slt2026-code / train_single_lang.py
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#!/usr/bin/env python3
"""
train_single_lang.py
Single-language fine-tuning of Nemotron-Speech-Streaming.
Adapted from train_multilingual_nemotron.py for per-language training.
This script is the entry point for every (language, hours, init) cell of
the main grid in the paper. The init arm is selected by the combination
of --resume_from and --encoder_from / --reinit_encoder; the multilingual
tokenizer, decoder and joint always come from the multilingual base.
ML init (paper's "ML" arm)
--resume_from <multilingual_base.nemo>
Encoder, decoder, joint and tokenizer all come from the multilingual
base checkpoint.
EN init (paper's "EN" arm)
--resume_from <multilingual_base.nemo>
--encoder_from nvidia/nemotron-speech-streaming-en-0.6b
The decoder, joint and tokenizer are kept from the multilingual base
(so the comparison isolates the encoder), and the encoder weights are
overwritten layer-for-layer with the English-only Nemotron encoder.
Random-encoder ablation (NOT the paper's EN arm)
--resume_from <multilingual_base.nemo>
--reinit_encoder
Same as ML init except the encoder is freshly random-initialized.
Direct from English checkpoint (legacy / not used in the main grid)
--student nvidia/nemotron-speech-streaming-en-0.6b
No --resume_from. Everything (encoder, decoder, joint, tokenizer) is
taken from the English checkpoint and only the prediction-network
output layer is resized to the target tokenizer.
Example usage (paper ML init for German, 100 h):
torchrun --nproc_per_node=1 train_single_lang.py \
--lang de \
--resume_from <CKPT_DIR>/multilingual_base.nemo \
--train_manifest <DATA_ROOT>/de/100h/train.jsonl \
--val_manifest <VAL_MANIFEST> \
--output_dir ./out/de_100h_ml \
--epochs 30 --batch_size 16 --grad_accum 3 --lr 1e-4 \
--early_stop_patience 8 --decay_spec_augment --seed 42
Example usage (paper EN init for the same cell):
torchrun --nproc_per_node=1 train_single_lang.py \
--lang de \
--resume_from <CKPT_DIR>/multilingual_base.nemo \
--encoder_from nvidia/nemotron-speech-streaming-en-0.6b \
--train_manifest <DATA_ROOT>/de/100h/train.jsonl \
--val_manifest <VAL_MANIFEST> \
--output_dir ./out/de_100h_en \
--epochs 30 --batch_size 16 --grad_accum 3 --lr 1e-4 \
--early_stop_patience 8 --decay_spec_augment --seed 42
Manifest format (one JSON object per line):
{"audio_filepath": "/abs/path/utt.wav", "duration": 8.4, "text": "reference transcript"}
`duration` (seconds) is required: it drives min/max-duration filtering and
the --max_train_hours subsampling.
Requirements:
pip install nemo_toolkit[asr] soundfile jiwer tqdm
Evaluation also requires Whisper's BasicMultilingualTextNormalizer from the
Open ASR Leaderboard repo (clone https://github.com/huggingface/open_asr_leaderboard
and add it to PYTHONPATH).
"""
import argparse
import json
import math
import os
import gc
import re
import sys
import unicodedata
from collections import defaultdict
import numpy as np
import torch
import torch.distributed as dist
import torch.nn as nn
import torch.nn.functional as F
from torch.nn.parallel import DistributedDataParallel as DDP
from torch.utils.data import DataLoader, DistributedSampler
from tqdm import tqdm
# Use Whisper's BasicMultilingualTextNormalizer for consistent eval
try:
from normalizer import BasicMultilingualTextNormalizer
_ml_normalizer = BasicMultilingualTextNormalizer()
_has_real_normalizer = True
except ImportError:
print(
"ERROR: could not import BasicMultilingualTextNormalizer. "
"This script requires Whisper's BasicMultilingualTextNormalizer, "
"shipped in the Open ASR Leaderboard repo. "
"Clone https://github.com/huggingface/open_asr_leaderboard and add it "
"to PYTHONPATH (or set OPEN_ASR_LB_ROOT).",
file=sys.stderr,
)
exit(1)
_ml_normalizer = None
_has_real_normalizer = False
# ═══════════════════════════════════════════════════════════
# DDP Utilities
# ═══════════════════════════════════════════════════════════
def setup_ddp():
"""Initialize distributed training. Returns (rank, world_size, local_rank, is_distributed)."""
if "RANK" in os.environ:
rank = int(os.environ["RANK"])
world_size = int(os.environ["WORLD_SIZE"])
local_rank = int(os.environ["LOCAL_RANK"])
from datetime import timedelta
dist.init_process_group("nccl", timeout=timedelta(minutes=60))
torch.cuda.set_device(local_rank)
return rank, world_size, local_rank, True
else:
return 0, 1, 0, False
def cleanup_ddp(is_distributed):
if is_distributed:
dist.destroy_process_group()
def is_main(rank):
return rank == 0
def print_rank0(msg, rank=0):
if is_main(rank):
print(msg, flush=True)
# ═══════════════════════════════════════════════════════════
# Configuration
# ═══════════════════════════════════════════════════════════
def parse_args():
p = argparse.ArgumentParser(
description="Single-language Nemotron Streaming ASR Training",
formatter_class=argparse.ArgumentDefaultsHelpFormatter,
)
# Language
p.add_argument("--lang", type=str, required=True,
help="Language code (e.g., de, es, fr, it, nl, sv, pt, pl)")
# Models
p.add_argument("--teacher", default="nvidia/parakeet-tdt-0.6b-v3",
help="Teacher model for tokenizer extraction")
p.add_argument("--student", default="nvidia/nemotron-speech-streaming-en-0.6b",
help="Student model (English, streaming)")
# Data
p.add_argument("--train_manifest", type=str, required=True,
help="Path to training manifest (JSONL)")
p.add_argument("--val_manifest", type=str, required=True,
help="Path to validation manifest (JSONL)")
# Training
p.add_argument("--output_dir", default="./nemotron_lang")
p.add_argument("--epochs", type=int, default=30)
p.add_argument("--batch_size", type=int, default=16,
help="Per-GPU batch size")
p.add_argument("--grad_accum", type=int, default=2,
help="Gradient accumulation steps")
p.add_argument("--lr", type=float, default=1e-4)
p.add_argument("--min_lr", type=float, default=1e-6)
p.add_argument("--weight_decay", type=float, default=1e-3)
p.add_argument("--warmup_epochs", type=int, default=1)
p.add_argument("--max_duration", type=float, default=20.0)
p.add_argument("--min_duration", type=float, default=0.3)
# SpecAugment
p.add_argument("--no_spec_augment", action="store_true", default=False)
p.add_argument("--freq_masks", type=int, default=2)
p.add_argument("--freq_width", type=int, default=27)
p.add_argument("--time_masks", type=int, default=10)
p.add_argument("--time_width", type=float, default=0.05)
# Speed perturbation
p.add_argument("--speed_perturb", action="store_true", default=True)
p.add_argument("--speed_perturb_factors", type=float, nargs='+', default=[0.9, 1.0, 1.1])
# Misc
p.add_argument("--freeze_encoder_epochs", type=int, default=0,
help="Freeze encoder for first N epochs")
p.add_argument("--reinit_encoder", action="store_true", default=False,
help="Randomly reinitialize all encoder weights (ablation). "
"NOT the paper's EN arm -- EN init uses --encoder_from "
"to copy the English encoder weights, not random init.")
p.add_argument("--reinit_joint", action="store_true", default=False,
help="Randomly reinitialize the RNNT joint network weights (ablation study). "
"Useful after swapping encoders so the joint relearns the encoder->vocab mapping.")
p.add_argument("--lr_decay_epochs", type=int, default=25,
help="Cosine decay reaches min_lr after N epochs (0=use total epochs)")
p.add_argument("--constant_lr", action="store_true", default=False)
p.add_argument("--log_every", type=int, default=50)
p.add_argument("--eval_every_epoch", type=int, default=1)
p.add_argument("--save_every_epoch", type=int, default=0,
help="Save training state every N epochs (0=disabled)")
p.add_argument("--early_stop_patience", type=int, default=30,
help="Stop if WER doesn't improve for N evals (0=disabled)")
p.add_argument("--grad_clip", type=float, default=1.0,
help="Gradient clipping max norm")
p.add_argument("--rnnt_clamp", type=float, default=-1.0,
help="RNNT loss per-frame clamping value (-1=disabled, 1.0=recommended)")
p.add_argument("--bf16", action="store_true", default=True)
p.add_argument("--fp16", action="store_true", default=False)
p.add_argument("--num_workers", type=int, default=4)
p.add_argument("--max_train_hours", type=float, default=0,
help="Limit training data to N hours (0=use all data). Samples randomly.")
p.add_argument("--data_seed", type=int, default=12345,
help="Seed for data subsampling (separate from training seed for reproducibility)")
p.add_argument("--seed", type=int, default=42)
p.add_argument("--resume_from", type=str, default=None,
help="Resume from .nemo checkpoint (the multilingual base for both "
"the ML and EN arms of the paper's main grid). Sets the "
"tokenizer, decoder and joint; the encoder is then either kept "
"(ML arm), overwritten via --encoder_from (EN arm), or "
"re-initialized via --reinit_encoder (ablation).")
p.add_argument("--encoder_from", type=str, default=None,
help="Overwrite encoder weights with those of this checkpoint after "
"--resume_from has loaded the multilingual base. This is how "
"the paper's EN arm is built: multilingual tokenizer/decoder/joint "
"+ English encoder (nvidia/nemotron-speech-streaming-en-0.6b).")
