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Esta habilidad proporciona un enfoque estructurado para evolucionar gradualmente la arquitectura del sistema, utilizando patrones como la migración de higuera estranguladora y la ejecución en paralelo. Permite realizar cambios incrementales seguros, como migraciones de monolito a microservicios o reemplazos de subsistemas, sin cortes abruptos. Úsela cuando una evaluación previa haya determinado que el sistema está listo para la transformación y necesite una transición progresiva con seguridad de reversión.
Instalación rápida
Claude Code
Recomendadonpx skills add pjt222/agent-almanac -a claude-code/plugin add https://github.com/pjt222/agent-almanacgit clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/adapt-architectureCopia y pega este comando en Claude Code para instalar esta habilidad
Documentación
Adapt Architecture
Execute structural metamorphosis — transform system architecture from current form to target form while keep operational continuity. Use strangler fig migration, chrysalis phases, interface preservation. System never stops working during transformation.
When Use
- Form assessment (see
assess-form) classified system as READY - System must evolve architecture to meet new requirements without downtime
- Migrating from monolith to microservices (or reverse)
- Replacing core subsystem while dependent systems keep operating
- Evolving data model while keep backward compatibility
- Any architectural change must be gradual, not big-bang
Inputs
- Required: Current form assessment (from
assess-formor equivalent analysis) - Required: Target architecture (what system should become)
- Required: Operational continuity requirements (what must not break during transformation)
- Optional: Available transformation budget (time, people, compute)
- Optional: Rollback requirements (how far back must retreat?)
- Optional: Parallel running duration (how long run old and new together)
Steps
Step 1: Design Transformation Blueprint
Plan metamorphosis path from current form to target form.
- Map transformation as sequence of intermediate forms:
- Current form → Intermediate form 1 → ... → Target form
- Each intermediate form must be operationally viable (serves traffic, passes tests)
- No intermediate form harder to maintain than current form
- Identify transformation seams:
- Where can current form be "cut" to insert new architecture?
- Natural seams: existing interfaces, module boundaries, data partitions
- Artificial seams: interfaces created specifically to enable cut (anti-corruption layers)
- Choose metamorphosis pattern:
- Strangler fig: new system grows around old, gradually replaces it
- Chrysalis: old system wrapped in new shell; internals replaced while shell preserves external interface
- Budding: new system grows alongside old; traffic gradually shifts (see
scale-colonyfor colony budding) - Metamorphic migration: phased replacement of components in dependency order (leaves first, roots last)
- Design interface preservation layer:
- External consumers must not experience disruption
- API versioning, backward-compatible contracts, adapter patterns
- Preservation layer is temporary scaffolding — plan its removal
Metamorphosis Patterns:
┌───────────────┬───────────────────────────────────────────────────┐
│ Strangler Fig │ New code intercepts routes one by one; │
│ │ old code handles everything else until replaced │
│ │ ┌──────────┐ │
│ │ │ Old ████ │ → │ Old ██ New ██ │ → │ New ████ │ │
│ │ └──────────┘ │
├───────────────┼───────────────────────────────────────────────────┤
│ Chrysalis │ Wrap old system in new interface; replace │
│ │ internals while external shell stays stable │
│ │ ┌──────────┐ ┌──[new]───┐ ┌──[new]───┐ │
│ │ │ old core │ → │ old core │ → │ new core │ │
│ │ └──────────┘ └──────────┘ └──────────┘ │
├───────────────┼───────────────────────────────────────────────────┤
│ Budding │ New system runs in parallel; traffic shifts │
│ │ ┌──────┐ ┌──────┐ ┌──────┐ ┌──────┐ │
│ │ │ Old │ │ New │ → │ Old │ │ New │ │
│ │ │ 100% │ │ 0% │ │ 0% │ │ 100% │ │
│ │ └──────┘ └──────┘ └──────┘ └──────┘ │
└───────────────┴───────────────────────────────────────────────────┘
Got: Transformation blueprint shows intermediate forms, seams, chosen metamorphosis pattern, interface preservation strategy. Each step concrete and testable.
If fail: No clean seam? System may need preliminary dissolution (see dissolve-form) to create seams before transformation. Intermediate forms not operationally viable? Transformation steps too large — decompose into smaller increments.
Step 2: Build Scaffolding
Construct temporary infrastructure that supports metamorphosis.
- Create anti-corruption layer:
- Thin translation layer between old and new systems
- Routes requests to appropriate system (old or new) based on migration state
- Translates data formats between old and new representations
- This layer is "cocoon" that protects transformation
- Set up parallel running infrastructure:
- Both old and new systems must be deployable together
- Feature flags control which system handles which traffic
- Comparison mechanisms validate that old and new produce equivalent results
- Establish rollback checkpoints:
- At each intermediate form, verify rollback to previous form possible
- Rollback must be faster than forward transformation step
- Data migration must be reversible (or data must be dual-written during transition)
- Build validation harness:
- Automated tests verify operational continuity at each intermediate form
- Performance benchmarks detect regression
- Data integrity checks catch migration errors
Got: Scaffolding infrastructure (anti-corruption layer, parallel running, rollback, validation) in place before any transformation begins. Scaffolding itself tested and verified.
If fail: Scaffolding too expensive? Simplify: minimum viable scaffolding is feature flag and rollback procedure. Anti-corruption layers and parallel running add safety but not always necessary for smaller transformations.
Step 3: Execute Progressive Cutover
Migrate functionality from old form to new form incrementally.
