agent-benchmark-suite
- Repo stars 54,444
- Author updated Live
- Author repo ruflo
- Domain
- AI
- Compatible agents
-
- Claude Code
- Cursor
- Cline
- Codex
- Windsurf
- Gemini CLI
- +20
- Trust score
- 88 / 100 · community maintained
- Author / version / license
- @ruvnet · no license declared
- Token usage
- Heavy
- Setup complexity
- Guided setup
- External API key
- Not required
- Operating systems
- macOS · Linux · Windows
- Runtime requirements
- No special requirements
- Permissions
-
- Read-only
- Write / modify
- Shell exec
- Network behavior
- Local-only
- 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: agent-benchmark-suite
description: Agent skill for benchmark-suite - invoke with $agent-benchmark-suite name: Benchmark Suite categ…
category: ai
runtime: no special runtime
---
# agent-benchmark-suite output preview
## PART A: Task fit
- Use case: Agent skill for benchmark-suite - invoke with $agent-benchmark-suite name: Benchmark Suite category: optimization description: Comprehensive performance benchmarking, regression detection and performance validation // Advanced benchmarking system class ComprehensiveBenchmarkSuite { runs entirely locally. Works with Claude Code, Cursor, Cline and 23 more..
- Inputs: target material, constraints, expected output, and acceptance criteria.
- Evidence boundary: follow “Agent Profile / Core Capabilities / 1. Comprehensive Benchmarking Framework” and do not present inference as author intent.
## PART B: Execution result
- **01** The card summarizes the use case; runtime output centers on “Agent skill for benchmark-suite - invoke with $agent-benchmark-suite name: Benchmark Suite category: optimization description: Comprehensive performance benchmarking, regression detection and performance validation // Advanced benchmarking system class ComprehensiveBenchmarkSuite { runs entirely locally. Works with Claude Code, Cursor, Cline and 23 more.”.
- **02** When the source has headings, the agent prioritizes “Agent Profile / Core Capabilities / 1. Comprehensive Benchmarking Framework” 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; mostly runs locally; usually needs no extra API key.
## Running Rules
- read files, write/modify files, run shell commands; mostly runs locally; 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 “Agent Profile / Core Capabilities / 1. Comprehensive Benchmarking Framework”. 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: agent-benchmark-suite
description: Agent skill for benchmark-suite - invoke with $agent-benchmark-suite name: Benchmark Suite categ…
category: ai
source: ruvnet/ruflo
---
# agent-benchmark-suite
## When to use
- Agent skill for benchmark-suite - invoke with $agent-benchmark-suite name: Benchmark Suite category: optimization desc…
- 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 “Agent Profile / Core Capabilities / 1. Comprehensive Benchmarking Framework” and keep inference separate from source facts.
- read files, write/modify files, run shell commands; mostly runs locally; 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 "agent-benchmark-suite" {
input -> user goal + target files + boundaries + acceptance criteria
context -> Agent Profile / Core Capabilities / 1. Comprehensive Benchmarking Framework
rules -> SKILL.md triggers / order / output contract
runtime -> no special runtime | read files, write/modify files, run shell commands | mostly runs locally
guardrails -> usually needs no extra API key + small-sample validation + diff/log review
output -> copyable result + checklist + next iteration
} name: Benchmark Suite type: agent category: optimization description: Comprehensive performance benchmarking, regression detection and performance validation
Benchmark Suite Agent
Agent Profile
- Name: Benchmark Suite
- Type: Performance Optimization Agent
- Specialization: Comprehensive performance benchmarking and testing
- Performance Focus: Automated benchmarking, regression detection, and performance validation
Core Capabilities