p.add_argument("--swap_joint_enc", action="store_true", default=False,
help="When using --encoder_from, also copy the joint network's encoder projection (enc linear + enc_hat) from the source model. Keeps encoder and joint.enc in sync.")
p.add_argument("--encoder_from_layers", type=str, default="all",
help="Which Conformer layer indices to copy from --encoder_from. "
"Examples: 'all' (default, full encoder), 'none' (skip layers, only use preencode/postnorm flags), "
"'0:8' (Python slice, layers 0..7), '-8:' (last 8 layers), '0:8,16:24' (multiple ranges). "
"Negative indices count from the end. Layers outside the slice stay from --resume_from/--student.")
p.add_argument("--encoder_from_preencode", type=str, default="off", choices=["auto", "on", "off"],
help="Copy the pre-encoder subsampling (conv frontend) and positional embeddings from --encoder_from. "
"Default 'off' keeps the destination model's preencode (ML baseline when --resume_from is set), "
"which is preferable for cross-lingual splices since the ML preencode has seen the target language. "
"'auto': on iff layer 0 is in --encoder_from_layers.")
p.add_argument("--encoder_from_postnorm", type=str, default="off", choices=["auto", "on", "off"],
help="Copy the final encoder norm/output projection from --encoder_from. "
"Default 'off' keeps the destination model's postnorm (ML baseline when --resume_from is set), "
"which is the natural pairing when the top layers also come from the destination. "
"'auto': on iff the last layer is in --encoder_from_layers.")
p.add_argument("--decay_spec_augment", action="store_true", default=False,
help="Linearly decay SpecAugment mask counts over training (time_masks: N->2, freq_masks: N->1)")
p.add_argument("--resume_training", type=str, default=None,
help="Resume training from a training_state.pt checkpoint (saved in output_dir). Restores optimizer, scheduler, epoch, and all training state.")
p.add_argument("--confidence_penalty", type=float, default=0.0,
help="Entropy regularization weight (0=off). Penalizes overconfident joint predictions. Try 0.1-0.3.")
p.add_argument("--streaming_chunk_sec", type=float, default=0,
help="Enable chunk-aware streaming training. Chunk duration in seconds (e.g., 1.2). 0=full context training.")
p.add_argument("--test_manifest", type=str, default=None,
help="Path to test manifest (JSONL) for final evaluation")
p.add_argument("--decoder_hidden", type=int, default=0,
help="Override RNNT decoder (prediction network) LSTM hidden size. 0=keep original (640). E.g., 860, 1024.")
p.add_argument("--decoder_layers", type=int, default=0,
help="Override RNNT decoder LSTM layer count. 0=keep original (2). E.g., 3, 4.")
return p.parse_args()
# ═══════════════════════════════════════════════════════════
# Tokenizer Extraction (from teacher)
# ═══════════════════════════════════════════════════════════
def extract_tokenizer(model, tokenizer_dir):
"""Extract tokenizer .model file from a NeMo ASR model."""
from pathlib import Path
os.makedirs(tokenizer_dir, exist_ok=True)
out_model = Path(tokenizer_dir) / "tokenizer.model"
tok = getattr(model, "tokenizer", None)
sp = getattr(tok, "tokenizer", None)
if sp is not None and hasattr(sp, "serialized_model_proto"):
blob = sp.serialized_model_proto()
if blob:
out_model.write_bytes(blob)
_generate_vocab_txt(tokenizer_dir)
vs = getattr(sp, "vocab_size", None)
if callable(vs):
vs = vs()
return str(Path(tokenizer_dir)), int(vs) if vs else 0
raise RuntimeError("Could not extract tokenizer from teacher model")
def _generate_vocab_txt(tokenizer_dir):
import sentencepiece as spm_lib
model_path = os.path.join(tokenizer_dir, "tokenizer.model")
vocab_path = os.path.join(tokenizer_dir, "vocab.txt")
if os.path.exists(vocab_path):
return
sp = spm_lib.SentencePieceProcessor()
sp.load(model_path)
with open(vocab_path, "w", encoding="utf-8") as f:
for i in range(sp.get_piece_size()):
f.write(sp.id_to_piece(i) + "\n")
# ═══════════════════════════════════════════════════════════
# Model Setup
# ═══════════════════════════════════════════════════════════
def setup_spec_augment(student, args):
from nemo.collections.asr.modules.audio_preprocessing import SpectrogramAugmentation
if args.no_spec_augment:
student.spec_augmentation = None
return
spec_aug = SpectrogramAugmentation(
freq_masks=args.freq_masks,
time_masks=args.time_masks,
freq_width=args.freq_width,
time_width=args.time_width,
)
student.spec_augmentation = spec_aug.to(next(student.parameters()).device)
def update_spec_augment(student, args, epoch, total_epochs, rank):
"""Linearly decay SpecAugment mask counts over training."""
if not args.decay_spec_augment or args.no_spec_augment:
return
from nemo.collections.asr.modules.audio_preprocessing import SpectrogramAugmentation
progress = epoch / max(1, total_epochs - 1)
new_time_masks = max(2, round(args.time_masks * (1 - progress)))
new_freq_masks = max(1, round(args.freq_masks * (1 - 0.5 * progress)))
model = student.module if isinstance(student, DDP) else student
spec_aug = SpectrogramAugmentation(
freq_masks=new_freq_masks,
time_masks=new_time_masks,
freq_width=args.freq_width,
time_width=args.time_width,
)
model.spec_augmentation = spec_aug.to(next(model.parameters()).device)
print_rank0(f" SpecAug decay: freq={new_freq_masks}x{args.freq_width} time={new_time_masks}x{args.time_width}", rank)
from omegaconf import open_dict
with open_dict(model.cfg):
model.cfg.spec_augment.freq_masks = new_freq_masks
model.cfg.spec_augment.time_masks = new_time_masks
model.cfg.spec_augment.freq_width = args.freq_width
model.cfg.spec_augment.time_width = args.time_width
def _parse_layer_slice(spec, num_layers):
"""Parse a slice spec like 'all', 'none', '0:8', '-8:', '0:8,16:24' into a sorted set of indices.
Supports Python-style slice ranges, comma-separated. Negative indices count from num_layers.
Returns a set of ints in [0, num_layers).
"""
if spec is None:
return set()
s = spec.strip().lower()
if s in ("all", "*"):
return set(range(num_layers))
if s in ("none", ""):
return set()
out = set()
for part in s.split(","):
part = part.strip()
if not part:
continue
if ":" in part:
lo_s, hi_s = part.split(":", 1)
lo = int(lo_s) if lo_s else 0
hi = int(hi_s) if hi_s else num_layers
if lo < 0:
lo += num_layers
if hi < 0:
hi += num_layers
lo = max(0, min(num_layers, lo))
hi = max(0, min(num_layers, hi))
out.update(range(lo, hi))
else:
idx = int(part)
if idx < 0:
idx += num_layers
if 0 <= idx < num_layers:
out.add(idx)
return out
def _splice_encoder(dst_encoder, src_encoder, layer_indices, include_preencode, include_postnorm, rank):
"""Merge src_encoder weights into dst_encoder for the given layer indices, plus optional
preencode (subsampling + positional encoding) and postnorm modules.
Layer keys are expected to start with 'layers.<i>.'. Everything else is treated as
'preencode-like' if its name matches pre_encode/pos_enc/embedding, or 'postnorm-like' otherwise.
"""
src_sd = src_encoder.state_dict()
dst_sd = dst_encoder.state_dict()
PREENC_PREFIXES = ("pre_encode", "pos_enc", "pos_embedding", "pos_embed", "embedding")
copied_layers = set()
copied_pre = []
copied_post = []
skipped_shape = []
skipped_missing = []
for k, v in src_sd.items():
if k.startswith("layers."):
try:
idx = int(k.split(".", 2)[1])
except (ValueError, IndexError):
continue
if idx not in layer_indices:
continue
target_key = k
bucket = ("layer", idx)
elif any(k.startswith(p) for p in PREENC_PREFIXES):
if not include_preencode:
continue
target_key = k
bucket = ("pre", k)
else:
if not include_postnorm:
continue
target_key = k
bucket = ("post", k)
if target_key not in dst_sd:
skipped_missing.append(target_key)
continue
if dst_sd[target_key].shape != v.shape:
skipped_shape.append((target_key, tuple(v.shape), tuple(dst_sd[target_key].shape)))
continue
dst_sd[target_key] = v
if bucket[0] == "layer":
copied_layers.add(bucket[1])
elif bucket[0] == "pre":
copied_pre.append(target_key)
else:
copied_post.append(target_key)
missing, unexpected = dst_encoder.load_state_dict(dst_sd, strict=False)
print_rank0(
f" Encoder splice: copied layers {sorted(copied_layers)} "
f"({len(copied_layers)} of {len(layer_indices)} requested)", rank
)
if copied_pre:
print_rank0(f" Encoder splice: copied {len(copied_pre)} preencode keys", rank)
if copied_post:
print_rank0(f" Encoder splice: copied {len(copied_post)} postnorm/other keys", rank)
if skipped_shape:
print_rank0(f" WARNING: skipped {len(skipped_shape)} keys due to shape mismatch (first: {skipped_shape[0]})", rank)
if skipped_missing:
print_rank0(f" WARNING: skipped {len(skipped_missing)} keys missing in dst encoder (first: {skipped_missing[0]})", rank)
def load_student(args, device, rank):
"""Load student model, optionally swap tokenizer."""
