Fun-CineForge-Demo / funcineforge /models /flow_matching_model.py
xuan3986's picture
Upload 111 files
03022ee verified
Raw
History Blame Contribute Delete
21.7 kB
import os.path
import torch
import torch.nn as nn
from typing import Dict
import logging
from librosa.filters import mel as librosa_mel_fn
import torch.nn.functional as F
from funcineforge.models.utils.nets_utils import make_pad_mask
from funcineforge.utils.device_funcs import to_device
import numpy as np
from funcineforge.utils.load_utils import extract_campp_xvec
import time
from funcineforge.models.utils import dtype_map
from funcineforge.utils.hinter import hint_once
from funcineforge.models.utils.masks import add_optional_chunk_mask
from .modules.dit_flow_matching.dit_model import DiT
class Audio2Mel(nn.Module):
def __init__(
self,
n_fft=1024,
hop_length=256,
win_length=1024,
sampling_rate=22050,
n_mel_channels=80,
mel_fmin=0.0,
mel_fmax=None,
center=False,
device='cuda',
feat_type="power_log",
):
super().__init__()
##############################################
# FFT Parameters
##############################################
window = torch.hann_window(win_length, device=device).float()
mel_basis = librosa_mel_fn(
sr=sampling_rate, n_fft=n_fft, n_mels=n_mel_channels, fmin=mel_fmin, fmax=mel_fmax
)
mel_basis = torch.from_numpy(mel_basis).float().to(device)
self.register_buffer("mel_basis", mel_basis)
self.register_buffer("window", window)
self.n_fft = n_fft
self.hop_length = hop_length
self.win_length = win_length
self.sampling_rate = sampling_rate
self.n_mel_channels = n_mel_channels
self.mel_fmax = mel_fmax
self.center = center
self.feat_type = feat_type
def forward(self, audioin):
p = (self.n_fft - self.hop_length) // 2
audio = F.pad(audioin, (p, p), "reflect").squeeze(1)
fft = torch.stft(
audio,
n_fft=self.n_fft,
hop_length=self.hop_length,
win_length=self.win_length,
window=self.window,
center=self.center,
pad_mode="reflect",
normalized=False,
onesided=True,
return_complex=True,
)
if self.feat_type == "mag_log10":
power_spec = torch.sqrt(torch.pow(fft.imag, 2) + torch.pow(fft.real, 2))
mel_output = torch.matmul(self.mel_basis, power_spec)
return torch.log10(torch.clamp(mel_output, min=1e-5))
power_spec = torch.pow(fft.imag, 2) + torch.pow(fft.real, 2)
mel_spec = torch.matmul(self.mel_basis, torch.sqrt(power_spec + 1e-9))
return self.spectral_normalize(mel_spec)
@classmethod
def spectral_normalize(cls, spec, C=1, clip_val=1e-5):
output = cls.dynamic_range_compression(spec, C, clip_val)
return output
@classmethod
def spectral_de_normalize_torch(cls, spec, C=1, clip_val=1e-5):
output = cls.dynamic_range_decompression(spec, C, clip_val)
return output
@staticmethod
def dynamic_range_compression(x, C=1, clip_val=1e-5):
return torch.log(torch.clamp(x, min=clip_val) * C)
@staticmethod
def dynamic_range_decompression(x, C=1):
return torch.exp(x) / C
class LookaheadBlock(nn.Module):
def __init__(self, in_channels: int, channels: int, pre_lookahead_len: int = 1):
super().__init__()
self.channels = channels
self.pre_lookahead_len = pre_lookahead_len
self.conv1 = nn.Conv1d(
in_channels, channels,
kernel_size=pre_lookahead_len+1,
stride=1, padding=0,
)
self.conv2 = nn.Conv1d(
channels, in_channels,
kernel_size=3, stride=1, padding=0,
)
def forward(self, inputs, ilens, context: torch.Tensor = torch.zeros(0, 0, 0)):
"""
inputs: (batch_size, seq_len, channels)
"""
outputs = inputs.transpose(1, 2).contiguous()
context = context.transpose(1, 2).contiguous()
# look ahead
if context.size(2) == 0:
outputs = F.pad(outputs, (0, self.pre_lookahead_len), mode='constant', value=0)
