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common.py
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common.py
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# Copyright 2016 Vijayaditya Peddinti.
# 2016 Vimal Manohar
# 2017 Johns Hopkins University (author: Daniel Povey)
# Apache 2.0.
""" This is a module with methods which will be used by scripts for training of
deep neural network acoustic model and raw model (i.e., generic neural
network without transition model) with frame-level objectives.
"""
from __future__ import print_function
from __future__ import division
import glob
import logging
import math
import os
import random
import time
import libs.common as common_lib
import libs.nnet3.train.common as common_train_lib
logger = logging.getLogger(__name__)
logger.addHandler(logging.NullHandler())
def train_new_models(dir, iter, srand, num_jobs,
num_archives_processed, num_archives,
raw_model_string, egs_dir,
momentum, max_param_change,
shuffle_buffer_size, minibatch_size_str,
image_augmentation_opts,
run_opts, frames_per_eg=-1,
min_deriv_time=None, max_deriv_time_relative=None,
use_multitask_egs=False, train_opts="",
backstitch_training_scale=0.0, backstitch_training_interval=1):
""" Called from train_one_iteration(), this model does one iteration of
training with 'num_jobs' jobs, and writes files like
exp/tdnn_a/24.{1,2,3,..<num_jobs>}.raw
We cannot easily use a single parallel SGE job to do the main training,
because the computation of which archive and which --frame option
to use for each job is a little complex, so we spawn each one separately.
this is no longer true for RNNs as we use do not use the --frame option
but we use the same script for consistency with FF-DNN code
Selected args:
frames_per_eg:
The frames_per_eg, in the context of (non-chain) nnet3 training,
is normally the number of output (supervised) frames in each training
example. However, the frames_per_eg argument to this function should
only be set to that number (greater than zero) if you intend to
train on a single frame of each example, on each minibatch. If you
provide this argument >0, then for each training job a different
frame from the dumped example is selected to train on, based on
the option --frame=n to nnet3-copy-egs.
If you leave frames_per_eg at its default value (-1), then the
entire sequence of frames is used for supervision. This is suitable
for RNN training, where it helps to amortize the cost of computing
the activations for the frames of context needed for the recurrence.
use_multitask_egs : True, if different examples used to train multiple
tasks or outputs, e.g.multilingual training. multilingual egs can
be generated using get_egs.sh and
steps/nnet3/multilingual/allocate_multilingual_examples.py, those
are the top-level scripts.
"""
chunk_level_training = False if frames_per_eg > 0 else True
deriv_time_opts = []
if min_deriv_time is not None:
deriv_time_opts.append("--optimization.min-deriv-time={0}".format(
min_deriv_time))
if max_deriv_time_relative is not None:
deriv_time_opts.append("--optimization.max-deriv-time-relative={0}".format(
max_deriv_time_relative))
threads = []
# the GPU timing info is only printed if we use the --verbose=1 flag; this
# slows down the computation slightly, so don't accumulate it on every
# iteration. Don't do it on iteration 0 either, because we use a smaller
# than normal minibatch size, and people may get confused thinking it's
# slower for iteration 0 because of the verbose option.
verbose_opt = ("--verbose=1" if iter % 20 == 0 and iter > 0 else "")
for job in range(1, num_jobs+1):
