m2-market/scout/SPIKE.md

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Scout Host Spike (T041)

Time-boxed, read-mostly investigation of this host (m2, the machine this repo lives on) to pick where the Solution Scout (Story 5 / FR-011) should live. Evaluates the three options named in research.md §R6: (A) standalone supervised watcher, (B) Hermes plugin, (C) herdr plugin/hook — against (a) access to structured summaries without raw keystrokes, (b) opt-in enforcement point, (c) on-box summarization cost, (d) notification surface, (e) update/rollout story across the primus and agent-latest image classes.

Note: specs/S4-solution-scout.md §5 already drafted a recommendation (Option A) before this spike ran. This report re-derives the decision from concrete file/path evidence gathered on the live host, and overrides that draft — see §5 for why.

0. Fleet context confirmed on this host

  • Two desktop image classes exist, and they are not interchangeable for rollout:
    • primus — built from /home/m2/m2o/desktop/Dockerfile, this repo's own supervisord config, canary machine chris-m2o. System/image changes here mean re-baking primus (/home/m2/m2o/desktop/README.md:74, :95-104).
    • agent-latestghcr.io/machine-machine/m2-desktop:agent-latest, described repeatedly in /home/m2/m2o/.planning/federated-learning/* as "legacy/Coolify", a different image lineage this repo does not build (m2o/.planning/federated-learning/proposals/A4-propagation-rollout.md:5,17).
    • The federated-learning propagation ADR is explicit: "image/system changes are baked into m2-desktop:primus... This avoids pretending that primus and legacy/Coolify agent-latest machines can be updated the same way" (A4:5). Constitution VI says the same: "runtime-sync is the only universal install path across mixed desktop images."
    • Concretely on this host, every desktop-level supervised program (hermes-gateway, herdr-integrations, ttyd) is wired in by Dockerfile COPY ... >> supervisord.conf steps at build time (m2o/desktop/Dockerfile:73-126) into /etc/supervisor/conf.d/supervisord.conf. That file is not part of any volume that runtime-sync touches — it only exists post-bake, inside the image.

This single fact is the crux of the spike: adding a new supervised process is an image-bake operation, reachable on primus (we own the Dockerfile) but not on agent-latest (we don't own that image's build) without a separate, per-machine, non-idempotent docker exec patch to a running container's supervisord config — exactly the kind of fleet-wide-blast / non-reversible operation constitution VI rules out.

1. Option A — Standalone supervised watcher

Evidence:

  • Pattern to copy: hermes-gateway.supervisor.conf (m2o/desktop/hermes/hermes-gateway.supervisor.conf) — [program:hermes-gateway], autorestart=true, priority=45, sleep 12 boot stagger, appended into the active supervisord.conf via Dockerfile:79-82.
  • Adding m2-solution-scout the same way means a third COPY ... >> supervisord.conf block in m2o/desktop/Dockerfile, i.e. a primus image cut (VERSION=vN ./build.sh, README.md:99).
  • Rollout gap (the finding S4 missed): there is no equivalent Dockerfile for agent-latest in this repo — it's pulled pre-built from ghcr.io. Reaching it means either waiting for whoever owns that image to add the program, or docker exec-patching each running agent-latest container's /etc/supervisor/conf.d/supervisord.conf and supervisorctl update by hand per machine. That is not idempotent/reversible/runtime-sync in the sense constitution VI and the "Inherited Hard Constraints" section require.

Scoring: strongest privacy isolation (a dedicated process only reads what it's told to), but the update/rollout story (e) is the weakest of the three on THIS fleet, not the strongest as S4 assumed.

2. Option B — Hermes plugin

Evidence:

