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PortaSpeech / tasks /tts /ps.py

RayeRen

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	import os
	import torch
	import torch.nn.functional as F
	from torch import nn

	from modules.tts.portaspeech.portaspeech import PortaSpeech
	from tasks.tts.fs import FastSpeechTask
	from utils.audio.align import mel2token_to_dur
	from utils.commons.hparams import hparams
	from utils.metrics.diagonal_metrics import get_focus_rate, get_phone_coverage_rate, get_diagonal_focus_rate
	from utils.nn.model_utils import num_params
	import numpy as np

	from utils.plot.plot import spec_to_figure
	from utils.text.text_encoder import build_token_encoder


	class PortaSpeechTask(FastSpeechTask):
	def __init__(self):
	super().__init__()
	data_dir = hparams['binary_data_dir']
	self.word_encoder = build_token_encoder(f'{data_dir}/word_set.json')

	def build_tts_model(self):
	ph_dict_size = len(self.token_encoder)
	word_dict_size = len(self.word_encoder)
	self.model = PortaSpeech(ph_dict_size, word_dict_size, hparams)

	def on_train_start(self):
	super().on_train_start()
	for n, m in self.model.named_children():
	num_params(m, model_name=n)
	if hasattr(self.model, 'fvae'):
	for n, m in self.model.fvae.named_children():
	num_params(m, model_name=f'fvae.{n}')

	def run_model(self, sample, infer=False, args, *kwargs):
	txt_tokens = sample['txt_tokens']
	word_tokens = sample['word_tokens']
	spk_embed = sample.get('spk_embed')
	spk_id = sample.get('spk_ids')
	if not infer:
	output = self.model(txt_tokens, word_tokens,
	ph2word=sample['ph2word'],
	mel2word=sample['mel2word'],
	mel2ph=sample['mel2ph'],
	word_len=sample['word_lengths'].max(),
	tgt_mels=sample['mels'],
	pitch=sample.get('pitch'),
	spk_embed=spk_embed,
	spk_id=spk_id,
	infer=False,
	global_step=self.global_step)
	losses = {}
	losses['kl_v'] = output['kl'].detach()
	losses_kl = output['kl']
	losses_kl = torch.clamp(losses_kl, min=hparams['kl_min'])
	losses_kl = min(self.global_step / hparams['kl_start_steps'], 1) * losses_kl
	losses_kl = losses_kl * hparams['lambda_kl']
	losses['kl'] = losses_kl
	self.add_mel_loss(output['mel_out'], sample['mels'], losses)
	if hparams['dur_level'] == 'word':
	self.add_dur_loss(
	output['dur'], sample['mel2word'], sample['word_lengths'], sample['txt_tokens'], losses)
	self.get_attn_stats(output['attn'], sample, losses)
	else:
	super(PortaSpeechTask, self).add_dur_loss(output['dur'], sample['mel2ph'], sample['txt_tokens'], losses)
	return losses, output
	else:
	use_gt_dur = kwargs.get('infer_use_gt_dur', hparams['use_gt_dur'])
	output = self.model(
	txt_tokens, word_tokens,
	ph2word=sample['ph2word'],
	word_len=sample['word_lengths'].max(),
	pitch=sample.get('pitch'),
	mel2ph=sample['mel2ph'] if use_gt_dur else None,
	mel2word=sample['mel2word'] if use_gt_dur else None,
	tgt_mels=sample['mels'],
	infer=True,
	spk_embed=spk_embed,
	spk_id=spk_id,
	)
	return output

	def add_dur_loss(self, dur_pred, mel2token, word_len, txt_tokens, losses=None):
	T = word_len.max()
	dur_gt = mel2token_to_dur(mel2token, T).float()
	nonpadding = (torch.arange(T).to(dur_pred.device)[None, :] < word_len[:, None]).float()
	dur_pred = dur_pred * nonpadding
	dur_gt = dur_gt * nonpadding
	wdur = F.l1_loss((dur_pred + 1).log(), (dur_gt + 1).log(), reduction='none')
	wdur = (wdur * nonpadding).sum() / nonpadding.sum()
	if hparams['lambda_word_dur'] > 0:
	losses['wdur'] = wdur * hparams['lambda_word_dur']
	if hparams['lambda_sent_dur'] > 0:
	sent_dur_p = dur_pred.sum(-1)
	sent_dur_g = dur_gt.sum(-1)
	sdur_loss = F.l1_loss(sent_dur_p, sent_dur_g, reduction='mean')
	losses['sdur'] = sdur_loss.mean() * hparams['lambda_sent_dur']

	def validation_step(self, sample, batch_idx):
	return super().validation_step(sample, batch_idx)

