import os from pytorch_memlab import LineProfiler,profile import torch import torch.nn as nn import numpy as np import pytorch_lightning as pl from torch.optim.lr_scheduler import LambdaLR from einops import rearrange, repeat from contextlib import contextmanager from functools import partial from tqdm import tqdm from torchvision.utils import make_grid from pytorch_lightning.utilities.distributed import rank_zero_only from ldm.util import log_txt_as_img, exists, default, ismap, isimage, mean_flat, count_params, instantiate_from_config from ldm.modules.ema import LitEma from ldm.modules.distributions.distributions import normal_kl, DiagonalGaussianDistribution from ldm.models.autoencoder import VQModelInterface, IdentityFirstStage, AutoencoderKL from ldm.modules.diffusionmodules.util import make_beta_schedule, extract_into_tensor, noise_like from ldm.models.diffusion.ddim import DDIMSampler from ldm.models.diffusion.ddpm import DDPM, disabled_train, DiffusionWrapper from omegaconf import ListConfig from ldm.models.diffusion.scheduling_lcm import LCMSampler from ldm.models.diffusion.ddim_solver import DDIMSolver __conditioning_keys__ = {'concat': 'c_concat', 'crossattn': 'c_crossattn', 'adm': 'y'} def append_dims(x, target_dims): """Appends dimensions to the end of a tensor until it has target_dims dimensions.""" dims_to_append = target_dims - x.ndim if dims_to_append < 0: raise ValueError(f"input has {x.ndim} dims but target_dims is {target_dims}, which is less") return x[(...,) + (None,) * dims_to_append] # From LCMScheduler.get_scalings_for_boundary_condition_discrete def scalings_for_boundary_conditions(timestep, sigma_data=0.5, timestep_scaling=10.0): c_skip = sigma_data**2 / ((timestep / 0.1) ** 2 + sigma_data**2) c_out = (timestep / 0.1) / ((timestep / 0.1) ** 2 + sigma_data**2) ** 0.5 return c_skip, c_out class LCM_audio(DDPM): """main class""" def __init__(self, first_stage_config, cond_stage_config, num_timesteps_cond=None, mel_dim=80, mel_length=848, cond_stage_key="image", cond_stage_trainable=False, concat_mode=True, cond_stage_forward=None, conditioning_key=None, scale_factor=1.0, scale_by_std=False, use_lcm=True, num_ddim_timesteps=50, w_min=None, w_max=None, *args, **kwargs): self.num_timesteps_cond = default(num_timesteps_cond, 1) self.scale_by_std = scale_by_std assert self.num_timesteps_cond <= kwargs['timesteps'] # for backwards compatibility after implementation of DiffusionWrapper if conditioning_key is None: conditioning_key = 'concat' if concat_mode else 'crossattn' if cond_stage_config == '__is_unconditional__': conditioning_key = None ckpt_path = kwargs.pop("ckpt_path", None) ignore_keys = kwargs.pop("ignore_keys", []) super().__init__(conditioning_key=conditioning_key, *args, **kwargs) self.concat_mode = concat_mode self.mel_dim = mel_dim self.mel_length = mel_length self.use_lcm = use_lcm self.cond_stage_trainable = cond_stage_trainable self.cond_stage_key = cond_stage_key try: self.num_downs = len(first_stage_config.params.ddconfig.ch_mult) - 1 except: self.num_downs = 0 if not scale_by_std: self.scale_factor = scale_factor else: self.register_buffer('scale_factor', torch.tensor(scale_factor)) self.instantiate_first_stage(first_stage_config) self.instantiate_cond_stage(cond_stage_config) self.cond_stage_forward = cond_stage_forward self.clip_denoised = False self.bbox_tokenizer = None self.restarted_from_ckpt = False if ckpt_path is not None: self.init_from_ckpt(ckpt_path, ignore_keys) self.restarted_from_ckpt = True if self.use_lcm: ### DDIM Solver self.solver = DDIMSolver(self.alphas_cumprod.numpy(),self.num_timesteps, num_ddim_timesteps) step_ratio = self.num_timesteps // num_ddim_timesteps self.step_ratio = step_ratio self.num_ddim_timesteps = num_ddim_timesteps self.ddim_timesteps = (np.arange(1, num_ddim_timesteps + 1) * step_ratio).round().astype(np.int64) - 1 # convert to torch tensors self.ddim_timesteps = torch.from_numpy(self.ddim_timesteps).long() self.model.requires_grad_(False) self.unet = DiffusionWrapper(self.unet_config, conditioning_key) self.unet.load_state_dict(self.model.state_dict(), strict=False) self.unet.train() self.target_unet = DiffusionWrapper(self.unet_config, conditioning_key) self.target_unet.load_state_dict(self.unet.state_dict()) self.target_unet.requires_grad_(False) self.target_unet.train() self.w_min = w_min self.w_max = w_max def make_cond_schedule(self, ): self.cond_ids = torch.full(size=(self.num_timesteps,), fill_value=self.num_timesteps - 1, dtype=torch.long) ids = torch.round(torch.linspace(0, self.num_timesteps - 1, self.num_timesteps_cond)).long() self.cond_ids[:self.num_timesteps_cond] = ids @rank_zero_only @torch.no_grad() def on_train_batch_start(self, batch, batch_idx): # only for very first batch if self.scale_by_std and self.current_epoch == 0 and self.global_step == 0 and batch_idx == 0 and not self.restarted_from_ckpt: assert self.scale_factor == 1., 'rather not use custom rescaling and std-rescaling simultaneously' # set rescale weight to 1./std of encodings print("### USING STD-RESCALING ###") x = super().get_input(batch, self.first_stage_key) x = x.to(self.device) encoder_posterior = self.encode_first_stage(x) z = self.get_first_stage_encoding(encoder_posterior).detach()# get latent del self.scale_factor self.register_buffer('scale_factor', 1. / z.flatten().std())# 1/latent.std, get_first_stage_encoding returns self.scale_factor * latent print(f"setting self.scale_factor to {self.scale_factor}") print("### USING STD-RESCALING ###") # def on_train_epoch_start(self): # print("!!!!!!!!!!!!!!!!!!!!!!!!!!on_train_epoch_strat",self.trainer.train_dataloader.batch_sampler,hasattr(self.trainer.train_dataloader.batch_sampler,'set_epoch')) # if hasattr(self.trainer.train_dataloader.batch_sampler,'set_epoch'): # self.trainer.train_dataloader.batch_sampler.set_epoch(self.current_epoch) # return super().on_train_epoch_start() def register_schedule(self, given_betas=None, beta_schedule="linear", timesteps=1000, linear_start=1e-4, linear_end=2e-2, cosine_s=8e-3): super().register_schedule(given_betas, beta_schedule, timesteps, linear_start, linear_end, cosine_s) self.shorten_cond_schedule = self.num_timesteps_cond > 1 if self.shorten_cond_schedule: self.make_cond_schedule() def instantiate_first_stage(self, config): model = instantiate_from_config(config) self.first_stage_model = model.eval() self.first_stage_model.train = disabled_train for param in self.first_stage_model.parameters(): param.requires_grad = False def instantiate_cond_stage(self, config): if not self.cond_stage_trainable: if config == "__is_first_stage__": print("Using first stage also as cond stage.") self.cond_stage_model = self.first_stage_model elif config == "__is_unconditional__": print(f"Training {self.__class__.__name__} as an unconditional model.") self.cond_stage_model = None else: model = instantiate_from_config(config) self.cond_stage_model = model.eval() self.cond_stage_model.train = disabled_train for param in self.cond_stage_model.parameters(): param.requires_grad = False else: assert config != '__is_first_stage__' assert config != '__is_unconditional__' model = instantiate_from_config(config) self.cond_stage_model = model def _get_denoise_row_from_list(self, samples, desc='', force_no_decoder_quantization=False): denoise_row = [] for zd in tqdm(samples, desc=desc): denoise_row.append(self.decode_first_stage(zd.to(self.device), force_not_quantize=force_no_decoder_quantization)) n_imgs_per_row = len(denoise_row) if len(denoise_row[0].shape) == 3: denoise_row = [x.unsqueeze(1) for x in denoise_row] denoise_row = torch.stack(denoise_row) # n_log_step, n_row, C, H, W denoise_grid = rearrange(denoise_row, 'n b c h w -> b n c h w') denoise_grid = rearrange(denoise_grid, 'b n c h w -> (b n) c h w') denoise_grid = make_grid(denoise_grid, nrow=n_imgs_per_row) return denoise_grid def get_first_stage_encoding(self, encoder_posterior): if isinstance(encoder_posterior, DiagonalGaussianDistribution): z = encoder_posterior.sample() elif isinstance(encoder_posterior, torch.Tensor): z = encoder_posterior else: raise NotImplementedError(f"encoder_posterior of type '{type(encoder_posterior)}' not yet implemented") return self.scale_factor * z #@profile def get_learned_conditioning(self, c): if self.cond_stage_forward is None: if hasattr(self.cond_stage_model, 'encode') and callable(self.cond_stage_model.encode): c = self.cond_stage_model.encode(c) if isinstance(c, DiagonalGaussianDistribution): c = c.mode() else: c = self.cond_stage_model(c) else: assert hasattr(self.cond_stage_model, self.cond_stage_forward) c = getattr(self.cond_stage_model, self.cond_stage_forward)(c) return c @torch.no_grad() def get_unconditional_conditioning(self, batch_size, null_label=None): if null_label is not None: xc = null_label if isinstance(xc, ListConfig): xc = list(xc) if isinstance(xc, dict) or isinstance(xc, list): c = self.get_learned_conditioning(xc) else: if hasattr(xc, "to"): xc = xc.to(self.device) c = self.get_learned_conditioning(xc) else: if self.cond_stage_key in ["class_label", "cls"]: xc = self.cond_stage_model.get_unconditional_conditioning(batch_size, device=self.device) return self.get_learned_conditioning(xc) else: raise NotImplementedError("todo") if isinstance(c, list): # in case the encoder gives us a list for i in range(len(c)): c[i] = repeat(c[i], '1 ... -> b ...', b=batch_size).to(self.device) else: c = repeat(c, '1 ... -> b ...', b=batch_size).to(self.device) return c def meshgrid(self, h, w): y = torch.arange(0, h).view(h, 1, 1).repeat(1, w, 1) x = torch.arange(0, w).view(1, w, 1).repeat(h, 1, 1) arr = torch.cat([y, x], dim=-1) return arr