train_stacked_cond_laion.py

#!/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 torch.nn.parameter import Parameter
from tqdm import trange
import pytorch_lightning as pl
from pytorch_lightning.utilities.distributed import rank_zero_only
from einops import rearrange
import numpy as np
import torchaudio
import random

import wandb

from diffusion.pqmf import CachedPQMF as PQMF
from autoencoders.soundstream import SoundStreamXLEncoder, SoundStreamXLDecoder
from autoencoders.models import AudioAutoencoder
from audio_encoders_pytorch import Encoder1d
from ema_pytorch import EMA
from blocks.utils import InverseLR
from audio_diffusion_pytorch import UNetConditional1d, T5Embedder, NumberEmbedder
from torchaudio import transforms as T

from decoders.diffusion_decoder import DiffusionAttnUnet1D
from diffusion.model import ema_update
from aeiou.viz import embeddings_table, pca_point_cloud, audio_spectrogram_image, tokens_spectrogram_image
#from aeiou.datasets import HybridAudioDataset, get_all_s3_urls, PadCrop, Stereo, PhaseFlipper
from dataset.dataset import get_laion_630k_loader, get_wds_loader

# 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 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, **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 (v, the predicted velocity)
        with torch.cuda.amp.autocast():
            v = model(x, ts * t[i], **extra_args).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

def unwrap_text(str_or_tuple):
    if type(str_or_tuple) is tuple:
        return random.choice(str_or_tuple)
    elif type(str_or_tuple) is str:
        return str_or_tuple

class LatentAudioDiffusionAutoencoder(pl.LightningModule):
    def __init__(self, autoencoder: AudioAutoencoder):
        super().__init__()

        
        self.latent_dim = autoencoder.latent_dim
                
        self.second_stage_latent_dim = 32

        factors = [2, 2, 2, 2]

        self.latent_downsampling_ratio = np.prod(factors)
        
        self.downsampling_ratio = autoencoder.downsampling_ratio * self.latent_downsampling_ratio

        self.latent_encoder = Encoder1d(
            in_channels=self.latent_dim, 
            out_channels = self.second_stage_latent_dim,
            channels = 128,
            multipliers = [1, 2, 4, 8, 8],
            factors =  factors,
            num_blocks = [8, 8, 8, 8],
        )

        self.latent_encoder_ema = deepcopy(self.latent_encoder)

        self.diffusion = DiffusionAttnUnet1D(
            io_channels=self.latent_dim, 
            cond_dim = self.second_stage_latent_dim,
            n_attn_layers=0, 
            c_mults=[512] * 10,
            depth=10
        )

        self.diffusion_ema = deepcopy(self.diffusion)

        self.diffusion_ema.requires_grad_(False)
        self.latent_encoder_ema.requires_grad_(False)

        self.autoencoder = autoencoder

        self.autoencoder.requires_grad_(False)
        
        self.rng = torch.quasirandom.SobolEngine(1, scramble=True)

    def encode(self, reals):
        first_stage_latents = self.autoencoder.encode(reals)

        second_stage_latents = self.latent_encoder(first_stage_latents)

        second_stage_latents = torch.tanh(second_stage_latents)

        return second_stage_latents

    def decode(self, latents, steps=100, device="cuda"):
        first_stage_latent_noise = torch.randn([latents.shape[0], self.latent_dim, latents.shape[2]*self.latent_downsampling_ratio]).to(device)

        first_stage_sampled = sample(self.diffusion, first_stage_latent_noise, steps, 0, cond=latents)
        first_stage_sampled = first_stage_sampled.clamp(-1, 1)
        decoded = self.autoencoder.decode(first_stage_sampled)
        return decoded

class StackedAELatentDiffusionCond(pl.LightningModule):
    def __init__(self, latent_ae: LatentAudioDiffusionAutoencoder):
        super().__init__()

        self.latent_dim = latent_ae.second_stage_latent_dim
        self.downsampling_ratio = latent_ae.downsampling_ratio

        embedding_max_len = 128

        self.embedder = T5Embedder(model='t5-base', max_length=embedding_max_len).requires_grad_(False)

        self.embedding_features = 768

        self.diffusion = UNetConditional1d(
            in_channels = self.latent_dim, 
            context_embedding_features = self.embedding_features,
            context_embedding_max_length = embedding_max_len + 2, #2 for timestep embeds
            channels = 256,
            patch_blocks = 1,
            patch_factor = 1,
            resnet_groups = 8,
            kernel_multiplier_downsample = 2,
            multipliers = [2, 2, 2, 4, 4, 4],
            factors = [2, 2, 2, 4, 4],
            num_blocks = [3, 3, 3, 4, 4],
            attentions = [2, 2, 2, 2, 2, 2],
            attention_heads = 16,
            attention_features = 64,
            attention_multiplier = 4,
            attention_use_rel_pos=False,
            use_nearest_upsample = False,
            use_skip_scale = True,
            use_context_time = True,
            use_magnitude_channels = False
        )

        # with torch.no_grad():
        #     for param in self.diffusion.parameters():
        #         param *= 0.5

        self.diffusion_ema = EMA(
            self.diffusion,
            beta = 0.9999,
            power=3/4,
            update_every = 1,
            update_after_step = 1
        )

        self.autoencoder = latent_ae

        self.autoencoder.requires_grad_(False)
        
        self.rng = torch.quasirandom.SobolEngine(1, scramble=True)

    def encode(self, reals):
        return self.autoencoder.encode(reals)

    def decode(self, latents, steps=100):
        return self.autoencoder.decode(latents, steps, device=self.device)

    def configure_optimizers(self):
        optimizer = optim.Adam([*self.diffusion.parameters()], lr=1e-4)

        scheduler = optim.lr_scheduler.CosineAnnealingLR(optimizer, T_max=500, eta_min=1e-6)

        return [optimizer], [scheduler]

    def training_step(self, batch, batch_idx):
        reals, jsons, timestamps = batch
        reals = reals[0]
        
        condition_string = [unwrap_text(json["text"][0]) for json in jsons]

