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An implementation of Performer, a linear attention-based transformer, in Pytorch

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Performer - Pytorch

PyPI version

An implementation of Performer, a linear attention-based transformer variant with a Fast Attention Via positive Orthogonal Random features approach (FAVOR+).

Install

$ pip install performer-pytorch

Then you must run the following, if you plan on training an autoregressive model

$ pip install -r requirements.txt

Usage

Performer Language Model

import torch
from performer_pytorch import PerformerLM

model = PerformerLM(
    num_tokens = 20000,
    max_seq_len = 2048,             # max sequence length
    dim = 512,                      # dimension
    depth = 12,                     # layers
    heads = 8,                      # heads
    causal = False,                 # auto-regressive or not
    nb_features = 256,              # number of random features, if not set, will default to (d * log(d)), where d is the dimension of each head
    feature_redraw_interval = 1000, # how frequently to redraw the projection matrix, the more frequent, the slower the training
    generalized_attention = False,  # defaults to softmax approximation, but can be set to True for generalized attention
    kernel_fn = torch.nn.ReLU(),    # the kernel function to be used, if generalized attention is turned on, defaults to Relu
    reversible = True,              # reversible layers, from Reformer paper
    ff_chunks = 10,                 # chunk feedforward layer, from Reformer paper
    use_scalenorm = False,          # use scale norm, from 'Transformers without Tears' paper
    use_rezero = False,             # use rezero, from 'Rezero is all you need' paper
    ff_glu = True,                  # use GLU variant for feedforward
    emb_dropout = 0.1,              # embedding dropout
    ff_dropout = 0.1,               # feedforward dropout
    attn_dropout = 0.1,             # post-attn dropout
    local_attn_heads = 4,           # 4 heads are local attention, 4 others are global performers
    local_window_size = 256,        # window size of local attention
    rotary_position_emb = True,     # use rotary positional embedding, which endows linear attention with relative positional encoding with no learned parameters. should always be turned on unless if you want to go back to old absolute positional encoding
    shift_tokens = True             # shift tokens by 1 along sequence dimension before each block, for better convergence
)

x = torch.randint(0, 20000, (1, 2048))
mask = torch.ones_like(x).bool()

model(x, mask = mask) # (1, 2048, 20000)

Plain Performer, if you are working with say images or other modalities

import torch
from performer_pytorch import Performer

model = Performer(
    dim = 512,
    depth = 1,
    heads = 8,
    causal = True
)

x = torch.randn(1, 2048, 512)
model(x) # (1, 2048, 512)

Encoder / Decoder - Made possible by Thomas Melistas

import torch
from performer_pytorch import PerformerEncDec

SRC_SEQ_LEN = 4096
TGT_SEQ_LEN = 4096
GENERATE_LEN = 512

enc_dec = PerformerEncDec(
    dim = 512,
    tie_token_embed = True,
    enc_num_tokens = 20000,
    enc_depth = 6,
    enc_heads = 8,
    enc_max_seq_len = SRC_SEQ_LEN,
    dec_num_tokens = 20000,
    dec_depth = 6,
    dec_heads = 8,
    dec_max_seq_len = TGT_SEQ_LEN,
)

src = torch.randint(0, 20000, (1, SRC_SEQ_LEN))
tgt = torch.randint(0, 20000, (1, TGT_SEQ_LEN))
src_mask = torch.ones_like(src).bool()
tgt_mask = torch.ones_like(src).bool()

# train
enc_dec.train()
loss = enc_dec(src, tgt, enc_mask = src_mask, dec_mask = tgt_mask)
loss.backward()

# generate
generate_in = torch.randint(0, 20000, (1, SRC_SEQ_LEN)).long()
generate_out_prime = torch.tensor([[0.]]).long() # prime with <bos> token
samples = enc_dec.generate(generate_in, generate_out_prime, seq_len = GENERATE_LEN, eos_token = 1) # assume 1 is id of stop token
print(samples.shape) # (1, <= GENERATE_LEN) decode the tokens

Standalone self-attention layer with linear complexity in respect to sequence length, for replacing trained full-attention transformer self-attention layers.

