import math import torch from torch import nn from torch.nn import functional as F import torch.distributions as dist import numpy as np import copy from modules.audio2motion.flow_base import Glow, WN, ResidualCouplingBlock from modules.audio2motion.transformer_base import Embedding from utils.commons.pitch_utils import f0_to_coarse from utils.commons.hparams import hparams class LambdaLayer(nn.Module): def __init__(self, lambd): super(LambdaLayer, self).__init__() self.lambd = lambd def forward(self, x): return self.lambd(x) def make_positions(tensor, padding_idx): """Replace non-padding symbols with their position numbers. Position numbers begin at padding_idx+1. Padding symbols are ignored. """ # The series of casts and type-conversions here are carefully # balanced to both work with ONNX export and XLA. In particular XLA # prefers ints, cumsum defaults to output longs, and ONNX doesn't know # how to handle the dtype kwarg in cumsum. mask = tensor.ne(padding_idx).int() return ( torch.cumsum(mask, dim=1).type_as(mask) * mask ).long() + padding_idx class SinusoidalPositionalEmbedding(nn.Module): """This module produces sinusoidal positional embeddings of any length. Padding symbols are ignored. """ def __init__(self, embedding_dim, padding_idx, init_size=1024): super().__init__() self.embedding_dim = embedding_dim self.padding_idx = padding_idx self.weights = SinusoidalPositionalEmbedding.get_embedding( init_size, embedding_dim, padding_idx, ) self.register_buffer('_float_tensor', torch.FloatTensor(1)) @staticmethod def get_embedding(num_embeddings, embedding_dim, padding_idx=None): """Build sinusoidal embeddings. This matches the implementation in tensor2tensor, but differs slightly from the description in Section 3.5 of "Attention Is All You Need". """ half_dim = embedding_dim // 2 emb = math.log(10000) / (half_dim - 1) emb = torch.exp(torch.arange(half_dim, dtype=torch.float) * -emb) emb = torch.arange(num_embeddings, dtype=torch.float).unsqueeze(1) * emb.unsqueeze(0) emb = torch.cat([torch.sin(emb), torch.cos(emb)], dim=1).view(num_embeddings, -1) if embedding_dim % 2 == 1: # zero pad emb = torch.cat([emb, torch.zeros(num_embeddings, 1)], dim=1) if padding_idx is not None: emb[padding_idx, :] = 0 return emb def forward(self, input, incremental_state=None, timestep=None, positions=None, **kwargs): """Input is expected to be of size [bsz x seqlen].""" bsz, seq_len = input.shape[:2] max_pos = self.padding_idx + 1 + seq_len if self.weights is None or max_pos > self.weights.size(0): # recompute/expand embeddings if needed self.weights = SinusoidalPositionalEmbedding.get_embedding( max_pos, self.embedding_dim, self.padding_idx, ) self.weights = self.weights.to(self._float_tensor) if incremental_state is not None: # positions is the same for every token when decoding a single step pos = timestep.view(-1)[0] + 1 if timestep is not None else seq_len return self.weights[self.padding_idx + pos, :].expand(bsz, 1, -1) positions = make_positions(input, self.padding_idx) if positions is None else positions return self.weights.index_select(0, positions.view(-1)).view(bsz, seq_len, -1).detach() def max_positions(self): """Maximum number of supported positions.""" return int(1e4) # an arbitrary large number class FVAEEncoder(nn.Module): def __init__(self, in_channels, hidden_channels, latent_channels, kernel_size, n_layers, gin_channels=0, p_dropout=0, strides=[4]): super().