- Order components for migration:
- Start with least-coupled, lowest-risk component (build confidence)
- Progress toward more critical, more coupled components
- Save most coupled/critical component for last (by then team has experience)
- For each component: a. Implement new version behind anti-corruption layer b. Run parallel: both old and new process same inputs c. Compare outputs — should be equivalent (or differences should be expected and documented) d. When confident, switch traffic to new version (feature flag flip) e. Monitor for anomalies (increase monitoring sensitivity post-cutover) f. After stability period, decommission old version of this component
- Maintain continuous delivery throughout:
- Each cutover step is normal deployment, not special event
- System always in known, tested, operational state
- Cutover causes issues? Roll back to previous state (still operational)
Got: Functionality migrates component by component with validation at each step. System always operational. Each cutover builds confidence for next.
If fail: Parallel running reveals discrepancies? New implementation has bug — fix before cutting over. Cutover causes performance degradation? New component may need optimization or anti-corruption layer adding too much overhead. Team loses confidence mid-migration? Pause and stabilize — half-migrated system in known state far better than rushed full migration.
Step 4: Manage Chrysalis Phase
Navigate most vulnerable period — when system between forms.
- Acknowledge chrysalis reality:
- During migration, system is partly old and partly new
- This hybrid state inherently more complex than either pure state
- Complexity peaks at midpoint of migration, then decreases
- Chrysalis discipline:
- No new features during chrysalis phase (transformation only)
- Minimal external changes (freeze non-essential deployments)
- Increased monitoring and on-call coverage
- Daily check-ins on migration progress and system health
- Mid-chrysalis assessment:
- At halfway point, assess: target form still right goal?
- Anything changed (market, requirements, team) that affects target?
- Should transformation continue, pause, or redirect?
- Protect chrysalis:
- Keep rollback path clear at all times
- Document current hybrid state thoroughly (future debuggers will need it)
- Resist temptation to "clean up" temporary scaffolding before migration complete
Got: Chrysalis phase managed as deliberate, time-bounded period with increased discipline and monitoring. Team understands temporary complexity is cost of safe transformation.
If fail: Chrysalis phase drags too long? Hybrid state becomes new normal — worse than either old or new. Set time limit. Limit reached? Either accelerate remaining migration or accept hybrid state as "new form" and stabilize it.
Step 5: Complete Metamorphosis and Stabilize
Finish transformation. Remove scaffolding.
- Final cutover:
- Migrate last component(s) to new form
- Run full validation suite against complete new system
- Performance test under production-equivalent load
- Remove scaffolding:
- Decommission anti-corruption layer (no longer needed)
- Remove feature flags related to migration
- Clean up parallel running infrastructure
- Archive (don't delete) old system code for reference
- Post-metamorphosis stabilization:
- Run in new form for 2-4 weeks with enhanced monitoring
- Address any issues that emerge under real-world conditions
- Update documentation to reflect new architecture
- Retrospective:
- What went well in transformation?
- What was harder than expected?
- What would do differently next time?
- Update team's transformation playbook
Got: Transformation complete. System operates in new form. Scaffolding removed. Documentation updated. Team captured learnings for future transformations.
If fail: New form unstable after cutover? Maintain rollback path and continue stabilization. Stabilization takes more than planned period? Design issue in new architecture — consider whether targeted fixes or partial rollback of most problematic component appropriate.
Checks
- Transformation blueprint shows viable intermediate forms
- Scaffolding (anti-corruption layer, rollback, validation harness) in place before migration starts
- Components migrate in order from lowest to highest risk
- Parallel running validates equivalence at each step
- Chrysalis phase time-bounded with feature freeze discipline
- All scaffolding removed after transformation completes
- Post-metamorphosis stabilization period passes without critical issues
- Retrospective captures learnings
Pitfalls
- Big-bang migration: Transform everything at once. Abandons safety of incremental cutover. Maximizes blast radius. Always migrate incrementally
- Permanent scaffolding: Anti-corruption layers and feature flags never removed become technical debt. Plan scaffolding removal as part of transformation, not afterthought
- Chrysalis denial: Pretend hybrid state is normal. Leads to feature development on unstable foundations. Acknowledge chrysalis phase and enforce discipline
- Target fixation: Becoming so committed to target architecture that signs of better alternative ignored. Mid-chrysalis assessment exists for this reason
- Transformation fatigue: Long migrations exhaust teams. Keep each transformation step small enough to complete in days, not weeks. Celebrate milestones to maintain momentum
See Also
assess-form— prerequisite assessment determines if system ready for transformationdissolve-form— for systems too rigid to transform directly; dissolution creates seams needed hererepair-damage— recovery skill for when transformation introduces damageshift-camouflage— surface adaptation may suffice without deep architectural changecoordinate-swarm— swarm coordination informs sequencing of transformation across distributed systemsscale-colony— growth pressure is common trigger for architectural adaptationimplement-gitops-workflow— GitOps provides deployment infrastructure for progressive cutoverreview-software-architecture— complementary review skill for evaluating target architecture
Repositorio GitHub
Frequently asked questions
What is the adapt-architecture skill?
adapt-architecture is a Claude Skill by pjt222. Skills package instructions and resources that Claude loads on demand, so Claude can perform adapt-architecture-related tasks without extra prompting.
How do I install adapt-architecture?
Use the install commands on this page: add adapt-architecture to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does adapt-architecture belong to?
adapt-architecture is in the Design category, tagged design.
Is adapt-architecture free to use?
Yes. adapt-architecture is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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