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# coding=utf-8 | |
# Copyright 2023 The T5X Authors and The HuggingFace Inc. team. | |
# | |
# Licensed under the Apache License, Version 2.0 (the "License"); | |
# you may not use this file except in compliance with the License. | |
# You may obtain a copy of the License at | |
# | |
# http://www.apache.org/licenses/LICENSE-2.0 | |
# | |
# Unless required by applicable law or agreed to in writing, software | |
# distributed under the License is distributed on an "AS IS" BASIS, | |
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. | |
# See the License for the specific language governing permissions and | |
# limitations under the License. | |
"""Dense attention classes and mask/weighting functions.""" | |
# pylint: disable=attribute-defined-outside-init,g-bare-generic | |
import dataclasses | |
import functools | |
import operator | |
from typing import Any, Callable, Iterable, List, Optional, Sequence, Tuple, Union | |
import jax | |
import jax.numpy as jnp | |
import numpy as np | |
from flax import linen as nn | |
from flax.linen import partitioning as nn_partitioning | |
from flax.linen.dtypes import promote_dtype | |
from jax import lax, random | |
# from flax.linen.partitioning import param_with_axes, with_sharding_constraint | |
param_with_axes = nn_partitioning.param_with_axes | |
with_sharding_constraint = nn_partitioning.with_sharding_constraint | |
# Type annotations | |
Array = jnp.ndarray | |
DType = jnp.dtype | |
PRNGKey = jnp.ndarray | |
Shape = Iterable[int] | |
Activation = Callable[..., Array] | |
PrecisionLike = Union[None, str, lax.Precision, Tuple[str, str], Tuple[lax.Precision, lax.Precision]] | |
DotGeneralT = Callable[..., Array] | |
ConvGeneralDilatedT = Callable[..., Array] | |
PaddingLike = Union[str, int, Sequence[Union[int, Tuple[int, int]]]] | |
LaxPadding = Union[str, Sequence[Tuple[int, int]]] | |
# Parameter initializers. | |
Initializer = Callable[[PRNGKey, Shape, DType], Array] | |
InitializerAxis = Union[int, Tuple[int, ...]] | |
NdInitializer = Callable[[PRNGKey, Shape, DType, InitializerAxis, InitializerAxis], Array] | |
default_embed_init = nn.initializers.variance_scaling(1.0, "fan_in", "normal", out_axis=0) | |
# ------------------------------------------------------------------------------ | |
# Temporary inlined JAX N-d initializer code | |
# TODO(levskaya): remove once new JAX release is out. | |
# ------------------------------------------------------------------------------ | |
def _compute_fans(shape: jax.core.NamedShape, in_axis=-2, out_axis=-1): | |
"""Inlined JAX `nn.initializer._compute_fans`.""" | |
if isinstance(in_axis, int): | |
in_size = shape[in_axis] | |
else: | |
in_size = int(np.prod([shape[i] for i in in_axis])) | |
if isinstance(out_axis, int): | |
out_size = shape[out_axis] | |
else: | |
out_size = int(np.prod([shape[i] for i in out_axis])) | |
receptive_field_size = shape.total / in_size / out_size | |
fan_in = in_size * receptive_field_size | |
fan_out = out_size * receptive_field_size | |
return fan_in, fan_out | |
def variance_scaling(scale, mode, distribution, in_axis=-2, out_axis=-1, dtype=jnp.float_): | |
"""Inlined JAX `nn.initializer.variance_scaling`.""" | |
def init(key, shape, dtype=dtype): | |
return jnp.zeros(shape, dtype=dtype) | |
dtype = jax.dtypes.canonicalize_dtype(dtype) | |
shape = jax.core.as_named_shape(shape) | |
fan_in, fan_out = _compute_fans(shape, in_axis, out_axis) | |
if mode == "fan_in": | |
denominator = fan_in | |
elif mode == "fan_out": | |
denominator = fan_out | |
elif mode == "fan_avg": | |
denominator = (fan_in + fan_out) / 2 | |
else: | |
raise ValueError("invalid mode for variance scaling initializer: {}".format(mode)) | |
variance = jnp.array(scale / denominator, dtype=dtype) | |
if distribution == "truncated_normal": | |
# constant is stddev of standard normal truncated to (-2, 2) | |
stddev = jnp.sqrt(variance) / jnp.array(0.87962566103423978, dtype) | |
return random.truncated_normal(key, -2, 2, shape, dtype) * stddev | |
elif distribution == "normal": | |
return random.normal(key, shape, dtype) * jnp.sqrt(variance) | |
elif distribution == "uniform": | |
return random.uniform(key, shape, dtype, -1) * jnp.sqrt(3 * variance) | |
else: | |
raise ValueError("invalid distribution for variance scaling " "initializer: {}".format(distribution)) | |
return init | |
# ------------------------------------------------------------------------------ | |
def nd_dense_init(scale, mode, distribution): | |
"""Initializer with in_axis, out_axis set at call time.""" | |
def init_fn(key, shape, dtype, in_axis, out_axis): | |
fn = variance_scaling(scale, mode, distribution, in_axis, out_axis) | |
return fn(key, shape, dtype) | |
return init_fn | |
def dot_product_attention( | |
query: Array, | |
key: Array, | |
value: Array, | |
bias: Optional[Array] = None, | |
dropout_rng: Optional[PRNGKey] = None, | |
dropout_rate: float = 0.0, | |
deterministic: bool = False, | |
dtype: DType = jnp.float32, | |
float32_logits: bool = False, | |
): | |
"""Computes dot-product attention given query, key, and value. | |
This is the core function for applying attention based on | |
https://arxiv.org/abs/1706.03762. It calculates the attention weights given | |
query and key and combines the values using the attention weights. | |
Args: | |
query: queries for calculating attention with shape of `[batch, q_length, | |
num_heads, qk_depth_per_head]`. | |
key: keys for calculating attention with shape of `[batch, kv_length, | |
num_heads, qk_depth_per_head]`. | |
value: values to be used in attention with shape of `[batch, kv_length, | |
num_heads, v_depth_per_head]`. | |
bias: bias for the attention weights. This should be broadcastable to the | |
shape `[batch, num_heads, q_length, kv_length]` This can be used for | |
incorporating causal masks, padding masks, proximity bias, etc. | |
dropout_rng: JAX PRNGKey: to be used for dropout | |
dropout_rate: dropout rate | |
deterministic: bool, deterministic or not (to apply dropout) | |
dtype: the dtype of the computation (default: float32) | |
float32_logits: bool, if True then compute logits in float32 to avoid | |
numerical issues with bfloat16. | |
Returns: | |
Output of shape `[batch, length, num_heads, v_depth_per_head]`. | |
""" | |
