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generate_clap_seconds.py
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generate_clap_seconds.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, os
import random
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 wandb
import k_diffusion as K
from autoencoders.models import AudioAutoencoder
from audio_encoders_pytorch import Encoder1d
from ema_pytorch import EMA
from audio_diffusion_pytorch import NumberEmbedder
from audio_diffusion_pytorch.modules import UNetCFG1d
import laion_clap
from decoders.diffusion_decoder import DiffusionAttnUnet1D
# 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
def sample_v_ddim(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 sample(model_fn, noise, steps=100, sampler_type="v-iplms", device="cuda", **extra_args):
#Check for k-diffusion
if sampler_type.startswith('k-'):
denoiser = K.external.VDenoiser(model_fn)
sigmas = K.sampling.get_sigmas_vp(steps, device=device)
elif sampler_type.startswith("v-"):
t = torch.linspace(1, 0, steps + 1, device=device)[:-1]
step_list = get_crash_schedule(t)
# if sampler_type == "v-ddim":
# return sample_v_ddim(model_fn, noise, step_list, eta, {})
# elif sampler_type == "v-iplms":
# return sampling.iplms_sample(model_fn, noise, step_list, {})
elif sampler_type == "k-heun":
return K.sampling.sample_heun(denoiser, noise, sigmas, disable=False, extra_args=extra_args)
elif sampler_type == "k-lms":
return K.sampling.sample_lms(denoiser, noise, sigmas, disable=False, extra_args=extra_args)
elif sampler_type == "k-dpmpp_2s_ancestral":
return K.sampling.sample_dpmpp_2s_ancestral(denoiser, noise, sigmas, disable=False, extra_args=extra_args)
elif sampler_type == "k-dpm-2":
return K.sampling.sample_dpm_2(denoiser, noise, sigmas, disable=False, extra_args=extra_args)
elif sampler_type == "k-dpm-fast":
return K.sampling.sample_dpm_fast(denoiser, noise, sigma_min, sigma_max, steps, disable=False, extra_args=extra_args)
elif sampler_type == "k-dpm-adaptive":
return K.sampling.sample_dpm_adaptive(denoiser, noise, sigma_min, sigma_max, rtol=rtol, atol=atol, disable=False)
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.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.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_v_ddim(self.diffusion, first_stage_latent_noise, steps, 0, cond=latents)
denoiser = K.external.VDenoiser(self.diffusion)
sigma_max=50
sigma_min=0.11
sigmas = K.sampling.get_sigmas_polyexponential(steps, sigma_min, sigma_max, device=device)
first_stage_latent_noise = first_stage_latent_noise * sigmas[0]
first_stage_sampled = K.sampling.sample_dpmpp_2m(denoiser, first_stage_latent_noise, sigmas, extra_args=dict(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, clap_model):
super().__init__()
self.latent_dim = latent_ae.second_stage_latent_dim
self.downsampling_ratio = latent_ae.downsampling_ratio
embedding_max_len = 1
self.embedder = clap_model
self.embedding_features = 512
self.max_seconds = 512
self.second_start_embedder = nn.Embedding(self.max_seconds + 1, self.embedding_features)
self.second_total_embedder = nn.Embedding(self.max_seconds + 1, self.embedding_features)
self.timestamp_start_embedder = NumberEmbedder(features=self.embedding_features)
self.diffusion = UNetCFG1d(
in_channels = self.latent_dim,
context_embedding_features = self.embedding_features,
context_embedding_max_length = embedding_max_len + 3, #3 for timing embeds
channels = 256,
resnet_groups = 8,
kernel_multiplier_downsample = 2,
multipliers = [2, 3, 4, 4, 4, 5],
factors = [1, 2, 2, 4, 4],
num_blocks = [3, 3, 3, 3, 3],
attentions = [0, 0, 2, 2, 2, 2],
attention_heads = 16,
attention_features = 64,
attention_multiplier = 4,
attention_use_rel_pos=True,
attention_rel_pos_max_distance=2048,
attention_rel_pos_num_buckets=256,
use_nearest_upsample = False,
use_skip_scale = True,
use_context_time = True,
)
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)
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 get_timing_embeddings(self, seconds_starts_totals):
seconds_starts_totals = torch.tensor(seconds_starts_totals).to(self.device)
seconds_starts_totals = seconds_starts_totals.clamp(0, self.max_seconds)
seconds_starts_totals = seconds_starts_totals.transpose(0, 1)
second_starts = seconds_starts_totals[0]
second_totals = seconds_starts_totals[1]
second_starts_embeds = self.second_start_embedder(second_starts).unsqueeze(1)
second_totals_embeds = self.second_total_embedder(second_totals).unsqueeze(1)
#Divide second_starts by second_totals to get t_starts, make sure it's cast to a float
t_starts = second_starts / second_totals.float()
t_starts_embeds = self.timestamp_start_embedder(t_starts).unsqueeze(1)
return second_starts_embeds, second_totals_embeds, t_starts_embeds
def generate_audio(prompt, args, latent_diffusion_model, second_start=0, seconds_total=220):
