tf.vectorized_map
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Parallel map on the list of tensors unpacked from elems
on dimension 0.
tf.vectorized_map( fn, elems, fallback_to_while_loop=True )
This method works similar to tf.map_fn
but is optimized to run much faster, possibly with a much larger memory footprint. The speedups are obtained by vectorization (see Auto-Vectorizing TensorFlow Graphs: Jacobians, Auto-Batching and Beyond). The idea behind vectorization is to semantically launch all the invocations of fn
in parallel and fuse corresponding operations across all these invocations. This fusion is done statically at graph generation time and the generated code is often similar in performance to a manually fused version.
Because tf.vectorized_map
fully parallelizes the batch, this method will generally be significantly faster than using tf.map_fn
, especially in eager mode. However this is an experimental feature and currently has a lot of limitations:
- There should be no data dependency between the different semantic invocations of
fn
, i.e. it should be safe to map the elements of the inputs in any order. - Stateful kernels may mostly not be supported since these often imply a data dependency. We do support a limited set of such stateful kernels though (like RandomFoo, Variable operations like reads, etc).
-
fn
has limited support for control flow operations. -
fn
should return nested structure of Tensors or Operations. However if an Operation is returned, it should have zero outputs. - The shape and dtype of any intermediate or output tensors in the computation of
fn
should not depend on the input tofn
.
Examples:
def outer_product(a): return tf.tensordot(a, a, 0) batch_size = 100 a = tf.ones((batch_size, 32, 32)) c = tf.vectorized_map(outer_product, a) assert c.shape == (batch_size, 32, 32, 32, 32)
# Computing per-example gradients batch_size = 10 num_features = 32 layer = tf.keras.layers.Dense(1) def model_fn(arg): with tf.GradientTape() as g: inp, label = arg inp = tf.expand_dims(inp, 0) label = tf.expand_dims(label, 0) prediction = layer(inp) loss = tf.nn.l2_loss(label - prediction) return g.gradient(loss, (layer.kernel, layer.bias)) inputs = tf.random.uniform([batch_size, num_features]) labels = tf.random.uniform([batch_size, 1]) per_example_gradients = tf.vectorized_map(model_fn, (inputs, labels)) assert per_example_gradients[0].shape == (batch_size, num_features, 1) assert per_example_gradients[1].shape == (batch_size, 1)
Args | |
---|---|
fn | The callable to be performed. It accepts one argument, which will have the same (possibly nested) structure as elems , and returns a possibly nested structure of Tensors and Operations, which may be different than the structure of elems . |
elems | A tensor or (possibly nested) sequence of tensors, each of which will be unpacked along their first dimension. The nested sequence of the resulting slices will be mapped over by fn . The first dimensions of all elements must broadcast to a consistent value; equivalently, each element tensor must have first dimension of either B or 1 , for some common batch size B >= 1 . |
fallback_to_while_loop | If true, on failing to vectorize an operation, the unsupported op is wrapped in a tf.while_loop to execute the map iterations. Note that this fallback only happens for unsupported ops and other parts of fn are still vectorized. If false, on encountering an unsupported op, a ValueError is thrown. Note that the fallbacks can result in slowdowns since vectorization often yields speedup of one to two orders of magnitude. |
Returns | |
---|---|
A tensor or (possibly nested) sequence of tensors. Each tensor packs the results of applying fn to tensors unpacked from elems along the first dimension, from first to last. Although they are less common as user-visible inputs and outputs, note that tensors of type |
Raises | |
---|---|
ValueError | If vectorization fails and fallback_to_while_loop is False. |
© 2020 The TensorFlow Authors. All rights reserved.
Licensed under the Creative Commons Attribution License 3.0.
Code samples licensed under the Apache 2.0 License.
https://www.tensorflow.org/versions/r2.4/api_docs/python/tf/vectorized_map