assert key.ndim == query.ndim == value.ndim, "q, k, v must have same rank." | |
assert query.shape[:-3] == key.shape[:-3] == value.shape[:-3], "q, k, v batch dims must match." | |
assert query.shape[-2] == key.shape[-2] == value.shape[-2], "q, k, v num_heads must match." | |
assert key.shape[-3] == value.shape[-3], "k, v lengths must match." | |
assert query.shape[-1] == key.shape[-1], "q, k depths must match." | |
# Casting logits and softmax computation for float32 for model stability. | |
if float32_logits: | |
query = query.astype(jnp.float32) | |
key = key.astype(jnp.float32) | |
# `attn_weights`: [batch, num_heads, q_length, kv_length] | |
attn_weights = jnp.einsum("bqhd,bkhd->bhqk", query, key) | |
# Apply attention bias: masking, dropout, proximity bias, etc. | |
if bias is not None: | |
attn_weights = attn_weights + bias.astype(attn_weights.dtype) | |
# Normalize the attention weights across `kv_length` dimension. | |
attn_weights = jax.nn.softmax(attn_weights).astype(dtype) | |
# Apply attention dropout. | |
if not deterministic and dropout_rate > 0.0: | |
keep_prob = 1.0 - dropout_rate | |
# T5 broadcasts along the "length" dim, but unclear which one that | |
# corresponds to in positional dimensions here, assuming query dim. | |
dropout_shape = list(attn_weights.shape) | |
dropout_shape[-2] = 1 | |
keep = random.bernoulli(dropout_rng, keep_prob, dropout_shape) | |
keep = jnp.broadcast_to(keep, attn_weights.shape) | |
multiplier = keep.astype(attn_weights.dtype) / jnp.asarray(keep_prob, dtype=dtype) | |
attn_weights = attn_weights * multiplier | |
# Take the linear combination of `value`. | |
return jnp.einsum("bhqk,bkhd->bqhd", attn_weights, value) | |
dynamic_vector_slice_in_dim = jax.vmap(lax.dynamic_slice_in_dim, in_axes=(None, 0, None, None)) | |
class MultiHeadDotProductAttention(nn.Module): | |
"""Multi-head dot-product attention. | |
Attributes: | |
num_heads: number of attention heads. Features (i.e. inputs_q.shape[-1]) | |
should be divisible by the number of heads. | |
head_dim: dimension of each head. | |
dtype: the dtype of the computation. | |
dropout_rate: dropout rate | |
kernel_init: initializer for the kernel of the Dense layers. | |
float32_logits: bool, if True then compute logits in float32 to avoid | |
numerical issues with bfloat16. | |
""" | |
num_heads: int | |
head_dim: int | |
dtype: DType = jnp.float32 | |
dropout_rate: float = 0.0 | |
kernel_init: NdInitializer = nd_dense_init(1.0, "fan_in", "normal") | |
float32_logits: bool = False # computes logits in float32 for stability. | |
def __call__( | |
self, | |
inputs_q: Array, | |
inputs_kv: Array, | |
mask: Optional[Array] = None, | |
bias: Optional[Array] = None, | |
*, | |
decode: bool = False, | |
deterministic: bool = False, | |
) -> Array: | |
"""Applies multi-head dot product attention on the input data. | |
Projects the inputs into multi-headed query, key, and value vectors, | |
applies dot-product attention and project the results to an output vector. | |
There are two modes: decoding and non-decoding (e.g., training). The mode is | |
determined by `decode` argument. For decoding, this method is called twice, | |
first to initialize the cache and then for an actual decoding process. The | |
two calls are differentiated by the presence of 'cached_key' in the variable | |
dict. In the cache initialization stage, the cache variables are initialized | |
as zeros and will be filled in the subsequent decoding process. | |
In the cache initialization call, `inputs_q` has a shape [batch, length, | |
q_features] and `inputs_kv`: [batch, length, kv_features]. During the | |
incremental decoding stage, query, key and value all have the shape [batch, | |
1, qkv_features] corresponding to a single step. | |
Args: | |
inputs_q: input queries of shape `[batch, q_length, q_features]`. | |
inputs_kv: key/values of shape `[batch, kv_length, kv_features]`. | |
mask: attention mask of shape `[batch, num_heads, q_length, kv_length]`. | |
bias: attention bias of shape `[batch, num_heads, q_length, kv_length]`. | |
decode: Whether to prepare and use an autoregressive cache. | |
deterministic: Disables dropout if set to True. | |
Returns: | |
output of shape `[batch, length, q_features]`. | |
""" | |
projection = functools.partial( | |
DenseGeneral, | |
axis=-1, | |
features=(self.num_heads, self.head_dim), | |
kernel_axes=("embed", "heads", "kv"), | |
dtype=self.dtype, | |
) | |
# NOTE: T5 does not explicitly rescale the attention logits by | |
# 1/sqrt(depth_kq)! This is folded into the initializers of the | |
# linear transformations, which is equivalent under Adafactor. | |
depth_scaling = jnp.sqrt(self.head_dim).astype(self.dtype) | |
def query_init(*args): | |
return self.kernel_init(*args) / depth_scaling | |
# Project inputs_q to multi-headed q/k/v | |
# dimensions are then [batch, length, num_heads, head_dim] | |
query = projection(kernel_init=query_init, name="query")(inputs_q) | |
key = projection(kernel_init=self.kernel_init, name="key")(inputs_kv) | |
value = projection(kernel_init=self.kernel_init, name="value")(inputs_kv) | |
query = with_sharding_constraint(query, ("batch", "length", "heads", "kv")) | |
key = with_sharding_constraint(key, ("batch", "length", "heads", "kv")) | |
value = with_sharding_constraint(value, ("batch", "length", "heads", "kv")) | |
if decode: | |
# Detect if we're initializing by absence of existing cache data. | |
is_initialized = self.has_variable("cache", "cached_key") | |
# The key and value have dimension [batch, length, num_heads, head_dim], | |
# but we cache them as [batch, num_heads, head_dim, length] as a TPU | |
# fusion optimization. This also enables the "scatter via one-hot | |
# broadcast" trick, which means we do a one-hot broadcast instead of a | |
# scatter/gather operations, resulting in a 3-4x speedup in practice. | |
def swap_dims(x): | |
return x[:-3] + tuple(x[i] for i in [-2, -1, -3]) | |
cached_key = self.variable("cache", "cached_key", jnp.zeros, swap_dims(key.shape), key.dtype) | |
cached_value = self.variable("cache", "cached_value", jnp.zeros, swap_dims(value.shape), value.dtype) | |
cache_index = self.variable("cache", "cache_index", lambda: jnp.array(0, dtype=jnp.int32)) | |
if is_initialized: | |
batch, num_heads, head_dim, length = cached_key.value.shape | |
