site/en/r1/guide/saved_model.md
The tf.train.Saver class provides methods to save and restore models. The
tf.saved_model.simple_save function is an easy way to build a
tf.saved_model suitable for serving. Estimators
automatically save and restore variables in the model_dir.
TensorFlow Variables are the best way to represent shared, persistent state
manipulated by your program. The tf.train.Saver constructor adds save and
restore ops to the graph for all, or a specified list, of the variables in the
graph. The Saver object provides methods to run these ops, specifying paths
for the checkpoint files to write to or read from.
Saver restores all variables already defined in your model. If you're
loading a model without knowing how to build its graph (for example, if you're
writing a generic program to load models), then read the
Overview of saving and restoring models section
later in this document.
TensorFlow saves variables in binary checkpoint files that map variable names to tensor values.
Caution: TensorFlow model files are code. Be careful with untrusted code. See Using TensorFlow Securely for details.
Create a Saver with tf.train.Saver() to manage all variables in the
model. For example, the following snippet demonstrates how to call the
tf.train.Saver.save method to save variables to checkpoint files:
# Create some variables.
v1 = tf.get_variable("v1", shape=[3], initializer = tf.zeros_initializer)
v2 = tf.get_variable("v2", shape=[5], initializer = tf.zeros_initializer)
inc_v1 = v1.assign(v1+1)
dec_v2 = v2.assign(v2-1)
# Add an op to initialize the variables.
init_op = tf.global_variables_initializer()
# Add ops to save and restore all the variables.
saver = tf.train.Saver()
# Later, launch the model, initialize the variables, do some work, and save the
# variables to disk.
with tf.Session() as sess:
sess.run(init_op)
# Do some work with the model.
inc_v1.op.run()
dec_v2.op.run()
# Save the variables to disk.
save_path = saver.save(sess, "/tmp/model.ckpt")
print("Model saved in path: %s" % save_path)
The tf.train.Saver object not only saves variables to checkpoint files, it
also restores variables. Note that when you restore variables you do not have
to initialize them beforehand. For example, the following snippet demonstrates
how to call the tf.train.Saver.restore method to restore variables from the
checkpoint files:
tf.reset_default_graph()
# Create some variables.
v1 = tf.get_variable("v1", shape=[3])
v2 = tf.get_variable("v2", shape=[5])
# Add ops to save and restore all the variables.
saver = tf.train.Saver()
# Later, launch the model, use the saver to restore variables from disk, and
# do some work with the model.
with tf.Session() as sess:
# Restore variables from disk.
saver.restore(sess, "/tmp/model.ckpt")
print("Model restored.")
# Check the values of the variables
print("v1 : %s" % v1.eval())
print("v2 : %s" % v2.eval())
Note: There is not a physical file called /tmp/model.ckpt. It is the prefix of
filenames created for the checkpoint. Users only interact with the prefix
instead of physical checkpoint files.
If you do not pass any arguments to tf.train.Saver(), the saver handles all
variables in the graph. Each variable is saved under the name that was passed
when the variable was created.
It is sometimes useful to explicitly specify names for variables in the
checkpoint files. For example, you may have trained a model with a variable
named "weights" whose value you want to restore into a variable named
"params".
It is also sometimes useful to only save or restore a subset of the variables used by a model. For example, you may have trained a neural net with five layers, and you now want to train a new model with six layers that reuses the existing weights of the five trained layers. You can use the saver to restore the weights of just the first five layers.
You can easily specify the names and variables to save or load by passing to the
tf.train.Saver() constructor either of the following:
Continuing from the save/restore examples shown earlier:
tf.reset_default_graph()
# Create some variables.
v1 = tf.get_variable("v1", [3], initializer = tf.zeros_initializer)
v2 = tf.get_variable("v2", [5], initializer = tf.zeros_initializer)
# Add ops to save and restore only `v2` using the name "v2"
saver = tf.train.Saver({"v2": v2})
# Use the saver object normally after that.
with tf.Session() as sess:
# Initialize v1 since the saver will not.
v1.initializer.run()
saver.restore(sess, "/tmp/model.ckpt")
print("v1 : %s" % v1.eval())
print("v2 : %s" % v2.eval())
Notes:
You can create as many Saver objects as you want if you need to save and
restore different subsets of the model variables. The same variable can be
listed in multiple saver objects; its value is only changed when the
Saver.restore() method is run.
