| name | swarm-advanced |
| description | Advanced swarm orchestration patterns for research, development, testing, and complex distributed workflows
|
Advanced Swarm Orchestration
Master advanced swarm patterns for distributed research, development, and testing workflows. This skill covers comprehensive orchestration strategies using both MCP tools and CLI commands.
Quick Start
Prerequisites
npm install -g @sparkleideas/ruflo@latest
claude mcp add claude-flow npx @sparkleideas/ruflo@latest mcp start
Basic Pattern
mcp__ruflo__swarm_init({ topology: "mesh", maxAgents: 6 })
mcp__ruflo__agent_spawn({ type: "researcher", name: "Agent 1" })
mcp__ruflo__task_orchestrate({ task: "...", strategy: "parallel" })
Core Concepts
Swarm Topologies
Mesh Topology - Peer-to-peer communication, best for research and analysis
- All agents communicate directly
- High flexibility and resilience
- Use for: Research, analysis, brainstorming
Hierarchical Topology - Coordinator with subordinates, best for development
- Clear command structure
- Sequential workflow support
- Use for: Development, structured workflows
Star Topology - Central coordinator, best for testing
- Centralized control and monitoring
- Parallel execution with coordination
- Use for: Testing, validation, quality assurance
Ring Topology - Sequential processing chain
- Step-by-step processing
- Pipeline workflows
- Use for: Multi-stage processing, data pipelines
Agent Strategies
Adaptive - Dynamic adjustment based on task complexity
Balanced - Equal distribution of work across agents
Specialized - Task-specific agent assignment
Parallel - Maximum concurrent execution
Pattern 1: Research Swarm
Purpose
Deep research through parallel information gathering, analysis, and synthesis.
Architecture
mcp__ruflo__swarm_init({
"topology": "mesh",
"maxAgents": 6,
"strategy": "adaptive"
})
const researchAgents = [
{
type: "researcher",
name: "Web Researcher",
capabilities: ["web-search", "content-extraction", "source-validation"]
},
{
type: "researcher",
name: "Academic Researcher",
capabilities: ["paper-analysis", "citation-tracking", "literature-review"]
},
{
type: "analyst",
name: "Data Analyst",
capabilities: ["data-processing", "statistical-analysis", "visualization"]
},
{
type: "analyst",
name: "Pattern Analyzer",
capabilities: ["trend-detection", "correlation-analysis", "outlier-detection"]
},
{
type: "documenter",
name: "Report Writer",
capabilities: ["synthesis", "technical-writing", "formatting"]
}
]
researchAgents.forEach(agent => {
mcp__ruflo__agent_spawn({
type: agent.type,
name: agent.name,
capabilities: agent.capabilities
})
})
Research Workflow
Phase 1: Information Gathering
mcp__ruflo__parallel_execute({
"tasks": [
{
"id": "web-search",
"command": "search recent publications and articles"
},
{
"id": "academic-search",
"command": "search academic databases and papers"
},
{
"id": "data-collection",
"command": "gather relevant datasets and statistics"
},
{
"id": "expert-search",
"command": "identify domain experts and thought leaders"
}
]
})
mcp__ruflo__memory_usage({
"action": "store",
"key": "research-findings-" + Date.now(),
"value": JSON.stringify(findings),
"namespace": "research",
"ttl": 604800
})
Phase 2: Analysis and Validation
mcp__ruflo__pattern_recognize({
"data": researchData,
"patterns": ["trend", "correlation", "outlier", "emerging-pattern"]
})
mcp__ruflo__cognitive_analyze({
"behavior": "research-synthesis"
})
mcp__ruflo__quality_assess({
"target": "research-sources",
"criteria": ["credibility", "relevance", "recency", "authority"]
})
mcp__ruflo__neural_patterns({
"action": "analyze",
"operation": "fact-checking",
"metadata": { "sources": sourcesArray }
})
Phase 3: Knowledge Management
mcp__ruflo__memory_search({
"pattern": "topic X",
"namespace": "research",
"limit": 20
})
mcp__ruflo__neural_patterns({
"action": "learn",
"operation": "knowledge-graph",
"metadata": {
"topic": "X",
"connections": relatedTopics,
"depth": 3
}
})
mcp__ruflo__memory_usage({
"action": "store",
"key": "knowledge-graph-X",
"value": JSON.stringify(knowledgeGraph),
"namespace": "research/graphs",
"ttl": 2592000
})
Phase 4: Report Generation
mcp__ruflo__task_orchestrate({
"task": "generate comprehensive research report",
"strategy": "sequential",
"priority": "high",
"dependencies": ["gather", "analyze", "validate", "synthesize"]
})
mcp__ruflo__swarm_status({
"swarmId": "research-swarm"
})
mcp__ruflo__workflow_execute({
"workflowId": "research-report-generation",
"params": {
"findings": findings,
"format": "comprehensive",
"sections": ["executive-summary", "methodology", "findings", "analysis", "conclusions", "references"]
}
})
CLI Fallback
npx claude-flow swarm "research AI trends in 2025" \
--strategy research \
--mode distributed \
--max-agents 6 \
--parallel \
--output research-report.md
Pattern 2: Development Swarm
Purpose
Full-stack development through coordinated specialist agents.