# During fast autoregressive decoding, we feed one position at a time, | |
# and cache the keys and values step by step. | |
# Sanity shape check of cached key against input query. | |
expected_shape = (batch, 1, num_heads, head_dim) | |
if expected_shape != query.shape: | |
raise ValueError( | |
"Autoregressive cache shape error, " | |
"expected query shape %s instead got %s." % (expected_shape, query.shape) | |
) | |
# Create a OHE of the current index. NOTE: the index is increased below. | |
cur_index = cache_index.value | |
one_hot_indices = jax.nn.one_hot(cur_index, length, dtype=key.dtype) | |
# In order to update the key, value caches with the current key and | |
# value, we move the length axis to the back, similar to what we did for | |
# the cached ones above. | |
# Note these are currently the key and value of a single position, since | |
# we feed one position at a time. | |
one_token_key = jnp.moveaxis(key, -3, -1) | |
one_token_value = jnp.moveaxis(value, -3, -1) | |
# Update key, value caches with our new 1d spatial slices. | |
# We implement an efficient scatter into the cache via one-hot | |
# broadcast and addition. | |
key = cached_key.value + one_token_key * one_hot_indices | |
value = cached_value.value + one_token_value * one_hot_indices | |
cached_key.value = key | |
cached_value.value = value | |
cache_index.value = cache_index.value + 1 | |
# Move the keys and values back to their original shapes. | |
key = jnp.moveaxis(key, -1, -3) | |
value = jnp.moveaxis(value, -1, -3) | |
# Causal mask for cached decoder self-attention: our single query | |
# position should only attend to those key positions that have already | |
# been generated and cached, not the remaining zero elements. | |
mask = combine_masks( | |
mask, | |
jnp.broadcast_to( | |
jnp.arange(length) <= cur_index, | |
# (1, 1, length) represent (head dim, query length, key length) | |
# query length is 1 because during decoding we deal with one | |
# index. | |
# The same mask is applied to all batch elements and heads. | |
(batch, 1, 1, length), | |
), | |
) | |
# Grab the correct relative attention bias during decoding. This is | |
# only required during single step decoding. | |
if bias is not None: | |
# The bias is a full attention matrix, but during decoding we only | |
# have to take a slice of it. | |
# This is equivalent to bias[..., cur_index:cur_index+1, :]. | |
bias = dynamic_vector_slice_in_dim(jnp.squeeze(bias, axis=0), jnp.reshape(cur_index, (-1)), 1, -2) | |
# Convert the boolean attention mask to an attention bias. | |
if mask is not None: | |
# attention mask in the form of attention bias | |
attention_bias = lax.select( | |
mask > 0, jnp.full(mask.shape, 0.0).astype(self.dtype), jnp.full(mask.shape, -1e10).astype(self.dtype) | |
) | |
else: | |
attention_bias = None | |
# Add provided bias term (e.g. relative position embedding). | |
if bias is not None: | |
attention_bias = combine_biases(attention_bias, bias) | |
dropout_rng = None | |
if not deterministic and self.dropout_rate > 0.0: | |
dropout_rng = self.make_rng("dropout") | |
# Apply attention. | |
x = dot_product_attention( | |
query, | |
key, | |
value, | |
bias=attention_bias, | |
dropout_rng=dropout_rng, | |
dropout_rate=self.dropout_rate, | |
deterministic=deterministic, | |
dtype=self.dtype, | |
float32_logits=self.float32_logits, | |
) | |
# Back to the original inputs dimensions. | |
out = DenseGeneral( | |
features=inputs_q.shape[-1], # output dim is set to the input dim. | |
axis=(-2, -1), | |
kernel_init=self.kernel_init, | |
kernel_axes=("heads", "kv", "embed"), | |
dtype=self.dtype, | |
name="out", | |
)(x) | |
return out | |
def _normalize_axes(axes: Iterable[int], ndim: int) -> Tuple[int]: | |
# A tuple by convention. len(axes_tuple) then also gives the rank efficiently. | |
return tuple([ax if ax >= 0 else ndim + ax for ax in axes]) | |
def _canonicalize_tuple(x): | |
if isinstance(x, Iterable): | |
return tuple(x) | |
else: | |
return (x,) | |
# ------------------------------------------------------------------------------ | |
# DenseGeneral for attention layers. | |
# ------------------------------------------------------------------------------ | |
class DenseGeneral(nn.Module): | |
"""A linear transformation (without bias) with flexible axes. | |
Attributes: | |
features: tuple with numbers of output features. | |
axis: tuple with axes to apply the transformation on. | |
dtype: the dtype of the computation (default: float32). | |
kernel_init: initializer function for the weight matrix. | |
""" | |
features: Union[Iterable[int], int] | |
axis: Union[Iterable[int], int] = -1 | |
dtype: DType = jnp.float32 | |
params_dtype: DType = jnp.float32 | |
kernel_init: NdInitializer = nd_dense_init(1.0, "fan_in", "normal") | |
kernel_axes: Tuple[str, ...] = () | |
use_bias: bool = True | |
bias_init: Any = nn.initializers.zeros | |
def __call__(self, inputs: Array) -> Array: | |
"""Applies a linear transformation to the inputs along multiple dimensions. | |
Args: | |
inputs: The nd-array to be transformed. | |
Returns: | |
The transformed input. | |
""" | |
features = _canonicalize_tuple(self.features) | |
axis = _canonicalize_tuple(self.axis) | |
inputs = jnp.asarray(inputs, self.dtype) | |
axis = _normalize_axes(axis, inputs.ndim) | |
kernel_shape = tuple([inputs.shape[ax] for ax in axis]) + features | |
kernel_in_axis = np.arange(len(axis)) | |
kernel_out_axis = np.arange(len(axis), len(axis) + len(features)) | |
kernel = param_with_axes( | |
"kernel", | |
self.kernel_init, | |
kernel_shape, | |
self.params_dtype, | |
kernel_in_axis, | |
kernel_out_axis, | |
axes=self.kernel_axes, | |
) | |
if self.use_bias: | |
bias = param_with_axes("bias", self.bias_init, features, self.params_dtype, axes=(self.kernel_axes[-1],)) | |
kernel = jnp.asarray(kernel, self.dtype) | |
contract_ind = tuple(range(0, len(axis))) | |
y = lax.dot_general(inputs, kernel, ((axis, contract_ind), ((), ()))) | |
if self.use_bias: | |
bias = jnp.asarray(bias, self.dtype) | |
# y += jnp.reshape(bias, (1,) * (y.ndim - 1) + (-1,)) | |
y += jnp.reshape(bias, (1,) * (len(features) - y.ndim) + bias.shape[:]) | |
return y | |
def _convert_to_activation_function(fn_or_string: Union[str, Callable]) -> Callable: | |
"""Convert a string to an activation function.""" | |
if fn_or_string == "linear": | |
return lambda x: x | |
elif isinstance(fn_or_string, str): | |
