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42573d3
Update whisper_jax/layers.py
Browse files- whisper_jax/layers.py +1 -66
whisper_jax/layers.py
CHANGED
@@ -56,16 +56,6 @@ NdInitializer = Callable[[PRNGKey, Shape, DType, InitializerAxis, InitializerAxi
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default_embed_init = nn.initializers.variance_scaling(1.0, "fan_in", "normal", out_axis=0)
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-
def nd_dense_init(scale, mode, distribution):
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-
"""Initializer with in_axis, out_axis set at call time."""
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-
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def init_fn(key, shape, dtype, in_axis, out_axis):
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fn = variance_scaling(scale, mode, distribution, in_axis, out_axis)
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return fn(key, shape, dtype)
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-
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return init_fn
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-
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-
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def dot_product_attention(
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query: Array,
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key: Array,
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@@ -78,11 +68,9 @@ def dot_product_attention(
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float32_logits: bool = False,
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):
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"""Computes dot-product attention given query, key, and value.
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-
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This is the core function for applying attention based on
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https://arxiv.org/abs/1706.03762. It calculates the attention weights given
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query and key and combines the values using the attention weights.
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-
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Args:
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query: queries for calculating attention with shape of `[batch, q_length,
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num_heads, qk_depth_per_head]`.
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@@ -99,7 +87,6 @@ def dot_product_attention(
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dtype: the dtype of the computation (default: float32)
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float32_logits: bool, if True then compute logits in float32 to avoid
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numerical issues with bfloat16.
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-
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Returns:
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Output of shape `[batch, length, num_heads, v_depth_per_head]`.
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"""
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@@ -145,7 +132,6 @@ dynamic_vector_slice_in_dim = jax.vmap(lax.dynamic_slice_in_dim, in_axes=(None,
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class MultiHeadDotProductAttention(nn.Module):
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"""Multi-head dot-product attention.
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-
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Attributes:
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num_heads: number of attention heads. Features (i.e. inputs_q.shape[-1])
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should be divisible by the number of heads.
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@@ -176,22 +162,18 @@ class MultiHeadDotProductAttention(nn.Module):
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deterministic: bool = False,
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) -> Array:
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"""Applies multi-head dot product attention on the input data.
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-
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Projects the inputs into multi-headed query, key, and value vectors,
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applies dot-product attention and project the results to an output vector.
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-
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There are two modes: decoding and non-decoding (e.g., training). The mode is
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determined by `decode` argument. For decoding, this method is called twice,
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first to initialize the cache and then for an actual decoding process. The
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two calls are differentiated by the presence of 'cached_key' in the variable
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dict. In the cache initialization stage, the cache variables are initialized
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as zeros and will be filled in the subsequent decoding process.
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-
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In the cache initialization call, `inputs_q` has a shape [batch, length,
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q_features] and `inputs_kv`: [batch, length, kv_features]. During the
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incremental decoding stage, query, key and value all have the shape [batch,
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1, qkv_features] corresponding to a single step.
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-
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Args:
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inputs_q: input queries of shape `[batch, q_length, q_features]`.
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inputs_kv: key/values of shape `[batch, kv_length, kv_features]`.
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@@ -199,7 +181,6 @@ class MultiHeadDotProductAttention(nn.Module):
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bias: attention bias of shape `[batch, num_heads, q_length, kv_length]`.
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decode: Whether to prepare and use an autoregressive cache.
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deterministic: Disables dropout if set to True.
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-
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Returns:
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output of shape `[batch, length, q_features]`.
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"""
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@@ -360,7 +341,6 @@ def _canonicalize_tuple(x):
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# ------------------------------------------------------------------------------
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class DenseGeneral(nn.Module):
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"""A linear transformation (without bias) with flexible axes.
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-
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Attributes:
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features: tuple with numbers of output features.
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axis: tuple with axes to apply the transformation on.
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@@ -380,10 +360,8 @@ class DenseGeneral(nn.Module):
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@nn.compact
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def __call__(self, inputs: Array) -> Array:
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"""Applies a linear transformation to the inputs along multiple dimensions.
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-
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Args:
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inputs: The nd-array to be transformed.
