def entmax_forward(x, alpha=1.3, dim=None, n_iter=50):
assert alpha > 1 and alpha < 2, 'alpha must be between 1 and 2'
_gp = lambda x, alpha: x ** (alpha - 1)
_gp_inv = lambda x, alpha: mtf.pow(x, (1 / (alpha - 1)))
_p = lambda x, alpha: _gp_inv(mtf.relu(x), alpha)
dim = x.shape[-1] if dim is None else dim
d = dim.size
x = x * (alpha - 1)
max_val = mtf.reduce_max(x, reduced_dim=dim)
tau_lo = max_val - _gp(1, alpha)
tau_hi = max_val - _gp(1 / d, alpha)
f_lo = mtf.reduce_sum(_p(x - tau_lo, alpha), reduced_dim=dim) - 1
dm = tau_hi - tau_lo
for _ in range(n_iter):
dm = dm / 2
tau_m = tau_lo + dm
p_m = _p(x - tau_m, alpha)
f_m = mtf.reduce_sum(p_m, reduced_dim=dim) - 1
mask = mtf.greater_equal((f_m * f_lo), 0)
tau_lo = mtf.where(mask, tau_m, tau_lo)
p_m = p_m / mtf.reduce_sum(p_m, reduced_dim=dim)
return p_m
def entmax_backward(explicit_inputs, all_inputs, forward_operations, outputs, output_grads, alpha = 1.3, dim = None, n_iter = 50):
x, = explicit_inputs
y, = outputs
dY, = output_grads
gppr = mtf.where(mtf.greater(y, 0), mtf.pow(y, (2 - alpha)), mtf.zeros_like(y))
dX = dY * gppr
q = mtf.reduce_sum(dX, reduced_dim = dim) / mtf.reduce_sum(gppr, reduced_dim = dim)
dX = dX - q * gppr
return dX,
def recon_model(mesh,
datasm,
rsdfactor,
M0,
R0,
width,
off,
istd,
x0,
nc=FLAGS.nc,
bs=FLAGS.box_size,
batch_size=FLAGS.batch_size,
a0=FLAGS.a0,
a=FLAGS.af,
nsteps=FLAGS.nsteps,
dtype=tf.float32):
"""
Prototype of function computing LPT deplacement.
Returns output tensorflow and mesh tensorflow tensors
"""
if dtype == tf.float32:
npdtype = "float32"
cdtype = tf.complex64
elif dtype == tf.float64:
npdtype = "float64"
cdtype = tf.complex128
print("Dtype : ", dtype, npdtype)
# Compute a few things first, using simple tensorflow
kny = 1 * np.pi * nc / bs
R1, R2 = 3., 3 * 1.2
stages = np.linspace(a0, a, nsteps, endpoint=True)
#graph = mtf.Graph()
#mesh = mtf.Mesh(graph, "my_mesh")
# Define the named dimensions
# Parameters of the small scales decomposition
n_block_x = FLAGS.nx
n_block_y = FLAGS.ny
n_block_z = 1
halo_size = FLAGS.hsize
if halo_size >= 0.5 * min(nc // n_block_x, nc // n_block_y,
nc // n_block_z):
new_size = int(0.5 *
min(nc // n_block_x, nc // n_block_y, nc // n_block_z))
print('WARNING: REDUCING HALO SIZE from %d to %d' %
(halo_size, new_size))
halo_size = new_size
# Parameters of the large scales decomposition
scalar = mtf.Dimension("scalar", 1)
fx_dim = mtf.Dimension("nx", nc)
fy_dim = mtf.Dimension("ny", nc)
fz_dim = mtf.Dimension("nz", nc)
tfx_dim = mtf.Dimension("tx", nc)
tfy_dim = mtf.Dimension("ty", nc)
tfz_dim = mtf.Dimension("tz", nc)
tx_dim = mtf.Dimension("tx_lr", nc)
ty_dim = mtf.Dimension("ty_lr", nc)
tz_dim = mtf.Dimension("tz_lr", nc)
nx_dim = mtf.Dimension('nx_block', n_block_x)
ny_dim = mtf.Dimension('ny_block', n_block_y)
