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train.py
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train.py
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# -*- coding: utf-8 -*-
#!/usr/bin/env python
from data_iterator import *
from state import *
from dialog_encdec import *
from utils import *
import time
import traceback
import sys
import argparse
import cPickle
import logging
import search
import pprint
import numpy
import collections
import signal
import math
import gc
import os
import os.path
from os import listdir
from os.path import isfile, join
import matplotlib
matplotlib.use('Agg')
import pylab
class Unbuffered:
def __init__(self, stream):
self.stream = stream
def write(self, data):
self.stream.write(data)
self.stream.flush()
def __getattr__(self, attr):
return getattr(self.stream, attr)
sys.stdout = Unbuffered(sys.stdout)
logger = logging.getLogger(__name__)
### Unique RUN_ID for this execution
RUN_ID = str(time.time())
### Additional measures can be set here
measures = ["train_cost", "train_misclass", "train_kl_divergence_cost", "train_posterior_mean_variance", "valid_cost", "valid_misclass", "valid_posterior_mean_variance", "valid_kl_divergence_cost", "valid_emi"]
def init_timings():
timings = {}
for m in measures:
timings[m] = []
return timings
def save(model, timings, post_fix = ''):
print "Saving the model..."
# ignore keyboard interrupt while saving
start = time.time()
s = signal.signal(signal.SIGINT, signal.SIG_IGN)
model.save(model.state['save_dir'] + '/' + model.state['run_id'] + "_" + model.state['prefix'] + post_fix + 'model.npz')
cPickle.dump(model.state, open(model.state['save_dir'] + '/' + model.state['run_id'] + "_" + model.state['prefix'] + post_fix + 'state.pkl', 'w'))
numpy.savez(model.state['save_dir'] + '/' + model.state['run_id'] + "_" + model.state['prefix'] + post_fix + 'timing.npz', **timings)
signal.signal(signal.SIGINT, s)
print "Model saved, took {}".format(time.time() - start)
def load(model, filename, parameter_strings_to_ignore):
print "Loading the model..."
# ignore keyboard interrupt while saving
start = time.time()
s = signal.signal(signal.SIGINT, signal.SIG_IGN)
model.load(filename, parameter_strings_to_ignore)
signal.signal(signal.SIGINT, s)
print "Model loaded, took {}".format(time.time() - start)
def main(args):
logging.basicConfig(level = logging.DEBUG,
format = "%(asctime)s: %(name)s: %(levelname)s: %(message)s")
state = eval(args.prototype)()
timings = init_timings()
auto_restarting = False
if args.auto_restart:
assert not args.save_every_valid_iteration
assert len(args.resume) == 0
directory = state['save_dir']
if not directory[-1] == '/':
directory = directory + '/'
auto_resume_postfix = state['prefix'] + '_auto_model.npz'
if os.path.exists(directory):
directory_files = [f for f in listdir(directory) if isfile(join(directory, f))]
resume_filename = ''
for f in directory_files:
if len(f) > len(auto_resume_postfix):
if f[len(f) - len(auto_resume_postfix):len(f)] == auto_resume_postfix:
if len(resume_filename) > 0:
print 'ERROR: FOUND MULTIPLE MODELS IN DIRECTORY:', directory
assert False
else:
resume_filename = directory + f[0:len(f)-len('__auto_model.npz')]
if len(resume_filename) > 0:
logger.debug("Found model to automatically resume: %s" % resume_filename)
auto_restarting = True
# Setup training to automatically resume training with the model found
args.resume = resume_filename + '__auto'
# Disable training from reinitialization any parameters
args.reinitialize_decoder_parameters = False
args.reinitialize_latent_variable_parameters = False
else:
logger.debug("Could not find any model to automatically resume...")
if args.resume != "":
logger.debug("Resuming %s" % args.resume)
state_file = args.resume + '_state.pkl'
timings_file = args.resume + '_timing.npz'
if os.path.isfile(state_file) and os.path.isfile(timings_file):
logger.debug("Loading previous state")
state = cPickle.load(open(state_file, 'r'))
timings = dict(numpy.load(open(timings_file, 'r')))
for x, y in timings.items():
timings[x] = list(y)
# Increment seed to make sure we get newly shuffled batches when training on large datasets
state['seed'] = state['seed'] + 10
else:
raise Exception("Cannot resume, cannot find files!")
