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MusicGen / audiocraft /models /multibanddiffusion.py

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	# Copyright (c) Meta Platforms, Inc. and affiliates.
	# All rights reserved.
	#
	# This source code is licensed under the license found in the
	# LICENSE file in the root directory of this source tree.

	"""
	Multi Band Diffusion models as described in
	"From Discrete Tokens to High-Fidelity Audio Using Multi-Band Diffusion"
	(paper link).
	"""

	import typing as tp

	import torch
	import julius

	from .unet import DiffusionUnet
	from ..modules.diffusion_schedule import NoiseSchedule
	from .encodec import CompressionModel
	from ..solvers.compression import CompressionSolver
	from .loaders import load_compression_model, load_diffusion_models


	class DiffusionProcess:
	"""Sampling for a diffusion Model.

	Args:
	model (DiffusionUnet): Diffusion U-Net model.
	noise_schedule (NoiseSchedule): Noise schedule for diffusion process.
	"""
	def __init__(self, model: DiffusionUnet, noise_schedule: NoiseSchedule) -> None:
	"""
	"""
	self.model = model
	self.schedule = noise_schedule

	def generate(self, condition: torch.Tensor, initial_noise: torch.Tensor,
	step_list: tp.Optional[tp.List[int]] = None):
	"""Perform one diffusion process to generate one of the bands.

	Args:
	condition (tensor): The embeddings form the compression model.
	initial_noise (tensor): The initial noise to start the process/
	"""
	return self.schedule.generate_subsampled(model=self.model, initial=initial_noise, step_list=step_list,
	condition=condition)


	class MultiBandDiffusion:
	"""Sample from multiple diffusion models.

	Args:
	DPs (list of DiffusionProcess): Diffusion processes.
	codec_model (CompressionModel): Underlying compression model used to obtain discrete tokens.
	"""
	def __init__(self, DPs: tp.List[DiffusionProcess], codec_model: CompressionModel) -> None:
	self.DPs = DPs
	self.codec_model = codec_model
	self.device = next(self.codec_model.parameters()).device

	@property
	def sample_rate(self) -> int:
	return self.codec_model.sample_rate

	@staticmethod
	def get_mbd_musicgen(device=None):
	"""Load our diffusion models trained for MusicGen."""
	if device is None:
	device = 'cuda' if torch.cuda.is_available() else 'cpu'
	path = 'facebook/multiband-diffusion'
	filename = 'mbd_musicgen_32khz.th'
	name = 'facebook/musicgen-small'
	codec_model = load_compression_model(name, device=device)
	models, processors, cfgs = load_diffusion_models(path, filename=filename, device=device)
	DPs = []
	for i in range(len(models)):
	schedule = NoiseSchedule(**cfgs[i].schedule, sample_processor=processors[i], device=device)
	DPs.append(DiffusionProcess(model=models[i], noise_schedule=schedule))
	return MultiBandDiffusion(DPs=DPs, codec_model=codec_model)

	@staticmethod
	def get_mbd_24khz(bw: float = 3.0, pretrained: bool = True,
	device: tp.Optional[tp.Union[torch.device, str]] = None,
	n_q: tp.Optional[int] = None):
	"""Get the pretrained Models for MultibandDiffusion.

	Args:
	bw (float): Bandwidth of the compression model.
	pretrained (bool): Whether to use / download if necessary the models.
	device (torch.device or str, optional): Device on which the models are loaded.
	n_q (int, optional): Number of quantizers to use within the compression model.
	"""
	if device is None:
	device = 'cuda' if torch.cuda.is_available() else 'cpu'
	assert bw in [1.5, 3.0, 6.0], f"bandwidth {bw} not available"
	if n_q is not None:
	assert n_q in [2, 4, 8]
	assert {1.5: 2, 3.0: 4, 6.0: 8}[bw] == n_q, \
	f"bandwidth and number of codebooks missmatch to use n_q = {n_q} bw should be {n_q * (1.5 / 2)}"
	n_q = {1.5: 2, 3.0: 4, 6.0: 8}[bw]
	codec_model = CompressionSolver.model_from_checkpoint(
	'//pretrained/facebook/encodec_24khz', device=device)
	codec_model.set_num_codebooks(n_q)
	codec_model = codec_model.to(device)
	path = 'facebook/multiband-diffusion'
	filename = f'mbd_comp_{n_q}.pt'
	models, processors, cfgs = load_diffusion_models(path, filename=filename, device=device)
	DPs = []
	for i in range(len(models)):
	schedule = NoiseSchedule(**cfgs[i].schedule, sample_processor=processors[i], device=device)
	DPs.append(DiffusionProcess(model=models[i], noise_schedule=schedule))
	return MultiBandDiffusion(DPs=DPs, codec_model=codec_model)

	return MultiBandDiffusion(DPs, codec_model)

