rvc-ui / rvc /hubert.py
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import math
import random
from typing import Optional, Tuple
from fairseq.checkpoint_utils import load_model_ensemble_and_task
from fairseq.utils import index_put
import numpy as np
import torch
import torch.nn.functional as F
# @torch.jit.script
def pad_to_multiple(x, multiple, dim=-1, value=0):
# Inspired from https://github.com/lucidrains/local-attention/blob/master/local_attention/local_attention.py#L41
if x is None:
return None, 0
tsz = x.size(dim)
m = tsz / multiple
remainder = math.ceil(m) * multiple - tsz
if int(tsz % multiple) == 0:
return x, 0
pad_offset = (0,) * (-1 - dim) * 2
return F.pad(x, (*pad_offset, 0, remainder), value=value), remainder
def extract_features(
self,
x,
padding_mask=None,
tgt_layer=None,
min_layer=0,
):
if padding_mask is not None:
x = index_put(x, padding_mask, 0)
x_conv = self.pos_conv(x.transpose(1, 2))
x_conv = x_conv.transpose(1, 2)
x = x + x_conv
if not self.layer_norm_first:
x = self.layer_norm(x)
# pad to the sequence length dimension
x, pad_length = pad_to_multiple(x, self.required_seq_len_multiple, dim=-2, value=0)
if pad_length > 0 and padding_mask is None:
padding_mask = x.new_zeros((x.size(0), x.size(1)), dtype=torch.bool)
padding_mask[:, -pad_length:] = True
else:
padding_mask, _ = pad_to_multiple(
padding_mask, self.required_seq_len_multiple, dim=-1, value=True
)
x = F.dropout(x, p=self.dropout, training=self.training)
# B x T x C -> T x B x C
x = x.transpose(0, 1)
layer_results = []
r = None
for i, layer in enumerate(self.layers):
dropout_probability = np.random.random() if self.layerdrop > 0 else 1
if not self.training or (dropout_probability > self.layerdrop):
x, (z, lr) = layer(
x, self_attn_padding_mask=padding_mask, need_weights=False
)
if i >= min_layer:
layer_results.append((x, z, lr))
if i == tgt_layer:
r = x
break
if r is not None:
x = r
# T x B x C -> B x T x C
x = x.transpose(0, 1)
# undo paddding
if pad_length > 0:
x = x[:, :-pad_length]
def undo_pad(a, b, c):
return (
a[:-pad_length],
b[:-pad_length] if b is not None else b,
c[:-pad_length],
)
layer_results = [undo_pad(*u) for u in layer_results]
return x, layer_results
def compute_mask_indices(
shape: Tuple[int, int],
padding_mask: Optional[torch.Tensor],
mask_prob: float,
mask_length: int,
mask_type: str = "static",
mask_other: float = 0.0,
min_masks: int = 0,
no_overlap: bool = False,
min_space: int = 0,
require_same_masks: bool = True,
mask_dropout: float = 0.0,
) -> torch.Tensor:
"""
Computes random mask spans for a given shape
Args:
shape: the the shape for which to compute masks.
should be of size 2 where first element is batch size and 2nd is timesteps
padding_mask: optional padding mask of the same size as shape, which will prevent masking padded elements
mask_prob: probability for each token to be chosen as start of the span to be masked. this will be multiplied by
number of timesteps divided by length of mask span to mask approximately this percentage of all elements.
however due to overlaps, the actual number will be smaller (unless no_overlap is True)
mask_type: how to compute mask lengths
static = fixed size
uniform = sample from uniform distribution [mask_other, mask_length*2]
normal = sample from normal distribution with mean mask_length and stdev mask_other. mask is min 1 element
poisson = sample from possion distribution with lambda = mask length
min_masks: minimum number of masked spans
no_overlap: if false, will switch to an alternative recursive algorithm that prevents spans from overlapping
min_space: only used if no_overlap is True, this is how many elements to keep unmasked between spans
require_same_masks: if true, will randomly drop out masks until same amount of masks remains in each sample
mask_dropout: randomly dropout this percentage of masks in each example
"""
bsz, all_sz = shape
mask = torch.full((bsz, all_sz), False)
all_num_mask = int(
# add a random number for probabilistic rounding
mask_prob * all_sz / float(mask_length)
+ torch.rand([1]).item()
)
all_num_mask = max(min_masks, all_num_mask)
mask_idcs = []
for i in range(bsz):
if padding_mask is not None:
sz = all_sz - padding_mask[i].long().sum().item()
num_mask = int(mask_prob * sz / float(mask_length) + np.random.rand())
num_mask = max(min_masks, num_mask)
else:
sz = all_sz
num_mask = all_num_mask
if mask_type == "static":
lengths = torch.full([num_mask], mask_length)
elif mask_type == "uniform":
lengths = torch.randint(mask_other, mask_length * 2 + 1, size=[num_mask])
elif mask_type == "normal":
lengths = torch.normal(mask_length, mask_other, size=[num_mask])