import nemo.collections.asr as nemo_asr
if args.resume_from:
print_rank0(f" Resuming from: {args.resume_from}", rank)
student = nemo_asr.models.ASRModel.restore_from(args.resume_from, map_location='cpu')
print_rank0(f" Vocab: {student.tokenizer.vocab_size} tokens", rank)
args.freeze_encoder_epochs = 0
# Optionally override encoder weights from a different model (e.g., English)
if args.encoder_from:
print_rank0(f" Loading encoder from: {args.encoder_from}", rank)
if args.encoder_from.endswith('.nemo'):
encoder_model = nemo_asr.models.ASRModel.restore_from(args.encoder_from, map_location='cpu')
else:
encoder_model = nemo_asr.models.ASRModel.from_pretrained(args.encoder_from, map_location='cpu')
# Determine number of Conformer layers from the source encoder
src_layers_attr = getattr(encoder_model.encoder, "layers", None)
num_layers = len(src_layers_attr) if src_layers_attr is not None else 0
dst_layers_attr = getattr(student.encoder, "layers", None)
dst_num_layers = len(dst_layers_attr) if dst_layers_attr is not None else 0
if num_layers == 0 or dst_num_layers == 0:
raise RuntimeError(
f"Could not locate '.encoder.layers' on src ({num_layers}) or dst ({dst_num_layers}); "
f"layer splicing requires a Conformer-style encoder with .layers nn.ModuleList."
)
if num_layers != dst_num_layers:
print_rank0(
f" WARNING: src encoder has {num_layers} layers but dst has {dst_num_layers}; "
f"only layers present in both will be copied.", rank
)
spec = args.encoder_from_layers or "all"
effective_layers = min(num_layers, dst_num_layers)
layer_indices = _parse_layer_slice(spec, effective_layers)
# Auto-detect: preencode if EN provides layer 0; postnorm if EN provides last layer.
auto_preencode = 0 in layer_indices
auto_postnorm = (effective_layers - 1) in layer_indices
def _resolve(flag, auto_value, name):
if flag == "on":
return True
if flag == "off":
return False
return auto_value # "auto"
include_preencode = _resolve(args.encoder_from_preencode, auto_preencode, "preencode")
include_postnorm = _resolve(args.encoder_from_postnorm, auto_postnorm, "postnorm")
# Fast path: entire encoder copied (all layers + both boundaries) -> direct load_state_dict.
full_copy = (
len(layer_indices) == effective_layers
and include_preencode
and include_postnorm
and num_layers == dst_num_layers
)
if full_copy:
student.encoder.load_state_dict(encoder_model.encoder.state_dict())
enc_params = sum(p.numel() for p in student.encoder.parameters()) / 1e6
print_rank0(f" Encoder fully swapped: {enc_params:.1f}M params from {args.encoder_from}", rank)
else:
print_rank0(
f" Encoder splice spec='{spec}' ({len(layer_indices)}/{effective_layers} layers); "
f"preencode={include_preencode} ({args.encoder_from_preencode}"
f"{' -> auto=' + str(auto_preencode) if args.encoder_from_preencode == 'auto' else ''}), "
f"postnorm={include_postnorm} ({args.encoder_from_postnorm}"
f"{' -> auto=' + str(auto_postnorm) if args.encoder_from_postnorm == 'auto' else ''})", rank
)
_splice_encoder(
student.encoder,
encoder_model.encoder,
layer_indices,
include_preencode=include_preencode,
include_postnorm=include_postnorm,
rank=rank,
)
# Optionally also swap the joint network's encoder-side projection
if args.swap_joint_enc:
swapped_keys = []
src_joint_sd = encoder_model.joint.state_dict()
dst_joint_sd = student.joint.state_dict()
for key in src_joint_sd:
# Match encoder-side projection layers (enc, enc_hat, etc.)
if 'enc' in key and key in dst_joint_sd and src_joint_sd[key].shape == dst_joint_sd[key].shape:
dst_joint_sd[key] = src_joint_sd[key]
swapped_keys.append(key)
if swapped_keys:
student.joint.load_state_dict(dst_joint_sd)
print_rank0(f" Joint encoder projection swapped: {swapped_keys}", rank)
else:
print_rank0(f" WARNING: --swap_joint_enc set but no matching joint.enc keys found", rank)
del encoder_model
else:
# Extract teacher tokenizer (only rank 0 does this, then all read from disk)
tokenizer_dir = os.path.join(args.output_dir, "teacher_tokenizer")
if is_main(rank):
print_rank0(f" Loading teacher for tokenizer: {args.teacher}", rank)
teacher = nemo_asr.models.ASRModel.from_pretrained(args.teacher)
tokenizer_dir, teacher_vocab_size = extract_tokenizer(teacher, tokenizer_dir)
print_rank0(f" Teacher vocab: {teacher_vocab_size}", rank)
del teacher
torch.cuda.empty_cache()
if dist.is_initialized():
dist.barrier()
# Load student
print_rank0(f" Loading student: {args.student}", rank)
student = nemo_asr.models.ASRModel.from_pretrained(args.student)
old_vocab = student.tokenizer.vocab_size
student.change_vocabulary(new_tokenizer_dir=tokenizer_dir, new_tokenizer_type="bpe")
new_vocab = student.tokenizer.vocab_size
print_rank0(f" Tokenizer swap: {old_vocab}{new_vocab}", rank)
# Optionally resize decoder (prediction network)
if args.decoder_hidden > 0 or args.decoder_layers > 0:
from omegaconf import open_dict, OmegaConf
old_hidden = student.cfg.decoder.prednet.pred_hidden
old_layers = student.cfg.decoder.prednet.pred_rnn_layers
new_hidden = args.decoder_hidden if args.decoder_hidden > 0 else old_hidden
new_layers = args.decoder_layers if args.decoder_layers > 0 else old_layers
with open_dict(student.cfg):
student.cfg.decoder.prednet.pred_hidden = new_hidden
student.cfg.decoder.prednet.pred_rnn_layers = new_layers
# Rebuild decoder + joint with new dimensions
from nemo.collections.asr.modules import RNNTDecoder, RNNTJoint
student.decoder = RNNTDecoder(
prednet=OmegaConf.to_container(student.cfg.decoder.prednet, resolve=True),
vocab_size=student.tokenizer.vocab_size,
normalization_mode=student.cfg.decoder.get('normalization_mode', None),
random_state_sampling=student.cfg.decoder.get('random_state_sampling', False),
blank_as_pad=student.cfg.decoder.get('blank_as_pad', True),
)
# Rebuild joint network to match new decoder hidden
with open_dict(student.cfg):
student.cfg.joint.jointnet.pred_hidden = new_hidden
student.cfg.joint.jointnet.encoder_hidden = student.cfg.encoder.d_model
student.cfg.joint.num_classes = student.tokenizer.vocab_size
joint_cfg = OmegaConf.to_container(student.cfg.joint, resolve=True)
joint_cfg.pop('_target_', None)
joint_cfg.pop('vocabulary', None)
student.joint = RNNTJoint(**joint_cfg)
dec_params = sum(p.numel() for p in student.decoder.parameters()) / 1e6
joint_params = sum(p.numel() for p in student.joint.parameters()) / 1e6
print_rank0(f" Decoder resized: hidden {old_hidden}->{new_hidden}, layers {old_layers}->{new_layers}", rank)
print_rank0(f" New decoder params: {dec_params:.1f}M, joint params: {joint_params:.1f}M", rank)
student = student.to(device)
# Optionally reinitialize encoder weights (ablation study)
if args.reinit_encoder:
print_rank0(" REINITIALIZING ENCODER WEIGHTS (random init)", rank)
for name, param in student.encoder.named_parameters():
if param.dim() >= 2:
torch.nn.init.xavier_uniform_(param)
else:
torch.nn.init.zeros_(param)
# Also reinit batch norm running stats
for module in student.encoder.modules():
if isinstance(module, (torch.nn.BatchNorm1d, torch.nn.BatchNorm2d)):
module.reset_running_stats()
enc_params = sum(p.numel() for p in student.encoder.parameters())
print_rank0(f" Reinitialized {enc_params/1e6:.1f}M encoder parameters", rank)
# Optionally reinitialize joint network weights (ablation study)
if args.reinit_joint:
print_rank0(" REINITIALIZING JOINT NETWORK WEIGHTS (random init)", rank)