device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
prompts = [prompt] * args.batch_size
text_embeddings = latent_diffusion_model.embedder.get_text_embedding(prompts)
text_embeddings = torch.from_numpy(text_embeddings).unsqueeze(1).to(device)
latent_noise = torch.randn([len(text_embeddings), latent_diffusion_model.latent_dim, args.sample_size//latent_diffusion_model.downsampling_ratio]).to(device)
timing_embeddings = latent_diffusion_model.get_timing_embeddings([[second_start, seconds_total]] * args.batch_size)
embeddings = torch.cat([text_embeddings, *timing_embeddings], dim=1)
cfg_scale = args.cfg_scale
print(f"Generating latents, CFG scale {cfg_scale}")
#fake_latents = sample_v_ddim(latent_diffusion_model.diffusion_ema, latent_noise, args.gen_steps, args.eta, embedding=embeddings, embedding_scale=cfg_scale)
model_fn = latent_diffusion_model.diffusion_ema
sigma_max = 50
sigma_min = 0.014
denoiser = K.external.VDenoiser(model_fn)
sigmas = K.sampling.get_sigmas_polyexponential(args.gen_steps, sigma_min, sigma_max, device=device)
latent_noise = latent_noise * sigmas[0]
fake_latents = K.sampling.sample_dpmpp_2s_ancestral(denoiser, latent_noise, sigmas, eta=args.eta, extra_args=dict(embedding=embeddings, embedding_scale=cfg_scale))
fake_latents = fake_latents.clamp(-1, 1)
print(f"Decoding latents, shape: {fake_latents.shape}")
fakes = latent_diffusion_model.decode(fake_latents, steps=args.decoder_steps)
print("Rearranging demos")
# Put the demos together
fakes = rearrange(fakes, 'b d n -> d (b n)')
# Turn down the outputs
fakes = fakes * 0.66
log_dict = {}
print("Saving files")
if not os.path.exists(args.save_dir):
os.makedirs(args.save_dir)
prompt_filename = prompt.replace("/", "_")
filename = os.path.join(args.save_dir, f"{prompt_filename}.wav")
# check if file already exists, add an incrementing number to the end to avoid duplicates
if os.path.isfile(filename):
i = 1
while True:
new_filename = os.path.join(args.save_dir, f"{prompt_filename}_{i}.wav")
if os.path.isfile(new_filename):
i += 1
else:
filename = new_filename
break
fakes = fakes.clamp(-1, 1).mul(32767).to(torch.int16).cpu()
torchaudio.save(filename, fakes, args.sample_rate)
def encode_decode_file(latent_diffusion_model, input_file, save_dir):
device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
print('Using device:', device)
audio, sample_rate = torchaudio.load(input_file)
# Resample audio to 48 kHz
resample_transform = torchaudio.transforms.Resample(orig_freq=sample_rate, new_freq=48000)
audio = resample_transform(audio)
audio = audio.to(device)
# Pad audio with zeros to nearest multiple of 32768
audio_len = audio.size(-1)
pad_len = 32768 - audio_len % 32768
if pad_len != 32768:
audio = torch.nn.functional.pad(audio, (0, pad_len))
print(f"Padded audio with {pad_len} zeros")
# Encode the audio
encoded = latent_diffusion_model.autoencoder.encode(audio.unsqueeze(0))
# Decode the encoded audio
decoded = latent_diffusion_model.autoencoder.decode(encoded, steps=100, device=device)
# Save the reconstructed audio
output_file = os.path.join(save_dir, os.path.basename(os.path.splitext(input_file)[0]) + '_reconstructed.wav')
torchaudio.save(output_file, decoded.squeeze(0).cpu(), 48000)
print(f"Reconstructed audio saved to {output_file}")
def main():
args = get_all_args()
device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
print('Using device:', device)
seed = args.seed
if seed == -1:
seed = random.randint(0, sys.maxsize)
torch.manual_seed(seed)
first_stage_config = {"capacity": 64, "c_mults": [2, 4, 8, 16, 32], "strides": [2, 2, 2, 2, 2], "latent_dim": 32}
autoencoder = AudioAutoencoder(
**first_stage_config
).to(device).requires_grad_(False).eval()
latent_diffae = LatentAudioDiffusionAutoencoder(autoencoder).requires_grad_(False).eval()
clap_model = laion_clap.CLAP_Module(enable_fusion=args.clap_fusion, device=device, amodel= args.clap_amodel).requires_grad_(False).eval()
if args.clap_ckpt_path:
clap_model.load_ckpt(ckpt=args.clap_ckpt_path)
else:
clap_model.load_ckpt(model_id=1)
print("Loading model...")
latent_diffusion_model = StackedAELatentDiffusionCond.load_from_checkpoint(args.ckpt_path, latent_ae=latent_diffae, clap_model=clap_model, strict=False).to(device).requires_grad_(False).eval()
print("Model loaded")
while True:
prompt = input("Enter 'encode' to encode an audio file or enter a prompt to generate audio (or 'quit' to exit): ")
if prompt == "quit":
break
elif prompt == "encode":
input_file = input("Enter the path to the input audio file: ")
encode_decode_file(latent_diffusion_model, input_file, args.save_dir)
else:
second_start = input("Enter the starting second of the output: ")
second_start = int(second_start)
seconds_total = input("Enter the total number of seconds in the track: ")
seconds_total = int(seconds_total)
generate_audio(prompt, args, latent_diffusion_model, second_start, seconds_total)
if __name__ == '__main__':
main()