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decoder.py
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decoder.py
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"""
Decoder
"""
import theano
import theano.tensor as tensor
from theano.sandbox.rng_mrg import MRG_RandomStreams as RandomStreams
import cPickle as pkl
import numpy
from search import gen_sample
from collections import OrderedDict
def load_model(path_to_model, path_to_dictionary):
"""
Load a trained model for decoding
"""
# Load the worddict
with open(path_to_dictionary, 'rb') as f:
worddict = pkl.load(f)
# Create inverted dictionary
word_idict = dict()
for kk, vv in worddict.iteritems():
word_idict[vv] = kk
word_idict[0] = '<eos>'
word_idict[1] = 'UNK'
# Load model options
with open('%s.pkl'%path_to_model, 'rb') as f:
options = pkl.load(f)
if 'doutput' not in options.keys():
options['doutput'] = True
# Load parameters
params = init_params(options)
params = load_params(path_to_model, params)
tparams = init_tparams(params)
# Sampler.
trng = RandomStreams(1234)
f_init, f_next = build_sampler(tparams, options, trng)
# Pack everything up
dec = dict()
dec['options'] = options
dec['trng'] = trng
dec['worddict'] = worddict
dec['word_idict'] = word_idict
dec['tparams'] = tparams
dec['f_init'] = f_init
dec['f_next'] = f_next
return dec
def run_sampler(dec, c, beam_width=1, stochastic=False, use_unk=False):
"""
Generate text conditioned on c
"""
sample, score = gen_sample(dec['tparams'], dec['f_init'], dec['f_next'],
c.reshape(1, dec['options']['dimctx']), dec['options'],
trng=dec['trng'], k=beam_width, maxlen=1000, stochastic=stochastic,
use_unk=use_unk)
text = []
if stochastic:
sample = [sample]
for c in sample:
text.append(' '.join([dec['word_idict'][w] for w in c[:-1]]))
#Sort beams by their NLL, return the best result
lengths = numpy.array([len(s.split()) for s in text])
if lengths[0] == 0: # in case the model only predicts <eos>
lengths = lengths[1:]
score = score[1:]
text = text[1:]
sidx = numpy.argmin(score)
text = text[sidx]
score = score[sidx]
return text
def _p(pp, name):
"""
make prefix-appended name
"""
return '%s_%s'%(pp, name)
def init_tparams(params):
"""
initialize Theano shared variables according to the initial parameters
"""
tparams = OrderedDict()
for kk, pp in params.iteritems():
tparams[kk] = theano.shared(params[kk], name=kk)
return tparams
def load_params(path, params):
"""
load parameters
"""
pp = numpy.load(path)
for kk, vv in params.iteritems():
if kk not in pp:
warnings.warn('%s is not in the archive'%kk)
continue
params[kk] = pp[kk]
return params
# layers: 'name': ('parameter initializer', 'feedforward')
layers = {'ff': ('param_init_fflayer', 'fflayer'),
'gru': ('param_init_gru', 'gru_layer')}
def get_layer(name):
fns = layers[name]
return (eval(fns[0]), eval(fns[1]))
def init_params(options):
"""
Initialize all parameters
"""
params = OrderedDict()
# Word embedding
params['Wemb'] = norm_weight(options['n_words'], options['dim_word'])
# init state
params = get_layer('ff')[0](options, params, prefix='ff_state', nin=options['dimctx'], nout=options['dim'])
# Decoder
params = get_layer(options['decoder'])[0](options, params, prefix='decoder',
nin=options['dim_word'], dim=options['dim'])
# Output layer
if options['doutput']:
params = get_layer('ff')[0](options, params, prefix='ff_hid', nin=options['dim'], nout=options['dim_word'])
params = get_layer('ff')[0](options, params, prefix='ff_logit', nin=options['dim_word'], nout=options['n_words'])
else:
params = get_layer('ff')[0](options, params, prefix='ff_logit', nin=options['dim'], nout=options['n_words'])
return params
def build_sampler(tparams, options, trng):
"""
Forward sampling
"""
ctx = tensor.matrix('ctx', dtype='float32')
ctx0 = ctx
init_state = get_layer('ff')[1](tparams, ctx, options, prefix='ff_state', activ='tanh')
f_init = theano.function([ctx], init_state, name='f_init', profile=False)
# x: 1 x 1
y = tensor.vector('y_sampler', dtype='int64')
init_state = tensor.matrix('init_state', dtype='float32')
# if it's the first word, emb should be all zero
emb = tensor.switch(y[:,None] < 0, tensor.alloc(0., 1, tparams['Wemb'].shape[1]),
tparams['Wemb'][y])