else:
assert context.size(2) == self.pre_lookahead_len
outputs = torch.concat([outputs, context], dim=2)
outputs = F.leaky_relu(self.conv1(outputs))
# outputs
outputs = F.pad(outputs, (2, 0), mode='constant', value=0)
outputs = self.conv2(outputs)
outputs = outputs.transpose(1, 2).contiguous()
mask = (~make_pad_mask(ilens).unsqueeze(-1).to(inputs.device))
# residual connection
outputs = (outputs + inputs) * mask
return outputs, ilens
class CosyVoiceFlowMatching(nn.Module):
def __init__(
self,
codebook_size: int,
model_size: int,
xvec_size: int = 198,
dit_conf: Dict = {},
mel_feat_conf: Dict = {},
prompt_conf: Dict = None,
**kwargs):
super().__init__()
# feat related
self.feat_token_ratio = kwargs.get("feat_token_ratio", None)
try:
self.mel_extractor = Audio2Mel(**mel_feat_conf)
self.sample_rate = self.mel_extractor.sampling_rate
except:
self.mel_extractor = None
self.sample_rate = 24000
self.mel_norm_type = kwargs.get("mel_norm_type", None)
self.num_mels = num_mels = mel_feat_conf["n_mel_channels"]
self.token_rate = kwargs.get("token_rate", 25)
self.model_dtype = kwargs.get("model_dtype", "fp32")
self.codebook_size = codebook_size
# condition related
self.prompt_conf = prompt_conf
if self.prompt_conf is not None:
self.prompt_masker = self.build_prompt_masker()
# codec related
self.codec_embedder = nn.Embedding(codebook_size, num_mels)
lookahead_length = kwargs.get("lookahead_length", 4)
self.lookahead_conv1d = LookaheadBlock(num_mels, model_size, lookahead_length)
# spk embed related
if xvec_size is not None:
self.xvec_proj = torch.nn.Linear(xvec_size, num_mels)
# dit model related
self.dit_conf = dit_conf
self.dit_model = DiT(**dit_conf)
self.training_cfg_rate = kwargs.get("training_cfg_rate", 0)
self.only_mask_loss = kwargs.get("only_mask_loss", True)
# NOTE fm需要右看的下文
self.context_size = self.lookahead_conv1d.pre_lookahead_len
def build_prompt_masker(self):
prompt_type = self.prompt_conf.get("prompt_type", "free")
if prompt_type == "prefix":
from funcineforge.models.utils.mask_along_axis import MaskTailVariableMaxWidth
masker = MaskTailVariableMaxWidth(
mask_width_ratio_range=self.prompt_conf["prompt_width_ratio_range"],
)
else:
raise NotImplementedError
return masker
@staticmethod
def norm_spk_emb(xvec):
xvec_mask = (~xvec.norm(dim=-1).isnan()) * (~xvec.norm(dim=-1).isinf())
xvec = xvec * xvec_mask.unsqueeze(-1)
xvec = xvec.mean(dim=1)
xvec = F.normalize(xvec, dim=1)
return xvec
def select_target_prompt(self, y: torch.Tensor, y_lengths: torch.Tensor):
# cond_mask: 1, 1, 1, ..., 0, 0, 0
cond_mask = self.prompt_masker(y, y_lengths, return_mask=True)
return cond_mask
@torch.no_grad()
def normalize_mel_feat(self, feat, feat_lengths):
# feat in B,T,D
if self.mel_norm_type == "mean_std":
max_length = feat.shape[1]
mask = (~make_pad_mask(feat_lengths, maxlen=max_length))
mask = mask.unsqueeze(-1).to(feat)
mean = ((feat * mask).sum(dim=(1, 2), keepdim=True) /
(mask.sum(dim=(1, 2), keepdim=True) * feat.shape[-1]))
var = (((feat - mean)**2 * mask).sum(dim=(1, 2), keepdim=True) /
(mask.sum(dim=(1, 2), keepdim=True) * feat.shape[-1] - 1)) # -1 for unbiased estimation
std = torch.sqrt(var)
feat = (feat - mean) / std
feat = feat * mask
return feat
if self.mel_norm_type == "min_max":
bb, tt, dd = feat.shape
mask = (~make_pad_mask(feat_lengths, maxlen=tt))
mask = mask.unsqueeze(-1).to(feat)
feat_min = (feat * mask).reshape([bb, tt * dd]).min(dim=1, keepdim=True).values.unsqueeze(-1)
feat_max = (feat * mask).reshape([bb, tt * dd]).max(dim=1, keepdim=True).values.unsqueeze(-1)
feat = (feat - feat_min) / (feat_max - feat_min)
