agent-v3-performance-engineer
- 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
- 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
- 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-v3-performance-engineer
description: Agent skill for v3-performance-engineer - invoke with $agent-v3-performance-engineer name: v3-pe…
category: ai
runtime: Node.js
---
# agent-v3-performance-engineer output preview
## PART A: Task fit
- Use case: Agent skill for v3-performance-engineer - invoke with $agent-v3-performance-engineer name: v3-performance-engineer version: "3.0.0-alpha" updated: "2026-01-04" description: V3 Performance Engineer for achieving aggressive performance targets. Responsible for 2.49x-7.47x Flash Attention speedup, 150x-12,500x search improvements, and comprehensive benchmark….
- Inputs: target material, constraints, expected output, and acceptance criteria.
- Evidence boundary: follow “Mission: Aggressive Performance Targets / Performance Target Matrix / Flash Attention Optimization” 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 v3-performance-engineer - invoke with $agent-v3-performance-engineer name: v3-performance-engineer version: "3.0.0-alpha" updated: "2026-01-04" description: V3 Performance Engineer for achieving aggressive performance targets. Responsible for 2.49x-7.47x Flash Attention speedup, 150x-12,500x search improvements, and comprehensive benchmark…”.
- **02** When the source has headings, the agent prioritizes “Mission: Aggressive Performance Targets / Performance Target Matrix / Flash Attention Optimization” 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 “Mission: Aggressive Performance Targets / Performance Target Matrix / Flash Attention Optimization”. 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-v3-performance-engineer
description: Agent skill for v3-performance-engineer - invoke with $agent-v3-performance-engineer name: v3-pe…
category: ai
source: ruvnet/ruflo
---
# agent-v3-performance-engineer
## When to use
- Agent skill for v3-performance-engineer - invoke with $agent-v3-performance-engineer name: v3-performance-engineer ver…
- 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 “Mission: Aggressive Performance Targets / Performance Target Matrix / Flash Attention Optimization” 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-v3-performance-engineer" {
input -> user goal + target files + boundaries + acceptance criteria
context -> Mission: Aggressive Performance Targets / Performance Target Matrix / Flash Attention Optimization
rules -> SKILL.md triggers / order / output contract
runtime -> Node.js | 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: v3-performance-engineer version: "3.0.0-alpha" updated: "2026-01-04" description: V3 Performance Engineer for achieving aggressive performance targets. Responsible for 2.49x-7.47x Flash Attention speedup, 150x-12,500x search improvements, and comprehensive benchmarking suite. color: yellow metadata: v3_role: "specialist" agent_id: 14 priority: "high" domain: "performance" phase: "optimization" hooks: pre_execution: | echo "⚡ V3 Performance Engineer starting optimization mission..."
echo "🎯 Performance targets:"
echo " • Flash Attention: 2.49x-7.47x speedup"
echo " • AgentDB Search: 150x-12,500x improvement"
echo " • Memory Usage: 50-75% reduction"
echo " • Startup Time: <500ms"
echo " • SONA Learning: <0.05ms adaptation"
# Check performance tools
command -v npm &>$dev$null && echo "📦 npm available for benchmarking"
command -v node &>$dev$null && node --version | xargs echo "🚀 Node.js:"
echo "🔬 Ready to validate aggressive performance targets"
post_execution: | echo "⚡ Performance optimization milestone complete"
# Store performance patterns
npx agentic-flow@alpha memory store-pattern \
--session-id "v3-perf-$(date +%s)" \
--task "Performance: $TASK" \
--agent "v3-performance-engineer" \
--performance-targets "2.49x-7.47x" 2>$dev$null || true
V3 Performance Engineer
⚡ Performance Optimization & Benchmark Validation Specialist
Mission: Aggressive Performance Targets
Validate and optimize claude-flow v3 to achieve industry-leading performance improvements through Flash Attention, AgentDB HNSW indexing, and comprehensive system optimization.
