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# Copyright (c) 2023 Amphion.
#
# This source code is licensed under the MIT license found in the
# LICENSE file in the root directory of this source tree.
import random
import torch
from torch.nn.utils.rnn import pad_sequence
from utils.data_utils import *
from models.base.base_dataset import (
BaseOfflineCollator,
BaseOfflineDataset,
BaseTestDataset,
BaseTestCollator,
)
from text import text_to_sequence
class FS2Dataset(BaseOfflineDataset):
def __init__(self, cfg, dataset, is_valid=False):
BaseOfflineDataset.__init__(self, cfg, dataset, is_valid=is_valid)
self.batch_size = cfg.train.batch_size
cfg = cfg.preprocess
# utt2duration
self.utt2duration_path = {}
for utt_info in self.metadata:
dataset = utt_info["Dataset"]
uid = utt_info["Uid"]
utt = "{}_{}".format(dataset, uid)
self.utt2duration_path[utt] = os.path.join(
cfg.processed_dir,
dataset,
cfg.duration_dir,
uid + ".npy",
)
self.utt2dur = self.read_duration()
if cfg.use_frame_energy:
self.frame_utt2energy, self.energy_statistic = load_energy(
self.metadata,
cfg.processed_dir,
cfg.energy_dir,
use_log_scale=cfg.use_log_scale_energy,
utt2spk=self.preprocess.utt2spk if cfg.use_spkid else None,
return_norm=True,
)
elif cfg.use_phone_energy:
self.phone_utt2energy, self.energy_statistic = load_energy(
self.metadata,
cfg.processed_dir,
cfg.phone_energy_dir,
use_log_scale=cfg.use_log_scale_energy,
utt2spk=self.utt2spk if cfg.use_spkid else None,
return_norm=True,
)
if cfg.use_frame_pitch:
self.frame_utt2pitch, self.pitch_statistic = load_energy(
self.metadata,
cfg.processed_dir,
cfg.pitch_dir,
use_log_scale=cfg.energy_extract_mode,
utt2spk=self.utt2spk if cfg.use_spkid else None,
return_norm=True,
)
elif cfg.use_phone_pitch:
self.phone_utt2pitch, self.pitch_statistic = load_energy(
self.metadata,
cfg.processed_dir,
cfg.phone_pitch_dir,
use_log_scale=cfg.use_log_scale_pitch,
utt2spk=self.utt2spk if cfg.use_spkid else None,
return_norm=True,
)
# utt2lab
self.utt2lab_path = {}
for utt_info in self.metadata:
dataset = utt_info["Dataset"]
uid = utt_info["Uid"]
utt = "{}_{}".format(dataset, uid)
self.utt2lab_path[utt] = os.path.join(
cfg.processed_dir,
dataset,
cfg.lab_dir,
uid + ".txt",
)
self.speaker_map = {}
if os.path.exists(os.path.join(cfg.processed_dir, "spk2id.json")):
with open(
os.path.exists(os.path.join(cfg.processed_dir, "spk2id.json"))
) as f:
self.speaker_map = json.load(f)
self.metadata = self.check_metadata()
def __getitem__(self, index):
single_feature = BaseOfflineDataset.__getitem__(self, index)
utt_info = self.metadata[index]
dataset = utt_info["Dataset"]
uid = utt_info["Uid"]
utt = "{}_{}".format(dataset, uid)
duration = self.utt2dur[utt]
# text
f = open(self.utt2lab_path[utt], "r")
phones = f.readlines()[0].strip()
f.close()
# todo: add cleaner(chenxi)
phones_ids = np.array(text_to_sequence(phones, ["english_cleaners"]))
text_len = len(phones_ids)
if self.cfg.preprocess.use_frame_pitch:
pitch = self.frame_utt2pitch[utt]
elif self.cfg.preprocess.use_phone_pitch:
pitch = self.phone_utt2pitch[utt]
if self.cfg.preprocess.use_frame_energy:
energy = self.frame_utt2energy[utt]
elif self.cfg.preprocess.use_phone_energy:
energy = self.phone_utt2energy[utt]
# speaker
if len(self.speaker_map) > 0:
speaker_id = self.speaker_map[utt_info["Singer"]]
else:
speaker_id = 0
single_feature.update(
{
"durations": duration,
"texts": phones_ids,
"spk_id": speaker_id,
