How to do tool/function calling
We use the term tool calling interchangeably with function calling. Although function calling is sometimes meant to refer to invocations of a single function, we treat all models as though they can return multiple tool or function calls in each message.
Tool calling allows a model to respond to a given prompt by generating output that matches a user-defined schema. While the name implies that the model is performing some action, this is actually not the case! The model is coming up with the arguments to a tool, and actually running the tool (or not) is up to the user - for example, if you want to extract output matching some schema from unstructured text, you could give the model an "extraction" tool that takes parameters matching the desired schema, then treat the generated output as your final result.
A tool call includes a name, arguments dict, and an optional identifier. The
arguments dict is structured {argument_name: argument_value}
.
Many LLM providers, including Anthropic, Cohere, Google, Mistral, OpenAI, and others, support variants of a tool calling feature. These features typically allow requests to the LLM to include available tools and their schemas, and for responses to include calls to these tools. For instance, given a search engine tool, an LLM might handle a query by first issuing a call to the search engine. The system calling the LLM can receive the tool call, execute it, and return the output to the LLM to inform its response. LangChain includes a suite of built-in tools and supports several methods for defining your own custom tools. Tool-calling is extremely useful for building tool-using chains and agents, and for getting structured outputs from models more generally.
Providers adopt different conventions for formatting tool schemas and tool calls. For instance, Anthropic returns tool calls as parsed structures within a larger content block:
[
{
"text": "<thinking>\nI should use a tool.\n</thinking>",
"type": "text"
},
{
"id": "id_value",
"input": {"arg_name": "arg_value"},
"name": "tool_name",
"type": "tool_use"
}
]
whereas OpenAI separates tool calls into a distinct parameter, with arguments as JSON strings:
{
"tool_calls": [
{
"id": "id_value",
"function": {
"arguments": '{"arg_name": "arg_value"}',
"name": "tool_name"
},
"type": "function"
}
]
}
LangChain implements standard interfaces for defining tools, passing them to LLMs, and representing tool calls.
Passing tools to LLMsβ
Chat models supporting tool calling features implement a .bind_tools
method, which
receives a list of LangChain tool objects
and binds them to the chat model in its expected format. Subsequent invocations of the
chat model will include tool schemas in its calls to the LLM.
For example, we can define the schema for custom tools using the @tool
decorator
on Python functions:
from langchain_core.tools import tool
@tool
def add(a: int, b: int) -> int:
"""Adds a and b."""
return a + b
@tool
def multiply(a: int, b: int) -> int:
"""Multiplies a and b."""
return a * b
tools = [add, multiply]
Or below, we define the schema using Pydantic:
from langchain_core.pydantic_v1 import BaseModel, Field
# Note that the docstrings here are crucial, as they will be passed along
# to the model along with the class name.
class Add(BaseModel):
"""Add two integers together."""
a: int = Field(..., description="First integer")
b: int = Field(..., description="Second integer")
class Multiply(BaseModel):
"""Multiply two integers together."""
a: int = Field(..., description="First integer")
b: int = Field(..., description="Second integer")
tools = [Add, Multiply]
We can bind them to chat models as follows:
- OpenAI
- Anthropic
- Azure
- Cohere
- FireworksAI
- MistralAI
- TogetherAI
pip install -qU langchain-openai
import getpass
import os
os.environ["OPENAI_API_KEY"] = getpass.getpass()
from langchain_openai import ChatOpenAI
llm = ChatOpenAI(model="gpt-3.5-turbo-0125")
pip install -qU langchain-anthropic
import getpass
import os
os.environ["ANTHROPIC_API_KEY"] = getpass.getpass()
from langchain_anthropic import ChatAnthropic
llm = ChatAnthropic(model="claude-3-sonnet-20240229")
pip install -qU langchain-openai
import getpass
import os
os.environ["AZURE_OPENAI_API_KEY"] = getpass.getpass()
from langchain_openai import AzureChatOpenAI
llm = AzureChatOpenAI(
azure_endpoint=os.environ["AZURE_OPENAI_ENDPOINT"],
azure_deployment=os.environ["AZURE_OPENAI_DEPLOYMENT_NAME"],
openai_api_version=os.environ["AZURE_OPENAI_API_VERSION"],
)
pip install -qU langchain-google-vertexai
import getpass
import os
os.environ["GOOGLE_API_KEY"] = getpass.getpass()
from langchain_google_vertexai import ChatVertexAI
llm = ChatVertexAI(model="gemini-pro")
pip install -qU langchain-cohere
import getpass
import os
os.environ["COHERE_API_KEY"] = getpass.getpass()
from langchain_cohere import ChatCohere
llm = ChatCohere(model="command-r")
pip install -qU langchain-fireworks
import getpass
import os
os.environ["FIREWORKS_API_KEY"] = getpass.getpass()
from langchain_fireworks import ChatFireworks
llm = ChatFireworks(model="accounts/fireworks/models/firefunction-v1", temperature=0)
pip install -qU langchain-mistralai
import getpass
import os
os.environ["MISTRAL_API_KEY"] = getpass.getpass()
from langchain_mistralai import ChatMistralAI
llm = ChatMistralAI(model="mistral-large-latest")
pip install -qU langchain-openai
import getpass
import os
os.environ["TOGETHER_API_KEY"] = getpass.getpass()
from langchain_openai import ChatOpenAI
llm = ChatOpenAI(
base_url="https://api.together.xyz/v1",
api_key=os.environ["TOGETHER_API_KEY"],
model="mistralai/Mixtral-8x7B-Instruct-v0.1",
)
We can use the bind_tools()
method to handle converting
Multiply
to a "tool" and binding it to the model (i.e.,
passing it in each time the model is invoked).