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-
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Returns:
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The transformed input.
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"""
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@@ -432,7 +410,6 @@ def _convert_to_activation_function(fn_or_string: Union[str, Callable]) -> Calla
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class MlpBlock(nn.Module):
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"""Transformer MLP / feed-forward block.
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-
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Attributes:
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intermediate_dim: Shared dimension of hidden layers.
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activations: Type of activations for each layer. Each element is either
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@@ -482,7 +459,6 @@ class MlpBlock(nn.Module):
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class Embed(nn.Module):
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"""A parameterized function from integers [0, n) to d-dimensional vectors.
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-
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Attributes:
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num_embeddings: number of embeddings.
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features: number of feature dimensions for each embedding.
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@@ -513,10 +489,8 @@ class Embed(nn.Module):
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def __call__(self, inputs: Array) -> Array:
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"""Embeds the inputs along the last dimension.
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-
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Args:
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inputs: input data, all dimensions are considered batch dimensions.
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-
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Returns:
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Output which is embedded input data. The output shape follows the input,
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with an additional `features` dimension appended.
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@@ -536,11 +510,9 @@ class Embed(nn.Module):
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def attend(self, query: Array) -> Array:
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"""Attend over the embedding using a query array.
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-
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Args:
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query: array with last dimension equal the feature depth `features` of the
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embedding.
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-
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Returns:
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An array with final dim `num_embeddings` corresponding to the batched
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inner-product of the array of query vectors against each embedding.
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@@ -553,7 +525,6 @@ class Embed(nn.Module):
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class RelativePositionBiases(nn.Module):
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"""Adds T5-style relative positional embeddings to the attention logits.
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-
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Attributes:
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num_buckets: Number of buckets to bucket distances between key and query
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positions into.
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@@ -574,7 +545,6 @@ class RelativePositionBiases(nn.Module):
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@staticmethod
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def _relative_position_bucket(relative_position, bidirectional=True, num_buckets=32, max_distance=128):
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"""Translate relative position to a bucket number for relative attention.
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-
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The relative position is defined as memory_position - query_position, i.e.
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the distance in tokens from the attending position to the attended-to
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position. If bidirectional=False, then positive relative positions are
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@@ -585,13 +555,11 @@ class RelativePositionBiases(nn.Module):
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positions <=-max_distance map to the same bucket. This should allow for
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more graceful generalization to longer sequences than the model has been
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trained on.
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-
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Args:
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relative_position: an int32 array
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bidirectional: a boolean - whether the attention is bidirectional
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num_buckets: an integer
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max_distance: an integer
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-
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Returns:
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a Tensor with the same shape as relative_position, containing int32
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values in the range [0, num_buckets)
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@@ -619,13 +587,11 @@ class RelativePositionBiases(nn.Module):
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@nn.compact
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def __call__(self, qlen, klen, bidirectional=True):
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"""Produce relative position embedding attention biases.
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-
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Args:
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qlen: attention query length.
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klen: attention key length.
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bidirectional: whether to allow positive memory-query relative position
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embeddings.
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-
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Returns:
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output: `(1, len, q_len, k_len)` attention bias
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"""
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@@ -749,11 +715,9 @@ def make_attention_mask(
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dtype: DType = jnp.float32,
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) -> Array:
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"""Mask-making helper for attention weights.
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-
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In case of 1d inputs (i.e., `[batch, len_q]`, `[batch, len_kv]`, the
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attention weights will be `[batch, heads, len_q, len_kv]` and this
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function will produce `[batch, 1, len_q, len_kv]`.
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-
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Args:
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query_input: a batched, flat input of query_length size
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key_input: a batched, flat input of key_length size
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@@ -761,7 +725,6 @@ def make_attention_mask(
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extra_batch_dims: number of extra batch dims to add singleton axes for, none
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by default
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dtype: mask return dtype
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-
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Returns:
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A `[batch, 1, len_q, len_kv]` shaped mask for 1d attention.
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"""
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@@ -781,21 +744,17 @@ def make_attention_mask(
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def make_causal_mask(x: Array, extra_batch_dims: int = 0, dtype: DType = jnp.float32) -> Array:
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"""Make a causal mask for self-attention.
