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ADR-133: HOMECORE-ASSIST — Voice/Intent Pipeline + Ruflo Agent Bridge

Field Value
Status Proposed
Date 2026-05-25
Deciders ruv
Codename HOMECORE-ASSIST
Relates to ADR-126 (HOMECORE master), ADR-127 (HOMECORE-CORE), ADR-130 (HOMECORE-API), ADR-124 (SENSE-BRIDGE)
Tracking issue TBD
Crate v2/crates/homecore-assist

1. Context

Home Assistant's Assist pipeline (homeassistant/components/assist_pipeline/) provides voice-to-intent-to-response processing. It chains:

  1. STT (speech-to-text) — Whisper, cloud, or satellite
  2. NLU (natural language understanding) — intent recognition via regex/slots
  3. Intent handler — maps intent to a HA service call
  4. TTS (text-to-speech) — synthesises the response for the caller

HA's intent model (homeassistant/helpers/intent.py) is keyword/regex based. Every intent is a named template with slot definitions and a handler that dispatches to HA services. The built-in intents (homeassistant/components/conversation/default_agent.py) cover HassTurnOn, HassTurnOff, HassLightSet, HassNevermind, HassCancelAll, HassGetState, HassGetWeather, and many others.

HOMECORE needs a wire-compatible Assist pipeline so that:

  • The HA iOS/Android companion app's "Assist" button works against HOMECORE.
  • The HOMECORE-API WebSocket assist command (ADR-130 §2.2) has a handler.
  • The ruflo agent toolchain (ADR-124) can provide LLM-grade intent disambiguation as a drop-in upgrade path for the P1 regex recognizer.

1.1 Ruflo integration approach

Ruflo's agent runner exposes an MCP-over-stdio interface (node ruflo-agent.js). HOMECORE-ASSIST manages a long-lived subprocess (Q3 Windows concern below), sends utterance JSON, and receives intent JSON back. In P1 we ship only the trait surface and a NoopRunner stub; the real subprocess management is P2.

1.2 Ruvector semantic intent matching (P2)

ruvector-core provides embedding + cosine-similarity primitives. P2 will add a SemanticIntentRecognizer that embeds the utterance and compares it to a HNSW index of intent exemplars, falling back to the P1 regex recognizer when similarity < 0.75. This is the mechanism that allows "dim the lights" to match HassLightSet without an explicit regex entry.

2. Design

2.1 Module layout (v2/crates/homecore-assist/)

Module Contents
intent IntentName newtype, Intent (name + slots), IntentResponse (speech + optional card + optional data)
recognizer IntentRecognizer trait; RegexIntentRecognizer (P1); SemanticIntentRecognizer stub (P2)
handler IntentHandler trait; built-in handlers: HassTurnOn, HassTurnOff, HassLightSet, HassNevermind, HassCancelAll
runner RufloRunner trait + RufloRunnerOpts; NoopRunner (P1 stub); real subprocess runner (P2)
pipeline AssistPipeline: wires recognizer → handler → response; exposes async fn process(utterance, language) -> IntentResponse

2.2 Built-in intent handlers (P1)

Handler HA service call Slot
HassTurnOn homeassistant.turn_on / light.turn_on / switch.turn_on entity_id
HassTurnOff homeassistant.turn_off / light.turn_off / switch.turn_off entity_id
HassLightSet light.turn_on entity_id, brightness (0255), color_name
HassNevermind — (no-op, returns acknowledgement)
HassCancelAll — (fires homeassistant_stop_all_scripts domain event)

2.3 IntentResponse

pub struct IntentResponse {
    pub speech: String,
    pub card: Option<Card>,
    pub data: Option<serde_json::Value>,
}

pub struct Card {
    pub title: String,
    pub content: String,
}

2.4 RufloRunner trait

#[async_trait]
pub trait RufloRunner: Send + Sync + 'static {
    async fn spawn(&mut self, opts: RufloRunnerOpts) -> Result<(), AssistError>;
    async fn send_request(&self, payload: serde_json::Value) -> Result<RufloResponse, AssistError>;
    async fn shutdown(&mut self) -> Result<(), AssistError>;
}

RufloResponse is { intent: Option<Intent>, speech: Option<String> }.

2.5 Pipeline

pub struct AssistPipeline<R, H> {
    recognizer: R,
    handler: H,
    runner: Option<Box<dyn RufloRunner>>,
}

impl<R: IntentRecognizer, H: IntentHandler> AssistPipeline<R, H> {
    pub async fn process(&self, utterance: &str, language: &str, hc: &HomeCore)
        -> Result<IntentResponse, AssistError>;
}

3. Questions & Answers

Q1 — Why not reuse HA's existing homeassistant.helpers.intent via PyO3?

PyO3 bridges add a GIL lock on every cross-language call; the Assist pipeline processes hundreds of short utterances per day from voice satellites. A native Rust recognizer is simpler and faster. Python HA can still connect as an external integration via MQTT or the HOMECORE WebSocket API.

Q2 — How does RegexIntentRecognizer handle ambiguity?

Patterns are tried in registration order; the first match wins. Slot extraction uses named capture groups. A future P2 upgrade can run all patterns, score them by slot completeness, and return the highest-scoring match.

Q3 — Windows subprocess teardown (ruflo runner subprocess on Windows)

tokio::process::Child on Windows does not automatically kill the child process when the Child struct is dropped — SIGTERM is not a Windows concept, and TerminateProcess is not called automatically. Options for P2:

  1. Call child.start_kill() in a Drop impl (requires a Runtime handle — tricky in sync Drop).
  2. Wrap Child in an Arc<Mutex<Option<Child>>> and call kill() in an async fn shutdown().
  3. Use a Windows job object to bind the subprocess lifetime to the parent process.

P2 decision: implement option 2 (explicit async shutdown()) + register a tokio::signal handler for Ctrl+C / SIGINT that calls shutdown() before exit. Document the Windows caveat in the crate README and in runner.rs. Job object approach (option 3) is deferred to P3 only if option 2 proves insufficient in fleet testing.

Q4 — Why is SemanticIntentRecognizer a P2 stub?

The ruvector HNSW index requires the vector store to be populated at startup with intent exemplars. That startup path requires deciding on a serialization format (HNSW index files vs. an in-memory array at compile time), which intersects with ADR-084 (RabitQ) and ADR-067 (ruvector v2.0.5). P2 will define the exemplar format and populate the index.

4. Consequences

  • Positive: HOMECORE-API assist WebSocket command gets a functional backend.
  • Positive: Ruflo LLM pipelines can upgrade intent matching by swapping the RufloRunner impl.
  • Positive: P1 ships with zero new heavy dependencies (no subprocess spawning, no ML runtime).
  • Negative: Regex matching has limited coverage; long-tail utterances will return "I'm not sure".
  • Deferral: ruvector semantic recognizer and real subprocess runner both land in P2.

5. Implementation phases

Phase Scope
P1 (this ADR) intent, recognizer (regex), handler (5 built-ins), runner (trait + noop), pipeline (end-to-end wiring), 1015 tests
P2 Real tokio::process::Child runner with Windows-safe teardown; SemanticIntentRecognizer with ruvector HNSW
P3 STT/TTS bridge, satellite protocol, cloud fallback