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1
egs/librispeech/ASR/pruned_transducer_stateless-2/asr_datamodule.py Symbolic link
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../pruned_transducer_stateless/asr_datamodule.py

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egs/librispeech/ASR/pruned_transducer_stateless-2/blank_predictor.py Normal file
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# Copyright 2022 Xiaomi Corp. (authors: Fangjun Kuang, Wei Kang)
#
# See ../../../../LICENSE for clarification regarding multiple authors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import torch
import torch.nn as nn
from icefall.utils import make_pad_mask
class BlankPredictor(nn.Module):
def __init__(self, encoder_out_dim: int):
"""
Args:
Output dimension of the encoder network.
"""
super().__init__()
self.linear = nn.Linear(in_features=encoder_out_dim, out_features=1)
self.loss_func = nn.BCEWithLogitsLoss(reduction="none")
def forward(
self,
x: torch.Tensor,
x_lens: torch.Tensor,
soft_target: torch.Tensor,
) -> torch.Tensor:
"""
Args:
x:
A 3-D tensor of shape (N, T, encoder_out_dim) from the output of
the encoder network.
x_lens:
A 1-D tensor of shape (N,) containing the number of valid frames
for each element in `x`.
soft_target:
A 2-D tensor of shape (N, T) containing the soft label of each frame
in `x`.
"""
assert x.ndim == 3, x.shape
assert soft_target.ndim == 2, soft_target.shape
assert x.shape[:2] == soft_target.shape[:2], (
x.shape,
soft_target.shape,
)
logits = self.linear(x).squeeze(-1)
mask = make_pad_mask(x_lens)
loss = self.loss_func(logits, soft_target)
loss.masked_fill_(mask, 0)
return loss.sum()

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egs/librispeech/ASR/pruned_transducer_stateless-2/conformer.py Symbolic link
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../pruned_transducer_stateless/conformer.py

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egs/librispeech/ASR/pruned_transducer_stateless-2/decoder.py Symbolic link
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../pruned_transducer_stateless/decoder.py

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egs/librispeech/ASR/pruned_transducer_stateless-2/encoder_interface.py Symbolic link
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../pruned_transducer_stateless/encoder_interface.py

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egs/librispeech/ASR/pruned_transducer_stateless-2/joiner.py Symbolic link
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../pruned_transducer_stateless/joiner.py

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egs/librispeech/ASR/pruned_transducer_stateless-2/model.py Normal file
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# Copyright 2021 Xiaomi Corp. (authors: Fangjun Kuang, Wei Kang)
#
# See ../../../../LICENSE for clarification regarding multiple authors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from typing import Tuple
import k2
import torch
import torch.nn as nn
from encoder_interface import EncoderInterface
from icefall.utils import add_sos
class Transducer(nn.Module):
"""It implements https://arxiv.org/pdf/1211.3711.pdf
"Sequence Transduction with Recurrent Neural Networks"
"""
def __init__(
self,
encoder: EncoderInterface,
decoder: nn.Module,
joiner: nn.Module,
blank_predictor: nn.Module,
):
"""
Args:
encoder:
It is the transcription network in the paper. Its accepts
two inputs: `x` of (N, T, C) and `x_lens` of shape (N,).
It returns two tensors: `logits` of shape (N, T, C) and
`logit_lens` of shape (N,).
decoder:
It is the prediction network in the paper. Its input shape
is (N, U) and its output shape is (N, U, C). It should contain
one attribute: `blank_id`.
joiner:
It has two inputs with shapes: (N, T, C) and (N, U, C). Its
output shape is (N, T, U, C). Note that its output contains
unnormalized probs, i.e., not processed by log-softmax.
blank_predictor:
The model to predict blanks from the encoder output. See also
`./blank_predictor.py`.
