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repair-damage

pjt222
Mis à jour 2 days ago
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À propos

Cette compétence assure une récupération structurée des systèmes endommagés via le triage, la stabilisation et la reconstruction progressive. Elle est conçue pour les incidents, les migrations échouées, la dette technique ou les dégradations croissantes. Les capacités clés incluent l'évaluation des dommages, la stabilisation d'urgence et le renforcement de la résilience.

Installation rapide

Claude Code

Recommandé
Principal
npx skills add pjt222/agent-almanac -a claude-code
Commande PluginAlternatif
/plugin add https://github.com/pjt222/agent-almanac
Git CloneAlternatif
git clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/repair-damage

Copiez et collez cette commande dans Claude Code pour installer cette compétence

Documentation

Repair Damage

Impl regenerative recovery for systems sustained structural damage — incidents, failed migrations, accumulated neglect, external disruption. Uses bio wound-healing as framework: triage, stabilization, scaffolding, progressive rebuild, scar tissue mgmt.

Use When

  • System suffered incident, needs structured recovery beyond "fix it"
  • Failed transformation (see adapt-architecture) left damaged intermediate
  • Accumulated tech debt caused partial fail
  • Org damage (team departures, knowledge loss, morale collapse) needs structured repair
  • Post-defense recovery (see defend-colony) when colony sustained damage
  • System functional but degraded, degradation worsening

In

  • Required: Damage description (what broke, when, severity)
  • Required: Current system state (working vs not)
  • Optional: Root cause (if known — may not be clear yet)
  • Optional: Pre-damage state (compare)
  • Optional: Resources (time, people, budget)
  • Optional: Urgency (actively degrading or stable-but-damaged?)

Do

Step 1: Triage

Rapidly assess all damage + classify by severity + urgency.

  1. Catalog every known damage point:
    • What component, fn, capability affected?
    • Damage complete (non-functional) or partial (degraded)?
    • Spreading (affecting adjacent) or contained?
  2. Classify each wound:
Wound Classification:
┌──────────┬──────────────────────┬────────────────────────────────────┐
│ Class    │ Severity             │ Response                           │
├──────────┼──────────────────────┼────────────────────────────────────┤
│ Critical │ Core function lost,  │ Immediate: stop bleeding, activate │
│          │ data at risk,        │ backup, redirect traffic, page     │
│          │ actively spreading   │ on-call team                       │
├──────────┼──────────────────────┼────────────────────────────────────┤
│ Serious  │ Important function   │ Urgent: fix within hours/days,     │
│          │ degraded, no spread  │ workarounds acceptable short-term  │
├──────────┼──────────────────────┼────────────────────────────────────┤
│ Moderate │ Non-critical function│ Scheduled: fix within sprint,      │
│          │ affected, contained  │ prioritize against other work      │
├──────────┼──────────────────────┼────────────────────────────────────┤
│ Minor    │ Cosmetic or edge     │ Backlog: fix when convenient,      │
│          │ case, no user impact │ may self-resolve                   │
└──────────┴──────────────────────┴────────────────────────────────────┘
  1. Prioritize repair order:
    • Critical first (stop bleeding)
    • Then serious (restore important fn)
    • Moderate + minor wait scheduled
  2. Check wound interaction:
    • Wounds amplify each other? (A worse because B also broken)
    • Fixing one auto fix others? (shared root cause)
    • Fixing one make another worse? (competing strategies)

→ Complete wound inventory classified by severity, prioritized order accounting for interactions.

If err: triage too long (system actively degrading) → skip detailed classification + focus: "What single most critical thing to stabilize?" Fix that first, then return full triage.

Step 2: Emergency Stabilization

Stop damage spreading before repair.

  1. Contain wound:
    • Isolate damaged components (circuit breakers, network segmentation, traffic rerouting)
    • Prevent cascade: disable non-essential features depending on damaged
    • Preserve evidence: snapshots, save logs, capture current state before changes
  2. Apply emergency patches:
    • Not permanent fixes — tourniquets
    • Acceptable:
      • Redirect traffic to healthy replica
      • Disable damaged feature entirely
      • Apply known-working config from backup
      • Scale up healthy components to absorb redirected load
    • Unacceptable:
      • Modifying code w/o testing (creates new wounds)
      • Deleting data to "reset" (destroys recovery options)
      • Hiding damage (disabling alerts, suppressing errors)
  3. Verify stabilization:
    • Damage still spreading? Yes → containment failed → broader isolation
    • System functional (possibly degraded)? Yes → proceed repair
    • Emergency patches holding? Yes → time for deliberate repair

→ System stable (not actively degrading) even if degraded. Damage contained + not spreading. Evidence preserved for root cause.

If err: stabilization fails (damage continues spreading despite containment) → escalate to full system fallback: activate disaster recovery, switch backup, or gracefully degrade to minimal viable. Stabilization too long becomes the disaster.

Step 3: Build Repair Scaffolding

Construct temp structures supporting repair.