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-
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In case of 1d inputs (i.e., `[batch, len]`, the self-attention weights
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will be `[batch, heads, len, len]` and this function will produce a
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causal mask of shape `[batch, 1, len, len]`.
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-
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Note that a causal mask does not depend on the values of x; it only depends on
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the shape. If x has padding elements, they will not be treated in a special
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manner.
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-
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Args:
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x: input array of shape `[batch, len]`
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extra_batch_dims: number of batch dims to add singleton axes for, none by
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default
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dtype: mask return dtype
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-
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Returns:
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A `[batch, 1, len, len]` shaped causal mask for 1d attention.
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"""
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@@ -805,11 +764,9 @@ def make_causal_mask(x: Array, extra_batch_dims: int = 0, dtype: DType = jnp.flo
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def combine_masks(*masks: Optional[Array], dtype: DType = jnp.float32):
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"""Combine attention masks.
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-
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Args:
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*masks: set of attention mask arguments to combine, some can be None.
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dtype: final mask dtype
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-
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Returns:
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Combined mask, reduced by logical and, returns None if no masks given.
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"""
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@@ -827,10 +784,8 @@ def combine_masks(*masks: Optional[Array], dtype: DType = jnp.float32):
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def combine_biases(*masks: Optional[Array]):
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"""Combine attention biases.
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-
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Args:
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*masks: set of attention bias arguments to combine, some can be None.
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-
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Returns:
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Combined mask, reduced by summation, returns None if no masks given.
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"""
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@@ -853,40 +808,30 @@ def make_decoder_mask(
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decoder_segment_ids: Optional[Array] = None,
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) -> Array:
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"""Compute the self-attention mask for a decoder.
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-
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Decoder mask is formed by combining a causal mask, a padding mask and an
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optional packing mask. If decoder_causal_attention is passed, it makes the
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masking non-causal for positions that have value of 1.
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-
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A prefix LM is applied to a dataset which has a notion of "inputs" and
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"targets", e.g., a machine translation task. The inputs and targets are
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concatenated to form a new target. `decoder_target_tokens` is the concatenated
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decoder output tokens.
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-
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The "inputs" portion of the concatenated sequence can attend to other "inputs"
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tokens even for those at a later time steps. In order to control this
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behavior, `decoder_causal_attention` is necessary. This is a binary mask with
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a value of 1 indicating that the position belonged to "inputs" portion of the
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original dataset.
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-
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Example:
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-
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Suppose we have a dataset with two examples.
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-
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ds = [{"inputs": [6, 7], "targets": [8]},
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{"inputs": [3, 4], "targets": [5]}]
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-
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After the data preprocessing with packing, the two examples are packed into
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one example with the following three fields (some fields are skipped for
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simplicity).
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-
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decoder_target_tokens = [[6, 7, 8, 3, 4, 5, 0]]
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decoder_segment_ids = [[1, 1, 1, 2, 2, 2, 0]]
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decoder_causal_attention = [[1, 1, 0, 1, 1, 0, 0]]
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-
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where each array has [batch, length] shape with batch size being 1. Then,
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this function computes the following mask.
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-
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mask = [[[[1, 1, 0, 0, 0, 0, 0],
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[1, 1, 0, 0, 0, 0, 0],
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[1, 1, 1, 0, 0, 0, 0],
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@@ -894,14 +839,11 @@ def make_decoder_mask(
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[0, 0, 0, 1, 1, 0, 0],
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[0, 0, 0, 1, 1, 1, 0],
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[0, 0, 0, 0, 0, 0, 0]]]]
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-
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mask[b, 1, :, :] represents the mask for the example `b` in the batch.
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Because mask is for a self-attention layer, the mask's shape is a square of
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shape [query length, key length].
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-
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mask[b, 1, i, j] = 1 means that the query token at position i can attend to
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the key token at position j.
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-
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Args:
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decoder_target_tokens: decoder output tokens. [batch, length]
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dtype: dtype of the output mask.
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@@ -910,7 +852,6 @@ def make_decoder_mask(
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bidirectionally. [batch, length]
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decoder_segment_ids: decoder segmentation info for packed examples. [batch,
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length]
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-
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Returns:
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the combined decoder mask.