"""
super().__init__()
assert isinstance(encoder, EncoderInterface), type(encoder)
assert hasattr(decoder, "blank_id")
self.encoder = encoder
self.decoder = decoder
self.joiner = joiner
self.blank_predictor = blank_predictor
def forward(
self,
x: torch.Tensor,
x_lens: torch.Tensor,
y: k2.RaggedTensor,
prune_range: int = 5,
am_scale: float = 0.0,
lm_scale: float = 0.0,
) -> Tuple[torch.Tensor, torch.Tensor, torch.Tensor]:
"""
Args:
x:
A 3-D tensor of shape (N, T, C).
x_lens:
A 1-D tensor of shape (N,). It contains the number of frames in `x`
before padding.
y:
A ragged tensor with 2 axes [utt][label]. It contains labels of each
utterance.
prune_range:
The prune range for rnnt loss, it means how many symbols(context)
we are considering for each frame to compute the loss.
am_scale:
The scale to smooth the loss with am (output of encoder network)
part
lm_scale:
The scale to smooth the loss with lm (output of predictor network)
part
Returns:
Return a tuple containing:
- The loss for the "trivial" joiner
- The loss for the non-linear joiner
- The loss for predicting the blank token
Note:
Regarding am_scale & lm_scale, it will make the loss-function one of
the form:
lm_scale * lm_probs + am_scale * am_probs +
(1-lm_scale-am_scale) * combined_probs
"""
assert x.ndim == 3, x.shape
assert x_lens.ndim == 1, x_lens.shape
assert y.num_axes == 2, y.num_axes
assert x.size(0) == x_lens.size(0) == y.dim0
encoder_out, encoder_out_lens = self.encoder(x, x_lens)
assert torch.all(encoder_out_lens > 0)
# Now for the decoder, i.e., the prediction network
row_splits = y.shape.row_splits(1)
y_lens = row_splits[1:] - row_splits[:-1]
blank_id = self.decoder.blank_id
sos_y = add_sos(y, sos_id=blank_id)
# sos_y_padded: [B, S + 1], start with SOS.
sos_y_padded = sos_y.pad(mode="constant", padding_value=blank_id)
# decoder_out: [B, S + 1, C]
decoder_out = self.decoder(sos_y_padded)
# Note: y does not start with SOS
# y_padded : [B, S]
y_padded = y.pad(mode="constant", padding_value=0)
y_padded = y_padded.to(torch.int64)
boundary = torch.zeros(
(x.size(0), 4), dtype=torch.int64, device=x.device
)
boundary[:, 2] = y_lens
boundary[:, 3] = encoder_out_lens
simple_loss, (px_grad, py_grad) = k2.rnnt_loss_smoothed(
lm=decoder_out,
am=encoder_out,
symbols=y_padded,
termination_symbol=blank_id,
lm_only_scale=lm_scale,
am_only_scale=am_scale,
boundary=boundary,
reduction="sum",
return_grad=True,
)
#
# px_grad shape: (B, y_lens.max(), T+1)
# Note: In the paper, we use y'(t, u)
#
non_blank_occuptation = px_grad[:, :, :-1].sum(dim=1)
non_blank_occuptation = torch.clamp(non_blank_occuptation, min=0, max=1)
blank_occupation = 1 - non_blank_occuptation
blank_prediction_loss = self.blank_predictor(
encoder_out,
encoder_out_lens,
blank_occupation,
)
# ranges : [B, T, prune_range]
ranges = k2.get_rnnt_prune_ranges(
px_grad=px_grad,
py_grad=py_grad,
boundary=boundary,
s_range=prune_range,
)
# am_pruned : [B, T, prune_range, C]
# lm_pruned : [B, T, prune_range, C]
am_pruned, lm_pruned = k2.do_rnnt_pruning(
am=encoder_out, lm=decoder_out, ranges=ranges
)
# logits : [B, T, prune_range, C]
logits = self.joiner(am_pruned, lm_pruned)
pruned_loss = k2.rnnt_loss_pruned(
logits=logits,
symbols=y_padded,
ranges=ranges,
termination_symbol=blank_id,
boundary=boundary,
reduction="sum",
)
return (simple_loss, pruned_loss, blank_prediction_loss)

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egs/librispeech/ASR/pruned_transducer_stateless-2/subsampling.py Symbolic link
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../pruned_transducer_stateless/subsampling.py

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egs/librispeech/ASR/pruned_transducer_stateless-2/test_blank_predictor.py Executable file
