# iicp-client · Rust SDK
[](LICENSE)
[](https://iicp.network/spec)
[](https://crates.io/crates/iicp-client)
Use the open AI mesh from your Rust app. Install the client, send an intent,
and get a routed response from an IICP node.
You do **not** need to run a node to try the client path. Consume first,
provide later.
```
urn:iicp:intent:llm:chat:v1 → discover → select → submit
```
## Install
```bash
cargo add iicp-client
```
Or add to `Cargo.toml` directly:
```toml
[dependencies]
iicp-client = "0.7.90"
```
## One-line test
Install the CLI and ask the mesh:
```bash
cargo install iicp-client
iicp-node query "Hello, mesh."
```
What good looks like:
```bash
iicp-node --help # shows query, serve, proxy, mcp-gateway, credits, ...
which iicp-node # points to your Cargo bin directory
iicp-node --version # prints iicp-node 0.7.90 or newer
```
The query command contacts the public directory, discovers a matching live node,
routes your prompt, and prints the response. No account, API key, or local node
is required for this consumer path.
Privacy note: the selected remote node can read the prompt it executes. IICP-CX
keeps key-ready transport/relay paths confidential, but it is not
executor-blind inference. For sensitive data, use local/browser inference or a
fail-closed routing profile.
## MCP gateway safety
`iicp-node mcp-gateway --tools format_json,summarize_text` advertises only the
tools you name. Shell, file, network, browser, credential, system-control and
regulated-decision tools are denied by default. Enabling one requires all four
controls: `--allow-dangerous-tools`, `--authz-policy ID`, `--sandbox container`
and `--audit-redaction` (equivalent `IICP_MCP_*` environment variables exist).
Policy receipts include risk/decision metadata and argument counts, never tool
arguments, prompts, credentials or response content.
## Use from Rust
```rust
use iicp_client::{ChatMessage, ClientConfig, IicpClient};
#[tokio::main]
async fn main() -> iicp_client::Result<()> {
let client = IicpClient::new(ClientConfig::default())?;
let reply = client.chat(
vec![ChatMessage { role: "user".into(), content: "Hello, mesh.".into() }],
None,
).await?;
println!("{}", reply.choices[0].message.content);
Ok(())
}
```
## Do I need to run a node?
No. Running a node is only needed when you want to provide compute or tools to
the mesh. Start as a client; run a node later when you want to contribute.
## Routing policy profiles
The client applies routing policy **after prompt-free discovery and before the
prompt is sent**. Defaults stay adoption-friendly but keyless plaintext is still
refused.
```bash
iicp-node query "Hello" --routing-profile standard # default encrypted mesh
iicp-node query "Secret" --routing-profile sensitive # fail closed: no remote executor
iicp-node query "Hello" --routing-profile eu-restricted # EU/EEA regions only
iicp-node query "Hello" --routing-profile strict-policy # requires no-retention manifest
```
```rust
use iicp_client::{ChatOptions, RoutingPolicy, RoutingProfile};
let reply = client.chat(
vec![ChatMessage { role: "user".into(), content: "Hello".into() }],
Some(ChatOptions {
routing_policy: Some(RoutingPolicy {
profile: RoutingProfile::EuRestricted,
..Default::default()
}),
..Default::default()
}),
).await?;
```
For stricter deployments, require a minimum policy-manifest identity level
before any prompt leaves the client. This keeps the default open mesh behavior
unchanged, but lets controllers fail closed on self-attested or rotated/revoked
providers.
```rust
let reply = client.chat(
vec![ChatMessage { role: "user".into(), content: "Hello".into() }],
Some(ChatOptions {
routing_policy: Some(RoutingPolicy {
required_manifest_identity_level: Some("operator_bound".into()),
..Default::default()
}),
..Default::default()
}),
).await?;
```
## Migrate from existing AI tools
Direct call:
```rust
// Before: call one vendor endpoint directly.
// After: ask IICP to discover and route by capability.
let reply = client.chat(
vec![ChatMessage { role: "user".into(), content: "Summarize this document.".into() }],
None,
).await?;
```
Existing OpenAI-compatible tools:
```bash
cargo install iicp-client --features proxy
iicp-node proxy
export OPENAI_BASE_URL=http://127.0.0.1:9483/v1
```
Then point LangChain, Cursor, liteLLM or another OpenAI-compatible tool at that
base URL. Full guide: <https://iicp.network/docs/proxy>
## Keep provider nodes current
The current public release line is **0.7.90**. Upgrade through your package
manager before troubleshooting an older installation. Routing profiles can
refuse remote dispatch before a prompt leaves the client; use `sensitive` for
local-only work, `eu-restricted` for EU/EEA routing, or `strict-policy` when a
no-retention policy manifest is required.
