decomposition-reconstruction
- Repo stars 103
- Author updated Live
- Author repo claude
- Domain
- Other
- Compatible agents
-
- Claude Code
- Cursor
- Cline
- Codex
- Windsurf
- Gemini CLI
- +20
- Trust score
- 88 / 100 · community maintained
- Author / version / license
- @lyndonkl · no license declared
- Token usage
- Lean
- Setup complexity
- Guided setup
- External API key
- Not required
- Operating systems
- macOS · Linux · Windows
- Runtime requirements
- Node.js
- Permissions
-
- Read-only
- Write / modify
- Shell exec
- Network behavior
- External requests
- Install commands
- 26 variants
Profile is derived at build time from SKILL.md and install vectors. Subject to drift from author intent.
Heads up: 未限定 allowed-tools,默认拥有全部工具权限。
---
name: decomposition-reconstruction
description: Breaks complex systems into atomic components, maps their relationships, and reconstructs them i…
category: other
runtime: Node.js
---
# decomposition-reconstruction output preview
## PART A: Task fit
- Use case: Breaks complex systems into atomic components, maps their relationships, and reconstructs them in optimized configurations to identify bottlenecks, critical failure points, and redesign opportunities. Use when dealing with complex systems that need simplification, identifying bottlenecks or critical failure points, redesigning architecture or processes for better performance, breaking down problems that feel overwhelming, analyzing dependencies to understand ripple effects, or when optimization requires understanding how parts interact..
- Inputs: target material, constraints, expected output, and acceptance criteria.
- Evidence boundary: follow “Workflow / Scoping Questions / Decomposition Strategies” and do not present inference as author intent.
## PART B: Execution result
- **01** The card summarizes the use case; runtime output centers on “Breaks complex systems into atomic components, maps their relationships, and reconstructs them in optimized configurations to identify bottlenecks, critical failure points, and redesign opportunities. Use when dealing with complex systems that need simplification, identifying bottlenecks or critical failure points, redesigning architecture or processes for better performance, breaking down problems that feel overwhelming, analyzing dependencies to understand ripple effects, or when optimization requires understanding how parts interact.”.
- **02** When the source has headings, the agent prioritizes “Workflow / Scoping Questions / Decomposition Strategies” so the result follows the author’s structure.
- **03** Typical output includes task judgment, concrete steps, required commands or file edits, validation, and follow-up options.
- **04** Risk context follows the fingerprint: read files, write/modify files, run shell commands; may access external network resources; usually needs no extra API key.
## Running Rules
- read files, write/modify files, run shell commands; may access external network resources; usually needs no extra API key.
- Validate with a small sample before expanding scope.
- Return the result, validation criteria, and next iteration options. The source does not require a stable slash command. After installation, invoke the skill by name and describe the task.
Name target files or source material, expected output, forbidden changes, and whether network or shell access is allowed. Permission fingerprint: read files, write/modify files, run shell commands.
Start with a small task and check whether the result follows “Workflow / Scoping Questions / Decomposition Strategies”. Inspect diffs, logs, previews, or tests before expanding scope.
Confirm the final output includes a concrete result, evidence, and next action. If it stays generic, tighten inputs, boundaries, and acceptance criteria.
---
name: decomposition-reconstruction
description: Breaks complex systems into atomic components, maps their relationships, and reconstructs them i…
category: other
source: lyndonkl/claude
---
# decomposition-reconstruction
## When to use
- Breaks complex systems into atomic components, maps their relationships, and reconstructs them in optimized configurat…
- Use it when the task has clear inputs, repeatable steps, and validation criteria.
## What to provide
- Target material, scope, expected result, and forbidden changes.
- Whether network, commands, file writes, or external services are allowed.
## Execution rules
- Organize steps around “Workflow / Scoping Questions / Decomposition Strategies” and keep inference separate from source facts.
- read files, write/modify files, run shell commands; may access external network resources; usually needs no extra API key.
- Validate with a small sample before expanding the task.
## Output requirements
- Return the deliverable, key evidence, validation method, and next action.
