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langgraph-persistence

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by langchain-ai Β· part of langchain-ai/langchain-skills

Durable graph execution with thread-scoped checkpoints, state history, and cross-thread long-term memory. Three checkpointer options: InMemorySaver for testing, SqliteSaver for local development, PostgresSaver for production; always pass thread_id in config to enable persistence Browse and replay from past checkpoints using get_state_history() , fork execution by updating state at a past point, or manually modify state before resuming Store API provides cross-thread memory for user...

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🧩 One of 7 skills in the langchain-ai/langchain-skills package β€” works on its own, and pairs well with its siblings.

Durable graph execution with thread-scoped checkpoints, state history, and cross-thread long-term memory. Three checkpointer options: InMemorySaver for testing, SqliteSaver for local development, PostgresSaver for production; always pass thread_id in config to enable persistence Browse and replay from past checkpoints using get_state_history() , fork execution by updating state at a past point, or manually modify state before resuming Store API provides cross-thread memory for user...

Inspect the full instructions your agent will receiveExpand

This is the exact playbook injected into your agent when the skill activates β€” shown here so you can audit it before installing. You don't need to read it to use the skill.


name: langgraph-persistence description: "INVOKE THIS SKILL when your LangGraph needs to persist state, remember conversations, travel through history, or configure subgraph checkpointer scoping. Covers checkpointers, thread_id, time travel, Store, and subgraph persistence modes."

<overview> LangGraph's persistence layer enables durable execution by checkpointing graph state:
  • Checkpointer: Saves/loads graph state at every super-step
  • Thread ID: Identifies separate checkpoint sequences (conversations)
  • Store: Cross-thread memory for user preferences, facts

Two memory types:

  • Short-term (checkpointer): Thread-scoped conversation history
  • Long-term (store): Cross-thread user preferences, facts </overview>
<checkpointer-selection>
CheckpointerUse CaseProduction Ready
InMemorySaverTesting, developmentNo
SqliteSaverLocal developmentPartial
PostgresSaverProductionYes
</checkpointer-selection>

Thread Management

<ex-separate-threads> <python> Demonstrate isolated state between different thread IDs.
Copy & paste β€” that's it
# Different threads maintain separate state
alice_config = {"configurable": {"thread_id": "user-alice"}}
bob_config = {"configurable": {"thread_id": "user-bob"}}

graph.invoke({"messages": ["Hi from Alice"]}, alice_config)
graph.invoke({"messages": ["Hi from Bob"]}, bob_config)

# Alice's state is isolated from Bob's
</python> <typescript> Demonstrate isolated state between different thread IDs.
Copy & paste β€” that's it
// Different threads maintain separate state
const aliceConfig = { configurable: { thread_id: "user-alice" } };
const bobConfig = { configurable: { thread_id: "user-bob" } };

await graph.invoke({ messages: [new HumanMessage("Hi from Alice")] }, aliceConfig);
await graph.invoke({ messages: [new HumanMessage("Hi from Bob")] }, bobConfig);

// Alice's state is isolated from Bob's
</typescript> </ex-separate-threads>

State History & Time Travel

<ex-resume-from-checkpoint> <python> Time travel: browse checkpoint history and replay or fork from a past state.
Copy & paste β€” that's it
config = {"configurable": {"thread_id": "session-1"}}

result = graph.invoke({"messages": ["start"]}, config)

# Browse checkpoint history
states = list(graph.get_state_history(config))

# Replay from a past checkpoint
past = states[-2]
result = graph.invoke(None, past.config)  # None = resume from checkpoint

# Or fork: update state at a past checkpoint, then resume
fork_config = graph.update_state(past.config, {"messages": ["edited"]})
result = graph.invoke(None, fork_config)
</python> <typescript> Time travel: browse checkpoint history and replay or fork from a past state.
Copy & paste β€” that's it
const config = { configurable: { thread_id: "session-1" } };

const result = await graph.invoke({ messages: ["start"] }, config);

// Browse checkpoint history (async iterable, collect to array)
const states: Awaited<ReturnType<typeof graph.getState>>[] = [];
for await (const state of graph.getStateHistory(config)) {
  states.push(state);
}

