Meta-Cognition Parallel Analysis (Experimental)
Status: Experimental | Version: 0.2.0 | Last Updated: 2025-01-27
This skill tests parallel three-layer cognitive analysis.
Concept
Instead of sequential analysis, this skill launches three parallel analyzers - one for each cognitive layer - then synthesizes their results.
User Question
│
▼
┌─────────────────────────────────────────────────────┐
│ meta-cognition-parallel │
│ (Coordinator) │
└─────────────────────────────────────────────────────┘
│
├─── Layer 1 ──► Language Mechanics ──► L1 Result
│
├─── Layer 2 ──► Design Choices ──► L2 Result
│ ├── Parallel (Agent Mode)
│ │ or Sequential (Inline)
└─── Layer 3 ──► Domain Constraints ──► L3 Result
│
▼
┌─────────────────────────────────────────────────────┐
│ Cross-Layer Synthesis │
│ (In main context with all results) │
└─────────────────────────────────────────────────────┘
│
▼
Domain-Correct Architectural Solution
Usage
/meta-parallel <your Rust question>
Example:
/meta-parallel 我的交易系统报 E0382 错误,应该用 clone 吗?
Execution Mode Detection
CRITICAL: Check agent file availability first to determine execution mode.
Try to read layer analyzer files:
- •
../../agents/layer1-analyzer.md - •
../../agents/layer2-analyzer.md - •
../../agents/layer3-analyzer.md
Agent Mode (Plugin Install) - Parallel Execution
When all layer analyzer files exist at ../../agents/:
Step 1: Parse User Query
Extract from $ARGUMENTS:
- •The original question
- •Any code snippets
- •Domain hints (trading, web, embedded, etc.)
Step 2: Launch Three Parallel Agents
CRITICAL: Launch all three Tasks in a SINGLE message to enable parallel execution.
Read agent files, then launch in parallel:
Task(
subagent_type: "general-purpose",
run_in_background: true,
prompt: <content of ../../agents/layer1-analyzer.md>
+ "\n\n## User Query\n" + $ARGUMENTS
)
Task(
subagent_type: "general-purpose",
run_in_background: true,
prompt: <content of ../../agents/layer2-analyzer.md>
+ "\n\n## User Query\n" + $ARGUMENTS
)
Task(
subagent_type: "general-purpose",
run_in_background: true,
prompt: <content of ../../agents/layer3-analyzer.md>
+ "\n\n## User Query\n" + $ARGUMENTS
)
Step 3: Collect Results
Wait for all three agents to complete. Each returns structured analysis.
Step 4: Cross-Layer Synthesis
With all three results, perform synthesis per template below.
Inline Mode (Skills-only Install) - Sequential Execution
When layer analyzer files are NOT available, execute analysis directly:
Step 1: Parse User Query
Same as Agent Mode - extract question, code, and domain hints from $ARGUMENTS.
Step 2: Execute Layer 1 - Language Mechanics
Analyze the Rust language mechanics involved:
## Layer 1: Language Mechanics **Error/Pattern Identified:** - Error code: E0XXX (if applicable) - Pattern: ownership/borrowing/lifetime/etc. **Root Cause:** [Explain why this error occurs in terms of Rust's ownership model] **Language-Level Solutions:** 1. [Solution 1]: description 2. [Solution 2]: description **Confidence:** HIGH | MEDIUM | LOW **Reasoning:** [Why this confidence level]
Focus areas:
- •Ownership rules (move, copy, borrow)
- •Lifetime annotations
- •Borrowing rules (shared vs mutable)
- •Error codes and their meanings
Step 3: Execute Layer 2 - Design Choices
Analyze the design patterns and trade-offs:
## Layer 2: Design Choices **Design Pattern Context:** - Current approach: [What pattern is being used] - Problem: [Why it conflicts with Rust's rules] **Design Alternatives:** | Pattern | Pros | Cons | When to Use | |---------|------|------|-------------| | Pattern A | ... | ... | ... | | Pattern B | ... | ... | ... | **Recommended Pattern:** [Which pattern fits best and why] **Confidence:** HIGH | MEDIUM | LOW **Reasoning:** [Why this confidence level]
Focus areas:
- •Smart pointer choices (Box, Rc, Arc)
- •Interior mutability patterns (Cell, RefCell, Mutex)
- •Ownership transfer vs sharing
- •Cloning vs references
Step 4: Execute Layer 3 - Domain Constraints
Analyze domain-specific requirements:
## Layer 3: Domain Constraints **Domain Identified:** [trading/fintech | web | CLI | embedded | etc.] **Domain-Specific Requirements:** - [ ] Performance: [requirements] - [ ] Safety: [requirements] - [ ] Concurrency: [requirements] - [ ] Auditability: [requirements] **Domain Best Practices:** 1. [Best practice 1] 2. [Best practice 2] **Constraints on Solution:** - MUST: [hard requirements] - SHOULD: [soft requirements] - AVOID: [anti-patterns for this domain] **Confidence:** HIGH | MEDIUM | LOW **Reasoning:** [Why this confidence level]
Focus areas:
- •Industry requirements (FinTech regulations, web scalability, etc.)
