88f784a9aa
Move documentation files into a clearer structure: - concepts/: core ideas (convoy, identity, molecules, polecat-lifecycle, propulsion) - design/: architecture and protocols (architecture, escalation, federation, mail, etc.) - examples/: demos and tutorials (hanoi-demo) - overview.md: renamed from understanding-gas-town.md Remove outdated/superseded docs and update reference.md. Co-Authored-By: Claude Opus 4.5 <noreply@anthropic.com>
10 KiB
Polecat Lifecycle
Understanding the three-layer architecture of polecat workers
Overview
Polecats have three distinct lifecycle layers that operate independently. Confusing these layers leads to bugs like "idle polecats" and misunderstanding when recycling occurs.
The Self-Cleaning Polecat Model
Polecats are responsible for their own cleanup. When a polecat completes its work unit, it:
- Signals completion via
gt done - Exits its session immediately (no idle waiting)
- Requests its own nuke (self-delete)
This removes dependency on the Witness/Deacon for cleanup and ensures polecats never sit idle. The simple model: sandbox dies with session.
Why Self-Cleaning?
- No idle polecats - There's no state where a polecat exists without work
- Reduced watchdog overhead - Deacon doesn't need to patrol for zombies
- Faster turnover - Resources freed immediately on completion
- Simpler mental model - Done means gone
What About Pending Merges?
The Refinery owns the merge queue. Once gt done submits work:
- The branch is pushed to origin
- Work exists in the MQ, not in the polecat
- If rebase fails, Refinery re-implements on new baseline (fresh polecat)
- The original polecat is already gone - no sending work "back"
The Three Layers
| Layer | Component | Lifecycle | Persistence |
|---|---|---|---|
| Session | Claude (tmux pane) | Ephemeral | Cycles per step/handoff |
| Sandbox | Git worktree | Persistent | Until nuke |
| Slot | Name from pool | Persistent | Until nuke |
Session Layer
The Claude session is ephemeral. It cycles frequently:
- After each molecule step (via
gt handoff) - On context compaction
- On crash/timeout
- After extended work periods
Key insight: Session cycling is normal operation, not failure. The polecat continues working—only the Claude context refreshes.
Session 1: Steps 1-2 → handoff
Session 2: Steps 3-4 → handoff
Session 3: Step 5 → gt done
All three sessions are the same polecat. The sandbox and slot persist throughout.
Sandbox Layer
The sandbox is the git worktree—the polecat's working directory:
~/gt/gastown/polecats/Toast/
This worktree:
- Exists from
gt slinguntilgt polecat nuke - Survives all session cycles
- Contains uncommitted work, staged changes, branch state
- Is independent of other polecat sandboxes
The Witness never destroys sandboxes mid-work. Only nuke removes them.
Slot Layer
The slot is the name allocation from the polecat pool:
# Pool: [Toast, Shadow, Copper, Ash, Storm...]
# Toast is allocated to work gt-abc
The slot:
- Determines the sandbox path (
polecats/Toast/) - Maps to a tmux session (
gt-gastown-Toast) - Appears in attribution (
gastown/polecats/Toast) - Is released only on nuke
Correct Lifecycle
┌─────────────────────────────────────────────────────────────┐
│ gt sling │
│ → Allocate slot from pool (Toast) │
│ → Create sandbox (worktree on new branch) │
│ → Start session (Claude in tmux) │
│ → Hook molecule to polecat │
└─────────────────────────────────────────────────────────────┘
│
▼
┌─────────────────────────────────────────────────────────────┐
│ Work Happens │
│ │
│ Session cycles happen here: │
│ - gt handoff between steps │
│ - Compaction triggers respawn │
│ - Crash → Witness respawns │
│ │
│ Sandbox persists through ALL session cycles │
└─────────────────────────────────────────────────────────────┘
│
▼
┌─────────────────────────────────────────────────────────────┐
│ gt done (self-cleaning) │
│ → Push branch to origin │
│ → Submit work to merge queue (MR bead) │
│ → Request self-nuke (sandbox + session cleanup) │
│ → Exit immediately │
│ │
│ Work now lives in MQ, not in polecat. │
│ Polecat is GONE. No idle state. │
└─────────────────────────────────────────────────────────────┘
│
▼
┌─────────────────────────────────────────────────────────────┐
│ Refinery: merge queue │
│ → Rebase and merge to main │
│ → Close the issue │
│ → If conflict: spawn FRESH polecat to re-implement │
│ (never send work back to original polecat - it's gone) │
└─────────────────────────────────────────────────────────────┘
What "Recycle" Means
Session cycling: Normal. Claude restarts, sandbox stays, slot stays.