// Replay from a past checkpoint
const past = states[states.length - 2];
const replayed = await graph.invoke(null, past.config);  // null = resume from checkpoint

// Or fork: update state at a past checkpoint, then resume
const forkConfig = await graph.updateState(past.config, { messages: ["edited"] });
const forked = await graph.invoke(null, forkConfig);
</typescript> </ex-resume-from-checkpoint> <ex-update-state> <python> Manually update graph state before resuming execution.
Copy & paste β€” that's it
config = {"configurable": {"thread_id": "session-1"}}

# Modify state before resuming
graph.update_state(config, {"data": "manually_updated"})

# Resume with updated state
result = graph.invoke(None, config)
</python> <typescript> Manually update graph state before resuming execution.
Copy & paste β€” that's it
const config = { configurable: { thread_id: "session-1" } };

// Modify state before resuming
await graph.updateState(config, { data: "manually_updated" });

// Resume with updated state
const result = await graph.invoke(null, config);
</typescript> </ex-update-state>

Subgraph Checkpointer Scoping

When compiling a subgraph, the checkpointer parameter controls persistence behavior. This is critical for subgraphs that use interrupts, need multi-turn memory, or run in parallel.

<subgraph-checkpointer-scoping-table>
Featurecheckpointer=FalseNone (default)True
Interrupts (HITL)NoYesYes
Multi-turn memoryNoNoYes
Multiple calls (different subgraphs)YesYesWarning (namespace conflicts possible)
Multiple calls (same subgraph)YesYesNo
State inspectionNoWarning (current invocation only)Yes
</subgraph-checkpointer-scoping-table> <subgraph-checkpointer-when-to-use>

When to use each mode

  • checkpointer=False β€” Subgraph doesn't need interrupts or persistence. Simplest option, no checkpoint overhead.
  • None (default / omit checkpointer) β€” Subgraph needs interrupt() but not multi-turn memory. Each invocation starts fresh but can pause/resume. Parallel execution works because each invocation gets a unique namespace.
  • checkpointer=True β€” Subgraph needs to remember state across invocations (multi-turn conversations). Each call picks up where the last left off.
</subgraph-checkpointer-when-to-use> <warning-stateful-subgraphs-parallel>

Warning: Stateful subgraphs (checkpointer=True) do NOT support calling the same subgraph instance multiple times within a single node β€” the calls write to the same checkpoint namespace and conflict.

</warning-stateful-subgraphs-parallel> <ex-subgraph-checkpointer-modes> <python> Choose the right checkpointer mode for your subgraph.
Copy & paste β€” that's it
# No interrupts needed β€” opt out of checkpointing
subgraph = subgraph_builder.compile(checkpointer=False)

# Need interrupts but not cross-invocation persistence (default)
subgraph = subgraph_builder.compile()

# Need cross-invocation persistence (stateful)
subgraph = subgraph_builder.compile(checkpointer=True)
</python> <typescript> Choose the right checkpointer mode for your subgraph.
Copy & paste β€” that's it
// No interrupts needed β€” opt out of checkpointing
const subgraph = subgraphBuilder.compile({ checkpointer: false });

// Need interrupts but not cross-invocation persistence (default)
const subgraph = subgraphBuilder.compile();

// Need cross-invocation persistence (stateful)
const subgraph = subgraphBuilder.compile({ checkpointer: true });
</typescript> </ex-subgraph-checkpointer-modes> <parallel-subgraph-namespacing>

Parallel subgraph namespacing

When multiple different stateful subgraphs run in parallel, wrap each in its own StateGraph with a unique node name for stable namespace isolation:

<python>
Copy & paste β€” that's it
from langgraph.graph import MessagesState, StateGraph

def create_sub_agent(model, *, name, **kwargs):
    """Wrap an agent with a unique node name for namespace isolation."""
    agent = create_agent(model=model, name=name, **kwargs)
    return (
        StateGraph(MessagesState)
        .add_node(name, agent)  # unique name -> stable namespace
        .add_edge("__start__", name)
        .compile()
    )

fruit_agent = create_sub_agent(
    "gpt-4.1-mini", name="fruit_agent",
    tools=[fruit_info], prompt="...", checkpointer=True,
)
veggie_agent = create_sub_agent(
    "gpt-4.1-mini", name="veggie_agent",
    tools=[veggie_info], prompt="...", checkpointer=True,
)
</python> <typescript>
Copy & paste β€” that's it
import { StateGraph, StateSchema, MessagesValue, START } from "@langchain/langgraph";

function createSubAgent(model: string, { name, ...kwargs }: { name: string; [key: string]: any }) {
  const agent = createAgent({ model, name, ...kwargs });
  return new StateGraph(new StateSchema({ messages: MessagesValue }))
    .addNode(name, agent)  // unique name -> stable namespace
    .addEdge(START, name)
    .compile();
}

const fruitAgent = createSubAgent("gpt-4.1-mini", {
  name: "fruit_agent", tools: [fruitInfo], prompt: "...", checkpointer: true,
});
const veggieAgent = createSubAgent("gpt-4.1-mini", {
  name: "veggie_agent", tools: [veggieInfo], prompt: "...", checkpointer: true,
});
</typescript>

Note: Subgraphs added as nodes (via add_node) already get name-based namespaces automatically and don't need this wrapper.

</parallel-subgraph-namespacing>

Long-Term Memory (Store)

<ex-long-term-memory-store> <python> Use a Store for cross-thread memory to share user preferences across conversations.
Copy & paste β€” that's it
from langgraph.store.memory import InMemoryStore

store = InMemoryStore()

# Save user preference (available across ALL threads)
store.put(("alice", "preferences"), "language", {"preference": "short responses"})

# Node with store β€” access via runtime
from langgraph.runtime import Runtime

def respond(state, runtime: Runtime):
    prefs = runtime.store.get((state["user_id"], "preferences"), "language")
    return {"response": f"Using preference: {prefs.value}"}

# Compile with BOTH checkpointer and store
graph = builder.compile(checkpointer=checkpointer, store=store)

# Both threads access same long-term memory
graph.invoke({"user_id": "alice"}, {"configurable": {"thread_id": "thread-1"}})
graph.invoke({"user_id": "alice"}, {"configurable": {"thread_id": "thread-2"}})  # Same preferences!
</python> <typescript> Use a Store for cross-thread memory to share user preferences across conversations.
Copy & paste β€” that's it
import { MemoryStore } from "@langchain/langgraph";

const store = new MemoryStore();

// Save user preference (available across ALL threads)
await store.put(["alice", "preferences"], "language", { preference: "short responses" });

// Node with store β€” access via runtime
const respond = async (state: typeof State.State, runtime: any) => {
  const item = await runtime.store?.get(["alice", "preferences"], "language");
  return { response: `Using preference: ${item?.value?.preference}` };
};

// Compile with BOTH checkpointer and store
const graph = builder.compile({ checkpointer, store });

// Both threads access same long-term memory
await graph.invoke({ userId: "alice" }, { configurable: { thread_id: "thread-1" } });
await graph.invoke({ userId: "alice" }, { configurable: { thread_id: "thread-2" } });  // Same preferences!
</typescript> </ex-long-term-memory-store> <ex-store-operations> <python> Basic store operations: put, get, search, and delete.
Copy & paste β€” that's it
from langgraph.store.memory import InMemoryStore

store = InMemoryStore()

store.put(("user-123", "facts"), "location", {"city": "San Francisco"})  # Put
item = store.get(("user-123", "facts"), "location")  # Get
results = store.search(("user-123", "facts"), filter={"city": "San Francisco"})  # Search
store.delete(("user-123", "facts"), "location")  # Delete
</python> </ex-store-operations>

Fixes

<fix-thread-id-required> <python> Always provide thread_id in config to enable state persistence.
Copy & paste β€” that's it
# WRONG: No thread_id - state NOT persisted!
graph.invoke({"messages": ["Hello"]})
graph.invoke({"messages": ["What did I say?"]})  # Doesn't remember!