- •Performance constraints
- •Safety and correctness requirements
- •Common patterns in the domain
Step 5: Cross-Layer Synthesis
Combine all three layers:
## Cross-Layer Synthesis ### Layer Results Summary | Layer | Key Finding | Confidence | |-------|-------------|------------| | L1 (Mechanics) | [Summary] | [Level] | | L2 (Design) | [Summary] | [Level] | | L3 (Domain) | [Summary] | [Level] | ### Cross-Layer Reasoning 1. **L3 → L2:** [How domain constraints affect design choice] 2. **L2 → L1:** [How design choice determines mechanism] 3. **L1 ← L3:** [Direct domain impact on language features] ### Synthesized Recommendation **Problem:** [Restated with full context] **Solution:** [Domain-correct architectural solution] **Rationale:** - Domain requires: [L3 constraint] - Design pattern: [L2 pattern] - Mechanism: [L1 implementation] ### Confidence Assessment - **Overall:** HIGH | MEDIUM | LOW - **Limiting Factor:** [Which layer had lowest confidence]
Output Template
Both modes produce the same output format:
# Three-Layer Meta-Cognition Analysis > Query: [User's question] --- ## Layer 1: Language Mechanics [L1 analysis result] --- ## Layer 2: Design Choices [L2 analysis result] --- ## Layer 3: Domain Constraints [L3 analysis result] --- ## Cross-Layer Synthesis ### Reasoning Chain
L3 Domain: [Constraint] ↓ implies L2 Design: [Pattern] ↓ implemented via L1 Mechanism: [Feature]
### Final Recommendation **Do:** [Recommended approach] **Don't:** [What to avoid] **Code Pattern:** ```rust // Recommended implementation
Analysis performed by meta-cognition-parallel v0.2.0 (experimental)
--- ## Test Scenarios ### Test 1: Trading System E0382
/meta-parallel 交易系统报 E0382,trade record 被 move 了
Expected: L3 identifies FinTech constraints → L2 suggests shared immutable → L1 recommends Arc<T> ### Test 2: Web API Concurrency
/meta-parallel Web API 中多个 handler 需要共享数据库连接池
Expected: L3 identifies Web constraints → L2 suggests connection pooling → L1 recommends Arc<Pool> ### Test 3: CLI Tool Config
/meta-parallel CLI 工具如何处理配置文件和命令行参数的优先级
Expected: L3 identifies CLI constraints → L2 suggests config precedence pattern → L1 recommends builder pattern --- ## Error Handling | Error | Cause | Solution | |-------|-------|----------| | Agent files not found | Skills-only install | Use inline mode (sequential) | | Agent timeout | Complex analysis | Wait longer or use inline mode | | Incomplete layer result | Agent issue | Fill in with inline analysis | ## Limitations - **Agent Mode:** Parallel execution, faster but requires plugin install - **Inline Mode:** Sequential execution, slower but works everywhere - Cross-layer synthesis quality depends on result structure - May have higher latency than simple single-layer analysis ## Feedback This is experimental. Please report issues and suggestions to improve the three-layer analysis approach.