return getattr(nn, fn_or_string) | |
elif callable(fn_or_string): | |
return fn_or_string | |
else: | |
raise ValueError("don't know how to convert %s to an activation function" % (fn_or_string,)) | |
class MlpBlock(nn.Module): | |
"""Transformer MLP / feed-forward block. | |
Attributes: | |
intermediate_dim: Shared dimension of hidden layers. | |
activations: Type of activations for each layer. Each element is either | |
'linear', a string function name in flax.linen, or a function. | |
kernel_init: Kernel function, passed to the dense layers. | |
deterministic: Whether the dropout layers should be deterministic. | |
intermediate_dropout_rate: Dropout rate used after the intermediate layers. | |
dtype: Type for the dense layer. | |
""" | |
intermediate_dim: int = 2048 | |
activations: Sequence[Union[str, Callable]] = ("relu",) | |
kernel_init: NdInitializer = nd_dense_init(1.0, "fan_in", "truncated_normal") | |
intermediate_dropout_rate: float = 0.1 | |
dtype: Any = jnp.float32 | |
def __call__(self, inputs, decode: bool = False, deterministic: bool = False): | |
"""Applies Transformer MlpBlock module.""" | |
# Iterate over specified MLP input activation functions. | |
# e.g. ('relu',) or ('gelu', 'linear') for gated-gelu. | |
activations = [] | |
for idx, act_fn in enumerate(self.activations): | |
dense_name = "wi" if len(self.activations) == 1 else f"wi_{idx}" | |
x = DenseGeneral( | |
self.intermediate_dim, | |
dtype=self.dtype, | |
kernel_init=self.kernel_init, | |
kernel_axes=("embed", "mlp"), | |
name=dense_name, | |
)(inputs) | |
x = _convert_to_activation_function(act_fn)(x) | |
activations.append(x) | |
# Take elementwise product of above intermediate activations. | |
x = functools.reduce(operator.mul, activations) | |
# Apply dropout and final dense output projection. | |
x = nn.Dropout(rate=self.intermediate_dropout_rate, broadcast_dims=(-2,))( | |
x, deterministic=deterministic | |
) # Broadcast along length. | |
x = with_sharding_constraint(x, ("batch", "length", "mlp")) | |
output = DenseGeneral( | |
inputs.shape[-1], dtype=self.dtype, kernel_init=self.kernel_init, kernel_axes=("mlp", "embed"), name="wo" | |
)(x) | |
return output | |
class Embed(nn.Module): | |
"""A parameterized function from integers [0, n) to d-dimensional vectors. | |
Attributes: | |
num_embeddings: number of embeddings. | |
features: number of feature dimensions for each embedding. | |
dtype: the dtype of the embedding vectors (default: float32). | |
embedding_init: embedding initializer. | |
one_hot: performs the gather with a one-hot contraction rather than a true | |
gather. This is currently needed for SPMD partitioning. | |
""" | |
num_embeddings: int | |
features: int | |
cast_input_dtype: Optional[DType] = None | |
dtype: DType = jnp.float32 | |
params_dtype: DType = jnp.float32 | |
attend_dtype: Optional[DType] = None | |
embedding_init: Initializer = default_embed_init | |
one_hot: bool = True | |
embedding: Array = dataclasses.field(init=False) | |
def setup(self): | |
self.embedding = param_with_axes( | |
"embedding", | |
self.embedding_init, | |
(self.num_embeddings, self.features), | |
self.params_dtype, | |
axes=("vocab", "embed"), | |
) | |
def __call__(self, inputs: Array) -> Array: | |
"""Embeds the inputs along the last dimension. | |
Args: | |
inputs: input data, all dimensions are considered batch dimensions. | |
Returns: | |
Output which is embedded input data. The output shape follows the input, | |
with an additional `features` dimension appended. | |
""" | |
if self.cast_input_dtype: | |
inputs = inputs.astype(self.cast_input_dtype) | |
if not jnp.issubdtype(inputs.dtype, jnp.integer): | |
raise ValueError("Input type must be an integer or unsigned integer.") | |
if self.one_hot: | |
iota = lax.iota(jnp.int32, self.num_embeddings) | |
one_hot = jnp.array(inputs[..., jnp.newaxis] == iota, dtype=self.dtype) | |
output = jnp.dot(one_hot, jnp.asarray(self.embedding, self.dtype)) | |
else: | |
output = jnp.asarray(self.embedding, self.dtype)[inputs] | |
output = with_sharding_constraint(output, ("batch", "length", "embed")) | |
return output | |
def attend(self, query: Array) -> Array: | |
"""Attend over the embedding using a query array. | |
Args: | |
query: array with last dimension equal the feature depth `features` of the | |
embedding. | |
Returns: | |
An array with final dim `num_embeddings` corresponding to the batched | |
inner-product of the array of query vectors against each embedding. | |
Commonly used for weight-sharing between embeddings and logit transform | |
in NLP models. | |
""" | |
dtype = self.attend_dtype if self.attend_dtype is not None else self.dtype | |
return jnp.dot(query, jnp.asarray(self.embedding, dtype).T) | |
class RelativePositionBiases(nn.Module): | |
"""Adds T5-style relative positional embeddings to the attention logits. | |
Attributes: | |
num_buckets: Number of buckets to bucket distances between key and query | |
positions into. | |
max_distance: Maximum distance before everything is lumped into the last | |
distance bucket. | |
num_heads: Number of heads in the attention layer. Each head will get a | |
different relative position weighting. | |
dtype: Type of arrays through this module. | |
embedding_init: initializer for relative embedding table. | |
""" | |
num_buckets: int | |
max_distance: int | |
num_heads: int | |
dtype: Any | |
embedding_init: Callable[..., Array] = nn.linear.default_embed_init | |
def _relative_position_bucket(relative_position, bidirectional=True, num_buckets=32, max_distance=128): | |
"""Translate relative position to a bucket number for relative attention. | |
The relative position is defined as memory_position - query_position, i.e. | |
the distance in tokens from the attending position to the attended-to | |
position. If bidirectional=False, then positive relative positions are | |
invalid. | |
We use smaller buckets for small absolute relative_position and larger | |
buckets for larger absolute relative_positions. All relative | |
positions >=max_distance map to the same bucket. All relative | |
positions <=-max_distance map to the same bucket. This should allow for | |
more graceful generalization to longer sequences than the model has been | |
trained on. | |
Args: | |
relative_position: an int32 array | |
bidirectional: a boolean - whether the attention is bidirectional | |
