Class Graph
Defined in tensorflow/python/framework/ops.py
.
A TensorFlow computation, represented as a dataflow graph.
A Graph
contains a set of
tf.Operation
objects,
which represent units of computation; and
tf.Tensor
objects, which represent
the units of data that flow between operations.
A default Graph
is always registered, and accessible by calling
tf.get_default_graph
.
To add an operation to the default graph, simply call one of the functions
that defines a new Operation
:
c = tf.constant(4.0)
assert c.graph is tf.get_default_graph()
Another typical usage involves the
tf.Graph.as_default
context manager, which overrides the current default graph for the
lifetime of the context:
g = tf.Graph()
with g.as_default():
# Define operations and tensors in `g`.
c = tf.constant(30.0)
assert c.graph is g
Important note: This class is not thread-safe for graph construction. All operations should be created from a single thread, or external synchronization must be provided. Unless otherwise specified, all methods are not thread-safe.
A Graph
instance supports an arbitrary number of "collections"
that are identified by name. For convenience when building a large
graph, collections can store groups of related objects: for
example, the tf.Variable
uses a collection (named
tf.GraphKeys.GLOBAL_VARIABLES
) for
all variables that are created during the construction of a graph. The caller
may define additional collections by specifying a new name.
__init__
__init__()
Creates a new, empty Graph.
Properties
building_function
Returns True iff this graph represents a function.
collections
Returns the names of the collections known to this graph.
finalized
True if this graph has been finalized.
graph_def_versions
The GraphDef version information of this graph.
For details on the meaning of each version, see
GraphDef
.
Returns:
A VersionDef
.
seed
The graph-level random seed of this graph.
version
Returns a version number that increases as ops are added to the graph.
Note that this is unrelated to the
tf.Graph.graph_def_versions
.
Returns:
An integer version that increases as ops are added to the graph.
Methods
tf.Graph.add_to_collection
add_to_collection(
name,
value
)
Stores value
in the collection with the given name
.
Note that collections are not sets, so it is possible to add a value to a collection several times.
Args:
name
: The key for the collection. TheGraphKeys
class contains many standard names for collections.value
: The value to add to the collection.
tf.Graph.add_to_collections
add_to_collections(
names,
value
)
Stores value
in the collections given by names
.
Note that collections are not sets, so it is possible to add a value to
a collection several times. This function makes sure that duplicates in
names
are ignored, but it will not check for pre-existing membership of
value
in any of the collections in names
.
names
can be any iterable, but if names
is a string, it is treated as a
single collection name.
Args:
names
: The keys for the collections to add to. TheGraphKeys
class contains many standard names for collections.value
: The value to add to the collections.
tf.Graph.as_default
as_default()
Returns a context manager that makes this Graph
the default graph.
This method should be used if you want to create multiple graphs in the same process. For convenience, a global default graph is provided, and all ops will be added to this graph if you do not create a new graph explicitly.
Use this method with the with
keyword to specify that ops created within
the scope of a block should be added to this graph. In this case, once
the scope of the with
is exited, the previous default graph is set again
as default. There is a stack, so it's ok to have multiple nested levels
of as_default
calls.
The default graph is a property of the current thread. If you
create a new thread, and wish to use the default graph in that
thread, you must explicitly add a with g.as_default():
in that
thread's function.
The following code examples are equivalent:
# 1. Using Graph.as_default():
g = tf.Graph()
with g.as_default():
c = tf.constant(5.0)
assert c.graph is g
# 2. Constructing and making default:
with tf.Graph().as_default() as g:
c = tf.constant(5.0)
assert c.graph is g
If eager execution is enabled ops created under this context manager will be added to the graph instead of executed eagerly.
Returns:
A context manager for using this graph as the default graph.
tf.Graph.as_graph_def
as_graph_def(
from_version=None,
add_shapes=False
)
Returns a serialized GraphDef
representation of this graph.
The serialized GraphDef
can be imported into another Graph
(using tf.import_graph_def
) or used with the
C++ Session API.
This method is thread-safe.
Args:
from_version
: Optional. If this is set, returns aGraphDef
containing only the nodes that were added to this graph since itsversion
property had the given value.add_shapes
: If true, adds an "_output_shapes" list attr to each node with the inferred shapes of each of its outputs.