__init__() self.strides = strides self.hidden_size = hidden_channels self.pre_net = nn.Sequential(*[ nn.Conv1d(in_channels, hidden_channels, kernel_size=s * 2, stride=s, padding=s // 2) if i == 0 else nn.Conv1d(hidden_channels, hidden_channels, kernel_size=s * 2, stride=s, padding=s // 2) for i, s in enumerate(strides) ]) self.wn = WN(hidden_channels, kernel_size, 1, n_layers, gin_channels, p_dropout) self.out_proj = nn.Conv1d(hidden_channels, latent_channels * 2, 1) self.latent_channels = latent_channels def forward(self, x, x_mask, g): x = self.pre_net(x) x_mask = x_mask[:, :, ::np.prod(self.strides)][:, :, :x.shape[-1]] x = x * x_mask x = self.wn(x, x_mask, g) * x_mask x = self.out_proj(x) m, logs = torch.split(x, self.latent_channels, dim=1) z = (m + torch.randn_like(m) * torch.exp(logs)) return z, m, logs, x_mask class FVAEDecoder(nn.Module): def __init__(self, latent_channels, hidden_channels, out_channels, kernel_size, n_layers, gin_channels=0, p_dropout=0, strides=[4]): super().__init__() self.strides = strides self.hidden_size = hidden_channels self.pre_net = nn.Sequential(*[ nn.ConvTranspose1d(latent_channels, hidden_channels, kernel_size=s, stride=s) if i == 0 else nn.ConvTranspose1d(hidden_channels, hidden_channels, kernel_size=s, stride=s) for i, s in enumerate(strides) ]) self.wn = WN(hidden_channels, kernel_size, 1, n_layers, gin_channels, p_dropout) self.out_proj = nn.Conv1d(hidden_channels, out_channels, 1) def forward(self, x, x_mask, g): x = self.pre_net(x) x = x * x_mask x = self.wn(x, x_mask, g) * x_mask x = self.out_proj(x) return x class FVAE(nn.Module): def __init__(self, in_out_channels=64, hidden_channels=256, latent_size=16, kernel_size=3, enc_n_layers=5, dec_n_layers=5, gin_channels=80, strides=[4,], use_prior_glow=True, glow_hidden=256, glow_kernel_size=3, glow_n_blocks=5, sqz_prior=False, use_pos_emb=False): super(FVAE, self).__init__() self.in_out_channels = in_out_channels self.strides = strides self.hidden_size = hidden_channels self.latent_size = latent_size self.use_prior_glow = use_prior_glow self.sqz_prior = sqz_prior self.g_pre_net = nn.Sequential(*[ nn.Conv1d(gin_channels, gin_channels, kernel_size=s * 2, stride=s, padding=s // 2) for i, s in enumerate(strides) ]) self.encoder = FVAEEncoder(in_out_channels, hidden_channels, latent_size, kernel_size, enc_n_layers, gin_channels, strides=strides) if use_prior_glow: self.prior_flow = ResidualCouplingBlock( latent_size, glow_hidden, glow_kernel_size, 1, glow_n_blocks, 4, gin_channels=gin_channels) self.use_pos_embed = use_pos_emb if sqz_prior: self.query_proj = nn.Linear(latent_size, latent_size) self.key_proj = nn.Linear(latent_size, latent_size) self.value_proj = nn.Linear(latent_size, hidden_channels) if self.in_out_channels in [7, 64]: self.decoder = FVAEDecoder(hidden_channels, hidden_channels, in_out_channels, kernel_size, dec_n_layers, gin_channels, strides=strides) elif self.in_out_channels == 71: self.exp_decoder = FVAEDecoder(hidden_channels, hidden_channels, 64, kernel_size, dec_n_layers, gin_channels, strides=strides) self.pose_decoder = FVAEDecoder(hidden_channels, hidden_channels, 7, kernel_size, dec_n_layers, gin_channels, strides=strides) if self.use_pos_embed: self.embed_positions = SinusoidalPositionalEmbedding(self.latent_size, 0,init_size=2000+1,) else: self.decoder = FVAEDecoder(latent_size, hidden_channels, in_out_channels, kernel_size, dec_n_layers, gin_channels, strides=strides) self.prior_dist = dist.Normal(0, 1) def forward(self, x=None, x_mask=None, g=None, infer=False, temperature=1. , **kwargs): """ :param x: [B, T, C_in_out] :param x_mask: [B, T] :param g: [B, T, C_g] :return: """ x_mask = x_mask[:, None, :] # [B, 1, T] g = g.transpose(1,2) # [B, C_g, T] g_for_sqz = g g_sqz = self.g_pre_net(g_for_sqz) if not infer: x = x.transpose(1,2) # [B, C, T] z_q, m_q, logs_q, x_mask_sqz = self.encoder(x, x_mask, g_sqz) if self.sqz_prior: z = z_q if self.use_pos_embed: position = self.embed_positions(z.transpose(1,2).abs().sum(-1)).transpose(1,2) z = z + position q = self.query_proj(z.mean(dim=-1,keepdim=True).transpose(1,2)) # [B, 1, C=16] k = self.key_proj(z.transpose(1,2)) # [B, T, C=16] v = self.value_proj(z.transpose(1,2)) # [B, T, C=256] attn = torch.bmm(q,k.transpose(1,2)) # [B, 1, T] attn = F.softmax(attn, dim=-1) out = torch.bmm(attn, v) # [B, 1, C=256] style_encoding = out.repeat([1,z_q.shape[-1],1]).transpose(1,2) # [B, C=256, T] if self.in_out_channels == 71: x_recon = torch.cat([self.exp_decoder(style_encoding, x_mask, g), self.pose_decoder(style_encoding, x_mask, g)], dim=1) else: x_recon = self.decoder(style_encoding, x_mask, g) else: if self.in_out_channels == 71: x_recon = torch.cat([self.exp_decoder(z_q, x_mask, g), self.pose_decoder(z_q, x_mask, g)], dim=1) else: x_recon = self.decoder(z_q, x_mask, g) q_dist = dist.Normal(m_q, logs_q.exp()) if self.use_prior_glow: logqx = q_dist.log_prob(z_q) z_p = self.prior_flow(z_q, x_mask_sqz, g_sqz) logpx = self.prior_dist.log_prob(z_p) loss_kl = ((logqx - logpx) * x_mask_sqz).sum() / x_mask_sqz.sum() / logqx.shape[1] else: loss_kl = torch.distributions.kl_divergence(q_dist, self.prior_dist) loss_kl = (loss_kl * x_mask_sqz).sum() / x_mask_sqz.sum() / z_q.shape[1] z_p = z_q return x_recon.transpose(1,2), loss_kl, z_p.transpose(1,2), m_q.transpose(1,2), logs_q.transpose(1,2) else: latent_shape = [g_sqz.shape[0], self.latent_size, g_sqz.shape[2]] z_p = self.prior_dist.sample(latent_shape).to(g.device) * temperature # [B, latent_size, T_sqz] if self.use_prior_glow: z_p = self.prior_flow(z_p, 1, g_sqz, reverse=True) if self.sqz_prior: z = z_p if self.use_pos_embed: position = self.embed_positions(z.abs().sum(-1)) z += position q = self.query_proj(z.mean(dim=-1,keepdim=True).transpose(1,2)) # [B, 1, C=16] k = self.key_proj(z.transpose(1,2)) # [B, T, C=16] v = self.value_proj(z.transpose(1,2)) # [B, T, C=256] attn = torch.bmm(q,k.transpose(1,2)) # [B, 1, T] attn = F.softmax(attn, dim=-1) out = torch.bmm(attn, v) # [B, 1, C=256] style_encoding = out.repeat([1,z_p.shape[-1],1]).transpose(1,2) # [B, C=256, T] x_recon = self.decoder(style_encoding, 1, g) if self.in_out_channels == 71: x_recon = torch.cat([self.exp_decoder(style_encoding, 1, g), self.pose_decoder(style_encoding, 1, g)], dim=1) else: x_recon = self.decoder(style_encoding, 1, g) else: if self.in_out_channels == 71: x_recon = torch.cat([self.exp_decoder(z_p, 1, g), self.pose_decoder(z_p, 1, g)], dim=1) else: x_recon = self.decoder(z_p, 1, g) return x_recon.transpose(1,2), z_p.transpose(1,2) class VAEModel(nn.Module): def __init__(self, in_out_dim=64, audio_in_dim=1024, sqz_prior=False, cond_drop=False, use_prior_flow=True): super().