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#!/usr/bin/env python3
# Copyright 2022 Xiaomi Corp. (authors: Fangjun Kuang)
#
# See ../../../../LICENSE for clarification regarding multiple authors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
To run this file, do:
cd icefall/egs/librispeech/ASR
python ./pruned_transducer_stateless_2/test_blank_predictor.py
"""
import torch
from blank_predictor import BlankPredictor
def test_blank_predictor():
dim = 10
predictor = BlankPredictor(encoder_out_dim=dim)
x = torch.rand(4, 3, dim)
x_lens = torch.tensor([1, 3, 2, 3], dtype=torch.int32)
y = torch.rand(4, 3)
loss = predictor(x, x_lens, y)
print(loss)
def main():
test_blank_predictor()
if __name__ == "__main__":
main()

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egs/librispeech/ASR/pruned_transducer_stateless-2/train.py Executable file
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#!/usr/bin/env python3
# Copyright 2021 Xiaomi Corp. (authors: Fangjun Kuang,
# Wei Kang
# Mingshuang Luo)
#
# See ../../../../LICENSE for clarification regarding multiple authors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
Usage:
export CUDA_VISIBLE_DEVICES="0,1,2,3"
./pruned_transducer_stateless-2/train.py \
--world-size 4 \
--num-epochs 30 \
--start-epoch 0 \
--exp-dir pruned_transducer_stateless-2/exp \
--full-libri 1 \
--max-duration 300
"""
import argparse
import logging
import warnings
from pathlib import Path
from shutil import copyfile
from typing import Any, Dict, Optional, Tuple
import k2
import sentencepiece as spm
import torch
import torch.multiprocessing as mp
import torch.nn as nn
from asr_datamodule import LibriSpeechAsrDataModule
from blank_predictor import BlankPredictor
from conformer import Conformer
from decoder import Decoder
from joiner import Joiner
from lhotse.cut import Cut
from lhotse.dataset.sampling.base import CutSampler
from lhotse.utils import fix_random_seed
from model import Transducer
from torch import Tensor
from torch.nn.parallel import DistributedDataParallel as DDP
from torch.nn.utils import clip_grad_norm_
from torch.utils.tensorboard import SummaryWriter
from transformer import Noam
from icefall.checkpoint import load_checkpoint, remove_checkpoints
from icefall.checkpoint import save_checkpoint as save_checkpoint_impl
from icefall.checkpoint import save_checkpoint_with_global_batch_idx
from icefall.dist import cleanup_dist, setup_dist
from icefall.env import get_env_info
from icefall.utils import (
AttributeDict,
MetricsTracker,
measure_gradient_norms,
measure_weight_norms,
optim_step_and_measure_param_change,
setup_logger,
str2bool,
)
def get_parser():
parser = argparse.ArgumentParser(
formatter_class=argparse.ArgumentDefaultsHelpFormatter
)
parser.add_argument(
"--world-size",
type=int,
default=1,
help="Number of GPUs for DDP training.",
)
parser.add_argument(
"--master-port",
type=int,
default=12354,
help="Master port to use for DDP training.",
)
parser.add_argument(
"--tensorboard",
type=str2bool,
default=True,
help="Should various information be logged in tensorboard.",
)
parser.add_argument(
"--num-epochs",
type=int,
default=30,
help="Number of epochs to train.",
)
parser.add_argument(
"--start-epoch",
type=int,
default=0,
help="""Resume training from from this epoch.
If it is positive, it will load checkpoint from
transducer_stateless/exp/epoch-{start_epoch-1}.pt
""",
)
parser.add_argument(
"--start-batch",
type=int,
default=0,
help="""If positive, --start-epoch is ignored and
it loads the checkpoint from exp-dir/checkpoint-{start_batch}.pt
""",
)
parser.add_argument(
"--exp-dir",
type=str,
default="pruned_transducer_stateless-2/exp",
help="""The experiment dir.
