- Vision Transformer - Pytorch
- Install
- Usage
- Parameters
- Distillation
- Deep ViT
- CaiT
- Token-to-Token ViT
- CCT
- Cross ViT
- PiT
- LeViT
- CvT
- Twins SVT
- CrossFormer
- RegionViT
- NesT
- MobileViT
- Masked Autoencoder
- Simple Masked Image Modeling
- Masked Patch Prediction
- Adaptive Token Sampling
- Vision Transformer for Small Datasets
- Dino
- Accessing Attention
- Research Ideas
- FAQ
- Resources
- Citations
Implementation of Vision Transformer, a simple way to achieve SOTA in vision classification with only a single transformer encoder, in Pytorch. Significance is further explained in Yannic Kilcher's video. There's really not much to code here, but may as well lay it out for everyone so we expedite the attention revolution.
For a Pytorch implementation with pretrained models, please see Ross Wightman's repository here.
The official Jax repository is here.
$ pip install vit-pytorch
import torch
from vit_pytorch import ViT
v = ViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
img = torch.randn(1, 3, 256, 256)
preds = v(img) # (1, 1000)
image_size
: int.
Image size. If you have rectangular images, make sure your image size is the maximum of the width and heightpatch_size
: int.
Number of patches.image_size
must be divisible bypatch_size
.
The number of patches is:n = (image_size // patch_size) ** 2
andn
must be greater than 16.num_classes
: int.
Number of classes to classify.dim
: int.
Last dimension of output tensor after linear transformationnn.Linear(..., dim)
.depth
: int.
Number of Transformer blocks.heads
: int.
Number of heads in Multi-head Attention layer.mlp_dim
: int.
Dimension of the MLP (FeedForward) layer.channels
: int, default3
.
Number of image's channels.dropout
: float between[0, 1]
, default0.
.
Dropout rate.emb_dropout
: float between[0, 1]
, default0
.
Embedding dropout rate.pool
: string, eithercls
token pooling ormean
pooling
A recent paper has shown that use of a distillation token for distilling knowledge from convolutional nets to vision transformer can yield small and efficient vision transformers. This repository offers the means to do distillation easily.
ex. distilling from Resnet50 (or any teacher) to a vision transformer
import torch
from torchvision.models import resnet50
from vit_pytorch.distill import DistillableViT, DistillWrapper
teacher = resnet50(pretrained = True)
v = DistillableViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 8,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
distiller = DistillWrapper(
student = v,
teacher = teacher,
temperature = 3, # temperature of distillation
alpha = 0.5, # trade between main loss and distillation loss
hard = False # whether to use soft or hard distillation
)
img = torch.randn(2, 3, 256, 256)
labels = torch.randint(0, 1000, (2,))
loss = distiller(img, labels)
loss.backward()
# after lots of training above ...
pred = v(img) # (2, 1000)
The DistillableViT
class is identical to ViT
except for how the forward pass is handled, so you should be able to load the parameters back to ViT
after you have completed distillation training.
You can also use the handy .to_vit
method on the DistillableViT
instance to get back a ViT
instance.
v = v.to_vit()
type(v) # <class 'vit_pytorch.vit_pytorch.ViT'>
This paper notes that ViT struggles to attend at greater depths (past 12 layers), and suggests mixing the attention of each head post-softmax as a solution, dubbed Re-attention. The results line up with the Talking Heads paper from NLP.
You can use it as follows
import torch
from vit_pytorch.deepvit import DeepViT
v = DeepViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
img = torch.randn(1, 3, 256, 256)
preds = v(img) # (1, 1000)
This paper also notes difficulty in training vision transformers at greater depths and proposes two solutions. First it proposes to do per-channel multiplication of the output of the residual block. Second, it proposes to have the patches attend to one another, and only allow the CLS token to attend to the patches in the last few layers.