	@torch.no_grad()
	def get_condition(self, wav: torch.Tensor, sample_rate: int) -> torch.Tensor:
	"""Get the conditioning (i.e. latent reprentatios of the compression model) from a waveform.
	Args:
	wav (torch.Tensor): The audio that we want to extract the conditioning from
	sample_rate (int): sample rate of the audio"""
	if sample_rate != self.sample_rate:
	wav = julius.resample_frac(wav, sample_rate, self.sample_rate)
	codes, scale = self.codec_model.encode(wav)
	assert scale is None, "Scaled compression models not supported."
	emb = self.get_emb(codes)
	return emb

	@torch.no_grad()
	def get_emb(self, codes: torch.Tensor):
	"""Get latent representation from the discrete codes
	Argrs:
	codes (torch.Tensor): discrete tokens"""
	emb = self.codec_model.decode_latent(codes)
	return emb

	def generate(self, emb: torch.Tensor, size: tp.Optional[torch.Size] = None,
	step_list: tp.Optional[tp.List[int]] = None):
	"""Generate Wavform audio from the latent embeddings of the compression model
	Args:
	emb (torch.Tensor): Conditioning embeddinds
	size (none torch.Size): size of the output
	if None this is computed from the typical upsampling of the model
	step_list (optional list[int]): list of Markov chain steps, defaults to 50 linearly spaced step.
	"""
	if size is None:
	upsampling = int(self.codec_model.sample_rate / self.codec_model.frame_rate)
	size = torch.Size([emb.size(0), self.codec_model.channels, emb.size(-1) * upsampling])
	assert size[0] == emb.size(0)
	out = torch.zeros(size).to(self.device)
	for DP in self.DPs:
	out += DP.generate(condition=emb, step_list=step_list, initial_noise=torch.randn_like(out))
	return out

	def re_eq(self, wav: torch.Tensor, ref: torch.Tensor, n_bands: int = 32, strictness: float = 1):
	"""match the eq to the encodec output by matching the standard deviation of some frequency bands
	Args:
	wav (torch.Tensor): audio to equalize
	ref (torch.Tensor):refenrence audio from which we match the spectrogram.
	n_bands (int): number of bands of the eq
	strictness (float): how strict the the matching. 0 is no matching, 1 is exact matching.
	"""
	split = julius.SplitBands(n_bands=n_bands, sample_rate=self.codec_model.sample_rate).to(wav.device)
	bands = split(wav)
	bands_ref = split(ref)
	out = torch.zeros_like(ref)
	for i in range(n_bands):
	out += bands[i] * (bands_ref[i].std() / bands[i].std()) ** strictness
	return out

	def regenerate(self, wav: torch.Tensor, sample_rate: int):
	"""Regenerate a wavform through compression and diffusion regeneration.
	Args:
	wav (torch.Tensor): Original 'ground truth' audio
	sample_rate (int): sample rate of the input (and output) wav
	"""
	if sample_rate != self.codec_model.sample_rate:
	wav = julius.resample_frac(wav, sample_rate, self.codec_model.sample_rate)
	emb = self.get_condition(wav, sample_rate=self.codec_model.sample_rate)
	size = wav.size()
	out = self.generate(emb, size=size)
	if sample_rate != self.codec_model.sample_rate:
	out = julius.resample_frac(out, self.codec_model.sample_rate, sample_rate)
	return out

	def tokens_to_wav(self, tokens: torch.Tensor, n_bands: int = 32):
	"""Generate Waveform audio with diffusion from the discrete codes.
	Args:
	tokens (torch.Tensor): discrete codes
	n_bands (int): bands for the eq matching.
	"""
	wav_encodec = self.codec_model.decode(tokens)
	condition = self.get_emb(tokens)
	wav_diffusion = self.generate(emb=condition, size=wav_encodec.size())
	return self.re_eq(wav=wav_diffusion, ref=wav_encodec, n_bands=n_bands)