	def save_valid_result(self, sample, batch_idx, model_out):
	super(PortaSpeechTask, self).save_valid_result(sample, batch_idx, model_out)
	if self.global_step > 0 and hparams['dur_level'] == 'word':
	self.logger.add_figure(f'attn_{batch_idx}', spec_to_figure(model_out['attn'][0]), self.global_step)

	def get_attn_stats(self, attn, sample, logging_outputs, prefix=''):
	# diagonal_focus_rate
	txt_lengths = sample['txt_lengths'].float()
	mel_lengths = sample['mel_lengths'].float()
	src_padding_mask = sample['txt_tokens'].eq(0)
	target_padding_mask = sample['mels'].abs().sum(-1).eq(0)
	src_seg_mask = sample['txt_tokens'].eq(self.seg_idx)
	attn_ks = txt_lengths.float() / mel_lengths.float()

	focus_rate = get_focus_rate(attn, src_padding_mask, target_padding_mask).mean().data
	phone_coverage_rate = get_phone_coverage_rate(
	attn, src_padding_mask, src_seg_mask, target_padding_mask).mean()
	diagonal_focus_rate, diag_mask = get_diagonal_focus_rate(
	attn, attn_ks, mel_lengths, src_padding_mask, target_padding_mask)
	logging_outputs[f'{prefix}fr'] = focus_rate.mean().data
	logging_outputs[f'{prefix}pcr'] = phone_coverage_rate.mean().data
	logging_outputs[f'{prefix}dfr'] = diagonal_focus_rate.mean().data

	def get_plot_dur_info(self, sample, model_out):
	if hparams['dur_level'] == 'word':
	T_txt = sample['word_lengths'].max()
	dur_gt = mel2token_to_dur(sample['mel2word'], T_txt)[0]
	dur_pred = model_out['dur'] if 'dur' in model_out else dur_gt
	txt = sample['ph_words'][0].split(" ")
	else:
	T_txt = sample['txt_tokens'].shape[1]
	dur_gt = mel2token_to_dur(sample['mel2ph'], T_txt)[0]
	dur_pred = model_out['dur'] if 'dur' in model_out else dur_gt
	txt = self.token_encoder.decode(sample['txt_tokens'][0].cpu().numpy())
	txt = txt.split(" ")
	return {'dur_gt': dur_gt, 'dur_pred': dur_pred, 'txt': txt}

	def build_optimizer(self, model):
	self.optimizer = torch.optim.AdamW(
	self.model.parameters(),
	lr=hparams['lr'],
	betas=(hparams['optimizer_adam_beta1'], hparams['optimizer_adam_beta2']),
	weight_decay=hparams['weight_decay'])
	return self.optimizer

	def build_scheduler(self, optimizer):
	return FastSpeechTask.build_scheduler(self, optimizer)

	############
	# infer
	############
	def test_start(self):
	super().test_start()
	if hparams.get('save_attn', False):
	os.makedirs(f'{self.gen_dir}/attn', exist_ok=True)
	self.model.store_inverse_all()

	def test_step(self, sample, batch_idx):
	assert sample['txt_tokens'].shape[0] == 1, 'only support batch_size=1 in inference'
	outputs = self.run_model(sample, infer=True)
	text = sample['text'][0]
	item_name = sample['item_name'][0]
	tokens = sample['txt_tokens'][0].cpu().numpy()
	mel_gt = sample['mels'][0].cpu().numpy()
	mel_pred = outputs['mel_out'][0].cpu().numpy()
	mel2ph = sample['mel2ph'][0].cpu().numpy()
	mel2ph_pred = None
	str_phs = self.token_encoder.decode(tokens, strip_padding=True)
	base_fn = f'[{batch_idx:06d}][{item_name.replace("%", "_")}][%s]'
	if text is not None:
	base_fn += text.replace(":", "$3A")[:80]
	base_fn = base_fn.replace(' ', '_')
	gen_dir = self.gen_dir
	wav_pred = self.vocoder.spec2wav(mel_pred)
	self.saving_result_pool.add_job(self.save_result, args=[
	wav_pred, mel_pred, base_fn % 'P', gen_dir, str_phs, mel2ph_pred])
	if hparams['save_gt']:
	wav_gt = self.vocoder.spec2wav(mel_gt)
	self.saving_result_pool.add_job(self.save_result, args=[
	wav_gt, mel_gt, base_fn % 'G', gen_dir, str_phs, mel2ph])
	if hparams.get('save_attn', False):
	attn = outputs['attn'][0].cpu().numpy()
	np.save(f'{gen_dir}/attn/{item_name}.npy', attn)
	print(f"Pred_shape: {mel_pred.shape}, gt_shape: {mel_gt.shape}")
	return {
	'item_name': item_name,
	'text': text,
	'ph_tokens': self.token_encoder.decode(tokens.tolist()),
	'wav_fn_pred': base_fn % 'P',
	'wav_fn_gt': base_fn % 'G',
	}