They also add Talking Heads, noting improvements
You can use this scheme as follows
import torch
from vit_pytorch.cait import CaiT
v = CaiT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 12, # depth of transformer for patch to patch attention only
cls_depth = 2, # depth of cross attention of CLS tokens to patch
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1,
layer_dropout = 0.05 # randomly dropout 5% of the layers
)
img = torch.randn(1, 3, 256, 256)
preds = v(img) # (1, 1000)
This paper proposes that the first couple layers should downsample the image sequence by unfolding, leading to overlapping image data in each token as shown in the figure above. You can use this variant of the ViT
as follows.
import torch
from vit_pytorch.t2t import T2TViT
v = T2TViT(
dim = 512,
image_size = 224,
depth = 5,
heads = 8,
mlp_dim = 512,
num_classes = 1000,
t2t_layers = ((7, 4), (3, 2), (3, 2)) # tuples of the kernel size and stride of each consecutive layers of the initial token to token module
)
img = torch.randn(1, 3, 224, 224)
preds = v(img) # (1, 1000)
CCT proposes compact transformers by using convolutions instead of patching and performing sequence pooling. This allows for CCT to have high accuracy and a low number of parameters.
You can use this with two methods
import torch
from vit_pytorch.cct import CCT
model = CCT(
img_size=224,
embedding_dim=384,
n_conv_layers=2,
kernel_size=7,
stride=2,
padding=3,
pooling_kernel_size=3,
pooling_stride=2,
pooling_padding=1,
num_layers=14,
num_heads=6,
mlp_radio=3.,
num_classes=1000,
positional_embedding='learnable', # ['sine', 'learnable', 'none']
)
Alternatively you can use one of several pre-defined models [2,4,6,7,8,14,16]
which pre-define the number of layers, number of attention heads, the mlp ratio,
and the embedding dimension.
import torch
from vit_pytorch.cct import cct_14
model = cct_14(
img_size=224,
n_conv_layers=1,
kernel_size=7,
stride=2,
padding=3,
pooling_kernel_size=3,
pooling_stride=2,
pooling_padding=1,
num_classes=1000,
positional_embedding='learnable', # ['sine', 'learnable', 'none']
)
Official Repository includes links to pretrained model checkpoints.
This paper proposes to have two vision transformers processing the image at different scales, cross attending to one every so often. They show improvements on top of the base vision transformer.
import torch
from vit_pytorch.cross_vit import CrossViT
v = CrossViT(
image_size = 256,
num_classes = 1000,
depth = 4, # number of multi-scale encoding blocks
sm_dim = 192, # high res dimension
sm_patch_size = 16, # high res patch size (should be smaller than lg_patch_size)
sm_enc_depth = 2, # high res depth
sm_enc_heads = 8, # high res heads
sm_enc_mlp_dim = 2048, # high res feedforward dimension
lg_dim = 384, # low res dimension
lg_patch_size = 64, # low res patch size
lg_enc_depth = 3, # low res depth
lg_enc_heads = 8, # low res heads
lg_enc_mlp_dim = 2048, # low res feedforward dimensions
cross_attn_depth = 2, # cross attention rounds
cross_attn_heads = 8, # cross attention heads
dropout = 0.1,
emb_dropout = 0.1
)
img = torch.randn(1, 3, 256, 256)
pred = v(img) # (1, 1000)
This paper proposes to downsample the tokens through a pooling procedure using depth-wise convolutions.
import torch
from vit_pytorch.pit import PiT
v = PiT(
image_size = 224,
patch_size = 14,
dim = 256,
num_classes = 1000,
depth = (3, 3, 3), # list of depths, indicating the number of rounds of each stage before a downsample
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
# forward pass now returns predictions and the attention maps
img = torch.randn(1, 3, 224, 224)
preds = v(img) # (1, 1000)
This paper proposes a number of changes, including (1) convolutional embedding instead of patch-wise projection (2) downsampling in stages (3) extra non-linearity in attention (4) 2d relative positional biases instead of initial absolute positional bias (5) batchnorm in place of layernorm.
import torch
from vit_pytorch.levit import LeViT
levit = LeViT(
image_size = 224,
num_classes = 1000,
stages = 3, # number of stages
dim = (256, 384, 512), # dimensions at each stage
depth = 4, # transformer of depth 4 at each stage
heads = (4, 6, 8), # heads at each stage
mlp_mult = 2,
dropout = 0.1
)
img = torch.randn(1, 3, 224, 224)
levit(img) # (1, 1000)
This paper proposes mixing convolutions and attention. Specifically, convolutions are used to embed and downsample the image / feature map in three stages. Depthwise-convoltion is also used to project the queries, keys, and values for attention.