If you only restore a subset of the model variables at the start of a
session, you have to run an initialize op for the other variables. See
tf.variables_initializer for more information.
To inspect the variables in a checkpoint, you can use the
inspect_checkpoint
library, particularly the print_tensors_in_checkpoint_file function.
By default, Saver uses the value of the tf.Variable.name property
for each variable. However, when you create a Saver object, you may
optionally choose names for the variables in the checkpoint files.
We can quickly inspect variables in a checkpoint with the
inspect_checkpoint library.
Continuing from the save/restore examples shown earlier:
# import the inspect_checkpoint library
from tensorflow.python.tools import inspect_checkpoint as chkp
# print all tensors in checkpoint file
chkp.print_tensors_in_checkpoint_file("/tmp/model.ckpt", tensor_name='', all_tensors=True)
# tensor_name: v1
# [ 1. 1. 1.]
# tensor_name: v2
# [-1. -1. -1. -1. -1.]
# print only tensor v1 in checkpoint file
chkp.print_tensors_in_checkpoint_file("/tmp/model.ckpt", tensor_name='v1', all_tensors=False)
# tensor_name: v1
# [ 1. 1. 1.]
# print only tensor v2 in checkpoint file
chkp.print_tensors_in_checkpoint_file("/tmp/model.ckpt", tensor_name='v2', all_tensors=False)
# tensor_name: v2
# [-1. -1. -1. -1. -1.]
<a name="models"></a>
Use SavedModel to save and load your model—variables, the graph, and the
graph's metadata. This is a language-neutral, recoverable, hermetic
serialization format that enables higher-level systems and tools to produce,
consume, and transform TensorFlow models. TensorFlow provides several ways to
interact with SavedModel, including the tf.saved_model APIs,
tf.estimator.Estimator, and a command-line interface.
The easiest way to create a SavedModel is to use the tf.saved_model.simple_save
function:
simple_save(session,
export_dir,
inputs={"x": x, "y": y},
outputs={"z": z})
This configures the SavedModel so it can be loaded by
TensorFlow serving and supports the
Predict API.
To access the classify, regress, or multi-inference APIs, use the manual
SavedModel builder APIs or an tf.estimator.Estimator.
If your use case isn't covered by tf.saved_model.simple_save, use the manual
tf.saved_model.builder to create a SavedModel.
The tf.saved_model.builder.SavedModelBuilder class provides functionality to
save multiple MetaGraphDefs. A MetaGraph is a dataflow graph, plus
its associated variables, assets, and signatures. A MetaGraphDef
is the protocol buffer representation of a MetaGraph. A signature is
the set of inputs to and outputs from a graph.
If assets need to be saved and written or copied to disk, they can be provided
when the first MetaGraphDef is added. If multiple MetaGraphDefs are
associated with an asset of the same name, only the first version is retained.
Each MetaGraphDef added to the SavedModel must be annotated with
user-specified tags. The tags provide a means to identify the specific
MetaGraphDef to load and restore, along with the shared set of variables
and assets. These tags
typically annotate a MetaGraphDef with its functionality (for example,
serving or training), and optionally with hardware-specific aspects (for
example, GPU).
For example, the following code suggests a typical way to use
SavedModelBuilder to build a SavedModel:
export_dir = ...
...
builder = tf.saved_model.builder.SavedModelBuilder(export_dir)
with tf.Session(graph=tf.Graph()) as sess:
...
builder.add_meta_graph_and_variables(sess,
[tag_constants.TRAINING],
signature_def_map=foo_signatures,
assets_collection=foo_assets,
strip_default_attrs=True)
...
# Add a second MetaGraphDef for inference.
with tf.Session(graph=tf.Graph()) as sess:
...
builder.add_meta_graph([tag_constants.SERVING], strip_default_attrs=True)
...
builder.save()
<a name="forward_compatibility"></a>
strip_default_attrs=TrueFollowing the guidance below gives you forward compatibility only if the set of Ops has not changed.
