.. currentmodule:: torch.fx
.. automodule:: torch.fx
What is an FX transform? Essentially, it's a function that looks like this.
import torch import torch.fx def transform(m: nn.Module, tracer_class : type = torch.fx.Tracer) -> torch.nn.Module: # Step 1: Acquire a Graph representing the code in `m` # NOTE: torch.fx.symbolic_trace is a wrapper around a call to # fx.Tracer.trace and constructing a GraphModule. We'll # split that out in our transform to allow the caller to # customize tracing behavior. graph : torch.fx.Graph = tracer_class().trace(m) # Step 2: Modify this Graph or create a new one graph = ... # Step 3: Construct a Module to return return torch.fx.GraphModule(m, graph)
Your transform will take in an :class:`torch.nn.Module`, acquire a :class:`Graph` from it, do some modifications, and return a new :class:`torch.nn.Module`. You should think of the :class:`torch.nn.Module` that your FX transform returns as identical to a regular :class:`torch.nn.Module` -- you can pass it to another FX transform, you can pass it to TorchScript, or you can run it. Ensuring that the inputs and outputs of your FX transform are a :class:`torch.nn.Module` will allow for composability.
Note
It is also possible to modify an existing :class:`GraphModule` instead of creating a new one, like so:
import torch import torch.fx def transform(m : nn.Module) -> nn.Module: gm : torch.fx.GraphModule = torch.fx.symbolic_trace(m) # Modify gm.graph # <...> # Recompile the forward() method of `gm` from its Graph gm.recompile() return gm
Note that you MUST call :meth:`GraphModule.recompile` to bring the generated
forward()
method on the GraphModule
in sync with the modified :class:`Graph`.
Given that you’ve passed in a :class:`torch.nn.Module` that has been traced into a :class:`Graph`, there are now two primary approaches you can take to building a new :class:`Graph`.
Full treatment of the semantics of graphs can be found in the :class:`Graph` documentation, but we are going to cover the basics here. A :class:`Graph` is a data structure that represents a method on a :class:`GraphModule`. The information that this requires is:
- What are the inputs to the method?
- What are the operations that run inside the method?
- What is the output (i.e. return) value from the method?
All three of these concepts are represented with :class:`Node` instances. Let's see what we mean by that with a short example:
import torch import torch.fx class MyModule(torch.nn.Module): def __init__(self): super().__init__() self.param = torch.nn.Parameter(torch.rand(3, 4)) self.linear = torch.nn.Linear(4, 5) def forward(self, x): return torch.topk(torch.sum( self.linear(x + self.linear.weight).relu(), dim=-1), 3) m = MyModule() gm = torch.fx.symbolic_trace(m) gm.graph.print_tabular()
Here we define a module MyModule
for demonstration purposes, instantiate it,
symbolically trace it, then call the :meth:`Graph.print_tabular` method to print
out a table showing the nodes of this :class:`Graph`:
opcode name target args kwargs placeholder x x () {} get_attr linear_weight linear.weight () {} call_function add_1 <built-in function add> (x, linear_weight) {} call_module linear_1 linear (add_1,) {} call_method relu_1 relu (linear_1,) {} call_function sum_1 <built-in method sum ...> (relu_1,) {'dim': -1} call_function topk_1 <built-in method topk ...> (sum_1, 3) {} output output output (topk_1,) {}
We can use this information to answer the questions we posed above.
- What are the inputs to the method? In FX, method inputs are specified
via special
placeholder
nodes. In this case, we have a singleplaceholder
node with atarget
ofx
, meaning we have a single (non-self) argument named x. - What are the operations within the method? The
get_attr
,call_function
,call_module
, andcall_method
nodes represent the operations in the method. A full treatment of the semantics of all of these can be found in the :class:`Node` documentation. - What is the return value of the method? The return value in a
:class:`Graph` is specified by a special
output
node.
Given that we now know the basics of how code is represented in FX, we can now explore how we would edit a :class:`Graph`.