Returns:
A
GraphDef
protocol buffer.
Raises:
ValueError
: If thegraph_def
would be too large.
tf.Graph.as_graph_element
as_graph_element(
obj,
allow_tensor=True,
allow_operation=True
)
Returns the object referred to by obj
, as an Operation
or Tensor
.
This function validates that obj
represents an element of this
graph, and gives an informative error message if it is not.
This function is the canonical way to get/validate an object of one of the allowed types from an external argument reference in the Session API.
This method may be called concurrently from multiple threads.
Args:
obj
: ATensor
, anOperation
, or the name of a tensor or operation. Can also be any object with an_as_graph_element()
method that returns a value of one of these types.allow_tensor
: If true,obj
may refer to aTensor
.allow_operation
: If true,obj
may refer to anOperation
.
Returns:
The Tensor
or Operation
in the Graph corresponding to obj
.
Raises:
TypeError
: Ifobj
is not a type we support attempting to convert to types.ValueError
: Ifobj
is of an appropriate type but invalid. For example, an invalid string.KeyError
: Ifobj
is not an object in the graph.
tf.Graph.clear_collection
clear_collection(name)
Clears all values in a collection.
Args:
name
: The key for the collection. TheGraphKeys
class contains many standard names for collections.
tf.Graph.colocate_with
colocate_with(
op,
ignore_existing=False
)
Returns a context manager that specifies an op to colocate with.
For example:
a = tf.Variable([1.0])
with g.colocate_with(a):
b = tf.constant(1.0)
c = tf.add(a, b)
b
and c
will always be colocated with a
, no matter where a
is eventually placed.
NOTE Using a colocation scope resets any existing device constraints.
If op
is None
then ignore_existing
must be True
and the new
scope resets all colocation and device constraints.
Args:
op
: The op to colocate all created ops with, orNone
.ignore_existing
: If true, only applies colocation of this op within the context, rather than applying all colocation properties on the stack. Ifop
isNone
, this value must beTrue
.
Raises:
ValueError
: if op is None but ignore_existing is False.
Yields:
A context manager that specifies the op with which to colocate newly created ops.
tf.Graph.container
container(container_name)
Returns a context manager that specifies the resource container to use.
Stateful operations, such as variables and queues, can maintain their
states on devices so that they can be shared by multiple processes.
A resource container is a string name under which these stateful
operations are tracked. These resources can be released or cleared
with tf.Session.reset()
.
For example:
with g.container('experiment0'):
# All stateful Operations constructed in this context will be placed
# in resource container "experiment0".
v1 = tf.Variable([1.0])
v2 = tf.Variable([2.0])
with g.container("experiment1"):
# All stateful Operations constructed in this context will be
# placed in resource container "experiment1".
v3 = tf.Variable([3.0])
q1 = tf.FIFOQueue(10, tf.float32)
# All stateful Operations constructed in this context will be
# be created in the "experiment0".
v4 = tf.Variable([4.0])
q1 = tf.FIFOQueue(20, tf.float32)
with g.container(""):
# All stateful Operations constructed in this context will be
# be placed in the default resource container.
v5 = tf.Variable([5.0])
q3 = tf.FIFOQueue(30, tf.float32)
# Resets container "experiment0", after which the state of v1, v2, v4, q1
# will become undefined (such as uninitialized).
tf.Session.reset(target, ["experiment0"])
Args:
container_name
: container name string.
Returns:
A context manager for defining resource containers for stateful ops, yields the container name.
tf.Graph.control_dependencies
control_dependencies(control_inputs)
Returns a context manager that specifies control dependencies.
Use with the with
keyword to specify that all operations constructed
within the context should have control dependencies on
control_inputs
. For example:
with g.control_dependencies([a, b, c]):
# `d` and `e` will only run after `a`, `b`, and `c` have executed.
d = ...
e = ...