- Mark missing information as unknown; do not invent commands, platforms, or dependencies. The author source anchors workflow facts; repository files anchor sources and commands; Fluxly only adds fit, limitations, and quality judgment.
skill "decomposition-reconstruction" {
input -> user goal + target files + boundaries + acceptance criteria
context -> Workflow / Scoping Questions / Decomposition Strategies
rules -> SKILL.md triggers / order / output contract
runtime -> Node.js | read files, write/modify files, run shell commands | may access external network resources
guardrails -> usually needs no extra API key + small-sample validation + diff/log review
output -> copyable result + checklist + next iteration
} Decomposition & Reconstruction
Workflow
Copy this checklist and track your progress:
Decomposition & Reconstruction Progress:
- [ ] Step 1: Define the system and goal
- [ ] Step 2: Decompose into components and relationships
- [ ] Step 3: Analyze component properties and interactions
- [ ] Step 4: Reconstruct for insight or optimization
- [ ] Step 5: Validate and deliver recommendations
Step 1: Define the system and goal
Ask user to describe the system (what are we analyzing), current problem or goal (what needs improvement, understanding, or redesign), boundaries (what's in scope vs out of scope), and success criteria (what would "better" look like). Clear boundaries prevent endless decomposition. See Scoping Questions for clarification prompts.
Step 2: Decompose into components and relationships
Break system into atomic parts that can't be meaningfully subdivided further. Identify relationships (dependencies, data flow, control flow, temporal ordering). Choose decomposition strategy based on system type. See Decomposition Strategies and resources/template.md for structured process.
Step 3: Analyze component properties and interactions
For each component, identify key properties (cost, time, complexity, reliability, etc.). Map interactions (which components depend on which). Identify critical paths, bottlenecks, or vulnerable points. For complex analysis → See resources/methodology.md for dependency mapping and critical path techniques.
Step 4: Reconstruct for insight or optimization
Based on goal, either: (a) Identify critical components (bottleneck, single point of failure, highest cost driver), (b) Redesign configuration (reorder, parallelize, eliminate, combine components), or (c) Simplify (remove unnecessary components). See Reconstruction Patterns for common approaches.
Step 5: Validate and deliver recommendations
Self-assess using resources/evaluators/rubric_decomposition_reconstruction.json (minimum score ≥ 3.5). Present decomposition-reconstruction.md with clear component breakdown, analysis findings (bottlenecks, dependencies), and actionable recommendations with expected impact.
Scoping Questions
To define the system:
- What is the system we're analyzing? (Be specific: "checkout flow" not "website")
- Where does it start and end? (Boundaries)
- What's in scope vs out of scope? (Prevents endless decomposition)
To clarify the goal:
- What problem are we solving? (Slow performance, high cost, complexity, unreliability)
- What would success look like? (Specific target: "reduce latency to <500ms", "cut costs by 30%")
- Are we optimizing, understanding, or redesigning?
To understand constraints:
- What can't we change? (Legacy systems, budget limits, regulatory requirements)
- What's the time horizon? (Quick wins vs long-term redesign)
- Who are the stakeholders? (Engineering, business, customers)
Decomposition Strategies
Choose based on system type:
Functional Decomposition
When: Business processes, software features, workflows Approach: Break down by function or task Example: E-commerce checkout → Browse products | Add to cart | Enter shipping | Payment | Confirmation
Structural Decomposition
When: Architecture, organizations, physical systems Approach: Break down by component or module Example: Web app → Frontend (React) | API (Node.js) | Database (PostgreSQL) | Cache (Redis)
Data Flow Decomposition
When: Pipelines, ETL processes, information systems Approach: Break down by data transformations Example: Analytics pipeline → Ingest raw events | Clean & validate | Aggregate metrics | Store in warehouse | Visualize in dashboard
Temporal Decomposition
When: Processes with sequential stages, timelines, user journeys Approach: Break down by time or sequence Example: Customer onboarding → Day 1: Signup | Day 2-7: Tutorial | Day 8-30: First value moment | Day 31+: Retention
Cost/Resource Decomposition
When: Budget analysis, resource allocation, optimization Approach: Break down by cost center or resource type Example: AWS bill → Compute ($5K) | Storage ($2K) | Data transfer ($1K) | Other ($500)
Depth guideline: Stop decomposing when further breakdown doesn't reveal useful insights or actionable opportunities.