# noise ~ N(0, I), P(x >= 3sigma) = 0.001, 3 is enough.
feat = (feat * 3) * mask # feat in [-3, 3]
return feat
else:
raise NotImplementedError
@torch.no_grad()
def extract_feat(self, y: torch.Tensor, y_lengths: torch.Tensor):
mel_extractor = self.mel_extractor.float()
feat = mel_extractor(y)
feat = feat.transpose(1, 2)
feat_lengths = (y_lengths / self.mel_extractor.hop_length).to(y_lengths)
if self.mel_norm_type is not None:
feat = self.normalize_mel_feat(feat, feat_lengths)
return feat, feat_lengths
def load_data(self, contents: dict, **kwargs):
fm_use_prompt = kwargs.get("fm_use_prompt", True)
# codec
codec = contents["codec"]
if isinstance(codec, np.ndarray):
codec = torch.from_numpy(codec)
# codec = torch.from_numpy(codec)[None, :]
codec_lengths = torch.tensor([codec.shape[1]], dtype=torch.int64)
# prompt codec (optional)
prompt_codec = kwargs.get("prompt_codec", None)
prompt_codec_lengths = None
if prompt_codec is not None and fm_use_prompt:
if isinstance(prompt_codec, str) and os.path.exists(prompt_codec):
prompt_codec = np.load(prompt_codec)
if isinstance(prompt_codec, np.ndarray):
prompt_codec = torch.from_numpy(prompt_codec)[None, :]
prompt_codec_lengths = torch.tensor([prompt_codec.shape[1]], dtype=torch.int64)
else:
prompt_codec = None
spk_emb = kwargs.get("spk_emb", None)
spk_emb_lengths = None
if spk_emb is not None:
if isinstance(spk_emb, str) and os.path.exists(spk_emb):
spk_emb = np.load(spk_emb)
if isinstance(spk_emb, np.ndarray):
spk_emb = torch.from_numpy(spk_emb)[None, :]
spk_emb_lengths = torch.tensor([spk_emb.shape[1]], dtype=torch.int64)
# prompt wav as condition
prompt_wav = contents["vocal"]
prompt_wav_lengths = None
if prompt_wav is not None and fm_use_prompt and os.path.exists(prompt_wav):
if prompt_wav.endswith(".npy"):
spk_emb = np.load(prompt_wav)
spk_emb_lengths = torch.tensor([spk_emb.shape[1]], dtype=torch.int64)
else:
spk_emb = extract_campp_xvec(prompt_wav, **kwargs)
spk_emb = torch.from_numpy(spk_emb)
spk_emb_lengths = torch.tensor([spk_emb.shape[1]], dtype=torch.int64)
# prompt_wav = load_audio_text_image_video(prompt_wav, fs=self.sample_rate)
# prompt_wav = prompt_wav[None, :]
# prompt_wav_lengths = torch.tensor([prompt_wav.shape[1]], dtype=torch.int64)
else:
logging.info("[error] prompt_wav is None or not path or path not exists! Please provide the correct speaker embedding.")
output = {
"codec": codec,
"codec_lengths": codec_lengths,
"prompt_codec": prompt_codec,
"prompt_codec_lengths": prompt_codec_lengths,
"prompt_wav": None,
"prompt_wav_lengths": None,
"xvec": spk_emb,
"xvec_lengths": spk_emb_lengths,
}
return output
@torch.no_grad()
def inference(
self,
data_in,
data_lengths=None,
key: list = None,
chunk_size: int = -1,
finalize: bool = True,
**kwargs,
):
uttid = key[0]
if kwargs.get("batch_size", 1) > 1:
raise NotImplementedError("batch decoding is not implemented")
batch = self.load_data(data_in[0], **kwargs)
batch = to_device(batch, kwargs["device"])
batch.update({'finalize': finalize, 'chunk_size': chunk_size})
feat = self._inference(**batch, **kwargs)
feat = feat.float()
logging.info(f"{uttid}: feat lengths {feat.shape[1]}")
return feat
@torch.no_grad()
def _inference(
self,
codec, codec_lengths,
prompt_codec=None, prompt_codec_lengths=None,
prompt_wav=None, prompt_wav_lengths=None,
xvec=None, xvec_lengths=None, chunk_size=-1, finalize=False,
**kwargs
):
fm_dtype = dtype_map[kwargs.get("fm_dtype", "fp32")]
rand_xvec = None
if xvec is not None:
if xvec.dim() == 2:
xvec = xvec.unsqueeze(1)
xvec_lens = torch.ones_like(xvec_lengths)
rand_xvec = self.norm_spk_emb(xvec)
self.xvec_proj.to(fm_dtype)
rand_xvec = self.xvec_proj(rand_xvec.to(fm_dtype))
rand_xvec = rand_xvec.unsqueeze(1)
if (codec >= self.codebook_size).any():
new_codec = codec[codec < self.codebook_size].unsqueeze(0)
logging.info(f"remove out-of-range token for FM: from {codec.shape[1]} to {new_codec.shape[1]}.")
