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	import os
	import shutil
	import unittest

	import numpy as np
	import torch
	from torch.utils.data import DataLoader

	from tests import get_tests_data_path, get_tests_output_path
	from TTS.tts.configs.shared_configs import BaseDatasetConfig, BaseTTSConfig
	from TTS.tts.datasets import TTSDataset, load_tts_samples
	from TTS.tts.utils.text.tokenizer import TTSTokenizer
	from TTS.utils.audio import AudioProcessor

	# pylint: disable=unused-variable

	OUTPATH = os.path.join(get_tests_output_path(), "loader_tests/")
	os.makedirs(OUTPATH, exist_ok=True)

	# create a dummy config for testing data loaders.
	c = BaseTTSConfig(text_cleaner="english_cleaners", num_loader_workers=0, batch_size=2, use_noise_augment=False)
	c.r = 5
	c.data_path = os.path.join(get_tests_data_path(), "ljspeech/")
	ok_ljspeech = os.path.exists(c.data_path)

	dataset_config = BaseDatasetConfig(
	formatter="ljspeech_test", # ljspeech_test to multi-speaker
	meta_file_train="metadata.csv",
	meta_file_val=None,
	path=c.data_path,
	language="en",
	)

	DATA_EXIST = True
	if not os.path.exists(c.data_path):
	DATA_EXIST = False

	print(" > Dynamic data loader test: {}".format(DATA_EXIST))


	class TestTTSDataset(unittest.TestCase):
	def __init__(self, args, *kwargs):
	super().__init__(args, *kwargs)
	self.max_loader_iter = 4
	self.ap = AudioProcessor(**c.audio)

	def _create_dataloader(self, batch_size, r, bgs, start_by_longest=False):
	# load dataset
	meta_data_train, meta_data_eval = load_tts_samples(dataset_config, eval_split=True, eval_split_size=0.2)
	items = meta_data_train + meta_data_eval

	tokenizer, _ = TTSTokenizer.init_from_config(c)
	dataset = TTSDataset(
	outputs_per_step=r,
	compute_linear_spec=True,
	return_wav=True,
	tokenizer=tokenizer,
	ap=self.ap,
	samples=items,
	batch_group_size=bgs,
	min_text_len=c.min_text_len,
	max_text_len=c.max_text_len,
	min_audio_len=c.min_audio_len,
	max_audio_len=c.max_audio_len,
	start_by_longest=start_by_longest,
	)
	dataloader = DataLoader(
	dataset,
	batch_size=batch_size,
	shuffle=False,
	collate_fn=dataset.collate_fn,
	drop_last=True,
	num_workers=c.num_loader_workers,
	)
	return dataloader, dataset

	def test_loader(self):
	if ok_ljspeech:
	dataloader, dataset = self._create_dataloader(1, 1, 0)

	for i, data in enumerate(dataloader):
	if i == self.max_loader_iter:
	break
	text_input = data["token_id"]
	_ = data["token_id_lengths"]
	speaker_name = data["speaker_names"]
	linear_input = data["linear"]
	mel_input = data["mel"]
	mel_lengths = data["mel_lengths"]
	_ = data["stop_targets"]
	_ = data["item_idxs"]
	wavs = data["waveform"]

	neg_values = text_input[text_input < 0]
	check_count = len(neg_values)

	# check basic conditions
	self.assertEqual(check_count, 0)
	self.assertEqual(linear_input.shape[0], mel_input.shape[0], c.batch_size)
	self.assertEqual(linear_input.shape[2], self.ap.fft_size // 2 + 1)
	self.assertEqual(mel_input.shape[2], c.audio["num_mels"])
	self.assertEqual(wavs.shape[1], mel_input.shape[1] * c.audio.hop_length)
	self.assertIsInstance(speaker_name[0], str)

	# make sure that the computed mels and the waveform match and correctly computed
	mel_new = self.ap.melspectrogram(wavs[0].squeeze().numpy())
	# remove padding in mel-spectrogram
	mel_dataloader = mel_input[0].T.numpy()[:, : mel_lengths[0]]
	# guarantee that both mel-spectrograms have the same size and that we will remove waveform padding
	mel_new = mel_new[:, : mel_lengths[0]]
	ignore_seg = -(1 + c.audio.win_length // c.audio.hop_length)
	mel_diff = (mel_new[:, : mel_input.shape[1]] - mel_input[0].T.numpy())[:, 0:ignore_seg]
	self.assertLess(abs(mel_diff.sum()), 1e-5)

	# check normalization ranges
	if self.ap.symmetric_norm:
	self.assertLessEqual(mel_input.max(), self.ap.max_norm)
	self.assertGreaterEqual(
	mel_input.min(), -self.ap.max_norm # pylint: disable=invalid-unary-operand-type
	)
	self.assertLess(mel_input.min(), 0)
	else:
	self.assertLessEqual(mel_input.max(), self.ap.max_norm)
	self.assertGreaterEqual(mel_input.min(), 0)

	def test_batch_group_shuffle(self):
	if ok_ljspeech:
	dataloader, dataset = self._create_dataloader(2, c.r, 16)
	last_length = 0
	frames = dataset.samples
	for i, data in enumerate(dataloader):
	if i == self.max_loader_iter:
	break
	mel_lengths = data["mel_lengths"]
	avg_length = mel_lengths.numpy().mean()
	dataloader.dataset.preprocess_samples()
	is_items_reordered = False
	for idx, item in enumerate(dataloader.dataset.samples):
	if item != frames[idx]:
	is_items_reordered = True
	break
	self.assertGreaterEqual(avg_length, last_length)
	self.assertTrue(is_items_reordered)

	def test_start_by_longest(self):
	"""Test start_by_longest option.

