Skip to content

Implementation of MusicLM, Google's new SOTA model for music generation using attention networks, in Pytorch

License

Notifications You must be signed in to change notification settings

phber/musiclm-pytorch

 
 

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

66 Commits
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

MusicLM - Pytorch

Implementation of MusicLM, Google's new SOTA model for music generation using attention networks, in Pytorch.

They are basically using text-conditioned AudioLM, but surprisingly with the embeddings from a text-audio contrastive learned model named MuLan. MuLan is what will be built out in this repository, with AudioLM modified from the other repository to support the music generation needs here.

Please join Join us on Discord if you are interested in helping out with the replication with the LAION community

What's AI by Louis Bouchard

Appreciation

Usage

$ pip install musiclm-pytorch

Usage

MuLaN first needs to be trained

import torch
from musiclm_pytorch import MuLaN, AudioSpectrogramTransformer, TextTransformer

audio_transformer = AudioSpectrogramTransformer(
    dim = 512,
    depth = 6,
    heads = 8,
    dim_head = 64,
    spec_n_fft = 128,
    spec_win_length = 24,
    spec_aug_stretch_factor = 0.8
)

text_transformer = TextTransformer(
    dim = 512,
    depth = 6,
    heads = 8,
    dim_head = 64
)

mulan = MuLaN(
    audio_transformer = audio_transformer,
    text_transformer = text_transformer
)

# get a ton of <sound, text> pairs and train

wavs = torch.randn(2, 1024)
texts = torch.randint(0, 20000, (2, 256))

loss = mulan(wavs, texts)
loss.backward()

# after much training, you can embed sounds and text into a joint embedding space
# for conditioning the audio LM

embeds = mulan.get_audio_latents(wavs)  # during training

embeds = mulan.get_text_latents(texts)  # during inference

To obtain the conditioning embeddings for the three transformers that are a part of AudioLM, you must use the MuLaNEmbedQuantizer as so

from musiclm_pytorch import MuLaNEmbedQuantizer

# setup the quantizer with the namespaced conditioning embeddings, unique per quantizer as well as namespace (per transformer)

quantizer = MuLaNEmbedQuantizer(
    mulan = mulan,                          # pass in trained mulan from above
    conditioning_dims = (1024, 1024, 1024), # say all three transformers have model dimensions of 1024
    namespaces = ('semantic', 'coarse', 'fine')
)

# now say you want the conditioning embeddings for semantic transformer

wavs = torch.randn(2, 1024)
conds = quantizer(wavs = wavs, namespace = 'semantic') # (2, 8, 1024) - 8 is number of quantizers

To train (or finetune) the three transformers that are a part of AudioLM, you simply follow the instructions over at audiolm-pytorch for training, but pass in the MulanEmbedQuantizer instance to the training classes under the keyword audio_conditioner

ex. SemanticTransformerTrainer

import torch
from audiolm_pytorch import HubertWithKmeans, SemanticTransformer, SemanticTransformerTrainer

wav2vec = HubertWithKmeans(
    checkpoint_path = './hubert/hubert_base_ls960.pt',
    kmeans_path = './hubert/hubert_base_ls960_L9_km500.bin'
)

semantic_transformer = SemanticTransformer(
    num_semantic_tokens = wav2vec.codebook_size,
    dim = 1024,
    depth = 6,
    audio_text_condition = True      # this must be set to True (same for CoarseTransformer and FineTransformers)
).cuda()

trainer = SemanticTransformerTrainer(
    transformer = semantic_transformer,
    wav2vec = wav2vec,
    audio_conditioner = quantizer,   # pass in the MulanEmbedQuantizer instance above
    folder ='/path/to/audio/files',
    batch_size = 1,
    data_max_length = 320 * 32,
    num_train_steps = 1
)

trainer.train()

After much training on all three transformers (semantic, coarse, fine), you will pass your finetuned or trained-from-scratch AudioLM and MuLaN wrapped in MuLaNEmbedQuantizer to the MusicLM

