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Audio-SR / audiosr /latent_diffusion /models /ddpm.py

Nick088

added audio sr files, adapted them to zerogpu and optimization for memory

fa90792 almost 2 years ago

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	from multiprocessing.sharedctypes import Value
	import os
	import librosa
	import torch
	import torch.nn as nn
	import numpy as np
	from einops import rearrange, repeat
	from contextlib import contextmanager
	from functools import partial
	from tqdm import tqdm
	from torchvision.utils import make_grid
	from audiosr.latent_diffusion.modules.encoders.modules import *

	from audiosr.latent_diffusion.util import (
	exists,
	default,
	count_params,
	instantiate_from_config,
	)
	from audiosr.latent_diffusion.modules.ema import LitEma
	from audiosr.latent_diffusion.modules.distributions.distributions import (
	DiagonalGaussianDistribution,
	)

	from audiosr.latent_diffusion.modules.diffusionmodules.util import (
	make_beta_schedule,
	extract_into_tensor,
	noise_like,
	)

	from audiosr.latent_diffusion.models.ddim import DDIMSampler
	from audiosr.latent_diffusion.models.plms import PLMSSampler
	import soundfile as sf
	import os

	__conditioning_keys__ = {"concat": "c_concat", "crossattn": "c_crossattn", "adm": "y"}


	def disabled_train(self, mode=True):
	"""Overwrite model.train with this function to make sure train/eval mode
	does not change anymore."""
	return self


	def uniform_on_device(r1, r2, shape, device):
	return (r1 - r2) * torch.rand(*shape, device=device) + r2


	class DDPM(nn.Module):
	# classic DDPM with Gaussian diffusion, in image space
	def __init__(
	self,
	unet_config,
	sampling_rate=None,
	timesteps=1000,
	beta_schedule="linear",
	loss_type="l2",
	ckpt_path=None,
	ignore_keys=[],
	load_only_unet=False,
	monitor="val/loss",
	use_ema=True,
	first_stage_key="image",
	latent_t_size=256,
	latent_f_size=16,
	channels=3,
	log_every_t=100,
	clip_denoised=True,
	linear_start=1e-4,
	linear_end=2e-2,
	cosine_s=8e-3,
	given_betas=None,
	original_elbo_weight=0.0,
	v_posterior=0.0, # weight for choosing posterior variance as sigma = (1-v) * beta_tilde + v * beta
	l_simple_weight=1.0,
	conditioning_key=None,
	parameterization="eps", # all assuming fixed variance schedules
	scheduler_config=None,
	use_positional_encodings=False,
	learn_logvar=False,
	logvar_init=0.0,
	evaluator=None,
	device=None,
	):
	super().__init__()
	assert parameterization in [
	"eps",
	"x0",
	"v",
	], 'currently only supporting "eps" and "x0" and "v"'
	self.parameterization = parameterization
	self.state = None
	self.device = device
	# print(
	# f"{self.__class__.__name__}: Running in {self.parameterization}-prediction mode"
	# )
	assert sampling_rate is not None
	self.validation_folder_name = "temp_name"
	self.clip_denoised = clip_denoised
	self.log_every_t = log_every_t
	self.first_stage_key = first_stage_key
	self.sampling_rate = sampling_rate

	self.clap = CLAPAudioEmbeddingClassifierFreev2(
	pretrained_path="",
	enable_cuda=self.device == "cuda",
	sampling_rate=self.sampling_rate,
	embed_mode="audio",
	amodel="HTSAT-base",
	)

	self.initialize_param_check_toolkit()

	self.latent_t_size = latent_t_size
	self.latent_f_size = latent_f_size

	self.channels = channels
	self.use_positional_encodings = use_positional_encodings
	self.model = DiffusionWrapper(unet_config, conditioning_key)
	count_params(self.model, verbose=True)
	self.use_ema = use_ema
	if self.use_ema:
	self.model_ema = LitEma(self.model)
	# print(f"Keeping EMAs of {len(list(self.model_ema.buffers()))}.")

	self.use_scheduler = scheduler_config is not None
	if self.use_scheduler:
	self.scheduler_config = scheduler_config

	self.v_posterior = v_posterior
	self.original_elbo_weight = original_elbo_weight
	self.l_simple_weight = l_simple_weight

	if monitor is not None:
	self.monitor = monitor
	if ckpt_path is not None:
	self.init_from_ckpt(
	ckpt_path, ignore_keys=ignore_keys, only_model=load_only_unet
	)

	self.register_schedule(
	given_betas=given_betas,
	beta_schedule=beta_schedule,
	timesteps=timesteps,
	linear_start=linear_start,
	linear_end=linear_end,
	cosine_s=cosine_s,
	)

	self.loss_type = loss_type

	self.learn_logvar = learn_logvar
	self.logvar = torch.full(fill_value=logvar_init, size=(self.num_timesteps,))
	if self.learn_logvar:
	self.logvar = nn.Parameter(self.logvar, requires_grad=True)
	else:
	self.logvar = nn.Parameter(self.logvar, requires_grad=False)

	self.logger_save_dir = None
	self.logger_exp_name = None
	self.logger_exp_group_name = None
	self.logger_version = None