gt handoff # Session cycles, polecat continues
Sandbox recreation: Repair only. Should be rare.
gt polecat repair Toast # Emergency: recreate corrupted worktree
Session cycling happens constantly. Sandbox recreation should almost never happen during normal operation.
Anti-Patterns
Idle Polecats
Myth: Polecats wait between tasks in an idle state.
Reality: Polecats don't exist without work. The lifecycle is:
- Work assigned → polecat spawned
- Work done → polecat nuked
- There is no idle state
If you see a polecat without work, something is broken. Either:
- The hook was lost (bug)
- The session crashed before loading context
- Manual intervention corrupted state
Manual State Transitions
Anti-pattern:
gt polecat done Toast # DON'T: external state manipulation
gt polecat reset Toast # DON'T: manual lifecycle control
Correct:
# Polecat signals its own completion:
gt done # (from inside the polecat session)
# Only Witness nukes polecats:
gt polecat nuke Toast # (from Witness, after verification)
Polecats manage their own session lifecycle. The Witness manages sandbox lifecycle. External manipulation bypasses verification.
Sandboxes Without Work
Anti-pattern: A sandbox exists but no molecule is hooked.
This means:
- The polecat was spawned incorrectly
- The hook was lost during crash
- State corruption occurred
Recovery:
# From Witness:
gt polecat nuke Toast # Clean slate
gt sling gt-abc gastown # Respawn with work
Confusing Session with Sandbox
Anti-pattern: Thinking session restart = losing work.
# Session ends (handoff, crash, compaction)
# Work is NOT lost because:
# - Git commits persist in sandbox
# - Staged changes persist in sandbox
# - Molecule state persists in beads
# - Hook persists across sessions
The new session picks up where the old one left off via gt prime.
Session Lifecycle Details
Sessions cycle for these reasons:
| Trigger | Action | Result |
|---|---|---|
gt handoff |
Voluntary | Clean cycle to fresh context |
| Context compaction | Automatic | Forced by Claude Code |
| Crash/timeout | Failure | Witness respawns |
gt done |
Completion | Session exits, Witness takes over |
All except gt done result in continued work. Only gt done signals completion.
Witness Responsibilities
The Witness monitors polecats but does NOT:
- Force session cycles (polecats self-manage via handoff)
- Interrupt mid-step (unless truly stuck)
- Nuke polecats (polecats self-nuke via
gt done)
The Witness DOES:
- Respawn crashed sessions
- Nudge stuck polecats
- Handle escalations
- Clean up orphaned polecats (crash before
gt done)
Polecat Identity
Key insight: Polecat identity is long-lived; only sessions and sandboxes are ephemeral.
In the HOP model, every entity has a chain (CV) that tracks:
- What work they've done
- Success/failure rates
- Skills demonstrated
- Quality metrics
The polecat name (Toast, Shadow, etc.) is a slot from a pool - truly ephemeral. But the agent identity that executes as that polecat accumulates a work history.
POLECAT IDENTITY (persistent) SESSION (ephemeral) SANDBOX (ephemeral)
├── CV chain ├── Claude instance ├── Git worktree
├── Work history ├── Context window ├── Branch
├── Skills demonstrated └── Dies on handoff └── Dies on gt done
└── Credit for work or gt done
This distinction matters for:
- Attribution - Who gets credit for the work?
- Skill routing - Which agent is best for this task?
- Cost accounting - Who pays for inference?
- Federation - Agents having their own chains in a distributed world
Related Documentation
- Overview - Role taxonomy and architecture
- Molecules - Molecule execution and polecat workflow
- Propulsion Principle - Why work triggers immediate execution