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ComputePSIS_Hypos.py
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ComputePSIS_Hypos.py
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"""Pareto smoothed importance sampling (PSIS)
This module implements Pareto smoothed importance sampling (PSIS) and PSIS
leave-one-out (LOO) cross-validation for Python (Numpy).
Included functions
------------------
psisloo
Pareto smoothed importance sampling leave-one-out log predictive densities.
psislw
Pareto smoothed importance sampling.
gpdfitnew
Estimate the paramaters for the Generalized Pareto Distribution (GPD).
gpinv
Inverse Generalised Pareto distribution function.
sumlogs
Sum of vector where numbers are represented by their logarithms.
References
----------
Aki Vehtari, Andrew Gelman and Jonah Gabry (2017). Practical
Bayesian model evaluation using leave-one-out cross-validation
and WAIC. Statistics and Computing, 27(5):1413–1432.
doi:10.1007/s11222-016-9696-4. https://arxiv.org/abs/1507.04544
Aki Vehtari, Andrew Gelman and Jonah Gabry (2017). Pareto
smoothed importance sampling. https://arxiv.org/abs/arXiv:1507.02646v5
"""
from __future__ import division # For Python 2 compatibility
import numpy as np
# 3-Clause BSD License
"""
Copyright 2017 Aki Vehtari, Tuomas Sivula
Redistribution and use in source and binary forms, with or without modification,
are permitted provided that the following conditions are met:
1. Redistributions of source code must retain the above copyright notice, this
list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright notice,
this list of conditions and the following disclaimer in the documentation and/or
other materials provided with the distribution.
3. Neither the name of the copyright holder nor the names of its contributors
may be used to endorse or promote products derived from this software without
specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. """
def psisloo(log_lik, **kwargs):
r"""PSIS leave-one-out log predictive densities.
Computes the log predictive densities given posterior samples of the log
likelihood terms :math:`p(y_i|\theta^s)` in input parameter `log_lik`.
Returns a sum of the leave-one-out log predictive densities `loo`,
individual leave-one-out log predictive density terms `loos` and an estimate
of Pareto tail indeces `ks`. The estimates are unreliable if tail index
``k > 0.7`` (see more in the references listed in the module docstring).
Additional keyword arguments are passed to the :meth:`psislw()` function
(see the corresponding documentation).
Parameters
----------
log_lik : ndarray
Array of size n x m containing n posterior samples of the log likelihood
terms :math:`p(y_i|\theta^s)`.
Returns
-------
loo : scalar
sum of the leave-one-out log predictive densities
loos : ndarray
individual leave-one-out log predictive density terms
ks : ndarray
estimated Pareto tail indeces
"""
# ensure overwrite flag in passed arguments
kwargs['overwrite_lw'] = True
# log raw weights from log_lik
lw = -log_lik
# compute Pareto smoothed log weights given raw log weights
lw, ks = psislw(lw, **kwargs)
_, ks = psislw(-lw, **kwargs)
# compute
lw += log_lik
loos = sumlogs(lw, axis=0)
loo = loos.sum()
return dict(loo=loo, loos=loos, ks=ks)
#return loo, loos, ks
def psislw(lw, Reff=1.0, overwrite_lw=False):
"""Pareto smoothed importance sampling (PSIS).
Parameters
----------
lw : ndarray
Array of size n x m containing m sets of n log weights. It is also
possible to provide one dimensional array of length n.
Reff : scalar, optional
relative MCMC efficiency ``N_eff / N``
overwrite_lw : bool, optional
If True, the input array `lw` is smoothed in-place, assuming the array
is F-contiguous. By default, a new array is allocated.