"text_len": text_len,
"pitch": pitch,
"energy": energy,
"uid": uid,
}
)
return self.clip_if_too_long(single_feature)
def read_duration(self):
# read duration
utt2dur = {}
for index in range(len(self.metadata)):
utt_info = self.metadata[index]
dataset = utt_info["Dataset"]
uid = utt_info["Uid"]
utt = "{}_{}".format(dataset, uid)
if not os.path.exists(self.utt2mel_path[utt]) or not os.path.exists(
self.utt2duration_path[utt]
):
continue
mel = np.load(self.utt2mel_path[utt]).transpose(1, 0)
duration = np.load(self.utt2duration_path[utt])
assert mel.shape[0] == sum(
duration
), f"{utt}: mismatch length between mel {mel.shape[0]} and sum(duration) {sum(duration)}"
utt2dur[utt] = duration
return utt2dur
def __len__(self):
return len(self.metadata)
def random_select(self, feature_seq_len, max_seq_len, ending_ts=2812):
"""
ending_ts: to avoid invalid whisper features for over 30s audios
2812 = 30 * 24000 // 256
"""
ts = max(feature_seq_len - max_seq_len, 0)
ts = min(ts, ending_ts - max_seq_len)
start = random.randint(0, ts)
end = start + max_seq_len
return start, end
def clip_if_too_long(self, sample, max_seq_len=1000):
"""
sample :
{
'spk_id': (1,),
'target_len': int
'mel': (seq_len, dim),
'frame_pitch': (seq_len,)
'frame_energy': (seq_len,)
'content_vector_feat': (seq_len, dim)
}
"""
if sample["target_len"] <= max_seq_len:
return sample
start, end = self.random_select(sample["target_len"], max_seq_len)
sample["target_len"] = end - start
for k in sample.keys():
if k not in ["spk_id", "target_len"]:
sample[k] = sample[k][start:end]
return sample
def check_metadata(self):
new_metadata = []
for utt_info in self.metadata:
dataset = utt_info["Dataset"]
uid = utt_info["Uid"]
utt = "{}_{}".format(dataset, uid)
if not os.path.exists(self.utt2duration_path[utt]) or not os.path.exists(
self.utt2mel_path[utt]
):
continue
else:
new_metadata.append(utt_info)
return new_metadata
class FS2Collator(BaseOfflineCollator):
"""Zero-pads model inputs and targets based on number of frames per step"""
def __init__(self, cfg):
BaseOfflineCollator.__init__(self, cfg)
self.sort = cfg.train.sort_sample
self.batch_size = cfg.train.batch_size
self.drop_last = cfg.train.drop_last
def __call__(self, batch):
# mel: [b, T, n_mels]
# frame_pitch, frame_energy: [1, T]
# target_len: [1]
# spk_id: [b, 1]
# mask: [b, T, 1]
packed_batch_features = dict()
for key in batch[0].keys():
if key == "target_len":
packed_batch_features["target_len"] = torch.LongTensor(
[b["target_len"] for b in batch]
)
masks = [
torch.ones((b["target_len"], 1), dtype=torch.long) for b in batch
]
packed_batch_features["mask"] = pad_sequence(
masks, batch_first=True, padding_value=0
)
elif key == "text_len":
packed_batch_features["text_len"] = torch.LongTensor(
[b["text_len"] for b in batch]
)
masks = [
torch.ones((b["text_len"], 1), dtype=torch.long) for b in batch
]
packed_batch_features["text_mask"] = pad_sequence(
masks, batch_first=True, padding_value=0
)
elif key == "spk_id":
packed_batch_features["spk_id"] = torch.LongTensor(
[b["spk_id"] for b in batch]
)
elif key == "uid":
packed_batch_features[key] = [b["uid"] for b in batch]
else:
values = [torch.from_numpy(b[key]) for b in batch]
packed_batch_features[key] = pad_sequence(
values, batch_first=True, padding_value=0
)
return packed_batch_features
class FS2TestDataset(BaseTestDataset):
def __init__(self, args, cfg, infer_type=None):
datasets = cfg.dataset
cfg = cfg.preprocess