# you need the trained AudioLM (audio_lm) from above
# with the MulanEmbedQuantizer (mulan_embed_quantizer)

from musiclm_pytorch import MusicLM

musiclm = MusicLM(
    audio_lm = audio_lm,                 # `AudioLM` from https://github.com/lucidrains/audiolm-pytorch
    mulan_embed_quantizer = quantizer    # the `MuLaNEmbedQuantizer` from above
)

music = musiclm('the crystalline sounds of the piano in a ballroom', num_samples = 4) # sample 4 and pick the top match with mulan

Todo

  • mulan seems to be using decoupled contrastive learning, offer that as an option

  • wrap mulan with mulan wrapper and quantize the output, project to audiolm dimensions

  • modify audiolm to accept conditioning embeddings, optionally take care of different dimensions through a separate projection

  • audiolm and mulan goes into musiclm and generate, filter with mulan

  • give dynamic positional bias to self attention in AST

  • implement MusicLM generating multiple samples and selecting top match with MuLaN

  • support variable lengthed audio with masking in audio transformer

  • add a version of mulan to open clip

  • set all the proper spectrogram hyperparameters

Citations

@inproceedings{Agostinelli2023MusicLMGM,
    title     = {MusicLM: Generating Music From Text},
    author    = {Andrea Agostinelli and Timo I. Denk and Zal{\'a}n Borsos and Jesse Engel and Mauro Verzetti and Antoine Caillon and Qingqing Huang and Aren Jansen and Adam Roberts and Marco Tagliasacchi and Matthew Sharifi and Neil Zeghidour and C. Frank},
    year      = {2023}
}
@article{Huang2022MuLanAJ,
    title   = {MuLan: A Joint Embedding of Music Audio and Natural Language},
    author  = {Qingqing Huang and Aren Jansen and Joonseok Lee and Ravi Ganti and Judith Yue Li and Daniel P. W. Ellis},
    journal = {ArXiv},
    year    = {2022},
    volume  = {abs/2208.12415}
}
@misc{https://doi.org/10.48550/arxiv.2302.01327,
    doi     = {10.48550/ARXIV.2302.01327},
    url     = {https://arxiv.org/abs/2302.01327},
    author  = {Kumar, Manoj and Dehghani, Mostafa and Houlsby, Neil},
    title   = {Dual PatchNorm},
    publisher = {arXiv},
    year    = {2023},
    copyright = {Creative Commons Attribution 4.0 International}
}
@article{Liu2022PatchDropoutEV,
    title   = {PatchDropout: Economizing Vision Transformers Using Patch Dropout},
    author  = {Yue Liu and Christos Matsoukas and Fredrik Strand and Hossein Azizpour and Kevin Smith},
    journal = {ArXiv},
    year    = {2022},
    volume  = {abs/2208.07220}
}
@misc{liu2021swin,
    title   = {Swin Transformer V2: Scaling Up Capacity and Resolution},
    author  = {Ze Liu and Han Hu and Yutong Lin and Zhuliang Yao and Zhenda Xie and Yixuan Wei and Jia Ning and Yue Cao and Zheng Zhang and Li Dong and Furu Wei and Baining Guo},
    year    = {2021},
    eprint  = {2111.09883},
    archivePrefix = {arXiv},
    primaryClass = {cs.CV}
}
@misc{gilmer2023intriguing
    title  = {Intriguing Properties of Transformer Training Instabilities},
    author = {Justin Gilmer, Andrea Schioppa, and Jeremy Cohen},
    year   = {2023},
    status = {to be published - one attention stabilization technique is circulating within Google Brain, being used by multiple teams}
}
@inproceedings{Shukor2022EfficientVP,
    title   = {Efficient Vision-Language Pretraining with Visual Concepts and Hierarchical Alignment},
    author  = {Mustafa Shukor and Guillaume Couairon and Matthieu Cord},
    booktitle = {British Machine Vision Conference},
    year    = {2022}
}
@inproceedings{Zhai2023SigmoidLF,
    title   = {Sigmoid Loss for Language Image Pre-Training},
    author  = {Xiaohua Zhai and Basil Mustafa and Alexander Kolesnikov and Lucas Beyer},
    year    = {2023}
}

The only truth is music. - Jack Kerouac

Music is the universal language of mankind. - Henry Wadsworth Longfellow

About

Implementation of MusicLM, Google's new SOTA model for music generation using attention networks, in Pytorch

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages

  • Python 100.0%