	Ther first item of the fist batch must be longer than all the other items.
	"""
	if ok_ljspeech:
	dataloader, _ = self._create_dataloader(2, c.r, 0, True)
	dataloader.dataset.preprocess_samples()
	for i, data in enumerate(dataloader):
	if i == self.max_loader_iter:
	break
	mel_lengths = data["mel_lengths"]
	if i == 0:
	max_len = mel_lengths[0]
	print(mel_lengths)
	self.assertTrue(all(max_len >= mel_lengths))

	def test_padding_and_spectrograms(self):
	def check_conditions(idx, linear_input, mel_input, stop_target, mel_lengths):
	self.assertNotEqual(linear_input[idx, -1].sum(), 0) # check padding
	self.assertNotEqual(linear_input[idx, -2].sum(), 0)
	self.assertNotEqual(mel_input[idx, -1].sum(), 0)
	self.assertNotEqual(mel_input[idx, -2].sum(), 0)
	self.assertEqual(stop_target[idx, -1], 1)
	self.assertEqual(stop_target[idx, -2], 0)
	self.assertEqual(stop_target[idx].sum(), 1)
	self.assertEqual(len(mel_lengths.shape), 1)
	self.assertEqual(mel_lengths[idx], linear_input[idx].shape[0])
	self.assertEqual(mel_lengths[idx], mel_input[idx].shape[0])

	if ok_ljspeech:
	dataloader, _ = self._create_dataloader(1, 1, 0)

	for i, data in enumerate(dataloader):
	if i == self.max_loader_iter:
	break
	linear_input = data["linear"]
	mel_input = data["mel"]
	mel_lengths = data["mel_lengths"]
	stop_target = data["stop_targets"]
	item_idx = data["item_idxs"]

	# check mel_spec consistency
	wav = np.asarray(self.ap.load_wav(item_idx[0]), dtype=np.float32)
	mel = self.ap.melspectrogram(wav).astype("float32")
	mel = torch.FloatTensor(mel).contiguous()
	mel_dl = mel_input[0]
	# NOTE: Below needs to check == 0 but due to an unknown reason
	# there is a slight difference between two matrices.
	# TODO: Check this assert cond more in detail.
	self.assertLess(abs(mel.T - mel_dl).max(), 1e-5)

	# check mel-spec correctness
	mel_spec = mel_input[0].cpu().numpy()
	wav = self.ap.inv_melspectrogram(mel_spec.T)
	self.ap.save_wav(wav, OUTPATH + "/mel_inv_dataloader.wav")
	shutil.copy(item_idx[0], OUTPATH + "/mel_target_dataloader.wav")

	# check linear-spec
	linear_spec = linear_input[0].cpu().numpy()
	wav = self.ap.inv_spectrogram(linear_spec.T)
	self.ap.save_wav(wav, OUTPATH + "/linear_inv_dataloader.wav")
	shutil.copy(item_idx[0], OUTPATH + "/linear_target_dataloader.wav")

	# check the outputs
	check_conditions(0, linear_input, mel_input, stop_target, mel_lengths)

	# Test for batch size 2
	dataloader, _ = self._create_dataloader(2, 1, 0)

	for i, data in enumerate(dataloader):
	if i == self.max_loader_iter:
	break
	linear_input = data["linear"]
	mel_input = data["mel"]
	mel_lengths = data["mel_lengths"]
	stop_target = data["stop_targets"]
	item_idx = data["item_idxs"]

	# set id to the longest sequence in the batch
	if mel_lengths[0] > mel_lengths[1]:
	idx = 0
	else:
	idx = 1

	# check the longer item in the batch
	check_conditions(idx, linear_input, mel_input, stop_target, mel_lengths)

	# check the other item in the batch
	self.assertEqual(linear_input[1 - idx, -1].sum(), 0)
	self.assertEqual(mel_input[1 - idx, -1].sum(), 0)
	self.assertEqual(stop_target[1, mel_lengths[1] - 1], 1)
	self.assertEqual(stop_target[1, mel_lengths[1] :].sum(), stop_target.shape[1] - mel_lengths[1])
	self.assertEqual(len(mel_lengths.shape), 1)

	# check batch zero-frame conditions (zero-frame disabled)
	# assert (linear_input * stop_target.unsqueeze(2)).sum() == 0
	# assert (mel_input * stop_target.unsqueeze(2)).sum() == 0