# CORRECT: Always provide thread_id
config = {"configurable": {"thread_id": "session-1"}}
graph.invoke({"messages": ["Hello"]}, config)
graph.invoke({"messages": ["What did I say?"]}, config)  # Remembers!
</python> <typescript> Always provide thread_id in config to enable state persistence.
Copy & paste β€” that's it
// WRONG: No thread_id - state NOT persisted!
await graph.invoke({ messages: [new HumanMessage("Hello")] });
await graph.invoke({ messages: [new HumanMessage("What did I say?")] });  // Doesn't remember!

// CORRECT: Always provide thread_id
const config = { configurable: { thread_id: "session-1" } };
await graph.invoke({ messages: [new HumanMessage("Hello")] }, config);
await graph.invoke({ messages: [new HumanMessage("What did I say?")] }, config);  // Remembers!
</typescript> </fix-thread-id-required> <fix-inmemory-not-for-production> <python> Use PostgresSaver instead of InMemorySaver for production persistence.
Copy & paste β€” that's it
# WRONG: Data lost on process restart
checkpointer = InMemorySaver()  # In-memory only!

# CORRECT: Use persistent storage for production
from langgraph.checkpoint.postgres import PostgresSaver
with PostgresSaver.from_conn_string("postgresql://...") as checkpointer:
    checkpointer.setup()  # only needed on first use to create tables
    graph = builder.compile(checkpointer=checkpointer)
</python> <typescript> Use PostgresSaver instead of MemorySaver for production persistence.
Copy & paste β€” that's it
// WRONG: Data lost on process restart
const checkpointer = new MemorySaver();  // In-memory only!

// CORRECT: Use persistent storage for production
import { PostgresSaver } from "@langchain/langgraph-checkpoint-postgres";
const checkpointer = PostgresSaver.fromConnString("postgresql://...");
await checkpointer.setup(); // only needed on first use to create tables
</typescript> </fix-inmemory-not-for-production> <fix-update-state-with-reducers> <python> Use Overwrite to replace state values instead of passing through reducers.
Copy & paste β€” that's it
from langgraph.types import Overwrite

# State with reducer: items: Annotated[list, operator.add]
# Current state: {"items": ["A", "B"]}

# update_state PASSES THROUGH reducers
graph.update_state(config, {"items": ["C"]})  # Result: ["A", "B", "C"] - Appended!

# To REPLACE instead, use Overwrite
graph.update_state(config, {"items": Overwrite(["C"])})  # Result: ["C"] - Replaced
</python> <typescript> Use Overwrite to replace state values instead of passing through reducers.
Copy & paste β€” that's it
import { Overwrite } from "@langchain/langgraph";

// State with reducer: items uses concat reducer
// Current state: { items: ["A", "B"] }

// updateState PASSES THROUGH reducers
await graph.updateState(config, { items: ["C"] });  // Result: ["A", "B", "C"] - Appended!

// To REPLACE instead, use Overwrite
await graph.updateState(config, { items: new Overwrite(["C"]) });  // Result: ["C"] - Replaced
</typescript> </fix-update-state-with-reducers> <fix-store-injection> <python> Access store via the Runtime object in graph nodes.
Copy & paste β€” that's it
# WRONG: Store not available in node
def my_node(state):
    store.put(...)  # NameError! store not defined

# CORRECT: Access store via runtime
from langgraph.runtime import Runtime

def my_node(state, runtime: Runtime):
    runtime.store.put(...)  # Correct store instance
</python> <typescript> Access store via runtime parameter in graph nodes.
Copy & paste β€” that's it
// WRONG: Store not available in node
const myNode = async (state) => {
  store.put(...);  // ReferenceError!
};

// CORRECT: Access store via runtime
const myNode = async (state, runtime) => {
  await runtime.store?.put(...);  // Correct store instance
};
</typescript> </fix-store-injection> <boundaries> ### What You Should NOT Do
  • Use InMemorySaver in production β€” data lost on restart; use PostgresSaver
  • Forget thread_id β€” state won't persist without it
  • Expect update_state to bypass reducers β€” it passes through them; use Overwrite to replace
  • Run the same stateful subgraph (checkpointer=True) in parallel within one node β€” namespace conflict
  • Access store directly in a node β€” use runtime.store via the Runtime param
</boundaries>