	self.label_indices_total = None
	# To avoid the system cannot find metric value for checkpoint
	self.metrics_buffer = {
	"val/kullback_leibler_divergence_sigmoid": 15.0,
	"val/kullback_leibler_divergence_softmax": 10.0,
	"val/psnr": 0.0,
	"val/ssim": 0.0,
	"val/inception_score_mean": 1.0,
	"val/inception_score_std": 0.0,
	"val/kernel_inception_distance_mean": 0.0,
	"val/kernel_inception_distance_std": 0.0,
	"val/frechet_inception_distance": 133.0,
	"val/frechet_audio_distance": 32.0,
	}
	self.initial_learning_rate = None
	self.test_data_subset_path = None

	def get_log_dir(self):
	return os.path.join(
	self.logger_save_dir, self.logger_exp_group_name, self.logger_exp_name
	)

	def set_log_dir(self, save_dir, exp_group_name, exp_name):
	self.logger_save_dir = save_dir
	self.logger_exp_group_name = exp_group_name
	self.logger_exp_name = exp_name

	def register_schedule(
	self,
	given_betas=None,
	beta_schedule="linear",
	timesteps=1000,
	linear_start=1e-4,
	linear_end=2e-2,
	cosine_s=8e-3,
	):
	if exists(given_betas):
	betas = given_betas
	else:
	betas = make_beta_schedule(
	beta_schedule,
	timesteps,
	linear_start=linear_start,
	linear_end=linear_end,
	cosine_s=cosine_s,
	)
	alphas = 1.0 - betas
	alphas_cumprod = np.cumprod(alphas, axis=0)
	alphas_cumprod_prev = np.append(1.0, alphas_cumprod[:-1])

	(timesteps,) = betas.shape
	self.num_timesteps = int(timesteps)
	self.linear_start = linear_start
	self.linear_end = linear_end
	assert (
	alphas_cumprod.shape[0] == self.num_timesteps
	), "alphas have to be defined for each timestep"

	to_torch = partial(torch.tensor, dtype=torch.float32)

	self.register_buffer("betas", to_torch(betas))
	self.register_buffer("alphas_cumprod", to_torch(alphas_cumprod))
	self.register_buffer("alphas_cumprod_prev", to_torch(alphas_cumprod_prev))

	# calculations for diffusion q(x_t \| x_{t-1}) and others
	epsilon = 1e-10
	self.register_buffer("sqrt_alphas_cumprod", to_torch(np.sqrt(alphas_cumprod)))
	self.register_buffer(
	"sqrt_one_minus_alphas_cumprod", to_torch(np.sqrt(1.0 - alphas_cumprod))
	)
	self.register_buffer(
	"log_one_minus_alphas_cumprod", to_torch(np.log(1.0 - alphas_cumprod))
	)
	self.register_buffer(
	"sqrt_recip_alphas_cumprod", to_torch(np.sqrt(1.0 / (alphas_cumprod + epsilon)))
	)
	self.register_buffer(
	"sqrt_recipm1_alphas_cumprod", to_torch(np.sqrt(1.0 / (alphas_cumprod + epsilon) - 1))
	)

	# calculations for posterior q(x_{t-1} \| x_t, x_0)
	posterior_variance = (1 - self.v_posterior) * betas * (
	1.0 - alphas_cumprod_prev
	) / (1.0 - alphas_cumprod) + self.v_posterior * betas
	# above: equal to 1. / (1. / (1. - alpha_cumprod_tm1) + alpha_t / beta_t)
	self.register_buffer("posterior_variance", to_torch(posterior_variance))
	# below: log calculation clipped because the posterior variance is 0 at the beginning of the diffusion chain
	self.register_buffer(
	"posterior_log_variance_clipped",
	to_torch(np.log(np.maximum(posterior_variance, 1e-20))),
	)
	self.register_buffer(
	"posterior_mean_coef1",
	to_torch(betas * np.sqrt(alphas_cumprod_prev) / (1.0 - alphas_cumprod)),
	)
	self.register_buffer(
	"posterior_mean_coef2",
	to_torch(
	(1.0 - alphas_cumprod_prev) * np.sqrt(alphas) / (1.0 - alphas_cumprod)
	),
	)

	if self.parameterization == "eps":
	lvlb_weights = self.betas**2 / (
	2
	* self.posterior_variance
	* to_torch(alphas)
	* (1 - self.alphas_cumprod)
	)
	elif self.parameterization == "x0":
	lvlb_weights = (
	0.5
	* np.sqrt(torch.Tensor(alphas_cumprod))
	/ (2.0 * 1 - torch.Tensor(alphas_cumprod))
	)
	elif self.parameterization == "v":
	lvlb_weights = torch.ones_like(
	self.betas**2
	/ (
	2
	* self.posterior_variance
	* to_torch(alphas)
	* (1 - self.alphas_cumprod)
	)
	)
	else:
	raise NotImplementedError("mu not supported")
	# TODO how to choose this term
	lvlb_weights[0] = lvlb_weights[1]
	self.register_buffer("lvlb_weights", lvlb_weights, persistent=False)
	assert not torch.isnan(self.lvlb_weights).all()