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"""
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@@ -976,7 +917,6 @@ def _conv_dimension_numbers(input_shape):
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class _Conv(nn.Module):
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"""Convolution Module wrapping `lax.conv_general_dilated[_local]`.
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-
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Attributes:
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features: number of convolution filters.
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kernel_size: shape of the convolutional kernel. For 1D convolution,
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@@ -1032,19 +972,16 @@ class _Conv(nn.Module):
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@property
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def shared_weights(self) -> bool: # type: ignore
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"""Defines whether weights are shared or not between different pixels.
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-
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Returns:
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`True` to use shared weights in convolution (regular convolution).
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`False` to use different weights at different pixels, a.k.a.
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"locally connected layer", "unshared convolution", or "local convolution".
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-
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"""
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...
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@nn.compact
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def __call__(self, inputs: Array) -> Array:
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"""Applies a (potentially unshared) convolution to the inputs.
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1047 |
-
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1048 |
Args:
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1049 |
inputs: input data with dimensions (*batch_dims, spatial_dims...,
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1050 |
features). This is the channels-last convention, i.e. NHWC for a 2d
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@@ -1057,7 +994,6 @@ class _Conv(nn.Module):
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better performance than this default flattening approach. If the input
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lacks a batch dimension it will be added for the convolution and removed
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n return, an allowance made to enable writing single-example code.
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-
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Returns:
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The convolved data.
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"""
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@@ -1214,7 +1150,6 @@ class _Conv(nn.Module):
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class Conv(_Conv):
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"""Convolution Module wrapping `lax.conv_general_dilated`.
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1217 |
-
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Attributes:
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features: number of convolution filters.
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kernel_size: shape of the convolutional kernel. For 1D convolution,
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@@ -1252,4 +1187,4 @@ class Conv(_Conv):
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@property
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def shared_weights(self) -> bool:
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-
return True
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default_embed_init = nn.initializers.variance_scaling(1.0, "fan_in", "normal", out_axis=0)
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def dot_product_attention(
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query: Array,
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61 |
key: Array,
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68 |
float32_logits: bool = False,
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69 |
):
|
70 |
"""Computes dot-product attention given query, key, and value.
|
|
|
71 |
This is the core function for applying attention based on
|
72 |
https://arxiv.org/abs/1706.03762. It calculates the attention weights given
|
73 |
query and key and combines the values using the attention weights.
|
|
|
74 |
Args:
|
75 |
query: queries for calculating attention with shape of `[batch, q_length,
|
76 |
num_heads, qk_depth_per_head]`.
|
|
|
87 |
dtype: the dtype of the computation (default: float32)
|
88 |
float32_logits: bool, if True then compute logits in float32 to avoid
|
89 |
numerical issues with bfloat16.
|
|
|
90 |
Returns:
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Output of shape `[batch, length, num_heads, v_depth_per_head]`.
|
92 |
"""
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|
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class MultiHeadDotProductAttention(nn.Module):
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"""Multi-head dot-product attention.
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|
135 |
Attributes:
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136 |
num_heads: number of attention heads. Features (i.e. inputs_q.shape[-1])
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should be divisible by the number of heads.
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|
162 |
deterministic: bool = False,
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) -> Array:
|
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"""Applies multi-head dot product attention on the input data.
|
|
|
165 |
Projects the inputs into multi-headed query, key, and value vectors,
|
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applies dot-product attention and project the results to an output vector.
|
|
|
167 |
There are two modes: decoding and non-decoding (e.g., training). The mode is
|
168 |
determined by `decode` argument. For decoding, this method is called twice,
|
169 |
first to initialize the cache and then for an actual decoding process. The
|
170 |
two calls are differentiated by the presence of 'cached_key' in the variable
|
171 |
dict. In the cache initialization stage, the cache variables are initialized
|
172 |
as zeros and will be filled in the subsequent decoding process.
|
|
|
173 |
In the cache initialization call, `inputs_q` has a shape [batch, length,
|
174 |
q_features] and `inputs_kv`: [batch, length, kv_features]. During the
|
175 |
incremental decoding stage, query, key and value all have the shape [batch,
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176 |
1, qkv_features] corresponding to a single step.
|
|
|
177 |
Args:
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inputs_q: input queries of shape `[batch, q_length, q_features]`.
|
179 |
inputs_kv: key/values of shape `[batch, kv_length, kv_features]`.
