Source code for langchain.tools.base
"""Base implementation for tools or skills."""
from __future__ import annotations
import asyncio
import warnings
from abc import abstractmethod
from functools import partial
from inspect import signature
from typing import Any, Awaitable, Callable, Dict, List, Optional, Tuple, Type, Union
from pydantic import (
BaseModel,
Extra,
Field,
create_model,
root_validator,
validate_arguments,
)
from pydantic.main import ModelMetaclass
from langchain.callbacks.base import BaseCallbackManager
from langchain.callbacks.manager import (
AsyncCallbackManager,
AsyncCallbackManagerForToolRun,
CallbackManager,
CallbackManagerForToolRun,
Callbacks,
)
from langchain.schema.runnable import Runnable, RunnableConfig
[docs]class SchemaAnnotationError(TypeError):
"""Raised when 'args_schema' is missing or has an incorrect type annotation."""
[docs]class ToolMetaclass(ModelMetaclass):
"""Metaclass for BaseTool to ensure the provided args_schema
doesn't silently ignored."""
def __new__(
cls: Type[ToolMetaclass], name: str, bases: Tuple[Type, ...], dct: dict
) -> ToolMetaclass:
"""Create the definition of the new tool class."""
schema_type: Optional[Type[BaseModel]] = dct.get("args_schema")
if schema_type is not None:
schema_annotations = dct.get("__annotations__", {})
args_schema_type = schema_annotations.get("args_schema", None)
if args_schema_type is None or args_schema_type == BaseModel:
# Throw errors for common mis-annotations.
# TODO: Use get_args / get_origin and fully
# specify valid annotations.
typehint_mandate = """
class ChildTool(BaseTool):
...
args_schema: Type[BaseModel] = SchemaClass
..."""
raise SchemaAnnotationError(
f"Tool definition for {name} must include valid type annotations"
f" for argument 'args_schema' to behave as expected.\n"
f"Expected annotation of 'Type[BaseModel]'"
f" but got '{args_schema_type}'.\n"
f"Expected class looks like:\n"
f"{typehint_mandate}"
)
# Pass through to Pydantic's metaclass
return super().__new__(cls, name, bases, dct)
def _create_subset_model(
name: str, model: BaseModel, field_names: list
) -> Type[BaseModel]:
"""Create a pydantic model with only a subset of model's fields."""
fields = {}
for field_name in field_names:
field = model.__fields__[field_name]
fields[field_name] = (field.outer_type_, field.field_info)
return create_model(name, **fields) # type: ignore
def _get_filtered_args(
inferred_model: Type[BaseModel],
func: Callable,
) -> dict:
"""Get the arguments from a function's signature."""
schema = inferred_model.schema()["properties"]
valid_keys = signature(func).parameters
return {k: schema[k] for k in valid_keys if k not in ("run_manager", "callbacks")}
class _SchemaConfig:
"""Configuration for the pydantic model."""
extra = Extra.forbid
arbitrary_types_allowed = True
[docs]def create_schema_from_function(
model_name: str,
func: Callable,
) -> Type[BaseModel]:
"""Create a pydantic schema from a function's signature.
Args:
model_name: Name to assign to the generated pydandic schema
func: Function to generate the schema from
Returns:
A pydantic model with the same arguments as the function
"""
# https://docs.pydantic.dev/latest/usage/validation_decorator/
validated = validate_arguments(func, config=_SchemaConfig) # type: ignore
inferred_model = validated.model # type: ignore
if "run_manager" in inferred_model.__fields__:
del inferred_model.__fields__["run_manager"]
if "callbacks" in inferred_model.__fields__:
del inferred_model.__fields__["callbacks"]
# Pydantic adds placeholder virtual fields we need to strip
valid_properties = _get_filtered_args(inferred_model, func)
return _create_subset_model(
f"{model_name}Schema", inferred_model, list(valid_properties)
)
[docs]class ToolException(Exception):
"""An optional exception that tool throws when execution error occurs.
When this exception is thrown, the agent will not stop working,
but will handle the exception according to the handle_tool_error
variable of the tool, and the processing result will be returned
to the agent as observation, and printed in red on the console.
"""
pass
[docs]class BaseTool(BaseModel, Runnable[Union[str, Dict], Any], metaclass=ToolMetaclass):
"""Interface LangChain tools must implement."""
name: str
"""The unique name of the tool that clearly communicates its purpose."""
description: str
"""Used to tell the model how/when/why to use the tool.
