['xyz'].value
vxyz = f['vxyz'].value
xyz_s = f['xyz_s'].value
mh = f['mhalo'].value
f.close()
Nhalo = xyz.shape[0]
print('# halos = %i' % Nhalo)
nhalo = float(Nhalo) / Lbox**3
print('number density = %f' % nhalo)
print('1/nbar = %f' % (1. / nhalo))
# calculate powerspectrum
if not os.path.isfile(f_pell):
# calculate FFTs
if not rsd:
delta = pySpec.FFTperiodic(xyz.T,
fft='fortran',
Lbox=Lbox,
Ngrid=360,
silent=False)
else:
delta = pySpec.FFTperiodic(xyz_s.T,
fft='fortran',
Lbox=Lbox,
Ngrid=360,
silent=False)
delta_fft = pySpec.reflect_delta(delta, Ngrid=360)
# calculate powerspectrum monopole
k, p0k, cnts = pySpec.Pk_periodic(delta_fft)
k = k * kf
p0k = p0k / kf**3 - 1. / nhalo
# save to file
hdr = 'pyspectrum P_l=0(k) calculation. k_f = 2pi/1050.'
np.savetxt(f_pell,
np.array([k, p0k, cnts]).T,
fmt='%.5e %.5e %.5e',
delimiter='\t',
header=hdr)
else:
k, p0k, cnts = np.loadtxt(f_pell,
skiprows=1,
unpack=True,
usecols=[0, 1, 2])
# calculate P(k) using nbodykit for santiy check
if not os.path.isfile(f_pnkt):
# get cosmology from header
Omega_m = 0.3175
Omega_b = 0.049 # fixed baryon
h = 0.6711
cosmo = NBlab.cosmology.Planck15.clone(Omega_cdm=Omega_m - Omega_b,
h=h,
Omega_b=Omega_b)
halo_data = {}
if not rsd: halo_data['Position'] = xyz
else: halo_data['Position'] = xyz_s
halo_data['Velocity'] = vxyz
halo_data['Mass'] = mh
print("putting it into array catalog")
halos = NBlab.ArrayCatalog(halo_data,
BoxSize=np.array([Lbox, Lbox, Lbox]))
print("putting it into halo catalog")
halos = NBlab.HaloCatalog(halos, cosmo=cosmo, redshift=0., mdef='vir')
print("putting it into mesh")
mesh = halos.to_mesh(window='tsc',
Nmesh=360,
compensated=True,
position='Position')
print("calculating powerspectrum")
r = NBlab.FFTPower(mesh, mode='1d', dk=kf, kmin=kf, poles=[0, 2, 4])
poles = r.poles
plk = {'k': poles['k']}
for ell in [0, 2, 4]:
P = (poles['power_%d' % ell].real)
if ell == 0:
P = P - poles.attrs[
'shotnoise'] # subtract shotnoise from monopole
plk['p%dk' % ell] = P
plk['shotnoise'] = poles.attrs['shotnoise'] # save shot noise term
# header
hdr = 'pyspectrum P_l(k) calculation. k_f = 2pi/1050; P_shotnoise ' + str(
plk['shotnoise'])
# write to file
np.savetxt(f_pnkt,
np.array([plk['k'], plk['p0k'], plk['p2k'], plk['p4k']]).T,
header=hdr)
else:
_k, _p0k, _p2k, _p4k = np.loadtxt(f_pnkt,
skiprows=1,
unpack=True,
usecols=[0, 1, 2, 3])
plk = {}
plk['k'] = _k
plk['p0k'] = _p0k
plk['p2k'] = _p2k
plk['p4k'] = _p4k
# calculate bispectrum
if not os.path.isfile(f_b123):
if not rsd:
bispec = pySpec.Bk_periodic(xyz.T,
Lbox=Lbox,
Ngrid=360,
Nmax=40,
Ncut=3,
step=3,
fft='pyfftw',
nthreads=1,
silent=False)
else:
bispec = pySpec.Bk_periodic(xyz_s.T,
Lbox=Lbox,
Ngrid=360,
Nmax=40,
Ncut=3,
step=3,
fft='pyfftw',
nthreads=1,
silent=False)
i_k = bispec['i_k1']
j_k = bispec['i_k2']
l_k = bispec['i_k3']