The tf.saved_model.builder.SavedModelBuilder class allows
users to control whether default-valued attributes must be stripped from the
NodeDefs
while adding a meta graph to the SavedModel bundle. Both
tf.saved_model.builder.SavedModelBuilder.add_meta_graph_and_variables
and tf.saved_model.builder.SavedModelBuilder.add_meta_graph
methods accept a Boolean flag strip_default_attrs that controls this behavior.
If strip_default_attrs is False, the exported tf.MetaGraphDef will have
the default valued attributes in all its tf.NodeDef instances.
This can break forward compatibility with a sequence of events such as the
following:
Foo) is updated to include a new attribute (T) with a
default (bool) at version 101.OpDef and re-exports an existing model that uses Op Foo.T for Op Foo, but tries to
import this model. The model consumer doesn't recognize attribute T in a
NodeDef that uses Op Foo and therefore fails to load the model.strip_default_attrs to True, the model producers can strip away
any default valued attributes in the NodeDefs. This helps ensure that newly
added attributes with defaults don't cause older model consumers to fail
loading models regenerated with newer training binaries.See compatibility guidance for more information.
The Python version of the SavedModel
tf.saved_model.loader
provides load and restore capability for a SavedModel. The load operation
requires the following information:
Upon a load, the subset of variables, assets, and signatures supplied as part of the specific MetaGraphDef will be restored into the supplied session.
export_dir = ...
...
with tf.Session(graph=tf.Graph()) as sess:
tf.saved_model.loader.load(sess, [tag_constants.TRAINING], export_dir)
...
The C++ version of the SavedModel
loader
provides an API to load a SavedModel from a path, while allowing
SessionOptions and RunOptions.
You have to specify the tags associated with the graph to be loaded.
The loaded version of SavedModel is referred to as SavedModelBundle
and contains the MetaGraphDef and the session within which it is loaded.
const string export_dir = ...
SavedModelBundle bundle;
...
LoadSavedModel(session_options, run_options, export_dir, {kSavedModelTagTrain},
&bundle);
You can easily load and serve a SavedModel with the TensorFlow Serving Model Server binary. See instructions on how to install the server, or build it if you wish.
Once you have the Model Server, run it with:
tensorflow_model_server --port=port-numbers --model_name=your-model-name --model_base_path=your_model_base_path
Set the port and model_name flags to values of your choosing. The model_base_path flag expects to be to a base directory, with each version of your model residing in a numerically named subdirectory. If you only have a single version of your model, simply place it in a subdirectory like so:
Store different versions of your model in numerically named subdirectories of a
common base directory. For example, suppose the base directory is /tmp/model.
If you have only one version of your model, store it in /tmp/model/0001. If
you have two versions of your model, store the second version in
/tmp/model/0002, and so on. Set the --model-base_path flag to the base
directory (/tmp/model, in this example). TensorFlow Model Server will serve
the model in the highest numbered subdirectory of that base directory.
SavedModel offers the flexibility to build and load TensorFlow graphs for a variety of use-cases. For the most common use-cases, SavedModel's APIs provide a set of constants in Python and C++ that are easy to reuse and share across tools consistently.
You may use sets of tags to uniquely identify a MetaGraphDef saved in a
SavedModel. A subset of commonly used tags is specified in:
A SignatureDef is a protocol buffer that defines the signature of a computation supported by a graph. Commonly used input keys, output keys, and method names are defined in:
After training an Estimator model, you may want to create a service
from that model that takes requests and returns a result. You can run such a
service locally on your machine or deploy it in the cloud.
To prepare a trained Estimator for serving, you must export it in the standard SavedModel format. This section explains how to:
During training, an input_fn() ingests data
and prepares it for use by the model. At serving time, similarly, a
serving_input_receiver_fn() accepts inference requests and prepares them for
the model. This function has the following purposes:
Tensors expected by the model.The function returns a tf.estimator.export.ServingInputReceiver object,
which packages the placeholders and the resulting feature Tensors together.