  1. Set up repair env:
    • Branch or copy damaged system for repair work
    • Repair changes testable before applying to prod
    • Rollback plan for each repair step
  2. Build diagnostic infra:
    • Enhanced monitoring on damaged areas (detect regression immediately)
    • Logging captures repair process (what changed, when, why)
    • Comparison tools: pre-damage vs current vs post-repair
  3. Design repair sequence:
    • For each wound (priority order from triage): a. Root cause ID (why broke?) b. Repair approach (fix cause not just symptom) c. Verification method (confirm worked) d. Regression check (break anything else?)
  4. ID scar tissue risk:
    • Repairs under pressure often introduce scar tissue (workarounds, special cases, tech debt)
    • Plan scar mgmt (Step 5) from start

→ Repair env w/ diagnostic capability, sequenced plan, scar awareness.

If err: setting proper repair env too slow (urgency demands immediate prod changes) → apply directly w/ extreme discipline: one change at a time, tested by available means, rolled back if no help.

Step 4: Execute Progressive Rebuild

Repair systematically, verify each fix before next.

  1. For each wound (triage priority order): a. ID root cause:
    • Code bug? Config err? Data corruption? Dep fail?
    • Symptom of deeper structural problem?
    • Fixing cause also addresses other wounds? b. Implement repair:
    • Fix root cause not just symptom
    • Can't fix cause immediately → deliberate workaround + document
    • Keep minimal — fix what's broken, no refactor neighborhood c. Verify:
    • Specific damaged fn works correctly now?
    • Pass auto tests?
    • Overall health improved or unchanged? d. Regression check:
    • Break anything else?
    • Emergency patches Step 2 still needed, or remove?
  2. After all critical + serious repaired:
    • Remove emergency patches no longer needed
    • Restore disabled features
    • Return traffic normal routing
  3. Schedule moderate + minor repairs:
    • Enter normal dev workflow
    • Track to completion (no "accepted" damage)

→ Critical + serious wounds repaired w/ verified fixes. Emergency patches removed. System restored to functional.

If err: repair attempt fails or causes regression → rollback prev state + reassess. Multi attempts fail same wound → damage too deep for local repair → consider component needs full replacement not repair (see dissolve-form).

Step 5: Manage Scar + Strengthen

Address workarounds + shortcuts from emergency repair, strengthen vs recurrence.

  1. Inventory scar:
    • Emergency patches became permanent
    • Workarounds never replaced w/ proper fixes
    • Special cases for damage-related edges
    • Disabled features never re-enabled
  2. For each scar piece, decide:
    • Remove: workaround no longer needed (damage fully repaired)
    • Replace: workaround real need, impl proper
    • Accept: most practical long-term (rare, document why)
  3. Strengthen vs recurrence:
    • Root cause analysis: why did damage occur?
    • Prevention: what would have prevented? (monitoring, testing, arch change)
    • Detection: how detect faster next time? (alerts, health checks)
    • Recovery: how recover faster? (runbooks, backup procs, automation)
  4. Update immune memory:
    • Add incident pattern to monitoring + alerting (see defend-colony immune memory)
    • Update runbooks w/ working repair proc
    • Share learnings across team/org

→ Scar managed (removed/replaced/accepted documented). System repaired + more resilient than pre-damage. Learnings captured for future.

If err: scar mgmt deprioritized ("works, don't touch") → schedule explicit. Unmanaged scar accumulates + eventually contributes next incident. Root cause unidentifiable → strengthen detection + recovery speed as compensating controls.

Check

  • All damage inventoried + classified by severity
  • Emergency stabilization stopped spread
  • Evidence preserved for root cause
  • Critical + serious wounds repaired w/ verified fixes
  • Emergency patches removed after proper repair
  • Scar inventoried + managed (removed/replaced/documented)
  • Root cause analysis IDs prevention + detection improvements
  • System resilience improved vs pre-damage

Traps

  • Repair w/o stabilize: Fix root cause while system actively bleeding. Stabilize first, then repair. Tourniquets before surgery.
  • Permanent emergency patches: Emergency measures becoming permanent → compounding tech debt. Always follow w/ proper repair.
  • Root cause assumption: Assume root cause known w/o investigation. Many "obvious" causes are symptoms of deeper issues. Investigate before committing strategy.
  • Repair-induced damage: Rush repairs w/o testing → new wounds. One verified fix per iter — never batch untested.
  • Ignore scar: "Works now" ≠ "healthy". Scar from hasty repairs = seed of next incident.

  • assess-form — damage assess shares methodology w/ form assess
  • adapt-architecture — arch adaptation needed if damage reveals structural weakness
  • dissolve-form — components too damaged to repair → dissolve + rebuild
  • defend-colony — defense triggers repair; post-incident recovery feeds defense
  • shift-camouflage — surface adaptation masks damage while repair proceeds (caution)
  • conduct-post-mortem — structured post-incident analysis complements root cause
  • write-incident-runbook — repair procs captured as runbooks for future

Dépôt GitHub

pjt222/agent-almanac
Chemin: i18n/caveman-ultra/skills/repair-damage
0
agentsagentskillsai-assisted-developmentclaude-codeskillsteams

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