lengths = [max(1, int(round(x))) for x in lengths]
else:
raise Exception("unknown mask selection " + mask_type)
if sum(lengths) == 0:
lengths[0] = min(mask_length, sz - 1)
if no_overlap:
mask_idc = []
def arrange(s, e, length, keep_length):
span_start = torch.randint(low=s, high=e - length, size=[1]).item()
mask_idc.extend(span_start + i for i in range(length))
new_parts = []
if span_start - s - min_space >= keep_length:
new_parts.append((s, span_start - min_space + 1))
if e - span_start - length - min_space > keep_length:
new_parts.append((span_start + length + min_space, e))
return new_parts
parts = [(0, sz)]
min_length = min(lengths)
for length in sorted(lengths, reverse=True):
t = [e - s if e - s >= length + min_space else 0 for s, e in parts]
lens = torch.asarray(t, dtype=torch.int)
l_sum = torch.sum(lens)
if l_sum == 0:
break
probs = lens / torch.sum(lens)
c = torch.multinomial(probs.float(), len(parts)).item()
s, e = parts.pop(c)
parts.extend(arrange(s, e, length, min_length))
mask_idc = torch.asarray(mask_idc)
else:
min_len = min(lengths)
if sz - min_len <= num_mask:
min_len = sz - num_mask - 1
mask_idc = torch.asarray(
random.sample([i for i in range(sz - min_len)], num_mask)
)
mask_idc = torch.asarray(
[
mask_idc[j] + offset
for j in range(len(mask_idc))
for offset in range(lengths[j])
]
)
mask_idcs.append(torch.unique(mask_idc[mask_idc < sz]))
min_len = min([len(m) for m in mask_idcs])
for i, mask_idc in enumerate(mask_idcs):
if isinstance(mask_idc, torch.Tensor):
mask_idc = torch.asarray(mask_idc, dtype=torch.float)
if len(mask_idc) > min_len and require_same_masks:
mask_idc = torch.asarray(
random.sample([i for i in range(mask_idc)], min_len)
)
if mask_dropout > 0:
num_holes = int(round(len(mask_idc) * mask_dropout))
mask_idc = torch.asarray(
random.sample([i for i in range(mask_idc)], len(mask_idc) - num_holes)
)
mask[i, mask_idc.int()] = True
return mask
def apply_mask(self, x, padding_mask, target_list):
B, T, C = x.shape
torch.zeros_like(x)
if self.mask_prob > 0:
mask_indices = compute_mask_indices(
(B, T),
padding_mask,
self.mask_prob,
self.mask_length,
self.mask_selection,
self.mask_other,
min_masks=2,
no_overlap=self.no_mask_overlap,
min_space=self.mask_min_space,
)
mask_indices = mask_indices.to(x.device)
x[mask_indices] = self.mask_emb
else:
mask_indices = None
if self.mask_channel_prob > 0:
mask_channel_indices = compute_mask_indices(
(B, C),
None,
self.mask_channel_prob,
self.mask_channel_length,
self.mask_channel_selection,
self.mask_channel_other,
no_overlap=self.no_mask_channel_overlap,
min_space=self.mask_channel_min_space,
)
mask_channel_indices = (
mask_channel_indices.to(x.device).unsqueeze(1).expand(-1, T, -1)
)
x[mask_channel_indices] = 0
return x, mask_indices
def get_hubert(model_path="assets/hubert/hubert_base.pt", device=torch.device("cpu")):
models, _, _ = load_model_ensemble_and_task(
[model_path],
suffix="",
)
hubert_model = models[0]
hubert_model = hubert_model.to(device)
def _apply_mask(x, padding_mask, target_list):
return apply_mask(hubert_model, x, padding_mask, target_list)
hubert_model.apply_mask = _apply_mask
def _extract_features(
x,
padding_mask=None,
tgt_layer=None,
min_layer=0,
):
return extract_features(
hubert_model.encoder,
x,
padding_mask=padding_mask,
tgt_layer=tgt_layer,
min_layer=min_layer,
)
hubert_model.encoder.extract_features = _extract_features
hubert_model._forward = hubert_model.forward
def hubert_extract_features(
self,
source: torch.Tensor,
padding_mask: Optional[torch.Tensor] = None,
mask: bool = False,
ret_conv: bool = False,
output_layer: Optional[int] = None,
) -> Tuple[torch.Tensor, torch.Tensor]:
res = self._forward(
source,
padding_mask=padding_mask,
mask=mask,
features_only=True,
output_layer=output_layer,
)
feature = res["features"] if ret_conv else res["x"]
return feature, res["padding_mask"]
def _hubert_extract_features(
source: torch.Tensor,
padding_mask: Optional[torch.Tensor] = None,
mask: bool = False,
ret_conv: bool = False,
output_layer: Optional[int] = None,
) -> Tuple[torch.Tensor, torch.Tensor]:
return hubert_extract_features(
hubert_model, source, padding_mask, mask, ret_conv, output_layer
)
hubert_model.extract_features = _hubert_extract_features
def infer(source, padding_mask, output_layer: torch.Tensor):
output_layer = output_layer.item()
logits = hubert_model.extract_features(
source=source, padding_mask=padding_mask, output_layer=output_layer
)
feats = hubert_model.final_proj(logits[0]) if output_layer == 9 else logits[0]
return feats
hubert_model.infer = infer
# hubert_model.forward=infer
# hubert_model.forward
return hubert_model