Multiple calls to control_dependencies()
can be nested, and in
that case a new Operation
will have control dependencies on the union
of control_inputs
from all active contexts.
with g.control_dependencies([a, b]):
# Ops constructed here run after `a` and `b`.
with g.control_dependencies([c, d]):
# Ops constructed here run after `a`, `b`, `c`, and `d`.
You can pass None to clear the control dependencies:
with g.control_dependencies([a, b]):
# Ops constructed here run after `a` and `b`.
with g.control_dependencies(None):
# Ops constructed here run normally, not waiting for either `a` or `b`.
with g.control_dependencies([c, d]):
# Ops constructed here run after `c` and `d`, also not waiting
# for either `a` or `b`.
N.B. The control dependencies context applies only to ops that are constructed within the context. Merely using an op or tensor in the context does not add a control dependency. The following example illustrates this point:
# WRONG
def my_func(pred, tensor):
t = tf.matmul(tensor, tensor)
with tf.control_dependencies([pred]):
# The matmul op is created outside the context, so no control
# dependency will be added.
return t
# RIGHT
def my_func(pred, tensor):
with tf.control_dependencies([pred]):
# The matmul op is created in the context, so a control dependency
# will be added.
return tf.matmul(tensor, tensor)
Also note that though execution of ops created under this scope will trigger execution of the dependencies, the ops created under this scope might still be pruned from a normal tensorflow graph. For example, in the following snippet of code the dependencies are never executed:
loss = model.loss()
with tf.control_dependencies(dependencies):
loss = loss + tf.constant(1) # note: dependencies ignored in the
# backward pass
return tf.gradients(loss, model.variables)
This is because evaluating the gradient graph does not require evaluating the constant(1) op created in the forward pass.
Args:
control_inputs
: A list ofOperation
orTensor
objects which must be executed or computed before running the operations defined in the context. Can also beNone
to clear the control dependencies.
Returns:
A context manager that specifies control dependencies for all operations constructed within the context.
Raises:
TypeError
: Ifcontrol_inputs
is not a list ofOperation
orTensor
objects.
tf.Graph.create_op
create_op(
op_type,
inputs,
dtypes,
input_types=None,
name=None,
attrs=None,
op_def=None,
compute_shapes=True,
compute_device=True
)
Creates an Operation
in this graph. (deprecated arguments)
This is a low-level interface for creating an Operation
. Most
programs will not call this method directly, and instead use the
Python op constructors, such as tf.constant()
, which add ops to
the default graph.
Args:
op_type
: TheOperation
type to create. This corresponds to theOpDef.name
field for the proto that defines the operation.inputs
: A list ofTensor
objects that will be inputs to theOperation
.dtypes
: A list ofDType
objects that will be the types of the tensors that the operation produces.input_types
: (Optional.) A list ofDType
s that will be the types of the tensors that the operation consumes. By default, uses the baseDType
of each input ininputs
. Operations that expect reference-typed inputs must specifyinput_types
explicitly.name
: (Optional.) A string name for the operation. If not specified, a name is generated based onop_type
.attrs
: (Optional.) A dictionary where the key is the attribute name (a string) and the value is the respectiveattr
attribute of theNodeDef
proto that will represent the operation (anAttrValue
proto).op_def
: (Optional.) TheOpDef
proto that describes theop_type
that the operation will have.compute_shapes
: (Optional.) Deprecated. Has no effect (shapes are always computed).compute_device
: (Optional.) If True, device functions will be executed to compute the device property of the Operation.
Raises:
TypeError
: if any of the inputs is not aTensor
.ValueError
: if colocation conflicts with existing device assignment.
Returns:
An Operation
object.
tf.Graph.device
device(device_name_or_function)
Returns a context manager that specifies the default device to use.
The device_name_or_function
argument may either be a device name
string, a device function, or None:
- If it is a device name string, all operations constructed in
this context will be assigned to the device with that name, unless
overridden by a nested
device()
context. - If it is a function, it will be treated as a function from Operation objects to device name strings, and invoked each time a new Operation is created. The Operation will be assigned to the device with the returned name.
- If it is None, all
device()
invocations from the enclosing context will be ignored.
For information about the valid syntax of device name strings, see
the documentation in
DeviceNameUtils
.
For example:
with g.device('/device:GPU:0'):
# All operations constructed in this context will be placed
# on GPU 0.
with g.device(None):
# All operations constructed in this context will have no
# assigned device.
# Defines a function from `Operation` to device string.
def matmul_on_gpu(n):
if n.type == "MatMul":
return "/device:GPU:0"
else:
return "/cpu:0"
with g.device(matmul_on_gpu):
# All operations of type "MatMul" constructed in this context
# will be placed on GPU 0; all other operations will be placed
# on CPU 0.
N.B. The device scope may be overridden by op wrappers or
other library code. For example, a variable assignment op
v.assign()
must be colocated with the tf.Variable
v
, and
incompatible device scopes will be ignored.