import torch
from performer_pytorch import SelfAttention

attn = SelfAttention(
    dim = 512,
    heads = 8,
    causal = False,
).cuda()

x = torch.randn(1, 1024, 512).cuda()
attn(x) # (1, 1024, 512)

Cross attention is similarly

import torch
from performer_pytorch import CrossAttention

attn = CrossAttention(
    dim = 512,
    heads = 8
).cuda()

x = torch.randn(1, 1024, 512).cuda()
context = torch.randn(1, 512, 512).cuda()

attn(x, context = context) # (1, 1024, 512)

To minimize model surgery, you could also simply rewrite the code, so that the attention step is done by the FastAttention module, as follows.

import torch
from performer_pytorch import FastAttention

# queries / keys / values with heads already split and transposed to first dimension
# 8 heads, dimension of head is 64, sequence length of 512
q = torch.randn(1, 8, 512, 64)
k = torch.randn(1, 8, 512, 64)
v = torch.randn(1, 8, 512, 64)

attn_fn = FastAttention(
    dim_heads = 64,
    nb_features = 256,
    causal = False
)

out = attn_fn(q, k, v) # (1, 8, 512, 64)
# now merge heads and combine outputs with Wo

Advanced

At the end of training, if you wish to fix the projection matrices to get the model to output deterministically, you can invoke the following

model.fix_projection_matrices_()

Now your model will have fixed projection matrices across all layers

Citations

@misc{choromanski2020rethinking,
    title   = {Rethinking Attention with Performers},
    author  = {Krzysztof Choromanski and Valerii Likhosherstov and David Dohan and Xingyou Song and Andreea Gane and Tamas Sarlos and Peter Hawkins and Jared Davis and Afroz Mohiuddin and Lukasz Kaiser and David Belanger and Lucy Colwell and Adrian Weller},
    year    = {2020},
    eprint  = {2009.14794},
    archivePrefix = {arXiv},
    primaryClass = {cs.LG}
}
@inproceedings{kitaev2020reformer,
    title       = {Reformer: The Efficient Transformer},
    author      = {Nikita Kitaev and Lukasz Kaiser and Anselm Levskaya},
    booktitle   = {International Conference on Learning Representations},
    year        = {2020},
    url         = {https://openreview.net/forum?id=rkgNKkHtvB}
}
@inproceedings{katharopoulos_et_al_2020,
    author  = {Katharopoulos, A. and Vyas, A. and Pappas, N. and Fleuret, F.},
    title   = {Transformers are RNNs: Fast Autoregressive Transformers with Linear Attention},
    booktitle = {Proceedings of the International Conference on Machine Learning (ICML)},
    year    = {2020}
}
@misc{bachlechner2020rezero,
    title   = {ReZero is All You Need: Fast Convergence at Large Depth},
    author  = {Thomas Bachlechner and Bodhisattwa Prasad Majumder and Huanru Henry Mao and Garrison W. Cottrell and Julian McAuley},
    year    = {2020},
    url     = {https://arxiv.org/abs/2003.04887}
}
@article{1910.05895,
    author  = {Toan Q. Nguyen and Julian Salazar},
    title   = {Transformers without Tears: Improving the Normalization of Self-Attention},
    year    = {2019},
    eprint  = {arXiv:1910.05895},
    doi     = {10.5281/zenodo.3525484},
}
@misc{shazeer2020glu,
    title   = {GLU Variants Improve Transformer},
    author  = {Noam Shazeer},
    year    = {2020},
    url     = {https://arxiv.org/abs/2002.05202}
}
@misc{roy*2020efficient,
    title   = {Efficient Content-Based Sparse Attention with Routing Transformers},
    author  = {Aurko Roy* and Mohammad Taghi Saffar* and David Grangier and Ashish Vaswani},
    year    = {2020},
    url     = {https://arxiv.org/pdf/2003.05997.pdf}
}
@misc{su2021roformer,
    title   = {RoFormer: Enhanced Transformer with Rotary Position Embedding},
    author  = {Jianlin Su and Yu Lu and Shengfeng Pan and Bo Wen and Yunfeng Liu},
    year    = {2021},
    eprint  = {2104.09864},
    archivePrefix = {arXiv},
    primaryClass = {cs.CL},
    url     = {https://arxiv.org/abs/2104.09864}
}