# k is a zero-based index that we will derive the other indexes from.
k = num_archives_processed + job - 1
# work out the 1-based archive index.
archive_index = (k % num_archives) + 1
if not chunk_level_training:
frame = (k // num_archives + archive_index) % frames_per_eg
cache_io_opts = (("--read-cache={dir}/cache.{iter}".format(dir=dir,
iter=iter)
if iter > 0 else "") +
(" --write-cache={0}/cache.{1}".format(dir, iter + 1)
if job == 1 else ""))
if image_augmentation_opts:
image_augmentation_cmd = (
'nnet3-egs-augment-image --srand={srand} {aug_opts} ark:- ark:- |'.format(
srand=k+srand,
aug_opts=image_augmentation_opts))
else:
image_augmentation_cmd = ''
multitask_egs_opts = common_train_lib.get_multitask_egs_opts(
egs_dir,
egs_prefix="egs.",
archive_index=archive_index,
use_multitask_egs=use_multitask_egs)
scp_or_ark = "scp" if use_multitask_egs else "ark"
egs_rspecifier = (
"""ark,bg:nnet3-copy-egs {frame_opts} {multitask_egs_opts} \
{scp_or_ark}:{egs_dir}/egs.{archive_index}.{scp_or_ark} ark:- | \
nnet3-shuffle-egs --buffer-size={shuffle_buffer_size} \
--srand={srand} ark:- ark:- | {aug_cmd} \
nnet3-merge-egs --minibatch-size={minibatch_size} ark:- ark:- |""".format(
frame_opts=("" if chunk_level_training
else "--frame={0}".format(frame)),
egs_dir=egs_dir, archive_index=archive_index,
shuffle_buffer_size=shuffle_buffer_size,
minibatch_size=minibatch_size_str,
aug_cmd=image_augmentation_cmd,
srand=iter+srand,
scp_or_ark=scp_or_ark,
multitask_egs_opts=multitask_egs_opts))
# note: the thread waits on that process's completion.
thread = common_lib.background_command(
"""{command} {train_queue_opt} {dir}/log/train.{iter}.{job}.log \
nnet3-train {parallel_train_opts} {cache_io_opts} \
{verbose_opt} --print-interval=10 \
--momentum={momentum} \
--max-param-change={max_param_change} \
--backstitch-training-scale={backstitch_training_scale} \
--l2-regularize-factor={l2_regularize_factor} \
--backstitch-training-interval={backstitch_training_interval} \
--srand={srand} {train_opts} \
{deriv_time_opts} "{raw_model}" "{egs_rspecifier}" \
{dir}/{next_iter}.{job}.raw""".format(
command=run_opts.command,
train_queue_opt=run_opts.train_queue_opt,
dir=dir, iter=iter,
next_iter=iter + 1, srand=iter + srand,
job=job,
parallel_train_opts=run_opts.parallel_train_opts,
cache_io_opts=cache_io_opts,
verbose_opt=verbose_opt,
momentum=momentum, max_param_change=max_param_change,
l2_regularize_factor=1.0/num_jobs,
backstitch_training_scale=backstitch_training_scale,
backstitch_training_interval=backstitch_training_interval,
train_opts=train_opts,
deriv_time_opts=" ".join(deriv_time_opts),
raw_model=raw_model_string,
egs_rspecifier=egs_rspecifier),
require_zero_status=True)
threads.append(thread)
for thread in threads:
thread.join()
def train_one_iteration(dir, iter, srand, egs_dir,
num_jobs, num_archives_processed, num_archives,
learning_rate, minibatch_size_str,
momentum, max_param_change, shuffle_buffer_size,
run_opts, image_augmentation_opts=None,
frames_per_eg=-1,
min_deriv_time=None, max_deriv_time_relative=None,
shrinkage_value=1.0, dropout_edit_string="", train_opts="",
get_raw_nnet_from_am=True, use_multitask_egs=False,
backstitch_training_scale=0.0, backstitch_training_interval=1,
compute_per_dim_accuracy=False):
""" Called from steps/nnet3/train_*.py scripts for one iteration of neural
network training
Selected args:
frames_per_eg: The default value -1 implies chunk_level_training, which
is particularly applicable to RNN training. If it is > 0, then it
implies frame-level training, which is applicable for DNN training.
If it is > 0, then each parallel SGE job created, a different frame
numbered 0..frames_per_eg-1 is used.
shrinkage_value: If value is 1.0, no shrinkage is done; otherwise
parameter values are scaled by this value.
get_raw_nnet_from_am: If True, then the network is read and stored as
acoustic model i.e. along with transition model e.g. 10.mdl
as against a raw network e.g. 10.raw when the value is False.
