on-the-fly feature extraction by default

2025-08-27 02:34:21 +00:00 · 2021-11-13 17:45:35 -05:00 · 2021-11-13 17:45:35 -05:00 · 1d58765bd5
commit 1d58765bd5
parent 75860159a2
3 changed files with 183 additions and 31 deletions
--- a/.gitignore
+++ b/.gitignore
@ -6,3 +6,5 @@ exp
 exp*/
 *.pt
 download
 dask-worker-space
 log
--- a/egs/gigaspeech/ASR/local/compute_fbank_gigaspeech.py
+++ b/egs/gigaspeech/ASR/local/compute_fbank_gigaspeech.py
@ -1,5 +1,5 @@
 #!/usr/bin/env python3
-# Copyright    2021  Xiaomi Corp.        (authors: Fangjun Kuang)
+# Copyright    2021  Johns Hopkins University (Piotr Żelasko)
 #
 # See ../../../../LICENSE for clarification regarding multiple authors
 #
@ -23,15 +23,23 @@ It looks for manifests in the directory data/manifests.
 The generated fbank features are saved in data/fbank.
 """
 import argparse
 import logging
 import os
 import re
 from pathlib import Path
 import torch
-from lhotse import CutSet, Fbank, FbankConfig, LilcomHdf5Writer
+from lhotse import (
    CutSet,
    Fbank,
    FbankConfig,
    LilcomHdf5Writer,
    SupervisionSegment,
 )
 from lhotse.recipes.utils import read_manifests_if_cached
-from icefall.utils import get_executor
+from icefall.utils import get_executor, str2bool
 # Torch's multithreaded behavior needs to be disabled or
 # it wastes a lot of CPU and slow things down.
@ -41,10 +49,76 @@ torch.set_num_threads(1)
 torch.set_num_interop_threads(1)
-def compute_fbank_gigaspeech():
+def get_parser():
    parser = argparse.ArgumentParser(
        formatter_class=argparse.ArgumentDefaultsHelpFormatter
    )
    parser.add_argument(
        "--num-jobs",
        type=int,
        default=min(15, os.cpu_count()),
        help="Number of parallel jobs.",
    )
    parser.add_argument(
        "--context-window",
        type=float,
        default=0.0,
        help="Training cut duration in seconds. "
        "Use 0 to train on supervision segments without acoustic context, "
        "with variable cut lengths; number larger than zero will create "
        "multi-supervisions cuts with actual acoustic context. ",
    )
    parser.add_argument(
        "--context-direction",
        type=str,
        default="center",
        help="If context-window is 0, does nothing. "
        "If it's larger than 0, determines in which direction "
        "(relative to the supervision) to seek for extra acoustic context. "
        "Available values: (left|right|center|random).",
    )
    parser.add_argument(
        "--precomputed-features",
        type=str2bool,
        default=False,
        help="Should we pre-compute features and store them on disk or not. "
        "It is recommended to disable it for L and XL splits as the "
        "pre-computation might currently consume excessive memory and time "
        "-- use on-the-fly feature extraction in the training script instead.",
    )
    return parser
 # Similar text filtering and normalization procedure as in:
 # https://github.com/SpeechColab/GigaSpeech/blob/main/toolkits/kaldi/gigaspeech_data_prep.sh
 def normalize_text(
    utt: str,
    punct_pattern=re.compile(r"<(COMMA|PERIOD|QUESTIONMARK|EXCLAMATIONPOINT)>"),
    whitespace_pattern=re.compile(r"\s\s+"),
 ) -> str:
    return whitespace_pattern.sub(" ", punct_pattern.sub("", utt))
 def has_no_oov(
    sup: SupervisionSegment,
    oov_pattern=re.compile(r"<(SIL|MUSIC|NOISE|OTHER)>"),
 ) -> bool:
    return oov_pattern.search(sup.text) is None
 def get_context_suffix(args):
    if args.context_window is None or args.context_window <= 0.0:
        ctx_suffix = ""
    else:
        ctx_suffix = f"_{args.context_direction}{args.context_window}"
    return ctx_suffix
 def compute_fbank_gigaspeech(args):
    src_dir = Path("data/manifests")
    output_dir = Path("data/fbank")
    num_jobs = min(10, os.cpu_count())
    num_mel_bins = 80
    dataset_parts = (
@ -61,39 +135,114 @@ def compute_fbank_gigaspeech():
    assert manifests is not None
    extractor = Fbank(FbankConfig(num_mel_bins=num_mel_bins))
    ctx_suffix = get_context_suffix(args)
    with get_executor() as ex:  # Initialize the executor only once.
        for partition, m in manifests.items():
-            if (output_dir / f"cuts_{partition}.jsonl.gz").is_file():
+            raw_cuts_path = output_dir / f"cuts_{partition}_raw.jsonl.gz"
-                logging.info(f"{partition} already exists - skipping.")
