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# Copyright 2022 The DDSP 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. | ||
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r"""Prepare URMP dataset DDSP and NoteSequence features. | ||
Usage: | ||
==================== | ||
ddsp_prepare_urmp_dataset \ | ||
--input_filepath='/path/to/input.tfrecord-*' \ | ||
--output_filepath='/path/to/output.tfrecord' \ | ||
--instrument_key=vn \ | ||
--num_shards=10 \ | ||
--alsologtostderr | ||
""" | ||
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from absl import app | ||
from absl import flags | ||
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from ddsp.training.data_preparation.prepare_urmp_dataset_lib import prepare_urmp | ||
import tensorflow.compat.v2 as tf | ||
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FLAGS = flags.FLAGS | ||
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flags.DEFINE_string('input_filepath', '', 'Input filepath for dataset.') | ||
flags.DEFINE_string('output_filepath', '', 'Output filepath for dataset.') | ||
flags.DEFINE_multi_string( | ||
'instrument_key', [], 'Instrument keys to extract. ' | ||
'If not set, extract all instruments. Possible keys ' | ||
'are vn, va, vc, db, fl, ob, cl, sax, bn, tpt, hn, ' | ||
'tbn, tba.') | ||
flags.DEFINE_integer( | ||
'num_shards', None, 'Num shards for output dataset. If ' | ||
'None, this number will be determined automatically.') | ||
flags.DEFINE_bool('batch', True, 'Whether or not to batch the dataset.') | ||
flags.DEFINE_bool('force_monophonic', True, 'Fix URMP note labels such that ' | ||
'note onsets and offsets do not overlap.') | ||
flags.DEFINE_list( | ||
'pipeline_options', '--runner=DirectRunner', | ||
'A comma-separated list of command line arguments to be used as options ' | ||
'for the Beam Pipeline.') | ||
flags.DEFINE_integer('ddsp_sample_rate', 250, 'Sample rate for dataset output.') | ||
flags.DEFINE_integer('audio_sample_rate', 16000, 'Sample rate for URMP audio.') | ||
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def run(): | ||
prepare_urmp( | ||
input_filepath=FLAGS.input_filepath, | ||
output_filepath=FLAGS.output_filepath, | ||
instrument_keys=FLAGS.instrument_key, | ||
num_shards=FLAGS.num_shards, | ||
batch=FLAGS.batch, | ||
force_monophonic=FLAGS.force_monophonic, | ||
pipeline_options=FLAGS.pipeline_options, | ||
ddsp_sample_rate=FLAGS.ddsp_sample_rate, | ||
audio_sample_rate=FLAGS.audio_sample_rate) | ||
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def main(unused_argv): | ||
"""From command line.""" | ||
run() | ||
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def console_entry_point(): | ||
"""From pip installed script.""" | ||
app.run(main) | ||
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if __name__ == '__main__': | ||
console_entry_point() |
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ddsp/training/data_preparation/prepare_urmp_dataset_lib.py
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# Copyright 2022 The DDSP 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. | ||
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"""URMP data import pipeline.""" | ||
import apache_beam as beam | ||
import ddsp | ||
from ddsp.training import heuristics | ||
from mir_eval import melody | ||
from note_seq import audio_io | ||
from note_seq import constants | ||
from note_seq import sequences_lib | ||
from note_seq.protobuf import music_pb2 | ||
import numpy as np | ||
import tensorflow as tf | ||
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DDSP_SAMPLE_RATE = 250 | ||
AUDIO_SAMPLE_RATE = 16000 | ||
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def parse_example(tfexample): | ||
"""Parse tf.Example protos to dict of numpy arrays.""" | ||
features = { | ||
'id': | ||
tf.io.FixedLenFeature([], dtype=tf.string), | ||
'audio': | ||
tf.io.FixedLenFeature([], dtype=tf.string), | ||
'f0_hz': | ||
tf.io.FixedLenSequenceFeature([], | ||
dtype=tf.float32, | ||
allow_missing=True), | ||
'f0_time': | ||
tf.io.FixedLenSequenceFeature([], | ||
dtype=tf.float32, | ||
allow_missing=True), | ||
'sequence': | ||
tf.io.FixedLenFeature([], dtype=tf.string) | ||
} | ||
ex = { | ||
key: val.numpy() | ||
for key, val in tf.io.parse_single_example(tfexample, features).items() | ||
} | ||
return ex | ||
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def get_active_frame_indices(piano_roll): | ||