It specifies the directory where all training related
files, e.g., checkpoints, log, etc, are saved
""",
)
parser.add_argument(
"--bpe-model",
type=str,
default="data/lang_bpe_500/bpe.model",
help="Path to the BPE model",
)
parser.add_argument(
"--lr-factor",
type=float,
default=5.0,
help="The lr_factor for Noam optimizer",
)
parser.add_argument(
"--context-size",
type=int,
default=2,
help="The context size in the decoder. 1 means bigram; "
"2 means tri-gram",
)
parser.add_argument(
"--prune-range",
type=int,
default=5,
help="The prune range for rnnt loss, it means how many symbols(context)"
"we are using to compute the loss",
)
parser.add_argument(
"--lm-scale",
type=float,
default=0.25,
help="The scale to smooth the loss with lm "
"(output of prediction network) part.",
)
parser.add_argument(
"--am-scale",
type=float,
default=0.0,
help="The scale to smooth the loss with am (output of encoder network)"
"part.",
)
parser.add_argument(
"--simple-loss-scale",
type=float,
default=0.5,
help="To get pruning ranges, we will calculate a simple version"
"loss(joiner is just addition), this simple loss also uses for"
"training (as a regularization item). We will scale the simple loss"
"with this parameter before adding to the final loss.",
)
parser.add_argument(
"--blank-prediction-scale",
type=float,
default=0.1,
help="Scale to use for the blank prediction loss",
)
parser.add_argument(
"--seed",
type=int,
default=42,
help="The seed for random generators intended for reproducibility",
)
parser.add_argument(
"--save-every-n",
type=int,
default=8000,
help="""Save checkpoint after processing this number of batches"
periodically. We save checkpoint to exp-dir/ whenever
params.batch_idx_train % save_every_n == 0. The checkpoint filename
has the form: f'exp-dir/checkpoint-{params.batch_idx_train}.pt'
Note: It also saves checkpoint to `exp-dir/epoch-xxx.pt` at the
end of each epoch where `xxx` is the epoch number counting from 0.
""",
)
parser.add_argument(
"--keep-last-k",
type=int,
default=20,
help="""Only keep this number of checkpoints on disk.
For instance, if it is 3, there are only 3 checkpoints
in the exp-dir with filenames `checkpoint-xxx.pt`.
It does not affect checkpoints with name `epoch-xxx.pt`.
""",
)
return parser
def get_params() -> AttributeDict:
"""Return a dict containing training parameters.
All training related parameters that are not passed from the commandline
are saved in the variable `params`.
Commandline options are merged into `params` after they are parsed, so
you can also access them via `params`.
Explanation of options saved in `params`:
- best_train_loss: Best training loss so far. It is used to select
the model that has the lowest training loss. It is
updated during the training.
- best_valid_loss: Best validation loss so far. It is used to select
the model that has the lowest validation loss. It is
updated during the training.
- best_train_epoch: It is the epoch that has the best training loss.
- best_valid_epoch: It is the epoch that has the best validation loss.
- batch_idx_train: Used to writing statistics to tensorboard. It
contains number of batches trained so far across
epochs.
- log_interval: Print training loss if batch_idx % log_interval` is 0
- reset_interval: Reset statistics if batch_idx % reset_interval is 0
- valid_interval: Run validation if batch_idx % valid_interval is 0
- feature_dim: The model input dim. It has to match the one used
in computing features.
- subsampling_factor: The subsampling factor for the model.
- attention_dim: Hidden dim for multi-head attention model.
- num_decoder_layers: Number of decoder layer of transformer decoder.
- warm_step: The warm_step for Noam optimizer.
"""
params = AttributeDict(
{
"best_train_loss": float("inf"),
"best_valid_loss": float("inf"),
"best_train_epoch": -1,
"best_valid_epoch": -1,
"batch_idx_train": 0,
"log_interval": 50,
"reset_interval": 200,
"valid_interval": 3000, # For the 100h subset, use 800
"log_diagnostics": False,
# parameters for conformer
"feature_dim": 80,
"subsampling_factor": 4,
"attention_dim": 512,
"nhead": 8,
"dim_feedforward": 2048,
"num_encoder_layers": 12,
"vgg_frontend": False,
# parameters for decoder
"embedding_dim": 512,
# parameters for Noam
"warm_step": 80000, # For the 100h subset, use 30000
"env_info": get_env_info(),
}
)
return params
def get_encoder_model(params: AttributeDict) -> nn.Module:
# TODO: We can add an option to switch between Conformer and Transformer
encoder = Conformer(
num_features=params.feature_dim,
output_dim=params.vocab_size,
subsampling_factor=params.subsampling_factor,
d_model=params.attention_dim,
nhead=params.nhead,
dim_feedforward=params.dim_feedforward,
num_encoder_layers=params.num_encoder_layers,
vgg_frontend=params.vgg_frontend,
)
return encoder
def get_decoder_model(params: AttributeDict) -> nn.Module:
decoder = Decoder(
vocab_size=params.vocab_size,
embedding_dim=params.embedding_dim,
blank_id=params.blank_id,
context_size=params.context_size,
)
return decoder
def get_joiner_model(params: AttributeDict) -> nn.Module:
joiner = Joiner(
input_dim=params.vocab_size,
inner_dim=params.embedding_dim,
output_dim=params.vocab_size,
)
return joiner
def get_blank_prediction_model(params: AttributeDict) -> nn.Module:
blank_predictor = BlankPredictor(encoder_out_dim=params.vocab_size)
return blank_predictor
def get_transducer_model(params: AttributeDict) -> nn.Module:
encoder = get_encoder_model(params)
decoder = get_decoder_model(params)
joiner = get_joiner_model(params)
blank_predictor = get_blank_prediction_model(params)
model = Transducer(
encoder=encoder,
decoder=decoder,
joiner=joiner,
blank_predictor=blank_predictor,
)
return model
def load_checkpoint_if_available(
params: AttributeDict,
model: nn.Module,
optimizer: Optional[torch.optim.Optimizer] = None,
) -> Optional[Dict[str, Any]]:
"""Load checkpoint from file.