import torch
from vit_pytorch.cvt import CvT
v = CvT(
num_classes = 1000,
s1_emb_dim = 64, # stage 1 - dimension
s1_emb_kernel = 7, # stage 1 - conv kernel
s1_emb_stride = 4, # stage 1 - conv stride
s1_proj_kernel = 3, # stage 1 - attention ds-conv kernel size
s1_kv_proj_stride = 2, # stage 1 - attention key / value projection stride
s1_heads = 1, # stage 1 - heads
s1_depth = 1, # stage 1 - depth
s1_mlp_mult = 4, # stage 1 - feedforward expansion factor
s2_emb_dim = 192, # stage 2 - (same as above)
s2_emb_kernel = 3,
s2_emb_stride = 2,
s2_proj_kernel = 3,
s2_kv_proj_stride = 2,
s2_heads = 3,
s2_depth = 2,
s2_mlp_mult = 4,
s3_emb_dim = 384, # stage 3 - (same as above)
s3_emb_kernel = 3,
s3_emb_stride = 2,
s3_proj_kernel = 3,
s3_kv_proj_stride = 2,
s3_heads = 4,
s3_depth = 10,
s3_mlp_mult = 4,
dropout = 0.
)
img = torch.randn(1, 3, 224, 224)
pred = v(img) # (1, 1000)
This paper proposes mixing local and global attention, along with position encoding generator (proposed in CPVT) and global average pooling, to achieve the same results as Swin, without the extra complexity of shifted windows, CLS tokens, nor positional embeddings.
import torch
from vit_pytorch.twins_svt import TwinsSVT
model = TwinsSVT(
num_classes = 1000, # number of output classes
s1_emb_dim = 64, # stage 1 - patch embedding projected dimension
s1_patch_size = 4, # stage 1 - patch size for patch embedding
s1_local_patch_size = 7, # stage 1 - patch size for local attention
s1_global_k = 7, # stage 1 - global attention key / value reduction factor, defaults to 7 as specified in paper
s1_depth = 1, # stage 1 - number of transformer blocks (local attn -> ff -> global attn -> ff)
s2_emb_dim = 128, # stage 2 (same as above)
s2_patch_size = 2,
s2_local_patch_size = 7,
s2_global_k = 7,
s2_depth = 1,
s3_emb_dim = 256, # stage 3 (same as above)
s3_patch_size = 2,
s3_local_patch_size = 7,
s3_global_k = 7,
s3_depth = 5,
s4_emb_dim = 512, # stage 4 (same as above)
s4_patch_size = 2,
s4_local_patch_size = 7,
s4_global_k = 7,
s4_depth = 4,
peg_kernel_size = 3, # positional encoding generator kernel size
dropout = 0. # dropout
)
img = torch.randn(1, 3, 224, 224)
pred = model(img) # (1, 1000)
This paper proposes to divide up the feature map into local regions, whereby the local tokens attend to each other. Each local region has its own regional token which then attends to all its local tokens, as well as other regional tokens.
You can use it as follows
import torch
from vit_pytorch.regionvit import RegionViT
model = RegionViT(
dim = (64, 128, 256, 512), # tuple of size 4, indicating dimension at each stage
depth = (2, 2, 8, 2), # depth of the region to local transformer at each stage
window_size = 7, # window size, which should be either 7 or 14
num_classes = 1000, # number of output classes
tokenize_local_3_conv = False, # whether to use a 3 layer convolution to encode the local tokens from the image. the paper uses this for the smaller models, but uses only 1 conv (set to False) for the larger models
use_peg = False, # whether to use positional generating module. they used this for object detection for a boost in performance
)
img = torch.randn(1, 3, 224, 224)
pred = model(img) # (1, 1000)
This paper beats PVT and Swin using alternating local and global attention. The global attention is done across the windowing dimension for reduced complexity, much like the scheme used for axial attention.
They also have cross-scale embedding layer, which they shown to be a generic layer that can improve all vision transformers. Dynamic relative positional bias was also formulated to allow the net to generalize to images of greater resolution.
import torch
from vit_pytorch.crossformer import CrossFormer
model = CrossFormer(
num_classes = 1000, # number of output classes
dim = (64, 128, 256, 512), # dimension at each stage
depth = (2, 2, 8, 2), # depth of transformer at each stage
global_window_size = (8, 4, 2, 1), # global window sizes at each stage
local_window_size = 7, # local window size (can be customized for each stage, but in paper, held constant at 7 for all stages)
)
img = torch.randn(1, 3, 224, 224)
pred = model(img) # (1, 1000)
This paper decided to process the image in hierarchical stages, with attention only within tokens of local blocks, which aggregate as it moves up the heirarchy. The aggregation is done in the image plane, and contains a convolution and subsequent maxpool to allow it to pass information across the boundary.