Provider nodes run an hourly official-registry check by default
(`IICP_AUTO_UPDATE=1`, `IICP_AUTO_UPDATE_INTERVAL_S=3600`; minimum 300s).
When crates.io publishes a newer stable release, `serve` installs it with
`cargo install iicp-client --force --features nat,iicp-tcp` and re-execs the
node so identity and cached node tokens are preserved.
If an older supervised node does not update itself, perform one manual upgrade
and restart through its normal supervisor. For Docker, use a restart policy
such as `--restart unless-stopped` so verified recovery can restart cleanly.
Or for the latest unreleased code:
```toml
[dependencies]
iicp-client = { git = "https://github.com/RobLe3/iicp-client-rust" }
```
---
## Architecture — consumer or provider?
This SDK covers **both** sides of the IICP protocol:
| **Consumer** | Send AI tasks to the mesh; discover and submit | `IicpClient` |
| **Provider** | Run a node, register with the directory, serve tasks | `IicpNode` |
Consumer and provider can run in the same process. For production provider nodes backed by Ollama/vLLM, see [iicp.network/docs/node-setup](https://iicp.network/docs/node-setup).
---
## Library quickstart
`chat()` discovers the best node and submits the task internally (SDK-01) — no
manual node selection needed.
```rust
use iicp_client::{ChatMessage, ChatOptions, ClientConfig, IicpClient};
#[tokio::main]
async fn main() -> iicp_client::Result<()> {
let client = IicpClient::new(ClientConfig::default())?;
let reply = client.chat(
vec![
ChatMessage { role: "system".into(), content: "You are a helpful assistant.".into() },
ChatMessage { role: "user".into(), content: "What is IICP?".into() },
],
Some(ChatOptions { timeout_ms: Some(30_000), ..Default::default() }),
).await?;
println!("{}", reply.choices[0].message.content);
Ok(())
}
```
Need the discovered nodes directly? Call `discover` yourself — the third
argument is an optional W3C `traceparent` for trace propagation:
```rust
let nodes = client.discover("urn:iicp:intent:llm:chat:v1", None, None).await?;
let node = nodes.nodes.into_iter().next().expect("no nodes available");
```
---
## Use as a local API proxy (OpenAI / Ollama / Anthropic compat)
Run a local gateway that speaks the OpenAI, Ollama, and Anthropic HTTP APIs and routes
every request across the IICP mesh — point any tool you already use at it, no code changes.
```bash
cargo install iicp-client --features proxy
iicp-node proxy # → http://127.0.0.1:9483
export OPENAI_BASE_URL=http://127.0.0.1:9483/v1 # OpenAI SDK / LangChain / Cursor / liteLLM
export OLLAMA_HOST=http://127.0.0.1:9483 # Open WebUI / Continue.dev / aider / Jan
```
Loopback-only consumer (never registers with the directory). The proxy is behind the
`proxy` Cargo feature (kept out of `default` so library builds stay lean). Override the
port with `--port` / `IICP_PROXY_PORT`; co-host next to a node with
`iicp-node serve --with-proxy`. Every response carries `Server: iicp-proxy`. Full guide:
<https://iicp.network/docs/proxy>
## Configuration
```rust
use iicp_client::ClientConfig;
let config = ClientConfig {
directory_url : "https://iicp.network/api".into(), // IICP directory
timeout_ms : 30_000, // max 120 000 (SDK-04)
region : Some("eu-central".into()), // prefer nodes in region
node_token : None, // optional auth token
..Default::default()
};
```
| `directory_url` | `"https://iicp.network/api"` | IICP directory endpoint |
| `timeout_ms` | `30000` | Request timeout — max 120 000 ms |
| `region` | `None` | Preferred node region |
| `routing_policy` | `RoutingPolicy::default()` | Pre-dispatch remote-routing gate; use `Sensitive`, `EuRestricted`, `StrictPolicy`, or an explicit debug override for special cases |
| `node_token` | `None` | Bearer token for authenticated nodes |
| `routing_epsilon` | `0.05` | ε-greedy exploration probability — with this probability a random node is selected instead of the top-ranked one, promoting discovery of new providers; `0.0` disables; override with `IICP_ROUTING_EPSILON` |
---
## Discover options
```rust
use iicp_client::DiscoverOptions;
let nodes = client.discover(
"urn:iicp:intent:llm:chat:v1",
Some(DiscoverOptions {
region : Some("eu-central".into()),
model : Some("phi3:mini".into()),
min_reputation: Some(0.7),
limit : Some(5),
browser_usable_only: None,
}),
None, // optional W3C traceparent
).await?;
```
---
## Error handling
```rust
use iicp_client::IicpError;
match client.submit(request).await {
Ok(resp) => println!("{:?}", resp),
Err(IicpError::Protocol { code, message, status }) =>
eprintln!("[{code}] {message} (HTTP {status})"),
Err(e) => eprintln!("Error: {e}"),
}
```
Error codes match the [IICP error reference](https://iicp.network/docs/error-reference).