nz_dim = mtf.Dimension('nz_block', n_block_z)
sx_dim = mtf.Dimension('sx_block', nc // n_block_x)
sy_dim = mtf.Dimension('sy_block', nc // n_block_y)
sz_dim = mtf.Dimension('sz_block', nc // n_block_z)
#k_dims = [tx_dim, ty_dim, tz_dim]
batch_dim = mtf.Dimension("batch", batch_size)
klin = np.loadtxt('../flowpm/data/Planck15_a1p00.txt').T[0]
plin = np.loadtxt('../flowpm/data/Planck15_a1p00.txt').T[1]
ipklin = iuspline(klin, plin)
pk_dim = mtf.Dimension("npk", len(plin))
pk = mtf.import_tf_tensor(mesh, plin.astype(npdtype), shape=[pk_dim])
# Compute necessary Fourier kernels
kvec = flowpm.kernels.fftk((nc, nc, nc), symmetric=False)
kx = mtf.import_tf_tensor(mesh,
kvec[0].squeeze().astype('float32'),
shape=[tfx_dim])
ky = mtf.import_tf_tensor(mesh,
kvec[1].squeeze().astype('float32'),
shape=[tfy_dim])
kz = mtf.import_tf_tensor(mesh,
kvec[2].squeeze().astype('float32'),
shape=[tfz_dim])
kv = [ky, kz, kx]
# kvec for low resolution grid
kvec_lr = flowpm.kernels.fftk([nc, nc, nc], symmetric=False)
kx_lr = mtf.import_tf_tensor(mesh,
kvec_lr[0].squeeze().astype('float32'),
shape=[tx_dim])
ky_lr = mtf.import_tf_tensor(mesh,
kvec_lr[1].squeeze().astype('float32'),
shape=[ty_dim])
kz_lr = mtf.import_tf_tensor(mesh,
kvec_lr[2].squeeze().astype('float32'),
shape=[tz_dim])
kv_lr = [ky_lr, kz_lr, kx_lr]
shape = [batch_dim, fx_dim, fy_dim, fz_dim]
lr_shape = [batch_dim, fx_dim, fy_dim, fz_dim]
hr_shape = [batch_dim, nx_dim, ny_dim, nz_dim, sx_dim, sy_dim, sz_dim]
part_shape = [batch_dim, fx_dim, fy_dim, fz_dim]
splittables = lr_shape[:-1] + hr_shape[1:4] + part_shape[1:3]
#
# Begin simulation
if x0 is None:
fieldvar = mtf.get_variable(mesh,
'linear',
part_shape,
initializer=tf.random_normal_initializer(
mean=0.0, stddev=1, seed=None))
else:
fieldvar = mtf.get_variable(mesh,
'linear',
part_shape,
initializer=tf.constant_initializer(x0))
##
state = mtfpm.lpt_init_single(
fieldvar,
a0,
kv_lr,
halo_size,
lr_shape,
hr_shape,
part_shape[1:],
antialias=True,
)
final_state = mtfpm.nbody_single(state, stages, lr_shape, hr_shape, kv_lr,
halo_size)
final_field = mtf.zeros(mesh, shape=part_shape)
final_field = mcomp.cic_paint_fr(final_field,
final_state,
output_shape=part_shape,
hr_shape=hr_shape,
halo_size=halo_size,
splittables=splittables,
mesh=mesh)
##
x = final_field
ppars, mpars, kernel = setupfnn()
pwts, pbias, pmx, psx = ppars
mwts, mbias, mmx, msx, mmy, msy = mpars
msy, mmy = msy[0], mmy[0]
size = 3
k_dims = [d.shape[0] for d in kv]
k_dims = [k_dims[2], k_dims[0], k_dims[1]]
tfnc, tfbs = float_to_mtf(nc * 1., mesh,
scalar), float_to_mtf(bs, mesh, scalar)
x1f = mesh_utils.r2c3d(x, k_dims, dtype=cdtype)
x1f = mtf.cwise(cwise_decic, [x1f] + kv + [tfnc, tfbs],
output_dtype=cdtype)
x1d = mesh_utils.c2r3d(x1f, x.shape[-3:], dtype=dtype)
x1d = mtf.add(x1d, -1.)