"""
# Set off jobs doing some diagnostics, in the background.
# Use the egs dir from the previous iteration for the diagnostics
# check if different iterations use the same random seed
if os.path.exists('{0}/srand'.format(dir)):
try:
saved_srand = int(open('{0}/srand'.format(dir)).readline().strip())
except (IOError, ValueError):
logger.error("Exception while reading the random seed "
"for training")
raise
if srand != saved_srand:
logger.warning("The random seed provided to this iteration "
"(srand={0}) is different from the one saved last "
"time (srand={1}). Using srand={0}.".format(
srand, saved_srand))
else:
with open('{0}/srand'.format(dir), 'w') as f:
f.write(str(srand))
# Sets off some background jobs to compute train and
# validation set objectives
compute_train_cv_probabilities(
dir=dir, iter=iter, egs_dir=egs_dir,
run_opts=run_opts,
get_raw_nnet_from_am=get_raw_nnet_from_am,
use_multitask_egs=use_multitask_egs,
compute_per_dim_accuracy=compute_per_dim_accuracy)
if iter > 0:
# Runs in the background
compute_progress(dir=dir, iter=iter, egs_dir=egs_dir,
run_opts=run_opts,
get_raw_nnet_from_am=get_raw_nnet_from_am)
do_average = (iter > 0)
raw_model_string = ("nnet3-copy --learning-rate={lr} --scale={s} "
"{dir}/{iter}.{suf} - |".format(
lr=learning_rate, s=shrinkage_value,
suf="mdl" if get_raw_nnet_from_am else "raw",
dir=dir, iter=iter))
raw_model_string = raw_model_string + dropout_edit_string
if do_average:
cur_minibatch_size_str = minibatch_size_str
cur_max_param_change = max_param_change
else:
# on iteration zero, use a smaller minibatch size (and we will later
# choose the output of just one of the jobs): the model-averaging isn't
# always helpful when the model is changing too fast (i.e. it can worsen
# the objective function), and the smaller minibatch size will help to
# keep the update stable.
cur_minibatch_size_str = common_train_lib.halve_minibatch_size_str(minibatch_size_str)
cur_max_param_change = float(max_param_change) / math.sqrt(2)
train_new_models(dir=dir, iter=iter, srand=srand, num_jobs=num_jobs,
num_archives_processed=num_archives_processed,
num_archives=num_archives,
raw_model_string=raw_model_string, egs_dir=egs_dir,
momentum=momentum, max_param_change=cur_max_param_change,
shuffle_buffer_size=shuffle_buffer_size,
minibatch_size_str=cur_minibatch_size_str,
run_opts=run_opts,
frames_per_eg=frames_per_eg,
min_deriv_time=min_deriv_time,
max_deriv_time_relative=max_deriv_time_relative,
image_augmentation_opts=image_augmentation_opts,
use_multitask_egs=use_multitask_egs,
train_opts=train_opts,
backstitch_training_scale=backstitch_training_scale,
backstitch_training_interval=backstitch_training_interval)
[models_to_average, best_model] = common_train_lib.get_successful_models(
num_jobs, '{0}/log/train.{1}.%.log'.format(dir, iter))
nnets_list = []
for n in models_to_average:
nnets_list.append("{0}/{1}.{2}.raw".format(dir, iter + 1, n))
if do_average:
# average the output of the different jobs.
common_train_lib.get_average_nnet_model(
dir=dir, iter=iter,
nnets_list=" ".join(nnets_list),
run_opts=run_opts,
get_raw_nnet_from_am=get_raw_nnet_from_am)
else:
# choose the best model from different jobs
common_train_lib.get_best_nnet_model(
dir=dir, iter=iter,
best_model_index=best_model,
run_opts=run_opts,
get_raw_nnet_from_am=get_raw_nnet_from_am)
try:
for i in range(1, num_jobs + 1):
os.remove("{0}/{1}.{2}.raw".format(dir, iter + 1, i))
except OSError:
logger.error("Error while trying to delete the raw models")
raise
if get_raw_nnet_from_am:
new_model = "{0}/{1}.mdl".format(dir, iter + 1)
else:
new_model = "{0}/{1}.raw".format(dir, iter + 1)
if not os.path.isfile(new_model):
raise Exception("Could not find {0}, at the end of "
"iteration {1}".format(new_model, iter))
elif os.stat(new_model).st_size == 0:
raise Exception("{0} has size 0. Something went wrong in "
"iteration {1}".format(new_model, iter))
if os.path.exists("{0}/cache.{1}".format(dir, iter)):
os.remove("{0}/cache.{1}".format(dir, iter))
def compute_preconditioning_matrix(dir, egs_dir, num_lda_jobs, run_opts,
max_lda_jobs=None, rand_prune=4.0,
lda_opts=None, use_multitask_egs=False):
if max_lda_jobs is not None:
if num_lda_jobs > max_lda_jobs:
num_lda_jobs = max_lda_jobs
multitask_egs_opts = common_train_lib.get_multitask_egs_opts(
egs_dir,
egs_prefix="egs.",
archive_index="JOB",
use_multitask_egs=use_multitask_egs)
scp_or_ark = "scp" if use_multitask_egs else "ark"
egs_rspecifier = (
"ark:nnet3-copy-egs {multitask_egs_opts} "
"{scp_or_ark}:{egs_dir}/egs.JOB.{scp_or_ark} ark:- |"
"".format(egs_dir=egs_dir, scp_or_ark=scp_or_ark,
multitask_egs_opts=multitask_egs_opts))
