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parzen_ll.py
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parzen_ll.py
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import argparse
import time
import gc
import numpy
import theano
import theano.tensor as T
from pylearn2.utils import serial
from pylearn2.config import yaml_parse
from pylearn2.datasets.mnist import MNIST
from pylearn2.datasets.tfd import TFD
def get_nll(x, parzen, batch_size=10):
"""
Credit: Yann N. Dauphin
"""
inds = range(x.shape[0])
n_batches = int(numpy.ceil(float(len(inds)) / batch_size))
times = []
nlls = []
for i in range(n_batches):
begin = time.time()
nll = parzen(x[inds[i::n_batches]])
end = time.time()
times.append(end-begin)
nlls.extend(nll)
if i % 10 == 0:
print i, numpy.mean(times), numpy.mean(nlls)
return numpy.array(nlls)
def log_mean_exp(a):
"""
Credit: Yann N. Dauphin
"""
max_ = a.max(1)
return max_ + T.log(T.exp(a - max_.dimshuffle(0, 'x')).mean(1))
def theano_parzen(mu, sigma):
"""
Credit: Yann N. Dauphin
"""
x = T.matrix()
mu = theano.shared(mu)
a = ( x.dimshuffle(0, 'x', 1) - mu.dimshuffle('x', 0, 1) ) / sigma
E = log_mean_exp(-0.5*(a**2).sum(2))
Z = mu.shape[1] * T.log(sigma * numpy.sqrt(numpy.pi * 2))
return theano.function([x], E - Z)
def cross_validate_sigma(samples, data, sigmas, batch_size):
lls = []
for sigma in sigmas:
print sigma
parzen = theano_parzen(samples, sigma)
tmp = get_nll(data, parzen, batch_size = batch_size)
lls.append(numpy.asarray(tmp).mean())
del parzen
gc.collect()
ind = numpy.argmax(lls)
return sigmas[ind]
def get_valid(ds, limit_size = -1, fold = 0):
if ds == 'mnist':
data = MNIST('train', start=50000, stop=60000)
return data.X[:limit_size]
elif ds == 'tfd':
data = TFD('valid', fold = fold, scale=True)
return data.X
else:
raise ValueError("Unknow dataset: {}".format(args.dataet))
def get_test(ds, test, fold=0):
if ds == 'mnist':
return test.get_test_set()
elif ds == 'tfd':
return test.get_test_set(fold=fold)
else:
raise ValueError("Unknow dataset: {}".format(args.dataet))
def main():
parser = argparse.ArgumentParser(description = 'Parzen window, log-likelihood estimator')
parser.add_argument('-p', '--path', help='model path')
parser.add_argument('-s', '--sigma', default = None)
parser.add_argument('-d', '--dataset', choices=['mnist', 'tfd'])
parser.add_argument('-f', '--fold', default = 0, type=int)
parser.add_argument('-v', '--valid', default = False, action='store_true')
parser.add_argument('-n', '--num_samples', default=10000, type=int)
parser.add_argument('-l', '--limit_size', default=1000, type=int)
parser.add_argument('-b', '--batch_size', default=100, type=int)
parser.add_argument('-c', '--cross_val', default=10, type=int,
help="Number of cross valiation folds")
parser.add_argument('--sigma_start', default=-1, type=float)
parser.add_argument('--sigma_end', default=0., type=float)
args = parser.parse_args()
# load model
model = serial.load(args.path)
src = model.dataset_yaml_src
batch_size = args.batch_size
model.set_batch_size(batch_size)
# load test set
test = yaml_parse.load(src)
test = get_test(args.dataset, test, args.fold)
# generate samples
samples = model.generator.sample(args.num_samples).eval()
output_space = model.generator.mlp.get_output_space()
if 'Conv2D' in str(output_space):
samples = output_space.convert(samples, output_space.axes, ('b', 0, 1, 'c'))
samples = samples.reshape((samples.shape[0], numpy.prod(samples.shape[1:])))
del model
gc.collect()
# cross validate sigma
if args.sigma is None:
valid = get_valid(args.dataset, limit_size = args.limit_size, fold = args.fold)
sigma_range = numpy.logspace(args.sigma_start, args.sigma_end, num=args.cross_val)
sigma = cross_validate_sigma(samples, valid, sigma_range, batch_size)
else:
sigma = float(args.sigma)
print "Using Sigma: {}".format(sigma)
gc.collect()
# fit and evaulate
parzen = theano_parzen(samples, sigma)
ll = get_nll(test.X, parzen, batch_size = batch_size)
se = ll.std() / numpy.sqrt(test.X.shape[0])
print "Log-Likelihood of test set = {}, se: {}".format(ll.mean(), se)
# valid
if args.valid:
valid = get_valid(args.dataset)
ll = get_nll(valid, parzen, batch_size = batch_size)
se = ll.std() / numpy.sqrt(valid.shape[0])
print "Log-Likelihood of valid set = {}, se: {}".format(ll.mean(), se)
if __name__ == "__main__":
main()