# decoder
proj = get_layer(options['decoder'])[1](tparams, emb, init_state, options,
prefix='decoder',
mask=None,
one_step=True)
next_state = proj[0]
# output
if options['doutput']:
hid = get_layer('ff')[1](tparams, next_state, options, prefix='ff_hid', activ='tanh')
logit = get_layer('ff')[1](tparams, hid, options, prefix='ff_logit', activ='linear')
else:
logit = get_layer('ff')[1](tparams, next_state, options, prefix='ff_logit', activ='linear')
next_probs = tensor.nnet.softmax(logit)
next_sample = trng.multinomial(pvals=next_probs).argmax(1)
# next word probability
inps = [y, init_state]
outs = [next_probs, next_sample, next_state]
f_next = theano.function(inps, outs, name='f_next', profile=False)
return f_init, f_next
def linear(x):
"""
Linear activation function
"""
return x
def tanh(x):
"""
Tanh activation function
"""
return tensor.tanh(x)
def ortho_weight(ndim):
"""
Orthogonal weight init, for recurrent layers
"""
W = numpy.random.randn(ndim, ndim)
u, s, v = numpy.linalg.svd(W)
return u.astype('float32')
def norm_weight(nin,nout=None, scale=0.1, ortho=True):
"""
Uniform initalization from [-scale, scale]
If matrix is square and ortho=True, use ortho instead
"""
if nout == None:
nout = nin
if nout == nin and ortho:
W = ortho_weight(nin)
else:
W = numpy.random.uniform(low=-scale, high=scale, size=(nin, nout))
return W.astype('float32')
# Feedforward layer
def param_init_fflayer(options, params, prefix='ff', nin=None, nout=None, ortho=True):
"""
Affine transformation + point-wise nonlinearity
"""
if nin == None:
nin = options['dim_proj']
if nout == None:
nout = options['dim_proj']
params[_p(prefix,'W')] = norm_weight(nin, nout)
params[_p(prefix,'b')] = numpy.zeros((nout,)).astype('float32')
return params
def fflayer(tparams, state_below, options, prefix='rconv', activ='lambda x: tensor.tanh(x)', **kwargs):
"""
Feedforward pass
"""
return eval(activ)(tensor.dot(state_below, tparams[_p(prefix,'W')])+tparams[_p(prefix,'b')])
# GRU layer
def param_init_gru(options, params, prefix='gru', nin=None, dim=None):
"""
Gated Recurrent Unit (GRU)
"""
if nin == None:
nin = options['dim_proj']
if dim == None:
dim = options['dim_proj']
W = numpy.concatenate([norm_weight(nin,dim),
norm_weight(nin,dim)], axis=1)
params[_p(prefix,'W')] = W
params[_p(prefix,'b')] = numpy.zeros((2 * dim,)).astype('float32')
U = numpy.concatenate([ortho_weight(dim),
ortho_weight(dim)], axis=1)
params[_p(prefix,'U')] = U
Wx = norm_weight(nin, dim)
params[_p(prefix,'Wx')] = Wx
Ux = ortho_weight(dim)
params[_p(prefix,'Ux')] = Ux
params[_p(prefix,'bx')] = numpy.zeros((dim,)).astype('float32')
return params
def gru_layer(tparams, state_below, init_state, options, prefix='gru', mask=None, one_step=False, **kwargs):
"""
Feedforward pass through GRU
"""
nsteps = state_below.shape[0]
if state_below.ndim == 3:
n_samples = state_below.shape[1]
else:
n_samples = 1
dim = tparams[_p(prefix,'Ux')].shape[1]
if init_state == None:
init_state = tensor.alloc(0., n_samples, dim)
if mask == None:
mask = tensor.alloc(1., state_below.shape[0], 1)
def _slice(_x, n, dim):
if _x.ndim == 3:
return _x[:, :, n*dim:(n+1)*dim]
return _x[:, n*dim:(n+1)*dim]
state_below_ = tensor.dot(state_below, tparams[_p(prefix, 'W')]) + tparams[_p(prefix, 'b')]
state_belowx = tensor.dot(state_below, tparams[_p(prefix, 'Wx')]) + tparams[_p(prefix, 'bx')]
U = tparams[_p(prefix, 'U')]
Ux = tparams[_p(prefix, 'Ux')]
def _step_slice(m_, x_, xx_, h_, U, Ux):
preact = tensor.dot(h_, U)
preact += x_
r = tensor.nnet.sigmoid(_slice(preact, 0, dim))
u = tensor.nnet.sigmoid(_slice(preact, 1, dim))
preactx = tensor.dot(h_, Ux)
preactx = preactx * r
preactx = preactx + xx_
h = tensor.tanh(preactx)
h = u * h_ + (1. - u) * h
h = m_[:,None] * h + (1. - m_)[:,None] * h_
return h
seqs = [mask, state_below_, state_belowx]
_step = _step_slice
if one_step:
rval = _step(*(seqs+[init_state, tparams[_p(prefix, 'U')], tparams[_p(prefix, 'Ux')]]))
else:
rval, updates = theano.scan(_step,
sequences=seqs,
outputs_info = [init_state],
non_sequences = [tparams[_p(prefix, 'U')],
tparams[_p(prefix, 'Ux')]],
name=_p(prefix, '_layers'),
n_steps=nsteps,
profile=False,
strict=True)
rval = [rval]
return rval