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|
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bias: attention bias of shape `[batch, num_heads, q_length, kv_length]`.
|
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decode: Whether to prepare and use an autoregressive cache.
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deterministic: Disables dropout if set to True.
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|
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Returns:
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185 |
output of shape `[batch, length, q_features]`.
|
186 |
"""
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|
341 |
# ------------------------------------------------------------------------------
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342 |
class DenseGeneral(nn.Module):
|
343 |
"""A linear transformation (without bias) with flexible axes.
|
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|
344 |
Attributes:
|
345 |
features: tuple with numbers of output features.
|
346 |
axis: tuple with axes to apply the transformation on.
|
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|
360 |
@nn.compact
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361 |
def __call__(self, inputs: Array) -> Array:
|
362 |
"""Applies a linear transformation to the inputs along multiple dimensions.
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|
363 |
Args:
|
364 |
inputs: The nd-array to be transformed.
|
|
|
365 |
Returns:
|
366 |
The transformed input.
|
367 |
"""
|
|
|
410 |
|
411 |
class MlpBlock(nn.Module):
|
412 |
"""Transformer MLP / feed-forward block.
|
|
|
413 |
Attributes:
|
414 |
intermediate_dim: Shared dimension of hidden layers.
|
415 |
activations: Type of activations for each layer. Each element is either
|
|
|
459 |
|
460 |
class Embed(nn.Module):
|
461 |
"""A parameterized function from integers [0, n) to d-dimensional vectors.
|
|
|
462 |
Attributes:
|
463 |
num_embeddings: number of embeddings.
|
464 |
features: number of feature dimensions for each embedding.
|
|
|
489 |
|
490 |
def __call__(self, inputs: Array) -> Array:
|
491 |
"""Embeds the inputs along the last dimension.
|
|
|
492 |
Args:
|
493 |
inputs: input data, all dimensions are considered batch dimensions.
|
|
|
494 |
Returns:
|
495 |
Output which is embedded input data. The output shape follows the input,
|
496 |
with an additional `features` dimension appended.
|
|
|
510 |
|
511 |
def attend(self, query: Array) -> Array:
|
512 |
"""Attend over the embedding using a query array.
|
|
|
513 |
Args:
|
514 |
query: array with last dimension equal the feature depth `features` of the
|
515 |
embedding.
|
|
|
516 |
Returns:
|
517 |
An array with final dim `num_embeddings` corresponding to the batched
|
518 |
inner-product of the array of query vectors against each embedding.
|
|
|
525 |
|
526 |
class RelativePositionBiases(nn.Module):
|
527 |
"""Adds T5-style relative positional embeddings to the attention logits.
|
|
|
528 |
Attributes:
|
529 |
num_buckets: Number of buckets to bucket distances between key and query
|
530 |
positions into.
|
|
|
545 |
@staticmethod
|
546 |
def _relative_position_bucket(relative_position, bidirectional=True, num_buckets=32, max_distance=128):
|
547 |
"""Translate relative position to a bucket number for relative attention.
|
|
|
548 |
The relative position is defined as memory_position - query_position, i.e.
|
549 |
the distance in tokens from the attending position to the attended-to
|
550 |
position. If bidirectional=False, then positive relative positions are
|
|
|
555 |
positions <=-max_distance map to the same bucket. This should allow for
|
556 |
more graceful generalization to longer sequences than the model has been
|
557 |
trained on.
|
|
|
558 |
Args:
|
559 |
relative_position: an int32 array
|
560 |
bidirectional: a boolean - whether the attention is bidirectional
|
561 |
num_buckets: an integer
|
562 |
max_distance: an integer
|
|
|
563 |
Returns:
|
564 |
a Tensor with the same shape as relative_position, containing int32
|
565 |
values in the range [0, num_buckets)
|
|
|
587 |
@nn.compact
|
588 |
def __call__(self, qlen, klen, bidirectional=True):
|
589 |
"""Produce relative position embedding attention biases.
