torch/fx/passes/tools_common.py - platform/external/pytorch - Git at Google

 # mypy: allow-untyped-defs
 from typing import List, Tuple, Union, Dict, Any, Set, Mapping, Optional
 import collections
 from dataclasses import dataclass
 import operator

 import torch
 import torch.fx
 from torch.fx.node import _get_qualified_name
 from torch.fx._compatibility import compatibility

 __all__ = ['get_acc_ops_name', 'get_node_target', 'is_node_output_tensor', 'FxNetAccFusionsFinder', 'legalize_graph']

 Tensors = Union[Tuple[torch.Tensor], List[torch.Tensor]]
 TensorOrTensors = Union[torch.Tensor, Tensors]
 NodeList = List[torch.fx.Node]
 NodeSet = Set[torch.fx.Node]
 Names = List[str]
 CALLABLE_NODE_OPS = {"call_module", "call_function", "call_method"}


 @compatibility(is_backward_compatible=False)
 def get_acc_ops_name(k):
     if isinstance(k, str):
         return k
     elif k.__module__ and "acc_ops" in k.__module__:
         return f"acc_ops.{k.__name__}"
     else:
         module = k.__module__.replace('torch._ops', 'torch.ops')  # WAR for bug in how torch.ops assigns module
         return f"{module if module else ''}.{k.__name__}"


 @compatibility(is_backward_compatible=False)
 def get_node_target(submodules: Mapping[str, torch.nn.Module], node: torch.fx.Node) -> str:
     """
     Given a `node` returns its target typename.

     For "call_method" node, return node.target which is the name of that method being called.
     This could potential lead to conflict but should be okay because normally it's on a tensor.

     For "call_function" node, return typename of node.target.

     For "call_module" node, return typename of the module that node.target point to.

     If seeing "_VariableFunctionsClass" in the target name string, it will be replaced by
     "torch". e.g. _VariableFunctionsClass.relu would become torch.relu.
     """

     assert node.op in CALLABLE_NODE_OPS, (
         "Expect op types of " + ", ".join(CALLABLE_NODE_OPS) + f", but found {node.op}"
     )

     if node.op == "call_module":
         assert isinstance(node.target, str)
         submod = submodules[node.target]
         submod_type = getattr(submod, "_base_class_origin", type(submod))
         return get_acc_ops_name(submod_type)
     elif node.op == "call_function":
         target: Any = node.target
         return (
             f"acc_ops.{target.__name__}"
             if target.__module__ is not None and "acc_ops" in target.__module__
             else _get_qualified_name(target)
         )
     else:
         assert isinstance(node.target, str)
         return node.target

 @compatibility(is_backward_compatible=False)
 def is_node_output_tensor(node: torch.fx.Node) -> bool:
     """Checks if the node output produces a Tensor or not.

     NOTE: This requires to run `ShapeProp` on the containing fx graph before
     calling this function. This is because it works by checking the `type`
     metadata on the node. This metadata is produced by the `ShapeProp`.
     """
     type_ = node.meta.get("type", None)
     return type_ is not None and issubclass(type_, torch.Tensor)

 @compatibility(is_backward_compatible=False)
 class FxNetAccFusionsFinder:
     """
     Finds groups of connected ACC nodes that pass non-tensor data between each other.
     Such groups are called fusion groups.
     """

     def __init__(self, module: torch.fx.GraphModule, acc_nodes: NodeSet):
         self.module = module
         self.nodes = list(module.graph.nodes)
         self.acc_nodes = acc_nodes

     @dataclass
     class FusionGroup:
         # The smallest idx of nodes in the fusion group after topological sorting all the nodes in the model.
         top_node_idx: int

