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Source code for torch.fx.subgraph_rewriter

from .graph_module import GraphModule
from .graph import Graph
from .node import Node
from ._symbolic_trace import symbolic_trace
from ._compatibility import compatibility

import copy
from dataclasses import dataclass
from typing import Any, Callable, Dict, List, NamedTuple, Optional, Set, Union, TYPE_CHECKING
import torch

if TYPE_CHECKING:
    from .passes.utils.matcher_with_name_node_map_utils import InternalMatch

__all__ = ['Match', 'replace_pattern', 'replace_pattern_with_filters', "ReplacedPatterns"]

@compatibility(is_backward_compatible=True)
class Match(NamedTuple):
    # 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]

@compatibility(is_backward_compatible=False)
@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]

def _replace_attributes(gm: GraphModule, replacement: torch.nn.Module) -> None:
    gm.delete_all_unused_submodules()

    if isinstance(replacement, GraphModule):
        replacement.graph.lint()

    def try_get_attr(gm: torch.nn.Module, target: str) -> Optional[Any]:
        module_path, _, attr_name = target.rpartition(".")
        try:
            mod: torch.nn.Module = gm.get_submodule(module_path)
        except AttributeError:
            return None
        attr = getattr(mod, attr_name, None)
        return attr

    for node in gm.graph.nodes:
        if node.op == "call_module" or node.op == "get_attr":

            gm_attr = try_get_attr(gm, node.target)
            replacement_attr = try_get_attr(replacement, node.target)

            # CASE 1: This target already exists as an attribute in our
            # result GraphModule. Whether or not it exists in
            # `replacement`, the existing submodule takes precedence.
            if gm_attr is not None:
                continue

            # CASE 2: The target exists as an attribute in `replacement`
            # only, so we need to copy it over.
            elif replacement_attr is not None:
                new_attr = copy.deepcopy(replacement_attr)
                if isinstance(replacement_attr, torch.nn.Module):
                    gm.add_submodule(node.target, new_attr)
                else:
                    setattr(gm, node.target, new_attr)

            # CASE 3: The target doesn't exist as an attribute in `gm`
            # or `replacement`
            else:
                raise RuntimeError('Attempted to create a "', node.op,
                                   '" node during subgraph rewriting '
                                   f"with target {node.target}, but "
                                   "the referenced attribute does not "
                                   "exist in the replacement GraphModule")

    gm.graph.lint()


