Custom Compiler Passes and Partitioners¶
Passes¶
Passes can be roughly categorized into a couple of axes:
Axis A:
Creating one-to-X mapping (for example, decomposition)
Creating many-to-one mapping (for example, fusion)
Axis B:
Performing forwards iteration (for example, shape propagation)
Performing backwards iteration (for example, dead code elimination)
Axis C:
Dependent on local node information (eg. out-variant conversion)
Dependent on global graph information (eg. memory planning)
Our projection on the frequency of these use cases are:
A.1, B.1, C.1
A.2
B.2, C.2
Level 1¶
For level 1 uses cases (creating one-to-X mappings, performing forwards iterations,
and looking at local node information), we can utilize a helper class called
ExportPass
.
This is an
interpreter-based
way where we execute each node and recreate the graph except with
transformations specified. This allows us to preserve the IR Spec by ensuring
that all nodes created while in the pass meet the IR Spec including ensuring that
metadata such as stack trace, FakeTensor values, and torch.nn.Module heirarchy
are preserved and updated depending on the transformations made.
To implement this pass, we can create a subclass of
ExportPass
and implement the exposed functions. When called with a graph module, it will
run the graph module and create a new graph containing the changes specified by
the pass. This means that the graph module passed in must be runnable on CPU,
and this invariant will be maintained after the pass is run.
One-to-One Pass¶
An example for one-to-one mappings, if we wanted to replace an op A with another op B,
we can run the given
fx.GraphModule
, and every time we see op A, return op B.
Consider the following example:
class ReplaceInPlaceReluWithOutOfPlaceReluPass(ExportPass):
"""
relu_ is the in-place version. Replace it with relu, which is the
out-of-place version
"""
def call_operator(self, op, args, kwargs, meta):
if op != torch.ops.aten.relu_.default:
return super().call_operator(op, args, kwargs, meta)
return super().call_operator(Op(torch.ops.aten.relu.default), args, kwargs, meta)
# To create a pass
replace_pass = ReplaceInPlaceReluWithOutOfPlaceReluPass()
# To run a pass
new_graph_module = replace_pass(graph_module).graph_module
The super().call_operator(op, args, kwargs, meta)
call creates a
call_function
FX node, and returns the result of running the operator with the
given arguments.
One-to-X Pass¶
If we wanted to do one-to-X mappings, like replacing op A with 2 other ops B and
C, we would then make 2 calls to super().call_operator
to create 2 FX nodes,
one with op B and another with op C, and return the result of running op C.
For example:
class ReplaceAddWithMulSub(ExportPass):
"""
Original:
def f(x, y):
return x + y
After pass:
def f(x, y):
z = x * y
return z - y
"""
def call_operator(self, op, args, kwargs, meta):
if op != torch.ops.aten.add.default:
return super().call_operator(op, args, kwargs, meta)
x, y = args
mul_res = super().call_operator(
torch.ops.aten.mul.default,
args,
{},
meta
)
return super().call_operator(
torch.ops.aten.sub.default,
(mul_res, y),
{},
meta
)
One-to-None Pass¶
If we wanted to remove an op, we can just return the value passed into the function:
class RemoveDetachPass(ExportPass):
def call_operator(self, op, args, kwargs, meta):
if op not in (
torch.ops.aten.detach.default,
torch.ops.aten.detach_copy.default,
):
return super().call_operator(op, args, kwargs, meta)
assert len(args) == 1
return args[0]
Utilizing Local Information¶
An example of utilizing local node information is, if we wanted to convert all the
scalars within the graph to tensors, we
can run the given fx.GraphModule
, and for every argument that contains a scalar,
we convert it to a tensor. It might look something like:
def args_map(op, fn, args, kwargs):
assert isinstance(args, tuple)
assert isinstance(kwargs, dict)
args = list(args)
kwargs = kwargs.copy()
# Update the argument based on the function passed
def update(key, args, schema):
args[key] = fn(args[key], schema)
# Update each argument in the schema
for i, schema in enumerate(self.op._schema.arguments):
if schema.name in kwargs:
update(schema.name, kwargs, schema)
elif not schema.kwarg_only and i < len(args):
update(i, args, schema)
class ScalarToTensorPass(ExportPass):
def call_operator(self, op, args, kwargs):
def try_coerce(value, arg):
return (
torch.tensor(value)
if isinstance(value, (float, int, bool))
and type(arg.type) == torch.TensorType
else value
)
args, kwargs = args_map(op, try_coerce, args, kwargs)
return super().call_operator(op, args, kwargs)
Level 2¶
For creating many-to-one mappings, we can utilize FX’s subgraph
rewriter.