         # Nodes in this fusion group.
         nodes: NodeSet

         # Inputs to this fusion group.
         inputs: NodeSet

         # Nodes that in the fusion group that haven't been processed yet.
         nodes_need_process: NodeSet

         def add_node(self, node):
             """
             Add a node to fusion group.
             """
             if node in self.nodes:
                 return

             self.nodes_need_process.add(node)
             self.nodes.add(node)
             self.inputs.discard(node)
             self.inputs.update(
                 {
                     n
                     for n in node.all_input_nodes
                     if n.op in CALLABLE_NODE_OPS and n not in self.nodes
                 }
             )

     def recursive_add_node(
         self,
         fusion_group: "FxNetAccFusionsFinder.FusionGroup",
         inputs: Union[NodeSet, NodeList],
         visited: Optional[NodeSet] = None,
     ):
         """
         Start from inputs and going reverse topological order. If any upstream node
         is in the fusion group, add all the nodes in this path to fusion group.
         """
         for arg in inputs:
             # skip the node if already seen
             if visited is not None:
                 if arg in visited:
                     continue
                 visited.add(arg)

             # Skip placeholder and get_attr because they won't be in the fusion group.
             if arg.op not in CALLABLE_NODE_OPS:
                 continue

             # If the node has smaller idx, it's already an upstream node of the fusion
             # group. We don't need to check it anymore.
             if self.nodes.index(arg) < fusion_group.top_node_idx:
                 continue

             # If the node is in the fusion group, return True.
             if arg in fusion_group.nodes:
                 return True

             # Check the upstream nodes of the node, if any of them is in the fusion group
             # we'll add this node to fusion group and return True.
             if self.recursive_add_node(fusion_group, arg.all_input_nodes, visited):
                 fusion_group.add_node(arg)
                 return True

         return False

     def __call__(self) -> Dict[torch.fx.Node, NodeSet]:
         result: Dict[torch.fx.Node, NodeSet] = {}
         acc_nodes = list(self.acc_nodes)

         for node in acc_nodes:
             if node in result:
                 continue
             if node.op not in CALLABLE_NODE_OPS:
                 continue
             if "tensor_meta" in node.meta:
                 continue
             if node not in self.acc_nodes:
                 continue

             fusion_group: FxNetAccFusionsFinder.FusionGroup = self.FusionGroup(
                 top_node_idx=self.nodes.index(node),
                 nodes={node},
                 inputs=set(node.all_input_nodes),
                 nodes_need_process={node},
             )
             while fusion_group.nodes_need_process:
                 node = fusion_group.nodes_need_process.pop()
                 self.recursive_add_node(
                     fusion_group,
                     fusion_group.inputs,
                     visited=set(),
                 )

                 # Optionally add downstream nodes
                 if "tensor_meta" not in node.meta:
                     for user in node.users:
                         if user.op not in CALLABLE_NODE_OPS:
                             continue
                         if user in fusion_group.nodes:
                             continue

                         fusion_group.add_node(user)
                         self.recursive_add_node(
                             fusion_group,
                             fusion_group.inputs,
                             visited=set(),
                         )

                 # Add some upstream nodes
                 for arg in node.all_input_nodes:
                     if arg.op not in CALLABLE_NODE_OPS:
                         continue
                     if "tensor_meta" in arg.meta:
                         continue
                     if arg in fusion_group.nodes:
                         continue

                     fusion_group.add_node(arg)
                     fusion_group.top_node_idx = min(
                         fusion_group.top_node_idx, self.nodes.index(arg)
                     )
                     self.recursive_add_node(
                         fusion_group,
                         fusion_group.inputs,
                         visited=set(),
                     )

             if not (set(fusion_group.nodes) <= self.acc_nodes):
                 self.acc_nodes -= fusion_group.nodes
             else:
                 for n in fusion_group.nodes:
                     result[n] = fusion_group.nodes

         return result


 @compatibility(is_backward_compatible=False)
 def legalize_graph(gm: torch.fx.GraphModule) -> torch.fx.GraphModule:
     """
     Replace the graph of the given GraphModule with one that contains the same nodes as the
     original, but in topologically sorted order.

     This is used by the merge_matmul transformation below, which disturbs the topologically sorted
     order of its input GraphModule, so that this order is restored before further transformation.

     Arguments:
         gm: The graph module to topologically sort. It is modified in-place.