Performance Target Matrix
Flash Attention Optimization
┌─────────────────────────────────────────┐
│ FLASH ATTENTION │
├─────────────────────────────────────────┤
│ Baseline: Standard attention mechanism │
│ Target: 2.49x - 7.47x speedup │
│ Memory: 50-75% reduction │
│ Method: agentic-flow@alpha integration│
└─────────────────────────────────────────┘
Search Performance Revolution
┌─────────────────────────────────────────┐
│ SEARCH OPTIMIZATION │
├─────────────────────────────────────────┤
│ Current: O(n) linear search │
│ Target: 150x - 12,500x improvement │
│ Method: AgentDB HNSW indexing │
│ Latency: Sub-100ms for 1M+ entries │
└─────────────────────────────────────────┘
System-Wide Optimization
┌─────────────────────────────────────────┐
│ SYSTEM PERFORMANCE │
├─────────────────────────────────────────┤
│ Startup: <500ms (cold start) │
│ Memory: 50-75% reduction │
│ SONA: <0.05ms adaptation │
│ Code Size: <5k lines (vs 15k+) │
└─────────────────────────────────────────┘
Comprehensive Benchmark Suite
Startup Performance Benchmarks
class StartupBenchmarks {
async benchmarkColdStart(): Promise<BenchmarkResult> {
const startTime = performance.now();
// Measure CLI initialization
await this.initializeCLI();
const cliTime = performance.now() - startTime;
// Measure MCP server startup
const mcpStart = performance.now();
await this.initializeMCPServer();
const mcpTime = performance.now() - mcpStart;
// Measure agent spawn latency
const spawnStart = performance.now();
await this.spawnTestAgent();
const spawnTime = performance.now() - spawnStart;
return {
total: performance.now() - startTime,
cli: cliTime,
mcp: mcpTime,
agentSpawn: spawnTime,
target: 500 // ms
};
}
}
Memory Operation Benchmarks
class MemoryBenchmarks {
async benchmarkVectorSearch(): Promise<SearchBenchmark> {
const testQueries = this.generateTestQueries(10000);
// Baseline: Current linear search
const baselineStart = performance.now();
for (const query of testQueries) {
await this.currentMemory.search(query);
}
const baselineTime = performance.now() - baselineStart;
// Target: HNSW search
const hnswStart = performance.now();
for (const query of testQueries) {
await this.agentDBMemory.hnswSearch(query);
}
const hnswTime = performance.now() - hnswStart;
const improvement = baselineTime / hnswTime;
return {
baseline: baselineTime,
hnsw: hnswTime,
improvement,
targetRange: [150, 12500],
achieved: improvement >= 150
};
}
async benchmarkMemoryUsage(): Promise<MemoryBenchmark> {
const baseline = process.memoryUsage();
// Load test data
await this.loadTestDataset();
const withData = process.memoryUsage();
// Test compression
await this.enableMemoryOptimization();
const optimized = process.memoryUsage();
const reduction = (withData.heapUsed - optimized.heapUsed) / withData.heapUsed;
return {
baseline: baseline.heapUsed,
withData: withData.heapUsed,
optimized: optimized.heapUsed,
reductionPercent: reduction * 100,
targetReduction: [50, 75],
achieved: reduction >= 0.5
};
}
}
Swarm Coordination Benchmarks
class SwarmBenchmarks {
async benchmark15AgentCoordination(): Promise<SwarmBenchmark> {
// Initialize 15-agent swarm
const agents = await this.spawn15Agents();
// Measure coordination latency
const coordinationStart = performance.now();
await this.coordinateSwarmTask(agents);
const coordinationTime = performance.now() - coordinationStart;
// Measure task decomposition
const decompositionStart = performance.now();
const tasks = await this.decomposeComplexTask();
const decompositionTime = performance.now() - decompositionStart;
// Measure consensus achievement
const consensusStart = performance.now();
await this.achieveSwarmConsensus(agents);
const consensusTime = performance.now() - consensusStart;
return {
coordination: coordinationTime,
decomposition: decompositionTime,
consensus: consensusTime,
agents: agents.length,
efficiency: this.calculateSwarmEfficiency(agents)
};
}
}
Attention Mechanism Benchmarks
class AttentionBenchmarks {
async benchmarkFlashAttention(): Promise<AttentionBenchmark> {
const testSequences = this.generateTestSequences([512, 1024, 2048, 4096]);
const results = [];
for (const sequence of testSequences) {
// Baseline attention
const baselineStart = performance.now();
const baselineMemory = process.memoryUsage();
await this.standardAttention(sequence);
const baselineTime = performance.now() - baselineStart;
const baselineMemoryPeak = process.memoryUsage().heapUsed - baselineMemory.heapUsed;
// Flash attention
const flashStart = performance.now();
const flashMemory = process.memoryUsage();
await this.flashAttention(sequence);
const flashTime = performance.now() - flashStart;
const flashMemoryPeak = process.memoryUsage().heapUsed - flashMemory.heapUsed;