You can provide few-shot examples as a part of the description.
"""
args_schema: Optional[Type[BaseModel]] = None
"""Pydantic model class to validate and parse the tool's input arguments."""
return_direct: bool = False
"""Whether to return the tool's output directly. Setting this to True means
that after the tool is called, the AgentExecutor will stop looping.
"""
verbose: bool = False
"""Whether to log the tool's progress."""
callbacks: Callbacks = Field(default=None, exclude=True)
"""Callbacks to be called during tool execution."""
callback_manager: Optional[BaseCallbackManager] = Field(default=None, exclude=True)
"""Deprecated. Please use callbacks instead."""
tags: Optional[List[str]] = None
"""Optional list of tags associated with the tool. Defaults to None
These tags will be associated with each call to this tool,
and passed as arguments to the handlers defined in `callbacks`.
You can use these to eg identify a specific instance of a tool with its use case.
"""
metadata: Optional[Dict[str, Any]] = None
"""Optional metadata associated with the tool. Defaults to None
This metadata will be associated with each call to this tool,
and passed as arguments to the handlers defined in `callbacks`.
You can use these to eg identify a specific instance of a tool with its use case.
"""
handle_tool_error: Optional[
Union[bool, str, Callable[[ToolException], str]]
] = False
"""Handle the content of the ToolException thrown."""
[docs] class Config:
"""Configuration for this pydantic object."""
extra = Extra.forbid
arbitrary_types_allowed = True
@property
def is_single_input(self) -> bool:
"""Whether the tool only accepts a single input."""
keys = {k for k in self.args if k != "kwargs"}
return len(keys) == 1
@property
def args(self) -> dict:
if self.args_schema is not None:
return self.args_schema.schema()["properties"]
else:
schema = create_schema_from_function(self.name, self._run)
return schema.schema()["properties"]
# --- Runnable ---
[docs] def invoke(
self,
input: Union[str, Dict],
config: Optional[RunnableConfig] = None,
**kwargs: Any,
) -> Any:
config = config or {}
return self.run(input, **config, **kwargs)
[docs] async def ainvoke(
self,
input: Union[str, Dict],
config: Optional[RunnableConfig] = None,
**kwargs: Any,
) -> Any:
if type(self)._arun == BaseTool._arun:
# If the tool does not implement async, fall back to default implementation
return super().ainvoke(input, config, **kwargs)
config = config or {}
return await self.arun(input, **config, **kwargs)
# --- Tool ---
def _parse_input(
self,
tool_input: Union[str, Dict],
) -> Union[str, Dict[str, Any]]:
"""Convert tool input to pydantic model."""
input_args = self.args_schema
if isinstance(tool_input, str):
if input_args is not None:
key_ = next(iter(input_args.__fields__.keys()))
input_args.validate({key_: tool_input})
return tool_input
else:
if input_args is not None:
result = input_args.parse_obj(tool_input)
return {k: v for k, v in result.dict().items() if k in tool_input}
return tool_input
[docs] @root_validator()
def raise_deprecation(cls, values: Dict) -> Dict:
"""Raise deprecation warning if callback_manager is used."""
if values.get("callback_manager") is not None:
warnings.warn(
"callback_manager is deprecated. Please use callbacks instead.",
DeprecationWarning,
)
values["callbacks"] = values.pop("callback_manager", None)
return values
@abstractmethod
def _run(
self,
*args: Any,
**kwargs: Any,
) -> Any:
"""Use the tool.
Add run_manager: Optional[CallbackManagerForToolRun] = None
to child implementations to enable tracing,
"""
async def _arun(
self,
*args: Any,
**kwargs: Any,
) -> Any:
"""Use the tool asynchronously.
