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generate.py
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generate.py
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from __future__ import division
from __future__ import print_function
import argparse
from datetime import datetime
import json
import os
import librosa
import numpy as np
import tensorflow as tf
from wavenet import WaveNetModel, mu_law_decode, mu_law_encode, audio_reader
SAMPLES = 16000
TEMPERATURE = 1.0
LOGDIR = './logdir'
WAVENET_PARAMS = './wavenet_params.json'
SAVE_EVERY = None
SILENCE_THRESHOLD = 0.1
def get_arguments():
def _str_to_bool(s):
"""Convert string to bool (in argparse context)."""
if s.lower() not in ['true', 'false']:
raise ValueError('Argument needs to be a '
'boolean, got {}'.format(s))
return {'true': True, 'false': False}[s.lower()]
def _ensure_positive_float(f):
"""Ensure argument is a positive float."""
if float(f) < 0:
raise argparse.ArgumentTypeError(
'Argument must be greater than zero')
return float(f)
parser = argparse.ArgumentParser(description='WaveNet generation script')
parser.add_argument(
'checkpoint', type=str, help='Which model checkpoint to generate from')
parser.add_argument(
'--samples',
type=int,
default=SAMPLES,
help='How many waveform samples to generate')
parser.add_argument(
'--temperature',
type=_ensure_positive_float,
default=TEMPERATURE,
help='Sampling temperature')
parser.add_argument(
'--logdir',
type=str,
default=LOGDIR,
help='Directory in which to store the logging '
'information for TensorBoard.')
parser.add_argument(
'--wavenet_params',
type=str,
default=WAVENET_PARAMS,
help='JSON file with the network parameters')
parser.add_argument(
'--wav_out_path',
type=str,
default=None,
help='Path to output wav file')
parser.add_argument(
'--save_every',
type=int,
default=SAVE_EVERY,
help='How many samples before saving in-progress wav')
parser.add_argument(
'--fast_generation',
type=_str_to_bool,
default=True,
help='Use fast generation')
parser.add_argument(
'--wav_seed',
type=str,
default=None,
help='The wav file to start generation from')
parser.add_argument(
'--gc_channels',
type=int,
default=None,
help='Number of global condition embedding channels. Omit if no '
'global conditioning.')
parser.add_argument(
'--gc_cardinality',
type=int,
default=None,
help='Number of categories upon which we globally condition.')
parser.add_argument(
'--gc_id',
type=int,
default=None,
help='ID of category to generate, if globally conditioned.')
arguments = parser.parse_args()
if arguments.gc_channels is not None:
if arguments.gc_cardinality is None:
raise ValueError("Globally conditioning but gc_cardinality not "
"specified. Use --gc_cardinality=377 for full "
"VCTK corpus.")
if arguments.gc_id is None:
raise ValueError("Globally conditioning, but global condition was "
"not specified. Use --gc_id to specify global "
"condition.")
return arguments
def write_wav(waveform, sample_rate, filename):
y = np.array(waveform)
librosa.output.write_wav(filename, y, sample_rate)
print('Updated wav file at {}'.format(filename))
def create_seed(filename,
sample_rate,
quantization_channels,
window_size,
silence_threshold=SILENCE_THRESHOLD):
audio, _ = librosa.load(filename, sr=sample_rate, mono=True)
audio = audio_reader.trim_silence(audio, silence_threshold)
quantized = mu_law_encode(audio, quantization_channels)
cut_index = tf.cond(tf.size(quantized) < tf.constant(window_size),
lambda: tf.size(quantized),
lambda: tf.constant(window_size))
return quantized[:cut_index]
def main():
args = get_arguments()
started_datestring = "{0:%Y-%m-%dT%H-%M-%S}".format(datetime.now())
logdir = os.path.join(args.logdir, 'generate', started_datestring)
with open(args.wavenet_params, 'r') as config_file:
wavenet_params = json.load(config_file)
sess = tf.Session()
net = WaveNetModel(
batch_size=1,
dilations=wavenet_params['dilations'],
filter_width=wavenet_params['filter_width'],
residual_channels=wavenet_params['residual_channels'],
dilation_channels=wavenet_params['dilation_channels'],
quantization_channels=wavenet_params['quantization_channels'],
skip_channels=wavenet_params['skip_channels'],
use_biases=wavenet_params['use_biases'],
scalar_input=wavenet_params['scalar_input'],
initial_filter_width=wavenet_params['initial_filter_width'],
global_condition_channels=args.gc_channels,
global_condition_cardinality=args.gc_cardinality)
samples = tf.placeholder(tf.int32)
if args.fast_generation:
next_sample = net.predict_proba_incremental(samples, args.gc_id)
else:
next_sample = net.predict_proba(samples, args.gc_id)
if args.fast_generation:
sess.run(tf.global_variables_initializer())
sess.run(net.init_ops)
variables_to_restore = {
var.name[:-2]: var for var in tf.global_variables()
if not ('state_buffer' in var.name or 'pointer' in var.name)}
saver = tf.train.Saver(variables_to_restore)
print('Restoring model from {}'.format(args.checkpoint))
saver.restore(sess, args.checkpoint)
decode = mu_law_decode(samples, wavenet_params['quantization_channels'])
quantization_channels = wavenet_params['quantization_channels']
if args.wav_seed:
seed = create_seed(args.wav_seed,
wavenet_params['sample_rate'],
quantization_channels,
net.receptive_field)
waveform = sess.run(seed).tolist()
else:
# Silence with a single random sample at the end.
waveform = [quantization_channels / 2] * (net.receptive_field - 1)
waveform.append(np.random.randint(quantization_channels))
if args.fast_generation and args.wav_seed:
# When using the incremental generation, we need to
# feed in all priming samples one by one before starting the
# actual generation.
# TODO This could be done much more efficiently by passing the waveform
# to the incremental generator as an optional argument, which would be
# used to fill the queues initially.
outputs = [next_sample]
outputs.extend(net.push_ops)
print('Priming generation...')
for i, x in enumerate(waveform[-net.receptive_field: -1]):
if i % 100 == 0:
print('Priming sample {}'.format(i))
sess.run(outputs, feed_dict={samples: x})
print('Done.')
last_sample_timestamp = datetime.now()
for step in range(args.samples):
if args.fast_generation:
outputs = [next_sample]
outputs.extend(net.push_ops)
window = waveform[-1]
else:
if len(waveform) > net.receptive_field:
window = waveform[-net.receptive_field:]
else:
window = waveform
outputs = [next_sample]
# Run the WaveNet to predict the next sample.
prediction = sess.run(outputs, feed_dict={samples: window})[0]
# Scale prediction distribution using temperature.
np.seterr(divide='ignore')
scaled_prediction = np.log(prediction) / args.temperature
scaled_prediction = (scaled_prediction -
np.logaddexp.reduce(scaled_prediction))
scaled_prediction = np.exp(scaled_prediction)
np.seterr(divide='warn')
# Prediction distribution at temperature=1.0 should be unchanged after
# scaling.
if args.temperature == 1.0:
np.testing.assert_allclose(
prediction, scaled_prediction, atol=1e-5,
err_msg='Prediction scaling at temperature=1.0 '
'is not working as intended.')
sample = np.random.choice(
np.arange(quantization_channels), p=scaled_prediction)
waveform.append(sample)
# Show progress only once per second.
current_sample_timestamp = datetime.now()
time_since_print = current_sample_timestamp - last_sample_timestamp
if time_since_print.total_seconds() > 1.:
print('Sample {:3<d}/{:3<d}'.format(step + 1, args.samples),
end='\r')
last_sample_timestamp = current_sample_timestamp
# If we have partial writing, save the result so far.
if (args.wav_out_path and args.save_every and
(step + 1) % args.save_every == 0):
out = sess.run(decode, feed_dict={samples: waveform})
write_wav(out, wavenet_params['sample_rate'], args.wav_out_path)
# Introduce a newline to clear the carriage return from the progress.
print()
# Save the result as an audio summary.
datestring = str(datetime.now()).replace(' ', 'T')
writer = tf.summary.FileWriter(logdir)
tf.summary.audio('generated', decode, wavenet_params['sample_rate'])
summaries = tf.summary.merge_all()
summary_out = sess.run(summaries,
feed_dict={samples: np.reshape(waveform, [-1, 1])})
writer.add_summary(summary_out)
# Save the result as a wav file.
if args.wav_out_path:
out = sess.run(decode, feed_dict={samples: waveform})
write_wav(out, wavenet_params['sample_rate'], args.wav_out_path)
print('Finished generating. The result can be viewed in TensorBoard.')
if __name__ == '__main__':
main()