"""Create matrix of frame indices for active notes relative to onset.""" | ||
active_frame_indices = np.zeros_like(piano_roll.active_velocities) | ||
for frame_i in range(1, active_frame_indices.shape[0]): | ||
prev_indices = active_frame_indices[frame_i - 1, :] | ||
active_notes = piano_roll.active[frame_i, :] | ||
active_frame_indices[frame_i, :] = (prev_indices + 1) * active_notes | ||
return active_frame_indices | ||
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def attach_metadata(ex, ddsp_sample_rate, audio_sample_rate, force_monophonic): | ||
"""Parse and attach metadata from the dataset.""" | ||
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def extract_recording_id(id_string): | ||
id_string = id_string.split(b'/')[-1] | ||
id_string = id_string.split(b'.')[0] | ||
return id_string | ||
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def extract_instrument_id(id_string): | ||
id_string = extract_recording_id(id_string).split(b'_') | ||
return id_string[2] | ||
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def extract_notes(sequence_str, expected_seconds): | ||
ns = music_pb2.NoteSequence.FromString(sequence_str) | ||
# total time in dataset doesn't include silence at the end | ||
if force_monophonic: | ||
for i in range(1, len(ns.notes)): | ||
note = ns.notes[i] | ||
prev_note = ns.notes[i - 1] | ||
onset_frame = int(note.start_time * ddsp_sample_rate) | ||
prev_note_offset_frame = int(prev_note.end_time * ddsp_sample_rate) | ||
if prev_note_offset_frame >= onset_frame: | ||
frames_to_move = (prev_note_offset_frame - onset_frame) + 1 | ||
# move previous note's onset back by frames_to_move frames in seconds | ||
prev_note.end_time -= float(frames_to_move) / ddsp_sample_rate | ||
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ns.total_time = expected_seconds | ||
piano_roll = sequences_lib.sequence_to_pianoroll( | ||
ns, | ||
frames_per_second=ddsp_sample_rate, | ||
min_pitch=constants.MIN_MIDI_PITCH, | ||
max_pitch=constants.MAX_MIDI_PITCH, | ||
onset_mode='length_ms') | ||
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note_dict = { | ||
'note_active_velocities': piano_roll.active_velocities, | ||
'note_active_frame_indices': get_active_frame_indices(piano_roll), | ||
'note_onsets': piano_roll.onsets, | ||
'note_offsets': piano_roll.offsets | ||
} | ||
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return note_dict | ||
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ex['recording_id'] = extract_recording_id(ex['id']) | ||
ex['instrument_id'] = extract_instrument_id(ex['id']) | ||
ex['audio'] = audio_io.wav_data_to_samples_librosa( | ||
ex['audio'], sample_rate=audio_sample_rate) | ||
expected_seconds = ex['audio'].shape[0] / audio_sample_rate | ||
ex.update(extract_notes(ex['sequence'], expected_seconds)) | ||
beam.metrics.Metrics.distribution('prepare-urmp', | ||
'orig-audio-len').update(len(ex['audio'])) | ||
return ex | ||
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def normalize_audio(ex, max_audio): | ||
ex['audio'] /= max_audio | ||
return ex | ||
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def resample(ex, ddsp_sample_rate, audio_sample_rate): | ||
"""Resample features to standard DDSP sample rate.""" | ||
f0_times = ex['f0_time'] | ||
f0_orig = ex['f0_hz'] | ||
max_time = np.max(f0_times) | ||
new_times = np.linspace(0, max_time, int(ddsp_sample_rate * max_time)) | ||
if f0_times[0] > 0: | ||
f0_orig = np.insert(f0_orig, 0, f0_orig[0]) | ||
f0_times = np.insert(f0_times, 0, 0) | ||
f0_interpolated, _ = melody.resample_melody_series( | ||
f0_times, f0_orig, | ||
melody.freq_to_voicing(f0_orig)[1], new_times) | ||
ex['f0_hz'] = f0_interpolated | ||
ex['f0_time'] = new_times | ||
ex['orig_f0_hz'] = f0_orig | ||
ex['orig_f0_time'] = f0_times | ||
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# Truncate audio to an integer multiple of f0_hz vector. | ||
num_audio_samples = round( | ||
len(ex['f0_hz']) * (audio_sample_rate / ddsp_sample_rate)) | ||
beam.metrics.Metrics.distribution( | ||
'prepare-urmp', | ||
'resampled-audio-diff').update(num_audio_samples - len(ex['audio'])) | ||
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ex['audio'] = ex['audio'][:num_audio_samples] | ||
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# Truncate pianoroll features to length of f0_hz vector. | ||
for key in [ | ||
'note_active_frame_indices', 'note_active_velocities', 'note_onsets', | ||
'note_offsets' | ||
]: | ||