# Write stats with the same format as stats for LDA.
common_lib.execute_command(
"""{command} JOB=1:{num_lda_jobs} {dir}/log/get_lda_stats.JOB.log \
nnet3-acc-lda-stats --rand-prune={rand_prune} \
{dir}/init.raw "{egs_rspecifier}" \
{dir}/JOB.lda_stats""".format(
command=run_opts.command,
num_lda_jobs=num_lda_jobs,
dir=dir,
egs_rspecifier=egs_rspecifier,
rand_prune=rand_prune))
# the above command would have generated dir/{1..num_lda_jobs}.lda_stats
lda_stat_files = ['{0}/{1}.lda_stats'.format(dir, x) for x in range(1, num_lda_jobs + 1)]
common_lib.execute_command(
"""{command} {dir}/log/sum_transform_stats.log \
sum-lda-accs {dir}/lda_stats {lda_stat_files}""".format(
command=run_opts.command,
dir=dir, lda_stat_files=" ".join(lda_stat_files)))
for file in lda_stat_files:
try:
os.remove(file)
except OSError:
logger.error("There was error while trying to remove "
"lda stat files.")
raise
# this computes a fixed affine transform computed in the way we described
# in Appendix C.6 of http://arxiv.org/pdf/1410.7455v6.pdf; it's a scaled
# variant of an LDA transform but without dimensionality reduction.
common_lib.execute_command(
"""{command} {dir}/log/get_transform.log \
nnet-get-feature-transform {lda_opts} {dir}/lda.mat \
{dir}/lda_stats""".format(
command=run_opts.command, dir=dir,
lda_opts=lda_opts if lda_opts is not None else ""))
common_lib.force_symlink("../lda.mat", "{0}/configs/lda.mat".format(dir))
def compute_train_cv_probabilities(dir, iter, egs_dir, run_opts,
get_raw_nnet_from_am=True,
use_multitask_egs=False,
compute_per_dim_accuracy=False):
if get_raw_nnet_from_am:
model = "{dir}/{iter}.mdl".format(dir=dir, iter=iter)
else:
model = "{dir}/{iter}.raw".format(dir=dir, iter=iter)
scp_or_ark = "scp" if use_multitask_egs else "ark"
egs_suffix = ".scp" if use_multitask_egs else ".egs"
egs_rspecifier = ("{0}:{1}/valid_diagnostic{2}".format(
scp_or_ark, egs_dir, egs_suffix))
opts = []
if compute_per_dim_accuracy:
opts.append("--compute-per-dim-accuracy")
multitask_egs_opts = common_train_lib.get_multitask_egs_opts(
egs_dir,
egs_prefix="valid_diagnostic.",
use_multitask_egs=use_multitask_egs)
common_lib.background_command(
""" {command} {dir}/log/compute_prob_valid.{iter}.log \
nnet3-compute-prob "{model}" \
"ark,bg:nnet3-copy-egs {multitask_egs_opts} \
{egs_rspecifier} ark:- | \
nnet3-merge-egs --minibatch-size=1:64 ark:- \
ark:- |" """.format(command=run_opts.command,
dir=dir,
iter=iter,
egs_rspecifier=egs_rspecifier,
opts=' '.join(opts), model=model,
multitask_egs_opts=multitask_egs_opts))
egs_rspecifier = ("{0}:{1}/train_diagnostic{2}".format(
scp_or_ark, egs_dir, egs_suffix))
multitask_egs_opts = common_train_lib.get_multitask_egs_opts(
egs_dir,
egs_prefix="train_diagnostic.",
use_multitask_egs=use_multitask_egs)