	@contextmanager
	def ema_scope(self, context=None):
	if self.use_ema:
	self.model_ema.store(self.model.parameters())
	self.model_ema.copy_to(self.model)
	# if context is not None:
	# print(f"{context}: Switched to EMA weights")
	try:
	yield None
	finally:
	if self.use_ema:
	self.model_ema.restore(self.model.parameters())
	# if context is not None:
	# print(f"{context}: Restored training weights")

	def init_from_ckpt(self, path, ignore_keys=list(), only_model=False):
	sd = torch.load(path, map_location="cpu")
	if "state_dict" in list(sd.keys()):
	sd = sd["state_dict"]
	keys = list(sd.keys())
	for k in keys:
	for ik in ignore_keys:
	if k.startswith(ik):
	print("Deleting key {} from state_dict.".format(k))
	del sd[k]
	missing, unexpected = (
	self.load_state_dict(sd, strict=False)
	if not only_model
	else self.model.load_state_dict(sd, strict=False)
	)
	print(
	f"Restored from {path} with {len(missing)} missing and {len(unexpected)} unexpected keys"
	)
	if len(missing) > 0:
	print(f"Missing Keys: {missing}")
	if len(unexpected) > 0:
	print(f"Unexpected Keys: {unexpected}")

	def q_mean_variance(self, x_start, t):
	"""
	Get the distribution q(x_t \| x_0).
	:param x_start: the [N x C x ...] tensor of noiseless inputs.
	:param t: the number of diffusion steps (minus 1). Here, 0 means one step.
	:return: A tuple (mean, variance, log_variance), all of x_start's shape.
	"""
	mean = extract_into_tensor(self.sqrt_alphas_cumprod, t, x_start.shape) * x_start
	variance = extract_into_tensor(1.0 - self.alphas_cumprod, t, x_start.shape)
	log_variance = extract_into_tensor(
	self.log_one_minus_alphas_cumprod, t, x_start.shape
	)
	return mean, variance, log_variance

	def predict_start_from_noise(self, x_t, t, noise):
	return (
	extract_into_tensor(self.sqrt_recip_alphas_cumprod, t, x_t.shape) * x_t
	- extract_into_tensor(self.sqrt_recipm1_alphas_cumprod, t, x_t.shape)
	* noise
	)

	def q_posterior(self, x_start, x_t, t):
	posterior_mean = (
	extract_into_tensor(self.posterior_mean_coef1, t, x_t.shape) * x_start
	+ extract_into_tensor(self.posterior_mean_coef2, t, x_t.shape) * x_t
	)
	posterior_variance = extract_into_tensor(self.posterior_variance, t, x_t.shape)
	posterior_log_variance_clipped = extract_into_tensor(
	self.posterior_log_variance_clipped, t, x_t.shape
	)
	return posterior_mean, posterior_variance, posterior_log_variance_clipped

	def p_mean_variance(self, x, t, clip_denoised: bool):
	model_out = self.model(x, t)
	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
	if clip_denoised:
	x_recon.clamp_(-1.0, 1.0)

	model_mean, posterior_variance, posterior_log_variance = self.q_posterior(
	x_start=x_recon, x_t=x, t=t
	)
	return model_mean, posterior_variance, posterior_log_variance

	@torch.no_grad()
	def p_sample(self, x, t, clip_denoised=True, repeat_noise=False):
	b, _, device = x.shape, x.device
	model_mean, _, model_log_variance = self.p_mean_variance(
	x=x, t=t, clip_denoised=clip_denoised
	)
	noise = noise_like(x.shape, device, repeat_noise)
	# no noise when t == 0
	nonzero_mask = (
	(1 - (t == 0).float()).reshape(b, ((1,) (len(x.shape) - 1))).contiguous()
	)
	return model_mean + nonzero_mask * (0.5 * model_log_variance).exp() * noise

	@torch.no_grad()
	def p_sample_loop(self, shape, return_intermediates=False):
	device = self.betas.device
	b = shape[0]
	img = torch.randn(shape, device=device)
	intermediates = [img]
	for i in tqdm(
	reversed(range(0, self.num_timesteps)),
	desc="Sampling t",
	total=self.num_timesteps,
	):
	img = self.p_sample(
	img,
	torch.full((b,), i, device=device, dtype=torch.long),
	clip_denoised=self.clip_denoised,
	)
	if i % self.log_every_t == 0 or i == self.num_timesteps - 1:
	intermediates.append(img)
	if return_intermediates:
	return img, intermediates
	return img

	@torch.no_grad()
	def sample(self, batch_size=16, return_intermediates=False):
	shape = (batch_size, channels, self.latent_t_size, self.latent_f_size)
	self.channels
	return self.p_sample_loop(shape, return_intermediates=return_intermediates)

	def q_sample(self, x_start, t, noise=None):
	noise = default(noise, lambda: torch.randn_like(x_start))
	return (
	extract_into_tensor(self.sqrt_alphas_cumprod, t, x_start.shape) * x_start
	+ extract_into_tensor(self.sqrt_one_minus_alphas_cumprod, t, x_start.shape)
	* noise
	)

	def get_loss(self, pred, target, mean=True):
	if self.loss_type == "l1":
	loss = (target - pred).abs()
	if mean:
	loss = loss.mean()
	elif self.loss_type == "l2":
	if mean:
	loss = torch.nn.functional.mse_loss(target, pred)
	else:
	loss = torch.nn.functional.mse_loss(target, pred, reduction="none")
	else:
	raise NotImplementedError("unknown loss type '{loss_type}'")