If params.start_batch is positive, it will load the checkpoint from
`params.exp_dir/checkpoint-{params.start_batch}.pt`. Otherwise, if
params.start_epoch is positive, it will load the checkpoint from
`params.start_epoch - 1`.
Apart from loading state dict for `model` and `optimizer` it also updates
`best_train_epoch`, `best_train_loss`, `best_valid_epoch`,
and `best_valid_loss` in `params`.
Args:
params:
The return value of :func:`get_params`.
model:
The training model.
optimizer:
The optimizer that we are using.
Returns:
Return a dict containing previously saved training info.
"""
if params.start_batch > 0:
filename = params.exp_dir / f"checkpoint-{params.start_batch}.pt"
elif params.start_epoch > 0:
filename = params.exp_dir / f"epoch-{params.start_epoch-1}.pt"
else:
return None
assert filename.is_file(), f"{filename} does not exist!"
saved_params = load_checkpoint(
filename,
model=model,
optimizer=optimizer,
)
keys = [
"best_train_epoch",
"best_valid_epoch",
"batch_idx_train",
"best_train_loss",
"best_valid_loss",
]
for k in keys:
params[k] = saved_params[k]
if params.start_batch > 0:
if "cur_epoch" in saved_params:
params["start_epoch"] = saved_params["cur_epoch"]
if "cur_batch_idx" in saved_params:
params["cur_batch_idx"] = saved_params["cur_batch_idx"]
return saved_params
def save_checkpoint(
params: AttributeDict,
model: nn.Module,
optimizer: Optional[torch.optim.Optimizer] = None,
sampler: Optional[CutSampler] = None,
rank: int = 0,
) -> None:
"""Save model, optimizer, scheduler and training stats to file.
Args:
params:
It is returned by :func:`get_params`.
model:
The training model.
optimizer:
The optimizer used in the training.
sampler:
The sampler for the training dataset.
"""
if rank != 0:
return
filename = params.exp_dir / f"epoch-{params.cur_epoch}.pt"
save_checkpoint_impl(
filename=filename,
model=model,
params=params,
optimizer=optimizer,
sampler=sampler,
rank=rank,
)
if params.best_train_epoch == params.cur_epoch:
best_train_filename = params.exp_dir / "best-train-loss.pt"
copyfile(src=filename, dst=best_train_filename)
if params.best_valid_epoch == params.cur_epoch:
best_valid_filename = params.exp_dir / "best-valid-loss.pt"
copyfile(src=filename, dst=best_valid_filename)
def compute_loss(
params: AttributeDict,
model: nn.Module,
sp: spm.SentencePieceProcessor,
batch: dict,
is_training: bool,
) -> Tuple[Tensor, MetricsTracker]:
"""
Compute CTC loss given the model and its inputs.
Args:
params:
Parameters for training. See :func:`get_params`.
model:
The model for training. It is an instance of Conformer in our case.
batch:
A batch of data. See `lhotse.dataset.K2SpeechRecognitionDataset()`
for the content in it.
is_training:
True for training. False for validation. When it is True, this
function enables autograd during computation; when it is False, it
disables autograd.
