mirror of
https://github.com/invoke-ai/InvokeAI
synced 2024-08-30 20:32:17 +00:00
1236 lines
49 KiB
Python
1236 lines
49 KiB
Python
# Copyright (c) 2022 Kyle Schouviller (https://github.com/kyle0654)
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import copy
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import itertools
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from typing import Annotated, Any, Optional, Union, get_args, get_origin, get_type_hints
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import networkx as nx
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from pydantic import BaseModel, ConfigDict, field_validator, model_validator
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from pydantic.fields import Field
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# Importing * is bad karma but needed here for node detection
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from invokeai.app.invocations import * # noqa: F401 F403
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from invokeai.app.invocations.baseinvocation import (
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BaseInvocation,
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BaseInvocationOutput,
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Input,
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InputField,
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InvocationContext,
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OutputField,
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UIType,
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invocation,
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invocation_output,
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)
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from invokeai.app.util.misc import uuid_string
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# in 3.10 this would be "from types import NoneType"
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NoneType = type(None)
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class EdgeConnection(BaseModel):
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node_id: str = Field(description="The id of the node for this edge connection")
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field: str = Field(description="The field for this connection")
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def __eq__(self, other):
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return (
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isinstance(other, self.__class__)
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and getattr(other, "node_id", None) == self.node_id
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and getattr(other, "field", None) == self.field
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)
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def __hash__(self):
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return hash(f"{self.node_id}.{self.field}")
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class Edge(BaseModel):
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source: EdgeConnection = Field(description="The connection for the edge's from node and field")
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destination: EdgeConnection = Field(description="The connection for the edge's to node and field")
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def get_output_field(node: BaseInvocation, field: str) -> Any:
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node_type = type(node)
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node_outputs = get_type_hints(node_type.get_output_type())
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node_output_field = node_outputs.get(field) or None
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return node_output_field
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def get_input_field(node: BaseInvocation, field: str) -> Any:
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node_type = type(node)
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node_inputs = get_type_hints(node_type)
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node_input_field = node_inputs.get(field) or None
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return node_input_field
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def is_union_subtype(t1, t2):
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t1_args = get_args(t1)
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t2_args = get_args(t2)
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if not t1_args:
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# t1 is a single type
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return t1 in t2_args
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else:
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# t1 is a Union, check that all of its types are in t2_args
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return all(arg in t2_args for arg in t1_args)
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def is_list_or_contains_list(t):
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t_args = get_args(t)
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# If the type is a List
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if get_origin(t) is list:
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return True
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# If the type is a Union
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elif t_args:
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# Check if any of the types in the Union is a List
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for arg in t_args:
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if get_origin(arg) is list:
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return True
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return False
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def are_connection_types_compatible(from_type: Any, to_type: Any) -> bool:
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if not from_type:
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return False
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if not to_type:
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return False
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# TODO: this is pretty forgiving on generic types. Clean that up (need to handle optionals and such)
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if from_type and to_type:
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# Ports are compatible
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if (
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from_type == to_type
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or from_type == Any
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or to_type == Any
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or Any in get_args(from_type)
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or Any in get_args(to_type)
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):
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return True
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if from_type in get_args(to_type):
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return True
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if to_type in get_args(from_type):
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return True
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# allow int -> float, pydantic will cast for us
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if from_type is int and to_type is float:
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return True
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# allow int|float -> str, pydantic will cast for us
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if (from_type is int or from_type is float) and to_type is str:
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return True
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# if not issubclass(from_type, to_type):
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if not is_union_subtype(from_type, to_type):
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return False
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else:
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return False
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return True
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def are_connections_compatible(
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from_node: BaseInvocation, from_field: str, to_node: BaseInvocation, to_field: str
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) -> bool:
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"""Determines if a connection between fields of two nodes is compatible."""
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# TODO: handle iterators and collectors
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from_node_field = get_output_field(from_node, from_field)
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to_node_field = get_input_field(to_node, to_field)
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return are_connection_types_compatible(from_node_field, to_node_field)
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class NodeAlreadyInGraphError(ValueError):
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pass
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class InvalidEdgeError(ValueError):
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pass
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class NodeNotFoundError(ValueError):
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pass
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class NodeAlreadyExecutedError(ValueError):
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pass
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class DuplicateNodeIdError(ValueError):
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pass
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class NodeFieldNotFoundError(ValueError):
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pass
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class NodeIdMismatchError(ValueError):
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pass
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class InvalidSubGraphError(ValueError):
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pass
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class CyclicalGraphError(ValueError):
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pass
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class UnknownGraphValidationError(ValueError):
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pass
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# TODO: Create and use an Empty output?
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@invocation_output("graph_output")
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class GraphInvocationOutput(BaseInvocationOutput):
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pass
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# TODO: Fill this out and move to invocations
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@invocation("graph")
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class GraphInvocation(BaseInvocation):
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"""Execute a graph"""
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# TODO: figure out how to create a default here
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graph: "Graph" = InputField(description="The graph to run", default=None)
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def invoke(self, context: InvocationContext) -> GraphInvocationOutput:
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"""Invoke with provided services and return outputs."""
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return GraphInvocationOutput()
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@invocation_output("iterate_output")
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class IterateInvocationOutput(BaseInvocationOutput):
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"""Used to connect iteration outputs. Will be expanded to a specific output."""
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item: Any = OutputField(
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description="The item being iterated over", title="Collection Item", ui_type=UIType.CollectionItem
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)
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# TODO: Fill this out and move to invocations
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@invocation("iterate", version="1.0.0")
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class IterateInvocation(BaseInvocation):
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"""Iterates over a list of items"""
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collection: list[Any] = InputField(
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description="The list of items to iterate over", default_factory=list, ui_type=UIType.Collection
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)
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index: int = InputField(description="The index, will be provided on executed iterators", default=0, ui_hidden=True)
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def invoke(self, context: InvocationContext) -> IterateInvocationOutput:
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"""Produces the outputs as values"""
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return IterateInvocationOutput(item=self.collection[self.index])
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@invocation_output("collect_output")
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class CollectInvocationOutput(BaseInvocationOutput):
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collection: list[Any] = OutputField(
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description="The collection of input items", title="Collection", ui_type=UIType.Collection
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)
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@invocation("collect", version="1.0.0")
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class CollectInvocation(BaseInvocation):
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"""Collects values into a collection"""
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item: Optional[Any] = InputField(
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default=None,
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description="The item to collect (all inputs must be of the same type)",
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ui_type=UIType.CollectionItem,
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title="Collection Item",
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input=Input.Connection,
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)
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collection: list[Any] = InputField(
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description="The collection, will be provided on execution", default_factory=list, ui_hidden=True
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)
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def invoke(self, context: InvocationContext) -> CollectInvocationOutput:
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"""Invoke with provided services and return outputs."""