is_bigdata = False
assert len(datasets) >= 1
if len(datasets) > 1:
datasets.sort()
bigdata_version = "_".join(datasets)
processed_data_dir = os.path.join(cfg.processed_dir, bigdata_version)
is_bigdata = True
else:
processed_data_dir = os.path.join(cfg.processed_dir, args.dataset)
if args.test_list_file:
self.metafile_path = args.test_list_file
self.metadata = self.get_metadata()
else:
assert args.testing_set
source_metafile_path = os.path.join(
cfg.processed_dir,
args.dataset,
"{}.json".format(args.testing_set),
)
with open(source_metafile_path, "r") as f:
self.metadata = json.load(f)
self.cfg = cfg
self.datasets = datasets
self.data_root = processed_data_dir
self.is_bigdata = is_bigdata
self.source_dataset = args.dataset
######### Load source acoustic features #########
if cfg.use_spkid:
spk2id_path = os.path.join(self.data_root, cfg.spk2id)
utt2sp_path = os.path.join(self.data_root, cfg.utt2spk)
self.spk2id, self.utt2spk = get_spk_map(spk2id_path, utt2sp_path, datasets)
# utt2lab
self.utt2lab_path = {}
for utt_info in self.metadata:
dataset = utt_info["Dataset"]
uid = utt_info["Uid"]
utt = "{}_{}".format(dataset, uid)
self.utt2lab_path[utt] = os.path.join(
cfg.processed_dir,
dataset,
cfg.lab_dir,
uid + ".txt",
)
self.speaker_map = {}
if os.path.exists(os.path.join(cfg.processed_dir, "spk2id.json")):
with open(
os.path.exists(os.path.join(cfg.processed_dir, "spk2id.json"))
) as f:
self.speaker_map = json.load(f)
def __getitem__(self, index):
single_feature = {}
utt_info = self.metadata[index]
dataset = utt_info["Dataset"]
uid = utt_info["Uid"]
utt = "{}_{}".format(dataset, uid)
# text
f = open(self.utt2lab_path[utt], "r")
phones = f.readlines()[0].strip()
f.close()
phones_ids = np.array(text_to_sequence(phones, self.cfg.text_cleaners))
text_len = len(phones_ids)
# speaker
if len(self.speaker_map) > 0:
speaker_id = self.speaker_map[utt_info["Singer"]]
else:
speaker_id = 0
single_feature.update(
{
"texts": phones_ids,
"spk_id": speaker_id,
"text_len": text_len,
}
)
return single_feature
def __len__(self):
return len(self.metadata)
def get_metadata(self):
with open(self.metafile_path, "r", encoding="utf-8") as f:
metadata = json.load(f)
return metadata
class FS2TestCollator(BaseTestCollator):
"""Zero-pads model inputs and targets based on number of frames per step"""
def __init__(self, cfg):
self.cfg = cfg
def __call__(self, batch):
packed_batch_features = dict()
# mel: [b, T, n_mels]
# frame_pitch, frame_energy: [1, T]
# target_len: [1]
# spk_id: [b, 1]
# mask: [b, T, 1]
for key in batch[0].keys():
if key == "target_len":
packed_batch_features["target_len"] = torch.LongTensor(
[b["target_len"] for b in batch]
)
masks = [
torch.ones((b["target_len"], 1), dtype=torch.long) for b in batch
]
packed_batch_features["mask"] = pad_sequence(
masks, batch_first=True, padding_value=0
)
elif key == "text_len":
packed_batch_features["text_len"] = torch.LongTensor(
[b["text_len"] for b in batch]
)
masks = [
torch.ones((b["text_len"], 1), dtype=torch.long) for b in batch
]
packed_batch_features["text_mask"] = pad_sequence(
masks, batch_first=True, padding_value=0
)
elif key == "spk_id":
packed_batch_features["spk_id"] = torch.LongTensor(
[b["spk_id"] for b in batch]
)
else:
values = [torch.from_numpy(b[key]) for b in batch]
packed_batch_features[key] = pad_sequence(
values, batch_first=True, padding_value=0
)
return packed_batch_features
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