--- name: langgraph description: Expert in LangGraph - the production-grade framework for building stateful, multi-actor AI applications. Covers graph construction, state management, cycles and branches, persistence with checkpointers, human-in-the-loop patterns, and the ReAct agent pattern. risk: unknown source: vibeship-spawner-skills (Apache 2.0) date_added: 2026-02-27 --- # LangGraph Expert in LangGraph - the production-grade framework for building stateful, multi-actor AI applications. Covers graph construction, state management, cycles and branches, persistence with checkpointers, human-in-the-loop patterns, and the ReAct agent pattern. Used in production at LinkedIn, Uber, and 400+ companies. This is LangChain's recommended approach for building agents. **Role**: LangGraph Agent Architect You are an expert in building production-grade AI agents with LangGraph. You understand that agents need explicit structure - graphs make the flow visible and debuggable. You design state carefully, use reducers appropriately, and always consider persistence for production. You know when cycles are needed and how to prevent infinite loops. ### Expertise - Graph topology design - State schema patterns - Conditional branching - Persistence strategies - Human-in-the-loop - Tool integration - Error handling and recovery ## Capabilities - Graph construction (StateGraph) - State management and reducers - Node and edge definitions - Conditional routing - Checkpointers and persistence - Human-in-the-loop patterns - Tool integration - Streaming and async execution ## Prerequisites - 0: Python proficiency - 1: LLM API basics - 2: Async programming concepts - 3: Graph theory fundamentals - Required skills: Python 3.9+, langgraph package, LLM API access (OpenAI, Anthropic, etc.), Understanding of graph concepts ## Scope - 0: Python-only (TypeScript in early stages) - 1: Learning curve for graph concepts - 2: State management complexity - 3: Debugging can be challenging ## Ecosystem ### Primary - LangGraph - LangChain - LangSmith (observability) ### Common_integrations - OpenAI / Anthropic / Google - Tavily (search) - SQLite / PostgreSQL (persistence) - Redis (state store) ### Platforms - Python applications - FastAPI / Flask backends - Cloud deployments ## Patterns ### Basic Agent Graph Simple ReAct-style agent with tools **When to use**: Single agent with tool calling from typing import Annotated, TypedDict from langgraph.graph import StateGraph, START, END from langgraph.graph.message import add_messages from langgraph.prebuilt import ToolNode from langchain_openai import ChatOpenAI from langchain_core.tools import tool # 1. Define State class AgentState(TypedDict): messages: Annotated[list, add_messages] # add_messages reducer appends, doesn't overwrite # 2. Define Tools @tool def search(query: str) -> str: """Search the web for information.""" # Implementation here return f"Results for: {query}" @tool def calculator(expression: str) -> str: """Evaluate a math expression.""" return str(eval(expression)) tools = [search, calculator] # 3. Create LLM with tools llm = ChatOpenAI(model="gpt-4o").bind_tools(tools) # 4. Define Nodes def agent(state: AgentState) -> dict: """The agent node - calls LLM.""" response = llm.invoke(state["messages"]) return {"messages": [response]} # Tool node handles tool execution tool_node = ToolNode(tools) # 5. Define Routing def should_continue(state: AgentState) -> str: """Route based on whether tools were called.""" last_message = state["messages"][-1] if last_message.tool_calls: return "tools" return END # 6. Build Graph graph = StateGraph(AgentState) # Add nodes graph.add_node("agent", agent) graph.add_node("tools", tool_node) # Add edges graph.add_edge(START, "agent") graph.add_conditional_edges("agent", should_continue, ["tools", END]) graph.add_edge("tools", "agent") # Loop back # Compile app = graph.compile() # 7. Run result = app.invoke({ "messages": [("user", "What is 25 * 4?")] }) ### State with Reducers Complex state management with custom reducers **When to use**: Multiple agents updating shared state from typing import Annotated, TypedDict from operator import add from langgraph.graph import StateGraph # Custom reducer for merging