One approach to building this new :class:`Graph` is to directly manipulate your old one. To aid in this, we can simply take the :class:`Graph` we obtain from symbolic tracing and modify it. For example, let’s say we desire to replace :func:`torch.add` calls with :func:`torch.mul` calls.
import torch import torch.fx # Sample module class M(torch.nn.Module): def forward(self, x, y): return torch.add(x, y) def transform(m: torch.nn.Module, tracer_class : type = fx.Tracer) -> torch.nn.Module: graph : fx.Graph = tracer_class().trace(m) # FX represents its Graph as an ordered list of # nodes, so we can iterate through them. for node in graph.nodes: # Checks if we're calling a function (i.e: # torch.add) if node.op == 'call_function': # The target attribute is the function # that call_function calls. if node.target == torch.add: node.target = torch.mul graph.lint() # Does some checks to make sure the # Graph is well-formed. return fx.GraphModule(m, graph)
We can also do more involved :class:`Graph` rewrites, such as deleting or appending nodes. To aid in these transformations, FX has utility functions for transforming the graph that can be found in the :class:`Graph` documentation. An example of using these APIs to append a :func:`torch.relu` call can be found below.
# Specifies the insertion point. Any nodes added to the # Graph within this scope will be inserted after `node` with traced.graph.inserting_after(node): # Insert a new `call_function` node calling `torch.relu` new_node = traced.graph.call_function( torch.relu, args=(node,)) # We want all places that used the value of `node` to # now use that value after the `relu` call we've added. # We use the `replace_all_uses_with` API to do this. node.replace_all_uses_with(new_node)
For simple transformations that only consist of substitutions, you can also make use of the subgraph rewriter.
FX also provides another level of automation on top of direct graph manipulation.
The :func:`replace_pattern` API is essentially a "find/replace" tool for editing
:class:`Graph`s. It allows you to specify a pattern
and replacement
function
and it will trace through those functions, find instances of the group of operations
in the pattern
graph, and replace those instances with copies of the replacement
graph. This can help to greatly automate tedious graph manipulation code, which can
get unwieldy as the transformations get more complex.
- Replace one op
- Conv/Batch Norm fusion
- replace_pattern: Basic usage
- Quantization
- Invert Transformation
Another way of manipulating :class:`Graph`s is by reusing the :class:`Proxy`
machinery used in symbolic tracing. For example, let’s
imagine that we wanted to write a transformation that decomposed
PyTorch functions into smaller operations. It would transform every
F.relu(x)
call into (x > 0) * x
. One possibility would be to
perform the requisite graph rewriting to insert the comparison and
multiplication after the F.relu
, and then clean up the original
F.relu
. However, we can automate this process by using :class:`Proxy`
objects to automatically record operations into the :class:`Graph`.
To use this method, we write the operations that we want inserted as regular PyTorch code and invoke that code with :class:`Proxy` objects as arguments. These :class:`Proxy` objects will capture the operations that are performed on them and append them to the :class:`Graph`.
# Note that this decomposition rule can be read as regular Python def relu_decomposition(x): return (x > 0) * x decomposition_rules = {} decomposition_rules[F.relu] = relu_decomposition def decompose(model: torch.nn.Module, tracer_class : type = fx.Tracer) -> torch.nn.Module: """ Decompose `model` into smaller constituent operations. Currently,this only supports decomposing ReLU into its mathematical definition: (x > 0) * x """ graph : fx.Graph = tracer_class().trace(model) new_graph = fx.Graph() env = {} for node in graph.nodes: if node.op == 'call_function' and node.target in decomposition_rules: # By wrapping the arguments with proxies, # we can dispatch to the appropriate # decomposition rule and implicitly add it # to the Graph by symbolically tracing it. proxy_args = [ fx.Proxy(env[x.name]) if isinstance(x, fx.Node) else x for x in node.args] output_proxy = decomposition_rules[node.target](*proxy_args) # Operations on `Proxy` always yield new `Proxy`s, and the # return value of our decomposition rule is no exception. # We need to extract the underlying `Node` from the `Proxy` # to use it in subsequent iterations of this transform. new_node = output_proxy.node env[node.name] = new_node else: # Default case: we don't have a decomposition rule for this # node, so just copy the node over into the new graph. new_node = new_graph.node_copy(node, lambda x: env[x.name]) env[node.name] = new_node return fx.GraphModule(model, new_graph)
In addition to avoiding explicit graph manipulation, using :class:`Proxy`s also allows you to specify your rewrite rules as native Python code. For transformations that require a large amount of rewrite rules (such as vmap or grad), this can often improve readability and maintainability of the rules.