common_lib.background_command(
"""{command} {dir}/log/compute_prob_train.{iter}.log \
nnet3-compute-prob {opts} "{model}" \
"ark,bg:nnet3-copy-egs {multitask_egs_opts} \
{egs_rspecifier} ark:- | \
nnet3-merge-egs --minibatch-size=1:64 ark:- \
ark:- |" """.format(command=run_opts.command,
dir=dir,
iter=iter,
egs_rspecifier=egs_rspecifier,
opts=' '.join(opts), model=model,
multitask_egs_opts=multitask_egs_opts))
def compute_progress(dir, iter, egs_dir,
run_opts,
get_raw_nnet_from_am=True):
suffix = "mdl" if get_raw_nnet_from_am else "raw"
prev_model = '{0}/{1}.{2}'.format(dir, iter - 1, suffix)
model = '{0}/{1}.{2}'.format(dir, iter, suffix)
common_lib.background_command(
"""{command} {dir}/log/progress.{iter}.log \
nnet3-info {model} '&&' \
nnet3-show-progress --use-gpu=no {prev_model} {model} """
''.format(command=run_opts.command, dir=dir,
iter=iter, model=model, prev_model=prev_model))
if iter % 10 == 0 and iter > 0:
# Every 10 iters, print some more detailed information.
# full_progress.X.log contains some diagnostics of the difference in
# parameters, printed in the same format as from nnet3-info.
common_lib.background_command(
"""{command} {dir}/log/full_progress.{iter}.log \
nnet3-show-progress --use-gpu=no --verbose=2 {prev_model} {model}
""".format(command=run_opts.command,
dir=dir,
iter=iter,
model=model,
prev_model=prev_model))
# full_info.X.log is just the nnet3-info of the model, with the --verbose=2
# option which includes stats on the singular values of the parameter matrices.
common_lib.background_command(
"""{command} {dir}/log/full_info.{iter}.log \
nnet3-info --verbose=2 {model}
""".format(command=run_opts.command,
dir=dir,
iter=iter,
model=model))
def combine_models(dir, num_iters, models_to_combine, egs_dir,
minibatch_size_str,
run_opts,
chunk_width=None, get_raw_nnet_from_am=True,
max_objective_evaluations=30,
use_multitask_egs=False,
compute_per_dim_accuracy=False):
""" Function to do model combination
In the nnet3 setup, the logic
for doing averaging of subsets of the models in the case where
there are too many models to reliably esetimate interpolation
factors (max_models_combine) is moved into the nnet3-combine.
"""
raw_model_strings = []
logger.info("Combining {0} models.".format(models_to_combine))
models_to_combine.add(num_iters)
for iter in sorted(models_to_combine):
suffix = "mdl" if get_raw_nnet_from_am else "raw"
model_file = '{0}/{1}.{2}'.format(dir, iter, suffix)
if not os.path.exists(model_file):
raise Exception('Model file {0} missing'.format(model_file))
raw_model_strings.append(model_file)
if get_raw_nnet_from_am:
out_model = ("| nnet3-am-copy --set-raw-nnet=- {dir}/{num_iters}.mdl "
"{dir}/combined.mdl".format(dir=dir, num_iters=num_iters))
else:
out_model = '{dir}/final.raw'.format(dir=dir)