	return loss

	def predict_start_from_z_and_v(self, x_t, t, v):
	# self.register_buffer('sqrt_alphas_cumprod', to_torch(np.sqrt(alphas_cumprod)))
	# self.register_buffer('sqrt_one_minus_alphas_cumprod', to_torch(np.sqrt(1. - alphas_cumprod)))
	return (
	extract_into_tensor(self.sqrt_alphas_cumprod, t, x_t.shape) * x_t
	- extract_into_tensor(self.sqrt_one_minus_alphas_cumprod, t, x_t.shape) * v
	)

	def predict_eps_from_z_and_v(self, x_t, t, v):
	return (
	extract_into_tensor(self.sqrt_alphas_cumprod, t, x_t.shape) * v
	+ extract_into_tensor(self.sqrt_one_minus_alphas_cumprod, t, x_t.shape)
	* x_t
	)

	def get_v(self, x, noise, t):
	return (
	extract_into_tensor(self.sqrt_alphas_cumprod, t, x.shape) * noise
	- extract_into_tensor(self.sqrt_one_minus_alphas_cumprod, t, x.shape) * x
	)

	def forward(self, x, args, *kwargs):
	# b, c, h, w, device, img_size, = *x.shape, x.device, self.image_size
	# assert h == img_size and w == img_size, f'height and width of image must be {img_size}'
	t = torch.randint(
	0, self.num_timesteps, (x.shape[0],), device=self.device
	).long()
	return self.p_losses(x, t, args, *kwargs)

	def get_input(self, batch, k):
	# fbank, log_magnitudes_stft, label_indices, fname, waveform, clip_label, text = batch
	# fbank, stft, label_indices, fname, waveform, text = batch
	waveform, stft, fbank = (
	batch["waveform"],
	batch["stft"],
	batch["log_mel_spec"],
	)
	# for i in range(fbank.size(0)):
	# fb = fbank[i].numpy()
	# seg_lb = seg_label[i].numpy()
	# logits = np.mean(seg_lb, axis=0)
	# index = np.argsort(logits)[::-1][:5]
	# plt.imshow(seg_lb[:,index], aspect="auto")
	# plt.title(index)
	# plt.savefig("%s_label.png" % i)
	# plt.close()
	# plt.imshow(fb, aspect="auto")
	# plt.savefig("%s_fb.png" % i)
	# plt.close()
	ret = {}

	ret["fbank"] = (
	fbank.unsqueeze(1).to(memory_format=torch.contiguous_format).float()
	)
	ret["stft"] = stft.to(memory_format=torch.contiguous_format).float()
	# ret["clip_label"] = clip_label.to(memory
	# _format=torch.contiguous_format).float()
	ret["waveform"] = waveform.to(memory_format=torch.contiguous_format).float()
	# ret["phoneme_idx"] = phoneme_idx.to(memory_format=torch.contiguous_format).long()
	# ret["text"] = list(text)
	# ret["fname"] = fname

	for key in batch.keys():
	if key not in ret.keys():
	ret[key] = batch[key]

	return ret[k]

	def _get_rows_from_list(self, samples):
	n_imgs_per_row = len(samples)
	denoise_grid = rearrange(samples, "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

	@torch.no_grad()
	def log_images(self, batch, N=8, n_row=2, sample=True, return_keys=None, **kwargs):
	log = dict()
	x = self.get_input(batch, self.first_stage_key)
	N = min(x.shape[0], N)
	n_row = min(x.shape[0], n_row)
	x = x.to(self.device)[:N]
	log["inputs"] = x

	# get diffusion row
	diffusion_row = list()
	x_start = x[: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(x_start)
	x_noisy = self.q_sample(x_start=x_start, t=t, noise=noise)
	diffusion_row.append(x_noisy)

	log["diffusion_row"] = self._get_rows_from_list(diffusion_row)

	if sample:
	# get denoise row
	with self.ema_scope("Plotting"):
	samples, denoise_row = self.sample(
	batch_size=N, return_intermediates=True
	)

	log["samples"] = samples
	log["denoise_row"] = self._get_rows_from_list(denoise_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.model.parameters())
	if self.learn_logvar:
	params = params + [self.logvar]
	opt = torch.optim.AdamW(params, lr=lr)
	return opt

	def initialize_param_check_toolkit(self):
	self.tracked_steps = 0
	self.param_dict = {}

	def statistic_require_grad_tensor_number(self, module, name=None):
	requires_grad_num = 0
	total_num = 0
	require_grad_tensor = None
	for p in module.parameters():
	if p.requires_grad:
	requires_grad_num += 1
	if require_grad_tensor is None:
	require_grad_tensor = p
	total_num += 1
	print(
	"Module: [%s] have %s trainable parameters out of %s total parameters (%.2f)"
	% (name, requires_grad_num, total_num, requires_grad_num / total_num)
	)
	return require_grad_tensor


	class LatentDiffusion(DDPM):
	"""main class"""

	def __init__(
	self,
	first_stage_config,
	cond_stage_config=None,
	num_timesteps_cond=None,
	cond_stage_key="image",
	optimize_ddpm_parameter=True,
	unconditional_prob_cfg=0.1,
	warmup_steps=10000,
	cond_stage_trainable=False,
	concat_mode=True,
	cond_stage_forward=None,
	conditioning_key=None,
	scale_factor=1.0,
	batchsize=None,
	evaluation_params={},
	scale_by_std=False,
	base_learning_rate=None,
	*args,
	**kwargs,
	):
	self.learning_rate = base_learning_rate
	self.num_timesteps_cond = default(num_timesteps_cond, 1)
	self.scale_by_std = scale_by_std
	self.warmup_steps = warmup_steps