You can use it with the following code (ex. NesT-T)
import torch
from vit_pytorch.nest import NesT
nest = NesT(
image_size = 224,
patch_size = 4,
dim = 96,
heads = 3,
num_hierarchies = 3, # number of hierarchies
block_repeats = (2, 2, 8), # the number of transformer blocks at each heirarchy, starting from the bottom
num_classes = 1000
)
img = torch.randn(1, 3, 224, 224)
pred = nest(img) # (1, 1000)
This paper introduce MobileViT, a light-weight and general purpose vision transformer for mobile devices. MobileViT presents a different perspective for the global processing of information with transformers.
You can use it with the following code (ex. mobilevit_xs)
import torch
from vit_pytorch.mobile_vit import MobileViT
mbvit_xs = MobileViT(
image_size = (256, 256),
dims = [96, 120, 144],
channels = [16, 32, 48, 48, 64, 64, 80, 80, 96, 96, 384],
num_classes = 1000
)
img = torch.randn(1, 3, 256, 256)
pred = mbvit_xs(img) # (1, 1000)
This paper proposes a simple masked image modeling (SimMIM) scheme, using only a linear projection off the masked tokens into pixel space followed by an L1 loss with the pixel values of the masked patches. Results are competitive with other more complicated approaches.
You can use this as follows
import torch
from vit_pytorch import ViT
from vit_pytorch.simmim import SimMIM
v = ViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 8,
mlp_dim = 2048
)
mim = SimMIM(
encoder = v,
masking_ratio = 0.5 # they found 50% to yield the best results
)
images = torch.randn(8, 3, 256, 256)
loss = mim(images)
loss.backward()
# that's all!
# do the above in a for loop many times with a lot of images and your vision transformer will learn
torch.save(v.state_dict(), './trained-vit.pt')
A new Kaiming He paper proposes a simple autoencoder scheme where the vision transformer attends to a set of unmasked patches, and a smaller decoder tries to reconstruct the masked pixel values.
You can use it with the following code
import torch
from vit_pytorch import ViT, MAE
v = ViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 8,
mlp_dim = 2048
)
mae = MAE(
encoder = v,
masking_ratio = 0.75, # the paper recommended 75% masked patches
decoder_dim = 512, # paper showed good results with just 512
decoder_depth = 6 # anywhere from 1 to 8
)
images = torch.randn(8, 3, 256, 256)
loss = mae(images)
loss.backward()
# that's all!
# do the above in a for loop many times with a lot of images and your vision transformer will learn
# save your improved vision transformer
torch.save(v.state_dict(), './trained-vit.pt')
Thanks to Zach, you can train using the original masked patch prediction task presented in the paper, with the following code.
import torch
from vit_pytorch import ViT
from vit_pytorch.mpp import MPP
model = ViT(
image_size=256,
patch_size=32,
num_classes=1000,
dim=1024,
depth=6,
heads=8,
mlp_dim=2048,
dropout=0.1,
emb_dropout=0.1
)
mpp_trainer = MPP(
transformer=model,
patch_size=32,
dim=1024,
mask_prob=0.15, # probability of using token in masked prediction task
random_patch_prob=0.30, # probability of randomly replacing a token being used for mpp
replace_prob=0.50, # probability of replacing a token being used for mpp with the mask token
)
opt = torch.optim.Adam(mpp_trainer.parameters(), lr=3e-4)
def sample_unlabelled_images():
return torch.FloatTensor(20, 3, 256, 256).uniform_(0., 1.)
for _ in range(100):
images = sample_unlabelled_images()
loss = mpp_trainer(images)
opt.zero_grad()
loss.backward()
opt.step()
# save your improved network
torch.save(model.state_dict(), './pretrained-net.pt')
This paper proposes to use the CLS attention scores, re-weighed by the norms of the value heads, as means to discard unimportant tokens at different layers.