A worked example of using :class:`Proxy`s for :class:`Graph` manipulation can be found here.
A useful code organizational pattern in FX is to loop over all the :class:`Node`s in a :class:`Graph` and execute them. This can be used for several things including runtime analysis of values flowing through the graph or transformation of the code via retracing with :class:`Proxy`s. For example, suppose we want to run a :class:`GraphModule` and record the :class:`torch.Tensor` shape and dtype properties on the nodes as we see them at runtime. That might look like:
import torch import torch.fx from torch.fx.node import Node from typing import Dict class ShapeProp: """ Shape propagation. This class takes a `GraphModule`. Then, its `propagate` method executes the `GraphModule` node-by-node with the given arguments. As each operation executes, the ShapeProp class stores away the shape and element type for the output values of each operation on the `shape` and `dtype` attributes of the operation's `Node`. """ def __init__(self, mod): self.mod = mod self.graph = mod.graph self.modules = dict(self.mod.named_modules()) def propagate(self, *args): args_iter = iter(args) env : Dict[str, Node] = {} def load_arg(a): return torch.fx.graph.map_arg(a, lambda n: env[n.name]) def fetch_attr(target : str): target_atoms = target.split('.') attr_itr = self.mod for i, atom in enumerate(target_atoms): if not hasattr(attr_itr, atom): raise RuntimeError(f"Node referenced nonexistant target {'.'.join(target_atoms[:i])}") attr_itr = getattr(attr_itr, atom) return attr_itr for node in self.graph.nodes: if node.op == 'placeholder': result = next(args_iter) elif node.op == 'get_attr': result = fetch_attr(node.target) elif node.op == 'call_function': result = node.target(*load_arg(node.args), **load_arg(node.kwargs)) elif node.op == 'call_method': self_obj, *args = load_arg(node.args) kwargs = load_arg(node.kwargs) result = getattr(self_obj, node.target)(*args, **kwargs) elif node.op == 'call_module': result = self.modules[node.target](*load_arg(node.args), **load_arg(node.kwargs)) # This is the only code specific to shape propagation. # you can delete this `if` branch and this becomes # a generic GraphModule interpreter. if isinstance(result, torch.Tensor): node.shape = result.shape node.dtype = result.dtype env[node.name] = result return load_arg(self.graph.result)
As you can see, a full interpreter for FX is not that complicated but it can be very useful. To ease using this pattern, we provide the :class:`Interpreter` class, which encompasses the above logic in a way that certain aspects of the interpreter's execution can be overridden via method overrides.
In addition to executing operations, we can also generate a new
Graph by feeding :class:`Proxy` values through an interpreter.
Similarly, we provide the :class:`Transformer` class to encompass
this pattern. :class:`Transformer` behaves similarly to
:class:`Interpreter`, but instead of calling the run
method to
get a concrete output value from the Module, you would call the
:meth:`Transformer.transform` method to return a new
:class:`GraphModule` which was subject to any transformation rules
you installed as overridden methods.
Often in the course of authoring transformations, our code will not be quite right. In this case, we may need to do some debugging. The key is to work backwards: first, check the results of invoking the generated module to prove or disprove correctness. Then, inspect and debug the generated code. Then, debug the process of transformations that led to the generated code.
If you’re not familiar with debuggers, please see the auxiliary section :ref:`Available Debuggers`.