     Returns:
         The graph module in-place sorted
     """

     # These operators are used for making runtime assertions before any
     # data-dependent operators occur. We want to prioritize sorting these to
     # ensure that these assertions appear before any data-dependent operations
     # in the graph.
     PRIORITIZED_OPS = [
         operator.add,
         operator.mul,
         operator.sub,
         operator.floordiv,
         operator.truediv,
         operator.mod,
         operator.le,
         operator.lt,
         operator.ge,
         operator.gt,
         operator.eq,
         operator.ne,
         torch.ops.aten.sym_constrain_range.default,
         torch.ops.aten.sym_constrain_range_for_size.default,
         torch.ops.aten._assert_async.msg,
         torch.ops.aten.scalar_tensor.default,
         torch.ops.aten._assert_scalar.default,
     ]

     indeg = dict.fromkeys(gm.graph.nodes, 0)
     new_graph = torch.fx.Graph()
     # Track how many unfulfilled dependencies each node has
     for node in gm.graph.nodes:
         for user in node.users:
             indeg[user] += 1
     queue: collections.deque = collections.deque()
     # Add all nodes with no dependencies to the queue
     for node in gm.graph.nodes:
         if indeg[node] == 0:
             queue.append(node)
     env: Dict[torch.fx.Node, torch.fx.Node] = {}
     # Pop nodes from the queue, and add nodes that have had all their
     # dependencies fulfilled
     while len(queue) > 0:
         cur = queue.popleft()
         env[cur] = new_graph.node_copy(cur, lambda x: env[x])
         for user in cur.users:
             indeg[user] -= 1
             if indeg[user] == 0:
                 if user.op == "call_function" and user.target in PRIORITIZED_OPS:
                     queue.appendleft(user)
                 else:
                     queue.append(user)
     # If the new graph's size is not as large as the old one, then there must be
     # a cycle (i.e. some node's dependencies were not satisfied.)
     if len(new_graph.nodes) < len(gm.graph.nodes):
         raise RuntimeError(f"Input graph has cycles, unable to add {[node for node in indeg if indeg[node] != 0]}")
     new_graph._codegen = gm.graph._codegen
     gm.graph = new_graph
     return gm
	# mypy: allow-untyped-defs
	from typing import List, Tuple, Union, Dict, Any, Set, Mapping, Optional
	import collections
	from dataclasses import dataclass
	import operator

	import torch
	import torch.fx
	from torch.fx.node import _get_qualified_name
	from torch.fx._compatibility import compatibility

	__all__ = ['get_acc_ops_name', 'get_node_target', 'is_node_output_tensor', 'FxNetAccFusionsFinder', 'legalize_graph']

	Tensors = Union[Tuple[torch.Tensor], List[torch.Tensor]]
	TensorOrTensors = Union[torch.Tensor, Tensors]
	NodeList = List[torch.fx.Node]
	NodeSet = Set[torch.fx.Node]
	Names = List[str]
	CALLABLE_NODE_OPS = {"call_module", "call_function", "call_method"}


	@compatibility(is_backward_compatible=False)
	def get_acc_ops_name(k):
	if isinstance(k, str):
	return k
	elif k.__module__ and "acc_ops" in k.__module__:
	return f"acc_ops.{k.__name__}"
	else:
	module = k.__module__.replace('torch._ops', 'torch.ops') # WAR for bug in how torch.ops assigns module
	return f"{module if module else ''}.{k.__name__}"


	@compatibility(is_backward_compatible=False)
	def get_node_target(submodules: Mapping[str, torch.nn.Module], node: torch.fx.Node) -> str:
	"""
	Given a `node` returns its target typename.

	For "call_method" node, return node.target which is the name of that method being called.
	This could potential lead to conflict but should be okay because normally it's on a tensor.

	For "call_function" node, return typename of node.target.

	For "call_module" node, return typename of the module that node.target point to.