num_buckets: an integer | |
max_distance: an integer | |
Returns: | |
a Tensor with the same shape as relative_position, containing int32 | |
values in the range [0, num_buckets) | |
""" | |
ret = 0 | |
n = -relative_position | |
if bidirectional: | |
num_buckets //= 2 | |
ret += (n < 0).astype(np.int32) * num_buckets | |
n = np.abs(n) | |
else: | |
n = np.maximum(n, 0) | |
# now n is in the range [0, inf) | |
max_exact = num_buckets // 2 | |
is_small = n < max_exact | |
val_if_large = max_exact + ( | |
np.log(n.astype(np.float32) / max_exact + np.finfo(np.float32).eps) | |
/ np.log(max_distance / max_exact) | |
* (num_buckets - max_exact) | |
).astype(np.int32) | |
val_if_large = np.minimum(val_if_large, num_buckets - 1) | |
ret += np.where(is_small, n, val_if_large) | |
return ret | |
def __call__(self, qlen, klen, bidirectional=True): | |
"""Produce relative position embedding attention biases. | |
Args: | |
qlen: attention query length. | |
klen: attention key length. | |
bidirectional: whether to allow positive memory-query relative position | |
embeddings. | |
Returns: | |
output: `(1, len, q_len, k_len)` attention bias | |
""" | |
# TODO(levskaya): should we be computing this w. numpy as a program | |
# constant? | |
context_position = np.arange(qlen, dtype=jnp.int32)[:, None] | |
memory_position = np.arange(klen, dtype=jnp.int32)[None, :] | |
relative_position = memory_position - context_position # shape (qlen, klen) | |
rp_bucket = self._relative_position_bucket( | |
relative_position, | |
bidirectional=bidirectional, | |
num_buckets=self.num_buckets, | |
max_distance=self.max_distance, | |
) | |
relative_attention_bias = param_with_axes( | |
"rel_embedding", | |
self.embedding_init, | |
(self.num_heads, self.num_buckets), | |
jnp.float32, | |
axes=("heads", "relpos_buckets"), | |
) | |
relative_attention_bias = jnp.asarray(relative_attention_bias, self.dtype) | |
# Instead of using a slow gather, we create a leading-dimension one-hot | |
# array from rp_bucket and use it to perform the gather-equivalent via a | |
# contraction, i.e.: | |
# (num_head, num_buckets) x (num_buckets one-hot, qlen, klen). | |
# This is equivalent to relative_attention_bias[:, rp_bucket] | |
bcast_iota = lax.broadcasted_iota(jnp.int32, (self.num_buckets, 1, 1), 0) | |
rp_bucket_one_hot = jnp.array(rp_bucket[jnp.newaxis, ...] == bcast_iota, dtype=self.dtype) | |
# --> shape (qlen, klen, num_heads) | |
values = lax.dot_general( | |
relative_attention_bias, rp_bucket_one_hot, (((1,), (0,)), ((), ())) # rhs, lhs contracting dims | |
) # no batched dims | |
# Add a singleton batch dimension. | |
# --> shape (1, num_heads, qlen, klen) | |
return values[jnp.newaxis, ...] | |
# ------------------------------------------------------------------------------ | |
# T5 Layernorm - no subtraction of mean or bias. | |
# ------------------------------------------------------------------------------ | |
# class LayerNorm(nn.Module): | |
# """T5 Layer normalization operating on the last axis of the input data.""" | |
# epsilon: float = 1e-6 | |
# dtype: Any = jnp.float32 | |
# scale_init: Initializer = nn.initializers.ones | |
# @nn.compact | |
# def __call__(self, x: jnp.ndarray) -> jnp.ndarray: | |
# """Applies layer normalization on the input.""" | |
# x = jnp.asarray(x, jnp.float32) | |
# features = x.shape[-1] | |
# mean2 = jnp.mean(lax.square(x), axis=-1, keepdims=True) | |
# y = jnp.asarray(x * lax.rsqrt(mean2 + self.epsilon), self.dtype) | |
# scale = param_with_axes( | |
# 'scale', self.scale_init, (features,), jnp.float32, axes=('embed',)) | |
# scale = jnp.asarray(scale, self.dtype) | |
# return y * scale | |
class LayerNorm(nn.Module): | |
"""Layer normalization (https://arxiv.org/abs/1607.06450). | |
Operates on the last axis of the input data. | |
It normalizes the activations of the layer for each given example in a | |
batch independently, rather than across a batch like Batch Normalization. | |
i.e. applies a transformation that maintains the mean activation within | |
each example close to 0 and the activation standard deviation close to 1. | |
Attributes: | |
epsilon: A small float added to variance to avoid dividing by zero. | |
dtype: the dtype of the computation (default: float32). | |
use_bias: If True, bias (beta) is added. | |
use_scale: If True, multiply by scale (gamma). When the next layer is linear | |
(also e.g. nn.relu), this can be disabled since the scaling will be done | |
by the next layer. | |
bias_init: Initializer for bias, by default, zero. | |
scale_init: Initializer for scale, by default, one. | |
""" | |
epsilon: float = 1e-6 | |
dtype: Any = jnp.float32 | |
params_dtype: DType = jnp.float32 | |
use_bias: bool = True | |
use_scale: bool = True | |
bias_init: Callable[[PRNGKey, Shape, Any], Array] = nn.initializers.zeros | |
scale_init: Callable[[PRNGKey, Shape, Any], Array] = nn.initializers.ones | |
def __call__(self, x): | |
"""Applies layer normalization on the input. | |
Args: | |
x: the inputs | |
Returns: | |
Normalized inputs (the same shape as inputs). | |
""" | |
x = jnp.asarray(x, jnp.float32) | |
features = x.shape[-1] | |
mean = jnp.mean(x, axis=-1, keepdims=True) | |
mean2 = jnp.mean(lax.square(x), axis=-1, keepdims=True) | |
var = mean2 - lax.square(mean) | |
mul = lax.rsqrt(var + self.epsilon) | |
if self.use_scale: | |
scale = param_with_axes("scale", self.scale_init, (features,), self.params_dtype, axes=("embed",)) | |
mul = mul * jnp.asarray(scale, self.dtype) | |
y = (x - mean) * mul | |
if self.use_bias: | |
bias = param_with_axes("bias", self.bias_init, (features,), self.params_dtype, axes=("embed",)) | |
y = y + jnp.asarray(bias, self.dtype) | |
return jnp.asarray(y, self.dtype) | |
# ------------------------------------------------------------------------------ | |
# Mask-making utility functions. | |
# ------------------------------------------------------------------------------ | |
def make_attention_mask( | |
query_input: Array, | |
key_input: Array, | |
pairwise_fn: Callable = jnp.multiply, | |
extra_batch_dims: int = 0, | |
dtype: DType = jnp.float32, | |
) -> Array: | |
"""Mask-making helper for attention weights. | |
In case of 1d inputs (i.e., `[batch, len_q]`, `[batch, len_kv]`, the | |
attention weights will be `[batch, heads, len_q, len_kv]` and this | |