Component Relationship Types
After decomposition, map relationships:
1. Dependency (A requires B):
- API service depends on database
- Frontend depends on API
- Critical for: Identifying cascading failures, understanding change impact
2. Data flow (A sends data to B):
- User input → Validation → Database → API response
- Critical for: Tracing information, finding transformation bottlenecks
3. Control flow (A triggers B):
- Button click triggers form submission
- Payment success triggers order fulfillment
- Critical for: Understanding execution paths, identifying race conditions
4. Temporal ordering (A before B in time):
- Authentication before authorization
- Compile before deploy
- Critical for: Sequencing, finding parallelization opportunities
5. Resource sharing (A and B compete for C):
- Multiple services share database connection pool
- Teams share budget
- Critical for: Identifying contention, resource constraints
Reconstruction Patterns
Pattern 1: Bottleneck Identification
Goal: Find what limits system throughput or speed Approach: Measure component properties (time, cost, capacity), identify critical path or highest value Example: DB query takes 80% of request time → Optimize DB query first
Pattern 2: Simplification
Goal: Reduce complexity by removing unnecessary parts Approach: Question necessity of each component, eliminate redundant or low-value parts Example: Workflow has 5 approval steps, 3 are redundant → Remove 3 steps
Pattern 3: Reordering
Goal: Improve efficiency by changing sequence Approach: Identify dependencies, move independent tasks earlier or parallel Example: Run tests parallel to build instead of sequential → Reduce CI time
Pattern 4: Parallelization
Goal: Increase throughput by doing work concurrently Approach: Find independent components, execute simultaneously Example: Fetch user data and product data in parallel instead of serial → Cut latency in half
Pattern 5: Substitution
Goal: Replace weak component with better alternative Approach: Identify underperforming component, find replacement Example: Replace synchronous API call with async message queue → Improve reliability
Pattern 6: Consolidation
Goal: Reduce overhead by combining similar components Approach: Find redundant or overlapping components, merge them Example: Consolidate 3 microservices doing similar work into 1 → Reduce operational overhead
Pattern 7: Modularization
Goal: Improve maintainability by separating concerns Approach: Identify tightly coupled components, separate with clear interfaces Example: Extract auth logic from monolith into separate service → Enable independent scaling
When NOT to Use This Skill
Skip decomposition-reconstruction if:
- System is already simple (3-5 obvious components, no complex interactions)
- Problem is not about system structure (purely execution issue, not design issue)
- You need creativity/ideation (not analysis) - use brainstorming instead
- System is poorly understood (need discovery/research first, not decomposition)
- Changes are impossible (no point analyzing if you can't act on findings)
Use instead:
- Simple system → Direct analysis or observation
- Execution problem → Project management, process improvement
- Need ideas → Brainstorming, design thinking
- Unknown system → Discovery interviews, research
- Unchangeable → Workaround planning, constraint optimization
Common Patterns by Domain
Software Architecture:
- Decompose: Modules, services, layers, data stores
- Reconstruct for: Microservices migration, performance optimization, reducing coupling
Business Processes:
- Decompose: Steps, decision points, handoffs, approvals
- Reconstruct for: Cycle time reduction, automation opportunities, removing waste
Problem Solving:
- Decompose: Sub-problems, dependencies, unknowns, constraints
- Reconstruct for: Task sequencing, identifying blockers, finding parallelizable work
Cost Optimization:
- Decompose: Cost centers, line items, resource usage
- Reconstruct for: Identifying biggest cost drivers, finding quick wins
User Experience:
- Decompose: User journey stages, interactions, pain points
- Reconstruct for: Simplifying flows, removing friction, improving conversion
System Reliability:
- Decompose: Components, failure modes, dependencies
- Reconstruct for: Identifying single points of failure, improving resilience
Quick Reference
Process:
- Define system and goal → Set boundaries
- Decompose → Break into components and relationships
- Analyze → Measure properties, map interactions
- Reconstruct → Optimize, simplify, or redesign
- Validate → Check against rubric, deliver recommendations
Decomposition strategies:
- Functional (by task), Structural (by component), Data flow, Temporal, Cost/Resource
Reconstruction patterns:
- Bottleneck ID, Simplification, Reordering, Parallelization, Substitution, Consolidation, Modularization
Resources:
- resources/template.md - Structured decomposition process with templates
- resources/methodology.md - Advanced techniques (dependency graphs, critical path analysis, hierarchical decomposition)
- resources/evaluators/rubric_decomposition_reconstruction.json - Quality checklist
Deliverable: decomposition-reconstruction.md with component breakdown, analysis, and recommendations
Decide Fit First
Design Intent
How To Use It
Boundaries And Review