codec_lengths = codec_lengths - (codec.shape[1] - new_codec.shape[1])
codec = new_codec
if prompt_codec is not None:
codec, codec_lengths = self.concat_prompt(prompt_codec, prompt_codec_lengths, codec, codec_lengths)
mask = (codec != -1).float().unsqueeze(-1)
codec_emb = self.codec_embedder(torch.clamp(codec, min=0)) * mask
self.lookahead_conv1d.to(fm_dtype)
if finalize is True:
context = torch.zeros(1, 0, self.codec_embedder.embedding_dim).to(fm_dtype)
else:
codec_emb, context = codec_emb[:, :-self.context_size].to(fm_dtype), codec_emb[:, -self.context_size:].to(fm_dtype)
codec_lengths = codec_lengths - self.context_size
mu, _ = self.lookahead_conv1d(codec_emb, codec_lengths, context)
mu = mu.repeat_interleave(self.feat_token_ratio, dim=1)
# print(mu.size())
conditions = torch.zeros([mu.size(0), mu.shape[1], self.num_mels]).to(mu)
# get conditions
if prompt_wav is not None:
if prompt_wav.ndim == 2:
prompt_wav, prompt_wav_lengths = self.extract_feat(prompt_wav, prompt_wav_lengths)
# NOTE 在fmax12k fm中,尝试mel interploate成token 2倍shape,而不是强制截断
prompt_wav = prompt_wav.to(fm_dtype)
for i, _len in enumerate(prompt_wav_lengths):
conditions[i, :_len] = prompt_wav[i]
feat_lengths = codec_lengths * self.feat_token_ratio
# NOTE add_optional_chunk_mask支持生成-1/1/15/30不同chunk_size的mask
mask = add_optional_chunk_mask(mu, torch.ones([1, 1, mu.shape[1]]).to(mu).bool(), False, False, 0, chunk_size, -1)
feat = self.solve_ode(mu, rand_xvec, conditions.to(fm_dtype), mask, **kwargs)
if prompt_codec is not None and prompt_wav is not None:
feat, feat_lens = self.remove_prompt(None, prompt_wav_lengths, feat, feat_lengths)
return feat
@staticmethod
def concat_prompt(prompt, prompt_lengths, text, text_lengths):
xs_list, x_len_list = [], []
for idx, (_prompt_len, _text_len) in enumerate(zip(prompt_lengths, text_lengths)):
xs_list.append(torch.concat([prompt[idx, :_prompt_len], text[idx, :_text_len]], dim=0))
x_len_list.append(_prompt_len + _text_len)
xs = torch.nn.utils.rnn.pad_sequence(xs_list, batch_first=True, padding_value=0.0)
x_lens = torch.tensor(x_len_list, dtype=torch.int64).to(xs.device)
return xs, x_lens
@staticmethod
def remove_prompt(prompt, prompt_lengths, padded, padded_lengths):
xs_list = []
for idx, (_prompt_len, _x_len) in enumerate(zip(prompt_lengths, padded_lengths)):
xs_list.append(padded[idx, _prompt_len: _x_len])
xs = torch.nn.utils.rnn.pad_sequence(xs_list, batch_first=True, padding_value=0.0)
return xs, padded_lengths - prompt_lengths
def get_rand_noise(self, mu: torch.Tensor, **kwargs):
use_fixed_noise_infer = kwargs.get("use_fixed_noise_infer", True)
max_len = kwargs.get("max_len", 50*300)
if use_fixed_noise_infer:
if not hasattr(self, "rand_noise") or self.rand_noise is None or self.rand_noise.shape[2] < mu.shape[2]:
self.rand_noise = torch.randn([1, max_len, mu.shape[2]]).to(mu)
logging.info("init random noise for Flow")
# return self.rand_noise[:, :mu.shape[1], :]
return torch.concat([self.rand_noise[:, :mu.shape[1], :] for _ in range(mu.size(0))], dim = 0)
else:
return torch.randn_like(mu)
def solve_ode(self, mu, rand_xvec, conditions, mask, **kwargs):