A typical pattern is that inference requests arrive in the form of serialized
tf.Examples, so the serving_input_receiver_fn() creates a single string
placeholder to receive them. The serving_input_receiver_fn() is then also
responsible for parsing the tf.Examples by adding a tf.parse_example op to
the graph.
When writing such a serving_input_receiver_fn(), you must pass a parsing
specification to tf.parse_example to tell the parser what feature names to
expect and how to map them to Tensors. A parsing specification takes the
form of a dict from feature names to tf.FixedLenFeature, tf.VarLenFeature,
and tf.SparseFeature. Note this parsing specification should not include
any label or weight columns, since those will not be available at serving
time—in contrast to a parsing specification used in the input_fn() at
training time.
In combination, then:
feature_spec = {'foo': tf.FixedLenFeature(...),
'bar': tf.VarLenFeature(...)}
def serving_input_receiver_fn():
"""An input receiver that expects a serialized tf.Example."""
serialized_tf_example = tf.placeholder(dtype=tf.string,
shape=[default_batch_size],
name='input_example_tensor')
receiver_tensors = {'examples': serialized_tf_example}
features = tf.parse_example(serialized_tf_example, feature_spec)
return tf.estimator.export.ServingInputReceiver(features, receiver_tensors)
The tf.estimator.export.build_parsing_serving_input_receiver_fn utility
function provides that input receiver for the common case.
Note: when training a model to be served using the Predict API with a local server, the parsing step is not needed because the model will receive raw feature data.
Even if you require no parsing or other input processing—that is, if the
serving system will feed feature Tensors directly—you must still provide
a serving_input_receiver_fn() that creates placeholders for the feature
Tensors and passes them through. The
tf.estimator.export.build_raw_serving_input_receiver_fn utility provides for
this.
If these utilities do not meet your needs, you are free to write your own
serving_input_receiver_fn(). One case where this may be needed is if your
training input_fn() incorporates some preprocessing logic that must be
recapitulated at serving time. To reduce the risk of training-serving skew, we
recommend encapsulating such processing in a function which is then called
from both input_fn() and serving_input_receiver_fn().
Note that the serving_input_receiver_fn() also determines the input
portion of the signature. That is, when writing a
serving_input_receiver_fn(), you must tell the parser what signatures
to expect and how to map them to your model's expected inputs.
By contrast, the output portion of the signature is determined by the model.
<a name="specify_outputs"></a>
When writing a custom model_fn, you must populate the export_outputs element
of the tf.estimator.EstimatorSpec return value. This is a dict of
{name: output} describing the output signatures to be exported and used during
serving.
In the usual case of making a single prediction, this dict contains
one element, and the name is immaterial. In a multi-headed model, each head
is represented by an entry in this dict. In this case the name is a string
of your choice that can be used to request a specific head at serving time.
Each output value must be an ExportOutput object such as
tf.estimator.export.ClassificationOutput,
tf.estimator.export.RegressionOutput, or
tf.estimator.export.PredictOutput.
These output types map straightforwardly to the TensorFlow Serving APIs, and so determine which request types will be honored.
Note: In the multi-headed case, a SignatureDef will be generated for each
element of the export_outputs dict returned from the model_fn, named using
the same keys. These SignatureDefs differ only in their outputs, as
provided by the corresponding ExportOutput entry. The inputs are always
those provided by the serving_input_receiver_fn.
An inference request may specify the head by name. One head must be named
using signature_constants.DEFAULT_SERVING_SIGNATURE_DEF_KEY
indicating which SignatureDef will be served when an inference request
does not specify one.
<a name="perform_export"></a>
To export your trained Estimator, call
tf.estimator.Estimator.export_savedmodel with the export base path and
the serving_input_receiver_fn.
estimator.export_savedmodel(export_dir_base, serving_input_receiver_fn,
strip_default_attrs=True)
This method builds a new graph by first calling the
serving_input_receiver_fn() to obtain feature Tensors, and then calling
this Estimator's model_fn() to generate the model graph based on those
features. It starts a fresh Session, and, by default, restores the most recent
checkpoint into it. (A different checkpoint may be passed, if needed.)
