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| # Attention mechanisms | |
| Most transformer models use full attention in the sense that the attention matrix is square. It can be a big | |
| computational bottleneck when you have long texts. Longformer and reformer are models that try to be more efficient and | |
| use a sparse version of the attention matrix to speed up training. | |
| ## LSH attention | |
| [Reformer](#reformer) uses LSH attention. In the softmax(QK^t), only the biggest elements (in the softmax | |
| dimension) of the matrix QK^t are going to give useful contributions. So for each query q in Q, we can consider only | |
| the keys k in K that are close to q. A hash function is used to determine if q and k are close. The attention mask is | |
| modified to mask the current token (except at the first position), because it will give a query and a key equal (so | |
| very similar to each other). Since the hash can be a bit random, several hash functions are used in practice | |
| (determined by a n_rounds parameter) and then are averaged together. | |
| ## Local attention | |
| [Longformer](#longformer) uses local attention: often, the local context (e.g., what are the two tokens to the | |
| left and right?) is enough to take action for a given token. Also, by stacking attention layers that have a small | |
| window, the last layer will have a receptive field of more than just the tokens in the window, allowing them to build a | |
| representation of the whole sentence. | |
| Some preselected input tokens are also given global attention: for those few tokens, the attention matrix can access | |
| all tokens and this process is symmetric: all other tokens have access to those specific tokens (on top of the ones in | |
| their local window). This is shown in Figure 2d of the paper, see below for a sample attention mask: | |
| <div class="flex justify-center"> | |
| <img scale="50 %" align="center" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/local_attention_mask.png"/> | |
| </div> | |
| Using those attention matrices with less parameters then allows the model to have inputs having a bigger sequence | |
| length. | |
| ## Other tricks | |
| ### Axial positional encodings | |
| [Reformer](#reformer) uses axial positional encodings: in traditional transformer models, the positional encoding | |
| E is a matrix of size \\(l\\) by \\(d\\), \\(l\\) being the sequence length and \\(d\\) the dimension of the | |
| hidden state. If you have very long texts, this matrix can be huge and take way too much space on the GPU. To alleviate | |
| that, axial positional encodings consist of factorizing that big matrix E in two smaller matrices E1 and E2, with | |
| dimensions \\(l_{1} \times d_{1}\\) and \\(l_{2} \times d_{2}\\), such that \\(l_{1} \times l_{2} = l\\) and | |
| \\(d_{1} + d_{2} = d\\) (with the product for the lengths, this ends up being way smaller). The embedding for time | |
| step \\(j\\) in E is obtained by concatenating the embeddings for timestep \\(j \% l1\\) in E1 and \\(j // l1\\) | |
| in E2. | |