llm_with_tools = llm.bind_tools(tools)
Tool callsβ
If tool calls are included in a LLM response, they are attached to the corresponding
message
or message chunk
as a list of tool call
objects in the .tool_calls
attribute. A ToolCall
is a typed dict that includes a
tool name, dict of argument values, and (optionally) an identifier. Messages with no
tool calls default to an empty list for this attribute.
Example:
query = "What is 3 * 12? Also, what is 11 + 49?"
llm_with_tools.invoke(query).tool_calls
[{'name': 'Multiply',
'args': {'a': 3, 'b': 12},
'id': 'call_1Tdp5wUXbYQzpkBoagGXqUTo'},
{'name': 'Add',
'args': {'a': 11, 'b': 49},
'id': 'call_k9v09vYioS3X0Qg35zESuUKI'}]
The .tool_calls
attribute should contain valid tool calls. Note that on occasion,
model providers may output malformed tool calls (e.g., arguments that are not
valid JSON). When parsing fails in these cases, instances
of InvalidToolCall
are populated in the .invalid_tool_calls
attribute. An InvalidToolCall
can have
a name, string arguments, identifier, and error message.
If desired, output parsers can further process the output. For example, we can convert back to the original Pydantic class:
from langchain_core.output_parsers.openai_tools import PydanticToolsParser
chain = llm_with_tools | PydanticToolsParser(tools=[Multiply, Add])
chain.invoke(query)
[Multiply(a=3, b=12), Add(a=11, b=49)]
Streamingβ
When tools are called in a streaming context,
message chunks
will be populated with tool call chunk
objects in a list via the .tool_call_chunks
attribute. A ToolCallChunk
includes
optional string fields for the tool name
, args
, and id
, and includes an optional
integer field index
that can be used to join chunks together. Fields are optional
because portions of a tool call may be streamed across different chunks (e.g., a chunk
that includes a substring of the arguments may have null values for the tool name and id).
Because message chunks inherit from their parent message class, an
AIMessageChunk
with tool call chunks will also include .tool_calls
and .invalid_tool_calls
fields.
These fields are parsed best-effort from the message's tool call chunks.
Note that not all providers currently support streaming for tool calls.
Example:
async for chunk in llm_with_tools.astream(query):
print(chunk.tool_call_chunks)
[]
[{'name': 'Multiply', 'args': '', 'id': 'call_d39MsxKM5cmeGJOoYKdGBgzc', 'index': 0}]
[{'name': None, 'args': '{"a"', 'id': None, 'index': 0}]
[{'name': None, 'args': ': 3, ', 'id': None, 'index': 0}]
[{'name': None, 'args': '"b": 1', 'id': None, 'index': 0}]
[{'name': None, 'args': '2}', 'id': None, 'index': 0}]
[{'name': 'Add', 'args': '', 'id': 'call_QJpdxD9AehKbdXzMHxgDMMhs', 'index': 1}]
[{'name': None, 'args': '{"a"', 'id': None, 'index': 1}]
[{'name': None, 'args': ': 11,', 'id': None, 'index': 1}]
[{'name': None, 'args': ' "b": ', 'id': None, 'index': 1}]
[{'name': None, 'args': '49}', 'id': None, 'index': 1}]
[]
Note that adding message chunks will merge their corresponding tool call chunks. This is the principle by which LangChain's various tool output parsers support streaming.