logger.debug("State:\n{}".format(pprint.pformat(state)))
logger.debug("Timings:\n{}".format(pprint.pformat(timings)))
if args.force_train_all_wordemb == True:
state['fix_pretrained_word_embeddings'] = False
model = DialogEncoderDecoder(state)
rng = model.rng
valid_rounds = 0
save_model_on_first_valid = False
if args.resume != "":
filename = args.resume + '_model.npz'
if os.path.isfile(filename):
logger.debug("Loading previous model")
parameter_strings_to_ignore = []
if args.reinitialize_decoder_parameters:
parameter_strings_to_ignore += ['Wd_']
parameter_strings_to_ignore += ['bd_']
save_model_on_first_valid = True
if args.reinitialize_latent_variable_parameters:
parameter_strings_to_ignore += ['latent_utterance_prior']
parameter_strings_to_ignore += ['latent_utterance_approx_posterior']
parameter_strings_to_ignore += ['kl_divergence_cost_weight']
parameter_strings_to_ignore += ['latent_dcgm_encoder']
save_model_on_first_valid = True
load(model, filename, parameter_strings_to_ignore)
else:
raise Exception("Cannot resume, cannot find model file!")
if 'run_id' not in model.state:
raise Exception('Backward compatibility not ensured! (need run_id in state)')
else:
# assign new run_id key
model.state['run_id'] = RUN_ID
logger.debug("Compile trainer")
if not state["use_nce"]:
if ('add_latent_gaussian_per_utterance' in state) and (state["add_latent_gaussian_per_utterance"]):
logger.debug("Training using variational lower bound on log-likelihood")
else:
logger.debug("Training using exact log-likelihood")
train_batch = model.build_train_function()
else:
logger.debug("Training with noise contrastive estimation")
train_batch = model.build_nce_function()
eval_batch = model.build_eval_function()
if model.add_latent_gaussian_per_utterance:
eval_grads = model.build_eval_grads()
random_sampler = search.RandomSampler(model)
beam_sampler = search.BeamSampler(model)
logger.debug("Load data")
train_data, \
valid_data, = get_train_iterator(state)
train_data.start()
# Start looping through the dataset
step = 0
patience = state['patience']
start_time = time.time()
train_cost = 0
train_kl_divergence_cost = 0
train_posterior_mean_variance = 0
train_misclass = 0
train_done = 0
train_dialogues_done = 0.0
prev_train_cost = 0
prev_train_done = 0
ex_done = 0
is_end_of_batch = True
start_validation = False
batch = None
while (step < state['loop_iters'] and
(time.time() - start_time)/60. < state['time_stop'] and
patience >= 0):
### Sampling phase
if step % 200 == 0:
# First generate stochastic samples
for param in model.params:
print "%s = %.4f" % (param.name, numpy.sum(param.get_value() ** 2) ** 0.5)
samples, costs = random_sampler.sample([[]], n_samples=1, n_turns=3)
print "Sampled : {}".format(samples[0])
### Training phase
batch = train_data.next()
# Train finished
if not batch:
# Restart training
logger.debug("Got None...")
break
logger.debug("[TRAIN] - Got batch %d,%d" % (batch['x'].shape[1], batch['max_length']))
x_data = batch['x']
x_data_reversed = batch['x_reversed']
max_length = batch['max_length']
x_cost_mask = batch['x_mask']
x_reset = batch['x_reset']
ran_cost_utterance = batch['ran_var_constutterance']
ran_decoder_drop_mask = batch['ran_decoder_drop_mask']
is_end_of_batch = False
if numpy.sum(numpy.abs(x_reset)) < 1:
# Print when we reach the end of an example (e.g. the end of a dialogue or a document)
# Knowing when the training procedure reaches the end is useful for diagnosing training problems
#print 'END-OF-BATCH EXAMPLE!'