Finally it creates a time-stamped export directory below the given
export_dir_base (i.e., export_dir_base/<timestamp>), and writes a
SavedModel into it containing a single MetaGraphDef saved from this
Session.
Note: It is your responsibility to garbage-collect old exports. Otherwise, successive exports will accumulate under
export_dir_base.
For local deployment, you can serve your model using TensorFlow Serving, an open-source project that loads a SavedModel and exposes it as a gRPC service.
First, install TensorFlow Serving.
Then build and run the local model server, substituting $export_dir_base with
the path to the SavedModel you exported above:
bazel build //tensorflow_serving/model_servers:tensorflow_model_server
bazel-bin/tensorflow_serving/model_servers/tensorflow_model_server --port=9000 --model_base_path=$export_dir_base
Now you have a server listening for inference requests via gRPC on port 9000!
The server responds to gRPC requests according to the PredictionService gRPC API service definition. (The nested protocol buffers are defined in various neighboring files).
From the API service definition, the gRPC framework generates client libraries in various languages providing remote access to the API. In a project using the Bazel build tool, these libraries are built automatically and provided via dependencies like these (using Python for example):
deps = [
"//tensorflow_serving/apis:classification_proto_py_pb2",
"//tensorflow_serving/apis:regression_proto_py_pb2",
"//tensorflow_serving/apis:predict_proto_py_pb2",
"//tensorflow_serving/apis:prediction_service_proto_py_pb2"
]
Python client code can then import the libraries thus:
from tensorflow_serving.apis import classification_pb2
from tensorflow_serving.apis import regression_pb2
from tensorflow_serving.apis import predict_pb2
from tensorflow_serving.apis import prediction_service_pb2
Note:
prediction_service_pb2defines the service as a whole and so is always required. However a typical client will need only one ofclassification_pb2,regression_pb2, andpredict_pb2, depending on the type of requests being made.
Sending a gRPC request is then accomplished by assembling a protocol buffer containing the request data and passing it to the service stub. Note how the request protocol buffer is created empty and then populated via the generated protocol buffer API.
from grpc.beta import implementations
channel = implementations.insecure_channel(host, int(port))
stub = prediction_service_pb2.beta_create_PredictionService_stub(channel)
request = classification_pb2.ClassificationRequest()
example = request.input.example_list.examples.add()
example.features.feature['x'].float_list.value.extend(image[0].astype(float))
result = stub.Classify(request, 10.0) # 10 secs timeout
The returned result in this example is a ClassificationResponse protocol
buffer.
This is a skeletal example; please see the Tensorflow Serving documentation and examples for more details.
<!-- TODO(soergel): give examples of making requests against this server, using the different Tensorflow Serving APIs, selecting the signature by key, etc. --> <!-- TODO(soergel): document ExportStrategy here once Experiment moves from contrib to core. -->Note:
ClassificationRequestandRegressionRequestcontain atensorflow.serving.Inputprotocol buffer, which in turn contains a list oftensorflow.Exampleprotocol buffers.PredictRequest, by contrast, contains a mapping from feature names to values encoded viaTensorProto. Correspondingly: When using theClassifyandRegressAPIs, TensorFlow Serving feeds serializedtf.Examples to the graph, so yourserving_input_receiver_fn()should include atf.parse_example()Op. When using the genericPredictAPI, however, TensorFlow Serving feeds raw feature data to the graph, so a pass throughserving_input_receiver_fn()should be used.
You can use the SavedModel Command Line Interface (CLI) to inspect and
execute a SavedModel.
For example, you can use the CLI to inspect the model's SignatureDefs.
The CLI enables you to quickly confirm that the input
Tensor dtype and shape match the model. Moreover, if you
want to test your model, you can use the CLI to do a sanity check by
passing in sample inputs in various formats (for example, Python
expressions) and then fetching the output.
Broadly speaking, you can install TensorFlow in either of the following two ways:
If you installed TensorFlow through a pre-built TensorFlow binary,
then the SavedModel CLI is already installed on your system
at pathname bin\saved_model_cli.