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return CollectInvocationOutput(collection=copy.copy(self.collection))
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InvocationsUnion: Any = BaseInvocation.get_invocations_union()
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InvocationOutputsUnion: Any = BaseInvocationOutput.get_outputs_union()
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class Graph(BaseModel):
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id: str = Field(description="The id of this graph", default_factory=uuid_string)
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# TODO: use a list (and never use dict in a BaseModel) because pydantic/fastapi hates me
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nodes: dict[str, Annotated[InvocationsUnion, Field(discriminator="type")]] = Field(
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description="The nodes in this graph", default_factory=dict
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)
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edges: list[Edge] = Field(
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description="The connections between nodes and their fields in this graph",
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default_factory=list,
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)
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def add_node(self, node: BaseInvocation) -> None:
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"""Adds a node to a graph
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:raises NodeAlreadyInGraphError: the node is already present in the graph.
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"""
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if node.id in self.nodes:
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raise NodeAlreadyInGraphError()
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self.nodes[node.id] = node
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def _get_graph_and_node(self, node_path: str) -> tuple["Graph", str]:
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"""Returns the graph and node id for a node path."""
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# Materialized graphs may have nodes at the top level
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if node_path in self.nodes:
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return (self, node_path)
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node_id = node_path if "." not in node_path else node_path[: node_path.index(".")]
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if node_id not in self.nodes:
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raise NodeNotFoundError(f"Node {node_path} not found in graph")
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node = self.nodes[node_id]
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if not isinstance(node, GraphInvocation):
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# There's more node path left but this isn't a graph - failure
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raise NodeNotFoundError("Node path terminated early at a non-graph node")
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return node.graph._get_graph_and_node(node_path[node_path.index(".") + 1 :])
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def delete_node(self, node_path: str) -> None:
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"""Deletes a node from a graph"""
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try:
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graph, node_id = self._get_graph_and_node(node_path)
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# Delete edges for this node
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input_edges = self._get_input_edges_and_graphs(node_path)
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output_edges = self._get_output_edges_and_graphs(node_path)
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for edge_graph, _, edge in input_edges:
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edge_graph.delete_edge(edge)
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for edge_graph, _, edge in output_edges:
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edge_graph.delete_edge(edge)
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del graph.nodes[node_id]
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except NodeNotFoundError:
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pass # Ignore, not doesn't exist (should this throw?)
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def add_edge(self, edge: Edge) -> None:
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"""Adds an edge to a graph
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:raises InvalidEdgeError: the provided edge is invalid.
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"""
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self._validate_edge(edge)
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if edge not in self.edges:
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self.edges.append(edge)
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else:
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raise InvalidEdgeError()
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def delete_edge(self, edge: Edge) -> None:
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"""Deletes an edge from a graph"""
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try:
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self.edges.remove(edge)
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except KeyError:
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pass
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def validate_self(self) -> None:
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"""
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Validates the graph.
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Raises an exception if the graph is invalid:
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- `DuplicateNodeIdError`
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- `NodeIdMismatchError`
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- `InvalidSubGraphError`
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- `NodeNotFoundError`
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- `NodeFieldNotFoundError`
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- `CyclicalGraphError`
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- `InvalidEdgeError`
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"""
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# Validate that all node ids are unique
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node_ids = [n.id for n in self.nodes.values()]
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duplicate_node_ids = {node_id for node_id in node_ids if node_ids.count(node_id) >= 2}
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if duplicate_node_ids:
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raise DuplicateNodeIdError(f"Node ids must be unique, found duplicates {duplicate_node_ids}")
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# Validate that all node ids match the keys in the nodes dict
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for k, v in self.nodes.items():
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if k != v.id:
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raise NodeIdMismatchError(f"Node ids must match, got {k} and {v.id}")
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# Validate all subgraphs
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for gn in (n for n in self.nodes.values() if isinstance(n, GraphInvocation)):
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try:
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gn.graph.validate_self()
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except Exception as e:
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raise InvalidSubGraphError(f"Subgraph {gn.id} is invalid") from e
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# Validate that all edges match nodes and fields in the graph
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for edge in self.edges:
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source_node = self.nodes.get(edge.source.node_id, None)
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if source_node is None:
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raise NodeNotFoundError(f"Edge source node {edge.source.node_id} does not exist in the graph")
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destination_node = self.nodes.get(edge.destination.node_id, None)
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if destination_node is None:
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raise NodeNotFoundError(f"Edge destination node {edge.destination.node_id} does not exist in the graph")
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# output fields are not on the node object directly, they are on the output type
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if edge.source.field not in source_node.get_output_type().model_fields:
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raise NodeFieldNotFoundError(
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f"Edge source field {edge.source.field} does not exist in node {edge.source.node_id}"
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)
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# input fields are on the node
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if edge.destination.field not in destination_node.model_fields:
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raise NodeFieldNotFoundError(
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f"Edge destination field {edge.destination.field} does not exist in node {edge.destination.node_id}"
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)
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# Validate there are no cycles
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g = self.nx_graph_flat()
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if not nx.is_directed_acyclic_graph(g):
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raise CyclicalGraphError("Graph contains cycles")
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# Validate all edge connections are valid
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for edge in self.edges:
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if not are_connections_compatible(
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self.get_node(edge.source.node_id),
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edge.source.field,
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self.get_node(edge.destination.node_id),
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edge.destination.field,
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):
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raise InvalidEdgeError(
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f"Invalid edge from {edge.source.node_id}.{edge.source.field} to {edge.destination.node_id}.{edge.destination.field}"
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)
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# Validate all iterators & collectors
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# TODO: may need to validate all iterators & collectors in subgraphs so edge connections in parent graphs will be available
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for node in self.nodes.values():
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if isinstance(node, IterateInvocation) and not self._is_iterator_connection_valid(node.id):
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raise InvalidEdgeError(f"Invalid iterator node {node.id}")
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if isinstance(node, CollectInvocation) and not self._is_collector_connection_valid(node.id):
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raise InvalidEdgeError(f"Invalid collector node {node.id}")
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return None
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def is_valid(self) -> bool:
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"""
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Checks if the graph is valid.