# We reverse the order of the raw model strings so that the freshest one
# goes first. This is important for systems that include batch
# normalization-- it means that the freshest batch-norm stats are used.
# Since the batch-norm stats are not technically parameters, they are not
# combined in the combination code, they are just obtained from the first
# model.
raw_model_strings = list(reversed(raw_model_strings))
scp_or_ark = "scp" if use_multitask_egs else "ark"
egs_suffix = ".scp" if use_multitask_egs else ".egs"
egs_rspecifier = "{0}:{1}/combine{2}".format(scp_or_ark,
egs_dir, egs_suffix)
multitask_egs_opts = common_train_lib.get_multitask_egs_opts(
egs_dir,
egs_prefix="combine.",
use_multitask_egs=use_multitask_egs)
common_lib.execute_command(
"""{command} {combine_queue_opt} {dir}/log/combine.log \
nnet3-combine {combine_gpu_opt} \
--max-objective-evaluations={max_objective_evaluations} \
--verbose=3 {raw_models} \
"ark,bg:nnet3-copy-egs {multitask_egs_opts} \
{egs_rspecifier} ark:- | \
nnet3-merge-egs --minibatch-size=1:{mbsize} ark:- ark:- |" \
"{out_model}"
""".format(command=run_opts.command,
combine_queue_opt=run_opts.combine_queue_opt,
combine_gpu_opt=run_opts.combine_gpu_opt,
dir=dir, raw_models=" ".join(raw_model_strings),
max_objective_evaluations=max_objective_evaluations,
egs_rspecifier=egs_rspecifier,
mbsize=minibatch_size_str,
out_model=out_model,
multitask_egs_opts=multitask_egs_opts))
# Compute the probability of the final, combined model with
# the same subset we used for the previous compute_probs, as the
# different subsets will lead to different probs.
if get_raw_nnet_from_am:
compute_train_cv_probabilities(
dir=dir, iter='combined', egs_dir=egs_dir,
run_opts=run_opts, use_multitask_egs=use_multitask_egs,
compute_per_dim_accuracy=compute_per_dim_accuracy)
else:
compute_train_cv_probabilities(
dir=dir, iter='final', egs_dir=egs_dir,
run_opts=run_opts, get_raw_nnet_from_am=False,
use_multitask_egs=use_multitask_egs,
compute_per_dim_accuracy=compute_per_dim_accuracy)
def get_realign_iters(realign_times, num_iters,
num_jobs_initial, num_jobs_final):
""" Takes the realign_times string and identifies the approximate
iterations at which realignments have to be done.
realign_times is a space seperated string of values between 0 and 1
"""
realign_iters = []
for realign_time in realign_times.split():
realign_time = float(realign_time)
assert(realign_time > 0 and realign_time < 1)
if num_jobs_initial == num_jobs_final:
realign_iter = int(0.5 + num_iters * realign_time)
else:
realign_iter = math.sqrt((1 - realign_time)
* math.pow(num_jobs_initial, 2)
+ realign_time * math.pow(num_jobs_final,
2))
realign_iter = realign_iter - num_jobs_initial
realign_iter = realign_iter // (num_jobs_final - num_jobs_initial)
realign_iter = realign_iter * num_iters
realign_iters.append(int(realign_iter))
return realign_iters
def align(dir, data, lang, run_opts, iter=None,
online_ivector_dir=None):
alidir = '{dir}/ali{ali_suffix}'.format(
dir=dir,
ali_suffix="_iter_{0}".format(iter) if iter is not None else "")
logger.info("Aligning the data{gpu}with {num_jobs} jobs.".format(
gpu=" using gpu " if run_opts.realign_use_gpu else " ",
num_jobs=run_opts.realign_num_jobs))
common_lib.execute_command(
"""steps/nnet3/align.sh --nj {num_jobs_align} \
--cmd "{align_cmd} {align_queue_opt}" \
--use-gpu {align_use_gpu} \
--online-ivector-dir "{online_ivector_dir}" \
--iter "{iter}" {data} {lang} {dir} {alidir}""".format(
dir=dir, align_use_gpu=("yes"
if run_opts.realign_use_gpu
else "no"),
align_cmd=run_opts.realign_command,
align_queue_opt=run_opts.realign_queue_opt,
num_jobs_align=run_opts.realign_num_jobs,
online_ivector_dir=(online_ivector_dir
if online_ivector_dir is not None
else ""),
iter=iter if iter is not None else "",
alidir=alidir,
lang=lang, data=data))
return alidir
def realign(dir, iter, feat_dir, lang, prev_egs_dir, cur_egs_dir,
prior_subset_size, num_archives,
run_opts, online_ivector_dir=None):
raise Exception("Realignment stage has not been implemented in nnet3")
logger.info("Getting average posterior for purposes of adjusting "
"the priors.")