If you built TensorFlow from source code, you must run the following
additional command to build saved_model_cli:
$ bazel build third_party/tensorflow/python/tools:saved_model_cli
The SavedModel CLI supports the following two commands on a
MetaGraphDef in a SavedModel:
show, which shows a computation on a MetaGraphDef in a SavedModel.run, which runs a computation on a MetaGraphDef.show commandA SavedModel contains one or more MetaGraphDefs, identified by their tag-sets.
To serve a model, you
might wonder what kind of SignatureDefs are in each model, and what are their
inputs and outputs. The show command let you examine the contents of the
SavedModel in hierarchical order. Here's the syntax:
usage: saved_model_cli show [-h] --dir DIR [--all]
[--tag_set TAG_SET] [--signature_def SIGNATURE_DEF_KEY]
For example, the following command shows all available MetaGraphDef tag-sets in the SavedModel:
$ saved_model_cli show --dir /tmp/saved_model_dir
The given SavedModel contains the following tag-sets:
serve
serve, gpu
The following command shows all available SignatureDef keys in
a MetaGraphDef:
$ saved_model_cli show --dir /tmp/saved_model_dir --tag_set serve
The given SavedModel `MetaGraphDef` contains `SignatureDefs` with the
following keys:
SignatureDef key: "classify_x2_to_y3"
SignatureDef key: "classify_x_to_y"
SignatureDef key: "regress_x2_to_y3"
SignatureDef key: "regress_x_to_y"
SignatureDef key: "regress_x_to_y2"
SignatureDef key: "serving_default"
If a MetaGraphDef has multiple tags in the tag-set, you must specify
all tags, each tag separated by a comma. For example:
To show all inputs and outputs TensorInfo for a specific SignatureDef, pass in
the SignatureDef key to signature_def option. This is very useful when you
want to know the tensor key value, dtype and shape of the input tensors for
executing the computation graph later. For example:
$ saved_model_cli show --dir \
/tmp/saved_model_dir --tag_set serve --signature_def serving_default
The given SavedModel SignatureDef contains the following input(s):
inputs['x'] tensor_info:
dtype: DT_FLOAT
shape: (-1, 1)
name: x:0
The given SavedModel SignatureDef contains the following output(s):
outputs['y'] tensor_info:
dtype: DT_FLOAT
shape: (-1, 1)
name: y:0
Method name is: tensorflow/serving/predict
To show all available information in the SavedModel, use the --all option.
For example:
run commandInvoke the run command to run a graph computation, passing
inputs and then displaying (and optionally saving) the outputs.
Here's the syntax:
usage: saved_model_cli run [-h] --dir DIR --tag_set TAG_SET --signature_def
SIGNATURE_DEF_KEY [--inputs INPUTS]
[--input_exprs INPUT_EXPRS]
[--input_examples INPUT_EXAMPLES] [--outdir OUTDIR]
[--overwrite] [--tf_debug]
The run command provides the following three ways to pass inputs to the model:
--inputs option enables you to pass numpy ndarray in files.--input_exprs option enables you to pass Python expressions.--input_examples option enables you to pass tf.train.Example.--inputsTo pass input data in files, specify the --inputs option, which takes the
following general format:
--inputs <INPUTS>
where INPUTS is either of the following formats:
<input_key>=<filename><input_key>=<filename>[<variable_name>]You may pass multiple INPUTS. If you do pass multiple inputs, use a semicolon to separate each of the INPUTS.
saved_model_cli uses numpy.load to load the filename.
The filename may be in any of the following formats:
.npy.npzA .npy file always contains a numpy ndarray. Therefore, when loading from
a .npy file, the content will be directly assigned to the specified input
tensor. If you specify a variable_name with that .npy file, the
variable_name will be ignored and a warning will be issued.
When loading from a .npz (zip) file, you may optionally specify a
variable_name to identify the variable within the zip file to load for
the input tensor key. If you don't specify a variable_name, the SavedModel
CLI will check that only one file is included in the zip file and load it
for the specified input tensor key.
When loading from a pickle file, if no variable_name is specified in the
square brackets, whatever that is inside the pickle file will be passed to the
specified input tensor key. Otherwise, the SavedModel CLI will assume a
dictionary is stored in the pickle file and the value corresponding to
the variable_name will be used.
