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Real-Time-Voice-Cloning / synthesizer /inference.py

akhaliq3

spaces demo

24829a1 over 2 years ago

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	import torch
	from synthesizer import audio
	from synthesizer.hparams import hparams
	from synthesizer.models.tacotron import Tacotron
	from synthesizer.utils.symbols import symbols
	from synthesizer.utils.text import text_to_sequence
	from vocoder.display import simple_table
	from pathlib import Path
	from typing import Union, List
	import numpy as np
	import librosa


	class Synthesizer:
	sample_rate = hparams.sample_rate
	hparams = hparams

	def __init__(self, model_fpath: Path, verbose=True):
	"""
	The model isn't instantiated and loaded in memory until needed or until load() is called.

	:param model_fpath: path to the trained model file
	:param verbose: if False, prints less information when using the model
	"""
	self.model_fpath = model_fpath
	self.verbose = verbose

	# Check for GPU
	if torch.cuda.is_available():
	self.device = torch.device("cuda")
	else:
	self.device = torch.device("cpu")
	if self.verbose:
	print("Synthesizer using device:", self.device)

	# Tacotron model will be instantiated later on first use.
	self._model = None

	def is_loaded(self):
	"""
	Whether the model is loaded in memory.
	"""
	return self._model is not None

	def load(self):
	"""
	Instantiates and loads the model given the weights file that was passed in the constructor.
	"""
	self._model = Tacotron(embed_dims=hparams.tts_embed_dims,
	num_chars=len(symbols),
	encoder_dims=hparams.tts_encoder_dims,
	decoder_dims=hparams.tts_decoder_dims,
	n_mels=hparams.num_mels,
	fft_bins=hparams.num_mels,
	postnet_dims=hparams.tts_postnet_dims,
	encoder_K=hparams.tts_encoder_K,
	lstm_dims=hparams.tts_lstm_dims,
	postnet_K=hparams.tts_postnet_K,
	num_highways=hparams.tts_num_highways,
	dropout=hparams.tts_dropout,
	stop_threshold=hparams.tts_stop_threshold,
	speaker_embedding_size=hparams.speaker_embedding_size).to(self.device)

	self._model.load(self.model_fpath)
	self._model.eval()

	if self.verbose:
	print("Loaded synthesizer \"%s\" trained to step %d" % (self.model_fpath.name, self._model.state_dict()["step"]))

	def synthesize_spectrograms(self, texts: List[str],
	embeddings: Union[np.ndarray, List[np.ndarray]],
	return_alignments=False):
	"""
	Synthesizes mel spectrograms from texts and speaker embeddings.

	:param texts: a list of N text prompts to be synthesized
	:param embeddings: a numpy array or list of speaker embeddings of shape (N, 256)
	:param return_alignments: if True, a matrix representing the alignments between the
	characters
	and each decoder output step will be returned for each spectrogram
	:return: a list of N melspectrograms as numpy arrays of shape (80, Mi), where Mi is the
	sequence length of spectrogram i, and possibly the alignments.
	"""
	# Load the model on the first request.
	if not self.is_loaded():
	self.load()

	# Print some info about the model when it is loaded
	tts_k = self._model.get_step() // 1000

	simple_table([("Tacotron", str(tts_k) + "k"),
	("r", self._model.r)])

	# Preprocess text inputs
	inputs = [text_to_sequence(text.strip(), hparams.tts_cleaner_names) for text in texts]
	if not isinstance(embeddings, list):
	embeddings = [embeddings]

	# Batch inputs
	batched_inputs = [inputs[i:i+hparams.synthesis_batch_size]
	for i in range(0, len(inputs), hparams.synthesis_batch_size)]
	batched_embeds = [embeddings[i:i+hparams.synthesis_batch_size]
	for i in range(0, len(embeddings), hparams.synthesis_batch_size)]

	specs = []
	for i, batch in enumerate(batched_inputs, 1):
	if self.verbose:
	print(f"\n\| Generating {i}/{len(batched_inputs)}")

	# Pad texts so they are all the same length
	text_lens = [len(text) for text in batch]
	max_text_len = max(text_lens)
	chars = [pad1d(text, max_text_len) for text in batch]
	chars = np.stack(chars)

	# Stack speaker embeddings into 2D array for batch processing
	speaker_embeds = np.stack(batched_embeds[i-1])

	# Convert to tensor
	chars = torch.tensor(chars).long().to(self.device)
	speaker_embeddings = torch.tensor(speaker_embeds).float().to(self.device)

	# Inference
	_, mels, alignments = self._model.generate(chars, speaker_embeddings)
	mels = mels.detach().cpu().numpy()
	for m in mels:
	# Trim silence from end of each spectrogram
	while np.max(m[:, -1]) < hparams.tts_stop_threshold:
	m = m[:, :-1]
	specs.append(m)

	if self.verbose:
	print("\n\nDone.\n")
	return (specs, alignments) if return_alignments else specs

	@staticmethod
	def load_preprocess_wav(fpath):
	"""
	Loads and preprocesses an audio file under the same conditions the audio files were used to
	train the synthesizer.
	"""
	wav = librosa.load(str(fpath), hparams.sample_rate)[0]
	if hparams.rescale:
	wav = wav / np.abs(wav).max() * hparams.rescaling_max
	return wav

	@staticmethod
	def make_spectrogram(fpath_or_wav: Union[str, Path, np.ndarray]):
	"""
	Creates a mel spectrogram from an audio file in the same manner as the mel spectrograms that
	were fed to the synthesizer when training.
	"""
	if isinstance(fpath_or_wav, str) or isinstance(fpath_or_wav, Path):
	wav = Synthesizer.load_preprocess_wav(fpath_or_wav)
	else:
	wav = fpath_or_wav

	mel_spectrogram = audio.melspectrogram(wav, hparams).astype(np.float32)
	return mel_spectrogram

	@staticmethod
	def griffin_lim(mel):
	"""
	Inverts a mel spectrogram using Griffin-Lim. The mel spectrogram is expected to have been built
	with the same parameters present in hparams.py.
	"""
	return audio.inv_mel_spectrogram(mel, hparams)


	def pad1d(x, max_len, pad_value=0):
	return np.pad(x, (0, max_len - len(x)), mode="constant", constant_values=pad_value)