---
## Serving as a node — handler contract
When you run a serving node (`IicpNode::serve`), your handler returns the **inner result
value**; `serve()` wraps it in the `TaskResponse.result` envelope for you. Do **not** return
an already-wrapped `{"result": ...}` value — that double-nests the response and breaks
cross-flavour interop with the Python/TS SDKs (response shape must be `{"result": {...}}`).
The `backends::invoke_backend` / `openai_compat::invoke` helpers return a
`{"result": ...}` consumer envelope, so when using them as a serve handler, unwrap the
inner value first:
```rust
let v = iicp_client::backends::invoke_backend("openai_compat", &opts, &req.intent, &req.payload)
.await
.unwrap_or_else(|e| serde_json::json!({"error_code": 500, "error_message": e}));
// serve() re-wraps in TaskResponse.result — return the inner value to stay single-level.
Ok(v.get("result").cloned().unwrap_or(v))
```
### Backends — pick an inference engine
`iicp-node serve` (and the `backends::invoke_backend` dispatch) supports named
backend engines, selected with `--backend-type` / `IICP_BACKEND_TYPE`
(default `openai_compat`):
| `openai_compat` | OpenAI `/v1/*` | Ollama, LM Studio, any OpenAI-compatible server |
| `meshllm` | Stable chat over local OpenAI `/v1` | MeshLLM at `http://localhost:9337/v1` |
| `vllm` | OpenAI `/v1/*` | vLLM OpenAI server (default port 8000) |
| `llamacpp` | OpenAI `/v1/*` | llama.cpp `llama-server` (default port 8080) |
| `anthropic` | Anthropic Messages API (`POST /v1/messages`) | Anthropic API → first-class Claude |
### MeshLLM
MeshLLM is a local OpenAI-compatible backend. Start its local gateway, then choose
one advertised model explicitly (the stable IICP profile serves chat only):
```bash
iicp-node serve --backend-type meshllm --model <meshllm-model-id>
```
The upstream experimental `mesh` ensemble is never selected automatically. Use it
only with an explicit `--model mesh --experimental` opt-in.
MeshLLM remains the local inference runtime. IICP uses its local OpenAI-compatible
gateway for task execution and does not publish MeshLLM peer or topology details
through IICP discovery.
The `anthropic` backend translates the IICP `llm:chat:v1` task into an Anthropic
Messages request and translates the reply back to the OpenAI chat-completion
shape — so a Claude-backed node looks identical to any other node to IICP
clients. It hoists system-role messages into the top-level `system` param, sends
`x-api-key` + `anthropic-version` headers, and defaults `max_tokens` (Anthropic
requires it). With no `--backend-url` override it targets `https://api.anthropic.com/v1`.
```bash
# Serve Claude as an IICP node
iicp-node serve \
--backend-type anthropic \
--model claude-opus-4-8 \
--backend-api-key "$ANTHROPIC_API_KEY"
# or set IICP_BACKEND_TYPE / IICP_BACKEND_API_KEY in the environment
```
The API key comes from `--backend-api-key` (env `IICP_BACKEND_API_KEY`). For the
OpenAI-compatible backends this is sent as a Bearer token; for `anthropic` it is
sent as the `x-api-key` header.
### Input modalities — text, image, audio
A node advertises the input modalities each model accepts under
`capabilities[].input_modalities`, detected from the model name (conservative
name-pattern matching, ADR-046 / #408 / #414):
| `vl` / `vision` / `llava` | `["text", "image"]` |
| `audio` / `voxtral` | `["text", "audio"]` |
| `omni` | `["text", "image", "audio"]` |
| anything else | `["text"]` |
Each modality is a modality of chat, not a separate intent. A single node hosting
several models advertises one capability object per `(intent, input_modalities)`
group, so a text model and a vision model on the same node surface as distinct
capabilities. Image and audio are passed through OpenAI-style content parts
(`text` and `image_url` blocks); the `anthropic` backend maps `image_url` parts
(data-URL or remote URL) into native Anthropic image content blocks.