	if optimize_ddpm_parameter:
	if unconditional_prob_cfg == 0.0:
	"You choose to optimize DDPM. The classifier free guidance scale should be 0.1"
	unconditional_prob_cfg = 0.1
	else:
	if unconditional_prob_cfg == 0.1:
	"You choose not to optimize DDPM. The classifier free guidance scale should be 0.0"
	unconditional_prob_cfg = 0.0

	self.evaluation_params = evaluation_params
	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

	conditioning_key = list(cond_stage_config.keys())

	self.conditioning_key = conditioning_key

	ckpt_path = kwargs.pop("ckpt_path", None)
	ignore_keys = kwargs.pop("ignore_keys", [])
	super().__init__(conditioning_key=conditioning_key, args, *kwargs)

	self.optimize_ddpm_parameter = optimize_ddpm_parameter
	# if(not optimize_ddpm_parameter):
	# print("Warning: Close the optimization of the latent diffusion model")
	# for p in self.model.parameters():
	# p.requires_grad=False

	self.concat_mode = concat_mode
	self.cond_stage_key = cond_stage_key
	self.cond_stage_key_orig = 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.model.scale_factor = self.scale_factor
	self.instantiate_first_stage(first_stage_config)
	self.unconditional_prob_cfg = unconditional_prob_cfg
	self.cond_stage_models = nn.ModuleList([])
	self.instantiate_cond_stage(cond_stage_config)
	self.cond_stage_forward = cond_stage_forward
	self.clip_denoised = False
	self.bbox_tokenizer = None
	self.conditional_dry_run_finished = False
	self.restarted_from_ckpt = False
	if ckpt_path is not None:
	self.init_from_ckpt(ckpt_path, ignore_keys)
	self.restarted_from_ckpt = True

	def configure_optimizers(self):
	lr = self.learning_rate
	params = list(self.model.parameters())

	for each in self.cond_stage_models:
	params = params + list(
	each.parameters()
	) # Add the parameter from the conditional stage

	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 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

	@torch.no_grad()
	def on_train_batch_start(self, batch, batch_idx):
	# only for very first batch
	if (
	self.scale_factor == 1
	and 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()
	del self.scale_factor
	self.register_buffer("scale_factor", 1.0 / z.flatten().std())
	print(f"setting self.scale_factor to {self.scale_factor}")
	print("### USING STD-RESCALING ###")

	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 make_decision(self, probability):
	if float(torch.rand(1)) < probability:
	return True
	else:
	return False

	def instantiate_cond_stage(self, config):
	self.cond_stage_model_metadata = {}
	for i, cond_model_key in enumerate(config.keys()):
	if (
	"params" in config[cond_model_key]
	and "device" in config[cond_model_key]["params"]
	):
	config[cond_model_key]["params"]["device"] = self.device
	model = instantiate_from_config(config[cond_model_key])
	model = model.to(self.device)
	self.cond_stage_models.append(model)
	self.cond_stage_model_metadata[cond_model_key] = {
	"model_idx": i,
	"cond_stage_key": config[cond_model_key]["cond_stage_key"],
	"conditioning_key": config[cond_model_key]["conditioning_key"],
	}

	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

	def get_learned_conditioning(self, c, key, unconditional_cfg):
	assert key in self.cond_stage_model_metadata.keys()

	# Classifier-free guidance
	if not unconditional_cfg:
	c = self.cond_stage_models[
	self.cond_stage_model_metadata[key]["model_idx"]
	](c)
	else:
	# when the cond_stage_key is "all", pick one random element out
	if isinstance(c, dict):
	c = c[list(c.keys())[0]]

	if isinstance(c, torch.Tensor):
	batchsize = c.size(0)
	elif isinstance(c, list):
	batchsize = len(c)
	else:
	raise NotImplementedError()

	c = self.cond_stage_models[
	self.cond_stage_model_metadata[key]["model_idx"]
	].get_unconditional_condition(batchsize)

	return c

	def get_input(
	self,
	batch,
	k,
	return_first_stage_encode=True,
	return_decoding_output=False,
	return_encoder_input=False,
	return_encoder_output=False,
	unconditional_prob_cfg=0.1,
	):
	x = super().get_input(batch, k)

	x = x.to(self.device)

	if return_first_stage_encode:
	encoder_posterior = self.encode_first_stage(x)
	z = self.get_first_stage_encoding(encoder_posterior).detach()
	else:
	z = None
	cond_dict = {}
	if len(self.cond_stage_model_metadata.keys()) > 0:
	unconditional_cfg = False
	if self.conditional_dry_run_finished and self.make_decision(
	unconditional_prob_cfg
	):
	unconditional_cfg = True
	for cond_model_key in self.cond_stage_model_metadata.keys():
	cond_stage_key = self.cond_stage_model_metadata[cond_model_key][
	"cond_stage_key"
	]

	if cond_model_key in cond_dict.keys():
	continue

	# if not self.training:
	# if isinstance(
	# self.cond_stage_models[
	# self.cond_stage_model_metadata[cond_model_key]["model_idx"]
	# ],
	# CLAPAudioEmbeddingClassifierFreev2,
	# ):
	# print(
	# "Warning: CLAP model normally should use text for evaluation"
	# )