  • Hermes already runs a real plugin on this host: /home/m2/.hermes/plugins/herdr-agent-state/{__init__.py,plugin.yaml}, installed by herdr integration install hermes (confirmed via herdr integration subcommand list; this exact plugin ships with # HERDR_INTEGRATION_ID=hermes header). It registers hooks via ctx.register_hook(...) for on_session_start, pre_llm_call, pre_tool_call, post_tool_call, pre_approval_request, post_approval_response, post_llm_call, on_session_end, on_session_finalize — reporting only lifecycle state (working|blocked|idle) over the herdr Unix socket, never message content.
  • Plugin hook docs (/home/m2/.hermes/hermes-agent/website/docs/user-guide/features/hooks.md) show the two hooks a Scout would actually want:
    • post_llm_call(session_id, user_message, assistant_response, conversation_history, model, platform, **kwargs) — fires once per turn, already gives structured, per-turn intent content (not raw keystrokes — it's the resolved message/response text, the same thing Hermes itself just processed).
    • pre_llm_call(...) -> {"context": str} — could be reused later to inject a "here's a matching Solution" hint directly into the next turn instead of only toasting.
  • Deployment is a pure file drop: ~/.hermes/plugins/m2-solution-scout/{__init__.py,plugin.yaml}. No supervisord, no image bake — this is exactly the "runtime fleet-sync agent into persisted home volumes" path the federated-learning ADR (A4) calls out as the one path that reaches BOTH image classes, because Hermes itself is already supervised on both (hermes-gateway is the canonical per-desktop supervision pattern referenced by this very task, and its plugin directory lives under $HERMES_HOME regardless of which image booted it).
  • Opt-in enforcement point: hooks are in-process Python: a pull-policy.toml read at plugin register() time can make every hook a no-op when scout.enabled=false, exactly like the CLAUDE.md-documented pattern for other opt-in config.
  • On-box summarization cost: cheapest of the three — the plugin receives already-clean turn text; no separate log-tailing/parsing/redaction pass over external files is needed before summarizing, only redaction of the text it's handed directly (same redact_secrets/redact_client_identifiers obligations from S4's pull-policy.toml draft).
  • Notification surface: none built in — the plugin still needs to shell out to notify-send (XFCE) or the herdr toast socket (see Option C) for the actual popup. This is a small, one-file bridge either way.

Cons confirmed from the doc: plugin hooks run in-process with Hermes (same trust boundary — a crashing hook is caught and logged per the docs, "never crashing the agent", but a slow hook still adds latency to every turn). And it only sees Hermes sessions — OpenClaw-only or bare-herdr (Claude Code/Codex panes with no Hermes chat active) sessions are invisible to it.

3. Option C — herdr plugin/hook

Evidence:

  • herdr agent list (run once, per task instructions) returns a live, structured JSON lifecycle feed today: {agent, agent_status: working|idle|done, cwd, pane_id, workspace_id, ...} for every pane across every workspace on the box — genuinely "structured run/lifecycle summary," zero raw keystrokes, already running, no code to write.
  • ~/.herdr/runs/*.md (e.g. 2026-07-02-m2-market-first-wedge-gate.md) are rich, human/agent-authored narrative summaries — but they are a manual convention written by an orchestrating session at the end of a herd run (see this repo's own recent runs), not an automatic per-session artifact. Most single-agent sessions never produce one. This makes Option C's "structured summary" source sparse and bursty rather than continuous — a poor fit for "an operator is mid-session, starts building something... an agent proposes the link right then" (CONCEPT.md §5).
  • ~/.claude/hooks/herdr-agent-state.sh (installed by herdr integration install claude) shows the wire protocol: a Claude Code hook posts pane.report_agent_session over $HERDR_SOCKET_PATH — again lifecycle-only, no content.
  • ~/.config/herdr/config.toml already has [ui.toast] delivery = "herdr" — confirms herdr owns a native toast/notification surface today (this is also directly reusable by Options A/B as the notification backend, independent of which host wins).
  • herdr integration subcommands (install/uninstall {pi,omp,claude,codex,copilot, opencode,hermes,qodercli}, status) show integrations are themselves file-drops under ~/.claude/hooks/, ~/.hermes/plugins/, etc. — same runtime-sync-friendly deploy story as Option B.

Scoring: best-in-class for (b) opt-in enforcement (a single socket message gate) and (d) notification, but weakest for (a) — the only continuous signal herdr exposes natively is coarse lifecycle state (working/idle/done + cwd), not intent. Getting real intent out of herdr alone means depending on the sparse runs/*.md convention, which most sessions don't produce.

4. Scored comparison

Criterion A: Standalone watcher B: Hermes plugin C: herdr plugin/hook
(a) structured intent w/o raw keystrokes Depends entirely on tap sources it's given — none exist continuously today Bestpost_llm_call gives per-turn content already, every turn Weak — only continuous signal is lifecycle state; real intent needs sparse runs/*.md
(b) opt-in enforcement point Own config file, own gate — clean but net-new Clean — gate inside register() before any hook does work Best — one socket message, herdr already gates its own integrations
(c) on-box summarization cost Highest — must tail/parse/redact multiple external files first Lowest — handed clean text directly Low for lifecycle, but high if it also has to parse runs/*.md
(d) notification surface Must shell out (herdr toast or XFCE) Must shell out (herdr toast or XFCE) Native — herdr toast is its own surface, [ui.toast] already configured
(e) update/rollout, both image classes Weakest — new supervisor program = image bake; no equivalent Dockerfile for agent-latest Best — pure file drop under $HERMES_HOME, works wherever Hermes already runs (both classes) Good — file drop under ~/.claude/hooks/~/.hermes/plugins via herdr integration install, but only reaches herdr-managed panes