is_end_of_batch = True
if state['use_nce']:
y_neg = rng.choice(size=(10, max_length, x_data.shape[1]), a=model.idim, p=model.noise_probs).astype('int32')
c, kl_divergence_cost, posterior_mean_variance = train_batch(x_data, x_data_reversed, y_neg, max_length, x_cost_mask, x_reset, ran_cost_utterance, ran_decoder_drop_mask)
else:
c, kl_divergence_cost, posterior_mean_variance = train_batch(x_data, x_data_reversed, max_length, x_cost_mask, x_reset, ran_cost_utterance, ran_decoder_drop_mask)
# Print batch statistics
print 'cost_sum', c
print 'cost_mean', c / float(numpy.sum(x_cost_mask))
print 'kl_divergence_cost_sum', kl_divergence_cost
print 'kl_divergence_cost_mean', kl_divergence_cost / float(len(numpy.where(x_data == model.eos_sym)[0]))
print 'posterior_mean_variance', posterior_mean_variance
if numpy.isinf(c) or numpy.isnan(c):
logger.warn("Got NaN cost .. skipping")
gc.collect()
continue
train_cost += c
train_kl_divergence_cost += kl_divergence_cost
train_posterior_mean_variance += posterior_mean_variance
train_done += batch['num_preds']
train_dialogues_done += batch['num_dialogues']
this_time = time.time()
if step % state['train_freq'] == 0:
elapsed = this_time - start_time
# Keep track of training cost for the last 'train_freq' batches.
current_train_cost = train_cost/train_done
if prev_train_done >= 1 and abs(train_done - prev_train_done) > 0:
current_train_cost = float(train_cost - prev_train_cost)/float(train_done - prev_train_done)
if numpy.isinf(c) or numpy.isnan(c):
current_train_cost = 0
prev_train_cost = train_cost
prev_train_done = train_done
h, m, s = ConvertTimedelta(this_time - start_time)
# We need to catch exceptions due to high numbers in exp
try:
print ".. %.2d:%.2d:%.2d %4d mb # %d bs %d maxl %d acc_cost = %.4f acc_word_perplexity = %.4f cur_cost = %.4f cur_word_perplexity = %.4f acc_mean_word_error = %.4f acc_mean_kl_divergence_cost = %.8f acc_mean_posterior_variance = %.8f" % (h, m, s,\
state['time_stop'] - (time.time() - start_time)/60.,\
step, \
batch['x'].shape[1], \
batch['max_length'], \
float(train_cost/train_done), \
math.exp(float(train_cost/train_done)), \
current_train_cost, \
math.exp(current_train_cost), \
float(train_misclass)/float(train_done), \
float(train_kl_divergence_cost/train_done), \
float(train_posterior_mean_variance/train_dialogues_done))
except:
pass
### Inspection phase
# Evaluate gradient variance every 200 steps for GRU decoder
if state['utterance_decoder_gating'].upper() == "GRU":
if (step % 200 == 0) and (model.add_latent_gaussian_per_utterance):
k_eval = 10
softmax_costs = numpy.zeros((k_eval), dtype='float32')
var_costs = numpy.zeros((k_eval), dtype='float32')
gradients_wrt_softmax = numpy.zeros((k_eval, model.qdim_decoder, model.qdim_decoder), dtype='float32')
for k in range(0, k_eval):
batch = add_random_variables_to_batch(model.state, model.rng, batch, None, False)
ran_cost_utterance = batch['ran_var_constutterance']
ran_decoder_drop_mask = batch['ran_decoder_drop_mask']
softmax_cost, var_cost, grads_wrt_softmax, grads_wrt_kl_divergence_cost = eval_grads(x_data, x_data_reversed, max_length, x_cost_mask, x_reset, ran_cost_utterance, ran_decoder_drop_mask)
softmax_costs[k] = softmax_cost
var_costs[k] = var_cost
gradients_wrt_softmax[k, :, :] = grads_wrt_softmax
print 'mean softmax_costs', numpy.mean(softmax_costs)
print 'std softmax_costs', numpy.std(softmax_costs)
print 'mean var_costs', numpy.mean(var_costs)
print 'std var_costs', numpy.std(var_costs)
print 'mean gradients_wrt_softmax', numpy.mean(numpy.abs(numpy.mean(gradients_wrt_softmax, axis=0))), numpy.mean(gradients_wrt_softmax, axis=0)
