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train_uncond_denoiser.py
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train_uncond_denoiser.py
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#!/usr/bin/env python3
from prefigure.prefigure import get_all_args, push_wandb_config
from contextlib import contextmanager
from copy import deepcopy
import math
from pathlib import Path
import sys
import torch
from torch import optim, nn
from torch.nn import functional as F
from torch.utils import data
from tqdm import trange
import pytorch_lightning as pl
from pytorch_lightning.utilities.distributed import rank_zero_only
from einops import rearrange
from diffusion.pqmf import CachedPQMF as PQMF
import torchaudio
import auraloss
import wandb
from aeiou.datasets import AudioDataset
from dataset.dataset import SampleDataset
from decoders.diffusion_decoder import DiffusionAttnUnet1D
from diffusion.model import ema_update
from viz.viz import embeddings_table, pca_point_cloud, audio_spectrogram_image, tokens_spectrogram_image
# Define the noise schedule and sampling loop
def get_alphas_sigmas(t):
"""Returns the scaling factors for the clean image (alpha) and for the
noise (sigma), given a timestep."""
return torch.cos(t * math.pi / 2), torch.sin(t * math.pi / 2)
def get_crash_schedule(t):
sigma = torch.sin(t * math.pi / 2) ** 2
alpha = (1 - sigma ** 2) ** 0.5
return alpha_sigma_to_t(alpha, sigma)
def alpha_sigma_to_t(alpha, sigma):
"""Returns a timestep, given the scaling factors for the clean image and for
the noise."""
return torch.atan2(sigma, alpha) / math.pi * 2
@torch.no_grad()
def sample(model, x, steps, eta):
"""Draws samples from a model given starting noise."""
ts = x.new_ones([x.shape[0]])
# Create the noise schedule
t = torch.linspace(1, 0, steps + 1)[:-1]
t = get_crash_schedule(t)
alphas, sigmas = get_alphas_sigmas(t)
# The sampling loop
for i in trange(steps):
# Get the model output (v, the predicted velocity)
with torch.cuda.amp.autocast():
v = model(x, ts * t[i]).float()
# Predict the noise and the denoised image
pred = x * alphas[i] - v * sigmas[i]
eps = x * sigmas[i] + v * alphas[i]
# If we are not on the last timestep, compute the noisy image for the
# next timestep.
if i < steps - 1:
# If eta > 0, adjust the scaling factor for the predicted noise
# downward according to the amount of additional noise to add
ddim_sigma = eta * (sigmas[i + 1]**2 / sigmas[i]**2).sqrt() * \
(1 - alphas[i]**2 / alphas[i + 1]**2).sqrt()
adjusted_sigma = (sigmas[i + 1]**2 - ddim_sigma**2).sqrt()
# Recombine the predicted noise and predicted denoised image in the
# correct proportions for the next step
x = pred * alphas[i + 1] + eps * adjusted_sigma
# Add the correct amount of fresh noise
if eta:
x += torch.randn_like(x) * ddim_sigma
# If we are on the last timestep, output the denoised image
return pred
@torch.no_grad()
def sample_pred(model, x, steps, **extra_args):
"""Draws samples from a model given starting noise."""
ts = x.new_ones([x.shape[0]])
# Create the noise schedule
t = torch.linspace(1, 0, steps + 1)[:-1]
alphas, sigmas = get_alphas_sigmas(t)
# The sampling loop
for i in trange(steps):
# Get the model output (pred, the predicted denoised audio)
with torch.cuda.amp.autocast():
pred = model(x, ts * t[i], **extra_args).float()
# Predict the noise and the denoised audio
#pred = x * alphas[i] - v * sigmas[i]