Add run_manager: Optional[AsyncCallbackManagerForToolRun] = None
to child implementations to enable tracing,
"""
raise NotImplementedError()
def _to_args_and_kwargs(self, tool_input: Union[str, Dict]) -> Tuple[Tuple, Dict]:
# For backwards compatibility, if run_input is a string,
# pass as a positional argument.
if isinstance(tool_input, str):
return (tool_input,), {}
else:
return (), tool_input
[docs] def run(
self,
tool_input: Union[str, Dict],
verbose: Optional[bool] = None,
start_color: Optional[str] = "green",
color: Optional[str] = "green",
callbacks: Callbacks = None,
*,
tags: Optional[List[str]] = None,
metadata: Optional[Dict[str, Any]] = None,
**kwargs: Any,
) -> Any:
"""Run the tool."""
parsed_input = self._parse_input(tool_input)
if not self.verbose and verbose is not None:
verbose_ = verbose
else:
verbose_ = self.verbose
callback_manager = CallbackManager.configure(
callbacks,
self.callbacks,
verbose_,
tags,
self.tags,
metadata,
self.metadata,
)
# TODO: maybe also pass through run_manager is _run supports kwargs
new_arg_supported = signature(self._run).parameters.get("run_manager")
run_manager = callback_manager.on_tool_start(
{"name": self.name, "description": self.description},
tool_input if isinstance(tool_input, str) else str(tool_input),
color=start_color,
**kwargs,
)
try:
tool_args, tool_kwargs = self._to_args_and_kwargs(parsed_input)
observation = (
self._run(*tool_args, run_manager=run_manager, **tool_kwargs)
if new_arg_supported
else self._run(*tool_args, **tool_kwargs)
)
except ToolException as e:
if not self.handle_tool_error:
run_manager.on_tool_error(e)
raise e
elif isinstance(self.handle_tool_error, bool):
if e.args:
observation = e.args[0]
else:
observation = "Tool execution error"
elif isinstance(self.handle_tool_error, str):
observation = self.handle_tool_error
elif callable(self.handle_tool_error):
observation = self.handle_tool_error(e)
else:
raise ValueError(
f"Got unexpected type of `handle_tool_error`. Expected bool, str "
f"or callable. Received: {self.handle_tool_error}"
)
run_manager.on_tool_end(
str(observation), color="red", name=self.name, **kwargs
)
return observation
except (Exception, KeyboardInterrupt) as e:
run_manager.on_tool_error(e)
raise e
else:
run_manager.on_tool_end(
str(observation), color=color, name=self.name, **kwargs
)
return observation
[docs] async def arun(
self,
tool_input: Union[str, Dict],
verbose: Optional[bool] = None,
start_color: Optional[str] = "green",
color: Optional[str] = "green",
callbacks: Callbacks = None,
*,
tags: Optional[List[str]] = None,
metadata: Optional[Dict[str, Any]] = None,
**kwargs: Any,
) -> Any:
"""Run the tool asynchronously."""
parsed_input = self._parse_input(tool_input)
if not self.verbose and verbose is not None:
verbose_ = verbose
else:
verbose_ = self.verbose
callback_manager = AsyncCallbackManager.configure(
callbacks,
self.callbacks,
verbose_,
tags,
self.tags,
metadata,
self.metadata,
)
new_arg_supported = signature(self._arun).parameters.get("run_manager")
run_manager = await callback_manager.on_tool_start(
{"name": self.name, "description": self.description},
tool_input if isinstance(tool_input, str) else str(tool_input),
color=start_color,
**kwargs,
)
try:
# We then call the tool on the tool input to get an observation
tool_args, tool_kwargs = self._to_args_and_kwargs(parsed_input)
observation = (
await self._arun(*tool_args, run_manager=run_manager, **tool_kwargs)
if new_arg_supported
else await self._arun(*tool_args, **tool_kwargs)
)
except ToolException as e:
if not self.handle_tool_error:
await run_manager.on_tool_error(e)
raise e
elif isinstance(self.handle_tool_error, bool):
if e.args:
observation = e.args[0]
else:
observation = "Tool execution error"
elif isinstance(self.handle_tool_error, str):
observation = self.handle_tool_error
elif callable(self.handle_tool_error):
observation = self.handle_tool_error(e)
else:
raise ValueError(
f"Got unexpected type of `handle_tool_error`. Expected bool, str "
f"or callable. Received: {self.handle_tool_error}"
)
await run_manager.on_tool_end(
str(observation), color="red", name=self.name, **kwargs
)
return observation
except (Exception, KeyboardInterrupt) as e:
await run_manager.on_tool_error(e)
raise e
else:
await run_manager.on_tool_end(
str(observation), color=color, name=self.name, **kwargs
)
return observation
[docs] def __call__(self, tool_input: str, callbacks: Callbacks = None) -> str:
"""Make tool callable."""
return self.run(tool_input, callbacks=callbacks)
[docs]class Tool(BaseTool):
"""Tool that takes in function or coroutine directly."""
description: str = ""
func: Callable[..., str]
"""The function to run when the tool is called."""
coroutine: Optional[Callable[..., Awaitable[str]]] = None
"""The asynchronous version of the function."""