	# The original data for conditioning
	# If cond_model_key is "all", that means the conditional model need all the information from a batch

	if cond_stage_key != "all":
	xc = super().get_input(batch, cond_stage_key)
	if type(xc) == torch.Tensor:
	xc = xc.to(self.device)
	else:
	xc = batch

	# if cond_stage_key is "all", xc will be a dictionary containing all keys
	# Otherwise xc will be an entry of the dictionary
	c = self.get_learned_conditioning(
	xc, key=cond_model_key, unconditional_cfg=unconditional_cfg
	)

	# cond_dict will be used to condition the diffusion model
	# If one conditional model return multiple conditioning signal
	if isinstance(c, dict):
	for k in c.keys():
	cond_dict[k] = c[k]
	else:
	cond_dict[cond_model_key] = c

	# If the key is accidently added to the dictionary and not in the condition list, remove the condition
	# for k in list(cond_dict.keys()):
	# if(k not in self.cond_stage_model_metadata.keys()):
	# del cond_dict[k]

	out = [z, cond_dict]

	if return_decoding_output:
	xrec = self.decode_first_stage(z)
	out += [xrec]

	if return_encoder_input:
	out += [x]

	if return_encoder_output:
	out += [encoder_posterior]

	if not self.conditional_dry_run_finished:
	self.conditional_dry_run_finished = True

	# Output is a dictionary, where the value could only be tensor or tuple
	return out

	def decode_first_stage(self, z):
	with torch.no_grad():
	z = 1.0 / self.scale_factor * z
	decoding = self.first_stage_model.decode(z)
	return decoding

	def mel_spectrogram_to_waveform(
	self, mel, savepath=".", bs=None, name="outwav", save=True
	):
	# Mel: [bs, 1, t-steps, fbins]
	if len(mel.size()) == 4:
	mel = mel.squeeze(1)
	mel = mel.permute(0, 2, 1)
	waveform = self.first_stage_model.vocoder(mel)
	waveform = waveform.cpu().detach().numpy()
	if save:
	self.save_waveform(waveform, savepath, name)
	return waveform

	def encode_first_stage(self, x):
	with torch.no_grad():
	return self.first_stage_model.encode(x)

	def extract_possible_loss_in_cond_dict(self, cond_dict):
	# This function enable the conditional module to return loss function that can optimize them

	assert isinstance(cond_dict, dict)
	losses = {}

	for cond_key in cond_dict.keys():
	if "loss" in cond_key and "noncond" in cond_key:
	assert cond_key not in losses.keys()
	losses[cond_key] = cond_dict[cond_key]

	return losses

	def filter_useful_cond_dict(self, cond_dict):
	new_cond_dict = {}
	for key in cond_dict.keys():
	if key in self.cond_stage_model_metadata.keys():
	new_cond_dict[key] = cond_dict[key]

	# All the conditional key in the metadata should be used

	for key in self.cond_stage_model_metadata.keys():
	assert key in new_cond_dict.keys(), "%s, %s" % (
	key,
	str(new_cond_dict.keys()),
	)

	return new_cond_dict

	def shared_step(self, batch, **kwargs):
	if self.training:
	# Classifier-free guidance
	unconditional_prob_cfg = self.unconditional_prob_cfg
	else:
	unconditional_prob_cfg = 0.0 # TODO possible bug here

	x, c = self.get_input(
	batch, self.first_stage_key, unconditional_prob_cfg=unconditional_prob_cfg
	)

	if self.optimize_ddpm_parameter:
	loss, loss_dict = self(x, self.filter_useful_cond_dict(c))
	else:
	loss_dict = {}
	loss = None

	additional_loss_for_cond_modules = self.extract_possible_loss_in_cond_dict(c)
	assert isinstance(additional_loss_for_cond_modules, dict)

	loss_dict.update(additional_loss_for_cond_modules)

	if len(additional_loss_for_cond_modules.keys()) > 0:
	for k in additional_loss_for_cond_modules.keys():
	if loss is None:
	loss = additional_loss_for_cond_modules[k]
	else:
	loss = loss + additional_loss_for_cond_modules[k]

	# for k,v in additional_loss_for_cond_modules.items():
	# self.log(
	# "cond_stage/"+k,
	# float(v),
	# prog_bar=True,
	# logger=True,
	# on_step=True,
	# on_epoch=True,
	# )
	if self.training:
	assert loss is not None

	return loss, loss_dict

	def forward(self, x, c, args, *kwargs):
	t = torch.randint(
	0, self.num_timesteps, (x.shape[0],), device=self.device
	).long()

	# assert c is not None
	# c = self.get_learned_conditioning(c)

	loss, loss_dict = self.p_losses(x, c, t, args, *kwargs)
	return loss, loss_dict

	def reorder_cond_dict(self, cond_dict):
	# To make sure the order is correct
	new_cond_dict = {}
	for key in self.conditioning_key:
	new_cond_dict[key] = cond_dict[key]
	return new_cond_dict

	def apply_model(self, x_noisy, t, cond, return_ids=False):
	cond = self.reorder_cond_dict(cond)

	x_recon = self.model(x_noisy, t, cond_dict=cond)

	if isinstance(x_recon, tuple) and not return_ids:
	return x_recon[0]
	else:
	return x_recon

