slt2026-code / eval_model.py
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#!/usr/bin/env python3
"""
eval_model.py
Evaluate a .nemo ASR model on a manifest (batch + streaming WER).
Usage:
python eval_model.py --model /path/to/best_model.nemo --manifest /path/to/test_manifest.json
python eval_model.py --model /path/to/best_model.nemo --manifest /path/to/test_manifest.json --gpu 0
python eval_model.py --model /path/to/best_model.nemo --manifest /path/to/test_manifest.json --no-streaming
Manifest format (one JSON object per line):
{"audio_filepath": "/abs/path/utt.wav", "text": "reference transcript"}
Only `audio_filepath` and `text` are read; other keys (e.g. `duration`) are ignored.
Note:
WER here uses Whisper's BasicMultilingualTextNormalizer from the
Open ASR Leaderboard repo, matching the paper pipeline.
Requirements:
pip install nemo_toolkit[asr] soundfile numpy
"""
import argparse
import json
import os
import sys
import numpy as np
import torch
# Use Whisper's BasicMultilingualTextNormalizer for consistency with paper runs.
try:
from normalizer import BasicMultilingualTextNormalizer
_ml_normalizer = BasicMultilingualTextNormalizer()
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,
)
raise SystemExit(1)
def normalize_text(text):
return _ml_normalizer(text)
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]
@torch.no_grad()
def evaluate_batch(model, manifest_path, device):
import soundfile as sf
model.eval()
samples = []
with open(manifest_path) as f:
for line in f:
samples.append(json.loads(line))
total_edits, total_words = 0, 0
errors = 0
batch_size = 16
examples = []
for start in range(0, len(samples), batch_size):
batch_samples = samples[start:start + batch_size]
try:
audios = []
for s in batch_samples:
audio, sr = sf.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 = normalize_text(s["text"])
pred_n = normalize_text(pred)
ref_words = ref_n.split()
pred_words = pred_n.split()
if ref_words:
total_edits += simple_wer(ref_words, pred_words)
total_words += len(ref_words)
if len(examples) < 10:
examples.append((s["text"][:60], pred[:60]))
except Exception as e:
errors += 1
if errors <= 3:
print(f" [batch eval error] {type(e).__name__}: {e}")
wer_score = total_edits / max(total_words, 1) * 100
print(f"\n {'Reference':<60} | {'Prediction':<60}")
print(f" {'-'*60} | {'-'*60}")
for ref, pred in examples:
print(f" {ref:<60} | {pred:<60}")
if errors:
print(f" ({errors} batch eval errors)")
return wer_score, total_edits, total_words
@torch.no_grad()
def evaluate_streaming(model, manifest_path, device):
import soundfile as sf
from nemo.collections.asr.parts.utils.streaming_utils import CacheAwareStreamingAudioBuffer
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))
total_edits, total_words = 0, 0
examples = []
errors = 0
for s in samples:
try:
audio, sr = sf.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:
total_edits += simple_wer(ref_words, pred_words)
total_words += len(ref_words)
if len(examples) < 10:
examples.append((s["text"][:60], pred[:60]))
except Exception as e:
errors += 1
if errors <= 3:
print(f" [streaming eval error] {type(e).__name__}: {e}")
wer_score = total_edits / max(total_words, 1) * 100
print(f"\n {'Reference':<60} | {'Prediction':<60}")
print(f" {'-'*60} | {'-'*60}")
for ref, pred in examples:
print(f" {ref:<60} | {pred:<60}")
if errors:
print(f" ({errors} samples failed)")
return wer_score, total_edits, total_words
def main():
parser = argparse.ArgumentParser(description="Evaluate NeMo ASR model")
parser.add_argument("--model", type=str, required=True, help="Path to .nemo model")
parser.add_argument("--manifest", type=str, required=True,
help="Path to evaluation manifest (JSONL)")
parser.add_argument("--gpu", type=int, default=0, help="GPU index")
parser.add_argument("--no-streaming", action="store_true", help="Skip streaming eval")
args = parser.parse_args()
device = torch.device(f"cuda:{args.gpu}")
torch.cuda.set_device(args.gpu)
import nemo.collections.asr as nemo_asr
from nemo.core.classes.common import typecheck
typecheck.set_typecheck_enabled(False)
print(f"\n{'='*65}")
print(f" Model: {args.model}")
print(f" Manifest: {args.manifest}")
print(f" GPU: {args.gpu}")
print(f"{'='*65}")
print(f"\n Loading model...")
model = nemo_asr.models.ASRModel.restore_from(args.model, map_location=device)
model = model.to(device)
model.eval()
from omegaconf import open_dict
with open_dict(model.cfg):
model.cfg.decoding.greedy.use_cuda_graph_decoder = False
model.change_decoding_strategy(model.cfg.decoding)
print(f" Vocab: {model.tokenizer.vocab_size} tokens")
print(f" Params: {sum(p.numel() for p in model.parameters()) / 1e6:.1f}M")
# Count samples
with open(args.manifest) as f:
n_samples = sum(1 for _ in f)
print(f" Samples: {n_samples}")
# Batch eval
print(f"\n{'='*65}")
print(f" Batch Evaluation")
print(f"{'='*65}")
batch_wer, batch_edits, batch_words = evaluate_batch(model, args.manifest, device)
print(f"\n Batch WER: {batch_wer:.2f}% ({batch_edits}/{batch_words})")
# Streaming eval
if not args.no_streaming:
print(f"\n{'='*65}")
print(f" Streaming Evaluation")
print(f"{'='*65}")
stream_wer, stream_edits, stream_words = evaluate_streaming(model, args.manifest, device)
print(f"\n Streaming WER: {stream_wer:.2f}% ({stream_edits}/{stream_words})")
# Summary
print(f"\n{'='*65}")
print(f" Summary")
print(f"{'='*65}")
print(f" Model: {os.path.basename(args.model)}")
print(f" Manifest: {os.path.basename(args.manifest)}")
print(f" Batch WER: {batch_wer:.2f}%")
if not args.no_streaming:
print(f" Streaming WER: {stream_wer:.2f}%")
print(f"{'='*65}")
if __name__ == "__main__":
main()