Parses Example
protos into a dict
of tensors.
tf.compat.v1.parse_example( serialized, features, name=None, example_names=None )
Parses a number of serialized Example
protos given in serialized
. We refer to serialized
as a batch with batch_size
many entries of individual Example
protos.
example_names
may contain descriptive names for the corresponding serialized protos. These may be useful for debugging purposes, but they have no effect on the output. If not None
, example_names
must be the same length as serialized
.
This op parses serialized examples into a dictionary mapping keys to Tensor
SparseTensor
, and RaggedTensor
objects. features
is a dict from keys to VarLenFeature
, SparseFeature
, RaggedFeature
, and FixedLenFeature
objects. Each VarLenFeature
and SparseFeature
is mapped to a SparseTensor
; each FixedLenFeature
is mapped to a Tensor
; and each RaggedFeature
is mapped to a RaggedTensor
.
Each VarLenFeature
maps to a SparseTensor
of the specified type representing a ragged matrix. Its indices are [batch, index]
where batch
identifies the example in serialized
, and index
is the value's index in the list of values associated with that feature and example.
Each SparseFeature
maps to a SparseTensor
of the specified type representing a Tensor of dense_shape
[batch_size] + SparseFeature.size
. Its values
come from the feature in the examples with key value_key
. A values[i]
comes from a position k
in the feature of an example at batch entry batch
. This positional information is recorded in indices[i]
as [batch, index_0, index_1, ...]
where index_j
is the k-th
value of the feature in the example at with key SparseFeature.index_key[j]
. In other words, we split the indices (except the first index indicating the batch entry) of a SparseTensor
by dimension into different features of the Example
. Due to its complexity a VarLenFeature
should be preferred over a SparseFeature
whenever possible.
Each FixedLenFeature
df
maps to a Tensor
of the specified type (or tf.float32
if not specified) and shape (serialized.size(),) + df.shape
.
FixedLenFeature
entries with a default_value
are optional. With no default value, we will fail if that Feature
is missing from any example in serialized
.
Each FixedLenSequenceFeature
df
maps to a Tensor
of the specified type (or tf.float32
if not specified) and shape (serialized.size(), None) + df.shape
. All examples in serialized
will be padded with default_value
along the second dimension.
Each RaggedFeature
maps to a RaggedTensor
of the specified type. It is formed by stacking the RaggedTensor
for each example, where the RaggedTensor
for each individual example is constructed using the tensors specified by RaggedTensor.values_key
and RaggedTensor.partition
. See the tf.io.RaggedFeature
documentation for details and examples.
For example, if one expects a tf.float32
VarLenFeature
ft
and three serialized Example
s are provided:
serialized = [ features { feature { key: "ft" value { float_list { value: [1.0, 2.0] } } } }, features { feature []}, features { feature { key: "ft" value { float_list { value: [3.0] } } } ]
then the output will look like:
{"ft": SparseTensor(indices=[[0, 0], [0, 1], [2, 0]], values=[1.0, 2.0, 3.0], dense_shape=(3, 2)) }
If instead a FixedLenSequenceFeature
with default_value = -1.0
and shape=[]
is used then the output will look like:
{"ft": [[1.0, 2.0], [3.0, -1.0]]}
Given two Example
input protos in serialized
:
[ features { feature { key: "kw" value { bytes_list { value: [ "knit", "big" ] } } } feature { key: "gps" value { float_list { value: [] } } } }, features { feature { key: "kw" value { bytes_list { value: [ "emmy" ] } } } feature { key: "dank" value { int64_list { value: [ 42 ] } } } feature { key: "gps" value { } } } ]
And arguments
example_names: ["input0", "input1"], features: { "kw": VarLenFeature(tf.string), "dank": VarLenFeature(tf.int64), "gps": VarLenFeature(tf.float32), }
Then the output is a dictionary:
{ "kw": SparseTensor( indices=[[0, 0], [0, 1], [1, 0]], values=["knit", "big", "emmy"] dense_shape=[2, 2]), "dank": SparseTensor( indices=[[1, 0]], values=[42], dense_shape=[2, 1]), "gps": SparseTensor( indices=[], values=[], dense_shape=[2, 0]), }
For dense results in two serialized Example
s:
[ features { feature { key: "age" value { int64_list { value: [ 0 ] } } } feature { key: "gender" value { bytes_list { value: [ "f" ] } } } }, features { feature { key: "age" value { int64_list { value: [] } } } feature { key: "gender" value { bytes_list { value: [ "f" ] } } } } ]
example_names: ["input0", "input1"], features: { "age": FixedLenFeature([], dtype=tf.int64, default_value=-1), "gender": FixedLenFeature([], dtype=tf.string), }
And the expected output is:
{ "age": [[0], [-1]], "gender": [["f"], ["f"]], }
An alternative to VarLenFeature
to obtain a SparseTensor
is SparseFeature
. For example, given two Example
input protos in serialized
:
[ features { feature { key: "val" value { float_list { value: [ 0.5, -1.0 ] } } } feature { key: "ix" value { int64_list { value: [ 3, 20 ] } } } }, features { feature { key: "val" value { float_list { value: [ 0.0 ] } } } feature { key: "ix" value { int64_list { value: [ 42 ] } } } } ]
And arguments
example_names: ["input0", "input1"], features: { "sparse": SparseFeature( index_key="ix", value_key="val", dtype=tf.float32, size=100), }
Then the output is a dictionary:
{ "sparse": SparseTensor( indices=[[0, 3], [0, 20], [1, 42]], values=[0.5, -1.0, 0.0] dense_shape=[2, 100]), }
See the tf.io.RaggedFeature
documentation for examples showing how RaggedFeature
can be used to obtain RaggedTensor
s.
Args | |
---|---|
serialized | A vector (1-D Tensor) of strings, a batch of binary serialized Example protos. |
features | A dict mapping feature keys to FixedLenFeature , VarLenFeature , SparseFeature , and RaggedFeature values. |
example_names | A vector (1-D Tensor) of strings (optional), the names of the serialized protos in the batch. |
name | A name for this operation (optional). |
Returns | |
---|---|
A dict mapping feature keys to Tensor , SparseTensor , and RaggedTensor values. |
Raises | |
---|---|
ValueError | if any feature is invalid. |
© 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/compat/v1/parse_example