- Nondeterministic
set
iteration order. In Python, theset
datatype is unordered. Usingset
to contain collections of objects likeNode
s, for example, can cause unexpected nondeterminism. An example is iterating over a set ofNode
s to insert them into aGraph
. Because theset
data type is unordered, the ordering of the operations in the output program will be nondeterministic and can change across program invocations. The recommended alternative is to use adict
data type, which is insertion ordered as of Python 3.7 (and as of cPython 3.6). Adict
can be used equivalently to a set by storing values to be deduplicated in the keys of thedict
.
Because the output of most deep learning modules consists of floating point :class:`torch.Tensor` instances, checking for equivalence between the results of two :class:`torch.nn.Module` is not as straightforward as doing a simple equality check. To motivate this, let's use an example:
import torch import torch.fx import torchvision.models as models def transform(m : torch.nn.Module) -> torch.nn.Module: gm = torch.fx.symbolic_trace(m) # Imagine we're doing some transforms here # <...> gm.recompile() return gm resnet18 = models.resnet18() transformed_resnet18 = transform(resnet18) input_image = torch.randn(5, 3, 224, 224) assert resnet18(input_image) == transformed_resnet18(input_image) """ RuntimeError: Boolean value of Tensor with more than one value is ambiguous """
Here, we've tried to check equality of the values of two deep learning
models with the ==
equality operator. However, this is not well-
defined both due to the issue of that operator returning a tensor
and not a bool, but also because comparison of floating point values
should use a margin of error (or epsilon) to account for the
non-commutativity of floating point operations (see
here for more
details). We can use :func:`torch.allclose` instead, which will give
us an approximate comparison taking into account a relative and
absolute tolerance threshold:
assert torch.allclose(resnet18(input_image), transformed_resnet18(input_image))
This is the first tool in our toolbox to check if transformed modules are behaving as we expect compared to a reference implementation.
Because FX generates the forward()
function on :class:`GraphModule`s, using
traditional debugging techniques like print
statements or pdb
is
not as straightforward. Luckily, we have several techniques we can use
for debugging the generated code.
Invoke pdb
to step into the running program. Although the code that
represents the :class:`Graph` is not in any source file, we can still step
into it manually using pdb
when the forward pass is invoked.
import torch import torch.fx import torchvision.models as models def my_pass(inp: torch.nn.Module, tracer_class : type = fx.Tracer) -> torch.nn.Module: graph = tracer_class().trace(inp) # Transformation logic here # <...> # Return new Module return fx.GraphModule(inp, graph) my_module = models.resnet18() my_module_transformed = my_pass(my_module) input_value = torch.randn(5, 3, 224, 224) # When this line is executed at runtime, we will be dropped into an # interactive `pdb` prompt. We can use the `step` or `s` command to # step into the execution of the next line import pdb; pdb.set_trace() my_module_transformed(input_value)
If you’d like to run the same code multiple times, then it can be
a bit tedious to step to the right code with pdb
. In that case, one
approach is to simply copy-paste the generated forward
pass into
your code and examine it from there.
# Assume that `traced` is a GraphModule that has undergone some # number of transforms # Copy this code for later print(traced) # Print the code generated from symbolic tracing. This outputs: """ def forward(self, y): x = self.x add_1 = x + y; x = y = None return add_1 """ # Subclass the original Module class SubclassM(M): def __init__(self): super().__init__() # Paste the generated `forward` function (the one we printed and # copied above) here def forward(self, y): x = self.x add_1 = x + y; x = y = None return add_1 # Create an instance of the original, untraced Module. Then, create an # instance of the Module with the copied `forward` function. We can # now compare the output of both the original and the traced version. pre_trace = M() post_trace = SubclassM()
:meth:`GraphModule.to_folder` is a method in GraphModule
that allows
you to dump out the generated FX code to a folder. Although copying the
forward pass into the code often suffices as in :ref:`Print the Generated Code`,
it may be easier to examine modules and parameters using to_folder
.
m = symbolic_trace(M()) m.to_folder("foo", "Bar") from foo import Bar y = Bar()
After running the above example, we can then look at the code within
foo/module.py
and modify it as desired (e.g. adding print
statements or using pdb
) to debug the generated code.