--input_exprsTo pass inputs through Python expressions, specify the --input_exprs option.
This can be useful for when you don't have data
files lying around, but still want to sanity check the model with some simple
inputs that match the dtype and shape of the model's SignatureDefs.
For example:
`<input_key>=[[1],[2],[3]]`
In addition to Python expressions, you may also pass numpy functions. For example:
`<input_key>=np.ones((32,32,3))`
(Note that the numpy module is already available to you as np.)
--input_examplesTo pass tf.train.Example as inputs, specify the --input_examples option.
For each input key, it takes a list of dictionary, where each dictionary is an
instance of tf.train.Example. The dictionary keys are the features and the
values are the value lists for each feature.
For example:
`<input_key>=[{"age":[22,24],"education":["BS","MS"]}]`
By default, the SavedModel CLI writes output to stdout. If a directory is
passed to --outdir option, the outputs will be saved as npy files named after
output tensor keys under the given directory.
Use --overwrite to overwrite existing output files.
If --tf_debug option is set, the SavedModel CLI will use the
TensorFlow Debugger (tfdbg) to watch the intermediate Tensors and runtime
graphs or subgraphs while running the SavedModel.
runGiven:
x1 and x2 to get output y.(-1, 1).npy files:
/tmp/my_data1.npy, which contains a numpy ndarray [[1], [2], [3]]./tmp/my_data2.npy, which contains another numpy
ndarray [[0.5], [0.5], [0.5]].To run these two npy files through the model to get output y, issue
the following command:
$ saved_model_cli run --dir /tmp/saved_model_dir --tag_set serve \
--signature_def x1_x2_to_y --inputs 'x1=/tmp/my_data1.npy;x2=/tmp/my_data2.npy' \
--outdir /tmp/out
Result for output key y:
[[ 1.5]
[ 2.5]
[ 3.5]]
Let's change the preceding example slightly. This time, instead of two
.npy files, you now have an .npz file and a pickle file. Furthermore,
you want to overwrite any existing output file. Here's the command:
$ saved_model_cli run --dir /tmp/saved_model_dir --tag_set serve \
--signature_def x1_x2_to_y \
--inputs 'x1=/tmp/my_data1.npz[x];x2=/tmp/my_data2.pkl' --outdir /tmp/out \
--overwrite
Result for output key y:
[[ 1.5]
[ 2.5]
[ 3.5]]
You may specify python expression instead of an input file. For example,
the following command replaces input x2 with a Python expression:
$ saved_model_cli run --dir /tmp/saved_model_dir --tag_set serve \
--signature_def x1_x2_to_y --inputs x1=/tmp/my_data1.npz[x] \
--input_exprs 'x2=np.ones((3,1))'
Result for output key y:
[[ 2]
[ 3]
[ 4]]
To run the model with the TensorFlow Debugger on, issue the following command:
$ saved_model_cli run --dir /tmp/saved_model_dir --tag_set serve \
--signature_def serving_default --inputs x=/tmp/data.npz[x] --tf_debug
<a name="structure"></a>
When you save a model in SavedModel format, TensorFlow creates a SavedModel directory consisting of the following subdirectories and files:
assets/
assets.extra/
variables/
variables.data-?????-of-?????
variables.index
saved_model.pb|saved_model.pbtxt
where:
assets is a subfolder containing auxiliary (external) files,
such as vocabularies. Assets are copied to the SavedModel location
and can be read when loading a specific MetaGraphDef.assets.extra is a subfolder where higher-level libraries and users can
add their own assets that co-exist with the model, but are not loaded by
the graph. This subfolder is not managed by the SavedModel libraries.variables is a subfolder that includes output from
tf.train.Saver.saved_model.pb or saved_model.pbtxt is the SavedModel protocol buffer.
It includes the graph definitions as MetaGraphDef protocol buffers.A single SavedModel can represent multiple graphs. In this case, all the
graphs in the SavedModel share a single set of checkpoints (variables)
and assets. For example, the following diagram shows one SavedModel
containing three MetaGraphDefs, all three of which share the same set
of checkpoints and assets:
Each graph is associated with a specific set of tags, which enables identification during a load or restore operation.