import torch
from vit_pytorch.ats_vit import ViT
v = ViT(
image_size = 256,
patch_size = 16,
num_classes = 1000,
dim = 1024,
depth = 6,
max_tokens_per_depth = (256, 128, 64, 32, 16, 8), # a tuple that denotes the maximum number of tokens that any given layer should have. if the layer has greater than this amount, it will undergo adaptive token sampling
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
img = torch.randn(4, 3, 256, 256)
preds = v(img) # (1, 1000)
# you can also get a list of the final sampled patch ids
# a value of -1 denotes padding
preds, token_ids = v(img, return_sampled_token_ids = True) # (1, 1000), (1, <=8)
This paper proposes a new image to patch function that incorporates shifts of the image, before normalizing and dividing the image into patches. I have found shifting to be extremely helpful in some other transformers work, so decided to include this for further explorations. It also includes the LSA
with the learned temperature and masking out of a token's attention to itself.
You can use as follows:
import torch
from vit_pytorch.vit_for_small_dataset import ViT
v = ViT(
image_size = 256,
patch_size = 16,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
img = torch.randn(4, 3, 256, 256)
preds = v(img) # (1, 1000)
You can also use the SPT
from this paper as a standalone module
import torch
from vit_pytorch.vit_for_small_dataset import SPT
spt = SPT(
dim = 1024,
patch_size = 16,
channels = 3
)
img = torch.randn(4, 3, 256, 256)
tokens = spt(img) # (4, 256, 1024)
You can train ViT
with the recent SOTA self-supervised learning technique, Dino, with the following code.
Yannic Kilcher video
import torch
from vit_pytorch import ViT, Dino
model = ViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 8,
mlp_dim = 2048
)
learner = Dino(
model,
image_size = 256,
hidden_layer = 'to_latent', # hidden layer name or index, from which to extract the embedding
projection_hidden_size = 256, # projector network hidden dimension
projection_layers = 4, # number of layers in projection network
num_classes_K = 65336, # output logits dimensions (referenced as K in paper)
student_temp = 0.9, # student temperature
teacher_temp = 0.04, # teacher temperature, needs to be annealed from 0.04 to 0.07 over 30 epochs
local_upper_crop_scale = 0.4, # upper bound for local crop - 0.4 was recommended in the paper
global_lower_crop_scale = 0.5, # lower bound for global crop - 0.5 was recommended in the paper
moving_average_decay = 0.9, # moving average of encoder - paper showed anywhere from 0.9 to 0.999 was ok
center_moving_average_decay = 0.9, # moving average of teacher centers - paper showed anywhere from 0.9 to 0.999 was ok
)
opt = torch.optim.Adam(learner.parameters(), lr = 3e-4)
def sample_unlabelled_images():
return torch.randn(20, 3, 256, 256)
for _ in range(100):
images = sample_unlabelled_images()
loss = learner(images)
opt.zero_grad()
loss.backward()
opt.step()
learner.update_moving_average() # update moving average of teacher encoder and teacher centers
# save your improved network
torch.save(model.state_dict(), './pretrained-net.pt')
If you would like to visualize the attention weights (post-softmax) for your research, just follow the procedure below
import torch
from vit_pytorch.vit import ViT
v = ViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
# import Recorder and wrap the ViT
from vit_pytorch.recorder import Recorder
v = Recorder(v)
# forward pass now returns predictions and the attention maps
img = torch.randn(1, 3, 256, 256)
preds, attns = v(img)
# there is one extra patch due to the CLS token
attns # (1, 6, 16, 65, 65) - (batch x layers x heads x patch x patch)
to cleanup the class and the hooks once you have collected enough data
v = v.eject() # wrapper is discarded and original ViT instance is returned
You can similarly access the embeddings with the Extractor
wrapper
import torch
from vit_pytorch.vit import ViT
v = ViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
# import Recorder and wrap the ViT
from vit_pytorch.extractor import Extractor
v = Extractor(v)
# forward pass now returns predictions and the attention maps
img = torch.randn(1, 3, 256, 256)
logits, embeddings = v(img)
# there is one extra token due to the CLS token
embeddings # (1, 65, 1024) - (batch x patches x model dim)
There may be some coming from computer vision who think attention still suffers from quadratic costs. Fortunately, we have a lot of new techniques that may help. This repository offers a way for you to plugin your own sparse attention transformer.