x1f0 = mesh_utils.r2c3d(x1d, k_dims, dtype=cdtype)
x1f = mtf.cwise(cwise_fingauss,
[x1f0, float_to_mtf(R1, mesh, scalar)] + kv + [tfnc, tfbs],
output_dtype=cdtype)
x1 = mesh_utils.c2r3d(x1f, x1d.shape[-3:], dtype=dtype)
x2f = mtf.cwise(cwise_fingauss,
[x1f0, float_to_mtf(R2, mesh, scalar)] + kv + [tfnc, tfbs],
output_dtype=cdtype)
x2 = mesh_utils.c2r3d(x2f, x1d.shape[-3:], dtype=dtype)
x12 = x1 - x2
def apply_pwts(x, x1, x2):
#y = tf.expand_dims(x, axis=-1)
y = tf.nn.conv3d(tf.expand_dims(x, axis=-1), kernel, [1, 1, 1, 1, 1],
'SAME')
y1 = tf.nn.conv3d(tf.expand_dims(x1, axis=-1), kernel, [1, 1, 1, 1, 1],
'SAME')
y2 = tf.nn.conv3d(tf.expand_dims(x2, axis=-1), kernel, [1, 1, 1, 1, 1],
'SAME')
#y = tf.nn.conv3d(tf.expand_dims(tfwrap3D(x), -1), kernel, [1, 1, 1, 1, 1], 'VALID')
#y1 = tf.nn.conv3d(tf.expand_dims(tfwrap3D(x1), -1), kernel, [1, 1, 1, 1, 1], 'VALID')
#y2 = tf.nn.conv3d(tf.expand_dims(tfwrap3D(x12), -1), kernel, [1, 1, 1, 1, 1], 'VALID')
yy = tf.concat([y, y1, y2], axis=-1)
yy = yy - pmx
yy = yy / psx
yy1 = tf.nn.relu(tf.matmul(yy, pwts[0]) + pbias[0])
yy2 = tf.nn.relu(tf.matmul(yy1, pwts[1]) + pbias[1])
yy3 = tf.matmul(yy2, pwts[2]) + pbias[2]
pmodel = tf.nn.sigmoid(tf.constant(width) * yy3)
return pmodel[..., 0]
pmodel = mtf.slicewise(
apply_pwts,
[x, x1, x12],
output_dtype=tf.float32,
output_shape=part_shape, # + [mtf.Dimension('c_dim', 81)],
name='apply_pwts',
splittable_dims=lr_shape[:-1] + hr_shape[1:4] + part_shape[1:3])
def apply_mwts(x, x1, x2):
#y = tf.expand_dims(x, axis=-1)
zz = tf.concat([
tf.expand_dims(x, -1),
tf.expand_dims(x1, -1),
tf.expand_dims(x2, -1)
],
axis=-1)
zz = zz - mmx
zz = zz / msx
zz1 = tf.nn.elu(tf.matmul(zz, mwts[0]) + mbias[0])
zz2 = tf.nn.elu(tf.matmul(zz1, mwts[1]) + mbias[1])
zz3 = tf.matmul(zz2, mwts[2]) + mbias[2]
mmodel = zz3 * msy + mmy
return mmodel[..., 0]
mmodel = mtf.slicewise(
apply_mwts,
[x, x1, x12],
output_dtype=tf.float32,
output_shape=part_shape, # + [mtf.Dimension('c_dim', 81)],
name='apply_mwts',
splittable_dims=lr_shape[:-1] + hr_shape[1:4] + part_shape[1:3])
model = pmodel * mmodel
##RSD below
hr_field = mcomp.fr_to_hr(final_field, hr_shape, halo_size, splittables,
mesh)
mstate = mpm.mtf_indices(hr_field.mesh,
shape=part_shape[1:],
dtype=tf.float32)
X = mtf.einsum([mtf.ones(hr_field.mesh, [batch_dim]), mstate],
output_shape=[batch_dim] + mstate.shape[:])
massf = mesh_utils.r2c3d(final_field, k_dims, dtype=cdtype)
masssmf = mtf.cwise(cwise_fingauss,
[massf, float_to_mtf(R1, mesh, scalar)] + kv +
[tfnc, tfbs],
output_dtype=cdtype)
masssm = mesh_utils.c2r3d(masssmf, final_field.shape[-3:], dtype=dtype)
masssm = masssm + 1e-5
imasssm = mtf.pow(x, -1.)