print 'std gradients_wrt_softmax', numpy.mean(numpy.std(gradients_wrt_softmax, axis=0)), numpy.std(gradients_wrt_softmax, axis=0)
print 'std greater than mean', numpy.where(numpy.std(gradients_wrt_softmax, axis=0) > numpy.abs(numpy.mean(gradients_wrt_softmax, axis=0)))[0].shape[0]
Wd_s_q = model.utterance_decoder.Wd_s_q.get_value()
print 'Wd_s_q all', numpy.sum(numpy.abs(Wd_s_q)), numpy.mean(numpy.abs(Wd_s_q))
print 'Wd_s_q latent', numpy.sum(numpy.abs(Wd_s_q[(Wd_s_q.shape[0]-state['latent_gaussian_per_utterance_dim']):Wd_s_q.shape[0], :])), numpy.mean(numpy.abs(Wd_s_q[(Wd_s_q.shape[0]-state['latent_gaussian_per_utterance_dim']):Wd_s_q.shape[0], :]))
print 'Wd_s_q ratio', (numpy.sum(numpy.abs(Wd_s_q[(Wd_s_q.shape[0]-state['latent_gaussian_per_utterance_dim']):Wd_s_q.shape[0], :])) / numpy.sum(numpy.abs(Wd_s_q)))
if 'latent_gaussian_linear_dynamics' in state:
if state['latent_gaussian_linear_dynamics']:
prior_Wl_linear_dynamics = model.latent_utterance_variable_prior_encoder.Wl_linear_dynamics.get_value()
print 'prior_Wl_linear_dynamics', numpy.sum(numpy.abs(prior_Wl_linear_dynamics)), numpy.mean(numpy.abs(prior_Wl_linear_dynamics)), numpy.std(numpy.abs(prior_Wl_linear_dynamics))
approx_posterior_Wl_linear_dynamics = model.latent_utterance_variable_approx_posterior_encoder.Wl_linear_dynamics.get_value()
print 'approx_posterior_Wl_linear_dynamics', numpy.sum(numpy.abs(approx_posterior_Wl_linear_dynamics)), numpy.mean(numpy.abs(approx_posterior_Wl_linear_dynamics)), numpy.std(numpy.abs(approx_posterior_Wl_linear_dynamics))
#print 'grads_wrt_softmax', grads_wrt_softmax.shape, numpy.sum(numpy.abs(grads_wrt_softmax)), numpy.abs(grads_wrt_softmax[0:5,0:5])
#print 'grads_wrt_kl_divergence_cost', grads_wrt_kl_divergence_cost.shape, numpy.sum(numpy.abs(grads_wrt_kl_divergence_cost)), numpy.abs(grads_wrt_kl_divergence_cost[0:5,0:5])
### Evaluation phase
if valid_data is not None and\
step % state['valid_freq'] == 0 and step > 1:
start_validation = True
# Only start validation loop once it's time to validate and once all previous batches have been reset
if start_validation and is_end_of_batch:
start_validation = False
valid_data.start()
valid_cost = 0
valid_kl_divergence_cost = 0
valid_posterior_mean_variance = 0
valid_wordpreds_done = 0
valid_dialogues_done = 0
logger.debug("[VALIDATION START]")
while True:
batch = valid_data.next()
# Validation finished
if not batch:
break
logger.debug("[VALID] - Got batch %d,%d" % (batch['x'].shape[1], batch['max_length']))
x_data = batch['x']
x_data_reversed = batch['x_reversed']
max_length = batch['max_length']
x_cost_mask = batch['x_mask']
x_reset = batch['x_reset']
ran_cost_utterance = batch['ran_var_constutterance']
ran_decoder_drop_mask = batch['ran_decoder_drop_mask']
c, kl_term, c_list, kl_term_list, posterior_mean_variance = eval_batch(x_data, x_data_reversed, max_length, x_cost_mask, x_reset, ran_cost_utterance, ran_decoder_drop_mask)
# Rehape into matrix, where rows are validation samples and columns are tokens
# Note that we use max_length-1 because we don't get a cost for the first token
# (the first token is always assumed to be eos)
c_list = c_list.reshape((batch['x'].shape[1],max_length-1), order=(1,0))
c_list = numpy.sum(c_list, axis=1)
words_in_dialogues = numpy.sum(x_cost_mask, axis=0)
c_list = c_list / words_in_dialogues
if numpy.isinf(c) or numpy.isnan(c):
continue
valid_cost += c
valid_kl_divergence_cost += kl_divergence_cost
valid_posterior_mean_variance += posterior_mean_variance
# Print batch statistics
print 'valid_cost', valid_cost
print 'valid_kl_divergence_cost sample', kl_divergence_cost
print 'posterior_mean_variance', posterior_mean_variance
valid_wordpreds_done += batch['num_preds']