	If seeing "_VariableFunctionsClass" in the target name string, it will be replaced by
	"torch". e.g. _VariableFunctionsClass.relu would become torch.relu.
	"""

	assert node.op in CALLABLE_NODE_OPS, (
	"Expect op types of " + ", ".join(CALLABLE_NODE_OPS) + f", but found {node.op}"
	)

	if node.op == "call_module":
	assert isinstance(node.target, str)
	submod = submodules[node.target]
	submod_type = getattr(submod, "_base_class_origin", type(submod))
	return get_acc_ops_name(submod_type)
	elif node.op == "call_function":
	target: Any = node.target
	return (
	f"acc_ops.{target.__name__}"
	if target.__module__ is not None and "acc_ops" in target.__module__
	else _get_qualified_name(target)
	)
	else:
	assert isinstance(node.target, str)
	return node.target

	@compatibility(is_backward_compatible=False)
	def is_node_output_tensor(node: torch.fx.Node) -> bool:
	"""Checks if the node output produces a Tensor or not.

	NOTE: This requires to run `ShapeProp` on the containing fx graph before
	calling this function. This is because it works by checking the `type`
	metadata on the node. This metadata is produced by the `ShapeProp`.
	"""
	type_ = node.meta.get("type", None)
	return type_ is not None and issubclass(type_, torch.Tensor)

	@compatibility(is_backward_compatible=False)
	class FxNetAccFusionsFinder:
	"""
	Finds groups of connected ACC nodes that pass non-tensor data between each other.
	Such groups are called fusion groups.
	"""

	def __init__(self, module: torch.fx.GraphModule, acc_nodes: NodeSet):
	self.module = module
	self.nodes = list(module.graph.nodes)
	self.acc_nodes = acc_nodes

	@dataclass
	class FusionGroup:
	# The smallest idx of nodes in the fusion group after topological sorting all the nodes in the model.
	top_node_idx: int

	# Nodes in this fusion group.
	nodes: NodeSet

	# Inputs to this fusion group.
	inputs: NodeSet

	# Nodes that in the fusion group that haven't been processed yet.
	nodes_need_process: NodeSet

	def add_node(self, node):
	"""
	Add a node to fusion group.
	"""
	if node in self.nodes:
	return

	self.nodes_need_process.add(node)
	self.nodes.add(node)
	self.inputs.discard(node)
	self.inputs.update(
	{
	n
	for n in node.all_input_nodes
	if n.op in CALLABLE_NODE_OPS and n not in self.nodes
	}
	)

	def recursive_add_node(
	self,
	fusion_group: "FxNetAccFusionsFinder.FusionGroup",
	inputs: Union[NodeSet, NodeList],
	visited: Optional[NodeSet] = None,
	):
	"""
	Start from inputs and going reverse topological order. If any upstream node
	is in the fusion group, add all the nodes in this path to fusion group.
	"""
	for arg in inputs:
	# skip the node if already seen
	if visited is not None:
	if arg in visited:
	continue
	visited.add(arg)

	# Skip placeholder and get_attr because they won't be in the fusion group.
	if arg.op not in CALLABLE_NODE_OPS:
	continue

	# If the node has smaller idx, it's already an upstream node of the fusion
	# group. We don't need to check it anymore.
	if self.nodes.index(arg) < fusion_group.top_node_idx:
	continue

	# If the node is in the fusion group, return True.
	if arg in fusion_group.nodes:
	return True

	# Check the upstream nodes of the node, if any of them is in the fusion group
	# we'll add this node to fusion group and return True.
	if self.recursive_add_node(fusion_group, arg.all_input_nodes, visited):
	fusion_group.add_node(arg)
	return True

	return False

	def __call__(self) -> Dict[torch.fx.Node, NodeSet]:
	result: Dict[torch.fx.Node, NodeSet] = {}
	acc_nodes = list(self.acc_nodes)

	for node in acc_nodes:
	if node in result:
	continue
	if node.op not in CALLABLE_NODE_OPS:
	continue
	if "tensor_meta" in node.meta:
	continue
	if node not in self.acc_nodes:
	continue

	fusion_group: FxNetAccFusionsFinder.FusionGroup = self.FusionGroup(
	top_node_idx=self.nodes.index(node),
	nodes={node},
	inputs=set(node.all_input_nodes),
	nodes_need_process={node},
	)
	while fusion_group.nodes_need_process:
	node = fusion_group.nodes_need_process.pop()
	self.recursive_add_node(
	fusion_group,
	fusion_group.inputs,
	visited=set(),
	)