def delta_border(self, h, w): """ :param h: height :param w: width :return: normalized distance to image border, wtith min distance = 0 at border and max dist = 0.5 at image center """ lower_right_corner = torch.tensor([h - 1, w - 1]).view(1, 1, 2) arr = self.meshgrid(h, w) / lower_right_corner dist_left_up = torch.min(arr, dim=-1, keepdims=True)[0] dist_right_down = torch.min(1 - arr, dim=-1, keepdims=True)[0] edge_dist = torch.min(torch.cat([dist_left_up, dist_right_down], dim=-1), dim=-1)[0] return edge_dist def get_weighting(self, h, w, Ly, Lx, device): weighting = self.delta_border(h, w) weighting = torch.clip(weighting, self.split_input_params["clip_min_weight"], self.split_input_params["clip_max_weight"], ) weighting = weighting.view(1, h * w, 1).repeat(1, 1, Ly * Lx).to(device) if self.split_input_params["tie_braker"]: L_weighting = self.delta_border(Ly, Lx) L_weighting = torch.clip(L_weighting, self.split_input_params["clip_min_tie_weight"], self.split_input_params["clip_max_tie_weight"]) L_weighting = L_weighting.view(1, 1, Ly * Lx).to(device) weighting = weighting * L_weighting return weighting def get_fold_unfold(self, x, kernel_size, stride, uf=1, df=1): # todo load once not every time, shorten code """ :param x: img of size (bs, c, h, w) :return: n img crops of size (n, bs, c, kernel_size[0], kernel_size[1]) """ bs, nc, h, w = x.shape # number of crops in image Ly = (h - kernel_size[0]) // stride[0] + 1 Lx = (w - kernel_size[1]) // stride[1] + 1 if uf == 1 and df == 1: fold_params = dict(kernel_size=kernel_size, dilation=1, padding=0, stride=stride) unfold = torch.nn.Unfold(**fold_params) fold = torch.nn.Fold(output_size=x.shape[2:], **fold_params) weighting = self.get_weighting(kernel_size[0], kernel_size[1], Ly, Lx, x.device).to(x.dtype) normalization = fold(weighting).view(1, 1, h, w) # normalizes the overlap weighting = weighting.view((1, 1, kernel_size[0], kernel_size[1], Ly * Lx)) elif uf > 1 and df == 1: fold_params = dict(kernel_size=kernel_size, dilation=1, padding=0, stride=stride) unfold = torch.nn.Unfold(**fold_params) fold_params2 = dict(kernel_size=(kernel_size[0] * uf, kernel_size[0] * uf), dilation=1, padding=0, stride=(stride[0] * uf, stride[1] * uf)) fold = torch.nn.Fold(output_size=(x.shape[2] * uf, x.shape[3] * uf), **fold_params2) weighting = self.get_weighting(kernel_size[0] * uf, kernel_size[1] * uf, Ly, Lx, x.device).to(x.dtype) normalization = fold(weighting).view(1, 1, h * uf, w * uf) # normalizes the overlap weighting = weighting.view((1, 1, kernel_size[0] * uf, kernel_size[1] * uf, Ly * Lx)) elif df > 1 and uf == 1: fold_params = dict(kernel_size=kernel_size, dilation=1, padding=0, stride=stride) unfold = torch.nn.Unfold(**fold_params) fold_params2 = dict(kernel_size=(kernel_size[0] // df, kernel_size[0] // df), dilation=1, padding=0, stride=(stride[0] // df, stride[1] // df)) fold = torch.nn.Fold(output_size=(x.shape[2] // df, x.shape[3] // df), **fold_params2) weighting = self.get_weighting(kernel_size[0] // df, kernel_size[1] // df, Ly, Lx, x.device).to(x.dtype) normalization = fold(weighting).view(1, 1, h // df, w // df) # normalizes the overlap weighting = weighting.view((1, 1, kernel_size[0] // df, kernel_size[1] // df, Ly * Lx)) else: raise NotImplementedError return fold, unfold, normalization, weighting @torch.no_grad() def get_input(self, batch, k, return_first_stage_outputs=False, force_c_encode=False, cond_key=None, return_original_cond=False, bs=None): x = super().get_input(batch, k) if bs is not None: x = x[:bs] x = x.to(self.device) encoder_posterior = self.encode_first_stage(x) z = self.get_first_stage_encoding(encoder_posterior).detach() if self.model.conditioning_key is not None: if cond_key is None: cond_key = self.cond_stage_key if cond_key != self.first_stage_key: if cond_key in ['caption', 'coordinates_bbox']: xc = batch[cond_key] elif cond_key == 'class_label': xc = batch else: xc = super().get_input(batch, cond_key).to(self.device) else: xc = x if not self.cond_stage_trainable or force_c_encode: if isinstance(xc, dict) or isinstance(xc, list): # import pudb; pudb.set_trace() c = self.get_learned_conditioning(xc) else: c = self.get_learned_conditioning(xc.to(self.device)) else: c = xc if bs is not None: c = c[:bs] # Testing # if cond_key == 'masked_image': mask = super().get_input(batch, "mask") cc = torch.nn.functional.interpolate(mask, size=c.shape[-2:]) # [B, 1, 10, 106] c = torch.cat((c, cc), dim=1) # [B, 5, 10, 106] # Testing # if self.use_positional_encodings: pos_x, pos_y = self.compute_latent_shifts(batch) ckey = __conditioning_keys__[self.model.conditioning_key] c = {ckey: c, 'pos_x': pos_x, 'pos_y': pos_y} else: c = None xc = None if self.use_positional_encodings: pos_x, pos_y = self.compute_latent_shifts(batch) c = {'pos_x': pos_x, 'pos_y': pos_y} out = [z, c] if