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New in version 2.0.0 LLM sampling allows your MCP tools to request text generation from an LLM during execution. This enables tools to leverage AI capabilities for analysis, generation, reasoning, and more—without the client needing to orchestrate multiple calls. By default, sampling requests are routed to the client’s LLM. You can also configure a fallback handler to use a specific provider (like OpenAI) when the client doesn’t support sampling, or to always use your own LLM regardless of client capabilities.

Overview

The simplest use of sampling is passing a prompt string to ctx.sample(). The method sends the prompt to the LLM, waits for the complete response, and returns a SamplingResult. You can access the generated text through the .text attribute.
The SamplingResult also provides .result (identical to .text for plain text responses) and .history containing the full message exchange—useful if you need to continue the conversation or debug the interaction.

System Prompts

System prompts let you establish the LLM’s role and behavioral guidelines before it processes your request. This is useful for controlling tone, enforcing constraints, or providing context that shouldn’t clutter the user-facing prompt.
The temperature parameter controls randomness—higher values (up to 1.0) produce more varied outputs, while lower values make responses more deterministic. The max_tokens parameter limits response length.

Model Preferences

Model preferences let you hint at which LLM the client should use for a request. You can pass a single model name or a list of preferences in priority order. These are hints rather than requirements—the actual model used depends on what the client has available.
Use model preferences when different tasks benefit from different model characteristics. Creative writing might prefer faster models with higher temperature, while complex analysis might benefit from larger reasoning-focused models.

Multi-Turn Conversations

For requests that need conversational context, construct a list of SamplingMessage objects representing the conversation history. Each message has a role (“user” or “assistant”) and content (a TextContent object).
The LLM receives the full conversation thread and responds with awareness of the preceding context.

Fallback Handlers

Client support for sampling is optional—some clients may not implement it. To ensure your tools work regardless of client capabilities, configure a sampling_handler that sends requests directly to an LLM provider. FastMCP provides built-in handlers for OpenAI and Anthropic APIs. These handlers support the full sampling API including tools, automatically converting your Python functions to each provider’s format.
Install handlers with pip install fastmcp[openai] or pip install fastmcp[anthropic].
The sampling_handler_behavior parameter controls when the handler is used:
  • "fallback" (default): Use the handler only when the client doesn’t support sampling. This lets capable clients use their own LLM while ensuring your tools still work with clients that lack sampling support.
  • "always": Always use the handler, bypassing the client entirely. Use this when you need guaranteed control over which LLM processes requests—for cost control, compliance requirements, or when specific model characteristics are essential.

Structured Output

New in version 2.14.1 When you need validated, typed data instead of free-form text, use the result_type parameter. FastMCP ensures the LLM returns data matching your type, handling validation and retries automatically. The result_type parameter accepts Pydantic models, dataclasses, and basic types like int, list[str], or dict[str, int]. When you specify a result type, FastMCP automatically creates a final_response tool that the LLM calls to provide its response. If validation fails, the error is sent back to the LLM for retry.
When you call this tool, the LLM returns a structured response that FastMCP validates against your Pydantic model. You access the validated object through result.result, while result.text contains the JSON representation.

Structured Output with Tools

Combine structured output with tools for agentic workflows that return validated data. The LLM uses your tools to gather information, then returns a response matching your type.
Structured output with automatic validation only applies to sample(). With sample_step(), you must manage structured output yourself.

Tool Use

New in version 2.14.1 Sampling with tools enables agentic workflows where the LLM can call functions to gather information before responding. This implements SEP-1577, allowing the LLM to autonomously orchestrate multi-step operations. Pass Python functions to the tools parameter, and FastMCP handles the execution loop automatically—calling tools, returning results to the LLM, and continuing until the LLM provides a final response.

Defining Tools

Define regular Python functions with type hints and docstrings. FastMCP extracts the function’s name, docstring, and parameter types to create tool schemas that the LLM can understand.
The LLM sees each function’s signature and docstring, using this information to decide when and how to call them. Tool errors are caught and sent back to the LLM, allowing it to recover gracefully. An internal safety limit prevents infinite loops.

Custom Tool Definitions

For custom names or descriptions, use SamplingTool.from_function():

Error Handling

By default, when a sampling tool raises an exception, the error message (including details) is sent back to the LLM so it can attempt recovery. To prevent sensitive information from leaking to the LLM, use the mask_error_details parameter:
When mask_error_details=True, tool errors become generic messages like "Error executing tool 'search'" instead of exposing stack traces or internal details. To intentionally provide specific error messages to the LLM regardless of masking, raise ToolError:
ToolError messages always pass through to the LLM, making it the escape hatch for errors you want the LLM to see and handle.

Concurrent Tool Execution

By default, tools execute sequentially — one at a time, in order. When your tools are independent (no shared state between them), you can execute them in parallel with tool_concurrency:
The tool_concurrency parameter controls how many tools run at once:
  • None (default): Sequential execution
  • 0: Unlimited parallel execution
  • N > 0: Execute at most N tools concurrently
For tools that must not run concurrently (file writes, shared state mutations, etc.), mark them as sequential when creating the SamplingTool:
When any tool in a batch has sequential=True, the entire batch executes sequentially regardless of tool_concurrency. This is a conservative guarantee — if one tool needs ordering, all tools in that batch respect it.

Client Requirements

Sampling with tools requires the client to advertise the sampling.tools capability. FastMCP clients do this automatically. For external clients that don’t support tool-enabled sampling, configure a fallback handler with sampling_handler_behavior="always".

Advanced Control

New in version 2.14.1 While sample() handles the tool execution loop automatically, some scenarios require fine-grained control over each step. The sample_step() method makes a single LLM call and returns a SampleStep containing the response and updated history. Unlike sample(), sample_step() is stateless—it doesn’t remember previous calls. You control the conversation by passing the full message history each time. The returned step.history includes all messages up through the current response, making it easy to continue the loop. Use sample_step() when you need to:
  • Inspect tool calls before they execute
  • Implement custom termination conditions
  • Add logging, metrics, or checkpointing between steps
  • Build custom agentic loops with domain-specific logic

Basic Loop

By default, sample_step() executes any tool calls and includes the results in the history. Call it in a loop, passing the updated history each time, until a stop condition is met.

SampleStep Properties

Each SampleStep provides information about what the LLM returned: The contents of step.history depend on execute_tools:
  • execute_tools=True (default): Includes tool results, ready for the next iteration
  • execute_tools=False: Includes the assistant’s tool request, but you add results yourself

Manual Tool Execution

Set execute_tools=False to handle tool execution yourself. When disabled, step.history contains the user message and the assistant’s response with tool calls—but no tool results. You execute the tools and append the results as a user message.
To report an error to the LLM, set isError=True on the tool result:

Method Reference

ctx.sample()

ctx.sample
async method
Request text generation from the LLM, running to completion automatically.

ctx.sample_step()

ctx.sample_step
async method
Make a single LLM sampling call. Use this for fine-grained control over the sampling loop.