Given a pattern
, it creates a subgraph of operators matching to the pattern,
and then replaces each matched subgraph with the replacement
.
Note
This is an inplace operation.
The pattern
and replacement
inputs must be callable functions written with
the same ops that are used in the EXIR graph you are matching with (ATen ops)
so that the subgraph rewriter can find the correct pattern in the graph. Inputs
to the pattern/replacement callables will be treated as wildcards.
Consider the following example:
from torch.fx import subgraph_rewriter
def replace_patterns(graph_module):
def pattern(x, y):
x = torch.ops.aten.add.Tensor(x, y)
x = torch.ops.aten.mul.Tensor(x, y)
return x
def replacement(x, y):
return torch.ops.aten.sub.Tensor(x, y)
replaced_patterns = subgraph_rewriter.replace_pattern_with_filters(
traced_module, pattern, replacement
)
The subgraph rewriter returns a list of ReplacedPatterns
:
@dataclass
class ReplacedPatterns:
# Node from which the match was found
anchor: Node
# Maps nodes in the pattern subgraph to nodes in the larger graph
nodes_map: Dict[Node, Node]
# List of nodes that were added into the graph
replacements: List[Node]
Note
The nodes created by the subgraph rewriter will not have the metadata that
is normally in EXIR nodes (`stack_trace`, `val`, `nn_module_stack`).
Level 3¶
For the third way of creating a pass, we can utilize the most basic
PassBase
.
To create a pass, we can subclass this and implement the function call
with
the pass contents. Additionally, we can implement the functions requires
and
ensures
which will be called before and after the function call
. Note that
these functions can also be overridden in ExportPass
. To run a pass on a graph
module, we can pass the graph module directly to an instance of the class.
Consider the following example:
class ReplaceAddPass(PassBase):
def __init__(self, replace_op):
self.replace_op = replace_op
def call(self, graph_module):
for node in gm.graph.nodes:
if node.op == "call_function" and node.target == torch.add:
node.target = self.replace_op
# Optional to implement, will be called before call()
def requires(self, graph_module) -> None:
for node in graph_module.graph.nodes:
if node.op == "call_function" and node.target == torch.add:
return
raise ValueError("No torch.add ops!")
# Optional to implement, will be called after call()
def ensures(self, graph_module: torch.fx.GraphModule) -> None:
pass
# To create a pass
replace_add_with_div = ReplaceAddPass(torch.div)
# To run a pass
replace_add_with_div(graph_module)
Pass Manager¶
The PassManager
is a class used to run multiple passes on a given graph
module. When initializing a PassManager
instance, we pass in a list of passes
that we want to run and set a couple of flags. To run the collection of passes
on a graph module, we can pass the graph module directly to the PassManager
instance.
An example:
from executorch.exir.pass_manager import PassManager
pm = PassManager(
passes=[replace_add_with_div, replace_div_with_mul],
run_checks_after_each_pass=True,
suppress_check_failures=False,
)
graph_module_out = pm(graph_module)
To add a common set of checks that are run after each pass, we can call the
function set_checks(check: Callable)
which takes in a callable function as
input. If the run_checks_after_each_pass
flag is set, the check
will be
called after each pass is run on the graph module.
An example:
pm = PassManager(passes=[replace_add_with_div, replace_div_with_mul])
def check_div_target(graph_module):
for node in graph_module.graph.nodes:
if node.op == "call_function" and node.target != torch.div:
raise ValueError("Target should be div!")
pm.add_checks(check_div_target)
pm(graph_module) # raises ValueError after replace_div_with_mul pass
Partitioner¶
There are a couple of common FX-graph based partitioners we can use to partition the graph. However, these do not necessarily produce a graph that is compliant with IR Spec, so be careful when using them.
Subgraph Matcher¶
For finding subgraphs within a graph that match a specific pattern, we can
utilize FX’s
SubgraphMatcher
.
Class Attributes:
pattern (Graph)
: The targeted matching pattern. Placeholder nodes in the graph will be treated as wildcards when matching.match_output (bool)
: If True, output node in the pattern graph will be treated as a part of the targeted pattern. If False, output node is ignored during match.match_placeholder (bool)
: If True, placeholder node in the pattern graph will be treated as a part of the targeted pattern. If False, placeholder nodes will be used a wildcard.remove_overlapping_matches (bool)
: If True, in the case of overlapping matches, only the first match will be returned.ignore_literals (bool)
: If True, will not check if literals are equal and will instead treat them as wildcards.