+            if raw_cuts_path.is_file():
-                continue
+                logging.info(
                    f"{partition} already exists - skipping feature extraction."
                )
            else:
                # Note this step makes the recipe different than LibriSpeech:
                # We must filter out some utterances and remove punctuation
                # to be consistent with Kaldi.
                logging.info("Filtering OOV utterances from supervisions")
                m["supervisions"] = m["supervisions"].filter(has_no_oov)
                logging.info(f"Normalizing text in {partition}")
                for sup in m["supervisions"]:
                    sup.text = normalize_text(sup.text)
                # Create long-recording cut manifests.
                logging.info(f"Processing {partition}")
                cut_set = CutSet.from_manifests(
                    recordings=m["recordings"],
                    supervisions=m["supervisions"],
                )
-            if "train" in partition:
+                # Run data augmentation that needs to be done in the
                # time domain.
                if partition not in ["DEV", "TEST"]:
                    cut_set = (
                        cut_set
                        + cut_set.perturb_speed(0.9)
                        + cut_set.perturb_speed(1.1)
                    )
                cut_set.to_file(raw_cuts_path)
            cuts_path = output_dir / f"cuts_{partition}{ctx_suffix}.jsonl.gz"
            if cuts_path.is_file():
                logging.info(
                    f"{partition} already exists - skipping cutting into "
                    f"sub-segments."
                )
            else:
                try:
                    # If we skipped initializing `cut_set` because it exists
                    # on disk, we'll load it. This helps us avoid re-computing
                    # the features for different variants of context windows.
                    cut_set
                except NameError:
                    logging.info(f"Reading {partition} raw cuts from disk.")
                    cut_set = CutSet.from_file(raw_cuts_path)
                # Note this step makes the recipe different than LibriSpeech:
                # Since recordings are long, the initial CutSet has very long
                # cuts with a plenty of supervisions. We cut these into smaller
                # chunks centered around each supervision, possibly adding
                # acoustic context.
                logging.info(
                    f"About to split {partition} raw cuts into smaller chunks."
                )
                cut_set = cut_set.trim_to_supervisions(
                    keep_overlapping=False,
                    min_duration=None
                    if args.context_window <= 0.0
                    else args.context_window,
                    context_direction=args.context_direction,
                )
                if partition in ["L", "XL"]:
                    # Before storing manifests in, we want to pre-shuffle them,
                    # as the sampler won't be able to do it later in an
                    # efficient manner.
                    cut_set = cut_set.shuffle()
                if args.precomputed_features:
                    # Extract the features after cutting large recordings into
                    # smaller cuts.
                    # Note:
                    # we support very efficient "chunked" feature reads with
                    # the argument `storage_type=ChunkedLilcomHdf5Writer`,
                    # but we don't support efficient data augmentation and
                    # feature computation for long recordings yet.
                    # Therefore, we sacrifice some storage for the ability to
                    # precompute features on shorter chunks,
                    # without memory blow-ups.
                    cut_set = cut_set.compute_and_store_features(
                        extractor=extractor,
                        storage_path=f"{output_dir}/feats_{partition}",
                        # when an executor is specified, make more partitions
-                num_jobs=num_jobs if ex is None else 80,
+                        num_jobs=args.num_jobs if ex is None else 80,
                        executor=ex,
                        storage_type=LilcomHdf5Writer,
                    )
-            cut_set.to_json(output_dir / f"cuts_{partition}.jsonl.gz")
+                cut_set.to_file(cuts_path)
                # Remove cut_set so the next iteration can correctly infer
                # whether it needs to load the raw cuts from disk or not.
                del cut_set
-if __name__ == "__main__":
+def main():
    formatter = (
        "%(asctime)s %(levelname)s [%(filename)s:%(lineno)d] %(message)s"
    )
    logging.basicConfig(format=formatter, level=logging.INFO)
-    compute_fbank_gigaspeech()
+    parser = get_parser()
    args = parser.parse_args()
    compute_fbank_gigaspeech(args)
 if __name__ == "__main__":
    main()
--- a/egs/gigaspeech/ASR/prepare.sh
+++ b/egs/gigaspeech/ASR/prepare.sh
@ -110,7 +110,8 @@ fi
 if [ $stage -le 3 ] && [ $stop_stage -ge 3 ]; then
  log "Stage 3: Compute fbank for GigaSpeech"
  mkdir -p data/fbank
-  ./local/compute_fbank_gigaspeech.py
+  ./local/compute_fbank_gigaspeech.py --num-jobs $nj --context-window 0.0 \
    --context-direction center --precomputed-features False
 fi
 if [ $stage -le 4 ] && [ $stop_stage -ge 4 ]; then