Returns
-------
lw_out : ndarray
smoothed log weights
kss : ndarray
Pareto tail indices
"""
if lw.ndim == 2:
n, m = lw.shape
elif lw.ndim == 1:
n = len(lw)
m = 1
else:
raise ValueError("Argument `lw` must be 1 or 2 dimensional.")
if n <= 1:
raise ValueError("More than one log-weight needed.")
if overwrite_lw and lw.flags.f_contiguous:
# in-place operation
lw_out = lw
else:
# allocate new array for output
lw_out = np.copy(lw, order='F')
# allocate output array for kss
kss = np.empty(m)
# precalculate constants
cutoff_ind = - int(np.ceil(min(0.2 * n, 3 * np.sqrt(n / Reff)))) - 1
cutoffmin = np.log(np.finfo(float).tiny)
logn = np.log(n)
k_min = 1/3
# loop over sets of log weights
for i, x in enumerate(lw_out.T if lw_out.ndim == 2 else lw_out[None, :]):
# improve numerical accuracy
x -= np.max(x)
# sort the array
x_sort_ind = np.argsort(x)
# divide log weights into body and right tail
xcutoff = max(
x[x_sort_ind[cutoff_ind]],
cutoffmin
)
expxcutoff = np.exp(xcutoff)
tailinds, = np.where(x > xcutoff)
x2 = x[tailinds]
n2 = len(x2)
if n2 <= 4:
# not enough tail samples for gpdfitnew
k = np.inf
else:
# order of tail samples
x2si = np.argsort(x2)
# fit generalized Pareto distribution to the right tail samples
np.exp(x2, out=x2)
x2 -= expxcutoff
k, sigma = gpdfitnew(x2, sort=x2si)
if k >= k_min and not np.isinf(k):
# no smoothing if short tail or GPD fit failed
# compute ordered statistic for the fit
sti = np.arange(0.5, n2)
sti /= n2
qq = gpinv(sti, k, sigma)
qq += expxcutoff
np.log(qq, out=qq)
# place the smoothed tail into the output array
x[tailinds[x2si]] = qq
# truncate smoothed values to the largest raw weight 0
x[x > 0] = 0
# renormalize weights
x -= sumlogs(x)
# store tail index k
kss[i] = k
# If the provided input array is one dimensional, return kss as scalar.
if lw_out.ndim == 1:
kss = kss[0]
return lw_out, kss
def gpdfitnew(x, sort=True, sort_in_place=False, return_quadrature=False):
"""Estimate the paramaters for the Generalized Pareto Distribution (GPD)
Returns empirical Bayes estimate for the parameters of the two-parameter
generalized Parato distribution given the data.
Parameters
----------
x : ndarray
One dimensional data array
sort : bool or ndarray, optional
If known in advance, one can provide an array of indices that would
sort the input array `x`. If the input array is already sorted, provide
False. If True (default behaviour), the array is sorted internally.
sort_in_place : bool, optional
If `sort` is True and `sort_in_place` is True, the array is sorted
in-place (False by default).
return_quadrature : bool, optional
If True, quadrature points and weight `ks` and `w` of the marginal posterior distribution of k are also calculated and returned. False by
default.
Returns
-------
k, sigma : float
estimated parameter values
ks, w : ndarray
Quadrature points and weights of the marginal posterior distribution
of `k`. Returned only if `return_quadrature` is True.
Notes
-----
This function returns a negative of Zhang and Stephens's k, because it is
more common parameterisation.
"""
if x.ndim != 1 or len(x) <= 1:
raise ValueError("Invalid input array.")
# check if x should be sorted
if sort is True:
if sort_in_place:
x.sort()
xsorted = True
else:
sort = np.argsort(x)
xsorted = False
elif sort is False:
xsorted = True
else:
xsorted = False
n = len(x)
PRIOR = 3
m = 30 + int(np.sqrt(n))
bs = np.arange(1, m + 1, dtype=float)
bs -= 0.5
np.divide(m, bs, out=bs)
np.sqrt(bs, out=bs)
np.subtract(1, bs, out=bs)
if xsorted:
bs /= PRIOR * x[int(n/4 + 0.5) - 1]
bs += 1 / x[-1]
else:
bs /= PRIOR * x[sort[int(n/4 + 0.5) - 1]]
bs += 1 / x[sort[-1]]
ks = np.negative(bs)
temp = ks[:,None] * x
np.log1p(temp, out=temp)
np.mean(temp, axis=1, out=ks)
L = bs / ks
np.negative(L, out=L)
np.log(L, out=L)
L -= ks
L -= 1
L *= n
temp = L - L[:,None]
np.exp(temp, out=temp)
w = np.sum(temp, axis=1)
np.divide(1, w, out=w)
# remove negligible weights
dii = w >= 10 * np.finfo(float).eps
if not np.all(dii):
w = w[dii]
bs = bs[dii]
# normalise w
w /= w.sum()
# posterior mean for b
b = np.sum(bs * w)