Now that we've identified that a transformation is creating incorrect
code, it's time to debug the transformation itself. First, we'll check
the :ref:`Limitations of Symbolic Tracing` section in the documentation.
Once we verify that tracing is working as expected, the goal
becomes figuring out what went wrong during our GraphModule
transformation. There may be a quick answer in
:ref:`Writing Transformations`, but, if not, there are several ways to
examine our traced module:
# Sample Module class M(torch.nn.Module): def forward(self, x, y): return x + y # Create an instance of `M` m = M() # Symbolically trace an instance of `M` (returns a GraphModule). In # this example, we'll only be discussing how to inspect a # GraphModule, so we aren't showing any sample transforms for the # sake of brevity. traced = symbolic_trace(m) # Print the code produced by tracing the module. print(traced) # The generated `forward` function is: """ def forward(self, x, y): add_1 = x + y; x = y = None return add_1 """ # Print the internal Graph. print(traced.graph) # This print-out returns: """ graph(x, y): %add_1 : [#users=1] = call_function[target=<built-in function add>](args = (%x, %y), kwargs = {}) return add_1 """ # Print a tabular representation of the internal Graph. traced.graph.print_tabular() # This gives us: """ opcode name target args kwargs ------------- ------ ----------------------- -------- -------- placeholder x x () {} placeholder y y () {} call_function add_1 <built-in function add> (x, y) {} """
Using the utility functions above, we can compare our traced Module
before and after we've applied our transformations. Sometimes, a
simple visual comparison is enough to trace down a bug. If it's still
not clear what's going wrong, a debugger like pdb
can be a good
next step.
Going off of the example above, consider the following code:
# Sample user-defined function def transform_graph(module: torch.nn.Module, tracer_class : type = fx.Tracer) -> torch.nn.Module: # Get the Graph from our traced Module g = tracer_class().trace(module) """ Transformations on `g` go here """ return fx.GraphModule(module, g) # Transform the Graph transformed = transform_graph(traced) # Print the new code after our transforms. Check to see if it was # what we expected print(transformed)
Using the above example, let’s say that the call to print(traced)
showed us that there was an error in our transforms. We want to find
what goes wrong using a debugger. We start a pdb
session. We can see
what’s happening during the transform by breaking on
transform_graph(traced)
, then pressing s
to “step into” the call
to transform_graph(traced)
.
We may also have good luck by editing the print_tabular
method to print
different attributes of the Nodes in the Graph. (For example, we might
want to see the Node’s input_nodes
and users
.)
The most common Python debugger is
pdb. You can start
your program in “debug mode” with pdb
by typing
python -m pdb FILENAME.py
into the command line, where FILENAME
is the name of the file you want to debug. After that, you can use the
pdb
debugger commands
to move through your running program stepwise. It’s common to set a
breakpoint (b LINE-NUMBER
) when you start pdb
, then call c
to
run the program until that point. This prevents you from having to step
through each line of execution (using s
or n
) to get to the part
of the code you want to examine. Alternatively, you can write
import pdb; pdb.set_trace()
before the line you want to break at.
If you add pdb.set_trace()
, your program will automatically start
in debug mode when you run it. (In other words, you can just type
python FILENAME.py
into the command line instead of
python -m pdb FILENAME.py
.) Once you're running your file in
debug mode, you can step through the code and examine your program's
internal state using certain commands. There are many excellent
tutorials on pdb
online, including RealPython’s
“Python Debugging With Pdb”.
IDEs like PyCharm or VSCode usually have a debugger built in. In your
IDE, you can choose to either a) use pdb
by pulling up a terminal
window in your IDE (e.g. View → Terminal in VSCode), or b) use the
built-in debugger (usually a graphical wrapper around pdb
).