p0k1 = bispec['p0k1']
p0k2 = bispec['p0k2']
p0k3 = bispec['p0k3']
b123 = bispec['b123']
b123_sn = bispec['b123_sn']
q123 = bispec['q123']
counts = bispec['counts']
# save to file
hdr = 'pyspectrum bispectrum calculation test. k_f = 2pi/%.1f' % Lbox
np.savetxt(f_b123,
np.array([
i_k, j_k, l_k, p0k1, p0k2, p0k3, b123, q123, counts,
b123_sn
]).T,
fmt='%i %i %i %.5e %.5e %.5e %.5e %.5e %.5e %.5e',
delimiter='\t',
header=hdr)
else:
i_k, j_k, l_k, p0k1, p0k2, p0k3, b123, q123, counts, b123_sn = np.loadtxt(
f_b123, skiprows=1, unpack=True, usecols=range(10))
# plot powerspecrtrum shape triangle plot
fig = plt.figure(figsize=(5, 5))
sub = fig.add_subplot(111)
sub.plot(k, p0k, c='k', lw=1, label='pySpectrum')
sub.plot(plk['k'], plk['p0k'], c='C1', lw=1, label='nbodykit')
iksort = np.argsort(i_k)
sub.plot(i_k[iksort] * kf,
p0k1[iksort],
c='k',
lw=1,
ls='--',
label='bispectrum code')
sub.legend(loc='lower left', fontsize=20)
sub.set_ylabel('$P_0(k)$', fontsize=25)
#sub.set_ylim([1e2, 3e4])
sub.set_yscale('log')
sub.set_xlabel('$k$', fontsize=25)
sub.set_xlim([3e-3, 1.])
sub.set_xscale('log')
fig.savefig(''.join([UT.dat_dir(), 'aemulus/aemulus_p0k', str_rsd,
'.png']),
bbox_inches='tight')
# plot bispectrum shape triangle plot
nbin = 31
x_bins = np.linspace(0., 1., nbin + 1)
y_bins = np.linspace(0.5, 1., (nbin // 2) + 1)
fig = plt.figure(figsize=(10, 5))
sub = fig.add_subplot(111)
Bgrid = Plots._BorQgrid(
l_k.astype(float) / i_k.astype(float),
j_k.astype(float) / i_k.astype(float), q123, counts, x_bins, y_bins)
bplot = plt.pcolormesh(x_bins,
y_bins,
Bgrid.T,
vmin=0,
vmax=1,
cmap='RdBu')
cbar = plt.colorbar(bplot, orientation='vertical')
sub.set_title(r'$Q(k_1, k_2, k_3)$ QPM halo catalog', fontsize=25)
sub.set_xlabel('$k_3/k_1$', fontsize=25)
sub.set_ylabel('$k_2/k_1$', fontsize=25)
fig.savefig(''.join(
[UT.dat_dir(), 'aemulus/aemulus_Q123_shape', str_rsd, '.png']),
bbox_inches='tight')
fig = plt.figure(figsize=(10, 5))
sub = fig.add_subplot(111)
Bgrid = Plots._BorQgrid(
l_k.astype(float) / i_k.astype(float),
j_k.astype(float) / i_k.astype(float), b123, counts, x_bins, y_bins)
bplot = plt.pcolormesh(x_bins,
y_bins,
Bgrid.T,
norm=LogNorm(vmin=1e6, vmax=1e8),
cmap='RdBu')
cbar = plt.colorbar(bplot, orientation='vertical')
sub.set_title(r'$B(k_1, k_2, k_3)$ QPM halo catalog', fontsize=25)
sub.set_xlabel('$k_3/k_1$', fontsize=25)
sub.set_ylabel('$k_2/k_1$', fontsize=25)
fig.savefig(''.join(
[UT.dat_dir(), 'aemulus/aemulus_B123_shape', str_rsd, '.png']),
bbox_inches='tight')
# plot bispectrum amplitude
fig = plt.figure(figsize=(10, 5))
sub = fig.add_subplot(111)
sub.scatter(range(len(b123)), q123, c='k', s=1)
sub.set_xlabel(r'$k_1 > k_2 > k_3$ triangle index', fontsize=25)
sub.set_xlim([0, len(b123)])
sub.set_ylabel(r'$Q(k_1, k_2, k_3)$', fontsize=25)
sub.set_ylim([0., 1.])