	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
	elif self.parameterization == "v":
	target = self.get_v(x_start, noise, t)
	else:
	raise NotImplementedError()
	# print(model_output.size(), target.size())
	loss_simple = self.get_loss(model_output, target, mean=False).mean([1, 2, 3])
	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=(1, 2, 3))
	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_(-1.0, 1.0)
	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

	@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=1.0,
	noise_dropout=0.0,
	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 > 0.0:
	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))).contiguous()
	)

	# 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=1.0,
	noise_dropout=0.0,
	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 + (1.0 - 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 + (1.0 - 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:
	shape = (batch_size, self.channels, self.latent_t_size, self.latent_f_size)
	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,
	**kwargs,
	)

	def save_waveform(self, waveform, savepath, name="outwav"):
	for i in range(waveform.shape[0]):
	if type(name) is str:
	path = os.path.join(
	savepath, "%s_%s_%s.wav" % (self.global_step, i, name)
	)
	elif type(name) is list:
	path = os.path.join(
	savepath,
	"%s.wav"
	% (
	os.path.basename(name[i])
	if (not ".wav" in name[i])
	else os.path.basename(name[i]).split(".")[0]
	),
	)
	else:
	raise NotImplementedError
	todo_waveform = waveform[i, 0]
	todo_waveform = (
	todo_waveform / np.max(np.abs(todo_waveform))
	) * 0.8 # Normalize the energy of the generation output
	sf.write(path, todo_waveform, samplerate=self.sampling_rate)

	@torch.no_grad()
	def sample_log(
	self,
	cond,
	batch_size,
	ddim,
	ddim_steps,
	unconditional_guidance_scale=1.0,
	unconditional_conditioning=None,
	use_plms=False,
	mask=None,
	**kwargs,
	):
	if mask is not None:
	shape = (self.channels, mask.size()[-2], mask.size()[-1])
	else:
	shape = (self.channels, self.latent_t_size, self.latent_f_size)

	intermediate = None
	if ddim and not use_plms:
	ddim_sampler = DDIMSampler(self, device=self.device)
	samples, intermediates = ddim_sampler.sample(
	ddim_steps,
	batch_size,
	shape,
	cond,
	verbose=False,
	unconditional_guidance_scale=unconditional_guidance_scale,
	unconditional_conditioning=unconditional_conditioning,
	mask=mask,
	**kwargs,
	)
	elif use_plms:
	plms_sampler = PLMSSampler(self)
	samples, intermediates = plms_sampler.sample(
	ddim_steps,
	batch_size,
	shape,
	cond,
	verbose=False,
	unconditional_guidance_scale=unconditional_guidance_scale,
	mask=mask,
	unconditional_conditioning=unconditional_conditioning,
	**kwargs,
	)

	else:
	samples, intermediates = self.sample(
	cond=cond,
	batch_size=batch_size,
	return_intermediates=True,
	unconditional_guidance_scale=unconditional_guidance_scale,
	mask=mask,
	unconditional_conditioning=unconditional_conditioning,
	**kwargs,
	)

	return samples, intermediate

	@torch.no_grad()
	def generate_batch(
	self,
	batch,
	ddim_steps=200,
	ddim_eta=1.0,
	x_T=None,
	n_gen=1,
	unconditional_guidance_scale=1.0,
	unconditional_conditioning=None,
	use_plms=False,
	**kwargs,
	):
	# Generate n_gen times and select the best
	# Batch: audio, text, fnames
	assert x_T is None

	if use_plms:
	assert ddim_steps is not None

	use_ddim = ddim_steps is not None

	# with self.ema_scope("Plotting"):
	for i in range(1):
	z, c = self.get_input(
	batch,
	self.first_stage_key,
	unconditional_prob_cfg=0.0, # Do not output unconditional information in the c
	)
	self.latent_t_size = z.size(-2)

	c = self.filter_useful_cond_dict(c)

	# Generate multiple samples
	batch_size = z.shape[0] * n_gen

	# Generate multiple samples at a time and filter out the best
	# The condition to the diffusion wrapper can have many format
	for cond_key in c.keys():
	if isinstance(c[cond_key], list):
	for i in range(len(c[cond_key])):
	c[cond_key][i] = torch.cat([c[cond_key][i]] * n_gen, dim=0)
	elif isinstance(c[cond_key], dict):
	for k in c[cond_key].keys():
	c[cond_key][k] = torch.cat([c[cond_key][k]] * n_gen, dim=0)
	else:
	c[cond_key] = torch.cat([c[cond_key]] * n_gen, dim=0)

	if unconditional_guidance_scale != 1.0:
	unconditional_conditioning = {}
	for key in self.cond_stage_model_metadata:
	model_idx = self.cond_stage_model_metadata[key]["model_idx"]
	unconditional_conditioning[key] = self.cond_stage_models[
	model_idx
	].get_unconditional_condition(batch_size)

	samples, _ = self.sample_log(
	cond=c,
	batch_size=batch_size,
	x_T=x_T,
	ddim=use_ddim,
	ddim_steps=ddim_steps,
	eta=ddim_eta,
	unconditional_guidance_scale=unconditional_guidance_scale,
	unconditional_conditioning=unconditional_conditioning,
	use_plms=use_plms,
	)

	mel = self.decode_first_stage(samples)

	mel = self.mel_replace_ops(mel, super().get_input(batch, "lowpass_mel"))

	waveform = self.mel_spectrogram_to_waveform(
	mel, savepath="", bs=None, save=False
	)