# --- Runnable ---
[docs] async def ainvoke(
self,
input: Union[str, Dict],
config: Optional[RunnableConfig] = None,
**kwargs: Any,
) -> Any:
if not self.coroutine:
# If the tool does not implement async, fall back to default implementation
return await asyncio.get_running_loop().run_in_executor(
None, partial(self.invoke, input, config, **kwargs)
)
return super().ainvoke(input, config, **kwargs)
# --- Tool ---
@property
def args(self) -> dict:
"""The tool's input arguments."""
if self.args_schema is not None:
return self.args_schema.schema()["properties"]
# For backwards compatibility, if the function signature is ambiguous,
# assume it takes a single string input.
return {"tool_input": {"type": "string"}}
def _to_args_and_kwargs(self, tool_input: Union[str, Dict]) -> Tuple[Tuple, Dict]:
"""Convert tool input to pydantic model."""
args, kwargs = super()._to_args_and_kwargs(tool_input)
# For backwards compatibility. The tool must be run with a single input
all_args = list(args) + list(kwargs.values())
if len(all_args) != 1:
raise ToolException(
f"Too many arguments to single-input tool {self.name}."
f" Args: {all_args}"
)
return tuple(all_args), {}
def _run(
self,
*args: Any,
run_manager: Optional[CallbackManagerForToolRun] = None,
**kwargs: Any,
) -> Any:
"""Use the tool."""
new_argument_supported = signature(self.func).parameters.get("callbacks")
return (
self.func(
*args,
callbacks=run_manager.get_child() if run_manager else None,
**kwargs,
)
if new_argument_supported
else self.func(*args, **kwargs)
)
async def _arun(
self,
*args: Any,
run_manager: Optional[AsyncCallbackManagerForToolRun] = None,
**kwargs: Any,
) -> Any:
"""Use the tool asynchronously."""
if self.coroutine:
new_argument_supported = signature(self.coroutine).parameters.get(
"callbacks"
)
return (
await self.coroutine(
*args,
callbacks=run_manager.get_child() if run_manager else None,
**kwargs,
)
if new_argument_supported
else await self.coroutine(*args, **kwargs)
)
raise NotImplementedError("Tool does not support async")
# TODO: this is for backwards compatibility, remove in future
def __init__(
self, name: str, func: Callable, description: str, **kwargs: Any
) -> None:
"""Initialize tool."""
super(Tool, self).__init__(
name=name, func=func, description=description, **kwargs
)
[docs] @classmethod
def from_function(
cls,
func: Callable,
name: str, # We keep these required to support backwards compatibility
description: str,
return_direct: bool = False,
args_schema: Optional[Type[BaseModel]] = None,
**kwargs: Any,
) -> Tool:
"""Initialize tool from a function."""
return cls(
name=name,
func=func,
description=description,
return_direct=return_direct,
args_schema=args_schema,
**kwargs,
)
[docs]class StructuredTool(BaseTool):
"""Tool that can operate on any number of inputs."""
description: str = ""
args_schema: Type[BaseModel] = Field(..., description="The tool schema.")
"""The input arguments' schema."""
func: Callable[..., Any]
"""The function to run when the tool is called."""
coroutine: Optional[Callable[..., Awaitable[Any]]] = None
"""The asynchronous version of the function."""
# --- Runnable ---
[docs] async def ainvoke(
self,
input: Union[str, Dict],
config: Optional[RunnableConfig] = None,
**kwargs: Any,
) -> Any:
if not self.coroutine:
# If the tool does not implement async, fall back to default implementation
return await asyncio.get_running_loop().run_in_executor(
None, partial(self.invoke, input, config, **kwargs)
)
return super().ainvoke(input, config, **kwargs)
# --- Tool ---
@property
def args(self) -> dict:
"""The tool's input arguments."""
return self.args_schema.schema()["properties"]
def _run(
self,
*args: Any,
run_manager: Optional[CallbackManagerForToolRun] = None,
**kwargs: Any,
) -> Any:
"""Use the tool."""