function will produce `[batch, 1, len_q, len_kv]`. | |
Args: | |
query_input: a batched, flat input of query_length size | |
key_input: a batched, flat input of key_length size | |
pairwise_fn: broadcasting elementwise comparison function | |
extra_batch_dims: number of extra batch dims to add singleton axes for, none | |
by default | |
dtype: mask return dtype | |
Returns: | |
A `[batch, 1, len_q, len_kv]` shaped mask for 1d attention. | |
""" | |
# [batch, len_q, len_kv] | |
mask = pairwise_fn( | |
# [batch, len_q] -> [batch, len_q, 1] | |
jnp.expand_dims(query_input, axis=-1), | |
# [batch, len_q] -> [batch, 1, len_kv] | |
jnp.expand_dims(key_input, axis=-2), | |
) | |
# [batch, 1, len_q, len_kv]. This creates the head dim. | |
mask = jnp.expand_dims(mask, axis=-3) | |
mask = jnp.expand_dims(mask, axis=tuple(range(extra_batch_dims))) | |
return mask.astype(dtype) | |
def make_causal_mask(x: Array, extra_batch_dims: int = 0, dtype: DType = jnp.float32) -> Array: | |
"""Make a causal mask for self-attention. | |
In case of 1d inputs (i.e., `[batch, len]`, the self-attention weights | |
will be `[batch, heads, len, len]` and this function will produce a | |
causal mask of shape `[batch, 1, len, len]`. | |
Note that a causal mask does not depend on the values of x; it only depends on | |
the shape. If x has padding elements, they will not be treated in a special | |
manner. | |
Args: | |
x: input array of shape `[batch, len]` | |
extra_batch_dims: number of batch dims to add singleton axes for, none by | |
default | |
dtype: mask return dtype | |
Returns: | |
A `[batch, 1, len, len]` shaped causal mask for 1d attention. | |
""" | |
idxs = jnp.broadcast_to(jnp.arange(x.shape[-1], dtype=jnp.int32), x.shape) | |
return make_attention_mask(idxs, idxs, jnp.greater_equal, extra_batch_dims=extra_batch_dims, dtype=dtype) | |
def combine_masks(*masks: Optional[Array], dtype: DType = jnp.float32): | |
"""Combine attention masks. | |
Args: | |
*masks: set of attention mask arguments to combine, some can be None. | |
dtype: final mask dtype | |
Returns: | |
Combined mask, reduced by logical and, returns None if no masks given. | |
""" | |
masks = [m for m in masks if m is not None] | |
if not masks: | |
return None | |
assert all( | |
(x.ndim == masks[0].ndim for x in masks) | |
), f"masks must have same rank: {tuple((x.ndim for x in masks))}" | |
mask, *other_masks = masks | |
for other_mask in other_masks: | |
mask = jnp.logical_and(mask, other_mask) | |
return mask.astype(dtype) | |
def combine_biases(*masks: Optional[Array]): | |
"""Combine attention biases. | |
Args: | |
*masks: set of attention bias arguments to combine, some can be None. | |
Returns: | |
Combined mask, reduced by summation, returns None if no masks given. | |
""" | |
masks = [m for m in masks if m is not None] | |
if not masks: | |
return None | |
assert all( | |
(x.ndim == masks[0].ndim for x in masks) | |
), f"masks must have same rank: {tuple((x.ndim for x in masks))}" | |
mask, *other_masks = masks | |
for other_mask in other_masks: | |
mask = mask + other_mask | |
return mask | |
def make_decoder_mask( | |
decoder_target_tokens: Array, | |
dtype: DType, | |
decoder_causal_attention: Optional[Array] = None, | |
decoder_segment_ids: Optional[Array] = None, | |
) -> Array: | |
"""Compute the self-attention mask for a decoder. | |
Decoder mask is formed by combining a causal mask, a padding mask and an | |
optional packing mask. If decoder_causal_attention is passed, it makes the | |
masking non-causal for positions that have value of 1. | |
A prefix LM is applied to a dataset which has a notion of "inputs" and | |
"targets", e.g., a machine translation task. The inputs and targets are | |
concatenated to form a new target. `decoder_target_tokens` is the concatenated | |
decoder output tokens. | |
The "inputs" portion of the concatenated sequence can attend to other "inputs" | |
tokens even for those at a later time steps. In order to control this | |
behavior, `decoder_causal_attention` is necessary. This is a binary mask with | |
a value of 1 indicating that the position belonged to "inputs" portion of the | |
original dataset. | |
Example: | |
Suppose we have a dataset with two examples. | |
ds = [{"inputs": [6, 7], "targets": [8]}, | |
{"inputs": [3, 4], "targets": [5]}] | |
After the data preprocessing with packing, the two examples are packed into | |
one example with the following three fields (some fields are skipped for | |
simplicity). | |
decoder_target_tokens = [[6, 7, 8, 3, 4, 5, 0]] | |
decoder_segment_ids = [[1, 1, 1, 2, 2, 2, 0]] | |
decoder_causal_attention = [[1, 1, 0, 1, 1, 0, 0]] | |
where each array has [batch, length] shape with batch size being 1. Then, | |
this function computes the following mask. | |
mask = [[[[1, 1, 0, 0, 0, 0, 0], | |
[1, 1, 0, 0, 0, 0, 0], | |
[1, 1, 1, 0, 0, 0, 0], | |
[0, 0, 0, 1, 1, 0, 0], | |
[0, 0, 0, 1, 1, 0, 0], | |
[0, 0, 0, 1, 1, 1, 0], | |
[0, 0, 0, 0, 0, 0, 0]]]] | |
mask[b, 1, :, :] represents the mask for the example `b` in the batch. | |
Because mask is for a self-attention layer, the mask's shape is a square of | |
shape [query length, key length]. | |
mask[b, 1, i, j] = 1 means that the query token at position i can attend to | |
the key token at position j. | |
Args: | |
decoder_target_tokens: decoder output tokens. [batch, length] | |
dtype: dtype of the output mask. | |
decoder_causal_attention: a binary mask indicating which position should | |
only attend to earlier positions in the sequence. Others will attend | |
bidirectionally. [batch, length] | |
decoder_segment_ids: decoder segmentation info for packed examples. [batch, | |
length] | |
Returns: | |
the combined decoder mask. | |
""" | |
masks = [] | |
# The same mask is applied to all attention heads. So the head dimension is 1, | |
# i.e., the mask will be broadcast along the heads dim. | |
# [batch, 1, length, length] | |
causal_mask = make_causal_mask(decoder_target_tokens, dtype=dtype) | |
# Positions with value 1 in `decoder_causal_attneition` can attend | |
# bidirectionally. | |
if decoder_causal_attention is not None: | |
# [batch, 1, length, length] | |
inputs_mask = make_attention_mask( | |
decoder_causal_attention, decoder_causal_attention, jnp.logical_and, dtype=dtype | |
) | |
masks.append(jnp.logical_or(causal_mask, inputs_mask).astype(dtype)) | |
else: | |