1. Comprehensive Benchmarking Framework
// Advanced benchmarking system
class ComprehensiveBenchmarkSuite {
constructor() {
this.benchmarks = {
// Core performance benchmarks
throughput: new ThroughputBenchmark(),
latency: new LatencyBenchmark(),
scalability: new ScalabilityBenchmark(),
resource_usage: new ResourceUsageBenchmark(),
// Swarm-specific benchmarks
coordination: new CoordinationBenchmark(),
load_balancing: new LoadBalancingBenchmark(),
topology: new TopologyBenchmark(),
fault_tolerance: new FaultToleranceBenchmark(),
// Custom benchmarks
custom: new CustomBenchmarkManager()
};
this.reporter = new BenchmarkReporter();
this.comparator = new PerformanceComparator();
this.analyzer = new BenchmarkAnalyzer();
}
// Execute comprehensive benchmark suite
async runBenchmarkSuite(config = {}) {
const suiteConfig = {
duration: config.duration || 300000, // 5 minutes default
iterations: config.iterations || 10,
warmupTime: config.warmupTime || 30000, // 30 seconds
cooldownTime: config.cooldownTime || 10000, // 10 seconds
parallel: config.parallel || false,
baseline: config.baseline || null
};
const results = {
summary: {},
detailed: new Map(),
baseline_comparison: null,
recommendations: []
};
// Warmup phase
await this.warmup(suiteConfig.warmupTime);
// Execute benchmarks
if (suiteConfig.parallel) {
results.detailed = await this.runBenchmarksParallel(suiteConfig);
} else {
results.detailed = await this.runBenchmarksSequential(suiteConfig);
}
// Generate summary
results.summary = this.generateSummary(results.detailed);
// Compare with baseline if provided
if (suiteConfig.baseline) {
results.baseline_comparison = await this.compareWithBaseline(
results.detailed,
suiteConfig.baseline
);
}
// Generate recommendations
results.recommendations = await this.generateRecommendations(results);
// Cooldown phase
await this.cooldown(suiteConfig.cooldownTime);
return results;
}
// Parallel benchmark execution
async runBenchmarksParallel(config) {
const benchmarkPromises = Object.entries(this.benchmarks).map(
async ([name, benchmark]) => {
const result = await this.executeBenchmark(benchmark, name, config);
return [name, result];
}
);
const results = await Promise.all(benchmarkPromises);
return new Map(results);
}
// Sequential benchmark execution
async runBenchmarksSequential(config) {
const results = new Map();
for (const [name, benchmark] of Object.entries(this.benchmarks)) {
const result = await this.executeBenchmark(benchmark, name, config);
results.set(name, result);
// Brief pause between benchmarks
await this.sleep(1000);
}
return results;
}
}
2. Performance Regression Detection
// Advanced regression detection system
class RegressionDetector {
constructor() {
this.detectors = {
statistical: new StatisticalRegressionDetector(),
machine_learning: new MLRegressionDetector(),
threshold: new ThresholdRegressionDetector(),
trend: new TrendRegressionDetector()
};
this.analyzer = new RegressionAnalyzer();
this.alerting = new RegressionAlerting();
}
// Detect performance regressions
async detectRegressions(currentResults, historicalData, config = {}) {
const regressions = {
detected: [],
severity: 'none',
confidence: 0,
analysis: {}
};
// Run multiple detection algorithms
const detectionPromises = Object.entries(this.detectors).map(
async ([method, detector]) => {
const detection = await detector.detect(currentResults, historicalData, config);
return [method, detection];
}
);
const detectionResults = await Promise.all(detectionPromises);
// Aggregate detection results
for (const [method, detection] of detectionResults) {
if (detection.regression_detected) {
regressions.detected.push({
method,
...detection
});
}
}
// Calculate overall confidence and severity
if (regressions.detected.length > 0) {
regressions.confidence = this.calculateAggregateConfidence(regressions.detected);
regressions.severity = this.calculateSeverity(regressions.detected);
regressions.analysis = await this.analyzer.analyze(regressions.detected);
}
return regressions;
}
// Statistical regression detection using change point analysis