# Re-seed RNG with a fixed value so ML and EN arms get IDENTICAL joint init
# (independent of prior RNG state consumed by different checkpoint loads).
# Using args.seed (not args.seed+rank) ensures same init across DDP ranks too.
_joint_seed = args.seed
_gen_state_cpu = torch.random.get_rng_state()
_gen_state_cuda = torch.cuda.get_rng_state_all() if torch.cuda.is_available() else None
torch.manual_seed(_joint_seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(_joint_seed)
print_rank0(f" Joint reinit RNG seeded with {_joint_seed} (identical across ML/EN arms)", rank)
for name, param in student.joint.named_parameters():
if param.dim() >= 2:
torch.nn.init.xavier_uniform_(param)
else:
torch.nn.init.zeros_(param)
for module in student.joint.modules():
if isinstance(module, (torch.nn.BatchNorm1d, torch.nn.BatchNorm2d)):
module.reset_running_stats()
# Restore prior RNG state so training stochasticity is unaffected
torch.random.set_rng_state(_gen_state_cpu)
if _gen_state_cuda is not None:
torch.cuda.set_rng_state_all(_gen_state_cuda)
joint_params = sum(p.numel() for p in student.joint.parameters())
print_rank0(f" Reinitialized {joint_params/1e6:.1f}M joint parameters", rank)
# SpecAugment
setup_spec_augment(student, args)
# Streaming chunk-aware training: restrict attention context
if args.streaming_chunk_sec > 0:
# Force single attention context mode [70, 13] instead of random multi-context
# Default model has 4 modes: [70,13], [70,6], [70,1], [70,0] sampled randomly
# This forces always using [70, 13] (largest context, lowest latency mode)
student.encoder.att_context_size = [70, 13]
student.encoder.att_context_size_all = [[70, 13]]
student.encoder.att_context_probs = [1.0]
print_rank0(f" Streaming training: forced att_context=[70,13] only (no multi-context)", rank)
# Disable CUDA graphs and typecheck
from omegaconf import open_dict
from nemo.core.classes.common import typecheck
typecheck.set_typecheck_enabled(False)
with open_dict(student.cfg):
student.cfg.decoding.greedy.use_cuda_graph_decoder = False
student.change_decoding_strategy(student.cfg.decoding)
# Override RNNT loss clamping if requested
if args.rnnt_clamp > 0:
from nemo.collections.asr.losses.rnnt import RNNTLoss
with open_dict(student.cfg):
student.cfg.loss.warprnnt_numba_kwargs.clamp = args.rnnt_clamp
student.loss = RNNTLoss(num_classes=student.decoder.vocab_size, loss_name='default',
loss_kwargs=dict(student.cfg.loss.warprnnt_numba_kwargs))
print_rank0(f" RNNT loss clamping: {args.rnnt_clamp}", rank)
params = sum(p.numel() for p in student.parameters()) / 1e6
print_rank0(f" Student params: {params:.1f}M", rank)
return student
# ═══════════════════════════════════════════════════════════
# Dataset & DataLoader
# ═══════════════════════════════════════════════════════════
class ASRManifestDataset(torch.utils.data.Dataset):
def __init__(self, manifest_path, tokenizer, min_duration=0.3, max_duration=20.0,
speed_perturb=False, speed_perturb_factors=None,
max_train_hours=0, seed=42):
self.tokenizer = tokenizer
self.speed_perturb = speed_perturb
self.speed_perturb_factors = speed_perturb_factors or [0.9, 1.0, 1.1]
self.samples = []
with open(manifest_path) as f:
for line in f:
item = json.loads(line)
dur = item["duration"]
if min_duration <= dur <= max_duration:
self.samples.append(item)
# Subsample to max_train_hours if specified
if max_train_hours > 0:
target_seconds = max_train_hours * 3600
rng = np.random.RandomState(seed)
rng.shuffle(self.samples)
selected = []
total_dur = 0.0
for s in self.samples:
if total_dur >= target_seconds:
break
selected.append(s)
total_dur += s["duration"]
self.samples = selected
self.total_hours = total_dur / 3600
def __len__(self):
return len(self.samples)
def __getitem__(self, idx):
import soundfile as sf
item = self.samples[idx]
try:
audio, sr = sf.read(item["audio_filepath"], dtype="float32")
except Exception as e:
print(f" Corrupt audio: {item['audio_filepath']} ({e})", flush=True)
return None
if sr != 16000:
ratio = 16000 / sr
new_len = int(len(audio) * ratio)
audio = np.interp(
np.linspace(0, len(audio) - 1, new_len),
np.arange(len(audio)), audio,
).astype(np.float32)
# Speed perturbation
if self.speed_perturb:
import random
speed = random.choice(self.speed_perturb_factors)
if speed != 1.0:
new_len = int(len(audio) / speed)
audio = np.interp(
np.linspace(0, len(audio) - 1, new_len),
np.arange(len(audio)), audio,
).astype(np.float32)
audio_tensor = torch.FloatTensor(audio)
text = unicodedata.normalize("NFKC", item["text"])
text = " ".join(text.split())
tokens = torch.LongTensor(self.tokenizer.text_to_ids(text))
return audio_tensor, tokens
def collate_asr(batch):
batch = [b for b in batch if b is not None]
if len(batch) == 0:
return None
audios = [b[0] for b in batch]
tokens_list = [b[1] for b in batch]
audio_lens = torch.LongTensor([len(a) for a in audios])
token_lens = torch.LongTensor([len(t) for t in tokens_list])
max_audio = audio_lens.max().item()
max_tokens = token_lens.max().item()
B = len(audios)
padded_audio = torch.zeros(B, max_audio)
padded_tokens = torch.zeros(B, max_tokens, dtype=torch.long)
for i in range(B):
padded_audio[i, :audio_lens[i]] = audios[i]
padded_tokens[i, :token_lens[i]] = tokens_list[i]
return padded_audio, audio_lens, padded_tokens, token_lens
# ═══════════════════════════════════════════════════════════
# Training Step
# ═══════════════════════════════════════════════════════════
def train_step(student, batch, device, confidence_penalty=0.0):
"""Single forward/backward step: RNNT loss + optional entropy regularization."""
audio, audio_len, tokens, token_len = batch
audio = audio.to(device)
audio_len = audio_len.to(device)
tokens = tokens.to(device)
token_len = token_len.to(device)
model = student.module if isinstance(student, DDP) else student
# Mel spectrogram
mel, mel_len = model.preprocessor(input_signal=audio, length=audio_len)
# Spec augmentation
if model.spec_augmentation is not None and model.training:
mel = model.spec_augmentation(input_spec=mel, length=mel_len)
# Encoder
enc, enc_len = model.encoder(audio_signal=mel, length=mel_len)
# Decoder
dec_out = model.decoder(targets=tokens, target_length=token_len)
if isinstance(dec_out, tuple):
dec_out = dec_out[0]
# Joint + RNNT loss
if getattr(model.joint, 'fuse_loss_wer', False):
result = model.joint(
encoder_outputs=enc, decoder_outputs=dec_out,
encoder_lengths=enc_len, transcripts=tokens,
transcript_lengths=token_len, compute_wer=False,
)
loss = result[0]
else:
joint_out = model.joint(encoder_outputs=enc, decoder_outputs=dec_out)
loss = model.loss(
log_probs=joint_out, targets=tokens,
input_lengths=enc_len, target_lengths=token_len,
)
if loss.dim() > 0:
loss = loss.mean()
# Confidence penalty: negative entropy regularization on joint output
# Encourages less confident (more spread) predictions, acts like label smoothing
if confidence_penalty > 0.0:
# Extra forward pass through joint to get logits (works with fuse_loss_wer too)
joint_logits = model.joint(encoder_outputs=enc, decoder_outputs=dec_out)
# joint_logits: (B, T, U, V) log-probabilities
probs = torch.exp(joint_logits)
entropy = -(probs * joint_logits).sum(dim=-1) # (B, T, U)
# Maximize entropy = minimize negative entropy = subtract from loss
loss = loss - confidence_penalty * entropy.mean()
return loss
# ═══════════════════════════════════════════════════════════
# Evaluation
# ═══════════════════════════════════════════════════════════
def normalize_text(text):
if _ml_normalizer is not None:
return _ml_normalizer(text)
text = unicodedata.normalize('NFKC', text)
text = text.lower()
text = re.sub(r'[^\w\s]', '', text)
return ' '.join(text.split())
def normalize_text_fallback(text):
"""Always use fallback normalizer for consistency with older runs."""
text = unicodedata.normalize('NFKC', text)
text = text.lower()
text = re.sub(r'[^\w\s]', '', text)
return ' '.join(text.split())
def simple_wer(ref_words, hyp_words):
n, m = len(ref_words), len(hyp_words)
dp = [[0] * (m + 1) for _ in range(n + 1)]
for i in range(n + 1): dp[i][0] = i
for j in range(m + 1): dp[0][j] = j
for i in range(1, n + 1):
for j in range(1, m + 1):
dp[i][j] = dp[i-1][j-1] if ref_words[i-1] == hyp_words[j-1] \
else 1 + min(dp[i-1][j], dp[i][j-1], dp[i-1][j-1])
return dp[n][m]
def compute_wer_ids(ref_words, hyp_words):
"""Edit distance with backtrace to get S/D/I counts."""
n, m = len(ref_words), len(hyp_words)
dp = [[0] * (m + 1) for _ in range(n + 1)]
for i in range(n + 1): dp[i][0] = i
for j in range(m + 1): dp[0][j] = j
for i in range(1, n + 1):
for j in range(1, m + 1):
if ref_words[i - 1] == hyp_words[j - 1]:
dp[i][j] = dp[i - 1][j - 1]
else:
dp[i][j] = 1 + min(dp[i - 1][j], dp[i][j - 1], dp[i - 1][j - 1])
subs, dels, ins = 0, 0, 0
i, j = n, m
while i > 0 or j > 0:
if i > 0 and j > 0 and ref_words[i - 1] == hyp_words[j - 1]:
i -= 1; j -= 1
elif i > 0 and j > 0 and dp[i][j] == dp[i - 1][j - 1] + 1:
subs += 1; i -= 1; j -= 1
elif i > 0 and dp[i][j] == dp[i - 1][j] + 1:
dels += 1; i -= 1
else:
ins += 1; j -= 1
return subs, dels, ins
@torch.no_grad()
def evaluate_batch(student, manifest_path, device, max_samples=None, normalizer_fn=None, rank=0):
"""Evaluate WER using batch (non-streaming) inference."""