	waveform_lowpass = super().get_input(batch, "waveform_lowpass")
	waveform = self.postprocessing(waveform, waveform_lowpass)

	max_amp = np.max(np.abs(waveform), axis=-1)
	waveform = 0.5 * waveform / max_amp[..., None]
	mean_amp = np.mean(waveform, axis=-1)[..., None]
	waveform = waveform - mean_amp

	return waveform

	def _locate_cutoff_freq(self, stft, percentile=0.985):
	def _find_cutoff(x, percentile=0.95):
	percentile = x[-1] * percentile
	for i in range(1, x.shape[0]):
	if x[-i] < percentile:
	return x.shape[0] - i
	return 0

	magnitude = torch.abs(stft)
	energy = torch.cumsum(torch.sum(magnitude, dim=0), dim=0)
	return _find_cutoff(energy, percentile)

	def mel_replace_ops(self, samples, input):
	for i in range(samples.size(0)):
	cutoff_melbin = self._locate_cutoff_freq(torch.exp(input[i]))

	# ratio = samples[i][...,:cutoff_melbin]/input[i][...,:cutoff_melbin]
	# print(torch.mean(ratio), torch.max(ratio), torch.min(ratio))

	samples[i][..., :cutoff_melbin] = input[i][..., :cutoff_melbin]
	return samples

	def postprocessing(self, out_batch, x_batch): # x is target
	# Replace the low resolution part with the ground truth
	for i in range(out_batch.shape[0]):
	out = out_batch[i, 0]
	x = x_batch[i, 0].cpu().numpy()
	cutoffratio = self._get_cutoff_index_np(x)

	length = out.shape[0]
	stft_gt = librosa.stft(x)

	stft_out = librosa.stft(out)
	energy_ratio = np.mean(
	np.sum(np.abs(stft_gt[cutoffratio]))
	/ np.sum(np.abs(stft_out[cutoffratio, ...]))
	)
	energy_ratio = min(max(energy_ratio, 0.8), 1.2)
	stft_out[:cutoffratio, ...] = stft_gt[:cutoffratio, ...] / energy_ratio

	out_renewed = librosa.istft(stft_out, length=length)
	out_batch[i] = out_renewed
	return out_batch

	def _find_cutoff_np(self, x, threshold=0.95):
	threshold = x[-1] * threshold
	for i in range(1, x.shape[0]):
	if x[-i] < threshold:
	return x.shape[0] - i
	return 0

	def _get_cutoff_index_np(self, x):
	stft_x = np.abs(librosa.stft(x))
	energy = np.cumsum(np.sum(stft_x, axis=-1))
	return self._find_cutoff_np(energy, 0.985)


	class DiffusionWrapper(nn.Module):
	def __init__(self, diff_model_config, conditioning_key):
	super().__init__()
	self.diffusion_model = instantiate_from_config(diff_model_config)
	self.scale_factor = (
	None # This factor is set in LatentDiffusion for scaling of VAE latent
	)
	self.conditioning_key = conditioning_key

	for key in self.conditioning_key:
	if (
	"concat" in key
	or "crossattn" in key
	or "hybrid" in key
	or "film" in key
	or "noncond" in key
	or "ignore" in key
	):
	continue
	else:
	raise Value("The conditioning key %s is illegal" % key)

	self.being_verbosed_once = False

	def forward(self, x, t, cond_dict: dict = {}):
	x = x.contiguous()
	t = t.contiguous()

	# x with condition (or maybe not)
	xc = x

	y = None
	context_list, attn_mask_list = [], []

	conditional_keys = cond_dict.keys()

	for key in conditional_keys:
	if "ignore" in key:
	continue
	elif "concat" in key:
	cond = cond_dict[key]
	cond = cond * self.scale_factor
	xc = torch.cat([x, cond], dim=1)
	elif "film" in key:
	if y is None:
	y = cond_dict[key].squeeze(1)
	else:
	y = torch.cat([y, cond_dict[key].squeeze(1)], dim=-1)
	elif "crossattn" in key:
	# assert context is None, "You can only have one context matrix, got %s" % (cond_dict.keys())
	if isinstance(cond_dict[key], dict):
	for k in cond_dict[key].keys():
	if "crossattn" in k:
	context, attn_mask = cond_dict[key][
	k
	] # crossattn_audiomae_pooled: torch.Size([12, 128, 768])
	else:
	assert len(cond_dict[key]) == 2, (
	"The context condition for %s you returned should have two element, one context one mask"
	% (key)
	)
	context, attn_mask = cond_dict[key]

	# The input to the UNet model is a list of context matrix
	context_list.append(context)
	attn_mask_list.append(attn_mask)

	elif (
	"noncond" in key
	): # If you use loss function in the conditional module, include the keyword "noncond" in the return dictionary
	continue
	else:
	raise NotImplementedError()

	out = self.diffusion_model(
	xc, t, context_list=context_list, y=y, context_attn_mask_list=attn_mask_list
	)
	return out


	if __name__ == "__main__":
	import yaml

	model_config = "/mnt/fast/nobackup/users/hl01486/projects/general_audio_generation/stable-diffusion/models/ldm/text2img256/config.yaml"
	model_config = yaml.load(open(model_config, "r"), Loader=yaml.FullLoader)

	latent_diffusion = LatentDiffusion(**model_config["model"]["params"])

	import ipdb

	ipdb.set_trace()