__init__() feat_dim = 64 self.blink_embed = nn.Embedding(2, feat_dim) self.audio_in_dim = audio_in_dim cond_dim = feat_dim self.mel_encoder = nn.Sequential(*[ nn.Conv1d(audio_in_dim, 64, 3, 1, 1, bias=False), nn.BatchNorm1d(64), nn.GELU(), nn.Conv1d(64, feat_dim, 3, 1, 1, bias=False) ]) self.cond_drop = cond_drop if self.cond_drop: self.dropout = nn.Dropout(0.5) self.in_dim, self.out_dim = in_out_dim, in_out_dim self.sqz_prior = sqz_prior self.use_prior_flow = use_prior_flow self.vae = FVAE(in_out_channels=in_out_dim, hidden_channels=256, latent_size=16, kernel_size=5, enc_n_layers=8, dec_n_layers=4, gin_channels=cond_dim, strides=[4,], use_prior_glow=self.use_prior_flow, glow_hidden=64, glow_kernel_size=3, glow_n_blocks=4,sqz_prior=sqz_prior) self.downsampler = LambdaLayer(lambda x: F.interpolate(x.transpose(1,2), scale_factor=0.5, mode='linear').transpose(1,2)) # self.downsampler = LambdaLayer(lambda x: F.interpolate(x.transpose(1,2), scale_factor=0.5, mode='nearest').transpose(1,2)) def num_params(self, model, print_out=True, model_name="model"): parameters = filter(lambda p: p.requires_grad, model.parameters()) parameters = sum([np.prod(p.size()) for p in parameters]) / 1_000_000 if print_out: print(f'| {model_name} Trainable Parameters: %.3fM' % parameters) return parameters @property def device(self): return self.vae.parameters().__next__().device def forward(self, batch, ret, train=True, return_latent=False, temperature=1.): infer = not train mask = batch['y_mask'].to(self.device) mel = batch['audio'].to(self.device) mel = self.downsampler(mel) cond_feat = self.mel_encoder(mel.transpose(1,2)).transpose(1,2) if self.cond_drop: cond_feat = self.dropout(cond_feat) if not infer: exp = batch['y'].to(self.device) x = exp x_recon, loss_kl, z_p, m_q, logs_q = self.vae(x=x, x_mask=mask, g=cond_feat, infer=False) x_recon = x_recon * mask.unsqueeze(-1) ret['pred'] = x_recon ret['mask'] = mask ret['loss_kl'] = loss_kl if return_latent: ret['m_q'] = m_q ret['z_p'] = z_p return x_recon, loss_kl, m_q, logs_q else: x_recon, z_p = self.vae(x=None, x_mask=mask, g=cond_feat, infer=True, temperature=temperature) x_recon = x_recon * mask.unsqueeze(-1) ret['pred'] = x_recon ret['mask'] = mask return x_recon class PitchContourVAEModel(nn.Module): def __init__(self, hparams, in_out_dim=64, audio_in_dim=1024, sqz_prior=False, cond_drop=False, use_prior_flow=True): super().__init__() self.hparams = copy.deepcopy(hparams) feat_dim = 128 self.audio_in_dim = audio_in_dim self.blink_embed = nn.Embedding(2, feat_dim) self.mel_encoder = nn.Sequential(*[ nn.Conv1d(audio_in_dim, feat_dim, 3, 1, 1, bias=False), nn.BatchNorm1d(feat_dim ), nn.GELU(), nn.Conv1d(feat_dim , feat_dim, 3, 1, 1, bias=False) ]) self.pitch_embed = Embedding(300, feat_dim, None) self.pitch_encoder = nn.Sequential(*[ nn.Conv1d(feat_dim, feat_dim , 3, 1, 1, bias=False), nn.BatchNorm1d(feat_dim), nn.GELU(), nn.Conv1d(feat_dim, feat_dim, 3, 1, 1, bias=False) ]) cond_dim = feat_dim + feat_dim + feat_dim if hparams.get('use_mouth_amp_embed', False): self.mouth_amp_embed = nn.Parameter(torch.randn(feat_dim)) cond_dim += feat_dim if hparams.get('use_eye_amp_embed', False): self.eye_amp_embed = nn.Parameter(torch.randn(feat_dim)) cond_dim += feat_dim self.cond_proj = nn.Linear(cond_dim, feat_dim, bias=True) self.cond_drop = cond_drop if self.cond_drop: self.dropout = nn.Dropout(0.5) self.in_dim, self.out_dim = in_out_dim, in_out_dim self.sqz_prior = sqz_prior self.use_prior_flow = use_prior_flow self.vae = FVAE(in_out_channels=in_out_dim, hidden_channels=256, latent_size=16, kernel_size=5, enc_n_layers=8, dec_n_layers=4, gin_channels=feat_dim, strides=[4,], use_prior_glow=self.use_prior_flow, glow_hidden=64, glow_kernel_size=3, glow_n_blocks=4,sqz_prior=sqz_prior) self.downsampler = LambdaLayer(lambda x: F.interpolate(x.transpose(1,2), scale_factor=0.5, mode='nearest').transpose(1,2)) def num_params(self, model, print_out=True, model_name="model"): parameters = filter(lambda p: p.requires_grad, model.parameters()) parameters = sum([np.prod(p.size()) for p in parameters]) / 1_000_000 if print_out: print(f'| {model_name} Trainable Parameters: %.3fM' % parameters) return parameters @property def device(self): return self.vae.parameters().__next__().device def forward(self, batch, ret, train=True, return_latent=False, temperature=1.): infer = not train hparams = self.hparams mask = batch['y_mask'].to(self.device) mel = batch['audio'].to(self.device) f0 = batch['f0'].to(self.device) # [b,t] if 'blink' not in batch: batch['blink'] = torch.zeros([f0.shape[0], f0.shape[1], 1], dtype=torch.long, device=f0.device) blink = batch['blink'].to(self.device) blink_feat = self.blink_embed(blink.squeeze(2)) blink_feat = self.downsampler(blink_feat) mel = self.downsampler(mel) f0 = self.downsampler(f0.unsqueeze(-1)).squeeze(-1) f0_coarse = f0_to_coarse(f0) pitch_emb = self.pitch_embed(f0_coarse) cond_feat = self.mel_encoder(mel.transpose(1,2)).transpose(1,2) pitch_feat = self.pitch_encoder(pitch_emb.transpose(1,2)).transpose(1,2) cond_feats = [cond_feat, pitch_feat, blink_feat] if hparams.get('use_mouth_amp_embed', False): mouth_amp = batch.get('mouth_amp', torch.ones([f0.shape[0], 1], device=f0.device) * 0.4) mouth_amp_feat = mouth_amp.unsqueeze(1) * self.mouth_amp_embed.unsqueeze(0) mouth_amp_feat = mouth_amp_feat.repeat([1,cond_feat.shape[1],1]) cond_feats.append(mouth_amp_feat) if hparams.get('use_eye_amp_embed', False): eye_amp = batch.get('eye_amp', torch.ones([f0.shape[0], 1], device=f0.device) * 0.4) eye_amp_feat = eye_amp.unsqueeze(1) * self.eye_amp_embed.unsqueeze(0) eye_amp_feat = eye_amp_feat.repeat([1,cond_feat.shape[1],1]) cond_feats.append(eye_amp_feat) cond_feat = torch.cat(cond_feats, dim=-1) cond_feat = self.cond_proj(cond_feat) if self.cond_drop: cond_feat = self.dropout(cond_feat) if not infer: exp = batch['y'].to(self.device) x = exp x_recon, loss_kl, z_p, m_q, logs_q = self.vae(x=x, x_mask=mask, g=cond_feat, infer=False) x_recon = x_recon * mask.unsqueeze(-1) ret['pred'] = x_recon ret['mask'] = mask ret['loss_kl'] = loss_kl if return_latent: ret['m_q'] = m_q ret['z_p'] = z_p return x_recon, loss_kl, m_q, logs_q else: x_recon, z_p = self.vae(x=None, x_mask=mask, g=cond_feat, infer=True, temperature=temperature) x_recon = x_recon * mask.unsqueeze(-1) ret['pred'] = x_recon ret['mask'] = mask return x_recon if __name__ == '__main__': model = FVAE(in_out_channels=64, hidden_channels=128, latent_size=32,kernel_size=3, enc_n_layers=6, dec_n_layers=2, gin_channels=80, strides=[4], use_prior_glow=False, glow_hidden=128, glow_kernel_size=3, glow_n_blocks=3) x = torch.rand([8, 64, 1000]) x_mask = torch.ones([8,1,1000]) g = torch.rand([8, 80, 1000]) train_out = model(x,x_mask,g,infer=False) x_recon, loss_kl, z_p, m_q, logs_q = train_out print(" ") infer_out = model(x,x_mask,g,infer=True) x_recon, z_p = infer_out print(" ")