### Listen port — default 9484, auto-increment (v0.7.5+)
The official IICP port **9484** is the default listen port (`IICP_PORT`, `--port`).
The `iicp-node` binary auto-increments to the next free port when 9484 is already
in use, so several nodes on one host don't need hand-picked ports — first binds
9484, second 9485, third 9486, etc. Each node gets its own port (hence its own NAT
pinhole); multiple models on one node share that single port. Auto-increment is
skipped when you pass an explicit `--public-endpoint`.
---
## NAT traversal — automatic (v0.7.3+)
Since v0.7.3, NAT detection runs automatically on every `iicp-node serve` startup — no flags
needed. Requires the `nat` feature (UPnP detection):
```toml
[dependencies]
iicp-client = { version = "0.7", features = ["nat"] }
# For relay substrate (CGNAT fallback): add "iicp-tcp"
iicp-client = { version = "0.7", features = ["nat", "iicp-tcp"] }
```
| **0** | VPS/cloud (public IP on NIC) or `IICP_PUBLIC_ENDPOINT` set | Registers directly |
| **1a** | Home router with UPnP, no CGNAT | Port-forward via UPnP → register WAN IP |
| **1b** | CGNAT + IPv6 + AddPinhole works | Registers IPv6 with firewall rule |
| **1c** | CGNAT + IPv6 + AddPinhole fails (FRITZ!Box error 606) | Registers IPv6 + logs guidance |
| **3** | CGNAT + no usable IPv6 | Opens a Quick Tunnel if available → otherwise auto-elects relay |
| **4** | Nothing worked | Serves locally with operator guidance |
### Environment-specific behaviour
**Docker bridge (`-p 8020:8020`)** — UPnP is skipped (reaches Docker NAT, not home router).
The official image includes `cloudflared`, so without a public endpoint it first tries a
zero-account Quick Tunnel, then relay. The image also sets `IICP_SUPERVISED=1`, so
with Docker restart policy enabled a confirmed tunnel-dead state exits visibly and lets
Docker restart the node. For stable direct hosting, set `IICP_PUBLIC_ENDPOINT`:
```bash
docker run --restart unless-stopped \
-e IICP_PUBLIC_ENDPOINT=http://your-host:8020 \
-e IICP_BACKEND_URL=http://host.docker.internal:11434 \
-p 8020:8020 my-iicp-node
```
**CGNAT + no IPv6 → Quick Tunnel, then relay:**
```
[iicp-node] NAT tier=3: opening Quick Tunnel...
[iicp-node] no tunnel available — auto-electing relay from directory...
[iicp-node] auto-elected relay: relay.example.com:9485
```
### Running a relay-capable node (relay operator)
```rust
use iicp_client::{IicpNode, NodeConfig};
let node = IicpNode::new(NodeConfig {
endpoint : "http://relay.example.com:8020".into(),
intent : "urn:iicp:intent:llm:chat:v1".into(),
relay_capable : true, // accept RELAY_BIND on TCP 9485 (requires iicp-tcp)
relay_accept_port: 9485,
enable_mesh : true, // advertise relay_capable=true in gossip
..Default::default()
});
```
Relay workers request short-lived directory-signed bind tickets when they have a saved node
token. Relay operators can enforce them with `IICP_RELAY_REQUIRE_BIND_TICKET=1` and the
directory's Ed25519 verification key in `IICP_RELAY_BIND_TICKET_PUBLIC_KEY`. Keep strict mode
enabled on public relays; unsigned compatibility mode is intended only for staged migration.