FX uses a system of symbolic tracing (a.k.a symbolic execution) to capture the semantics of programs in a transformable/analyzable form. The system is tracing in that it executes the program (really a :class:`torch.nn.Module` or function) to record operations. It is symbolic in that the data flowing through the program during this execution is not real data, but rather symbols (:class:`Proxy` in FX parlance).
Although symbolic tracing works for most neural net code, it has some limitations.
The main limitation of symbolic tracing is it does not currently support
dynamic control flow. That is, loops or if
statements where the
condition may depend on the input values of the program.
For example, let’s examine the following program:
def func_to_trace(x): if x.sum() > 0: return torch.relu(x) else: return torch.neg(x) traced = torch.fx.symbolic_trace(func_to_trace) """ <...> File "dyn.py", line 6, in func_to_trace if x.sum() > 0: File "pytorch/torch/fx/proxy.py", line 155, in __bool__ return self.tracer.to_bool(self) File "pytorch/torch/fx/proxy.py", line 85, in to_bool raise TraceError('symbolically traced variables cannot be used as inputs to control flow') torch.fx.proxy.TraceError: symbolically traced variables cannot be used as inputs to control flow """
The condition to the if
statement relies on the value of x.sum()
,
which relies on the value of x
, a function input. Since
x
can change (i.e. if you pass a new input tensor to the traced
function), this is dynamic control flow. The traceback walks back up
through your code to show you where this situation happens.
On the other hand, so-called static control flow is supported. Static
control flow is loops or if
statements whose value cannot change
across invocations. Typically, in PyTorch programs, this control flow
arises for code making decisions about a model’s architecture based on
hyper-parameters. As a concrete example:
import torch import torch.fx class MyModule(torch.nn.Module): def __init__(self, do_activation : bool = False): super().__init__() self.do_activation = do_activation self.linear = torch.nn.Linear(512, 512) def forward(self, x): x = self.linear(x) # This if-statement is so-called static control flow. # Its condition does not depend on any input values if self.do_activation: x = torch.relu(x) return x without_activation = MyModule(do_activation=False) with_activation = MyModule(do_activation=True) traced_without_activation = torch.fx.symbolic_trace(without_activation) print(traced_without_activation.code) """ def forward(self, x): linear_1 = self.linear(x); x = None return linear_1 """ traced_with_activation = torch.fx.symbolic_trace(with_activation) print(traced_with_activation.code) """ import torch def forward(self, x): linear_1 = self.linear(x); x = None relu_1 = torch.relu(linear_1); linear_1 = None return relu_1 """
The if-statement if self.do_activation
does not depend on any
function inputs, thus it is static. do_activation
can be considered
to be a hyper-parameter, and the traces of different instances of
MyModule
with different values for that parameter have different
code. This is a valid pattern that is supported by symbolic tracing.
Many instances of dynamic control flow are semantically static control
flow. These instances can be made to support symbolic tracing by
removing the data dependencies on input values, for example by moving
values to Module
attributes or by binding concrete values to arguments
during symbolic tracing:
def f(x, flag): if flag: return x else: return x*2 fx.symbolic_trace(f) # Fails! fx.symbolic_trace(f, concrete_args={'flag': True})
In the case of truly dynamic control flow, the sections of the program that contain this code can be traced as calls to the Method (see :ref:`Customizing Tracing`) or function (see :func:`wrap`) rather than tracing through them.
FX uses __torch_function__
as the mechanism by which it intercepts
calls (see the technical
overview
for more information about this). Some functions, such as builtin Python
functions or those in the math
module, are not covered by
__torch_function__
, but we would still like to capture them in
symbolic tracing. For example:
import torch import torch.fx from math import sqrt def normalize(x): """ Normalize `x` by the size of the batch dimension """ return x / sqrt(len(x)) # It's valid Python code normalize(torch.rand(3, 4)) traced = torch.fx.symbolic_trace(normalize) """ <...> File "sqrt.py", line 9, in normalize return x / sqrt(len(x)) File "pytorch/torch/fx/proxy.py", line 161, in __len__ raise RuntimeError("'len' is not supported in symbolic tracing by default. If you want " RuntimeError: 'len' is not supported in symbolic tracing by default. If you want this call to be recorded, please call torch.fx.wrap('len') at module scope """
The error tells us that the built-in function len
is not supported.