fig.savefig(''.join(
[UT.dat_dir(), 'aemulus/aemulus_Q123', str_rsd, '.png']),
bbox_inches='tight')
# plot bispectrum amplitude
fig = plt.figure(figsize=(10, 5))
sub = fig.add_subplot(111)
sub.scatter(range(len(b123)), b123, c='k', s=1)
sub.set_xlabel(r'$k_1 > k_2 > k_3$ triangle index', fontsize=25)
sub.set_xlim([0, len(b123)])
sub.set_ylabel(r'$B(k_1, k_2, k_3)$', fontsize=25)
sub.set_yscale('log')
fig.savefig(''.join(
[UT.dat_dir(), 'aemulus/aemulus_B123', str_rsd, '.png']),
bbox_inches='tight')
return None
label="Roman's code")
sub.legend(loc='upper right')
sub.set_xlabel('triangles', fontsize=25)
sub.set_xlim([0, len(_i)])
sub.set_ylabel(r'$B(k_1, k_2, k_3)$', fontsize=25)
sub.set_yscale('log')
sub.set_ylim([1e7, 8e9])
fig.savefig(''.join([UT.dat_dir(), 'test_b0k.BoxN1.png']), bbox_inches='tight')
########################################
# calculate redshift-space bispectrum
########################################
xyz_s = pySpec.applyRSD(xyz.T,
vxyz.T,
0.5,
h=0.7,
omega0_m=0.3,
LOS='z',
Lbox=2600.)
# z-space power/bispectrum with pySpectrum
t0 = time.time()
pspec = pySpec.Pk_periodic(xyz_s, Lbox=Lbox, Ngrid=Ngrid, silent=False)
print('--pySpec.Pk_periodic: %f sec' % ((time.time() - t0) / 60.))
t0 = time.time()
bispec = pySpec.Bk_periodic(xyz_s, Lbox=Lbox, Ngrid=Ngrid, silent=False)
print('--pySpec.Bk_periodic: %f sec' % ((time.time() - t0) / 60.))
# compare real-space bispectrum with Roman's output
f_bk_rs = os.path.join(UT.dat_dir(), 'bk.BoxN1.rsd_z.mock')
_i, _j, _l, _pi, _pj, _pl, _b123, _q123 = np.loadtxt(
unpack=True,
usecols=[0, 1, 2, 3, 4, 5])
xyz = np.zeros((3, len(x)))
xyz[0, :] = x
xyz[1, :] = y
xyz[2, :] = z
vxyz = np.zeros((3, len(x)))
vxyz[0, :] = vx
vxyz[1, :] = vy
vxyz[2, :] = vz
s_xyz = pySpec.applyRSD(xyz,
vxyz,
0.5,
h=0.7,
omega0_m=0.3,
LOS='z',
Lbox=2600.)
f = FortranFile(os.path.join(UT.dat_dir(), 'r_rsd'), 'r')
xyz_f = f.read_reals(dtype=np.float32)
xyz_f = np.reshape(xyz_f, (3, xyz_f.shape[0] / 3), order='F')
for i, ax in zip(range(3), ['x', 'y', 'z']):
print(ax)
print(s_xyz[i, :10])
print(xyz_f[i, :10])
_delta = pySpec.FFTperiodic(s_xyz, Lbox=2600, Ngrid=360, silent=False)
delta = pySpec.reflect_delta(_delta, Ngrid=360, silent=False)
xyz = np.zeros((len(x), 3))
xyz[:, 0] = x
xyz[:, 1] = y
xyz[:, 2] = z
vxyz = np.zeros((len(x), 3))
vxyz[:, 0] = vx
vxyz[:, 1] = vy
vxyz[:, 2] = vz
# RSD along the z axis
_xyz_s = pySpec.applyRSD(xyz.T,
vxyz.T,
0.0,
h=0.7,
omega0_m=0.340563,
LOS='z',
Lbox=Lbox)
xyz_s = _xyz_s.T
# impose halo mass limit
cut = (np.log10(mh) > logmlim)
# save to hdf5 for easy access
f = h5py.File(f_hdf5, 'w')
f.create_dataset('xyz', data=xyz[cut, :])
f.create_dataset('vxyz', data=vxyz[cut, :])
f.create_dataset('xyz_s', data=xyz_s[cut, :])
f.create_dataset('mhalo', data=mh[cut])
f.close()