For example, below we accumulate tool call chunks:
first = True
async for chunk in llm_with_tools.astream(query):
if first:
gathered = chunk
first = False
else:
gathered = gathered + chunk
print(gathered.tool_call_chunks)
[]
[{'name': 'Multiply', 'args': '', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}]
[{'name': 'Multiply', 'args': '{"a"', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}]
[{'name': 'Multiply', 'args': '{"a": 3, ', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}]
[{'name': 'Multiply', 'args': '{"a": 3, "b": 1', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}]
[{'name': 'Multiply', 'args': '{"a": 3, "b": 12}', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}]
[{'name': 'Multiply', 'args': '{"a": 3, "b": 12}', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}, {'name': 'Add', 'args': '', 'id': 'call_tYHYdEV2YBvzDcSCiFCExNvw', 'index': 1}]
[{'name': 'Multiply', 'args': '{"a": 3, "b": 12}', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}, {'name': 'Add', 'args': '{"a"', 'id': 'call_tYHYdEV2YBvzDcSCiFCExNvw', 'index': 1}]
[{'name': 'Multiply', 'args': '{"a": 3, "b": 12}', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}, {'name': 'Add', 'args': '{"a": 11,', 'id': 'call_tYHYdEV2YBvzDcSCiFCExNvw', 'index': 1}]
[{'name': 'Multiply', 'args': '{"a": 3, "b": 12}', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}, {'name': 'Add', 'args': '{"a": 11, "b": ', 'id': 'call_tYHYdEV2YBvzDcSCiFCExNvw', 'index': 1}]
[{'name': 'Multiply', 'args': '{"a": 3, "b": 12}', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}, {'name': 'Add', 'args': '{"a": 11, "b": 49}', 'id': 'call_tYHYdEV2YBvzDcSCiFCExNvw', 'index': 1}]
[{'name': 'Multiply', 'args': '{"a": 3, "b": 12}', 'id': 'call_erKtz8z3e681cmxYKbRof0NS', 'index': 0}, {'name': 'Add', 'args': '{"a": 11, "b": 49}', 'id': 'call_tYHYdEV2YBvzDcSCiFCExNvw', 'index': 1}]
print(type(gathered.tool_call_chunks[0]["args"]))
<class 'str'>
And below we accumulate tool calls to demonstrate partial parsing:
first = True
async for chunk in llm_with_tools.astream(query):
if first:
gathered = chunk
first = False
else:
gathered = gathered + chunk
print(gathered.tool_calls)
[]
[]
[{'name': 'Multiply', 'args': {}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}]
[{'name': 'Multiply', 'args': {'a': 3}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}]
[{'name': 'Multiply', 'args': {'a': 3, 'b': 1}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}]
[{'name': 'Multiply', 'args': {'a': 3, 'b': 12}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}]
[{'name': 'Multiply', 'args': {'a': 3, 'b': 12}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}]
[{'name': 'Multiply', 'args': {'a': 3, 'b': 12}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}, {'name': 'Add', 'args': {}, 'id': 'call_UjSHJKROSAw2BDc8cp9cSv4i'}]
[{'name': 'Multiply', 'args': {'a': 3, 'b': 12}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}, {'name': 'Add', 'args': {'a': 11}, 'id': 'call_UjSHJKROSAw2BDc8cp9cSv4i'}]
[{'name': 'Multiply', 'args': {'a': 3, 'b': 12}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}, {'name': 'Add', 'args': {'a': 11}, 'id': 'call_UjSHJKROSAw2BDc8cp9cSv4i'}]
[{'name': 'Multiply', 'args': {'a': 3, 'b': 12}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}, {'name': 'Add', 'args': {'a': 11, 'b': 49}, 'id': 'call_UjSHJKROSAw2BDc8cp9cSv4i'}]
[{'name': 'Multiply', 'args': {'a': 3, 'b': 12}, 'id': 'call_BXqUtt6jYCwR1DguqpS2ehP0'}, {'name': 'Add', 'args': {'a': 11, 'b': 49}, 'id': 'call_UjSHJKROSAw2BDc8cp9cSv4i'}]
print(type(gathered.tool_calls[0]["args"]))
<class 'dict'>
Passing tool outputs to modelβ
If we're using the model-generated tool invocations to actually call tools and want to pass the tool results back to the model, we can do so using ToolMessage
s.
