run_tdnn_1a.sh
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#!/bin/bash
# This script is based on run_tdnn_7h.sh in swbd chain recipe.
set -e
# configs for 'chain'
affix=1a
stage=0
train_stage=-10
get_egs_stage=-10
dir=exp/chain/tdnn # Note: _sp will get added to this
decode_iter=
# training options
num_epochs=4
initial_effective_lrate=0.001
final_effective_lrate=0.0001
max_param_change=2.0
final_layer_normalize_target=0.5
num_jobs_initial=2
num_jobs_final=12
minibatch_size=128
frames_per_eg=150,110,90
remove_egs=false
common_egs_dir=
xent_regularize=0.1
# End configuration section.
echo "$0 $@" # Print the command line for logging
. ./cmd.sh
. ./path.sh
. ./utils/parse_options.sh
if ! cuda-compiled; then
cat <<EOF && exit 1
This script is intended to be used with GPUs but you have not compiled Kaldi with CUDA
If you want to use GPUs (and have them), go to src/, and configure and make on a machine
where "nvcc" is installed.
EOF
fi
# The iVector-extraction and feature-dumping parts are the same as the standard
# nnet3 setup, and you can skip them by setting "--stage 8" if you have already
# run those things.
dir=${dir}${affix:+_$affix}_sp
train_set=train_sp
ali_dir=exp/tri5a_sp_ali
treedir=exp/chain/tri6_7d_tree_sp
lang=data/lang_chain
# if we are using the speed-perturbed data we need to generate
# alignments for it.
local/nnet3/run_ivector_common.sh --stage $stage || exit 1;
if [ $stage -le 7 ]; then
# Get the alignments as lattices (gives the LF-MMI training more freedom).
# use the same num-jobs as the alignments
nj=$(cat $ali_dir/num_jobs) || exit 1;
steps/align_fmllr_lats.sh --nj $nj --cmd "$train_cmd" data/$train_set \
data/lang exp/tri5a exp/tri5a_sp_lats
rm exp/tri5a_sp_lats/fsts.*.gz # save space
fi
if [ $stage -le 8 ]; then
# Create a version of the lang/ directory that has one state per phone in the
# topo file. [note, it really has two states.. the first one is only repeated
# once, the second one has zero or more repeats.]
rm -rf $lang
cp -r data/lang $lang
silphonelist=$(cat $lang/phones/silence.csl) || exit 1;
nonsilphonelist=$(cat $lang/phones/nonsilence.csl) || exit 1;
# Use our special topology... note that later on may have to tune this
# topology.
steps/nnet3/chain/gen_topo.py $nonsilphonelist $silphonelist >$lang/topo
fi
if [ $stage -le 9 ]; then
# Build a tree using our new topology. This is the critically different
# step compared with other recipes.
steps/nnet3/chain/build_tree.sh --frame-subsampling-factor 3 \
--context-opts "--context-width=2 --central-position=1" \
--cmd "$train_cmd" 5000 data/$train_set $lang $ali_dir $treedir
fi
if [ $stage -le 10 ]; then
echo "$0: creating neural net configs using the xconfig parser";
num_targets=$(tree-info $treedir/tree |grep num-pdfs|awk '{print $2}')
learning_rate_factor=$(echo "print (0.5/$xent_regularize)" | python)
mkdir -p $dir/configs
cat <<EOF > $dir/configs/network.xconfig
input dim=100 name=ivector
input dim=43 name=input
# please note that it is important to have input layer with the name=input
# as the layer immediately preceding the fixed-affine-layer to enable
# the use of short notation for the descriptor
fixed-affine-layer name=lda input=Append(-1,0,1,ReplaceIndex(ivector, t, 0)) affine-transform-file=$dir/configs/lda.mat
# the first splicing is moved before the lda layer, so no splicing here
relu-batchnorm-layer name=tdnn1 dim=625
relu-batchnorm-layer name=tdnn2 input=Append(-1,0,1) dim=625
relu-batchnorm-layer name=tdnn3 input=Append(-1,0,1) dim=625
relu-batchnorm-layer name=tdnn4 input=Append(-3,0,3) dim=625
relu-batchnorm-layer name=tdnn5 input=Append(-3,0,3) dim=625
relu-batchnorm-layer name=tdnn6 input=Append(-3,0,3) dim=625
## adding the layers for chain branch
relu-batchnorm-layer name=prefinal-chain input=tdnn6 dim=625 target-rms=0.5
output-layer name=output include-log-softmax=false dim=$num_targets max-change=1.5
# adding the layers for xent branch
# This block prints the configs for a separate output that will be
# trained with a cross-entropy objective in the 'chain' models... this
# has the effect of regularizing the hidden parts of the model. we use
# 0.5 / args.xent_regularize as the learning rate factor- the factor of
# 0.5 / args.xent_regularize is suitable as it means the xent
# final-layer learns at a rate independent of the regularization
# constant; and the 0.5 was tuned so as to make the relative progress
# similar in the xent and regular final layers.
relu-batchnorm-layer name=prefinal-xent input=tdnn6 dim=625 target-rms=0.5
output-layer name=output-xent dim=$num_targets learning-rate-factor=$learning_rate_factor max-change=1.5
EOF
steps/nnet3/xconfig_to_configs.py --xconfig-file $dir/configs/network.xconfig --config-dir $dir/configs/
fi
if [ $stage -le 11 ]; then
steps/nnet3/chain/train.py --stage $train_stage \
--cmd "$decode_cmd" \
--feat.online-ivector-dir exp/nnet3/ivectors_${train_set} \
--feat.cmvn-opts "--norm-means=false --norm-vars=false" \
--chain.xent-regularize $xent_regularize \
--chain.leaky-hmm-coefficient 0.1 \
--chain.l2-regularize 0.00005 \
--chain.apply-deriv-weights false \
--chain.lm-opts="--num-extra-lm-states=2000" \
--egs.dir "$common_egs_dir" \
--egs.stage $get_egs_stage \
--egs.opts "--frames-overlap-per-eg 0" \
--egs.chunk-width $frames_per_eg \
--trainer.num-chunk-per-minibatch $minibatch_size \
--trainer.frames-per-iter 1500000 \
--trainer.num-epochs $num_epochs \
--trainer.optimization.num-jobs-initial $num_jobs_initial \
--trainer.optimization.num-jobs-final $num_jobs_final \
--trainer.optimization.initial-effective-lrate $initial_effective_lrate \
--trainer.optimization.final-effective-lrate $final_effective_lrate \
--trainer.max-param-change $max_param_change \
--cleanup.remove-egs $remove_egs \
--feat-dir data/${train_set}_hires \
--tree-dir $treedir \
--lat-dir exp/tri5a_sp_lats \
--use-gpu wait \
--dir $dir || exit 1;
fi
if [ $stage -le 12 ]; then
# Note: it might appear that this $lang directory is mismatched, and it is as
# far as the 'topo' is concerned, but this script doesn't read the 'topo' from
# the lang directory.
utils/mkgraph.sh --self-loop-scale 1.0 data/lang_test $dir $dir/graph
fi
graph_dir=$dir/graph
if [ $stage -le 13 ]; then
for test_set in test eval; do
steps/nnet3/decode.sh --acwt 1.0 --post-decode-acwt 10.0 \
--nj 10 --cmd "$decode_cmd" \
--online-ivector-dir exp/nnet3/ivectors_$test_set \
$graph_dir data/${test_set}_hires $dir/decode_${test_set} || exit 1;
done
wait;
fi
exit 0;