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Raises `UnknownGraphValidationError` if there is a problem validating the graph (not a validation error).
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"""
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try:
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self.validate_self()
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return True
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except (
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DuplicateNodeIdError,
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NodeIdMismatchError,
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InvalidSubGraphError,
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NodeNotFoundError,
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NodeFieldNotFoundError,
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CyclicalGraphError,
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InvalidEdgeError,
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):
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return False
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except Exception as e:
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raise UnknownGraphValidationError(f"Problem validating graph {e}") from e
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def _is_destination_field_Any(self, edge: Edge) -> bool:
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"""Checks if the destination field for an edge is of type typing.Any"""
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return get_input_field(self.get_node(edge.destination.node_id), edge.destination.field) == Any
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def _is_destination_field_list_of_Any(self, edge: Edge) -> bool:
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"""Checks if the destination field for an edge is of type typing.Any"""
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return get_input_field(self.get_node(edge.destination.node_id), edge.destination.field) == list[Any]
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def _validate_edge(self, edge: Edge):
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"""Validates that a new edge doesn't create a cycle in the graph"""
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# Validate that the nodes exist (edges may contain node paths, so we can't just check for nodes directly)
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try:
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from_node = self.get_node(edge.source.node_id)
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to_node = self.get_node(edge.destination.node_id)
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except NodeNotFoundError:
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raise InvalidEdgeError("One or both nodes don't exist: {edge.source.node_id} -> {edge.destination.node_id}")
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# Validate that an edge to this node+field doesn't already exist
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input_edges = self._get_input_edges(edge.destination.node_id, edge.destination.field)
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if len(input_edges) > 0 and not isinstance(to_node, CollectInvocation):
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raise InvalidEdgeError(
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f"Edge to node {edge.destination.node_id} field {edge.destination.field} already exists"
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)
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# Validate that no cycles would be created
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g = self.nx_graph_flat()
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g.add_edge(edge.source.node_id, edge.destination.node_id)
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if not nx.is_directed_acyclic_graph(g):
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raise InvalidEdgeError(
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f"Edge creates a cycle in the graph: {edge.source.node_id} -> {edge.destination.node_id}"
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)
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# Validate that the field types are compatible
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if not are_connections_compatible(from_node, edge.source.field, to_node, edge.destination.field):
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raise InvalidEdgeError(
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f"Fields are incompatible: cannot connect {edge.source.node_id}.{edge.source.field} to {edge.destination.node_id}.{edge.destination.field}"
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)
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# Validate if iterator output type matches iterator input type (if this edge results in both being set)
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if isinstance(to_node, IterateInvocation) and edge.destination.field == "collection":
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if not self._is_iterator_connection_valid(edge.destination.node_id, new_input=edge.source):
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raise InvalidEdgeError(
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f"Iterator input type does not match iterator output type: {edge.source.node_id}.{edge.source.field} to {edge.destination.node_id}.{edge.destination.field}"
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)
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# Validate if iterator input type matches output type (if this edge results in both being set)
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if isinstance(from_node, IterateInvocation) and edge.source.field == "item":
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if not self._is_iterator_connection_valid(edge.source.node_id, new_output=edge.destination):
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raise InvalidEdgeError(
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f"Iterator output type does not match iterator input type:, {edge.source.node_id}.{edge.source.field} to {edge.destination.node_id}.{edge.destination.field}"
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)
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# Validate if collector input type matches output type (if this edge results in both being set)
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if isinstance(to_node, CollectInvocation) and edge.destination.field == "item":
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if not self._is_collector_connection_valid(edge.destination.node_id, new_input=edge.source):
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raise InvalidEdgeError(
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f"Collector output type does not match collector input type: {edge.source.node_id}.{edge.source.field} to {edge.destination.node_id}.{edge.destination.field}"
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)
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# Validate that we are not connecting collector to iterator (currently unsupported)
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if isinstance(from_node, CollectInvocation) and isinstance(to_node, IterateInvocation):
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raise InvalidEdgeError(
|
|
f"Cannot connect collector to iterator: {edge.source.node_id}.{edge.source.field} to {edge.destination.node_id}.{edge.destination.field}"
|
|
)
|
|
|
|
# Validate if collector output type matches input type (if this edge results in both being set) - skip if the destination field is not Any or list[Any]
|
|
if (
|
|
isinstance(from_node, CollectInvocation)
|
|
and edge.source.field == "collection"
|
|
and not self._is_destination_field_list_of_Any(edge)
|
|
and not self._is_destination_field_Any(edge)
|
|
):
|
|
if not self._is_collector_connection_valid(edge.source.node_id, new_output=edge.destination):
|
|
raise InvalidEdgeError(
|
|
f"Collector input type does not match collector output type: {edge.source.node_id}.{edge.source.field} to {edge.destination.node_id}.{edge.destination.field}"
|
|
)
|
|
|
|
def has_node(self, node_path: str) -> bool:
|
|
"""Determines whether or not a node exists in the graph."""
|
|
try:
|
|
n = self.get_node(node_path)
|
|
if n is not None:
|
|
return True
|
|
else:
|
|
return False
|
|
except NodeNotFoundError:
|
|
return False
|
|
|
|
def get_node(self, node_path: str) -> InvocationsUnion:
|
|
"""Gets a node from the graph using a node path."""
|
|
# Materialized graphs may have nodes at the top level
|
|
graph, node_id = self._get_graph_and_node(node_path)
|
|
return graph.nodes[node_id]
|
|
|
|
def _get_node_path(self, node_id: str, prefix: Optional[str] = None) -> str:
|
|
return node_id if prefix is None or prefix == "" else f"{prefix}.{node_id}"
|
|
|
|
def update_node(self, node_path: str, new_node: BaseInvocation) -> None:
|
|
"""Updates a node in the graph."""