|
|
|
590 |
Args:
|
591 |
qlen: attention query length.
|
592 |
klen: attention key length.
|
593 |
bidirectional: whether to allow positive memory-query relative position
|
594 |
embeddings.
|
|
|
595 |
Returns:
|
596 |
output: `(1, len, q_len, k_len)` attention bias
|
597 |
"""
|
|
|
715 |
dtype: DType = jnp.float32,
|
716 |
) -> Array:
|
717 |
"""Mask-making helper for attention weights.
|
|
|
718 |
In case of 1d inputs (i.e., `[batch, len_q]`, `[batch, len_kv]`, the
|
719 |
attention weights will be `[batch, heads, len_q, len_kv]` and this
|
720 |
function will produce `[batch, 1, len_q, len_kv]`.
|
|
|
721 |
Args:
|
722 |
query_input: a batched, flat input of query_length size
|
723 |
key_input: a batched, flat input of key_length size
|
|
|
725 |
extra_batch_dims: number of extra batch dims to add singleton axes for, none
|
726 |
by default
|
727 |
dtype: mask return dtype
|
|
|
728 |
Returns:
|
729 |
A `[batch, 1, len_q, len_kv]` shaped mask for 1d attention.
|
730 |
"""
|
|
|
744 |
|
745 |
def make_causal_mask(x: Array, extra_batch_dims: int = 0, dtype: DType = jnp.float32) -> Array:
|
746 |
"""Make a causal mask for self-attention.
|
|
|
747 |
In case of 1d inputs (i.e., `[batch, len]`, the self-attention weights
|
748 |
will be `[batch, heads, len, len]` and this function will produce a
|
749 |
causal mask of shape `[batch, 1, len, len]`.
|
|
|
750 |
Note that a causal mask does not depend on the values of x; it only depends on
|
751 |
the shape. If x has padding elements, they will not be treated in a special
|
752 |
manner.
|
|
|
753 |
Args:
|
754 |
x: input array of shape `[batch, len]`
|
755 |
extra_batch_dims: number of batch dims to add singleton axes for, none by
|
756 |
default
|
757 |
dtype: mask return dtype
|
|
|
758 |
Returns:
|
759 |
A `[batch, 1, len, len]` shaped causal mask for 1d attention.
|
760 |
"""
|
|
|
764 |
|
765 |
def combine_masks(*masks: Optional[Array], dtype: DType = jnp.float32):
|
766 |
"""Combine attention masks.
|
|
|
767 |
Args:
|
768 |
*masks: set of attention mask arguments to combine, some can be None.
|
769 |
dtype: final mask dtype
|
|
|
770 |
Returns:
|
771 |
Combined mask, reduced by logical and, returns None if no masks given.
|
772 |
"""
|
|
|
784 |
|
785 |
def combine_biases(*masks: Optional[Array]):
|
786 |
"""Combine attention biases.
|
|
|
787 |
Args:
|
788 |
*masks: set of attention bias arguments to combine, some can be None.
|
|
|
789 |
Returns:
|
790 |
Combined mask, reduced by summation, returns None if no masks given.
|
791 |
"""
|
|
|
808 |
decoder_segment_ids: Optional[Array] = None,
|
809 |
) -> Array:
|
810 |
"""Compute the self-attention mask for a decoder.
|
|
|
811 |
Decoder mask is formed by combining a causal mask, a padding mask and an
|
812 |
optional packing mask. If decoder_causal_attention is passed, it makes the
|
813 |
masking non-causal for positions that have value of 1.
|
|
|
814 |
A prefix LM is applied to a dataset which has a notion of "inputs" and
|
815 |
"targets", e.g., a machine translation task. The inputs and targets are
|
816 |
concatenated to form a new target. `decoder_target_tokens` is the concatenated
|
817 |
decoder output tokens.
|
|
|
818 |
The "inputs" portion of the concatenated sequence can attend to other "inputs"
|
819 |
tokens even for those at a later time steps. In order to control this
|
820 |
behavior, `decoder_causal_attention` is necessary. This is a binary mask with
|
821 |
a value of 1 indicating that the position belonged to "inputs" portion of the
|
822 |
original dataset.