### Opt-out / override
```bash
IICP_AUTO_DETECT_NAT=false # disable detection entirely
IICP_PUBLIC_ENDPOINT=http://x.x.x.x:8020 # trust this endpoint
IICP_TUNNEL=0 # opt out of Quick Tunnel fallback
IICP_TUNNEL_CREATE_MIN_INTERVAL_S=120 # host-wide Quick Tunnel create pacing
IICP_TUNNEL_CREATE_JITTER_MAX_S=15 # randomized suffix after shared deadlines
IICP_TUNNEL_WAIT_FOR_CAPACITY=1 # default: wait through local/provider cooldowns
IICP_TUNNEL_DEAD_POLICY=auto # auto|retry|exit|log-only (unrecoverable dead-state policy)
IICP_SUPERVISED=1 # set by generated services/Docker so supervisors can restart
IICP_AUTO_UPDATE=1 # hourly provider self-update; set 0 to disable
IICP_AUTO_UPDATE_INTERVAL_S=3600 # update cadence in seconds; minimum 300
IICP_RELAY_WORKER_ENDPOINT=host:9485 # specific relay instead of auto-elect
```
When several nodes on one host wake or recover together, they share a local creation
lease and cooldown state. A node waits until the authoritative deadline, then adds a
small randomized delay before attempting its own Quick Tunnel. This prevents a restart
storm without advertising an unverified direct route. Set
`IICP_TUNNEL_WAIT_FOR_CAPACITY=0` only for diagnostics that need the raw cooldown error.
### Publish a signed node policy
Operators can describe public handling rules in a local JSON file and have the client sign it
with their existing operator identity before registration:
```bash
iicp-node serve --node my-node --policy-manifest ~/.iicp/node-policy.json
# or: IICP_POLICY_MANIFEST_FILE=~/.iicp/node-policy.json
```
The source file stays local. The registration contains the public policy document, its public
operator key, timestamps, and detached Ed25519 signature—never the operator secret. The same
signed document is reused during recovery re-registration, so policy does not disappear when
a tunnel rotates. A signed declaration is tamper-evident operator evidence, not a legal or
privacy certification.
---
## Operator identity
Your **operator identity** is an ed25519 keypair — its public key *is* your `operator_id` (the
directory stores it as `operator_pubkey`). One identity spans every node you run: it binds them to
you (nodes show **`Operated by <your name>` ✓**), earns a
[founder ordinal](https://iicp.network/founders), and rolls each node's credits into one operator
wallet. Your `display_name` is the public, mutable handle; your contact stays local.
```bash
iicp-node init # create your key-backed identity (~/.iicp/operator.json)
iicp-node serve --node mynode # signs an operator→node delegation; binds the node to you
iicp-node operator rename "NewName" # change your public display_name (signed)
iicp-node operator encrypt # password-encrypt the secret at rest ($IICP_OPERATOR_PASSPHRASE)
iicp-node operator decrypt # remove at-rest encryption
```
**The key is the identity** — whoever holds `~/.iicp/operator.json` controls it (its nodes, ordinal,
and wallet); there is no central recovery. Back it up (encrypted), never commit or share it; lose it
and the identity, with its founder ordinal, is gone.
Full guide: **[iicp.network/docs/operator-identity](https://iicp.network/docs/operator-identity)**
### Operator data rights
You can request a portable, redacted record of the operator metadata held by a compatible directory without uploading your private identity key:
```bash
iicp-node operator dsr export --output ~/iicp-operator-export.json
```
The client obtains a short-lived challenge and signs it locally. The receipt excludes the private key, node tokens, prompt content, and contact details; it is saved owner-only on Unix. `restrict` and `anonymize` are explicit, confirmed requests and do not erase retention records that a directory must keep for security, fraud prevention, or legal obligations. See the [operator rights guide](https://iicp.network/operator/rights).
---
## SDK conformance
| SDK-01 | discover → select → submit pipeline | ✓ |
| SDK-02 | `task_id` auto-generated (UUID v4) | ✓ |
| SDK-03 | Intent URN pattern validation (regex) | ✓ |
| SDK-04 | `timeout_ms` capped at 120 000 ms | ✓ |
| SDK-05 | Retry on transient errors (429 / 502 / 503 / 504) | ✓ |
| SDK-06 | W3C `traceparent` propagation (shared across discover + submit) | ✓ |
Conformance tier: `iicp:sdk:v1` (spec S.14) · [Request a badge](https://iicp.network/conformance)
---
## Development
```bash
cargo test # run the unit suite
cargo clippy # lint
cargo build --release
cargo run --example quickstart
```
---
## Links
- [Protocol spec](https://iicp.network/spec) — full IICP specification
- [Node setup guide](https://iicp.network/docs/node-setup) — run your own node
- [Error reference](https://iicp.network/docs/error-reference) — all error codes
- [iicp-client-python](https://github.com/RobLe3/iicp-client-python) — Python SDK
- [iicp-client-typescript](https://github.com/RobLe3/iicp-client-typescript) — TypeScript SDK
---
Apache 2.0 · [iicp.network](https://iicp.network)