|
|
graph, node_id = self._get_graph_and_node(node_path)
|
|
node = graph.nodes[node_id]
|
|
|
|
# Ensure the node type matches the new node
|
|
if type(node) is not type(new_node):
|
|
raise TypeError(f"Node {node_path} is type {type(node)} but new node is type {type(new_node)}")
|
|
|
|
# Ensure the new id is either the same or is not in the graph
|
|
prefix = None if "." not in node_path else node_path[: node_path.rindex(".")]
|
|
new_path = self._get_node_path(new_node.id, prefix=prefix)
|
|
if new_node.id != node.id and self.has_node(new_path):
|
|
raise NodeAlreadyInGraphError("Node with id {new_node.id} already exists in graph")
|
|
|
|
# Set the new node in the graph
|
|
graph.nodes[new_node.id] = new_node
|
|
if new_node.id != node.id:
|
|
input_edges = self._get_input_edges_and_graphs(node_path)
|
|
output_edges = self._get_output_edges_and_graphs(node_path)
|
|
|
|
# Delete node and all edges
|
|
graph.delete_node(node_path)
|
|
|
|
# Create new edges for each input and output
|
|
for graph, _, edge in input_edges:
|
|
# Remove the graph prefix from the node path
|
|
new_graph_node_path = (
|
|
new_node.id
|
|
if "." not in edge.destination.node_id
|
|
else f'{edge.destination.node_id[edge.destination.node_id.rindex("."):]}.{new_node.id}'
|
|
)
|
|
graph.add_edge(
|
|
Edge(
|
|
source=edge.source,
|
|
destination=EdgeConnection(node_id=new_graph_node_path, field=edge.destination.field),
|
|
)
|
|
)
|
|
|
|
for graph, _, edge in output_edges:
|
|
# Remove the graph prefix from the node path
|
|
new_graph_node_path = (
|
|
new_node.id
|
|
if "." not in edge.source.node_id
|
|
else f'{edge.source.node_id[edge.source.node_id.rindex("."):]}.{new_node.id}'
|
|
)
|
|
graph.add_edge(
|
|
Edge(
|
|
source=EdgeConnection(node_id=new_graph_node_path, field=edge.source.field),
|
|
destination=edge.destination,
|
|
)
|
|
)
|
|
|
|
def _get_input_edges(self, node_path: str, field: Optional[str] = None) -> list[Edge]:
|
|
"""Gets all input edges for a node"""
|
|
edges = self._get_input_edges_and_graphs(node_path)
|
|
|
|
# Filter to edges that match the field
|
|
filtered_edges = (e for e in edges if field is None or e[2].destination.field == field)
|
|
|
|
# Create full node paths for each edge
|
|
return [
|
|
Edge(
|
|
source=EdgeConnection(
|
|
node_id=self._get_node_path(e.source.node_id, prefix=prefix),
|
|
field=e.source.field,
|
|
),
|
|
destination=EdgeConnection(
|
|
node_id=self._get_node_path(e.destination.node_id, prefix=prefix),
|
|
field=e.destination.field,
|
|
),
|
|
)
|
|
for _, prefix, e in filtered_edges
|
|
]
|
|
|
|
def _get_input_edges_and_graphs(
|
|
self, node_path: str, prefix: Optional[str] = None
|
|
) -> list[tuple["Graph", Union[str, None], Edge]]:
|
|
"""Gets all input edges for a node along with the graph they are in and the graph's path"""
|
|
edges = []
|
|
|
|
# Return any input edges that appear in this graph
|
|
edges.extend([(self, prefix, e) for e in self.edges if e.destination.node_id == node_path])
|
|
|
|
node_id = node_path if "." not in node_path else node_path[: node_path.index(".")]
|
|
node = self.nodes[node_id]
|
|
|
|
if isinstance(node, GraphInvocation):
|
|
graph = node.graph
|
|
graph_path = node.id if prefix is None or prefix == "" else self._get_node_path(node.id, prefix=prefix)
|
|
graph_edges = graph._get_input_edges_and_graphs(node_path[(len(node_id) + 1) :], prefix=graph_path)
|
|
edges.extend(graph_edges)
|
|
|
|
return edges
|
|
|
|
def _get_output_edges(self, node_path: str, field: str) -> list[Edge]:
|
|
"""Gets all output edges for a node"""
|
|
edges = self._get_output_edges_and_graphs(node_path)
|
|
|
|
# Filter to edges that match the field
|
|
filtered_edges = (e for e in edges if e[2].source.field == field)
|
|
|
|
# Create full node paths for each edge
|
|
return [
|
|
Edge(
|
|
source=EdgeConnection(
|
|
node_id=self._get_node_path(e.source.node_id, prefix=prefix),
|
|
field=e.source.field,
|
|
),
|
|
destination=EdgeConnection(
|
|
node_id=self._get_node_path(e.destination.node_id, prefix=prefix),
|
|
field=e.destination.field,
|
|
),
|
|
)
|
|
for _, prefix, e in filtered_edges
|
|
]
|
|
|
|
def _get_output_edges_and_graphs(
|
|
self, node_path: str, prefix: Optional[str] = None
|
|
) -> list[tuple["Graph", Union[str, None], Edge]]:
|
|
"""Gets all output edges for a node along with the graph they are in and the graph's path"""
|
|
edges = []
|
|
|
|
# Return any input edges that appear in this graph
|
|
edges.extend([(self, prefix, e) for e in self.edges if e.source.node_id == node_path])
|
|
|
|
node_id = node_path if "." not in node_path else node_path[: node_path.index(".")]