eps = x - pred
# If we are not on the last timestep, compute the noisy audio for the
# next timestep.
if i < steps - 1:
# Recombine the predicted noise and predicted denoised audio in the
# correct proportions for the next step
x = pred * alphas[i + 1] + eps * sigmas[i + 1]
# If we are on the last timestep, output the denoised audio
return pred
class DiffusionUncond(pl.LightningModule):
def __init__(self, global_args):
super().__init__()
#self.diffusion = DiffusionAttnUnet1D(io_channels=2, pqmf_bands=global_args.pqmf_bands, n_attn_layers=4)
self.diffusion = DiffusionAttnUnet1D(
io_channels=2,
n_attn_layers=0,
depth=6,
c_mults=[128, 128, 128, 256, 512, 512],
learned_resample=True,
strides=[2, 2, 4, 4, 4, 8],
kernel_size=3
)
scales = [2048, 1024, 512, 256, 128]
hop_sizes = []
win_lengths = []
overlap = 0.75
for s in scales:
hop_sizes.append(int(s * (1 - overlap)))
win_lengths.append(s)
self.sdstft = auraloss.freq.SumAndDifferenceSTFTLoss(fft_sizes=scales, hop_sizes=hop_sizes, win_lengths=win_lengths, sample_rate=global_args.sample_rate, perceptual_weighting=True)
self.diffusion_ema = deepcopy(self.diffusion)
self.rng = torch.quasirandom.SobolEngine(1, scramble=True, seed=global_args.seed)
self.ema_decay = global_args.ema_decay
def configure_optimizers(self):
return optim.Adam([*self.diffusion.parameters()], lr=4e-5)
def training_step(self, batch, batch_idx):
reals = batch
# Draw uniformly distributed continuous timesteps
t = self.rng.draw(reals.shape[0])[:, 0].to(self.device)
# Calculate the noise schedule parameters for those timesteps
alphas, sigmas = get_alphas_sigmas(t)
# Combine the ground truth images and the noise
alphas = alphas[:, None, None]
sigmas = sigmas[:, None, None]
noise = torch.randn_like(reals)
noised_reals = reals * alphas + noise * sigmas
targets = reals # noise * alphas - reals * sigmas
target_v = noise * alphas - reals * sigmas
with torch.cuda.amp.autocast():
denoised = self.diffusion(noised_reals, t)
v = noise * alphas - denoised * sigmas
mse_loss = F.mse_loss(v, target_v)
stft_loss = self.sdstft(denoised, targets)
loss = stft_loss + mse_loss
log_dict = {
'train/loss': loss.detach(),
'train/stft_loss': stft_loss.detach(),
'train/mse_loss': mse_loss.detach(),
}
self.log_dict(log_dict, prog_bar=True, on_step=True)
return loss
def on_before_zero_grad(self, *args, **kwargs):
decay = 0.95 if self.current_epoch < 25 else self.ema_decay
ema_update(self.diffusion, self.diffusion_ema, decay)
class ExceptionCallback(pl.Callback):
def on_exception(self, trainer, module, err):
print(f'{type(err).__name__}: {err}', file=sys.stderr)
class DemoCallback(pl.Callback):
def __init__(self, global_args):
super().__init__()
self.demo_every = global_args.demo_every
self.num_demos = global_args.num_demos
self.demo_samples = global_args.sample_size
self.demo_steps = global_args.demo_steps
self.sample_rate = global_args.sample_rate
@rank_zero_only
@torch.no_grad()
#def on_train_epoch_end(self, trainer, module):
def on_train_batch_end(self, trainer, module, outputs, batch, batch_idx):
last_demo_step = -1
if (trainer.global_step - 1) % self.demo_every != 0 or last_demo_step == trainer.global_step:
#if trainer.current_epoch % self.demo_every != 0:
return
last_demo_step = trainer.global_step
noise = torch.randn([self.num_demos, 2, self.demo_samples]).to(module.device)
try:
fakes = sample_pred(module.diffusion_ema, noise, self.demo_steps)
# Put the demos together
fakes = rearrange(fakes, 'b d n -> d (b n)')
log_dict = {}
filename = f'demo_{trainer.global_step:08}.wav'
fakes = fakes.clamp(-1, 1).mul(32767).to(torch.int16).cpu()
torchaudio.save(filename, fakes, self.sample_rate)
log_dict[f'demo'] = wandb.Audio(filename,
sample_rate=self.sample_rate,
caption=f'Reconstructed')
log_dict[f'demo_melspec_left'] = wandb.Image(audio_spectrogram_image(fakes))
trainer.logger.experiment.log(log_dict, step=trainer.global_step)
except Exception as e:
print(f'{type(e).__name__}: {e}')
def main():
args = get_all_args()
args.latent_dim = 0
#args.random_crop = False
device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
print('Using device:', device)
torch.manual_seed(args.seed)
train_set = AudioDataset(
[args.training_dir],
sample_rate=args.sample_rate,
sample_size=args.sample_size,
random_crop=args.random_crop,
augs='Stereo(), PhaseFlipper()'
)
#train_set = SampleDataset([args.training_dir], args, keywords=["kick", "snare", "clap", "snap", "hat", "cymbal", "crash", "ride"])
train_dl = data.DataLoader(train_set, args.batch_size, shuffle=True,
num_workers=args.num_workers, persistent_workers=True, pin_memory=True, drop_last=True)
wandb_logger = pl.loggers.WandbLogger(project=args.name)
exc_callback = ExceptionCallback()
ckpt_callback = pl.callbacks.ModelCheckpoint(every_n_train_steps=args.checkpoint_every, save_top_k=-1)
demo_callback = DemoCallback(args)
diffusion_model = DiffusionUncond(args)
wandb_logger.watch(diffusion_model)
push_wandb_config(wandb_logger, args)
diffusion_trainer = pl.Trainer(
devices=args.num_gpus,
accelerator="gpu",
num_nodes = args.num_nodes,
strategy='ddp',
precision=16,
accumulate_grad_batches=args.accum_batches,
callbacks=[ckpt_callback, demo_callback, exc_callback],
logger=wandb_logger,
log_every_n_steps=1,
max_epochs=10000000,
)
diffusion_trainer.fit(diffusion_model, train_dl, ckpt_path=args.ckpt_path)
if __name__ == '__main__':
main()