An example with Nystromformer
$ pip install nystrom-attention
import torch
from vit_pytorch.efficient import ViT
from nystrom_attention import Nystromformer
efficient_transformer = Nystromformer(
dim = 512,
depth = 12,
heads = 8,
num_landmarks = 256
)
v = ViT(
dim = 512,
image_size = 2048,
patch_size = 32,
num_classes = 1000,
transformer = efficient_transformer
)
img = torch.randn(1, 3, 2048, 2048) # your high resolution picture
v(img) # (1, 1000)
Other sparse attention frameworks I would highly recommend is Routing Transformer or Sinkhorn Transformer
This paper purposely used the most vanilla of attention networks to make a statement. If you would like to use some of the latest improvements for attention nets, please use the Encoder
from this repository.
ex.
$ pip install x-transformers
import torch
from vit_pytorch.efficient import ViT
from x_transformers import Encoder
v = ViT(
dim = 512,
image_size = 224,
patch_size = 16,
num_classes = 1000,
transformer = Encoder(
dim = 512, # set to be the same as the wrapper
depth = 12,
heads = 8,
ff_glu = True, # ex. feed forward GLU variant https://arxiv.org/abs/2002.05202
residual_attn = True # ex. residual attention https://arxiv.org/abs/2012.11747
)
)
img = torch.randn(1, 3, 224, 224)
v(img) # (1, 1000)
- How do I pass in non-square images?
You can already pass in non-square images - you just have to make sure your height and width is less than or equal to the image_size
, and both divisible by the patch_size
ex.
import torch
from vit_pytorch import ViT
v = ViT(
image_size = 256,
patch_size = 32,
num_classes = 1000,
dim = 1024,
depth = 6,
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
img = torch.randn(1, 3, 256, 128) # <-- not a square
preds = v(img) # (1, 1000)
- How do I pass in non-square patches?
import torch
from vit_pytorch import ViT
v = ViT(
num_classes = 1000,
image_size = (256, 128), # image size is a tuple of (height, width)
patch_size = (32, 16), # patch size is a tuple of (height, width)
dim = 1024,
depth = 6,
heads = 16,
mlp_dim = 2048,
dropout = 0.1,
emb_dropout = 0.1
)
img = torch.randn(1, 3, 256, 128)
preds = v(img)
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Illustrated Transformer - Jay Alammar
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Transformers from Scratch - Peter Bloem
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The Annotated Transformer - Harvard NLP
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title = {LeViT: a Vision Transformer in ConvNet's Clothing for Faster Inference},
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archivePrefix = {arXiv},
primaryClass = {cs.CV}
}
@misc{li2021localvit,
title = {LocalViT: Bringing Locality to Vision Transformers},
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year = {2021},
eprint = {2104.05707},
archivePrefix = {arXiv},
primaryClass = {cs.CV}
}
@misc{chu2021twins,
title = {Twins: Revisiting Spatial Attention Design in Vision Transformers},
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year = {2021},
eprint = {2104.13840},
archivePrefix = {arXiv},
primaryClass = {cs.CV}
}
@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},
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}
@misc{zhang2021aggregating,
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year = {2021},
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primaryClass = {cs.CV}
}
@misc{chen2021regionvit,
title = {RegionViT: Regional-to-Local Attention for Vision Transformers},
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primaryClass = {cs.CV}
}
@misc{wang2021crossformer,
title = {CrossFormer: A Versatile Vision Transformer Hinging on Cross-scale Attention},
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}
@misc{caron2021emerging,
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}
@misc{he2021masked,
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@misc{xie2021simmim,
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}
@misc{fayyaz2021ats,
title = {ATS: Adaptive Token Sampling For Efficient Vision Transformers},
author = {Mohsen Fayyaz and Soroush Abbasi Kouhpayegani and Farnoush Rezaei Jafari and Eric Sommerlade and Hamid Reza Vaezi Joze and Hamed Pirsiavash and Juergen Gall},
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}
@misc{mehta2021mobilevit,
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}
@misc{lee2021vision,
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@misc{vaswani2017attention,
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I visualise a time when we will be to robots what dogs are to humans, and I’m rooting for the machines. — Claude Shannon