vzweights = final_state[1]
vzweights = mtf.slicewise(lambda x: x[:, :, :, :, -1], [vzweights],
output_dtype=tf.float32,
output_shape=vzweights.shape[:-1],
name='get_vz',
splittable_dims=vzweights.shape[1:-1])
print("weights : ", vzweights)
momz = mtf.zeros(mesh, shape=part_shape)
momz = mcomp.cic_paint_fr(final_field, final_state, output_shape=part_shape, hr_shape=hr_shape, \
halo_size=halo_size, splittables=splittables, mesh=mesh, weights=vzweights)
momzf = mesh_utils.r2c3d(momz, k_dims, dtype=cdtype)
momzsmf = mtf.cwise(cwise_fingauss,
[momzf, float_to_mtf(R1, mesh, scalar)] + kv +
[tfnc, tfbs],
output_dtype=cdtype)
momzsm = mesh_utils.c2r3d(momzsmf, momz.shape[-3:], dtype=dtype)
#Shift
velzsm = mtf.divide(momzsm, masssm)
vz = mcomp.cic_readout_fr(velzsm, [X],
hr_shape=hr_shape,
halo_size=halo_size,
splittables=splittables,
mesh=mesh)
vz = mtf.multiply(vz, rsdfactor)
print("vz : ", vz)
Xrsd = mtf.slicewise(lambda x, vz: x + tf.stack(
[tf.zeros_like(vz), tf.zeros_like(vz), vz], 4), [X, vzweights],
output_dtype=tf.float32,
output_shape=X.shape,
name='add_vz',
splittable_dims=X.shape[1:-1])
print(Xrsd)
modelread = mcomp.cic_readout_fr(model, [X],
hr_shape=hr_shape,
halo_size=halo_size,
splittables=splittables,
mesh=mesh)
modelrsd = mtf.zeros(mesh, shape=part_shape)
modelrsd = mcomp.cic_paint_fr(modelrsd, [Xrsd], output_shape=part_shape, hr_shape=hr_shape, \
halo_size=halo_size, splittables=splittables, mesh=mesh, weights=modelread)
model = modelrsd
print(modelrsd)
#Likelihood and prior here
mtfdatasm = mtf.import_tf_tensor(mesh,
tf.convert_to_tensor(datasm),
shape=shape)
# Get prior
k_dims_pr = [d.shape[0] for d in kv]
k_dims_pr = [k_dims_pr[2], k_dims_pr[0], k_dims_pr[1]]
cfield = mesh_utils.r2c3d(fieldvar, k_dims_pr, dtype=cdtype)
def _cwise_prior(kfield, pk, kx, ky, kz):
kx = tf.reshape(kx, [-1, 1, 1])
ky = tf.reshape(ky, [1, -1, 1])
kz = tf.reshape(kz, [1, 1, -1])
kk = tf.sqrt((kx / bs * nc)**2 + (ky / bs * nc)**2 + (kz / bs * nc)**2)
kshape = kk.shape
kk = tf.reshape(kk, [-1])
pkmesh = tfp.math.interp_regular_1d_grid(
x=kk,
x_ref_min=1e-05,
x_ref_max=1000.0,
y_ref=pk,
grid_regularizing_transform=tf.log)
priormesh = tf.reshape(pkmesh, kshape)
return tf.abs(kfield) / priormesh**0.5
cpfield = mtf.cwise(_cwise_prior, [cfield, pk] + kv,
output_dtype=tf.float32)
prior = mtf.reduce_sum(mtf.square(cpfield)) * bs**3 * nc**3
# Total loss
#diff = (model - mtfdata)
modelf = mesh_utils.r2c3d(model, k_dims, dtype=cdtype)
modelsmf = mtf.cwise(cwise_fingauss,
[modelf, float_to_mtf(R1, mesh, scalar)] + kv +
[tfnc, tfbs],
output_dtype=cdtype)
modelsm = mesh_utils.c2r3d(modelsmf, x1d.shape[-3:], dtype=dtype)
##Anneal
M0 = tf.constant(M0)
diff = mtf.log(modelsm + M0) - mtf.log(mtfdatasm + M0)
if off is not None:
mtfoff = mtf.import_tf_tensor(mesh, off, shape=shape)
diff = diff + mtfoff
if istd is not None:
mtfistd = mtf.import_tf_tensor(mesh, istd, shape=shape)
diff = (diff + mtfoff
) * mtfistd #For some reason, doing things wrong this one
else:
diff = diff / 0.25
def _cwise_smooth(kfield, kx, ky, kz):
kx = tf.reshape(kx, [-1, 1, 1])
ky = tf.reshape(ky, [1, -1, 1])
kz = tf.reshape(kz, [1, 1, -1])
kk = (kx / bs * nc)**2 + (ky / bs * nc)**2 + (kz / bs * nc)**2
wts = tf.cast(tf.exp(-kk * (R0 * bs / nc)**2), kfield.dtype)
return kfield * wts
cdiff = mesh_utils.r2c3d(diff, k_dims_pr, dtype=cdtype)
cdiff = mtf.cwise(_cwise_smooth, [cdiff] + kv, output_dtype=cdtype)
diff = mesh_utils.c2r3d(cdiff, diff.shape[-3:], dtype=dtype)
chisq = mtf.reduce_sum(mtf.square(diff))
loss = chisq + prior
fields = [fieldvar, final_field, model]
metrics = [chisq, prior, loss]
return fields, metrics, kv