Consider the following example:
from torch.fx.passes.utils.matcher_utils import SubgraphMatcher
class LargeModel(torch.nn.Module):
def __init__(self):
super().__init__()
self._weight = torch.nn.Parameter(torch.ones(3, 3))
self._bias = torch.nn.Parameter(torch.ones(3, 3))
def forward(self, x):
return torch.ops.aten.addmm.default(self._bias, x, self._weight)
large_model_graph = exir.capture(LargeModel(), large_inputs).to_edge().graph
class PatternModel(torch.nn.Module):
def __init__(self):
super().__init__()
self._weight_1 = torch.nn.Parameter(torch.ones(5, 5))
self._bias_1 = torch.nn.Parameter(torch.ones(5, 5))
def forward(self, x):
return torch.ops.aten.addmm.default(self._bias_1, x, self._weight_1)
pattern_graph = exir.capture(PatternModel(), pattern_inputs).to_edge().graph
subgraph_matcher = SubgraphMatcher(pattern_graph)
match_result = subgraph_matcher.match(large_model_graph)
The match
function returns a list of InternalMatch
:
@dataclass
class InternalMatch():
# Nodes from which the match was found
anchors: List[Node]
# Maps nodes in the pattern subgraph to nodes in the larger graph
nodes_map: Dict[Node, Node] = field(default_factory=dict)
# Nodes in target graph that are matched placeholder in pattern
placeholder_nodes: List[Node] = field(default_factory=list)
# Nodes in matched subgraph returned by output
returning_nodes: List[Node] = field(default_factory=list)
Capability Based Partitioner¶
To find the largest subgraphs of nodes that support a specific invariant, we can
utilize FX’s
CapabilityBasedPartitioner
.
Class Attributes
graph_module (torch.fx.GraphModule)
: The graph module we are partitioning on.operator_support (OperatorSupportBase)
: The object used to determine if a node in the graph is supported in the partition.allows_single_node_partition (bool)
: If True, allows single node partitions to be formed.non_compute_ops (Optional[Sequence[str]])
: A set of ops that are considered to be “non-compute” (extorch.ops.aten.view
and_operator.getitem
, so that the partitioner will not create graphs that only contain these non-compute opsallowed_single_node_partition_ops (Optional[Sequence[str]])
: A set of ops that are allowed to be in a single node partition.
The
OperatorSupportBase
class is used by
the partitioner to determine if a specific node in the graph belongs in the
partition. This is done by overriding the is_node_supported
function. You can
chain multiple OperatorSuppportBase
by using
chain
(which
returns False if any of the OperatorSupportBase return False) and
any_chain
(which returns True if any of the OperatorSupportBase returns True).
Consider the following example:
from torch.fx.passes.infra.partitioner import CapabilityBasedPartitioner
from torch.fx.passes.operator_support import any_chain, OperatorSupportBase
class AddMulOperatorSupport(OperatorSupportBase):
def is_node_supported(self, submodules, node: torch.fx.Node) -> bool:
return node.op == "call_function" and node.target in [
torch.ops.aten.add.Tensor, torch.ops.aten.mul.Tensor,
]
capability_partitioner = CapabilityBasedPartitioner(
graph_module,
op_support,
)
# Returns a list of partitions (list of nodes that belong in each partition)
partition_list = capability_partitioner.propose_partitions()
If you look at the capability based partitioner, you may also find a
fuse_partition
function which will return a modified graph with the partitions
as submodules, and calls to these submodules in the toplevel graph through
call_module
nodes. However, this is not compliant to the IR Spec because we do
not allow call_module
nodes.
Combined¶
We also provide a combined helper function:
generate_pattern_op_partitions
Args:
graph_module (fx.GraphModule)
: Module that we want to partitionpatterns (List[torch.fx.Graph])
: A list of patterns in the form of torch.fx.Graph. These graphs can be obtained through thegraph
field from a GraphModule obtained by exir.capture (recommended) or symbolic tracing (which might not result in an accurate edge dialect graph), or by manual crafting a graph module.op_support (OperatorSupportBase)
: A OperatorSupportBase that can be created in the following ways:Subclassing it directly and implementing
is_node_supported()
Getting the result of
create_op_support()
Getting the result of
create_pattern_support()
Multiple OperatorSupportBase classes chained together with
chain()
orany_chain()
Returns
A list of partitions (largest possible subgraphs) containing nodes are supported by the union of the given OperatorSupportBase object and the given pattern graphs.