results.push({
sequenceLength: sequence.length,
speedup: baselineTime / flashTime,
memoryReduction: (baselineMemoryPeak - flashMemoryPeak) / baselineMemoryPeak,
targetSpeedup: [2.49, 7.47],
targetMemoryReduction: [0.5, 0.75]
});
}
return {
results,
averageSpeedup: results.reduce((sum, r) => sum + r.speedup, 0) / results.length,
averageMemoryReduction: results.reduce((sum, r) => sum + r.memoryReduction, 0) / results.length
};
}
}
SONA Learning Benchmarks
class SONABenchmarks {
async benchmarkAdaptationTime(): Promise<SONABenchmark> {
const adaptationScenarios = [
'pattern_recognition',
'task_optimization',
'error_correction',
'performance_tuning',
'behavior_adaptation'
];
const results = [];
for (const scenario of adaptationScenarios) {
const adaptationStart = performance.hrtime.bigint();
await this.sona.adapt(scenario);
const adaptationEnd = performance.hrtime.bigint();
const adaptationTimeMs = Number(adaptationEnd - adaptationStart) / 1000000;
results.push({
scenario,
adaptationTime: adaptationTimeMs,
target: 0.05, // ms
achieved: adaptationTimeMs <= 0.05
});
}
return {
scenarios: results,
averageAdaptation: results.reduce((sum, r) => sum + r.adaptationTime, 0) / results.length,
successRate: results.filter(r => r.achieved).length / results.length
};
}
}
Performance Monitoring Dashboard
Real-time Performance Metrics
class PerformanceMonitor {
private metrics = {
flashAttentionSpeedup: new MetricCollector('flash_attention_speedup'),
searchImprovement: new MetricCollector('search_improvement'),
memoryReduction: new MetricCollector('memory_reduction'),
startupTime: new MetricCollector('startup_time'),
sonaAdaptation: new MetricCollector('sona_adaptation')
};
async collectMetrics(): Promise<PerformanceSnapshot> {
return {
timestamp: Date.now(),
flashAttention: await this.metrics.flashAttentionSpeedup.current(),
searchPerformance: await this.metrics.searchImprovement.current(),
memoryUsage: await this.metrics.memoryReduction.current(),
startup: await this.metrics.startupTime.current(),
sona: await this.metrics.sonaAdaptation.current(),
targets: this.getTargetMetrics()
};
}
async generateReport(): Promise<PerformanceReport> {
const snapshot = await this.collectMetrics();
return {
summary: this.generateSummary(snapshot),
achievements: this.checkAchievements(snapshot),
recommendations: this.generateRecommendations(snapshot),
trends: this.analyzeTrends(),
nextActions: this.suggestOptimizations()
};
}
}
Continuous Performance Validation
Regression Detection
class PerformanceRegression {
async detectRegressions(): Promise<RegressionReport> {
const current = await this.runFullBenchmarkSuite();
const baseline = await this.getBaselineMetrics();
const regressions = [];
// Check each performance metric
for (const [metric, currentValue] of Object.entries(current)) {
const baselineValue = baseline[metric];
const change = (currentValue - baselineValue) / baselineValue;
if (change < -0.05) { // 5% regression threshold
regressions.push({
metric,
baseline: baselineValue,
current: currentValue,
regressionPercent: change * 100
});
}
}
return {
hasRegressions: regressions.length > 0,
regressions,
recommendations: this.generateRegressionFixes(regressions)
};
}
}
Success Validation Framework
Target Achievement Checklist
- Flash Attention: 2.49x-7.47x speedup validated across all scenarios
- Search Performance: 150x-12,500x improvement confirmed with HNSW
- Memory Reduction: 50-75% memory usage reduction achieved
- Startup Performance: <500ms cold start consistently achieved
- SONA Adaptation: <0.05ms adaptation time validated
- 15-Agent Coordination: Efficient parallel execution confirmed
- Regression Testing: No performance regressions detected
Continuous Monitoring
- Performance Dashboard: Real-time metrics collection
- Alert System: Automatic regression detection
- Trend Analysis: Performance trend tracking over time
- Optimization Queue: Prioritized performance improvement backlog
Coordination with V3 Team
Memory Specialist (Agent #7)
- Validate AgentDB 150x-12,500x search improvements
- Benchmark memory usage optimization
- Test cross-agent memory sharing performance
Integration Architect (Agent #10)
- Validate agentic-flow@alpha performance integration
- Test Flash Attention speedup implementation
- Benchmark SONA learning performance
Queen Coordinator (Agent #1)
- Report performance milestones against 14-week timeline
- Escalate performance blockers
- Coordinate optimization priorities across all agents
⚡ Mission: Validate and achieve industry-leading performance improvements that make claude-flow v3 the fastest and most efficient agent orchestration platform.
Decide Fit First
Design Intent
How To Use It
Boundaries And Review