|
|
node = self.nodes[node_id]
|
|
|
|
if isinstance(node, GraphInvocation):
|
|
graph = node.graph
|
|
graph_path = node.id if prefix is None or prefix == "" else self._get_node_path(node.id, prefix=prefix)
|
|
graph_edges = graph._get_output_edges_and_graphs(node_path[(len(node_id) + 1) :], prefix=graph_path)
|
|
edges.extend(graph_edges)
|
|
|
|
return edges
|
|
|
|
def _is_iterator_connection_valid(
|
|
self,
|
|
node_path: str,
|
|
new_input: Optional[EdgeConnection] = None,
|
|
new_output: Optional[EdgeConnection] = None,
|
|
) -> bool:
|
|
inputs = [e.source for e in self._get_input_edges(node_path, "collection")]
|
|
outputs = [e.destination for e in self._get_output_edges(node_path, "item")]
|
|
|
|
if new_input is not None:
|
|
inputs.append(new_input)
|
|
if new_output is not None:
|
|
outputs.append(new_output)
|
|
|
|
# Only one input is allowed for iterators
|
|
if len(inputs) > 1:
|
|
return False
|
|
|
|
# Get input and output fields (the fields linked to the iterator's input/output)
|
|
input_field = get_output_field(self.get_node(inputs[0].node_id), inputs[0].field)
|
|
output_fields = [get_input_field(self.get_node(e.node_id), e.field) for e in outputs]
|
|
|
|
# Input type must be a list
|
|
if get_origin(input_field) != list:
|
|
return False
|
|
|
|
# Validate that all outputs match the input type
|
|
input_field_item_type = get_args(input_field)[0]
|
|
if not all((are_connection_types_compatible(input_field_item_type, f) for f in output_fields)):
|
|
return False
|
|
|
|
return True
|
|
|
|
def _is_collector_connection_valid(
|
|
self,
|
|
node_path: str,
|
|
new_input: Optional[EdgeConnection] = None,
|
|
new_output: Optional[EdgeConnection] = None,
|
|
) -> bool:
|
|
inputs = [e.source for e in self._get_input_edges(node_path, "item")]
|
|
outputs = [e.destination for e in self._get_output_edges(node_path, "collection")]
|
|
|
|
if new_input is not None:
|
|
inputs.append(new_input)
|
|
if new_output is not None:
|
|
outputs.append(new_output)
|
|
|
|
# Get input and output fields (the fields linked to the iterator's input/output)
|
|
input_fields = [get_output_field(self.get_node(e.node_id), e.field) for e in inputs]
|
|
output_fields = [get_input_field(self.get_node(e.node_id), e.field) for e in outputs]
|
|
|
|
# Validate that all inputs are derived from or match a single type
|
|
input_field_types = {
|
|
t
|
|
for input_field in input_fields
|
|
for t in ([input_field] if get_origin(input_field) is None else get_args(input_field))
|
|
if t != NoneType
|
|
} # Get unique types
|
|
type_tree = nx.DiGraph()
|
|
type_tree.add_nodes_from(input_field_types)
|
|
type_tree.add_edges_from([e for e in itertools.permutations(input_field_types, 2) if issubclass(e[1], e[0])])
|
|
type_degrees = type_tree.in_degree(type_tree.nodes)
|
|
if sum((t[1] == 0 for t in type_degrees)) != 1: # type: ignore
|
|
return False # There is more than one root type
|
|
|
|
# Get the input root type
|
|
input_root_type = next(t[0] for t in type_degrees if t[1] == 0) # type: ignore
|
|
|
|
# Verify that all outputs are lists
|
|
if not all(is_list_or_contains_list(f) for f in output_fields):
|
|
return False
|
|
|
|
# Verify that all outputs match the input type (are a base class or the same class)
|
|
if not all(
|
|
is_union_subtype(input_root_type, get_args(f)[0]) or issubclass(input_root_type, get_args(f)[0])
|
|
for f in output_fields
|
|
):
|
|
return False
|
|
|
|
return True
|
|
|
|
def nx_graph(self) -> nx.DiGraph:
|
|
"""Returns a NetworkX DiGraph representing the layout of this graph"""
|
|
# TODO: Cache this?
|
|
g = nx.DiGraph()
|
|
g.add_nodes_from(list(self.nodes.keys()))
|
|
g.add_edges_from({(e.source.node_id, e.destination.node_id) for e in self.edges})
|
|
return g
|
|
|
|
def nx_graph_with_data(self) -> nx.DiGraph:
|
|
"""Returns a NetworkX DiGraph representing the data and layout of this graph"""
|
|
g = nx.DiGraph()
|
|
g.add_nodes_from(list(self.nodes.items()))
|
|
g.add_edges_from({(e.source.node_id, e.destination.node_id) for e in self.edges})
|
|
return g
|
|
|
|
def nx_graph_flat(self, nx_graph: Optional[nx.DiGraph] = None, prefix: Optional[str] = None) -> nx.DiGraph:
|
|
"""Returns a flattened NetworkX DiGraph, including all subgraphs (but not with iterations expanded)"""
|
|
g = nx_graph or nx.DiGraph()
|
|
|
|
# Add all nodes from this graph except graph/iteration nodes
|
|
g.add_nodes_from(
|
|
[
|
|
self._get_node_path(n.id, prefix)
|
|
for n in self.nodes.values()
|
|
if not isinstance(n, GraphInvocation) and not isinstance(n, IterateInvocation)
|
|
]
|
|
)
|
|
|
|
# Expand graph nodes
|
|
for sgn in (gn for gn in self.nodes.values() if isinstance(gn, GraphInvocation)):
|
|
g = sgn.graph.nx_graph_flat(g, self._get_node_path(sgn.id, prefix))
|
|
|
|
# TODO: figure out if iteration nodes need to be expanded
|
|
|
|
unique_edges = {(e.source.node_id, e.destination.node_id) for e in self.edges}
|
|
g.add_edges_from([(self._get_node_path(e[0], prefix), self._get_node_path(e[1], prefix)) for e in unique_edges])
|
|
return g
|
|
|
|
|
|
class GraphExecutionState(BaseModel):
|
|
"""Tracks the state of a graph execution"""
|
|
|
|
id: str = Field(description="The id of the execution state", default_factory=uuid_string)