Architecture
mcp__ruflo__swarm_init({
"topology": "hierarchical",
"maxAgents": 8,
"strategy": "balanced"
})
const devTeam = [
{ type: "architect", name: "System Architect", role: "coordinator" },
{ type: "coder", name: "Backend Developer", capabilities: ["node", "api", "database"] },
{ type: "coder", name: "Frontend Developer", capabilities: ["react", "ui", "ux"] },
{ type: "coder", name: "Database Engineer", capabilities: ["sql", "nosql", "optimization"] },
{ type: "tester", name: "QA Engineer", capabilities: ["unit", "integration", "e2e"] },
{ type: "reviewer", name: "Code Reviewer", capabilities: ["security", "performance", "best-practices"] },
{ type: "documenter", name: "Technical Writer", capabilities: ["api-docs", "guides", "tutorials"] },
{ type: "monitor", name: "DevOps Engineer", capabilities: ["ci-cd", "deployment", "monitoring"] }
]
devTeam.forEach(member => {
mcp__ruflo__agent_spawn({
type: member.type,
name: member.name,
capabilities: member.capabilities,
swarmId: "dev-swarm"
})
})
Development Workflow
Phase 1: Architecture and Design
mcp__ruflo__task_orchestrate({
"task": "design system architecture for REST API",
"strategy": "sequential",
"priority": "critical",
"assignTo": "System Architect"
})
mcp__ruflo__memory_usage({
"action": "store",
"key": "architecture-decisions",
"value": JSON.stringify(architectureDoc),
"namespace": "development/design"
})
Phase 2: Parallel Implementation
mcp__ruflo__parallel_execute({
"tasks": [
{
"id": "backend-api",
"command": "implement REST API endpoints",
"assignTo": "Backend Developer"
},
{
"id": "frontend-ui",
"command": "build user interface components",
"assignTo": "Frontend Developer"
},
{
"id": "database-schema",
"command": "design and implement database schema",
"assignTo": "Database Engineer"
},
{
"id": "api-documentation",
"command": "create API documentation",
"assignTo": "Technical Writer"
}
]
})
mcp__ruflo__swarm_monitor({
"swarmId": "dev-swarm",
"interval": 5000
})
Phase 3: Testing and Validation
mcp__ruflo__batch_process({
"items": [
{ type: "unit", target: "all-modules" },
{ type: "integration", target: "api-endpoints" },
{ type: "e2e", target: "user-flows" },
{ type: "performance", target: "critical-paths" }
],
"operation": "execute-tests"
})
mcp__ruflo__quality_assess({
"target": "codebase",
"criteria": ["coverage", "complexity", "maintainability", "security"]
})
Phase 4: Review and Deployment
mcp__ruflo__workflow_execute({
"workflowId": "code-review-process",
"params": {
"reviewers": ["Code Reviewer"],
"criteria": ["security", "performance", "best-practices"]
}
})
mcp__ruflo__pipeline_create({
"config": {
"stages": ["build", "test", "security-scan", "deploy"],
"environment": "production"
}
})
CLI Fallback
npx claude-flow swarm "build REST API with authentication" \
--strategy development \
--mode hierarchical \
--monitor \
--output sqlite
Pattern 3: Testing Swarm
Purpose
Comprehensive quality assurance through distributed testing.