# Estimate for k, note that we return a negative of Zhang and
# Stephens's k, because it is more common parameterisation.
temp = (-b) * x
np.log1p(temp, out=temp)
k = np.mean(temp)
if return_quadrature:
np.negative(x, out=temp)
temp = bs[:, None] * temp
np.log1p(temp, out=temp)
ks = np.mean(temp, axis=1)
# estimate for sigma
sigma = -k / b * n / (n - 0)
# weakly informative prior for k
a = 10
k = k * n / (n+a) + a * 0.5 / (n+a)
if return_quadrature:
ks *= n / (n+a)
ks += a * 0.5 / (n+a)
if return_quadrature:
return k, sigma, ks, w
else:
return k, sigma
def gpinv(p, k, sigma):
"""Inverse Generalised Pareto distribution function."""
x = np.empty(p.shape)
x.fill(np.nan)
if sigma <= 0:
return x
ok = (p > 0) & (p < 1)
if np.all(ok):
if np.abs(k) < np.finfo(float).eps:
np.negative(p, out=x)
np.log1p(x, out=x)
np.negative(x, out=x)
else:
np.negative(p, out=x)
np.log1p(x, out=x)
x *= -k
np.expm1(x, out=x)
x /= k
x *= sigma
else:
if np.abs(k) < np.finfo(float).eps:
# x[ok] = - np.log1p(-p[ok])
temp = p[ok]
np.negative(temp, out=temp)
np.log1p(temp, out=temp)
np.negative(temp, out=temp)
x[ok] = temp
else:
# x[ok] = np.expm1(-k * np.log1p(-p[ok])) / k
temp = p[ok]
np.negative(temp, out=temp)
np.log1p(temp, out=temp)
temp *= -k
np.expm1(temp, out=temp)
temp /= k
x[ok] = temp
x *= sigma
x[p == 0] = 0
if k >= 0:
x[p == 1] = np.inf
else:
x[p == 1] = -sigma / k
return x
def sumlogs(x, axis=None, out=None):
"""Sum of vector where numbers are represented by their logarithms.
Calculates ``np.log(np.sum(np.exp(x), axis=axis))`` in such a fashion that
it works even when elements have large magnitude.
"""
maxx = x.max(axis=axis, keepdims=True)
xnorm = x - maxx
np.exp(xnorm, out=xnorm)
out = np.sum(xnorm, axis=axis, out=out)
if isinstance(out, np.ndarray):
np.log(out, out=out)
else:
out = np.log(out)
out += np.squeeze(maxx)
return out
import sys, os
#filenames = sys.argv[3:]
#print(filenames)
import re
import glob
from operator import itemgetter
from parse_csv import parse_csv
cwd = os.getcwd()
Outfile_dir=os.path.join(cwd, str(sys.argv[3]))
print(Outfile_dir)
numbers = re.compile(r'(\d+)')
def numericalSort(value):
parts = numbers.split(value)
parts[1::2] = map(int, parts[1::2])
return parts
output_filenames = sorted(glob.glob(Outfile_dir + "/*.csv"), key=numericalSort)
print('............................................................')
#print(output_filenames)
print('............................................................')
results = {}
loo_values=[]
for filename in output_filenames:
#output = np.load(filename)
output = parse_csv(filename)
likelihood = -1*output['log_lik']
result = psisloo(likelihood)
results[filename]=(result)
loo_values.append(result['loo'])
from tempfile import TemporaryFile
outfile = TemporaryFile()
np.savez('Outfile_PSIS_CV_'+str(sys.argv[1])+'_'+str(sys.argv[2])+'.npz', loo_values=loo_values )
print("Writing PSIS-LOO completed")
##np.savez('Outfile_PSIS_CV_'+str(sys.argv[2].split(".")[0])+'.npz', loo_values=loo_values)