dictionaries def merge_dicts(left: dict, right: dict) -> dict: return {**left, **right} # State with multiple reducers class ResearchState(TypedDict): # Messages append (don't overwrite) messages: Annotated[list, add_messages] # Research findings merge findings: Annotated[dict, merge_dicts] # Sources accumulate sources: Annotated[list[str], add] # Current step (overwrites - no reducer) current_step: str # Error count (custom reducer) errors: Annotated[int, lambda a, b: a + b] # Nodes return partial state updates def researcher(state: ResearchState) -> dict: # Only return fields being updated return { "findings": {"topic_a": "New finding"}, "sources": ["source1.com"], "current_step": "researching" } def writer(state: ResearchState) -> dict: # Access accumulated state all_findings = state["findings"] all_sources = state["sources"] return { "messages": [("assistant", f"Report based on {len(all_sources)} sources")], "current_step": "writing" } # Build graph graph = StateGraph(ResearchState) graph.add_node("researcher", researcher) graph.add_node("writer", writer) # ... add edges ### Conditional Branching Route to different paths based on state **When to use**: Multiple possible workflows from langgraph.graph import StateGraph, START, END class RouterState(TypedDict): query: str query_type: str result: str def classifier(state: RouterState) -> dict: """Classify the query type.""" query = state["query"].lower() if "code" in query or "program" in query: return {"query_type": "coding"} elif "search" in query or "find" in query: return {"query_type": "search"} else: return {"query_type": "chat"} def coding_agent(state: RouterState) -> dict: return {"result": "Here's your code..."} def search_agent(state: RouterState) -> dict: return {"result": "Search results..."} def chat_agent(state: RouterState) -> dict: return {"result": "Let me help..."} # Routing function def route_query(state: RouterState) -> str: """Route to appropriate agent.""" query_type = state["query_type"] return query_type # Returns node name # Build graph graph = StateGraph(RouterState) graph.add_node("classifier", classifier) graph.add_node("coding", coding_agent) graph.add_node("search", search_agent) graph.add_node("chat", chat_agent) graph.add_edge(START, "classifier") # Conditional edges from classifier graph.add_conditional_edges( "classifier", route_query, { "coding": "coding", "search": "search", "chat": "chat" } ) # All agents lead to END graph.add_edge("coding", END) graph.add_edge("search", END) graph.add_edge("chat", END) app = graph.compile() ### Persistence with Checkpointer Save and resume agent state **When to use**: Multi-turn conversations, long-running agents from langgraph.graph import StateGraph from langgraph.checkpoint.sqlite import SqliteSaver from langgraph.checkpoint.postgres import PostgresSaver # SQLite for development memory = SqliteSaver.from_conn_string(":memory:") # Or persistent file memory = SqliteSaver.from_conn_string("agent_state.db") # PostgreSQL for production # memory = PostgresSaver.from_conn_string(DATABASE_URL) # Compile with checkpointer app = graph.compile(checkpointer=memory) # Run with thread_id for conversation continuity config = {"configurable": {"thread_id": "user-123-session-1"}} # First message result1 = app.invoke( {"messages": [("user", "My name is Alice")]}, config=config ) # Second message - agent remembers context result2 = app.invoke( {"messages": [("user", "What's my name?")]}, config=config ) # Agent knows name is Alice! # Get conversation history state = app.get_state(config) print(state.values["messages"]) # List all checkpoints for checkpoint in app.get_state_history(config): print(checkpoint.config, checkpoint.values) ### Human-in-the-Loop Pause for human approval before actions **When to use**: Sensitive operations, review before execution from langgraph.graph import StateGraph, START, END class ApprovalState(TypedDict): messages: Annotated[list, add_messages] pending_action: dict | None approved: bool def agent(state: ApprovalState) -> dict: # Agent decides on action action = {"type": "send_email", "to": "user@example.com"} return { "pending_action": action, "messages": [("assistant", f"I want to: {action}")] } def execute_action(state: ApprovalState) -> dict: action = state["pending_action"] # Execute the approved action result = f"Executed: {action['type']}" return { "messages": [("assistant", result)], "pending_action": None } def should_execute(state: ApprovalState) -> str: if state.get("approved"): return "execute" return END # Wait for approval # Build graph graph = StateGraph(ApprovalState) graph.add_node("agent", agent) graph.add_node("execute", execute_action) graph.add_edge(START, "agent") graph.add_conditional_edges("agent", should_execute, ["execute", END]) graph.add_edge("execute", END) # Compile with interrupt_before for human review app = graph.compile( checkpointer=memory, interrupt_before=["execute"] # Pause before execution ) # Run until interrupt config = {"configurable": {"thread_id": "approval-flow"}} result = app.invoke({"messages": [("user", "Send report")]}, config) # Agent paused - get pending state state = app.get_state(config) pending = state.values["pending_action"] print(f"Pending: {pending}") # Human reviews # Human approves - update state and continue app.update_state(config, {"approved": True}) result = app.invoke(None, config) # Resume ### Parallel Execution (Map-Reduce) Run multiple branches in parallel **When to use**: Parallel research, batch processing from langgraph.graph import StateGraph, START, END, Send from langgraph.constants import Send class ParallelState(TypedDict): topics: list[str] results: Annotated[list[str], add] summary: str def research_topic(state: dict) -> dict: """Research a single topic.""" topic = state["topic"] result = f"Research on {topic}..." return {"results": [result]} def summarize(state: ParallelState) -> dict: """Combine all research results.""" all_results = state["results"] summary = f"Summary of {len(all_results)} topics" return {"summary": summary} def fanout_topics(state: ParallelState) -> list[Send]: """Create parallel tasks for each topic.""" return [ Send("research", {"topic": topic}) for topic in state["topics"] ] # Build graph graph = StateGraph(ParallelState) graph.add_node("research", research_topic) graph.add_node("summarize", summarize) # Fan out to parallel research graph.add_conditional_edges(START, fanout_topics, ["research"]) # All research nodes lead to summarize graph.add_edge("research", "summarize") graph.add_edge("summarize", END) app = graph.compile() result = app.invoke({ "topics": ["AI", "Climate", "Space"], "results": [] }) # Research runs in parallel, then summarizes ## Collaboration ### Delegation Triggers - crewai|role-based|crew -> crewai (Need role-based multi-agent approach) - observability|tracing|langsmith -> langfuse (Need LLM observability) - structured output|json schema -> structured-output (Need structured LLM responses) - evaluate|benchmark|test agent -> agent-evaluation (Need to evaluate agent performance) ### Production Agent Stack Skills: langgraph, langfuse, structured-output Workflow: ``` 1. Design agent graph with LangGraph 2. Add structured outputs for tool responses 3. Integrate Langfuse for observability 4. Test and monitor in production ``` ### Multi-Agent System Skills: langgraph, crewai, agent-communication Workflow: ``` 1. Design agent roles (CrewAI patterns) 2. Implement as LangGraph with subgraphs 3. Add inter-agent communication 4. Orchestrate with supervisor pattern ``` ### Evaluated Agent Skills: langgraph, agent-evaluation, langfuse Workflow: ``` 1. Build agent with LangGraph 2. Create evaluation suite 3. Monitor with Langfuse 4. Iterate based on metrics ``` ## Related Skills Works well with: `crewai`, `autonomous-agents`, `langfuse`, `structured-output` ## When to Use - User mentions or implies: langgraph - User mentions or implies: langchain agent - User mentions or implies: stateful agent - User mentions or implies: agent graph - User mentions or implies: react agent - User mentions or implies: agent workflow - User mentions or implies: multi-step agent ## Limitations - Use this skill only when the task clearly matches the scope described above. - Do not treat the output as a substitute for environment-specific validation, testing, or expert review. - Stop and ask for clarification if required inputs, permissions, safety boundaries, or success criteria are missing.