        #timestamps = [[timestamp[0].item(), timestamp[1].item()] for timestamp in timestamps]

        #print(condition_string)
        #print(timestamps)

        #timestamp_embeddings = self.timestamp_embedder(timestamps)

        with torch.cuda.amp.autocast():
            with torch.no_grad():
                latents = self.encode(reals)
                text_embeddings = self.embedder(condition_string)
                

        embeddings = text_embeddings #torch.cat([text_embeddings, timestamp_embeddings], dim=1)

        # 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(latents)
        noised_latents = latents * alphas + noise * sigmas
        targets = noise * alphas - latents * sigmas

        with torch.cuda.amp.autocast():
            # 0.1 CFG dropout
            v = self.diffusion(noised_latents, t, embedding=embeddings, embedding_mask_proba = 0.1)
            mse_loss = F.mse_loss(v, targets)
            loss = mse_loss

        log_dict = {
            'train/loss': loss.detach(),
            'train/mse_loss': mse_loss.detach(),
            'train/lr': self.lr_schedulers().get_last_lr()[0]
        }

        self.log_dict(log_dict, prog_bar=True, on_step=True)
        return loss

    def on_before_zero_grad(self, *args, **kwargs):
        self.diffusion_ema.update()

class ExceptionCallback(pl.Callback):
    def on_exception(self, trainer, module, err):
        print(f'{type(err).__name__}: {err}')


class DemoCallback(pl.Callback):
    def __init__(self, global_args):
        super().__init__()
        self.demo_every = global_args.demo_every
        self.demo_samples = global_args.sample_size
        self.demo_steps = global_args.demo_steps
        self.num_demos = global_args.num_demos
        self.sample_rate = global_args.sample_rate

    @rank_zero_only
    @torch.no_grad()
    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
        
        print("Starting demo")
        try:
            latent_noise = torch.randn([8, module.latent_dim, self.demo_samples//module.downsampling_ratio]).to(module.device)

            text_embeddings = module.embedder([
                "",
                "",
                "",
                "",
                "",
                "",
                "",
                "",
            ])

            embeddings = text_embeddings # torch.cat([text_embeddings, timestamp_embeddings], dim=1)

            demo_cfg_scales = [3, 5, 7]

            for cfg_scale in demo_cfg_scales:
                print(f"Generating latents, CFG scale {cfg_scale}")
                fake_latents = sample(module.diffusion_ema, latent_noise, self.demo_steps, 0, embedding=embeddings, embedding_scale=cfg_scale)
                
                fake_latents = fake_latents.clamp(-1, 1)

                print(f"Decoding latents, shape: {fake_latents.shape}")
                fakes = module.decode(fake_latents, steps=100)

                print("Rearranging demos")
                # Put the demos together
                fakes = rearrange(fakes, 'b d n -> d (b n)')

                log_dict = {}
                
                print("Saving files")
                filename = f'demo_{trainer.global_step:08}_cfg_{cfg_scale}.wav'
                fakes = fakes.clamp(-1, 1).mul(32767).to(torch.int16).cpu()
                torchaudio.save(filename, fakes, self.sample_rate)


                log_dict[f'demo_cfg_{cfg_scale}'] = wandb.Audio(filename,
                                                    sample_rate=self.sample_rate,
                                                    caption=f'Demo CFG {cfg_scale}')
            
                log_dict[f'demo_melspec_left_{cfg_scale}'] = wandb.Image(audio_spectrogram_image(fakes))

                log_dict[f'embeddings_3dpca_{cfg_scale}'] = pca_point_cloud(fake_latents)
                log_dict[f'embeddings_spec_{cfg_scale}'] = wandb.Image(tokens_spectrogram_image(fake_latents))

            
                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()

    device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
    print('Using device:', device)
    torch.manual_seed(args.seed)
  
    names = []

    train_dl = get_wds_loader(
        batch_size=args.batch_size, 
        s3_url_prefix="s3://s-laion-audio/webdataset_tar/", 
        sample_size=args.sample_size, 
        names=names, 
        sample_rate=args.sample_rate, 
        num_workers=args.num_workers, 
        recursive=True,
        random_crop=True,
        epoch_steps=1000
    )
                                 
    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)

    first_stage_config = {"capacity": 64, "c_mults": [2, 4, 8, 16, 32], "strides": [2, 2, 2, 2, 2], "latent_dim": 32}

    first_stage_autoencoder = AudioAutoencoder( 
        **first_stage_config
    ).eval()

    latent_diffae = LatentAudioDiffusionAutoencoder.load_from_checkpoint(args.pretrained_ckpt_path, autoencoder=first_stage_autoencoder, strict=False)

    latent_diffae.diffusion = latent_diffae.diffusion_ema
    del latent_diffae.diffusion_ema

    latent_diffae.latent_encoder = latent_diffae.latent_encoder_ema
    del latent_diffae.latent_encoder_ema

    if args.ckpt_path:
        latent_diffusion_model = StackedAELatentDiffusionCond.load_from_checkpoint(args.ckpt_path, latent_ae=latent_diffae, strict=False)
    else:
        latent_diffusion_model = StackedAELatentDiffusionCond(latent_diffae)

    wandb_logger.watch(latent_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_find_unused_parameters_false',
        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,
        default_root_dir=args.save_dir
    )

    diffusion_trainer.fit(latent_diffusion_model, train_dl)

if __name__ == '__main__':
    main()