"""
device = model.device
feature = batch["inputs"]
# at entry, feature is (N, T, C)
assert feature.ndim == 3
feature = feature.to(device)
supervisions = batch["supervisions"]
feature_lens = supervisions["num_frames"].to(device)
texts = batch["supervisions"]["text"]
y = sp.encode(texts, out_type=int)
y = k2.RaggedTensor(y).to(device)
with torch.set_grad_enabled(is_training):
simple_loss, pruned_loss, blank_prediction_loss = model(
x=feature,
x_lens=feature_lens,
y=y,
prune_range=params.prune_range,
am_scale=params.am_scale,
lm_scale=params.lm_scale,
)
loss = (
params.simple_loss_scale * simple_loss
+ pruned_loss
+ params.blank_prediction_scale * blank_prediction_loss
)
assert loss.requires_grad == is_training
info = MetricsTracker()
with warnings.catch_warnings():
warnings.simplefilter("ignore")
info["frames"] = (
(feature_lens // params.subsampling_factor).sum().item()
)
# Note: We use reduction=sum while computing the loss.
info["loss"] = loss.detach().cpu().item()
info["simple_loss"] = simple_loss.detach().cpu().item()
info["pruned_loss"] = pruned_loss.detach().cpu().item()
info["blank_prediction_loss"] = blank_prediction_loss.detach().cpu().item()
return loss, info
def compute_validation_loss(
params: AttributeDict,
model: nn.Module,
sp: spm.SentencePieceProcessor,
valid_dl: torch.utils.data.DataLoader,
world_size: int = 1,
) -> MetricsTracker:
"""Run the validation process."""
model.eval()
tot_loss = MetricsTracker()
for batch_idx, batch in enumerate(valid_dl):
loss, loss_info = compute_loss(
params=params,
model=model,
sp=sp,
batch=batch,
is_training=False,
)
assert loss.requires_grad is False
tot_loss = tot_loss + loss_info
if world_size > 1:
tot_loss.reduce(loss.device)
loss_value = tot_loss["loss"] / tot_loss["frames"]
if loss_value < params.best_valid_loss:
params.best_valid_epoch = params.cur_epoch
params.best_valid_loss = loss_value
return tot_loss
def train_one_epoch(
params: AttributeDict,
model: nn.Module,
optimizer: torch.optim.Optimizer,
sp: spm.SentencePieceProcessor,
train_dl: torch.utils.data.DataLoader,
valid_dl: torch.utils.data.DataLoader,
tb_writer: Optional[SummaryWriter] = None,
world_size: int = 1,
rank: int = 0,
) -> None:
"""Train the model for one epoch.
The training loss from the mean of all frames is saved in
`params.train_loss`. It runs the validation process every
`params.valid_interval` batches.
Args:
params:
It is returned by :func:`get_params`.
model:
The model for training.
optimizer:
The optimizer we are using.
train_dl:
Dataloader for the training dataset.
valid_dl:
Dataloader for the validation dataset.
tb_writer:
Writer to write log messages to tensorboard.
world_size:
Number of nodes in DDP training. If it is 1, DDP is disabled.
rank:
The rank of the node in DDP training. If no DDP is used, it should
be set to 0.
"""
model.train()
tot_loss = MetricsTracker()
def maybe_log_gradients(tag: str):
if (
params.log_diagnostics
and tb_writer is not None
and params.batch_idx_train % (params.log_interval * 5) == 0
):
tb_writer.add_scalars(
tag,
measure_gradient_norms(model, norm="l2"),
global_step=params.batch_idx_train,
)
def maybe_log_weights(tag: str):
if (
params.log_diagnostics
and tb_writer is not None
and params.batch_idx_train % (params.log_interval * 5) == 0
):
tb_writer.add_scalars(
tag,
measure_weight_norms(model, norm="l2"),
global_step=params.batch_idx_train,
)
def maybe_log_param_relative_changes():
if (
params.log_diagnostics
and tb_writer is not None
and params.batch_idx_train % (params.log_interval * 5) == 0
):
deltas = optim_step_and_measure_param_change(model, optimizer)
tb_writer.add_scalars(
"train/relative_param_change_per_minibatch",
deltas,
global_step=params.batch_idx_train,
)
else:
optimizer.step()
cur_batch_idx = params.get("cur_batch_idx", 0)
for batch_idx, batch in enumerate(train_dl):
if batch_idx < cur_batch_idx:
continue
cur_batch_idx = batch_idx
params.batch_idx_train += 1
batch_size = len(batch["supervisions"]["text"])
loss, loss_info = compute_loss(
params=params,
model=model,
sp=sp,
batch=batch,
is_training=True,
)