fm_dtype = dtype_map[kwargs.get("fm_dtype", "fp32")]
temperature = kwargs.get("temperature", 1.0)
n_timesteps = kwargs.get("n_timesteps", 10)
infer_t_scheduler = kwargs.get("infer_t_scheduler", "cosine")
z = self.get_rand_noise(mu) * temperature
# print("z", z.size(), "mu", mu.size())
t_span = torch.linspace(0, 1, n_timesteps + 1).to(mu)
# print("t_span", t_span)
if infer_t_scheduler == 'cosine':
t_span = 1 - torch.cos(t_span * 0.5 * torch.pi)
fm_time = time.time()
self.dit_model.to(fm_dtype)
feat = self.solve_euler(
z.to(fm_dtype), t_span=t_span.to(fm_dtype), mu=mu.to(fm_dtype), mask=mask,
spks=rand_xvec.to(fm_dtype), cond=conditions.to(fm_dtype), **kwargs
)
escape_time = (time.time() - fm_time) * 1000.0
logging.info(f"fm dec {n_timesteps} step time: {escape_time:.2f}, avg {escape_time/n_timesteps:.2f} ms")
return feat
def solve_euler(self, x, t_span, mu, mask, spks=None, cond=None, **kwargs):
"""
Fixed euler solver for ODEs.
Args:
x (torch.Tensor): random noise
t_span (torch.Tensor): n_timesteps interpolated
shape: (n_timesteps + 1,)
mu (torch.Tensor): output of encoder
shape: (batch_size, n_feats, mel_timesteps)
mask (torch.Tensor): output_mask
shape: (batch_size, 1, mel_timesteps)
spks (torch.Tensor, optional): speaker ids. Defaults to None.
shape: (batch_size, spk_emb_dim)
cond: Not used but kept for future purposes
"""
inference_cfg_rate = kwargs.get("inference_cfg_rate", 0.7)
t, _, dt = t_span[0], t_span[-1], t_span[1] - t_span[0]
# print("solve_euler cond", cond.size())
steps = 1
z, bz = x, x.shape[0]
while steps <= len(t_span) - 1:
if inference_cfg_rate > 0:
x_in = torch.concat([x, x], dim=0)
spks_in = torch.cat([spks, torch.zeros_like(spks)], dim=0)
mask_in = torch.concat([mask, mask], dim=0)
mu_in = torch.concat([mu, torch.zeros_like(mu)], dim=0)
t_in = torch.concat([t.unsqueeze(0) for _ in range(mu_in.size(0))], dim=0)
if isinstance(cond, torch.Tensor):
cond_in = torch.concat([cond, torch.zeros_like(cond)], dim=0)
else:
cond_in = dict(
prompt=[
torch.concat([cond["prompt"][0], torch.zeros_like(cond["prompt"][0])], dim=0),
torch.concat([cond["prompt"][1], cond["prompt"][1]], dim=0),
]
)
else:
x_in, mask_in, mu_in, spks_in, t_in, cond_in = x, mask, mu, spks, t, cond
# if spks is not None:
# cond_in = cond_in + spks
infer_causal_mask_type = kwargs.get("infer_causal_mask_type", 0)
chunk_mask_value = self.dit_model.causal_mask_type[infer_causal_mask_type]["prob_min"]
hint_once(
f"flow mask type: {infer_causal_mask_type}, mask_rank value: {chunk_mask_value}.",
"chunk_mask_value"
)
# print("dit_model cond", x_in.size(), cond_in.size(), mu_in.size(), spks_in.size(), t_in.size())
# print(t_in)
dphi_dt = self.dit_model(
x_in, cond_in, mu_in, spks_in, t_in,
mask=mask_in,
mask_rand=torch.ones_like(t_in).reshape(-1, 1, 1) * chunk_mask_value
)
if inference_cfg_rate > 0:
dphi_dt, cfg_dphi_dt = torch.split(dphi_dt, [bz, bz], dim=0)
dphi_dt = ((1.0 + inference_cfg_rate) * dphi_dt -
inference_cfg_rate * cfg_dphi_dt)
x = x + dt * dphi_dt
t = t + dt
# sol.append(x)
if steps < len(t_span) - 1:
dt = t_span[steps + 1] - t
steps += 1
return x