|
|
# TODO: Store a reference to the graph instead of the actual graph?
|
|
graph: Graph = Field(description="The graph being executed")
|
|
|
|
# The graph of materialized nodes
|
|
execution_graph: Graph = Field(
|
|
description="The expanded graph of activated and executed nodes",
|
|
default_factory=Graph,
|
|
)
|
|
|
|
# Nodes that have been executed
|
|
executed: set[str] = Field(description="The set of node ids that have been executed", default_factory=set)
|
|
executed_history: list[str] = Field(
|
|
description="The list of node ids that have been executed, in order of execution",
|
|
default_factory=list,
|
|
)
|
|
|
|
# The results of executed nodes
|
|
results: dict[str, Annotated[InvocationOutputsUnion, Field(discriminator="type")]] = Field(
|
|
description="The results of node executions", default_factory=dict
|
|
)
|
|
|
|
# Errors raised when executing nodes
|
|
errors: dict[str, str] = Field(description="Errors raised when executing nodes", default_factory=dict)
|
|
|
|
# Map of prepared/executed nodes to their original nodes
|
|
prepared_source_mapping: dict[str, str] = Field(
|
|
description="The map of prepared nodes to original graph nodes",
|
|
default_factory=dict,
|
|
)
|
|
|
|
# Map of original nodes to prepared nodes
|
|
source_prepared_mapping: dict[str, set[str]] = Field(
|
|
description="The map of original graph nodes to prepared nodes",
|
|
default_factory=dict,
|
|
)
|
|
|
|
@field_validator("graph")
|
|
def graph_is_valid(cls, v: Graph):
|
|
"""Validates that the graph is valid"""
|
|
v.validate_self()
|
|
return v
|
|
|
|
model_config = ConfigDict(
|
|
json_schema_extra={
|
|
"required": [
|
|
"id",
|
|
"graph",
|
|
"execution_graph",
|
|
"executed",
|
|
"executed_history",
|
|
"results",
|
|
"errors",
|
|
"prepared_source_mapping",
|
|
"source_prepared_mapping",
|
|
]
|
|
}
|
|
)
|
|
|
|
def next(self) -> Optional[BaseInvocation]:
|
|
"""Gets the next node ready to execute."""
|
|
|
|
# TODO: enable multiple nodes to execute simultaneously by tracking currently executing nodes
|
|
# possibly with a timeout?
|
|
|
|
# If there are no prepared nodes, prepare some nodes
|
|
next_node = self._get_next_node()
|
|
if next_node is None:
|
|
prepared_id = self._prepare()
|
|
|
|
# Prepare as many nodes as we can
|
|
while prepared_id is not None:
|
|
prepared_id = self._prepare()
|
|
next_node = self._get_next_node()
|
|
|
|
# Get values from edges
|
|
if next_node is not None:
|
|
self._prepare_inputs(next_node)
|
|
|
|
# If next is still none, there's no next node, return None
|
|
return next_node
|
|
|
|
def complete(self, node_id: str, output: InvocationOutputsUnion):
|
|
"""Marks a node as complete"""
|
|
|
|
if node_id not in self.execution_graph.nodes:
|
|
return # TODO: log error?
|
|
|
|
# Mark node as executed
|
|
self.executed.add(node_id)
|
|
self.results[node_id] = output
|
|
|
|
# Check if source node is complete (all prepared nodes are complete)
|
|
source_node = self.prepared_source_mapping[node_id]
|
|
prepared_nodes = self.source_prepared_mapping[source_node]
|
|
|
|
if all(n in self.executed for n in prepared_nodes):
|
|
self.executed.add(source_node)
|
|
self.executed_history.append(source_node)
|
|
|
|
def set_node_error(self, node_id: str, error: str):
|
|
"""Marks a node as errored"""
|
|
self.errors[node_id] = error
|
|
|
|
def is_complete(self) -> bool:
|
|
"""Returns true if the graph is complete"""
|
|
node_ids = set(self.graph.nx_graph_flat().nodes)
|
|
return self.has_error() or all((k in self.executed for k in node_ids))
|
|
|
|
def has_error(self) -> bool:
|
|
"""Returns true if the graph has any errors"""
|
|
return len(self.errors) > 0
|
|
|
|
def _create_execution_node(self, node_path: str, iteration_node_map: list[tuple[str, str]]) -> list[str]:
|
|
"""Prepares an iteration node and connects all edges, returning the new node id"""
|
|
|
|
node = self.graph.get_node(node_path)
|
|
|
|
self_iteration_count = -1
|
|
|
|
# If this is an iterator node, we must create a copy for each iteration
|
|
if isinstance(node, IterateInvocation):
|
|
# Get input collection edge (should error if there are no inputs)
|
|
input_collection_edge = next(iter(self.graph._get_input_edges(node_path, "collection")))
|
|
input_collection_prepared_node_id = next(
|
|
n[1] for n in iteration_node_map if n[0] == input_collection_edge.source.node_id
|
|
)
|
|
input_collection_prepared_node_output = self.results[input_collection_prepared_node_id]
|
|
input_collection = getattr(input_collection_prepared_node_output, input_collection_edge.source.field)
|
|
self_iteration_count = len(input_collection)
|
|
|
|
new_nodes: list[str] = []
|
|
if self_iteration_count == 0:
|
|
# TODO: should this raise a warning? It might just happen if an empty collection is input, and should be valid.
|
|
return new_nodes
|
|
|
|
# Get all input edges
|
|
input_edges = self.graph._get_input_edges(node_path)
|
|
|
|
# Create new edges for this iteration
|
|
# For collect nodes, this may contain multiple inputs to the same field
|
|
new_edges: list[Edge] = []
|
|
for edge in input_edges:
|
|
for input_node_id in (n[1] for n in iteration_node_map if n[0] == edge.source.node_id):
|
|
new_edge = Edge(
|
|
source=EdgeConnection(node_id=input_node_id, field=edge.source.field),
|
|
destination=EdgeConnection(node_id="", field=edge.destination.field),
|
|
)
|
|
new_edges.append(new_edge)
|
|
|
|
# Create a new node (or one for each iteration of this iterator)
|
|
for i in range(self_iteration_count) if self_iteration_count > 0 else [-1]:
|
|
# Create a new node
|
|
new_node = copy.deepcopy(node)
|
|
|
|
# Create the node id (use a random uuid)
|
|
new_node.id = uuid_string()
|
|
|
|
# Set the iteration index for iteration invocations
|
|
if isinstance(new_node, IterateInvocation):
|
|
new_node.index = i
|
|
|
|
# Add to execution graph
|
|
self.execution_graph.add_node(new_node)
|
|
self.prepared_source_mapping[new_node.id] = node_path
|
|
if node_path not in self.source_prepared_mapping:
|
|
self.source_prepared_mapping[node_path] = set()
|
|
self.source_prepared_mapping[node_path].add(new_node.id)
|
|
|
|
# Add new edges to execution graph
|
|
for edge in new_edges:
|
|
new_edge = Edge(
|
|
source=edge.source,
|
|
destination=EdgeConnection(node_id=new_node.id, field=edge.destination.field),
|
|
)
|
|
self.execution_graph.add_edge(new_edge)
|
|
|
|
new_nodes.append(new_node.id)
|
|
|
|
return new_nodes
|
|
|
|
def _iterator_graph(self) -> nx.DiGraph:
|
|
"""Gets a DiGraph with edges to collectors removed so an ancestor search produces all active iterators for any node"""
|
|
g = self.graph.nx_graph_flat()
|
|
collectors = (n for n in self.graph.nodes if isinstance(self.graph.get_node(n), CollectInvocation))
|
|
for c in collectors:
|
|
g.remove_edges_from(list(g.in_edges(c)))
|
|
return g
|
|
|
|
def _get_node_iterators(self, node_id: str) -> list[str]:
|
|
"""Gets iterators for a node"""
|
|
g = self._iterator_graph()
|
|
iterators = [n for n in nx.ancestors(g, node_id) if isinstance(self.graph.get_node(n), IterateInvocation)]
|
|
return iterators
|
|
|
|
def _prepare(self) -> Optional[str]:
|
|
# Get flattened source graph
|
|
g = self.graph.nx_graph_flat()
|
|
|
|
# Find next node that:
|
|
# - was not already prepared
|
|
# - is not an iterate node whose inputs have not been executed
|
|
# - does not have an unexecuted iterate ancestor
|
|
sorted_nodes = nx.topological_sort(g)
|
|
next_node_id = next(
|
|
(
|
|
n
|
|
for n in sorted_nodes
|
|
# exclude nodes that have already been prepared
|
|
if n not in self.source_prepared_mapping
|
|
# exclude iterate nodes whose inputs have not been executed
|
|
and not (
|
|
isinstance(self.graph.get_node(n), IterateInvocation) # `n` is an iterate node...
|
|
and not all((e[0] in self.executed for e in g.in_edges(n))) # ...that has unexecuted inputs
|
|
)
|
|
# exclude nodes who have unexecuted iterate ancestors
|
|
and not any(
|
|
(
|
|
isinstance(self.graph.get_node(a), IterateInvocation) # `a` is an iterate ancestor of `n`...
|
|
and a not in self.executed # ...that is not executed
|
|
for a in nx.ancestors(g, n) # for all ancestors `a` of node `n`
|
|
)
|
|
)
|
|
),
|
|
None,
|
|
)
|
|
|
|
if next_node_id is None:
|
|
return None
|
|
|
|
# Get all parents of the next node
|
|
next_node_parents = [e[0] for e in g.in_edges(next_node_id)]
|
|
|
|
# Create execution nodes
|
|
next_node = self.graph.get_node(next_node_id)
|
|
new_node_ids = []
|
|
if isinstance(next_node, CollectInvocation):
|
|
# Collapse all iterator input mappings and create a single execution node for the collect invocation
|
|
all_iteration_mappings = list(
|
|
itertools.chain(*(((s, p) for p in self.source_prepared_mapping[s]) for s in next_node_parents))
|
|
)
|
|
# all_iteration_mappings = list(set(itertools.chain(*prepared_parent_mappings)))
|
|
create_results = self._create_execution_node(next_node_id, all_iteration_mappings)
|
|
if create_results is not None:
|
|
new_node_ids.extend(create_results)
|
|
else: # Iterators or normal nodes
|
|
# Get all iterator combinations for this node
|
|
# Will produce a list of lists of prepared iterator nodes, from which results can be iterated
|
|
iterator_nodes = self._get_node_iterators(next_node_id)
|
|
iterator_nodes_prepared = [list(self.source_prepared_mapping[n]) for n in iterator_nodes]
|
|
iterator_node_prepared_combinations = list(itertools.product(*iterator_nodes_prepared))
|
|
|
|
# Select the correct prepared parents for each iteration
|
|
# For every iterator, the parent must either not be a child of that iterator, or must match the prepared iteration for that iterator
|
|
# TODO: Handle a node mapping to none
|
|
eg = self.execution_graph.nx_graph_flat()
|
|
prepared_parent_mappings = [[(n, self._get_iteration_node(n, g, eg, it)) for n in next_node_parents] for it in iterator_node_prepared_combinations] # type: ignore
|
|
|
|
# Create execution node for each iteration
|
|
for iteration_mappings in prepared_parent_mappings:
|
|
create_results = self._create_execution_node(next_node_id, iteration_mappings) # type: ignore
|
|
if create_results is not None:
|
|
new_node_ids.extend(create_results)
|
|
|
|
return next(iter(new_node_ids), None)
|
|
|
|
def _get_iteration_node(
|
|
self,
|
|
source_node_path: str,
|
|
graph: nx.DiGraph,
|
|
execution_graph: nx.DiGraph,
|
|
prepared_iterator_nodes: list[str],
|
|
) -> Optional[str]:
|
|
"""Gets the prepared version of the specified source node that matches every iteration specified"""
|
|
prepared_nodes = self.source_prepared_mapping[source_node_path]
|
|
if len(prepared_nodes) == 1:
|
|
return next(iter(prepared_nodes))
|
|
|
|
# Check if the requested node is an iterator
|
|
prepared_iterator = next((n for n in prepared_nodes if n in prepared_iterator_nodes), None)
|
|
if prepared_iterator is not None:
|
|
return prepared_iterator
|
|
|
|
# Filter to only iterator nodes that are a parent of the specified node, in tuple format (prepared, source)
|
|
iterator_source_node_mapping = [(n, self.prepared_source_mapping[n]) for n in prepared_iterator_nodes]
|
|
parent_iterators = [itn for itn in iterator_source_node_mapping if nx.has_path(graph, itn[1], source_node_path)]
|
|
|
|
return next(
|
|
(n for n in prepared_nodes if all(nx.has_path(execution_graph, pit[0], n) for pit in parent_iterators)),
|
|
None,
|
|
)
|
|
|
|
def _get_next_node(self) -> Optional[BaseInvocation]:
|
|
"""Gets the deepest node that is ready to be executed"""
|
|
g = self.execution_graph.nx_graph()
|
|
|
|
# Depth-first search with pre-order traversal is a depth-first topological sort
|
|
sorted_nodes = nx.dfs_preorder_nodes(g)
|
|
|
|
next_node = next(
|
|
(
|
|
n
|
|
for n in sorted_nodes
|
|
if n not in self.executed # the node must not already be executed...