new_argument_supported = signature(self.func).parameters.get("callbacks")
return (
self.func(
*args,
callbacks=run_manager.get_child() if run_manager else None,
**kwargs,
)
if new_argument_supported
else self.func(*args, **kwargs)
)
async def _arun(
self,
*args: Any,
run_manager: Optional[AsyncCallbackManagerForToolRun] = None,
**kwargs: Any,
) -> str:
"""Use the tool asynchronously."""
if self.coroutine:
new_argument_supported = signature(self.coroutine).parameters.get(
"callbacks"
)
return (
await self.coroutine(
*args,
callbacks=run_manager.get_child() if run_manager else None,
**kwargs,
)
if new_argument_supported
else await self.coroutine(*args, **kwargs)
)
raise NotImplementedError("Tool does not support async")
[docs] @classmethod
def from_function(
cls,
func: Callable,
name: Optional[str] = None,
description: Optional[str] = None,
return_direct: bool = False,
args_schema: Optional[Type[BaseModel]] = None,
infer_schema: bool = True,
**kwargs: Any,
) -> StructuredTool:
"""Create tool from a given function.
A classmethod that helps to create a tool from a function.
Args:
func: The function from which to create a tool
name: The name of the tool. Defaults to the function name
description: The description of the tool. Defaults to the function docstring
return_direct: Whether to return the result directly or as a callback
args_schema: The schema of the tool's input arguments
infer_schema: Whether to infer the schema from the function's signature
**kwargs: Additional arguments to pass to the tool
Returns:
The tool
Examples:
... code-block:: python
def add(a: int, b: int) -> int:
\"\"\"Add two numbers\"\"\"
return a + b
tool = StructuredTool.from_function(add)
tool.run(1, 2) # 3
"""
name = name or func.__name__
description = description or func.__doc__
assert (
description is not None
), "Function must have a docstring if description not provided."
# Description example:
# search_api(query: str) - Searches the API for the query.
description = f"{name}{signature(func)} - {description.strip()}"
_args_schema = args_schema
if _args_schema is None and infer_schema:
_args_schema = create_schema_from_function(f"{name}Schema", func)
return cls(
name=name,
func=func,
args_schema=_args_schema,
description=description,
return_direct=return_direct,
**kwargs,
)
[docs]def tool(
*args: Union[str, Callable],
return_direct: bool = False,
args_schema: Optional[Type[BaseModel]] = None,
infer_schema: bool = True,
) -> Callable:
"""Make tools out of functions, can be used with or without arguments.
Args:
*args: The arguments to the tool.
return_direct: Whether to return directly from the tool rather
than continuing the agent loop.
args_schema: optional argument schema for user to specify
infer_schema: Whether to infer the schema of the arguments from
the function's signature. This also makes the resultant tool
accept a dictionary input to its `run()` function.
Requires:
- Function must be of type (str) -> str
- Function must have a docstring
Examples:
.. code-block:: python
@tool
def search_api(query: str) -> str:
# Searches the API for the query.
return
@tool("search", return_direct=True)
def search_api(query: str) -> str:
# Searches the API for the query.
return
"""
def _make_with_name(tool_name: str) -> Callable:
def _make_tool(func: Callable) -> BaseTool:
if infer_schema or args_schema is not None:
return StructuredTool.from_function(
func,
name=tool_name,
return_direct=return_direct,
args_schema=args_schema,
infer_schema=infer_schema,
)
# If someone doesn't want a schema applied, we must treat it as
# a simple string->string function
assert func.__doc__ is not None, "Function must have a docstring"
return Tool(
name=tool_name,
func=func,
description=f"{tool_name} tool",
return_direct=return_direct,
)
return _make_tool
if len(args) == 1 and isinstance(args[0], str):
# if the argument is a string, then we use the string as the tool name
# Example usage: @tool("search", return_direct=True)
return _make_with_name(args[0])
elif len(args) == 1 and callable(args[0]):
# if the argument is a function, then we use the function name as the tool name
# Example usage: @tool
return _make_with_name(args[0].__name__)(args[0])
elif len(args) == 0:
# if there are no arguments, then we use the function name as the tool name
# Example usage: @tool(return_direct=True)
def _partial(func: Callable[[str], str]) -> BaseTool:
return _make_with_name(func.__name__)(func)
return _partial
else:
raise ValueError("Too many arguments for tool decorator")