# summary stats
tot_loss = (tot_loss * (1 - 1 / params.reset_interval)) + loss_info
# NOTE: We use reduction==sum and loss is computed over utterances
# in the batch and there is no normalization to it so far.
loss.backward()
maybe_log_weights("train/param_norms")
maybe_log_gradients("train/grad_norms")
maybe_log_param_relative_changes()
optimizer.zero_grad()
if (
params.batch_idx_train > 0
and params.batch_idx_train % params.save_every_n == 0
):
params.cur_batch_idx = batch_idx
save_checkpoint_with_global_batch_idx(
out_dir=params.exp_dir,
global_batch_idx=params.batch_idx_train,
model=model,
params=params,
optimizer=optimizer,
sampler=train_dl.sampler,
rank=rank,
)
del params.cur_batch_idx
remove_checkpoints(
out_dir=params.exp_dir,
topk=params.keep_last_k,
rank=rank,
)
if batch_idx % params.log_interval == 0:
logging.info(
f"Epoch {params.cur_epoch}, "
f"batch {batch_idx}, loss[{loss_info}], "
f"tot_loss[{tot_loss}], batch size: {batch_size}"
)
if tb_writer is not None:
loss_info.write_summary(
tb_writer, "train/current_", params.batch_idx_train
)
tot_loss.write_summary(
tb_writer, "train/tot_", params.batch_idx_train
)
if batch_idx > 0 and batch_idx % params.valid_interval == 0:
logging.info("Computing validation loss")
valid_info = compute_validation_loss(
params=params,
model=model,
sp=sp,
valid_dl=valid_dl,
world_size=world_size,
)
model.train()
logging.info(f"Epoch {params.cur_epoch}, validation: {valid_info}")
if tb_writer is not None:
valid_info.write_summary(
tb_writer, "train/valid_", params.batch_idx_train
)
loss_value = tot_loss["loss"] / tot_loss["frames"]
params.train_loss = loss_value
if params.train_loss < params.best_train_loss:
params.best_train_epoch = params.cur_epoch
params.best_train_loss = params.train_loss
def run(rank, world_size, args):
"""
Args:
rank:
It is a value between 0 and `world_size-1`, which is
passed automatically by `mp.spawn()` in :func:`main`.
The node with rank 0 is responsible for saving checkpoint.
world_size:
Number of GPUs for DDP training.
args:
The return value of get_parser().parse_args()
"""
params = get_params()
params.update(vars(args))
if params.full_libri is False:
params.valid_interval = 800
params.warm_step = 30000
fix_random_seed(params.seed)
if world_size > 1:
setup_dist(rank, world_size, params.master_port)
setup_logger(f"{params.exp_dir}/log/log-train")
logging.info("Training started")
if args.tensorboard and rank == 0:
tb_writer = SummaryWriter(log_dir=f"{params.exp_dir}/tensorboard")
else:
tb_writer = None
device = torch.device("cpu")
if torch.cuda.is_available():
device = torch.device("cuda", rank)
logging.info(f"Device: {device}")
sp = spm.SentencePieceProcessor()
sp.load(params.bpe_model)
# <blk> is defined in local/train_bpe_model.py
params.blank_id = sp.piece_to_id("<blk>")
params.vocab_size = sp.get_piece_size()
logging.info(params)
logging.info("About to create model")
model = get_transducer_model(params)
num_param = sum([p.numel() for p in model.parameters()])
logging.info(f"Number of model parameters: {num_param}")
checkpoints = load_checkpoint_if_available(params=params, model=model)
model.to(device)
if world_size > 1:
logging.info("Using DDP")
model = DDP(model, device_ids=[rank])
model.device = device
optimizer = Noam(
model.parameters(),
model_size=params.attention_dim,
factor=params.lr_factor,
warm_step=params.warm_step,
)
if checkpoints and "optimizer" in checkpoints:
logging.info("Loading optimizer state dict")
optimizer.load_state_dict(checkpoints["optimizer"])
librispeech = LibriSpeechAsrDataModule(args)
train_cuts = librispeech.train_clean_100_cuts()
if params.full_libri:
train_cuts += librispeech.train_clean_360_cuts()
train_cuts += librispeech.train_other_500_cuts()