return_first_stage_outputs: xrec = self.decode_first_stage(z) out.extend([x, xrec]) if return_original_cond: out.append(xc) return out @torch.no_grad() def decode_first_stage(self, z, predict_cids=False, force_not_quantize=False): if predict_cids: if z.dim() == 4: z = torch.argmax(z.exp(), dim=1).long() z = self.first_stage_model.quantize.get_codebook_entry(z, shape=None) z = rearrange(z, 'b h w c -> b c h w').contiguous() z = 1. / self.scale_factor * z if isinstance(self.first_stage_model, VQModelInterface): return self.first_stage_model.decode(z, force_not_quantize=predict_cids or force_not_quantize) else: return self.first_stage_model.decode(z) # same as above but without decorator def differentiable_decode_first_stage(self, z, predict_cids=False, force_not_quantize=False): if predict_cids: if z.dim() == 4: z = torch.argmax(z.exp(), dim=1).long() z = self.first_stage_model.quantize.get_codebook_entry(z, shape=None) z = rearrange(z, 'b h w c -> b c h w').contiguous() z = 1. / self.scale_factor * z if isinstance(self.first_stage_model, VQModelInterface): return self.first_stage_model.decode(z, force_not_quantize=predict_cids or force_not_quantize) else: return self.first_stage_model.decode(z) @torch.no_grad() def encode_first_stage(self, x): return self.first_stage_model.encode(x) def shared_step(self, batch, **kwargs): x, c = self.get_input(batch, self.first_stage_key) loss = self(x, c) return loss def test_step(self,batch,batch_idx): cond = batch[self.cond_stage_key] # * self.test_repeat cond = self.get_learned_conditioning(cond) # c: string -> [B, T, Context_dim] batch_size = len(cond) enc_emb = self.sample(cond,batch_size,timesteps=self.num_timesteps)# shape = [batch_size,self.channels,self.mel_dim,self.mel_length] xrec = self.decode_first_stage(enc_emb) # reconstructions = (xrec + 1)/2 # to mel scale # test_ckpt_path = os.path.basename(self.trainer.tested_ckpt_path) # savedir = os.path.join(self.trainer.log_dir,f'output_imgs_{test_ckpt_path}','fake_class') # if not os.path.exists(savedir): # os.makedirs(savedir) # file_names = batch['f_name'] # nfiles = len(file_names) # reconstructions = reconstructions.cpu().numpy().squeeze(1) # squuze channel dim # for k in range(reconstructions.shape[0]): # b,repeat = k % nfiles, k // nfiles # vname_num_split_index = file_names[b].rfind('_')# file_names[b]:video_name+'_'+num # v_n,num = file_names[b][:vname_num_split_index],file_names[b][vname_num_split_index+1:] # save_img_path = os.path.join(savedir,f'{v_n}_sample_{num}_{repeat}.npy')# the num_th caption, the repeat_th repitition # np.save(save_img_path,reconstructions[b]) return None def forward(self, x, cond, *args, **kwargs): if self.use_lcm: index = torch.randint(0, self.num_ddim_timesteps, (x.shape[0],), device=self.device).long() t = self.ddim_timesteps[index].to(self.device) # t = torch.randint(0, self.ddim_timesteps, (x.shape[0],), device=self.device).long() else: t = torch.randint(0, self.num_timesteps, (x.shape[0],), device=self.device).long() if self.model.conditioning_key is not None: assert cond is not None cond = cond.to(x.device) if self.cond_stage_trainable: cond = self.get_learned_conditioning(cond) # c: string -> [B, T, Context_dim] if self.shorten_cond_schedule: # TODO: drop this option tc = self.cond_ids[t].to(self.device) cond = self.q_sample(x_start=cond, t=tc, noise=torch.randn_like(cond.float())) if self.use_lcm: return self.lcm_losses(x, cond, t, index, *args, **kwargs) return self.p_losses(x, cond, t, *args, **kwargs) def apply_model(self, x_noisy, t, cond, model, w_cond=None, return_ids=False): if isinstance(cond, dict): # hybrid case, cond is exptected to be a dict key = 'c_concat' if model.conditioning_key == 'concat' else 'c_crossattn' cond = {key: cond} else: if not isinstance(cond, list): cond = [cond] if model.conditioning_key == "concat": key = "c_concat" elif model.conditioning_key == "crossattn": key = "c_crossattn" else: key = "c_film" cond = {key: cond} x_recon = model(x_noisy, t, **cond, w_cond=w_cond) if isinstance(x_recon, tuple) and not return_ids: return x_recon[0] else: return x_recon def _predict_eps_from_xstart(self, x_t, t, pred_xstart): return (extract_into_tensor(self.sqrt_recip_alphas_cumprod, t, x_t.shape) * x_t - pred_xstart) / \ extract_into_tensor(self.sqrt_recipm1_alphas_cumprod, t, x_t.shape) def _prior_bpd(self, x_start): """ Get the prior KL term for the variational lower-bound, measured in bits-per-dim. This term can't be optimized, as it only depends on the encoder. :param x_start: the [N x C x ...] tensor of inputs. :return: a batch of [N] KL values (in bits), one per batch element. """ batch_size = x_start.shape[0] t = torch.tensor([self.num_timesteps - 1] * batch_size, device=x_start.device) qt_mean, _, qt_log_variance = self.q_mean_variance(x_start, t) kl_prior = normal_kl(mean1=qt_mean, logvar1=qt_log_variance, mean2=0.0, logvar2=0.0) return mean_flat(kl_prior) / np.log(2.0) def p_losses(self, x_start, cond, t, noise=None): noise = default(noise, lambda: torch.randn_like(x_start)) x_noisy = self.q_sample(x_start=x_start, t=t, noise=noise) model_output = self.apply_model(x_noisy, t, cond) loss_dict = {} prefix = 'train' if self.training else 'val' if self.parameterization == "x0": target = x_start elif self.parameterization == "eps": target = noise else: raise NotImplementedError() mean_dims = list(range(1,len(target.shape))) loss_simple = self.get_loss(model_output, target, mean=False).mean(dim=mean_dims) loss_dict.update({f'{prefix}/loss_simple': loss_simple.mean()}) logvar_t = self.logvar[t].to(self.device) loss = loss_simple / torch.exp(logvar_t) + logvar_t # loss = loss_simple / torch.exp(self.logvar) + self.logvar if self.learn_logvar: loss_dict.update({f'{prefix}/loss_gamma': loss.mean()}) loss_dict.update({'logvar': self.logvar.data.mean()}) loss = self.l_simple_weight * loss.mean() loss_vlb = self.get_loss(model_output, target, mean=False).mean(dim=mean_dims) loss_vlb = (self.lvlb_weights[t] * loss_vlb).mean() loss_dict.update({f'{prefix}/loss_vlb': loss_vlb}) loss += (self.original_elbo_weight * loss_vlb) loss_dict.update({f'{prefix}/loss': loss}) return loss, loss_dict def p_mean_variance(self, x, c, t, clip_denoised: bool, return_codebook_ids=False, quantize_denoised=False, return_x0=False, score_corrector=None, corrector_kwargs=None): t_in = t model_out = self.apply_model(x, t_in, c, return_ids=return_codebook_ids) if score_corrector is not None: assert self.parameterization == "eps" model_out = score_corrector.modify_score(self, model_out, x, t, c, **corrector_kwargs) if return_codebook_ids: model_out, logits = model_out if self.parameterization == "eps": x_recon = self.predict_start_from_noise(x, t=t, noise=model_out) elif self.parameterization == "x0": x_recon = model_out else: raise NotImplementedError() if clip_denoised: x_recon.clamp_(-1., 1.) if quantize_denoised: x_recon, _, [_, _, indices] = self.first_stage_model.quantize(x_recon) model_mean, posterior_variance, posterior_log_variance = self.q_posterior(x_start=x_recon, x_t=x, t=t) if return_codebook_ids: return model_mean, posterior_variance, posterior_log_variance, logits elif return_x0: return model_mean, posterior_variance, posterior_log_variance, x_recon else: return model_mean, posterior_variance, posterior_log_variance # From LatentConsistencyModel.get_guidance_scale_embedding def guidance_scale_embedding(self, w, embedding_dim=512, dtype=torch.float32): """ See https://github.com/google-research/vdm/blob/dc27b98a554f65cdc654b800da5aa1846545d41b/model_vdm.py#L298 Args: timesteps (`torch.Tensor`): generate embedding vectors at these timesteps embedding_dim (`int`, *optional*, defaults to 512): dimension of the embeddings to generate dtype: data type of the generated embeddings Returns: `torch.FloatTensor`: Embedding vectors with shape `(len(timesteps), embedding_dim)` """ assert len(w.shape) == 1 w = w * 1000.0 half_dim = embedding_dim // 2 emb = torch.log(torch.tensor(10000.0)) / (half_dim - 1) emb = torch.exp(torch.arange(half_dim, dtype=dtype) * -emb) emb = w.to(dtype)[:, None] * emb[None, :] emb = torch.cat([torch.sin(emb), torch.cos(emb)], dim=1) if embedding_dim % 2 == 1: # zero pad emb = torch.nn.functional.pad(emb, (0, 1)) assert emb.shape == (w.shape[0], embedding_dim) return emb def lcm_losses(self, x_start, cond, t, index, noise=None): # 20.4.4. Get boundary scalings for start_timesteps and (end) timesteps. c_skip_start, c_out_start = scalings_for_boundary_conditions(t) c_skip_start, c_out_start = [append_dims(x, x_start.ndim) for x in [c_skip_start, c_out_start]] timesteps = t - self.step_ratio timesteps = torch.where(timesteps < 0, torch.zeros_like(timesteps), timesteps) c_skip, c_out = scalings_for_boundary_conditions(timesteps) c_skip, c_out = [append_dims(x, x_start.ndim) for x in [c_skip, c_out]] noise = default(noise, lambda: torch.randn_like(x_start)) x_noisy = self.q_sample(x_start=x_start, t=t, noise=noise) bsz = x_start.shape[0] # 20.4.6. Sample a random guidance scale w from U[w_min, w_max] and embed it w = (self.w_max - self.w_min) * torch.rand((bsz,)) + self.w_min w_embedding = self.guidance_scale_embedding(w, embedding_dim=256) w = w.reshape(bsz, 1, 1) # Move to U-Net device and dtype w = w.to(device=x_start.device, dtype=x_start.dtype) w_embedding = w_embedding.to(device=x_start.device, dtype=x_start.dtype) # import ipdb # ipdb.set_trace() model_output = self.apply_model(x_noisy, t, cond, self.unet, w_cond=w_embedding) pred_x_0 = self.predict_start_from_noise(x_noisy,t,model_output) model_pred = c_skip_start * x_noisy + c_out_start * pred_x_0 # 20.4.10. Use the ODE solver to predict the kth step in the augmented PF-ODE