Args:
device_name_or_function
: The device name or function to use in the context.
Yields:
A context manager that specifies the default device to use for newly created ops.
tf.Graph.finalize
finalize()
Finalizes this graph, making it read-only.
After calling g.finalize()
, no new operations can be added to
g
. This method is used to ensure that no operations are added
to a graph when it is shared between multiple threads, for example
when using a tf.train.QueueRunner
.
tf.Graph.get_all_collection_keys
get_all_collection_keys()
Returns a list of collections used in this graph.
tf.Graph.get_collection
get_collection(
name,
scope=None
)
Returns a list of values in the collection with the given name
.
This is different from get_collection_ref()
which always returns the
actual collection list if it exists in that it returns a new list each time
it is called.
Args:
name
: The key for the collection. For example, theGraphKeys
class contains many standard names for collections.scope
: (Optional.) A string. If supplied, the resulting list is filtered to include only items whosename
attribute matchesscope
usingre.match
. Items without aname
attribute are never returned if a scope is supplied. The choice ofre.match
means that ascope
without special tokens filters by prefix.
Returns:
The list of values in the collection with the given name
, or
an empty list if no value has been added to that collection. The
list contains the values in the order under which they were
collected.
tf.Graph.get_collection_ref
get_collection_ref(name)
Returns a list of values in the collection with the given name
.
If the collection exists, this returns the list itself, which can be modified in place to change the collection. If the collection does not exist, it is created as an empty list and the list is returned.
This is different from get_collection()
which always returns a copy of
the collection list if it exists and never creates an empty collection.
Args:
name
: The key for the collection. For example, theGraphKeys
class contains many standard names for collections.
Returns:
The list of values in the collection with the given name
, or an empty
list if no value has been added to that collection.
tf.Graph.get_name_scope
get_name_scope()
Returns the current name scope.
For example:
with tf.name_scope('scope1'):
with tf.name_scope('scope2'):
print(tf.get_default_graph().get_name_scope())
would print the string scope1/scope2
.
Returns:
A string representing the current name scope.
tf.Graph.get_operation_by_name
get_operation_by_name(name)
Returns the Operation
with the given name
.
This method may be called concurrently from multiple threads.
Args:
name
: The name of theOperation
to return.
Returns:
The Operation
with the given name
.
Raises:
TypeError
: Ifname
is not a string.KeyError
: Ifname
does not correspond to an operation in this graph.
tf.Graph.get_operations
get_operations()
Return the list of operations in the graph.
You can modify the operations in place, but modifications to the list such as inserts/delete have no effect on the list of operations known to the graph.
This method may be called concurrently from multiple threads.
Returns:
A list of Operations.
tf.Graph.get_tensor_by_name
get_tensor_by_name(name)
Returns the Tensor
with the given name
.
This method may be called concurrently from multiple threads.
Args:
name
: The name of theTensor
to return.
Returns:
The Tensor
with the given name
.
Raises:
TypeError
: Ifname
is not a string.KeyError
: Ifname
does not correspond to a tensor in this graph.
tf.Graph.gradient_override_map
gradient_override_map(op_type_map)
EXPERIMENTAL: A context manager for overriding gradient functions.
This context manager can be used to override the gradient function that will be used for ops within the scope of the context.
For example:
@tf.RegisterGradient("CustomSquare")
def _custom_square_grad(op, grad):
# ...
with tf.Graph().as_default() as g:
c = tf.constant(5.0)
s_1 = tf.square(c) # Uses the default gradient for tf.square.
with g.gradient_override_map({"Square": "CustomSquare"}):
s_2 = tf.square(s_2) # Uses _custom_square_grad to compute the
# gradient of s_2.
Args:
op_type_map
: A dictionary mapping op type strings to alternative op type strings.
Returns:
A context manager that sets the alternative op type to be used for one or more ops created in that context.