import soundfile as sf_eval
if normalizer_fn is None:
normalizer_fn = normalize_text
model = student.module if isinstance(student, DDP) else student
model.eval()
samples = []
with open(manifest_path) as f:
for line in f:
samples.append(json.loads(line))
if max_samples and len(samples) > max_samples:
samples = samples[:max_samples]
total_edits, total_words = 0, 0
total_subs, total_dels, total_ins = 0, 0, 0
errors = 0
batch_size = 16
examples = []
total_batches = (len(samples) + batch_size - 1) // batch_size
for start in range(0, len(samples), batch_size):
batch_samples = samples[start:start + batch_size]
batch_num = start // batch_size + 1
if (batch_num % 10 == 0 or batch_num == 1) and rank == 0:
print(f" [eval batch {batch_num}/{total_batches}]", flush=True)
try:
audios = []
for s in batch_samples:
audio, sr = sf_eval.read(s["audio_filepath"], dtype="float32")
if len(audio.shape) > 1:
audio = audio.mean(axis=1)
audios.append(torch.FloatTensor(audio))
audio_lens = torch.LongTensor([len(a) for a in audios])
max_len = audio_lens.max().item()
padded = torch.zeros(len(audios), max_len)
for i, a in enumerate(audios):
padded[i, :len(a)] = a
padded = padded.to(device)
audio_lens = audio_lens.to(device)
mel, mel_len = model.preprocessor(input_signal=padded, length=audio_lens)
enc, enc_len = model.encoder(audio_signal=mel, length=mel_len)
best_hyps = model.decoding.rnnt_decoder_predictions_tensor(enc, enc_len)
if isinstance(best_hyps, tuple):
best_hyps = best_hyps[0]
for s, hyp in zip(batch_samples, best_hyps):
if hasattr(hyp, 'text') and hyp.text:
pred = hyp.text
elif hasattr(hyp, 'y_sequence'):
tids = hyp.y_sequence.tolist() if torch.is_tensor(hyp.y_sequence) else list(hyp.y_sequence)
pred = model.tokenizer.ids_to_text(tids) if tids else ""
else:
pred = str(hyp)
ref_n = normalizer_fn(s["text"])
pred_n = normalizer_fn(pred)
ref_words = ref_n.split()
pred_words = pred_n.split()
if ref_words:
sub_c, del_c, ins_c = compute_wer_ids(ref_words, pred_words)
total_subs += sub_c
total_dels += del_c
total_ins += ins_c
total_edits += sub_c + del_c + ins_c
total_words += len(ref_words)
if len(examples) < 5:
examples.append((s["text"][:55], pred[:55]))
except Exception as e:
errors += 1
if errors <= 3 and rank == 0:
print(f" [batch eval error] {type(e).__name__}: {e}")
wer_score = total_edits / max(total_words, 1) * 100
if normalizer_fn is normalize_text and rank == 0: # Only print examples for primary eval
print(f"\n {'Reference':<55} | {'Prediction':<55}")
print(f" {'-'*55} | {'-'*55}")
for ref, pred in examples:
print(f" {ref:<55} | {pred:<55}")
if errors:
print(f" ({errors} batch eval errors)")
model.train()
return wer_score, total_subs, total_dels, total_ins, total_words
@torch.no_grad()
def evaluate_streaming(student, manifest_path, device, max_samples=None, rank=0):
"""Evaluate WER using streaming inference."""
import soundfile as sf_eval
from nemo.collections.asr.parts.utils.streaming_utils import CacheAwareStreamingAudioBuffer
model = student.module if isinstance(student, DDP) else student
model.eval()
right_context = 13
chunk_frames = 1 + right_context
model.encoder.setup_streaming_params(
chunk_size=chunk_frames,
shift_size=chunk_frames,
left_chunks=70 // max(chunk_frames, 1),
)
samples = []
with open(manifest_path) as f:
for line in f:
samples.append(json.loads(line))
if max_samples and len(samples) > max_samples:
samples = samples[:max_samples]
total_edits, total_words = 0, 0
total_subs, total_dels, total_ins = 0, 0, 0
examples = []
errors = 0
for s in samples:
try:
audio, sr = sf_eval.read(s["audio_filepath"], dtype="float32")
if len(audio.shape) > 1:
audio = audio.mean(axis=1)
buffer = CacheAwareStreamingAudioBuffer(model=model)
buffer.append_audio(audio)
cache_last_channel, cache_last_time, cache_last_channel_len = \
model.encoder.get_initial_cache_state(batch_size=1, dtype=torch.float32, device=device)
previous_hypotheses = None
pred = ""
for chunk_audio, chunk_len in buffer:
if chunk_audio is None:
break
result = model.conformer_stream_step(
processed_signal=chunk_audio,
processed_signal_length=chunk_len,
cache_last_channel=cache_last_channel,
cache_last_time=cache_last_time,
cache_last_channel_len=cache_last_channel_len,
previous_hypotheses=previous_hypotheses,
return_transcription=True,
)
if isinstance(result, tuple) and len(result) >= 6:
cache_last_channel = result[2]
cache_last_time = result[3]
cache_last_channel_len = result[4]
previous_hypotheses = result[5]
if result[5] and len(result[5]) > 0:
hyp = result[5][0]
new_text = ""
if hasattr(hyp, 'text') and hyp.text:
new_text = hyp.text
elif hasattr(hyp, 'y_sequence'):
tids = hyp.y_sequence.tolist() if torch.is_tensor(hyp.y_sequence) else list(hyp.y_sequence)
if tids:
new_text = model.tokenizer.ids_to_text(tids)
if new_text and len(new_text) > len(pred):
pred = new_text
ref_n = normalize_text(s["text"])
pred_n = normalize_text(pred)
ref_words = ref_n.split()
pred_words = pred_n.split()
if ref_words:
sub_c, del_c, ins_c = compute_wer_ids(ref_words, pred_words)
total_subs += sub_c
total_dels += del_c
total_ins += ins_c
total_edits += sub_c + del_c + ins_c
total_words += len(ref_words)
if len(examples) < 5:
examples.append((s["text"][:55], pred[:55]))
except Exception as e:
errors += 1
if errors <= 3 and rank == 0:
print(f" [streaming eval error] {type(e).__name__}: {e}")
wer_score = total_edits / max(total_words, 1) * 100
if rank == 0:
print(f"\n {'Reference':<55} | {'Prediction':<55}")
print(f" {'-'*55} | {'-'*55}")
for ref, pred in examples:
print(f" {ref:<55} | {pred:<55}")
if errors:
print(f" ({errors} samples failed)")
model.train()
return wer_score, total_subs, total_dels, total_ins, total_words
@torch.no_grad()
def compute_val_loss(student, manifest_path, device, max_samples=500):
"""Compute RNNT loss on validation set."""