masks.append(causal_mask) | |
# Padding mask. | |
masks.append(make_attention_mask(decoder_target_tokens > 0, decoder_target_tokens > 0, dtype=dtype)) | |
# Packing mask | |
if decoder_segment_ids is not None: | |
masks.append(make_attention_mask(decoder_segment_ids, decoder_segment_ids, jnp.equal, dtype=dtype)) | |
return combine_masks(*masks, dtype=dtype) | |
def canonicalize_padding(padding: PaddingLike, rank: int) -> LaxPadding: | |
""" "Canonicalizes conv padding to a jax.lax supported format.""" | |
if isinstance(padding, str): | |
return padding | |
if isinstance(padding, int): | |
return [(padding, padding)] * rank | |
if isinstance(padding, Sequence) and len(padding) == rank: | |
new_pad = [] | |
for p in padding: | |
if isinstance(p, int): | |
new_pad.append((p, p)) | |
elif isinstance(p, tuple) and len(p) == 2: | |
new_pad.append(p) | |
else: | |
break | |
if len(new_pad) == rank: | |
return new_pad | |
raise ValueError( | |
f"Invalid padding format: {padding}, should be str, int," | |
f" or a sequence of len {rank} where each element is an" | |
f" int or pair of ints." | |
) | |
def _conv_dimension_numbers(input_shape): | |
"""Computes the dimension numbers based on the input shape.""" | |
ndim = len(input_shape) | |
lhs_spec = (0, ndim - 1) + tuple(range(1, ndim - 1)) | |
rhs_spec = (ndim - 1, ndim - 2) + tuple(range(0, ndim - 2)) | |
out_spec = lhs_spec | |
return lax.ConvDimensionNumbers(lhs_spec, rhs_spec, out_spec) | |
class _Conv(nn.Module): | |
"""Convolution Module wrapping `lax.conv_general_dilated[_local]`. | |
Attributes: | |
features: number of convolution filters. | |
kernel_size: shape of the convolutional kernel. For 1D convolution, | |
the kernel size can be passed as an integer. For all other cases, it must | |
be a sequence of integers. | |
strides: an integer or a sequence of `n` integers, representing the | |
inter-window strides (default: 1). | |
padding: either the string `'SAME'`, the string `'VALID'`, the string | |
`'CIRCULAR'` (periodic boundary conditions), or a sequence of `n` `(low, | |
high)` integer pairs that give the padding to apply before and after each | |
spatial dimension. A single int is interpeted as applying the same padding | |
in all dims and passign a single int in a sequence causes the same padding | |
to be used on both sides. `'CAUSAL'` padding for a 1D convolution will | |
left-pad the convolution axis, resulting in same-sized output. | |
input_dilation: an integer or a sequence of `n` integers, giving the | |
dilation factor to apply in each spatial dimension of `inputs` | |
(default: 1). Convolution with input dilation `d` is equivalent to | |
transposed convolution with stride `d`. | |
kernel_dilation: an integer or a sequence of `n` integers, giving the | |
dilation factor to apply in each spatial dimension of the convolution | |
kernel (default: 1). Convolution with kernel dilation | |
is also known as 'atrous convolution'. | |
feature_group_count: integer, default 1. If specified divides the input | |
features into groups. | |
use_bias: whether to add a bias to the output (default: True). | |
mask: Optional mask for the weights during masked convolution. The mask must | |
be the same shape as the convolution weight matrix. | |
dtype: the dtype of the computation (default: infer from input and params). | |
params_dtype: the dtype passed to parameter initializers (default: float32). | |
precision: numerical precision of the computation see `jax.lax.Precision` | |
for details. | |
kernel_init: initializer for the convolutional kernel. | |
bias_init: initializer for the bias. | |
""" | |
features: int | |
kernel_size: Sequence[int] | |
strides: Union[None, int, Sequence[int]] = 1 | |
padding: PaddingLike = "SAME" | |
input_dilation: Union[None, int, Sequence[int]] = 1 | |
kernel_dilation: Union[None, int, Sequence[int]] = 1 | |
feature_group_count: int = 1 | |
use_bias: bool = True | |
mask: Optional[Array] = None | |
dtype: Optional[DType] = None | |
params_dtype: DType = jnp.float32 | |
precision: PrecisionLike = None | |
kernel_init: Callable[[PRNGKey, Shape, DType], Array] = nn.initializers.lecun_normal() | |
bias_init: Callable[[PRNGKey, Shape, DType], Array] = nn.initializers.zeros | |
conv_general_dilated: ConvGeneralDilatedT = lax.conv_general_dilated | |
kernel_axes: Tuple[str, ...] = () | |
def shared_weights(self) -> bool: # type: ignore | |
"""Defines whether weights are shared or not between different pixels. | |
Returns: | |
`True` to use shared weights in convolution (regular convolution). | |
`False` to use different weights at different pixels, a.k.a. | |
"locally connected layer", "unshared convolution", or "local convolution". | |
""" | |
... | |
def __call__(self, inputs: Array) -> Array: | |
"""Applies a (potentially unshared) convolution to the inputs. | |
Args: | |
inputs: input data with dimensions (*batch_dims, spatial_dims..., | |
features). This is the channels-last convention, i.e. NHWC for a 2d | |
convolution and NDHWC for a 3D convolution. Note: this is different from | |
the input convention used by `lax.conv_general_dilated`, which puts the | |
spatial dimensions last. | |
Note: If the input has more than 1 batch dimension, all batch dimensions | |
are flattened into a single dimension for the convolution and restored | |
before returning. In some cases directly vmap'ing the layer may yield | |
better performance than this default flattening approach. If the input | |
lacks a batch dimension it will be added for the convolution and removed | |
n return, an allowance made to enable writing single-example code. | |
Returns: | |
The convolved data. | |
""" | |
if isinstance(self.kernel_size, int): | |
raise TypeError( | |
"Expected Conv kernel_size to be a" | |
" tuple/list of integers (eg.: [3, 3]) but got" | |
f" {self.kernel_size}." | |
) | |
else: | |
kernel_size = tuple(self.kernel_size) | |
def maybe_broadcast(x: Optional[Union[int, Sequence[int]]]) -> Tuple[int, ...]: | |
if x is None: | |
# backward compatibility with using None as sentinel for | |
# broadcast 1 | |
x = 1 | |
if isinstance(x, int): | |
return (x,) * len(kernel_size) | |
return tuple(x) | |
# Combine all input batch dimensions into a single leading batch axis. | |
num_batch_dimensions = inputs.ndim - (len(kernel_size) + 1) | |
if num_batch_dimensions != 1: | |