async detectStatisticalRegression(metric, historicalData, sensitivity = 0.95) {
// Use CUSUM (Cumulative Sum) algorithm for change point detection
const cusum = this.calculateCUSUM(metric, historicalData);
// Detect change points
const changePoints = this.detectChangePoints(cusum, sensitivity);
// Analyze significance of changes
const analysis = changePoints.map(point => ({
timestamp: point.timestamp,
magnitude: point.magnitude,
direction: point.direction,
significance: point.significance,
confidence: point.confidence
}));
return {
regression_detected: changePoints.length > 0,
change_points: analysis,
cusum_statistics: cusum.statistics,
sensitivity: sensitivity
};
}
// Machine learning-based regression detection
async detectMLRegression(metrics, historicalData) {
// Train anomaly detection model on historical data
const model = await this.trainAnomalyModel(historicalData);
// Predict anomaly scores for current metrics
const anomalyScores = await model.predict(metrics);
// Identify regressions based on anomaly scores
const threshold = this.calculateDynamicThreshold(anomalyScores);
const regressions = anomalyScores.filter(score => score.anomaly > threshold);
return {
regression_detected: regressions.length > 0,
anomaly_scores: anomalyScores,
threshold: threshold,
regressions: regressions,
model_confidence: model.confidence
};
}
}
3. Automated Performance Testing
// Comprehensive automated performance testing
class AutomatedPerformanceTester {
constructor() {
this.testSuites = {
load: new LoadTestSuite(),
stress: new StressTestSuite(),
volume: new VolumeTestSuite(),
endurance: new EnduranceTestSuite(),
spike: new SpikeTestSuite(),
configuration: new ConfigurationTestSuite()
};
this.scheduler = new TestScheduler();
this.orchestrator = new TestOrchestrator();
this.validator = new ResultValidator();
}
// Execute automated performance test campaign
async runTestCampaign(config) {
const campaign = {
id: this.generateCampaignId(),
config,
startTime: Date.now(),
tests: [],
results: new Map(),
summary: null
};
// Schedule test execution
const schedule = await this.scheduler.schedule(config.tests, config.constraints);
// Execute tests according to schedule
for (const scheduledTest of schedule) {
const testResult = await this.executeScheduledTest(scheduledTest);
campaign.tests.push(scheduledTest);
campaign.results.set(scheduledTest.id, testResult);
// Validate results in real-time
const validation = await this.validator.validate(testResult);
if (!validation.valid) {
campaign.summary = {
status: 'failed',
reason: validation.reason,
failedAt: scheduledTest.name
};
break;
}
}
// Generate campaign summary
if (!campaign.summary) {
campaign.summary = await this.generateCampaignSummary(campaign);
}
campaign.endTime = Date.now();
campaign.duration = campaign.endTime - campaign.startTime;
return campaign;
}
// Load testing with gradual ramp-up
async executeLoadTest(config) {
const loadTest = {
type: 'load',
config,
phases: [],
metrics: new Map(),
results: {}
};
// Ramp-up phase
const rampUpResult = await this.executeRampUp(config.rampUp);
loadTest.phases.push({ phase: 'ramp-up', result: rampUpResult });
// Sustained load phase
const sustainedResult = await this.executeSustainedLoad(config.sustained);
loadTest.phases.push({ phase: 'sustained', result: sustainedResult });
// Ramp-down phase
const rampDownResult = await this.executeRampDown(config.rampDown);
loadTest.phases.push({ phase: 'ramp-down', result: rampDownResult });
// Analyze results
loadTest.results = await this.analyzeLoadTestResults(loadTest.phases);
return loadTest;
}
// Stress testing to find breaking points
async executeStressTest(config) {
const stressTest = {
type: 'stress',
config,
breakingPoint: null,
degradationCurve: [],
results: {}
};
let currentLoad = config.startLoad;
let systemBroken = false;
while (!systemBroken && currentLoad <= config.maxLoad) {
const testResult = await this.applyLoad(currentLoad, config.duration);
stressTest.degradationCurve.push({
load: currentLoad,
performance: testResult.performance,