[docs]@compatibility(is_backward_compatible=True) def replace_pattern( gm: GraphModule, pattern: Union[Callable, GraphModule], replacement: Union[Callable, GraphModule] ) -> List[Match]: """ Matches all possible non-overlapping sets of operators and their data dependencies (``pattern``) in the Graph of a GraphModule (``gm``), then replaces each of these matched subgraphs with another subgraph (``replacement``). Args: ``gm``: The GraphModule that wraps the Graph to operate on ``pattern``: The subgraph to match in ``gm`` for replacement ``replacement``: The subgraph to replace ``pattern`` with Returns: List[Match]: A list of ``Match`` objects representing the places in the original graph that ``pattern`` was matched to. The list is empty if there are no matches. ``Match`` is defined as: .. code-block:: python class Match(NamedTuple): # 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] Examples: .. code-block:: python import torch from torch.fx import symbolic_trace, subgraph_rewriter class M(torch.nn.Module): def __init__(self): super().__init__() def forward(self, x, w1, w2): m1 = torch.cat([w1, w2]).sum() m2 = torch.cat([w1, w2]).sum() return x + torch.max(m1) + torch.max(m2) def pattern(w1, w2): return torch.cat([w1, w2]).sum() def replacement(w1, w2): return torch.stack([w1, w2]) traced_module = symbolic_trace(M()) subgraph_rewriter.replace_pattern(traced_module, pattern, replacement) The above code will first match ``pattern`` in the ``forward`` method of ``traced_module``. Pattern-matching is done based on use-def relationships, not node names. For example, if you had ``p = torch.cat([a, b])`` in ``pattern``, you could match ``m = torch.cat([a, b])`` in the original ``forward`` function, despite the variable names being different (``p`` vs ``m``). The ``return`` statement in ``pattern`` is matched based on its value only; it may or may not match to the ``return`` statement in the larger graph. In other words, the pattern doesn't have to extend to the end of the larger graph. When the pattern is matched, it will be removed from the larger function and replaced by ``replacement``. If there are multiple matches for ``pattern`` in the larger function, each non-overlapping match will be replaced. In the case of a match overlap, the first found match in the set of overlapping matches will be replaced. ("First" here being defined as the first in a topological ordering of the Nodes' use-def relationships. In most cases, the first Node is the parameter that appears directly after ``self``, while the last Node is whatever the function returns.) One important thing to note is that the parameters of the ``pattern`` Callable must be used in the Callable itself, and the parameters of the ``replacement`` Callable must match the pattern. The first rule is why, in the above code block, the ``forward`` function has parameters ``x, w1, w2``, but the ``pattern`` function only has parameters ``w1, w2``. ``pattern`` doesn't use ``x``, so it shouldn't specify ``x`` as a parameter. As an example of the second rule, consider replacing .. code-block:: python def pattern(x, y): return torch.neg(x) + torch.relu(y) with .. code-block:: python def replacement(x, y): return torch.relu(x) In this case, ``replacement`` needs the same number of parameters as ``pattern`` (both ``x`` and ``y``), even though the parameter ``y`` isn't used in ``replacement``. After calling ``subgraph_rewriter.replace_pattern``, the generated Python code looks like this: .. code-block:: python def forward(self, x, w1, w2): stack_1 = torch.stack([w1, w2]) sum_1 = stack_1.sum() stack_2 = torch.stack([w1, w2]) sum_2 = stack_2.sum() max_1 = torch.max(sum_1) add_1 = x + max_1 max_2 = torch.max(sum_2) add_2 = add_1 + max_2 return add_2 """ match_and_replacements = _replace_pattern(gm, pattern, replacement) return [Match(anchor=m.anchor, nodes_map=m.nodes_map) for m in match_and_replacements]
# Experimental API, not backward compatible @compatibility(is_backward_compatible=False) def replace_pattern_with_filters( gm: GraphModule, pattern: Union[Callable, Graph, GraphModule], replacement: Union[Callable, Graph, GraphModule], match_filters: Optional[List[Callable[["InternalMatch", Graph, Graph], bool]]] = None, ignore_literals: bool = False, ) -> List[ReplacedPatterns]: """ See replace_pattern for documentation. This function is an overload with an additional match_filter argument. Args: ``match_filters``: A list of functions that take in (match: InternalMatch, original_graph: Graph, pattern_graph: Graph) and return a boolean indicating whether the match satisfies the condition. See matcher_utils.py for definition of InternalMatch. """ return _replace_pattern(gm, pattern, replacement, match_filters, ignore_literals) def _replace_pattern( gm: GraphModule, pattern: Union[Callable, Graph, GraphModule], replacement: Union[Callable, Graph, GraphModule], match_filters: Optional[List[Callable[["InternalMatch", Graph, Graph], bool]]] = None, ignore_literals: bool = False, ) -> List[ReplacedPatterns]: from torch.fx.passes.utils.matcher_utils import SubgraphMatcher, InternalMatch if match_filters is None: match_filters = [] # Get the graphs for `gm`, `pattern`, `replacement` original_graph: Graph = gm.graph if isinstance(pattern, GraphModule): pattern_graph = pattern.graph elif isinstance(pattern, Graph): pattern_graph = pattern else: pattern_graph = symbolic_trace(pattern).graph if isinstance(replacement, GraphModule): replacement_graph = replacement.graph elif isinstance(replacement, Graph): replacement_graph = replacement else: replacement_graph = symbolic_trace(replacement).graph matcher = SubgraphMatcher(pattern_graph, match_output=False, match_placeholder=False, remove_overlapping_matches=True, ignore_literals=ignore_literals) _matches: List[InternalMatch] = matcher.match(original_graph) # Filter out matches that don't match the filter _matches = [ m for m in _matches if all(match_filter(m, original_graph, pattern_graph) for match_filter in match_filters) ] replacement_placeholders = [n for n in replacement_graph.nodes if n.op == "placeholder"] # As we progressively replace nodes, we'll need to keep track of how the match results should change match_changed_node: Dict[Node, Node] = {} match_and_replacements = [] for match in _matches: # Build connecting between replacement graph's input and original graph input producer node # Initialize `val_map` with mappings from placeholder nodes in # `replacement` to their corresponding node in `original_graph` assert len(match.placeholder_nodes) == len(replacement_placeholders) val_map: Dict[Node, Node] = {} for rn, gn in zip(replacement_placeholders, match.placeholder_nodes): if isinstance(gn, Node): val_map[rn] = match_changed_node.get(gn, gn) if gn != val_map[rn]: # Update match.placeholder_nodes and match.nodes_map with the node that replaced gn gn_ind = match.placeholder_nodes.index(gn) match.placeholder_nodes[gn_ind] = match_changed_node[gn] map_key = list(match.nodes_map.keys())[list(match.nodes_map.values()).index(gn)] match.nodes_map[map_key] = match_changed_node[gn] else: val_map[rn] = gn # Copy the replacement graph over user_nodes: Set[Node] = set() for n in match.returning_nodes: user_nodes.update(n.users) assert user_nodes, "The returning_nodes should have at least one user node" if len(user_nodes) == 1: first_user_node = next(iter(user_nodes)) else: # If there are multiple user nodes, we need to find the first user node # in the current execution order of the `original_graph` for n in original_graph.nodes: if n in user_nodes: first_user_node = n break with original_graph.inserting_before(first_user_node): # type: ignore[possibly-undefined] copied_returning_nodes = original_graph.graph_copy(replacement_graph, val_map) if isinstance(copied_returning_nodes, Node): copied_returning_nodes = (copied_returning_nodes, ) # Get a list of nodes that have been replaced into the graph replacement_nodes: List[Node] = [v for v in val_map.values() if v not in match.placeholder_nodes] # Hook the output Node of the replacement subgraph in to the # original Graph at the correct location assert len(match.returning_nodes) == len(copied_returning_nodes) for gn, copied_node in zip(match.returning_nodes, copied_returning_nodes): gn.replace_all_uses_with(copied_node) match_changed_node[gn] = copied_node # Remove the original nodes for node in reversed(pattern_graph.nodes): if node.op != "placeholder" and node.op != "output": gn = match.nodes_map[node] gm.graph.erase_node(gn) match_and_replacements.append( ReplacedPatterns( anchor=match.anchors[0], nodes_map=match.nodes_map, replacements=replacement_nodes ) ) # Update the passed-in GraphModule to reflect the new state of # `original_graph` gm.recompile() # If `replacement` was an nn.Module, we'll need to make sure that # all the submodules have been copied over correctly if isinstance(replacement, torch.nn.Module): _replace_attributes(gm, replacement) return match_and_replacements

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