import soundfile as sf_val
model = student.module if isinstance(student, DDP) else student
model.eval()
samples = []
with open(manifest_path) as f:
for line in f:
samples.append(json.loads(line))
if max_samples and len(samples) > max_samples:
samples = samples[:max_samples]
total_loss = 0.0
count = 0
for s in samples:
try:
audio, sr = sf_val.read(s["audio_filepath"], dtype="float32")
if len(audio.shape) > 1:
audio = audio.mean(axis=1)
text = unicodedata.normalize("NFKC", s["text"])
text = " ".join(text.split())
tokens = model.tokenizer.text_to_ids(text)
if not tokens:
continue
audio_tensor = torch.FloatTensor(audio).unsqueeze(0).to(device)
audio_len = torch.LongTensor([len(audio)]).to(device)
token_tensor = torch.LongTensor([tokens]).to(device)
token_len = torch.LongTensor([len(tokens)]).to(device)
mel, mel_len = model.preprocessor(input_signal=audio_tensor, length=audio_len)
enc, enc_len = model.encoder(audio_signal=mel, length=mel_len)
dec_out = model.decoder(targets=token_tensor, target_length=token_len)
if isinstance(dec_out, tuple):
dec_out = dec_out[0]
if getattr(model.joint, 'fuse_loss_wer', False):
result = model.joint(
encoder_outputs=enc, decoder_outputs=dec_out,
encoder_lengths=enc_len, transcripts=token_tensor,
transcript_lengths=token_len, compute_wer=False,
)
loss = result[0]
else:
joint_out = model.joint(encoder_outputs=enc, decoder_outputs=dec_out)
loss = model.loss(log_probs=joint_out, targets=token_tensor,
input_lengths=enc_len, target_lengths=token_len)
if loss.dim() > 0:
loss = loss.mean()
total_loss += loss.item()
count += 1
except Exception:
continue
model.train()
return total_loss / max(count, 1)
# ═══════════════════════════════════════════════════════════
# LR Schedule
# ═══════════════════════════════════════════════════════════
def get_cosine_schedule(optimizer, warmup_steps, total_steps, min_lr=1e-6):
base_lr = optimizer.defaults["lr"]
def lr_lambda(step):
if step < warmup_steps:
return max(1e-8 / base_lr, step / max(1, warmup_steps))
progress = min(1.0, (step - warmup_steps) / max(1, total_steps - warmup_steps))
return (min_lr + 0.5 * (base_lr - min_lr) * (1.0 + math.cos(math.pi * progress))) / base_lr
return torch.optim.lr_scheduler.LambdaLR(optimizer, lr_lambda)
def get_constant_schedule(optimizer, warmup_steps):
base_lr = optimizer.defaults["lr"]
def lr_lambda(step):
if step < warmup_steps:
return max(1e-8 / base_lr, step / max(1, warmup_steps))
return 1.0
return torch.optim.lr_scheduler.LambdaLR(optimizer, lr_lambda)
# ═══════════════════════════════════════════════════════════
# Main Training Loop
# ═══════════════════════════════════════════════════════════
def train(student, train_loader, train_sampler, args, device, rank, is_distributed):
os.makedirs(args.output_dir, exist_ok=True)
lang = args.lang.upper()
model = student.module if isinstance(student, DDP) else student
trainable_params = [p for p in student.parameters() if p.requires_grad]
optimizer = torch.optim.AdamW(
trainable_params,
lr=args.lr,
weight_decay=args.weight_decay,
betas=(0.9, 0.98),
eps=1e-9,
)
steps_per_epoch = len(train_loader) // args.grad_accum
total_steps = steps_per_epoch * args.epochs
warmup_steps = steps_per_epoch * args.warmup_epochs
if args.constant_lr:
scheduler = get_constant_schedule(optimizer, warmup_steps)
else:
decay_epochs = args.lr_decay_epochs if args.lr_decay_epochs > 0 else args.epochs
cosine_total_steps = steps_per_epoch * decay_epochs
scheduler = get_cosine_schedule(optimizer, warmup_steps, cosine_total_steps, args.min_lr)
use_amp = args.bf16 or args.fp16
amp_dtype = torch.bfloat16 if args.bf16 else torch.float16
scaler = torch.amp.GradScaler("cuda") if args.fp16 else None
effective_batch = args.batch_size * args.grad_accum
if is_distributed:
world_size = dist.get_world_size()
effective_batch *= world_size
else:
world_size = 1
starting_from = args.resume_from if args.resume_from else args.student
print_rank0(f"\n{'='*65}", rank)
print_rank0(f" {lang} Training Configuration", rank)
print_rank0(f"{'='*65}", rank)
print_rank0(f" Language: {lang}", rank)
print_rank0(f" Starting from: {starting_from}", rank)
print_rank0(f" GPUs: {world_size}", rank)
print_rank0(f" Train samples: {len(train_loader.dataset)}", rank)
print_rank0(f" Per-GPU batch: {args.batch_size}", rank)
print_rank0(f" Effective batch: {args.batch_size} x {args.grad_accum} x {world_size} = {effective_batch}", rank)
print_rank0(f" Steps/epoch: {steps_per_epoch}", rank)
print_rank0(f" Total steps: {total_steps}", rank)
print_rank0(f" Warmup steps: {warmup_steps}", rank)
print_rank0(f" Learning rate: {args.lr} ({'constant' if args.constant_lr else 'cosine decay'})", rank)
print_rank0(f" Min LR: {args.min_lr}", rank)
print_rank0(f" Freeze encoder: first {args.freeze_encoder_epochs} epochs", rank)
print_rank0(f" Mixed precision: {'bf16' if args.bf16 else 'fp16' if args.fp16 else 'off'}", rank)
print_rank0(f" Weight decay: {args.weight_decay}", rank)
print_rank0(f" Grad clip norm: {args.grad_clip}", rank)
if args.no_spec_augment:
print_rank0(f" SpecAugment: OFF", rank)
else:
print_rank0(f" SpecAugment: freq={args.freq_masks}x{args.freq_width} time={args.time_masks}x{args.time_width}", rank)
print_rank0(f" Speed perturb: {args.speed_perturb_factors if args.speed_perturb else 'OFF'}", rank)
print_rank0(f" LR decay epochs: {args.lr_decay_epochs}", rank)
print_rank0(f" Early stop: {args.early_stop_patience} epochs", rank)
if args.confidence_penalty > 0:
print_rank0(f" Confidence penalty: {args.confidence_penalty}", rank)
if args.streaming_chunk_sec > 0:
print_rank0(f" Streaming train: forced att_context=[70,13] only", rank)
print_rank0(f" Val manifest: {args.val_manifest}", rank)
print_rank0(f"{'='*65}\n", rank)
global_step = 0
best_wer = float("inf")
best_val_loss = float("inf")
patience_counter = 0
start_epoch = 0
# Track top-K best WER checkpoints
top_k_wer = 3
top_k_checkpoints = [] # list of (wer, epoch, path)
# Track WER per epoch for convergence analysis
wer_history = []
import time as time_module
# Resume from training checkpoint if specified
if args.resume_training:
ckpt_path = args.resume_training
if os.path.isdir(ckpt_path):
# Load latest model weights if available
latest_model_path = os.path.join(ckpt_path, "latest_model.pt")
if os.path.exists(latest_model_path):
print_rank0(f" Loading latest model weights from: {latest_model_path}", rank)
sd = torch.load(latest_model_path, map_location=device, weights_only=False)
model.load_state_dict(sd)
del sd
torch.cuda.empty_cache()
ckpt_path = os.path.join(ckpt_path, "training_state.pt")
if os.path.exists(ckpt_path):
print_rank0(f" Resuming training state from: {ckpt_path}", rank)
ckpt = torch.load(ckpt_path, map_location=device, weights_only=False)
optimizer.load_state_dict(ckpt["optimizer"])
scheduler.load_state_dict(ckpt["scheduler"])
start_epoch = ckpt["epoch"]
global_step = ckpt["global_step"]
best_wer = ckpt["best_wer"]
best_val_loss = ckpt["best_val_loss"]
patience_counter = ckpt["patience_counter"]
wer_history = ckpt.get("wer_history", [])
if scaler and "scaler" in ckpt:
scaler.load_state_dict(ckpt["scaler"])
print_rank0(f" Resumed at epoch {start_epoch}, step {global_step}, best_wer={best_wer:.2f}%", rank)
del ckpt
torch.cuda.empty_cache()
else:
print_rank0(f" WARNING: resume_training path not found: {ckpt_path}", rank)
if is_distributed:
dist.barrier()
# ── Epoch 0: evaluate before any training ──
if start_epoch == 0:
print_rank0(f"\n === Epoch 0 (pre-training baseline) ===", rank)
import sys as _sys
# Compute initial train loss + grad norm on first few batches (all ranks)
student.train()
e0_loss = 0.0
e0_gnorm = 0.0
e0_steps = 0
e0_max_batches = 20
for batch_idx, batch in enumerate(train_loader):
if batch is None:
continue
if batch_idx >= e0_max_batches:
break
try:
if use_amp:
with torch.amp.autocast("cuda", dtype=amp_dtype):
loss = train_step(student, batch, device, confidence_penalty=0.0)
loss.backward()
else:
loss = train_step(student, batch, device, confidence_penalty=0.0)
loss.backward()
trainable = [p for p in student.parameters() if p.requires_grad and p.grad is not None]
gnorm = torch.nn.utils.clip_grad_norm_(trainable, 1e6).item()
e0_loss += loss.item()
if math.isfinite(gnorm):
e0_gnorm += gnorm
e0_steps += 1
optimizer.zero_grad()
except Exception:
optimizer.zero_grad()
continue
if e0_steps > 0:
print_rank0(f" Epoch 0 train_loss={e0_loss/e0_steps:.4f} gnorm={e0_gnorm/e0_steps:.3f} (avg over {e0_steps} batches)", rank)
# Tear down DDP before eval (same as regular epoch eval)
if is_distributed:
optimizer.zero_grad(set_to_none=True)
del student
student = None
torch.cuda.empty_cache()
dist.barrier()