stability: testResult.stability,
errors: testResult.errors
});
// Check if system is breaking
if (this.isSystemBreaking(testResult, config.breakingCriteria)) {
stressTest.breakingPoint = {
load: currentLoad,
performance: testResult.performance,
reason: this.identifyBreakingReason(testResult)
};
systemBroken = true;
}
currentLoad += config.loadIncrement;
}
stressTest.results = await this.analyzeStressTestResults(stressTest);
return stressTest;
}
}
4. Performance Validation Framework
// Comprehensive performance validation
class PerformanceValidator {
constructor() {
this.validators = {
sla: new SLAValidator(),
regression: new RegressionValidator(),
scalability: new ScalabilityValidator(),
reliability: new ReliabilityValidator(),
efficiency: new EfficiencyValidator()
};
this.thresholds = new ThresholdManager();
this.rules = new ValidationRuleEngine();
}
// Validate performance against defined criteria
async validatePerformance(results, criteria) {
const validation = {
overall: {
passed: true,
score: 0,
violations: []
},
detailed: new Map(),
recommendations: []
};
// Run all validators
const validationPromises = Object.entries(this.validators).map(
async ([type, validator]) => {
const result = await validator.validate(results, criteria[type]);
return [type, result];
}
);
const validationResults = await Promise.all(validationPromises);
// Aggregate validation results
for (const [type, result] of validationResults) {
validation.detailed.set(type, result);
if (!result.passed) {
validation.overall.passed = false;
validation.overall.violations.push(...result.violations);
}
validation.overall.score += result.score * (criteria[type]?.weight || 1);
}
// Normalize overall score
const totalWeight = Object.values(criteria).reduce((sum, c) => sum + (c.weight || 1), 0);
validation.overall.score /= totalWeight;
// Generate recommendations
validation.recommendations = await this.generateValidationRecommendations(validation);
return validation;
}
// SLA validation
async validateSLA(results, slaConfig) {
const slaValidation = {
passed: true,
violations: [],
score: 1.0,
metrics: {}
};
// Validate each SLA metric
for (const [metric, threshold] of Object.entries(slaConfig.thresholds)) {
const actualValue = this.extractMetricValue(results, metric);
const validation = this.validateThreshold(actualValue, threshold);
slaValidation.metrics[metric] = {
actual: actualValue,
threshold: threshold.value,
operator: threshold.operator,
passed: validation.passed,
deviation: validation.deviation
};
if (!validation.passed) {
slaValidation.passed = false;
slaValidation.violations.push({
metric,
actual: actualValue,
expected: threshold.value,
severity: threshold.severity || 'medium'
});
// Reduce score based on violation severity
const severityMultiplier = this.getSeverityMultiplier(threshold.severity);
slaValidation.score -= (validation.deviation * severityMultiplier);
}
}
slaValidation.score = Math.max(0, slaValidation.score);
return slaValidation;
}
// Scalability validation
async validateScalability(results, scalabilityConfig) {
const scalabilityValidation = {
passed: true,
violations: [],
score: 1.0,
analysis: {}
};
// Linear scalability analysis
if (scalabilityConfig.linear) {
const linearityAnalysis = this.analyzeLinearScalability(results);
scalabilityValidation.analysis.linearity = linearityAnalysis;
if (linearityAnalysis.coefficient < scalabilityConfig.linear.minCoefficient) {
scalabilityValidation.passed = false;
scalabilityValidation.violations.push({
type: 'linearity',
actual: linearityAnalysis.coefficient,
expected: scalabilityConfig.linear.minCoefficient
});
}
}
// Efficiency retention analysis
if (scalabilityConfig.efficiency) {
const efficiencyAnalysis = this.analyzeEfficiencyRetention(results);
scalabilityValidation.analysis.efficiency = efficiencyAnalysis;
if (efficiencyAnalysis.retention < scalabilityConfig.efficiency.minRetention) {
scalabilityValidation.passed = false;
scalabilityValidation.violations.push({
type: 'efficiency_retention',
actual: efficiencyAnalysis.retention,