We can make it so that functions like this are recorded in the trace as
direct calls using the :func:`wrap` API:
torch.fx.wrap('len') torch.fx.wrap('sqrt') traced = torch.fx.symbolic_trace(normalize) print(traced.code) """ import math def forward(self, x): len_1 = len(x) sqrt_1 = math.sqrt(len_1); len_1 = None truediv = x / sqrt_1; x = sqrt_1 = None return truediv """
The :class:`Tracer` class is the class that underlies the
implementation of symbolic_trace
. The behavior of tracing can be
customized by subclassing Tracer, like so:
class MyCustomTracer(torch.fx.Tracer): # Inside here you can override various methods # to customize tracing. See the `Tracer` API # reference pass # Let's use this custom tracer to trace through this module class MyModule(torch.nn.Module): def forward(self, x): return torch.relu(x) + torch.ones(3, 4) mod = MyModule() traced_graph = MyCustomTracer().trace(mod) # trace() returns a Graph. Let's wrap it up in a # GraphModule to make it runnable traced = torch.fx.GraphModule(mod, traced_graph)
Leaf Modules are the modules that appear as calls in the symbolic trace
rather than being traced through. The default set of leaf modules is the
set of standard torch.nn
module instances. For example:
class MySpecialSubmodule(torch.nn.Module): def forward(self, x): return torch.neg(x) class MyModule(torch.nn.Module): def __init__(self): super().__init__() self.linear = torch.nn.Linear(3, 4) self.submod = MySpecialSubmodule() def forward(self, x): return self.submod(self.linear(x)) traced = torch.fx.symbolic_trace(MyModule()) print(traced.code) # `linear` is preserved as a call, yet `submod` is traced though. # This is because the default set of "Leaf Modules" includes all # standard `torch.nn` modules. """ import torch def forward(self, x): linear_1 = self.linear(x); x = None neg_1 = torch.neg(linear_1); linear_1 = None return neg_1 """
The set of leaf modules can be customized by overriding :meth:`Tracer.is_leaf_module`.
Tensor constructors (e.g.
torch.zeros
,torch.ones
,torch.rand
,torch.randn
,torch.sparse_coo_tensor
) are currently not traceable.- The deterministic constructors (
zeros
,ones
) can be used and the value they produce will be embedded in the trace as a constant. This is only problematic if the arguments to these constructors refers to dynamic input sizes. In this case,ones_like
orzeros_like
may be a viable substitute. - Nondeterministic constructors (
rand
,randn
) will have a single random value embedded in the trace. This is likely not the intended behavior. One workaround is to wraptorch.randn
in atorch.fx.wrap
function and call that instead.
@torch.fx.wrap def torch_randn(x, shape): return torch.randn(shape) def f(x): return x + torch_randn(x, 5) fx.symbolic_trace(f)
- This behavior may be fixed in a future release.
- The deterministic constructors (
Type annotations
- Python 3-style type annotations (e.g.
func(x : torch.Tensor, y : int) -> torch.Tensor
) are supported and will be preserved by symbolic tracing. - Python 2-style comment type annotations
# type: (torch.Tensor, int) -> torch.Tensor
are not currently supported. - Annotations on local names within a function are not currently supported.
- Python 3-style type annotations (e.g.
.. autofunction:: torch.fx.symbolic_trace
.. autofunction:: torch.fx.wrap
.. autoclass:: torch.fx.GraphModule :members: .. automethod:: __init__
.. autoclass:: torch.fx.Graph :members: .. automethod:: __init__
.. autoclass:: torch.fx.Node :members:
.. autoclass:: torch.fx.Tracer :members: :inherited-members:
.. autoclass:: torch.fx.Proxy
.. autoclass:: torch.fx.Interpreter :members:
.. autoclass:: torch.fx.Transformer :members:
.. autofunction:: torch.fx.replace_pattern