# Free GPU memory before eval
optimizer.zero_grad(set_to_none=True)
opt_state_backup_e0 = {}
for k, v in optimizer.state.items():
opt_state_backup_e0[k] = {sk: sv.cpu() if torch.is_tensor(sv) else sv for sk, sv in v.items()}
optimizer.state.clear()
torch.cuda.empty_cache()
gc.collect()
# Evaluate WER + val_loss (all ranks run forward passes)
print_rank0(f"\n Evaluating {lang} (epoch 0)...", rank)
_sys.stdout.flush()
val_wer, _, _, _, _ = evaluate_batch(model, args.val_manifest, device, rank=rank)
print_rank0(f" [eval] WER done", rank); _sys.stdout.flush()
val_loss = compute_val_loss(model, args.val_manifest, device)
print_rank0(f" [eval] val_loss done", rank); _sys.stdout.flush()
if is_main(rank):
print_rank0(f" Epoch 0 WER: {val_wer:.2f}% | Val loss: {val_loss:.4f}", rank)
wer_history.append({
'epoch': 0,
'wer': val_wer,
'val_loss': val_loss,
'lr': 0.0,
'train_loss': e0_loss / max(1, e0_steps),
})
_sys.stdout.flush()
# Restore optimizer states from CPU
for k, v in opt_state_backup_e0.items():
optimizer.state[k] = {sk: sv.to(device) if torch.is_tensor(sv) else sv for sk, sv in v.items()}
del opt_state_backup_e0
torch.cuda.empty_cache()
# Rebuild DDP for training
if is_distributed:
student = DDP(model, device_ids=[int(os.environ.get("LOCAL_RANK", 0))], find_unused_parameters=True)
optimizer.param_groups[0]["params"] = [p for p in student.parameters() if p.requires_grad]
# Reset dataloader state
if train_sampler is not None:
train_sampler.set_epoch(0)
for epoch in range(start_epoch, args.epochs):
epoch_start = time_module.time()
student.train()
# Decay SpecAugment if enabled (all ranks need updated module)
if args.decay_spec_augment:
update_spec_augment(student, args, epoch, args.epochs, rank)
if train_sampler is not None:
train_sampler.set_epoch(epoch)
# Phase management
if epoch < args.freeze_encoder_epochs:
for p in model.encoder.parameters():
p.requires_grad = False
phase = f"Encoder frozen ({epoch+1}/{args.freeze_encoder_epochs})"
else:
for p in model.encoder.parameters():
p.requires_grad = True
phase = "Full training"
optimizer.param_groups[0]["params"] = [
p for p in student.parameters() if p.requires_grad
]
epoch_loss = 0.0
epoch_steps = 0
epoch_grad_norm = 0.0
grad_norm_steps = 0
inf_grad_steps = 0
pbar = tqdm(train_loader, desc=f"Epoch {epoch+1}/{args.epochs} [{lang}]",
leave=True, ncols=120, disable=not is_main(rank) or not sys.stderr.isatty())
optimizer.zero_grad()
max_batch_audio_sec = 0.0
batch_lengths = []
for batch_idx, batch in enumerate(pbar):
if batch is None:
continue
# Track batch audio lengths
audio, audio_len_t, _, _ = batch
max_audio_samples = audio_len_t.max().item()
total_audio_samples = audio_len_t.sum().item()
max_sec = max_audio_samples / 16000
total_sec = total_audio_samples / 16000
batch_lengths.append(max_sec)
if max_sec > max_batch_audio_sec:
max_batch_audio_sec = max_sec
try:
if use_amp:
with torch.amp.autocast("cuda", dtype=amp_dtype):
loss = train_step(student, batch, device, confidence_penalty=args.confidence_penalty)
if scaler:
scaled_loss = loss / args.grad_accum
scaler.scale(scaled_loss).backward()
else:
(loss / args.grad_accum).backward()
else:
loss = train_step(student, batch, device, confidence_penalty=args.confidence_penalty)
(loss / args.grad_accum).backward()
except RuntimeError as e:
if "out of memory" in str(e).lower():
torch.cuda.empty_cache()
print_rank0(f"\n OOM at batch {batch_idx} (max_audio={max_sec:.1f}s, total={total_sec:.1f}s, batch_size={len(audio_len_t)}), skipping", rank)
optimizer.zero_grad()
continue
raise
epoch_loss += loss.item()
epoch_steps += 1
if (batch_idx + 1) % args.grad_accum == 0:
if scaler:
scaler.unscale_(optimizer)
trainable = [p for p in student.parameters() if p.requires_grad and p.grad is not None]
grad_norm = torch.nn.utils.clip_grad_norm_(trainable, args.grad_clip).item()
if scaler:
scaler.step(optimizer)
scaler.update()
else:
optimizer.step()
if math.isfinite(grad_norm):
epoch_grad_norm += grad_norm
grad_norm_steps += 1
else:
inf_grad_steps += 1
scheduler.step()
optimizer.zero_grad()
global_step += 1
if epoch_steps % args.log_every == 0 and epoch_steps > 0 and is_main(rank):
avg_loss = epoch_loss / epoch_steps
avg_gnorm = epoch_grad_norm / max(1, grad_norm_steps)
lr = optimizer.param_groups[0]["lr"]
gnorm_str = f"{avg_gnorm:.2f}" if grad_norm_steps > 0 else "n/a"
if inf_grad_steps > 0:
gnorm_str += f" ({inf_grad_steps} skipped)"
pbar.set_postfix(loss=f"{avg_loss:.3f}", gnorm=gnorm_str,
lr=f"{lr:.1e}", step=global_step)
# End of epoch
epoch_time = time_module.time() - epoch_start
avg_loss = epoch_loss / max(1, epoch_steps)
avg_gnorm = epoch_grad_norm / max(1, grad_norm_steps)
gnorm_display = f"{avg_gnorm:.3f}" if grad_norm_steps > 0 else "n/a"
if inf_grad_steps > 0:
gnorm_display += f" ({inf_grad_steps} inf-skipped)"
samples_per_sec = (epoch_steps * args.batch_size) / epoch_time
gpu_mem = torch.cuda.max_memory_allocated(device) / 1e9 if torch.cuda.is_available() else 0
# Batch length stats
if batch_lengths:
avg_max_sec = sum(batch_lengths) / len(batch_lengths)
p95 = sorted(batch_lengths)[int(0.95 * len(batch_lengths))]
print_rank0(f" [batch stats] max_audio={max_batch_audio_sec:.1f}s avg_max={avg_max_sec:.1f}s p95={p95:.1f}s", rank)
print_rank0(f"\n Epoch {epoch+1} [{lang}] | {phase} | loss={avg_loss:.4f} "
f"gnorm={gnorm_display} lr={optimizer.param_groups[0]['lr']:.2e}"
f" | {epoch_time/60:.1f}min | {samples_per_sec:.0f} samples/s | GPU: {gpu_mem:.1f}GB", rank)
# Tear down DDP before eval to remove forward hooks from model.
# DDP with find_unused_parameters=True registers hooks on the underlying
# model, so calling model.forward() during rank-0-only eval would trigger
# DDP communication and deadlock the other ranks.
if is_distributed:
optimizer.zero_grad(set_to_none=True)
del student
student = None
torch.cuda.empty_cache()
dist.barrier()
# Free GPU memory before eval: offload optimizer states to CPU
optimizer.zero_grad(set_to_none=True)
opt_state_backup = {}
for k, v in optimizer.state.items():
opt_state_backup[k] = {sk: sv.cpu() if torch.is_tensor(sv) else sv for sk, sv in v.items()}
optimizer.state.clear()
torch.cuda.empty_cache()
gc.collect()
mem_after = torch.cuda.memory_allocated(device) / 1e9
print_rank0(f" [pre-eval] GPU mem after offload: {mem_after:.1f}GB", rank)
import sys as _sys; _sys.stdout.flush()
# Evaluation — ALL ranks run forward passes (needed for SyncBatchNorm / distributed
# layers inside NeMo encoder), but only rank 0 uses the results.
if (epoch + 1) % args.eval_every_epoch == 0:
try:
print_rank0(f"\n Evaluating {lang}...", rank)
_sys.stdout.flush()
val_wer, _, _, _, _ = evaluate_batch(model, args.val_manifest, device, rank=rank)
print_rank0(f" [eval] WER done", rank); _sys.stdout.flush()
val_loss = compute_val_loss(model, args.val_manifest, device)
print_rank0(f" [eval] val_loss done", rank); _sys.stdout.flush()
if is_main(rank):
print_rank0(f" {lang} Batch WER: {val_wer:.2f}% | Val loss: {val_loss:.4f}", rank)
wer_history.append({
'epoch': epoch + 1,
'wer': val_wer,
'val_loss': val_loss,
'lr': optimizer.param_groups[0]["lr"],
'train_loss': avg_loss,
})
if val_wer < best_wer:
best_wer = val_wer
patience_counter = 0
save_path = os.path.join(args.output_dir, "best_model.nemo")
print_rank0(f" [saving] best_model.nemo...", rank); _sys.stdout.flush()
model.save_to(save_path)
print_rank0(f" New best WER! WER={best_wer:.2f}% -> {save_path}", rank)
else:
patience_counter += 1
print_rank0(f" No WER improvement ({patience_counter}/{args.early_stop_patience})", rank)
# Save top-K best WER checkpoints for post-hoc evaluation
should_save_topk = len(top_k_checkpoints) < top_k_wer or val_wer < top_k_checkpoints[-1][0]
if should_save_topk:
topk_path = os.path.join(args.output_dir, f"best_model_wer_ep{epoch+1}.nemo")
print_rank0(f" [saving] top-{top_k_wer} checkpoint (WER={val_wer:.2f}%)...", rank); _sys.stdout.flush()
model.save_to(topk_path)
top_k_checkpoints.append((val_wer, epoch + 1, topk_path))
top_k_checkpoints.sort(key=lambda x: x[0]) # sort by WER ascending
# Remove worst checkpoint if we exceed top_k_wer
while len(top_k_checkpoints) > top_k_wer:
_, _, old_path = top_k_checkpoints.pop()
if os.path.exists(old_path):
os.remove(old_path)
print_rank0(f" [removed] {os.path.basename(old_path)}", rank)
if args.early_stop_patience > 0 and patience_counter >= args.early_stop_patience:
print_rank0(f"\n Early stopping! No improvement for {args.early_stop_patience} epochs.", rank)
break
if val_loss < best_val_loss:
best_val_loss = val_loss
save_path = os.path.join(args.output_dir, "best_model_loss.nemo")
print_rank0(f" [saving] best_model_loss.nemo...", rank); _sys.stdout.flush()