trajectory after # noisy_latents with both the conditioning embedding c and unconditional embedding 0 # Get teacher model prediction on noisy_latents and conditional embedding with torch.no_grad(): with torch.autocast("cuda"): teacher_output = self.apply_model(x_noisy, t, cond, self.model) teacher_pred_x0 = self.predict_start_from_noise(x_noisy,t,teacher_output) uncond = self.get_learned_conditioning({'ori_caption': [""] * bsz,"struct_caption":[""] * bsz}) uncond_teacher_output = self.apply_model(x_noisy, t, uncond, self.model) uncond_teacher_pred_x0 = self.predict_start_from_noise(x_noisy,t,uncond_teacher_output) pred_x0 = teacher_pred_x0 + w * (teacher_pred_x0 - uncond_teacher_pred_x0) pred_noise = teacher_output + w * (teacher_output - uncond_teacher_output) x_prev = self.solver.ddim_step(pred_x0, pred_noise, index) # 20.4.12. Get target LCM prediction on x_prev, w, c, t_n with torch.no_grad(): with torch.autocast("cuda"): target_noise_pred = self.apply_model(x_prev.float(), timesteps, cond, self.target_unet, w_cond=w_embedding) pred_x_0 = self.predict_start_from_noise(x_prev,timesteps,target_noise_pred) target = c_skip * x_prev + c_out * pred_x_0 loss_dict = {} prefix = 'train' if self.training else 'val' # if self.parameterization == "x0": # target = x_start # elif self.parameterization == "eps": # target = noise # else: # raise NotImplementedError() # mean_dims = list(range(1,len(target.shape))) # loss_simple = self.get_loss(model_pred, target, mean=False).mean(dim=mean_dims) # loss = self.get_loss(model_pred, target, mean=True) # loss_dict.update({f'{prefix}/loss_simple': loss.mean()}) # loss = torch.nn.functional.mse_loss(model_pred.float(), target.float(), reduction="mean") loss = torch.mean( torch.sqrt((model_pred.float() - target.float()) ** 2 + 0.001**2) - 0.001 ) loss_dict.update({f'{prefix}/loss': loss.mean()}) loss = self.l_simple_weight * loss.mean() # logvar_t = self.logvar[t].to(self.device) # loss = loss_simple / torch.exp(logvar_t) + logvar_t # # loss = loss_simple / torch.exp(self.logvar) + self.logvar # if self.learn_logvar: # loss_dict.update({f'{prefix}/loss_gamma': loss.mean()}) # loss_dict.update({'logvar': self.logvar.data.mean()}) # loss = self.l_simple_weight * loss.mean() # loss_vlb = self.get_loss(model_pred, target, mean=False).mean(dim=mean_dims) # loss_vlb = (self.lvlb_weights[t] * loss_vlb).mean() # loss_dict.update({f'{prefix}/loss_vlb': loss_vlb}) # loss += (self.original_elbo_weight * loss_vlb) # loss_dict.update({f'{prefix}/loss': loss}) return loss, loss_dict @torch.no_grad() def p_sample(self, x, c, t, clip_denoised=False, repeat_noise=False, return_codebook_ids=False, quantize_denoised=False, return_x0=False, temperature=1., noise_dropout=0., score_corrector=None, corrector_kwargs=None): b, *_, device = *x.shape, x.device outputs = self.p_mean_variance(x=x, c=c, t=t, clip_denoised=clip_denoised, return_codebook_ids=return_codebook_ids, quantize_denoised=quantize_denoised, return_x0=return_x0, score_corrector=score_corrector, corrector_kwargs=corrector_kwargs) if return_codebook_ids: raise DeprecationWarning("Support dropped.") model_mean, _, model_log_variance, logits = outputs elif return_x0: model_mean, _, model_log_variance, x0 = outputs else: model_mean, _, model_log_variance = outputs noise = noise_like(x.shape, device, repeat_noise) * temperature if noise_dropout > 0.: noise = torch.nn.functional.dropout(noise, p=noise_dropout) # no noise when t == 0 nonzero_mask = (1 - (t == 0).float()).reshape(b, *((1,) * (len(x.shape) - 1))) if return_codebook_ids: return model_mean + nonzero_mask * (0.5 * model_log_variance).exp() * noise, logits.argmax(dim=1) if return_x0: return model_mean + nonzero_mask * (0.5 * model_log_variance).exp() * noise, x0 else: return model_mean + nonzero_mask * (0.5 * model_log_variance).exp() * noise @torch.no_grad() def progressive_denoising(self, cond, shape, verbose=True, callback=None, quantize_denoised=False, img_callback=None, mask=None, x0=None, temperature=1., noise_dropout=0., score_corrector=None, corrector_kwargs=None, batch_size=None, x_T=None, start_T=None, log_every_t=None): if not log_every_t: log_every_t = self.log_every_t timesteps = self.num_timesteps if batch_size is not None: b = batch_size if batch_size is not None else shape[0] shape = [batch_size] + list(shape) else: b = batch_size = shape[0] if x_T is None: img = torch.randn(shape, device=self.device) else: img = x_T intermediates = [] if cond is not None: if isinstance(cond, dict): cond = {key: cond[key][:batch_size] if not isinstance(cond[key], list) else list(map(lambda x: x[:batch_size], cond[key])) for key in cond} else: cond = [c[:batch_size] for c in cond] if isinstance(cond, list) else cond[:batch_size] if start_T is not None: timesteps = min(timesteps, start_T) iterator = tqdm(reversed(range(0, timesteps)), desc='Progressive Generation', total=timesteps) if verbose else reversed( range(0, timesteps)) if type(temperature) == float: temperature = [temperature] * timesteps for i in iterator: ts = torch.full((b,), i, device=self.device, dtype=torch.long) if self.shorten_cond_schedule: assert self.model.conditioning_key != 'hybrid' tc = self.cond_ids[ts].to(cond.device) cond = self.q_sample(x_start=cond, t=tc, noise=torch.randn_like(cond)) img, x0_partial = self.p_sample(img, cond, ts, clip_denoised=self.clip_denoised, quantize_denoised=quantize_denoised, return_x0=True, temperature=temperature[i], noise_dropout=noise_dropout, score_corrector=score_corrector, corrector_kwargs=corrector_kwargs) if mask is not None: assert x0 is not None img_orig = self.q_sample(x0, ts) img = img_orig * mask + (1. - mask) * img if i % log_every_t == 0 or i == timesteps - 1: intermediates.append(x0_partial) if callback: callback(i) if img_callback: img_callback(img, i) return img, intermediates @torch.no_grad() def p_sample_loop(self, cond, shape, return_intermediates=False, x_T=None, verbose=True, callback=None, timesteps=None, quantize_denoised=False, mask=None, x0=None, img_callback=None, start_T=None, log_every_t=None): if not log_every_t: log_every_t = self.log_every_t device = self.betas.device b = shape[0] if x_T is None: img = torch.randn(shape, device=device) else: img = x_T intermediates = [img] if timesteps is None: timesteps = self.num_timesteps if start_T is not None: timesteps = min(timesteps, start_T) iterator = tqdm(reversed(range(0, timesteps)), desc='Sampling t', total=timesteps) if verbose else reversed( range(0, timesteps)) if mask is not None: assert x0 is not None assert x0.shape[2:3] == mask.shape[2:3] # spatial size has to match for i in iterator: ts = torch.full((b,), i, device=device, dtype=torch.long) if self.shorten_cond_schedule: assert self.model.conditioning_key != 'hybrid' tc = self.cond_ids[ts].to(cond.device) cond = self.q_sample(x_start=cond, t=tc, noise=torch.randn_like(cond)) img = self.p_sample(img, cond, ts, clip_denoised=self.clip_denoised, quantize_denoised=quantize_denoised) if mask is not None: img_orig = self.q_sample(x0, ts) img = img_orig * mask + (1. - mask) * img if i % log_every_t == 0 or i == timesteps - 1: intermediates.append(img) if callback: callback(i) if img_callback: img_callback(img, i) if return_intermediates: return img, intermediates return img @torch.no_grad() def sample(self, cond, batch_size=16, return_intermediates=False, x_T=None, verbose=True, timesteps=None, quantize_denoised=False, mask=None, x0=None, shape=None,**kwargs): if shape is None: if self.channels > 0: shape = (batch_size, self.channels, self.mel_dim, self.mel_length) else: shape = (batch_size, self.mel_dim, self.mel_length) if cond is not None: if isinstance(cond, dict): cond = {key: cond[key][:batch_size] if not isinstance(cond[key], list) else list(map(lambda x: x[:batch_size], cond[key])) for key in cond} else: cond = [c[:batch_size] for c in cond] if isinstance(cond, list) else cond[:batch_size] return self.p_sample_loop(cond, shape, return_intermediates=return_intermediates, x_T=x_T, verbose=verbose, timesteps=timesteps, quantize_denoised=quantize_denoised, mask=mask, x0=x0) @torch.no_grad() def sample_log(self,cond,batch_size,ddim, ddim_steps,**kwargs): lcm_sampler = LCMSampler(self) shape = (self.channels, self.mel_dim, self.mel_length) if self.channels > 0 else (self.mel_dim, self.mel_length) samples, intermediates = lcm_sampler.sample(ddim_steps,batch_size, shape,cond,verbose=False,**kwargs) # if ddim: # ddim_sampler = DDIMSampler(self) # shape = (self.channels, self.mel_dim, self.mel_length) if self.channels > 0 else (self.mel_dim, self.mel_length) # samples, intermediates = ddim_sampler.sample(ddim_steps,batch_size, # shape,cond,verbose=False,**kwargs) # else: # samples, intermediates = self.sample(cond=cond, batch_size=batch_size, # return_intermediates=True,**kwargs) return samples, intermediates @torch.no_grad() def log_images(self, batch, N=8, n_row=4, sample=True, ddim_steps=50, ddim_eta=1., return_keys=None, quantize_denoised=True, inpaint=False, plot_denoise_rows=False, plot_progressive_rows=True, plot_diffusion_rows=True, **kwargs): use_ddim = ddim_steps is not None log = dict() z, c, x, xrec, xc = self.get_input(batch, self.first_stage_key, return_first_stage_outputs=True, force_c_encode=True, return_original_cond=True, bs=N) # z is latent,c is condition embedding, xc is condition(caption) list N = min(x.shape[0], N) n_row = min(x.shape[0], n_row) log["inputs"] = x if len(x.shape)==4 else x.unsqueeze(1) log["reconstruction"] = xrec if len(xrec.shape)==4 else xrec.unsqueeze(1) if self.model.conditioning_key is not None: if hasattr(self.cond_stage_model, "decode") and self.cond_stage_key != "masked_image": xc = self.cond_stage_model.decode(c) log["conditioning"] = xc elif self.cond_stage_key == "masked_image": log["mask"] = c[:, -1, :, :][:, None, :, :] xc = self.cond_stage_model.decode(c[:, :self.cond_stage_model.embed_dim, :, :]) log["conditioning"] = xc elif self.cond_stage_key in ["caption"]: pass # xc = log_txt_as_img((256, 256), batch["caption"]) # log["conditioning"] = xc elif self.cond_stage_key == 'class_label': xc = log_txt_as_img((x.shape[2], x.shape[3]), batch["human_label"]) log['conditioning'] = xc elif isimage(xc): log["conditioning"] = xc if plot_diffusion_rows: # get diffusion row diffusion_row = list() z_start = z[:n_row] for t in range(self.num_timesteps): if t % self.log_every_t == 0 or t == self.num_timesteps - 1: t = repeat(torch.tensor([t]), '1 -> b', b=n_row) t = t.to(self.device).long() noise = torch.randn_like(z_start) z_noisy = self.q_sample(x_start=z_start, t=t, noise=noise) diffusion_row.append(self.decode_first_stage(z_noisy)) if len(diffusion_row[0].shape) == 3: diffusion_row = [x.unsqueeze(1) for x in diffusion_row] diffusion_row = torch.stack(diffusion_row) # n_log_step, n_row, C, H, W diffusion_grid = rearrange(diffusion_row, 'n b c h w -> b n c h w') diffusion_grid = rearrange(diffusion_grid, 'b n c h w -> (b n) c h w') diffusion_grid = make_grid(diffusion_grid, nrow=diffusion_row.shape[0]) log["diffusion_row"] = diffusion_grid if sample: # get denoise row with self.ema_scope("Plotting"): samples, z_denoise_row = self.sample_log(cond=c,batch_size=N,ddim=use_ddim, ddim_steps=ddim_steps,eta=ddim_eta) # samples, z_denoise_row = self.sample(cond=c, batch_size=N, return_intermediates=True) x_samples = self.decode_first_stage(samples) log["samples"] = x_samples if len(x_samples.shape)==4 else x_samples.unsqueeze(1) if plot_denoise_rows: denoise_grid = self._get_denoise_row_from_list(z_denoise_row) log["denoise_row"] = denoise_grid if quantize_denoised and not isinstance(self.first_stage_model, AutoencoderKL) and not isinstance( self.first_stage_model, IdentityFirstStage): # also display when quantizing x0 while sampling with self.ema_scope("Plotting Quantized Denoised"): samples, z_denoise_row = self.sample_log(cond=c,batch_size=N,ddim=use_ddim, ddim_steps=ddim_steps,eta=ddim_eta, quantize_denoised=True) # samples, z_denoise_row = self.sample(cond=c, batch_size=N, return_intermediates=True, # quantize_denoised=True) x_samples = self.decode_first_stage(samples.to(self.device)) log["samples_x0_quantized"] = x_samples if len(x_samples.shape)==4 else x_samples.unsqueeze(1) if inpaint: # make a simple center square b, h, w = z.shape[0], z.shape[2], z.shape[3] mask = torch.ones(N, h, w).to(self.device) # zeros will be filled in mask[:, h // 4:3 * h // 4, w // 4:3 * w // 4] = 0. mask = mask[:, None, ...] with self.ema_scope("Plotting Inpaint"): samples, _ = self.sample_log(cond=c,batch_size=N,ddim=use_ddim, eta=ddim_eta, ddim_steps=ddim_steps, x0=z[:N], mask=mask) x_samples = self.decode_first_stage(samples.to(self.device)) log["samples_inpainting"] = x_samples log["mask_inpainting"] = mask # outpaint mask = 1 - mask with self.ema_scope("Plotting Outpaint"): samples, _ = self.sample_log(cond=c, batch_size=N, ddim=use_ddim,eta=ddim_eta, ddim_steps=ddim_steps, x0=z[:N], mask=mask) x_samples = self.decode_first_stage(samples.to(self.device)) log["samples_outpainting"] = x_samples log["mask_outpainting"] = mask # if plot_progressive_rows: # with self.ema_scope("Plotting Progressives"): # shape = (self.channels, self.mel_dim, self.mel_length) if self.channels > 0 else (self.mel_dim, self.mel_length) # img, progressives = self.progressive_denoising(c, # shape=shape, # batch_size=N) # prog_row = self._get_denoise_row_from_list(progressives, desc="Progressive Generation") # log["progressive_row"] = prog_row if return_keys: if np.intersect1d(list(log.keys()), return_keys).shape[0] == 0: return log else: return {key: log[key] for key in return_keys} return log def configure_optimizers(self): lr = self.learning_rate params = list(self.unet.parameters()) if self.cond_stage_trainable: print(f"{self.__class__.__name__}: Also optimizing conditioner params!") params = params + list(self.cond_stage_model.parameters()) if self.learn_logvar: print('Diffusion model optimizing logvar') params.append(self.logvar) opt = torch.optim.AdamW(params, lr=lr) if self.use_scheduler: assert 'target' in self.scheduler_config scheduler = instantiate_from_config(self.scheduler_config) print("Setting up LambdaLR scheduler...") scheduler = [ { 'scheduler': LambdaLR(opt, lr_lambda=scheduler.schedule), 'interval': 'step', 'frequency': 1 }] return [opt], scheduler return opt def on_train_batch_end(self, *args, **kwargs): rate = 0.95 for targ, src in zip(self.target_unet.parameters(), self.unet.parameters()): targ.detach().mul_(rate).add_(src, alpha=1 - rate)