Raises:
TypeError
: Ifop_type_map
is not a dictionary mapping strings to strings.
tf.Graph.is_feedable
is_feedable(tensor)
Returns True
if and only if tensor
is feedable.
tf.Graph.is_fetchable
is_fetchable(tensor_or_op)
Returns True
if and only if tensor_or_op
is fetchable.
tf.Graph.name_scope
name_scope(name)
Returns a context manager that creates hierarchical names for operations.
A graph maintains a stack of name scopes. A with name_scope(...):
statement pushes a new name onto the stack for the lifetime of the context.
The name
argument will be interpreted as follows:
- A string (not ending with '/') will create a new name scope, in which
name
is appended to the prefix of all operations created in the context. Ifname
has been used before, it will be made unique by callingself.unique_name(name)
. - A scope previously captured from a
with g.name_scope(...) as scope:
statement will be treated as an "absolute" name scope, which makes it possible to re-enter existing scopes. - A value of
None
or the empty string will reset the current name scope to the top-level (empty) name scope.
For example:
with tf.Graph().as_default() as g:
c = tf.constant(5.0, name="c")
assert c.op.name == "c"
c_1 = tf.constant(6.0, name="c")
assert c_1.op.name == "c_1"
# Creates a scope called "nested"
with g.name_scope("nested") as scope:
nested_c = tf.constant(10.0, name="c")
assert nested_c.op.name == "nested/c"
# Creates a nested scope called "inner".
with g.name_scope("inner"):
nested_inner_c = tf.constant(20.0, name="c")
assert nested_inner_c.op.name == "nested/inner/c"
# Create a nested scope called "inner_1".
with g.name_scope("inner"):
nested_inner_1_c = tf.constant(30.0, name="c")
assert nested_inner_1_c.op.name == "nested/inner_1/c"
# Treats `scope` as an absolute name scope, and
# switches to the "nested/" scope.
with g.name_scope(scope):
nested_d = tf.constant(40.0, name="d")
assert nested_d.op.name == "nested/d"
with g.name_scope(""):
e = tf.constant(50.0, name="e")
assert e.op.name == "e"
The name of the scope itself can be captured by with
g.name_scope(...) as scope:
, which stores the name of the scope
in the variable scope
. This value can be used to name an
operation that represents the overall result of executing the ops
in a scope. For example:
inputs = tf.constant(...)
with g.name_scope('my_layer') as scope:
weights = tf.Variable(..., name="weights")
biases = tf.Variable(..., name="biases")
affine = tf.matmul(inputs, weights) + biases
output = tf.nn.relu(affine, name=scope)
NOTE: This constructor validates the given name
. Valid scope
names match one of the following regular expressions:
[A-Za-z0-9.][A-Za-z0-9_.\\-/]* (for scopes at the root)
[A-Za-z0-9_.\\-/]* (for other scopes)
Args:
name
: A name for the scope.
Returns:
A context manager that installs name
as a new name scope.
Raises:
ValueError
: Ifname
is not a valid scope name, according to the rules above.
tf.Graph.prevent_feeding
prevent_feeding(tensor)
Marks the given tensor
as unfeedable in this graph.
tf.Graph.prevent_fetching
prevent_fetching(op)
Marks the given op
as unfetchable in this graph.
tf.Graph.switch_to_thread_local
switch_to_thread_local()
Make device, colocation and dependencies stacks thread-local.
Device, colocation and dependencies stacks are not thread-local be default. If multiple threads access them, then the state is shared. This means that one thread may affect the behavior of another thread.
After this method is called, the stacks become thread-local. If multiple threads access them, then the state is not shared. Each thread uses its own value; a thread doesn't affect other threads by mutating such a stack.
The initial value for every thread's stack is set to the current value
of the stack when switch_to_thread_local()
was first called.
tf.Graph.unique_name
unique_name(
name,
mark_as_used=True
)
Return a unique operation name for name
.
unique_name
is used to generate structured names, separated by
"/"
, to help identify operations when debugging a graph.
Operation names are displayed in error messages reported by the
TensorFlow runtime, and in various visualization tools such as
TensorBoard.
If mark_as_used
is set to True
, which is the default, a new
unique name is created and marked as in use. If it's set to False
,
the unique name is returned without actually being marked as used.
This is useful when the caller simply wants to know what the name
to be created will be.
Args:
name
: The name for an operation.mark_as_used
: Whether to mark this name as being used.
Returns:
A string to be passed to create_op()
that will be used
to name the operation being created.