Source Partitioner¶
For more complicated use cases in which users want to partition based on higher
level modules (torch.nn.Linear
or torch.nn.functional.Linear
) which are now
decomposed into their operators (aten.permute
, aten.addmm
), we have the
following helper function:
get_source_partitions(graph: torch.fx.Graph, wanted_sources: List[Any]) -> Dict[Any, SourcePartition]
Args:
graph
: The graph we want to partitionwanted_sources
: List of sources of nodes that were decomposed from this source. This can be a function (ex.torch.nn.functional.linear
) or a leaf module type (ex.torch.nn.Linear
)
Returns:
Dictionary mapping sources (ex.
torch.nn.modules.linear.Linear
) to a list ofSourcePartitions
that correspond to the list of nodes that were flattened from a module of that type.
@dataclass
class SourcePartition():
# Nodes in a particular partition
nodes: List[Node]
# Module type
module_type: Type
# Nodes in the graph that are needed as inputs to the partition
input_nodes: List[Node] = field(default_factory=list)
# Nodes in the partition that are being used by nodes outside of the partition
output_nodes: List[Node] = field(default_factory=list)
# Parameters that are being used
params: List[str] = field(default_factory=list)
An example:
class M(torch.nn.Module):
def __init__(self):
super().__init__()
self.linear1 = torch.nn.Linear(3, 3)
self.relu = torch.nn.ReLU()
self.linear2 = torch.nn.Linear(3, 5)
def forward(self, x):
x = self.linear1(x)
x = self.linear1(x)
x = self.relu(x)
x = self.linear2(x)
return x
inputs = (torch.randn(3, 3),)
edge_graph = exir.capture(M(), inputs).to_edge().graph
print(edge_graph)
"""
graph():
%arg0 : [#users=1] = placeholder[target=arg0]
%_param_constant0 : [#users=1] = get_attr[target=_param_constant0]
%permute_default : [#users=1] = call_function[target=torch.ops.aten.permute_copy.default](args = (%_param_constant0,), kwargs = {})
%_param_constant1 : [#users=1] = get_attr[target=_param_constant1]
%addmm_default : [#users=1] = call_function[target=torch.ops.aten.addmm.default](args = (%_param_constant1, %arg0, %t_default), kwargs = {})
%_param_constant0_1 : [#users=1] = get_attr[target=_param_constant0]
%permute_default_1 : [#users=1] = call_function[target=torch.ops.aten.permute_copy.default](args = (%_param_constant0_1,), kwargs = {})
%_param_constant1_1 : [#users=1] = get_attr[target=_param_constant1]
%addmm_default_1 : [#users=1] = call_function[target=torch.ops.aten.addmm.default](args = (%_param_constant1_1, %addmm_default, %t_default_1), kwargs = {})
%relu_default : [#users=1] = call_function[target=torch.ops.aten.relu.default](args = (%addmm_default_1,), kwargs = {})
%_param_constant2 : [#users=1] = get_attr[target=_param_constant2]
%permute_default_2 : [#users=1] = call_function[target=torch.ops.aten.permute_copy.default](args = (%_param_constant2,), kwargs = {})
%_param_constant3 : [#users=1] = get_attr[target=_param_constant3]
%addmm_default_2 : [#users=1] = call_function[target=torch.ops.aten.addmm.default](args = (%_param_constant3, %relu_default, %t_default_2), kwargs = {})
return [addmm_default_2]
"""
module_partitions = get_source_partitions(edge_graph, [torch.nn.Linear, torch.nn.ReLU])
print(module_partitions)
"""
{<class 'torch.nn.modules.linear.Linear'>: [
ModulePartition(nodes=[_param_constant0, t_default, _param_constant1, addmm_default], module_type=<class 'torch.nn.modules.linear.Linear'>, input_nodes=[arg0], output_nodes=[addmm_default], params=["_param_constant0", "_param_constant1"]),
ModulePartition(nodes=[_param_constant0_1, t_default_1, _param_constant1_1, addmm_default_1], module_type=<class 'torch.nn.modules.linear.Linear'>, input_nodes=[addmm_default], output_nodes=[addmm_default_1], params=["_param_constant0_1", "_param_constant1_1"]),
ModulePartition(nodes=[_param_constant2, t_default_2, _param_constant3, addmm_default_2], module_type=<class 'torch.nn.modules.linear.Linear'>, input_nodes=[relu_default], output_nodes=[addmm_default_2], params=["_param_constant2", "_param_constant3"])],
<class 'torch.nn.modules.activation.ReLU'>: [
ModulePartition(nodes=[relu_default], module_type=<class 'torch.nn.modules.activation.ReLU'>, input_nodes=[addmm_default_1], output_nodes=[relu_default], params=[])]}
"""