from langchain_core.messages import HumanMessage, ToolMessage
messages = [HumanMessage(query)]
ai_msg = llm_with_tools.invoke(messages)
messages.append(ai_msg)
for tool_call in ai_msg.tool_calls:
selected_tool = {"add": add, "multiply": multiply}[tool_call["name"].lower()]
tool_output = selected_tool.invoke(tool_call["args"])
messages.append(ToolMessage(tool_output, tool_call_id=tool_call["id"]))
messages
[HumanMessage(content='What is 3 * 12? Also, what is 11 + 49?'),
AIMessage(content='', additional_kwargs={'tool_calls': [{'id': 'call_K5DsWEmgt6D08EI9AFu9NaL1', 'function': {'arguments': '{"a": 3, "b": 12}', 'name': 'Multiply'}, 'type': 'function'}, {'id': 'call_qywVrsplg0ZMv7LHYYMjyG81', 'function': {'arguments': '{"a": 11, "b": 49}', 'name': 'Add'}, 'type': 'function'}]}, response_metadata={'token_usage': {'completion_tokens': 50, 'prompt_tokens': 105, 'total_tokens': 155}, 'model_name': 'gpt-3.5-turbo', 'system_fingerprint': 'fp_b28b39ffa8', 'finish_reason': 'tool_calls', 'logprobs': None}, id='run-1a0b8cdd-9221-4d94-b2ed-5701f67ce9fe-0', tool_calls=[{'name': 'Multiply', 'args': {'a': 3, 'b': 12}, 'id': 'call_K5DsWEmgt6D08EI9AFu9NaL1'}, {'name': 'Add', 'args': {'a': 11, 'b': 49}, 'id': 'call_qywVrsplg0ZMv7LHYYMjyG81'}]),
ToolMessage(content='36', tool_call_id='call_K5DsWEmgt6D08EI9AFu9NaL1'),
ToolMessage(content='60', tool_call_id='call_qywVrsplg0ZMv7LHYYMjyG81')]
llm_with_tools.invoke(messages)
AIMessage(content='3 * 12 is 36 and 11 + 49 is 60.', response_metadata={'token_usage': {'completion_tokens': 18, 'prompt_tokens': 171, 'total_tokens': 189}, 'model_name': 'gpt-3.5-turbo', 'system_fingerprint': 'fp_b28b39ffa8', 'finish_reason': 'stop', 'logprobs': None}, id='run-a6c8093c-b16a-4c92-8308-7c9ac998118c-0')
Few-shot promptingβ
For more complex tool use it's very useful to add few-shot examples to the prompt. We can do this by adding AIMessage
s with ToolCall
s and corresponding ToolMessage
s to our prompt.
For example, even with some special instructions our model can get tripped up by order of operations:
llm_with_tools.invoke(
"Whats 119 times 8 minus 20. Don't do any math yourself, only use tools for math. Respect order of operations"
).tool_calls
[{'name': 'Multiply',
'args': {'a': 119, 'b': 8},
'id': 'call_Dl3FXRVkQCFW4sUNYOe4rFr7'},
{'name': 'Add',
'args': {'a': 952, 'b': -20},
'id': 'call_n03l4hmka7VZTCiP387Wud2C'}]
The model shouldn't be trying to add anything yet, since it technically can't know the results of 119 * 8 yet.
By adding a prompt with some examples we can correct this behavior:
from langchain_core.messages import AIMessage
from langchain_core.prompts import ChatPromptTemplate
from langchain_core.runnables import RunnablePassthrough
examples = [
HumanMessage(
"What's the product of 317253 and 128472 plus four", name="example_user"
),
AIMessage(
"",
name="example_assistant",
tool_calls=[
{"name": "Multiply", "args": {"x": 317253, "y": 128472}, "id": "1"}
],
),
ToolMessage("16505054784", tool_call_id="1"),
AIMessage(
"",
name="example_assistant",
tool_calls=[{"name": "Add", "args": {"x": 16505054784, "y": 4}, "id": "2"}],
),
ToolMessage("16505054788", tool_call_id="2"),
AIMessage(
"The product of 317253 and 128472 plus four is 16505054788",
name="example_assistant",
),
]
system = """You are bad at math but are an expert at using a calculator.
Use past tool usage as an example of how to correctly use the tools."""
few_shot_prompt = ChatPromptTemplate.from_messages(
[
("system", system),
*examples,
("human", "{query}"),
]
)
chain = {"query": RunnablePassthrough()} | few_shot_prompt | llm_with_tools
chain.invoke("Whats 119 times 8 minus 20").tool_calls
[{'name': 'Multiply',
'args': {'a': 119, 'b': 8},
'id': 'call_MoSgwzIhPxhclfygkYaKIsGZ'}]
Seems like we get the correct output this time.
Here's what the LangSmith trace looks like.
Next stepsβ
- Output parsing: See OpenAI Tools output parsers to learn about extracting the function calling API responses into various formats.
- Structured output chains: Some models have constructors that handle creating a structured output chain for you.
- Tool use: See how to construct chains and agents that call the invoked tools in these guides.