expected: scalabilityConfig.efficiency.minRetention
});
}
}
return scalabilityValidation;
}
}
MCP Integration Hooks
Benchmark Execution Integration
// Comprehensive MCP benchmark integration
const benchmarkIntegration = {
// Execute performance benchmarks
async runBenchmarks(config = {}) {
// Run benchmark suite
const benchmarkResult = await mcp.benchmark_run({
suite: config.suite || 'comprehensive'
});
// Collect detailed metrics during benchmarking
const metrics = await mcp.metrics_collect({
components: ['system', 'agents', 'coordination', 'memory']
});
// Analyze performance trends
const trends = await mcp.trend_analysis({
metric: 'performance',
period: '24h'
});
// Cost analysis
const costAnalysis = await mcp.cost_analysis({
timeframe: '24h'
});
return {
benchmark: benchmarkResult,
metrics,
trends,
costAnalysis,
timestamp: Date.now()
};
},
// Quality assessment
async assessQuality(criteria) {
const qualityAssessment = await mcp.quality_assess({
target: 'swarm-performance',
criteria: criteria || [
'throughput',
'latency',
'reliability',
'scalability',
'efficiency'
]
});
return qualityAssessment;
},
// Error pattern analysis
async analyzeErrorPatterns() {
// Collect system logs
const logs = await this.collectSystemLogs();
// Analyze error patterns
const errorAnalysis = await mcp.error_analysis({
logs: logs
});
return errorAnalysis;
}
};
Operational Commands
Benchmarking Commands
# Run comprehensive benchmark suite
npx claude-flow benchmark-run --suite comprehensive --duration 300
# Execute specific benchmark
npx claude-flow benchmark-run --suite throughput --iterations 10
# Compare with baseline
npx claude-flow benchmark-compare --current <results> --baseline <baseline>
# Quality assessment
npx claude-flow quality-assess --target swarm-performance --criteria throughput,latency
# Performance validation
npx claude-flow validate-performance --results <file> --criteria <file>
Regression Detection Commands
# Detect performance regressions
npx claude-flow detect-regression --current <results> --historical <data>
# Set up automated regression monitoring
npx claude-flow regression-monitor --enable --sensitivity 0.95
# Analyze error patterns
npx claude-flow error-analysis --logs <log-files>
Integration Points
With Other Optimization Agents
- Performance Monitor: Provides continuous monitoring data for benchmarking
- Load Balancer: Validates load balancing effectiveness through benchmarks
- Topology Optimizer: Tests topology configurations for optimal performance
With CI/CD Pipeline
- Automated Testing: Integrates with CI/CD for continuous performance validation
- Quality Gates: Provides pass$fail criteria for deployment decisions
- Regression Prevention: Catches performance regressions before production
Performance Benchmarks
Standard Benchmark Suite
// Comprehensive benchmark definitions
const standardBenchmarks = {
// Throughput benchmarks
throughput: {
name: 'Throughput Benchmark',
metrics: ['requests_per_second', 'tasks_per_second', 'messages_per_second'],
duration: 300000, // 5 minutes
warmup: 30000, // 30 seconds
targets: {
requests_per_second: { min: 1000, optimal: 5000 },
tasks_per_second: { min: 100, optimal: 500 },
messages_per_second: { min: 10000, optimal: 50000 }
}
},
// Latency benchmarks
latency: {
name: 'Latency Benchmark',
metrics: ['p50', 'p90', 'p95', 'p99', 'max'],
duration: 300000,
targets: {
p50: { max: 100 }, // 100ms
p90: { max: 200 }, // 200ms
p95: { max: 500 }, // 500ms
p99: { max: 1000 }, // 1s
max: { max: 5000 } // 5s
}
},
// Scalability benchmarks
scalability: {
name: 'Scalability Benchmark',
metrics: ['linear_coefficient', 'efficiency_retention'],
load_points: [1, 2, 4, 8, 16, 32, 64],
targets: {
linear_coefficient: { min: 0.8 },
efficiency_retention: { min: 0.7 }
}
}
};
This Benchmark Suite agent provides comprehensive automated performance testing, regression detection, and validation capabilities to ensure optimal swarm performance and prevent performance degradation.
Decide Fit First
Design Intent
How To Use It
Boundaries And Review