def remove_short_and_long_utt(c: Cut):
# Keep only utterances with duration between 1 second and 20 seconds
#
# Caution: There is a reason to select 20.0 here. Please see
# ../local/display_manifest_statistics.py
#
# You should use ../local/display_manifest_statistics.py to get
# an utterance duration distribution for your dataset to select
# the threshold
return 1.0 <= c.duration <= 20.0
num_in_total = len(train_cuts)
train_cuts = train_cuts.filter(remove_short_and_long_utt)
num_left = len(train_cuts)
num_removed = num_in_total - num_left
removed_percent = num_removed / num_in_total * 100
logging.info(f"Before removing short and long utterances: {num_in_total}")
logging.info(f"After removing short and long utterances: {num_left}")
logging.info(f"Removed {num_removed} utterances ({removed_percent:.5f}%)")
if params.start_batch > 0 and checkpoints and "sampler" in checkpoints:
# We only load the sampler's state dict when it loads a checkpoint
# saved in the middle of an epoch
sampler_state_dict = checkpoints["sampler"]
else:
sampler_state_dict = None
train_dl = librispeech.train_dataloaders(
train_cuts, sampler_state_dict=sampler_state_dict
)
valid_cuts = librispeech.dev_clean_cuts()
valid_cuts += librispeech.dev_other_cuts()
valid_dl = librispeech.valid_dataloaders(valid_cuts)
scan_pessimistic_batches_for_oom(
model=model,
train_dl=train_dl,
optimizer=optimizer,
sp=sp,
params=params,
)
for epoch in range(params.start_epoch, params.num_epochs):
fix_random_seed(params.seed + epoch)
train_dl.sampler.set_epoch(epoch)
cur_lr = optimizer._rate
if tb_writer is not None:
tb_writer.add_scalar(
"train/learning_rate", cur_lr, params.batch_idx_train
)
tb_writer.add_scalar("train/epoch", epoch, params.batch_idx_train)
if rank == 0:
logging.info("epoch {}, learning rate {}".format(epoch, cur_lr))
params.cur_epoch = epoch
train_one_epoch(
params=params,
model=model,
optimizer=optimizer,
sp=sp,
train_dl=train_dl,
valid_dl=valid_dl,
tb_writer=tb_writer,
world_size=world_size,
rank=rank,
)
save_checkpoint(
params=params,
model=model,
optimizer=optimizer,
sampler=train_dl.sampler,
rank=rank,
)
logging.info("Done!")
if world_size > 1:
torch.distributed.barrier()
cleanup_dist()
def scan_pessimistic_batches_for_oom(
model: nn.Module,
train_dl: torch.utils.data.DataLoader,
optimizer: torch.optim.Optimizer,
sp: spm.SentencePieceProcessor,
params: AttributeDict,
):
from lhotse.dataset import find_pessimistic_batches
logging.info(
"Sanity check -- see if any of the batches in epoch 0 would cause OOM."
)
batches, crit_values = find_pessimistic_batches(train_dl.sampler)
for criterion, cuts in batches.items():
batch = train_dl.dataset[cuts]
try:
optimizer.zero_grad()
loss, _ = compute_loss(
params=params,
model=model,
sp=sp,
batch=batch,
is_training=True,
)
loss.backward()
clip_grad_norm_(model.parameters(), 5.0, 2.0)
optimizer.step()
except RuntimeError as e:
if "CUDA out of memory" in str(e):
logging.error(
"Your GPU ran out of memory with the current "
"max_duration setting. We recommend decreasing "
"max_duration and trying again.\n"
f"Failing criterion: {criterion} "
f"(={crit_values[criterion]}) ..."
)
raise
def main():
parser = get_parser()
LibriSpeechAsrDataModule.add_arguments(parser)
args = parser.parse_args()
args.exp_dir = Path(args.exp_dir)
world_size = args.world_size
assert world_size >= 1
if world_size > 1:
mp.spawn(run, args=(world_size, args), nprocs=world_size, join=True)
else:
run(rank=0, world_size=1, args=args)
torch.set_num_threads(1)
torch.set_num_interop_threads(1)
if __name__ == "__main__":
main()

1
egs/librispeech/ASR/pruned_transducer_stateless-2/transformer.py Symbolic link
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../pruned_transducer_stateless/transformer.py