	# Optionally add downstream nodes
	if "tensor_meta" not in node.meta:
	for user in node.users:
	if user.op not in CALLABLE_NODE_OPS:
	continue
	if user in fusion_group.nodes:
	continue

	fusion_group.add_node(user)
	self.recursive_add_node(
	fusion_group,
	fusion_group.inputs,
	visited=set(),
	)

	# Add some upstream nodes
	for arg in node.all_input_nodes:
	if arg.op not in CALLABLE_NODE_OPS:
	continue
	if "tensor_meta" in arg.meta:
	continue
	if arg in fusion_group.nodes:
	continue

	fusion_group.add_node(arg)
	fusion_group.top_node_idx = min(
	fusion_group.top_node_idx, self.nodes.index(arg)
	)
	self.recursive_add_node(
	fusion_group,
	fusion_group.inputs,
	visited=set(),
	)

	if not (set(fusion_group.nodes) <= self.acc_nodes):
	self.acc_nodes -= fusion_group.nodes
	else:
	for n in fusion_group.nodes:
	result[n] = fusion_group.nodes

	return result


	@compatibility(is_backward_compatible=False)
	def legalize_graph(gm: torch.fx.GraphModule) -> torch.fx.GraphModule:
	"""
	Replace the graph of the given GraphModule with one that contains the same nodes as the
	original, but in topologically sorted order.

	This is used by the merge_matmul transformation below, which disturbs the topologically sorted
	order of its input GraphModule, so that this order is restored before further transformation.

	Arguments:
	gm: The graph module to topologically sort. It is modified in-place.

	Returns:
	The graph module in-place sorted
	"""

	# These operators are used for making runtime assertions before any
	# data-dependent operators occur. We want to prioritize sorting these to
	# ensure that these assertions appear before any data-dependent operations
	# in the graph.
	PRIORITIZED_OPS = [
	operator.add,
	operator.mul,
	operator.sub,
	operator.floordiv,
	operator.truediv,
	operator.mod,
	operator.le,
	operator.lt,
	operator.ge,
	operator.gt,
	operator.eq,
	operator.ne,
	torch.ops.aten.sym_constrain_range.default,
	torch.ops.aten.sym_constrain_range_for_size.default,
	torch.ops.aten._assert_async.msg,
	torch.ops.aten.scalar_tensor.default,
	torch.ops.aten._assert_scalar.default,
	]

	indeg = dict.fromkeys(gm.graph.nodes, 0)
	new_graph = torch.fx.Graph()
	# Track how many unfulfilled dependencies each node has
	for node in gm.graph.nodes:
	for user in node.users:
	indeg[user] += 1
	queue: collections.deque = collections.deque()
	# Add all nodes with no dependencies to the queue
	for node in gm.graph.nodes:
	if indeg[node] == 0:
	queue.append(node)
	env: Dict[torch.fx.Node, torch.fx.Node] = {}
	# Pop nodes from the queue, and add nodes that have had all their
	# dependencies fulfilled
	while len(queue) > 0:
	cur = queue.popleft()
	env[cur] = new_graph.node_copy(cur, lambda x: env[x])
	for user in cur.users:
	indeg[user] -= 1
	if indeg[user] == 0:
	if user.op == "call_function" and user.target in PRIORITIZED_OPS:
	queue.appendleft(user)
	else:
	queue.append(user)
	# If the new graph's size is not as large as the old one, then there must be
	# a cycle (i.e. some node's dependencies were not satisfied.)
	if len(new_graph.nodes) < len(gm.graph.nodes):
	raise RuntimeError(f"Input graph has cycles, unable to add {[node for node in indeg if indeg[node] != 0]}")
	new_graph._codegen = gm.graph._codegen
	gm.graph = new_graph
	return gm