# Note: this just uses CPUs, using a smallish subset of data.
# always use the first egs archive, which makes the script simpler;
# we're using different random subsets of it.
avg_post_vec_file = compute_average_posterior(
dir=dir, iter=iter, egs_dir=prev_egs_dir,
num_archives=num_archives, prior_subset_size=prior_subset_size,
run_opts=run_opts)
avg_post_vec_file = "{dir}/post.{iter}.vec".format(dir=dir, iter=iter)
logger.info("Re-adjusting priors based on computed posteriors")
model = '{0}/{1}.mdl'.format(dir, iter)
adjust_am_priors(dir, model, avg_post_vec_file, model, run_opts)
alidir = align(dir, feat_dir, lang, run_opts, iter,
online_ivector_dir)
common_lib.execute_command(
"""steps/nnet3/relabel_egs.sh --cmd "{command}" --iter {iter} \
{alidir} {prev_egs_dir} {cur_egs_dir}""".format(
command=run_opts.command,
iter=iter,
dir=dir,
alidir=alidir,
prev_egs_dir=prev_egs_dir,
cur_egs_dir=cur_egs_dir))
def adjust_am_priors(dir, input_model, avg_posterior_vector, output_model,
run_opts):
common_lib.execute_command(
"""{command} {dir}/log/adjust_priors.final.log \
nnet3-am-adjust-priors "{input_model}" {avg_posterior_vector} \
"{output_model}" """.format(
command=run_opts.command,
dir=dir, input_model=input_model,
avg_posterior_vector=avg_posterior_vector,
output_model=output_model))
def compute_average_posterior(dir, iter, egs_dir, num_archives,
prior_subset_size,
run_opts, get_raw_nnet_from_am=True):
""" Computes the average posterior of the network
"""
for file in glob.glob('{0}/post.{1}.*.vec'.format(dir, iter)):
os.remove(file)
if run_opts.num_jobs_compute_prior > num_archives:
egs_part = 1
else:
egs_part = 'JOB'
suffix = "mdl" if get_raw_nnet_from_am else "raw"
model = "{0}/{1}.{2}".format(dir, iter, suffix)
common_lib.execute_command(
"""{command} JOB=1:{num_jobs_compute_prior} {prior_queue_opt} \
{dir}/log/get_post.{iter}.JOB.log \
nnet3-copy-egs \
ark:{egs_dir}/egs.{egs_part}.ark ark:- \| \
nnet3-subset-egs --srand=JOB --n={prior_subset_size} \
ark:- ark:- \| \
nnet3-merge-egs --minibatch-size=128 ark:- ark:- \| \
nnet3-compute-from-egs {prior_gpu_opt} --apply-exp=true \
"{model}" ark:- ark:- \| \
matrix-sum-rows ark:- ark:- \| vector-sum ark:- \
{dir}/post.{iter}.JOB.vec""".format(
command=run_opts.command,
dir=dir, model=model,
num_jobs_compute_prior=run_opts.num_jobs_compute_prior,
prior_queue_opt=run_opts.prior_queue_opt,
iter=iter, prior_subset_size=prior_subset_size,
egs_dir=egs_dir, egs_part=egs_part,
prior_gpu_opt=run_opts.prior_gpu_opt))
# make sure there is time for $dir/post.{iter}.*.vec to appear.
time.sleep(5)
avg_post_vec_file = "{dir}/post.{iter}.vec".format(dir=dir, iter=iter)
common_lib.execute_command(
"""{command} {dir}/log/vector_sum.{iter}.log \
vector-sum {dir}/post.{iter}.*.vec {output_file}
""".format(command=run_opts.command,
dir=dir, iter=iter, output_file=avg_post_vec_file))
for file in glob.glob('{0}/post.{1}.*.vec'.format(dir, iter)):
os.remove(file)
return avg_post_vec_file