5. Recommendation

DECISION: Hermes plugin (Option B)

Rationale: FR-011 and Story 5's hardest constraints are (1) real per-turn intent without raw keystrokes, and (5) a rollout story that doesn't require rebuilding either image class. Concrete evidence on this host shows Option A fails (5) outright — the only mechanism this repo has for registering a new supervised program is a Dockerfile COPY into supervisord.conf, which has no agent-latest equivalent, making that option image-bake-only on one of the two live classes. Option C is native for opt-in/notification but its only continuous, low-cost signal is coarse lifecycle state — it would need Option B's or Option A's tap to get real intent anyway. Option B satisfies (1) directly (post_llm_call hands over already-resolved turn text, cheapest to summarize-on-box), and (5) matches proven fact: this host already runtime-installs a real Hermes plugin (herdr-agent-state) as a pure file drop, no image rebuild, and Hermes is the one component already supervised identically across both primus and agent-latest (that's the same "hermes-gateway pattern" this task was pointed at as reference).

Caveat worth carrying into T042: a Hermes-hosted Scout is blind to bare-herdr sessions that never touch Hermes chat (a Claude Code/Codex pane with no Hermes turn). This does not violate the "Hermes first, never Hermes-only" inherited constraint — that constraint is about marketplace touchpoints in general (Store/CLI/catalog remain Hermes-independent), and Story 5's own acceptance criteria only require discovery "via Scout or Hermes/CLI." It is, however, a real coverage gap: pure-herdr desktops get no push-side discovery in v0. Cheap mitigation for a later phase, not blocking: also register herdr integration install hermes's existing socket report as a secondary opt-in trigger so the same plugin can request the herdr toast surface ([ui.toast] delivery = "herdr") instead of shelling to notify-send, without adding a second host.

6. v0 implementation sketch

Components:

  • ~/.hermes/plugins/m2-solution-scout/
    • plugin.yamlname: m2-solution-scout, description: Solution Scout intent watch.
    • __init__.pyregister(ctx) wires on_session_start (load pull-policy.toml, no-op immediately if scout.enabled=false or tenant_id missing — fail closed, per S4's policy rules) and post_llm_call (the intent tap).
  • Config: reuse S4's existing pull-policy.toml schema verbatim (~/.config/m2-market/pull-policy.toml, [scout] block, raw_keystrokes/ raw_client_data reserved-deny keys, max_proposals_per_day, cooldowns). No new config format — the plugin is a new host for the same contract S4 already specified.
  • State/telemetry: same paths as S4 §3 (~/.local/share/m2-market/scout/state.json, outbox/YYYY-MM-DD.jsonl) — the plugin process just runs inside Hermes instead of as its own daemon.

Event flow (per turn, inside post_llm_call):

  1. Gate: scout.enabled true, tenant_id present, rate cap and per-session cap not yet hit, cooldown not active for the last dismissed listing → else return immediately.
  2. Take user_message + assistant_response (bounded to summary.max_source_chars), redact secrets/client identifiers per pull-policy.toml, produce m2.scout.intent_summary.v1 (S4 schema, unchanged) — deterministic extractive summary in v0, no extra LLM call needed since the plugin already has clean turn text.
  3. POST /memory/search to memory-api, agent_id=market:catalog, tenant-filtered (S4 §3 catalog query, unchanged).
  4. Score/coverage threshold check (S4's m2.scout.match.v1) → if it clears, build m2.scout.proposal.v1 and fire the toast (notify-send primary, herdr socket toast as fallback/secondary surface) with the M2 Store deep link.
  5. Write proposal_shown telemetry to local outbox (batched flush to market:evidence, same as S4 §3/§4) — Scout never calls m2-market install itself; Store/CLI own debit→grant→apply and emit the accept/dismiss events this plugin later folds back in.
  6. All of steps 2-5 run off the hot path where possible (background thread, mirroring the boot-md hook tutorial's pattern of not blocking the turn on non-essential work) so a slow catalog query never adds latency to the operator's actual turn.

Guardrails carried over unchanged from FR-011 / S4: default enabled=false; opt-in is per-desktop pull-policy.toml; raw_keystrokes/raw_client_data keys hard-refuse start if true; rate cap default 5/day; propose-only — install always requires the human's click through M2 Store.

DECISION: Hermes plugin