ex[key] = ex[key][:len(ex['f0_hz']), :] | ||
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return ex | ||
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def batch_dataset(ex, audio_sample_rate, ddsp_sample_rate): | ||
"""Split features and audio into 4 second sliding windows.""" | ||
batched = [] | ||
for key, vec in ex.items(): | ||
if isinstance(vec, np.ndarray): | ||
if key == 'audio': | ||
sampling_rate = audio_sample_rate | ||
else: | ||
sampling_rate = ddsp_sample_rate | ||
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frames = heuristics.window_array(vec, sampling_rate, 4.0, 0.25) | ||
if not batched: | ||
batched = [{} for _ in range(len(frames))] | ||
for i, frame in enumerate(frames): | ||
batched[i][key] = frame | ||
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# once batches are created, replicate ids and metadata over all elements. | ||
for key, val in ex.items(): | ||
if not isinstance(val, np.ndarray): | ||
for batch in batched: | ||
batch[key] = val | ||
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beam.metrics.Metrics.counter('prepare-urmp', | ||
'batches-created').inc(len(batched)) | ||
return batched | ||
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def attach_ddsp_features(ex): | ||
ex['loudness_db'] = ddsp.spectral_ops.compute_loudness(ex['audio']) | ||
ex['power_db'] = ddsp.spectral_ops.compute_power(ex['audio'], frame_size=256) | ||
# ground truth annotations are set with confidence 1.0 | ||
ex['f0_confidence'] = np.ones_like(ex['f0_hz']) | ||
beam.metrics.Metrics.counter('prepare-urmp', 'ddsp-features-attached').inc() | ||
return ex | ||
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def serialize_tfexample(ex): | ||
"""Creates a tf.Example message ready to be written to a file.""" | ||
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def _feature(arr): | ||
"""Returns a feature from a numpy array or string.""" | ||
if isinstance(arr, (bytes, str)): | ||
return tf.train.Feature(bytes_list=tf.train.BytesList(value=[arr])) | ||
else: | ||
arr = np.asarray(arr).reshape(-1) | ||
return tf.train.Feature(float_list=tf.train.FloatList(value=arr)) | ||
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# Create a dictionary mapping the feature name to the tf.Example-compatible | ||
# data type. | ||
feature = {k: _feature(v) for k, v in ex.items()} | ||
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# Create a Features message using tf.train.Example. | ||
example_proto = tf.train.Example(features=tf.train.Features(feature=feature)) | ||
return example_proto | ||
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def prepare_urmp(input_filepath, | ||
output_filepath, | ||
instrument_keys, | ||
num_shards, | ||
batch, | ||
force_monophonic, | ||
pipeline_options, | ||
ddsp_sample_rate=DDSP_SAMPLE_RATE, | ||
audio_sample_rate=AUDIO_SAMPLE_RATE): | ||
"""Pipeline for parsing URMP dataset to a usable format for DDSP.""" | ||
pipeline_options = beam.options.pipeline_options.PipelineOptions( | ||
pipeline_options) | ||
with beam.Pipeline(options=pipeline_options) as pipeline: | ||
examples = ( | ||
pipeline | ||
| | ||
'read_tfrecords' >> beam.io.tfrecordio.ReadFromTFRecord(input_filepath) | ||
| 'parse_example' >> beam.Map(parse_example) | ||
| 'attach_metadata' >> beam.Map( | ||
attach_metadata, | ||
ddsp_sample_rate=ddsp_sample_rate, | ||
audio_sample_rate=audio_sample_rate, | ||
force_monophonic=force_monophonic)) | ||
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if instrument_keys: | ||
examples |= 'filter_instruments' >> beam.Filter( | ||
lambda ex: ex['instrument_id'].decode() in instrument_keys) | ||
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examples |= 'resample' >> beam.Map( | ||
resample, | ||
ddsp_sample_rate=ddsp_sample_rate, | ||
audio_sample_rate=audio_sample_rate) | ||
if batch: | ||
examples |= 'batch' >> beam.FlatMap( | ||
batch_dataset, | ||
audio_sample_rate=audio_sample_rate, | ||
ddsp_sample_rate=ddsp_sample_rate) | ||
_ = ( | ||
examples | ||
| 'attach_ddsp_features' >> beam.Map(attach_ddsp_features) | ||
| 'filter_silence' >> | ||
beam.Filter(lambda ex: np.any(ex['loudness_db'] > -70)) | ||
| 'serialize_tfexamples' >> beam.Map(serialize_tfexample) | ||
| 'shuffle' >> beam.Reshuffle() | ||
| beam.io.tfrecordio.WriteToTFRecord( | ||
output_filepath, | ||
num_shards=num_shards, | ||
coder=beam.coders.ProtoCoder(tf.train.Example))) |
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