valid_dialogues_done += batch['num_dialogues']
logger.debug("[VALIDATION END]")
valid_cost /= valid_wordpreds_done
valid_kl_divergence_cost /= valid_wordpreds_done
valid_posterior_mean_variance /= valid_dialogues_done
if (len(timings["valid_cost"]) == 0) \
or (valid_cost < numpy.min(timings["valid_cost"])) \
or (save_model_on_first_valid and valid_rounds == 0):
patience = state['patience']
# Save model if there is decrease in validation cost
save(model, timings)
print 'best valid_cost', valid_cost
elif valid_cost >= timings["valid_cost"][-1] * state['cost_threshold']:
patience -= 1
if args.save_every_valid_iteration:
save(model, timings, '_' + str(step) + '_')
if args.auto_restart:
save(model, timings, '_auto_')
# We need to catch exceptions due to high numbers in exp
try:
print "** valid cost (NLL) = %.4f, valid word-perplexity = %.4f, valid kldiv cost (per word) = %.8f, valid mean posterior variance (per word) = %.8f, patience = %d" % (float(valid_cost), float(math.exp(valid_cost)), float(valid_kl_divergence_cost), float(valid_posterior_mean_variance), patience)
except:
try:
print "** valid cost (NLL) = %.4f, patience = %d" % (float(valid_cost), patience)
except:
pass
timings["train_cost"].append(train_cost/train_done)
timings["train_kl_divergence_cost"].append(train_kl_divergence_cost/train_done)
timings["train_posterior_mean_variance"].append(train_posterior_mean_variance/train_dialogues_done)
timings["valid_cost"].append(valid_cost)
timings["valid_kl_divergence_cost"].append(valid_kl_divergence_cost)
timings["valid_posterior_mean_variance"].append(valid_posterior_mean_variance)
# Reset train cost, train misclass and train done metrics
train_cost = 0
train_done = 0
prev_train_cost = 0
prev_train_done = 0
# Count number of validation rounds done so far
valid_rounds += 1
step += 1
logger.debug("All done, exiting...")
def parse_args():
parser = argparse.ArgumentParser()
parser.add_argument("--resume", type=str, default="", help="Resume training from that state")
parser.add_argument("--force_train_all_wordemb", action='store_true', help="If true, will force the model to train all word embeddings in the encoder. This switch can be used to fine-tune a model which was trained with fixed (pretrained) encoder word embeddings.")
parser.add_argument("--save_every_valid_iteration", action='store_true', help="If true, will save a unique copy of the model at every validation round.")
parser.add_argument("--auto_restart", action='store_true', help="If true, will maintain a copy of the current model parameters updated at every validation round. Upon initialization, the script will automatically scan the output directory and and resume training of a previous model (if such exists). This option is meant to be used for training models on clusters with hard wall-times. This option is incompatible with the \"resume\" and \"save_every_valid_iteration\" options.")
parser.add_argument("--prototype", type=str, help="Prototype to use (must be specified)", default='prototype_state')
parser.add_argument("--reinitialize-latent-variable-parameters", action='store_true', help="Can be used when resuming a model. If true, will initialize all latent variable parameters randomly instead of loading them from previous model.")
parser.add_argument("--reinitialize-decoder-parameters", action='store_true', help="Can be used when resuming a model. If true, will initialize all parameters of the utterance decoder randomly instead of loading them from previous model.")
args = parser.parse_args()
return args
if __name__ == "__main__":
# Models only run with float32
assert(theano.config.floatX == 'float32')
args = parse_args()
main(args)