|
|
and all((e[0] in self.executed for e in g.in_edges(n))) # ...and all its inputs must be executed
|
|
),
|
|
None,
|
|
)
|
|
|
|
if next_node is None:
|
|
return None
|
|
|
|
return self.execution_graph.nodes[next_node]
|
|
|
|
def _prepare_inputs(self, node: BaseInvocation):
|
|
input_edges = [e for e in self.execution_graph.edges if e.destination.node_id == node.id]
|
|
if isinstance(node, CollectInvocation):
|
|
output_collection = [
|
|
getattr(self.results[edge.source.node_id], edge.source.field)
|
|
for edge in input_edges
|
|
if edge.destination.field == "item"
|
|
]
|
|
setattr(node, "collection", output_collection)
|
|
else:
|
|
for edge in input_edges:
|
|
output_value = getattr(self.results[edge.source.node_id], edge.source.field)
|
|
setattr(node, edge.destination.field, output_value)
|
|
|
|
# TODO: Add API for modifying underlying graph that checks if the change will be valid given the current execution state
|
|
def _is_edge_valid(self, edge: Edge) -> bool:
|
|
try:
|
|
self.graph._validate_edge(edge)
|
|
except InvalidEdgeError:
|
|
return False
|
|
|
|
# Invalid if destination has already been prepared or executed
|
|
if edge.destination.node_id in self.source_prepared_mapping:
|
|
return False
|
|
|
|
# Otherwise, the edge is valid
|
|
return True
|
|
|
|
def _is_node_updatable(self, node_id: str) -> bool:
|
|
# The node is updatable as long as it hasn't been prepared or executed
|
|
return node_id not in self.source_prepared_mapping
|
|
|
|
def add_node(self, node: BaseInvocation) -> None:
|
|
self.graph.add_node(node)
|
|
|
|
def update_node(self, node_path: str, new_node: BaseInvocation) -> None:
|
|
if not self._is_node_updatable(node_path):
|
|
raise NodeAlreadyExecutedError(
|
|
f"Node {node_path} has already been prepared or executed and cannot be updated"
|
|
)
|
|
self.graph.update_node(node_path, new_node)
|
|
|
|
def delete_node(self, node_path: str) -> None:
|
|
if not self._is_node_updatable(node_path):
|
|
raise NodeAlreadyExecutedError(
|
|
f"Node {node_path} has already been prepared or executed and cannot be deleted"
|
|
)
|
|
self.graph.delete_node(node_path)
|
|
|
|
def add_edge(self, edge: Edge) -> None:
|
|
if not self._is_node_updatable(edge.destination.node_id):
|
|
raise NodeAlreadyExecutedError(
|
|
f"Destination node {edge.destination.node_id} has already been prepared or executed and cannot be linked to"
|
|
)
|
|
self.graph.add_edge(edge)
|
|
|
|
def delete_edge(self, edge: Edge) -> None:
|
|
if not self._is_node_updatable(edge.destination.node_id):
|
|
raise NodeAlreadyExecutedError(
|
|
f"Destination node {edge.destination.node_id} has already been prepared or executed and cannot have a source edge deleted"
|
|
)
|
|
self.graph.delete_edge(edge)
|
|
|
|
|
|
class ExposedNodeInput(BaseModel):
|
|
node_path: str = Field(description="The node path to the node with the input")
|
|
field: str = Field(description="The field name of the input")
|
|
alias: str = Field(description="The alias of the input")
|
|
|
|
|
|
class ExposedNodeOutput(BaseModel):
|
|
node_path: str = Field(description="The node path to the node with the output")
|
|
field: str = Field(description="The field name of the output")
|
|
alias: str = Field(description="The alias of the output")
|
|
|
|
|
|
class LibraryGraph(BaseModel):
|
|
id: str = Field(description="The unique identifier for this library graph", default_factory=uuid_string)
|
|
graph: Graph = Field(description="The graph")
|
|
name: str = Field(description="The name of the graph")
|
|
description: str = Field(description="The description of the graph")
|
|
exposed_inputs: list[ExposedNodeInput] = Field(description="The inputs exposed by this graph", default_factory=list)
|
|
exposed_outputs: list[ExposedNodeOutput] = Field(
|
|
description="The outputs exposed by this graph", default_factory=list
|
|
)
|
|
|
|
@field_validator("exposed_inputs", "exposed_outputs")
|
|
def validate_exposed_aliases(cls, v: list[Union[ExposedNodeInput, ExposedNodeOutput]]):
|
|
if len(v) != len({i.alias for i in v}):
|
|
raise ValueError("Duplicate exposed alias")
|
|
return v
|
|
|
|
@model_validator(mode="after")
|
|
def validate_exposed_nodes(cls, values):
|
|
graph = values.graph
|
|
|
|
# Validate exposed inputs
|
|
for exposed_input in values.exposed_inputs:
|
|
if not graph.has_node(exposed_input.node_path):
|
|
raise ValueError(f"Exposed input node {exposed_input.node_path} does not exist")
|
|
node = graph.get_node(exposed_input.node_path)
|
|
if get_input_field(node, exposed_input.field) is None:
|
|
raise ValueError(
|
|
f"Exposed input field {exposed_input.field} does not exist on node {exposed_input.node_path}"
|
|
)
|
|
|
|
# Validate exposed outputs
|
|
for exposed_output in values.exposed_outputs:
|
|
if not graph.has_node(exposed_output.node_path):
|
|
raise ValueError(f"Exposed output node {exposed_output.node_path} does not exist")
|
|
node = graph.get_node(exposed_output.node_path)
|
|
if get_output_field(node, exposed_output.field) is None:
|
|
raise ValueError(
|
|
f"Exposed output field {exposed_output.field} does not exist on node {exposed_output.node_path}"
|
|
)
|
|
|
|
return values
|
|
|
|
|
|
GraphInvocation.model_rebuild(force=True)
|
|
Graph.model_rebuild(force=True)
|
|
GraphExecutionState.model_rebuild(force=True)
|