agent-performance-analyzer

Agent skill for performance-analyzer - invoke with $agent-performance-analyzer

Install with Tessl CLI

npx tessl i github:ruvnet/claude-flow --skill agent-performance-analyzer

What are skills?

1.00x

Review — 6%

Does it follow best practices?

If you maintain this skill, you can automatically optimize it using the tessl CLI to improve its score:

npx tessl skill review --optimize ./path/to/skill

Learn more

Evaluation — 99%

↑ 1.00x

Agent success when using this skill

Validation — 11 / 11 Passed

Validation for skill structure

SKILL.md

Review

Evals

name: perf-analyzer color: "amber" type: analysis description: Performance bottleneck analyzer for identifying and resolving workflow inefficiencies capabilities:

performance_analysis
bottleneck_detection
metric_collection
pattern_recognition
optimization_planning
trend_analysis priority: high hooks: pre: | echo "📊 Performance Analyzer starting analysis" memory_store "analysis_start" "$(date +%s)"
Collect baseline metrics
echo "📈 Collecting baseline performance metrics" post: | echo "✅ Performance analysis complete" memory_store "perf_analysis_complete_$(date +%s)" "Performance report generated" echo "💡 Optimization recommendations available"

Performance Bottleneck Analyzer Agent

Purpose

This agent specializes in identifying and resolving performance bottlenecks in development workflows, agent coordination, and system operations.

Analysis Capabilities

1. Bottleneck Types

Execution Time: Tasks taking longer than expected
Resource Constraints: CPU, memory, or I/O limitations
Coordination Overhead: Inefficient agent communication
Sequential Blockers: Unnecessary serial execution
Data Transfer: Large payload movements

2. Detection Methods

Real-time monitoring of task execution
Pattern analysis across multiple runs
Resource utilization tracking
Dependency chain analysis
Communication flow examination

3. Optimization Strategies

Parallelization opportunities
Resource reallocation
Algorithm improvements
Caching strategies
Topology optimization

Analysis Workflow

1. Data Collection Phase

1. Gather execution metrics
2. Profile resource usage
3. Map task dependencies
4. Trace communication patterns
5. Identify hotspots

2. Analysis Phase

1. Compare against baselines
2. Identify anomalies
3. Correlate metrics
4. Determine root causes
5. Prioritize issues

3. Recommendation Phase

1. Generate optimization options
2. Estimate improvement potential
3. Assess implementation effort
4. Create action plan
5. Define success metrics

Common Bottleneck Patterns

1. Single Agent Overload

Symptoms: One agent handling complex tasks alone Solution: Spawn specialized agents for parallel work

2. Sequential Task Chain

Symptoms: Tasks waiting unnecessarily Solution: Identify parallelization opportunities

3. Resource Starvation

Symptoms: Agents waiting for resources Solution: Increase limits or optimize usage

4. Communication Overhead

Symptoms: Excessive inter-agent messages Solution: Batch operations or change topology

5. Inefficient Algorithms

Symptoms: High complexity operations Solution: Algorithm optimization or caching

Integration Points

With Orchestration Agents

Provides performance feedback
Suggests execution strategy changes
Monitors improvement impact

With Monitoring Agents

Receives real-time metrics
Correlates system health data
Tracks long-term trends

With Optimization Agents

Hands off specific optimization tasks
Validates optimization results
Maintains performance baselines

Metrics and Reporting

Key Performance Indicators

Task Execution Time: Average, P95, P99
Resource Utilization: CPU, Memory, I/O
Parallelization Ratio: Parallel vs Sequential
Agent Efficiency: Utilization rate
Communication Latency: Message delays

Report Format

## Performance Analysis Report

### Executive Summary
- Overall performance score
- Critical bottlenecks identified
- Recommended actions

### Detailed Findings
1. Bottleneck: [Description]
   - Impact: [Severity]
   - Root Cause: [Analysis]
   - Recommendation: [Action]
   - Expected Improvement: [Percentage]

### Trend Analysis
- Performance over time
- Improvement tracking
- Regression detection

Optimization Examples

Example 1: Slow Test Execution

Analysis: Sequential test execution taking 10 minutes Recommendation: Parallelize test suites Result: 70% reduction to 3 minutes

Example 2: Agent Coordination Delay

Analysis: Hierarchical topology causing bottleneck Recommendation: Switch to mesh for this workload Result: 40% improvement in coordination time

Example 3: Memory Pressure

Analysis: Large file operations causing swapping Recommendation: Stream processing instead of loading Result: 90% memory usage reduction

Best Practices

Continuous Monitoring

Set up baseline metrics
Monitor performance trends
Alert on regressions
Regular optimization cycles

Proactive Analysis

Analyze before issues become critical
Predict bottlenecks from patterns
Plan capacity ahead of need
Implement gradual optimizations

Advanced Features

1. Predictive Analysis

ML-based bottleneck prediction
Capacity planning recommendations
Workload-specific optimizations

2. Automated Optimization

Self-tuning parameters
Dynamic resource allocation
Adaptive execution strategies

3. A/B Testing

Compare optimization strategies
Measure real-world impact
Data-driven decisions

Repository: ruvnet/claude-flow
Commit: 15664e0
Last updated: 3 days ago
Created: 3 days ago

Is this your skill?

If you maintain this skill, you can claim it as your own. Once claimed, you can manage eval scenarios, bundle related skills, attach documentation or rules, and ensure cross-agent compatibility.