|
|
|
823 |
Example:
|
|
|
824 |
Suppose we have a dataset with two examples.
|
|
|
825 |
ds = [{"inputs": [6, 7], "targets": [8]},
|
826 |
{"inputs": [3, 4], "targets": [5]}]
|
|
|
827 |
After the data preprocessing with packing, the two examples are packed into
|
828 |
one example with the following three fields (some fields are skipped for
|
829 |
simplicity).
|
|
|
830 |
decoder_target_tokens = [[6, 7, 8, 3, 4, 5, 0]]
|
831 |
decoder_segment_ids = [[1, 1, 1, 2, 2, 2, 0]]
|
832 |
decoder_causal_attention = [[1, 1, 0, 1, 1, 0, 0]]
|
|
|
833 |
where each array has [batch, length] shape with batch size being 1. Then,
|
834 |
this function computes the following mask.
|
|
|
835 |
mask = [[[[1, 1, 0, 0, 0, 0, 0],
|
836 |
[1, 1, 0, 0, 0, 0, 0],
|
837 |
[1, 1, 1, 0, 0, 0, 0],
|
|
|
839 |
[0, 0, 0, 1, 1, 0, 0],
|
840 |
[0, 0, 0, 1, 1, 1, 0],
|
841 |
[0, 0, 0, 0, 0, 0, 0]]]]
|
|
|
842 |
mask[b, 1, :, :] represents the mask for the example `b` in the batch.
|
843 |
Because mask is for a self-attention layer, the mask's shape is a square of
|
844 |
shape [query length, key length].
|
|
|
845 |
mask[b, 1, i, j] = 1 means that the query token at position i can attend to
|
846 |
the key token at position j.
|
|
|
847 |
Args:
|
848 |
decoder_target_tokens: decoder output tokens. [batch, length]
|
849 |
dtype: dtype of the output mask.
|
|
|
852 |
bidirectionally. [batch, length]
|
853 |
decoder_segment_ids: decoder segmentation info for packed examples. [batch,
|
854 |
length]
|
|
|
855 |
Returns:
|
856 |
the combined decoder mask.
|
857 |
"""
|
|
|
917 |
|
918 |
class _Conv(nn.Module):
|
919 |
"""Convolution Module wrapping `lax.conv_general_dilated[_local]`.
|
|
|
920 |
Attributes:
|
921 |
features: number of convolution filters.
|
922 |
kernel_size: shape of the convolutional kernel. For 1D convolution,
|
|
|
972 |
@property
|
973 |
def shared_weights(self) -> bool: # type: ignore
|
974 |
"""Defines whether weights are shared or not between different pixels.
|
|
|
975 |
Returns:
|
976 |
`True` to use shared weights in convolution (regular convolution).
|
977 |
`False` to use different weights at different pixels, a.k.a.
|
978 |
"locally connected layer", "unshared convolution", or "local convolution".
|
|
|
979 |
"""
|
980 |
...
|
981 |
|
982 |
@nn.compact
|
983 |
def __call__(self, inputs: Array) -> Array:
|
984 |
"""Applies a (potentially unshared) convolution to the inputs.
|
|
|
985 |
Args:
|
986 |
inputs: input data with dimensions (*batch_dims, spatial_dims...,
|
987 |
features). This is the channels-last convention, i.e. NHWC for a 2d
|
|
|
994 |
better performance than this default flattening approach. If the input
|
995 |
lacks a batch dimension it will be added for the convolution and removed
|
996 |
n return, an allowance made to enable writing single-example code.
|
|
|
997 |
Returns:
|
998 |
The convolved data.
|
999 |
"""
|
|
|
1150 |
|
1151 |
class Conv(_Conv):
|
1152 |
"""Convolution Module wrapping `lax.conv_general_dilated`.
|
|
|
1153 |
Attributes:
|
1154 |
features: number of convolution filters.
|
1155 |
kernel_size: shape of the convolutional kernel. For 1D convolution,
|
|
|
1187 |
|
1188 |
@property
|
1189 |
def shared_weights(self) -> bool:
|
1190 |
+
return True
|