Scan and Snap: Understanding Training Dynamics and Token Composition in 1-layer Transformer
Transformer architecture has shown impressive performance in multiple
research domains and has become the backbone of many neural network models.
However, there is limited understanding on how it works. In particular, with a
simple predictive loss, how the representation emerges from the gradient
\emph{training dynamics} remains a mystery. In this paper, for 1-layer
transformer with one self-attention layer plus one decoder layer, we analyze
its SGD training dynamics for the task of next token prediction in a
mathematically rigorous manner. We open the black box of the dynamic process of
how the self-attention layer combines input tokens, and reveal the nature of
underlying inductive bias. More specifically, with the assumption (a) no
positional encoding, (b) long input sequence, and (c) the decoder layer learns
faster than the self-attention layer, we prove that self-attention acts as a
\emph{discriminative scanning algorithm}: starting from uniform attention, it
gradually attends more to distinct key tokens for a specific next token to be
predicted, and pays less attention to common key tokens that occur across
different next tokens. Among distinct tokens, it progressively drops attention
weights, following the order of low to high co-occurrence between the key and
the query token in the training set. Interestingly, this procedure does not
lead to winner-takes-all, but decelerates due to a \emph{phase transition} that
is controllable by the learning rates of the two layers, leaving (almost) fixed
token combination. We verify this \textbf{\emph{scan and snap}} dynamics on
synthetic and real-world data (WikiText).