input_batch_shape = inputs.shape[:num_batch_dimensions] | |
total_batch_size = int(np.prod(input_batch_shape)) | |
flat_input_shape = (total_batch_size,) + inputs.shape[num_batch_dimensions:] | |
inputs = jnp.reshape(inputs, flat_input_shape) | |
# self.strides or (1,) * (inputs.ndim - 2) | |
strides = maybe_broadcast(self.strides) | |
input_dilation = maybe_broadcast(self.input_dilation) | |
kernel_dilation = maybe_broadcast(self.kernel_dilation) | |
padding_lax = canonicalize_padding(self.padding, len(kernel_size)) | |
if padding_lax == "CIRCULAR": | |
kernel_size_dilated = [(k - 1) * d + 1 for k, d in zip(kernel_size, kernel_dilation)] | |
zero_pad: List[Tuple[int, int]] = [(0, 0)] | |
pads = zero_pad + [((k - 1) // 2, k // 2) for k in kernel_size_dilated] + [(0, 0)] | |
inputs = jnp.pad(inputs, pads, mode="wrap") | |
padding_lax = "VALID" | |
elif padding_lax == "CAUSAL": | |
if len(kernel_size) != 1: | |
raise ValueError("Causal padding is only implemented for 1D convolutions.") | |
left_pad = kernel_dilation[0] * (kernel_size[0] - 1) | |
pads = [(0, 0), (left_pad, 0), (0, 0)] | |
inputs = jnp.pad(inputs, pads) | |
padding_lax = "VALID" | |
dimension_numbers = _conv_dimension_numbers(inputs.shape) | |
in_features = jnp.shape(inputs)[-1] | |
if self.shared_weights: | |
# One shared convolutional kernel for all pixels in the output. | |
assert in_features % self.feature_group_count == 0 | |
kernel_shape = kernel_size + (in_features // self.feature_group_count, self.features) | |
else: | |
if self.feature_group_count != 1: | |
raise NotImplementedError( | |
f"`lax.conv_general_dilated_local` does not support " | |
f"`feature_group_count != 1`, got `{self.feature_group_count}`." | |
) | |
# Need to know the spatial output shape of a standard convolution to | |
# create the unshared convolution kernel. | |
conv_output_shape = jax.eval_shape( | |
lambda lhs, rhs: self.conv_general_dilated( # pylint: disable=g-long-lambda | |
lhs=lhs, | |
rhs=rhs, | |
window_strides=strides, | |
padding=padding_lax, | |
dimension_numbers=dimension_numbers, | |
lhs_dilation=input_dilation, | |
rhs_dilation=kernel_dilation, | |
), | |
inputs, | |
jax.ShapedArray(kernel_size + (in_features, self.features), inputs.dtype), | |
).shape | |
# One (unshared) convolutional kernel per each pixel in the output. | |
kernel_shape = conv_output_shape[1:-1] + (np.prod(kernel_size) * in_features, self.features) | |
if self.mask is not None and self.mask.shape != kernel_shape: | |
raise ValueError( | |
"Mask needs to have the same shape as weights. " f"Shapes are: {self.mask.shape}, {kernel_shape}" | |
) | |
kernel = param_with_axes( | |
"kernel", | |
self.kernel_init, | |
kernel_shape, | |
self.params_dtype, | |
axes=self.kernel_axes, | |
) | |
if self.mask is not None: | |
kernel *= self.mask | |
if self.use_bias: | |
if self.shared_weights: | |
# One bias weight per output channel, shared between pixels. | |
bias_shape = (self.features,) | |
else: | |
# One bias weight per output entry, unshared betwen pixels. | |
bias_shape = conv_output_shape[1:] | |
bias = param_with_axes( | |
"bias", | |
self.bias_init, | |
bias_shape, | |
self.params_dtype, | |
axes=(self.kernel_axes[-1],), | |
) | |
else: | |
bias = None | |
inputs, kernel, bias = promote_dtype(inputs, kernel, bias, dtype=self.dtype) | |
if self.shared_weights: | |
y = self.conv_general_dilated( | |
inputs, | |
kernel, | |
strides, | |
padding_lax, | |
lhs_dilation=input_dilation, | |
rhs_dilation=kernel_dilation, | |
dimension_numbers=dimension_numbers, | |
feature_group_count=self.feature_group_count, | |
precision=self.precision, | |
) | |
else: | |
y = lax.conv_general_dilated_local( | |
lhs=inputs, | |
rhs=kernel, | |
window_strides=strides, | |
padding=padding_lax, | |
filter_shape=kernel_size, | |
lhs_dilation=input_dilation, | |
rhs_dilation=kernel_dilation, | |
dimension_numbers=dimension_numbers, | |
precision=self.precision, | |
) | |
if self.use_bias: | |
bias = bias.reshape((1,) * (y.ndim - bias.ndim) + bias.shape) | |
y += bias | |
if num_batch_dimensions != 1: | |
output_shape = input_batch_shape + y.shape[1:] | |
y = jnp.reshape(y, output_shape) | |
return y | |
class Conv(_Conv): | |
"""Convolution Module wrapping `lax.conv_general_dilated`. | |
Attributes: | |
features: number of convolution filters. | |
kernel_size: shape of the convolutional kernel. For 1D convolution, | |
the kernel size can be passed as an integer. For all other cases, it must | |
be a sequence of integers. | |
strides: an integer or a sequence of `n` integers, representing the | |
inter-window strides (default: 1). | |
padding: either the string `'SAME'`, the string `'VALID'`, the string | |
`'CIRCULAR'` (periodic boundary conditions), or a sequence of `n` `(low, | |
high)` integer pairs that give the padding to apply before and after each | |
spatial dimension. A single int is interpeted as applying the same padding | |
in all dims and passign a single int in a sequence causes the same padding | |
to be used on both sides. `'CAUSAL'` padding for a 1D convolution will | |
left-pad the convolution axis, resulting in same-sized output. | |
input_dilation: an integer or a sequence of `n` integers, giving the | |
dilation factor to apply in each spatial dimension of `inputs` | |
(default: 1). Convolution with input dilation `d` is equivalent to | |
transposed convolution with stride `d`. | |
kernel_dilation: an integer or a sequence of `n` integers, giving the | |
dilation factor to apply in each spatial dimension of the convolution | |
kernel (default: 1). Convolution with kernel dilation | |
is also known as 'atrous convolution'. | |
feature_group_count: integer, default 1. If specified divides the input | |
features into groups. | |
use_bias: whether to add a bias to the output (default: True). | |
mask: Optional mask for the weights during masked convolution. The mask must | |
be the same shape as the convolution weight matrix. | |
dtype: the dtype of the computation (default: infer from input and params). | |
params_dtype: the dtype passed to parameter initializers (default: float32). | |
precision: numerical precision of the computation see `jax.lax.Precision` | |
for details. | |
kernel_init: initializer for the convolutional kernel. | |
bias_init: initializer for the bias. | |
""" | |
def shared_weights(self) -> bool: | |
return True |