model.save_to(save_path)
print_rank0(f" New best loss! loss={best_val_loss:.4f} -> {save_path}", rank)
except Exception as e:
print_rank0(f" [eval error] {type(e).__name__}: {e} — skipping", rank)
print_rank0(f" [post-eval] reaching barrier...", rank); sys.stdout.flush()
# Restore optimizer states from CPU
for k, v in opt_state_backup.items():
optimizer.state[k] = {sk: sv.to(device) if torch.is_tensor(sv) else sv for sk, sv in v.items()}
del opt_state_backup
torch.cuda.empty_cache()
# Rebuild DDP for next training epoch (after eval is done)
if is_distributed:
student = DDP(model, device_ids=[int(os.environ.get("LOCAL_RANK", 0))], find_unused_parameters=True)
optimizer.param_groups[0]["params"] = [p for p in student.parameters() if p.requires_grad]
# Save full training state for resumability
if is_main(rank) and args.save_every_epoch > 0 and (epoch + 1) % args.save_every_epoch == 0:
# Save latest model weights as raw state dict (fast, avoids NeMo save_to overhead)
latest_path = os.path.join(args.output_dir, "latest_model.pt")
torch.save(model.state_dict(), latest_path + ".tmp")
os.replace(latest_path + ".tmp", latest_path)
state = {
"epoch": epoch + 1,
"global_step": global_step,
"optimizer": optimizer.state_dict(),
"scheduler": scheduler.state_dict(),
"best_wer": best_wer,
"best_val_loss": best_val_loss,
"patience_counter": patience_counter,
"wer_history": wer_history,
}
if scaler:
state["scaler"] = scaler.state_dict()
state_path = os.path.join(args.output_dir, "training_state.pt")
torch.save(state, state_path + ".tmp")
os.replace(state_path + ".tmp", state_path)
# Clear GPU memory fragmentation from eval/save before next training epoch
torch.cuda.empty_cache()
if is_distributed:
dist.barrier()
# Save WER history for convergence analysis
if is_main(rank):
history_path = os.path.join(args.output_dir, "wer_history.json")
with open(history_path, "w") as f:
json.dump(wer_history, f, indent=2)
print_rank0(f"\n WER history saved to {history_path}", rank)
# Final save
save_path = os.path.join(args.output_dir, "final_model.nemo")
model.save_to(save_path)
print_rank0(f" Final model -> {save_path}", rank)
print_rank0(f" Best {lang} WER: {best_wer:.2f}%", rank)
return student
# ═══════════════════════════════════════════════════════════
# Entry Point
# ═══════════════════════════════════════════════════════════
def main():
args = parse_args()
rank, world_size, local_rank, is_distributed = setup_ddp()
device = torch.device(f"cuda:{local_rank}")
torch.manual_seed(args.seed + rank)
np.random.seed(args.seed + rank)
torch.cuda.manual_seed_all(args.seed + rank)
import random
random.seed(args.seed + rank)
os.makedirs(args.output_dir, exist_ok=True)
lang = args.lang.upper()
starting_from = "multilingual base" if args.resume_from else "English checkpoint"
print_rank0(f"\n{'='*65}", rank)
print_rank0(f" Nemotron Streaming ASR — {lang} Training", rank)
print_rank0(f"{'='*65}", rank)
print_rank0(f" Language: {lang}", rank)
print_rank0(f" Path: {starting_from}", rank)
print_rank0(f" GPUs: {world_size}", rank)
if args.resume_from:
print_rank0(f" Base: {args.resume_from}", rank)
else:
print_rank0(f" Student: {args.student}", rank)
print_rank0(f" Train: {args.train_manifest}", rank)
print_rank0(f" Val: {args.val_manifest}", rank)
print_rank0(f"{'='*65}", rank)
# Load model
print_rank0(f"\n[1/3] Loading model...", rank)
student = load_student(args, device, rank)
# Wrap in DDP
if is_distributed:
student = DDP(student, device_ids=[local_rank], find_unused_parameters=True)
print_rank0(f" Wrapped in DDP (find_unused_parameters=True)", rank)
# Create dataloader
print_rank0(f"\n[2/3] Creating data loaders...", rank)
model_for_tok = student.module if isinstance(student, DDP) else student
train_dataset = ASRManifestDataset(
args.train_manifest,
model_for_tok.tokenizer,
min_duration=args.min_duration,
max_duration=args.max_duration,
speed_perturb=args.speed_perturb,
speed_perturb_factors=args.speed_perturb_factors,
max_train_hours=args.max_train_hours,
seed=args.data_seed,
)
print_rank0(f" Train dataset: {len(train_dataset)} samples", rank)
if args.max_train_hours > 0:
print_rank0(f" Subsampled to {train_dataset.total_hours:.1f}h (requested {args.max_train_hours}h)", rank)
# Offset by -42 so --seed=42 (default) keeps PyTorch's default sampler seed=0
# for backward compat with prior runs. --seed=43 -> sampler seed=1, etc.
train_sampler = DistributedSampler(train_dataset, shuffle=True, seed=args.seed - 42) if is_distributed else None
train_loader = DataLoader(
train_dataset,
batch_size=args.batch_size,
shuffle=(train_sampler is None),
sampler=train_sampler,
num_workers=args.num_workers,
collate_fn=collate_asr,
pin_memory=True,
drop_last=True,
)
# Train
print_rank0(f"\n[3/3] Starting {lang} training...", rank)
student = train(
student, train_loader, train_sampler,
args, device, rank, is_distributed,
)
# Final eval on best model — all ranks run eval (NeMo model has distributed internals),
# only rank 0 prints/uses results
import nemo.collections.asr as nemo_asr
best_path = os.path.join(args.output_dir, "best_model.nemo")
if os.path.exists(best_path):
print_rank0(f"\n Loading best model from {best_path}...", rank)
best_model = nemo_asr.models.ASRModel.restore_from(best_path, map_location=device)
best_model = best_model.to(device)
best_model.eval()
else:
print_rank0(f"\n Best model not found, using final model.", rank)
best_model = model
print_rank0(f"\n{'='*65}", rank)
print_rank0(f" Final Evaluation — {lang} (best checkpoint)", rank)
print_rank0(f"{'='*65}", rank)
batch_wer, b_s, b_d, b_i, b_w = evaluate_batch(best_model, args.val_manifest, device, rank=rank)
if is_main(rank):
print_rank0(f" {lang} Val Batch WER: {batch_wer:.2f}% (S={b_s/max(b_w,1)*100:.2f}% D={b_d/max(b_w,1)*100:.2f}% I={b_i/max(b_w,1)*100:.2f}%)", rank)
print_rank0(f" Counts: subs={b_s} dels={b_d} ins={b_i} / {b_w} ref words", rank)
print_rank0(f"\n Running streaming eval...", rank)
stream_wer, s_s, s_d, s_i, s_w = evaluate_streaming(best_model, args.val_manifest, device, rank=rank)
if is_main(rank):
print_rank0(f" {lang} Val Streaming WER: {stream_wer:.2f}% (S={s_s/max(s_w,1)*100:.2f}% D={s_d/max(s_w,1)*100:.2f}% I={s_i/max(s_w,1)*100:.2f}%)", rank)
print_rank0(f" Counts: subs={s_s} dels={s_d} ins={s_i} / {s_w} ref words", rank)
if args.test_manifest:
print_rank0(f"\n{'='*65}", rank)
print_rank0(f" Test Evaluation — {lang} (best checkpoint)", rank)
print_rank0(f"{'='*65}", rank)
test_batch_wer, tb_s, tb_d, tb_i, tb_w = evaluate_batch(best_model, args.test_manifest, device, rank=rank)
if is_main(rank):
print_rank0(f" {lang} Test Batch WER: {test_batch_wer:.2f}% (S={tb_s/max(tb_w,1)*100:.2f}% D={tb_d/max(tb_w,1)*100:.2f}% I={tb_i/max(tb_w,1)*100:.2f}%)", rank)
print_rank0(f" Counts: subs={tb_s} dels={tb_d} ins={tb_i} / {tb_w} ref words", rank)
print_rank0(f"\n Running streaming test eval...", rank)
test_stream_wer, ts_s, ts_d, ts_i, ts_w = evaluate_streaming(best_model, args.test_manifest, device, rank=rank)
if is_main(rank):
print_rank0(f" {lang} Test Streaming WER: {test_stream_wer:.2f}% (S={ts_s/max(ts_w,1)*100:.2f}% D={ts_d/max(ts_w,1)*100:.2f}% I={ts_i/max(ts_w,1)*100:.2f}%)", rank)
print_rank0(f" Counts: subs={ts_s} dels={ts_d} ins={ts_i} / {ts_w} ref words", rank)
del best_model
torch.cuda.empty_cache()
# Evaluate best-by-loss model if it exists
best_loss_path = os.path.join(args.output_dir, "best_model_loss.nemo")
if os.path.exists(best_loss_path):
print_rank0(f"\n{'='*65}", rank)
print_rank0(f" Final Evaluation — {lang} (best loss checkpoint)", rank)
print_rank0(f"{'='*65}", rank)
print_rank0(f" Loading best-by-loss model from {best_loss_path}...", rank)
best_loss_model = nemo_asr.models.ASRModel.restore_from(best_loss_path, map_location=device)
best_loss_model = best_loss_model.to(device)
best_loss_model.eval()
bl_wer, bl_s, bl_d, bl_i, bl_w = evaluate_batch(best_loss_model, args.val_manifest, device, rank=rank)
if is_main(rank):
print_rank0(f" {lang} Val Batch WER (loss-best): {bl_wer:.2f}% (S={bl_s/max(bl_w,1)*100:.2f}% D={bl_d/max(bl_w,1)*100:.2f}% I={bl_i/max(bl_w,1)*100:.2f}%)", rank)
if args.test_manifest:
tbl_wer, tbl_s, tbl_d, tbl_i, tbl_w = evaluate_batch(best_loss_model, args.test_manifest, device, rank=rank)
if is_main(rank):
print_rank0(f" {lang} Test Batch WER (loss-best): {tbl_wer:.2f}% (S={tbl_s/max(tbl_w,1)*100:.2f}% D={tbl_d/max(tbl_w,1)*100:.2f}% I={tbl_i/max(tbl_w,1)*100:.2f}%)", rank)
del best_loss_model
torch.cuda.empty_cache()
# All ranks must wait for rank 0's final eval before destroying process group
if is_distributed:
dist.barrier()
cleanup_ddp(is_distributed)
if __name__ == "__main__":
main()