Architecture
mcp__ruflo__swarm_init({
"topology": "star",
"maxAgents": 7,
"strategy": "parallel"
})
const testingTeam = [
{
type: "tester",
name: "Unit Test Coordinator",
capabilities: ["unit-testing", "mocking", "coverage", "tdd"]
},
{
type: "tester",
name: "Integration Tester",
capabilities: ["integration", "api-testing", "contract-testing"]
},
{
type: "tester",
name: "E2E Tester",
capabilities: ["e2e", "ui-testing", "user-flows", "selenium"]
},
{
type: "tester",
name: "Performance Tester",
capabilities: ["load-testing", "stress-testing", "benchmarking"]
},
{
type: "monitor",
name: "Security Tester",
capabilities: ["security-testing", "penetration-testing", "vulnerability-scanning"]
},
{
type: "analyst",
name: "Test Analyst",
capabilities: ["coverage-analysis", "test-optimization", "reporting"]
},
{
type: "documenter",
name: "Test Documenter",
capabilities: ["test-documentation", "test-plans", "reports"]
}
]
testingTeam.forEach(tester => {
mcp__ruflo__agent_spawn({
type: tester.type,
name: tester.name,
capabilities: tester.capabilities,
swarmId: "testing-swarm"
})
})
Testing Workflow
Phase 1: Test Planning
mcp__ruflo__quality_assess({
"target": "test-coverage",
"criteria": [
"line-coverage",
"branch-coverage",
"function-coverage",
"edge-cases"
]
})
mcp__ruflo__pattern_recognize({
"data": testScenarios,
"patterns": [
"edge-case",
"boundary-condition",
"error-path",
"happy-path"
]
})
mcp__ruflo__memory_usage({
"action": "store",
"key": "test-plan-" + Date.now(),
"value": JSON.stringify(testPlan),
"namespace": "testing/plans"
})
Phase 2: Parallel Test Execution
mcp__ruflo__parallel_execute({
"tasks": [
{
"id": "unit-tests",
"command": "npm run test:unit",
"assignTo": "Unit Test Coordinator"
},
{
"id": "integration-tests",
"command": "npm run test:integration",
"assignTo": "Integration Tester"
},
{
"id": "e2e-tests",
"command": "npm run test:e2e",
"assignTo": "E2E Tester"
},
{
"id": "performance-tests",
"command": "npm run test:performance",
"assignTo": "Performance Tester"
},
{
"id": "security-tests",
"command": "npm run test:security",
"assignTo": "Security Tester"
}
]
})
mcp__ruflo__batch_process({
"items": testSuites,
"operation": "execute-test-suite"
})
Phase 3: Performance and Security
mcp__ruflo__benchmark_run({
"suite": "comprehensive-performance"
})
mcp__ruflo__bottleneck_analyze({
"component": "application",
"metrics": ["response-time", "throughput", "memory", "cpu"]
})
mcp__ruflo__security_scan({
"target": "application",
"depth": "comprehensive"
})
mcp__ruflo__error_analysis({
"logs": securityScanLogs
})
Phase 4: Monitoring and Reporting
mcp__ruflo__swarm_monitor({
"swarmId": "testing-swarm",
"interval": 2000
})
mcp__ruflo__performance_report({
"format": "detailed",
"timeframe": "current-run"
})
mcp__ruflo__task_results({
"taskId": "test-execution-001"
})
mcp__ruflo__trend_analysis({
"metric": "test-coverage",
"period": "30d"
})
CLI Fallback
npx claude-flow swarm "test application comprehensively" \
--strategy testing \
--mode star \
--parallel \
--timeout 600
Pattern 4: Analysis Swarm
Purpose
Deep code and system analysis through specialized analyzers.
Architecture
mcp__ruflo__swarm_init({
"topology": "mesh",
"maxAgents": 5,
"strategy": "adaptive"
})
const analysisTeam = [
{
type: "analyst",
name: "Code Analyzer",
capabilities: ["static-analysis", "complexity-analysis", "dead-code-detection"]
},
{
type: "analyst",
name: "Security Analyzer",
capabilities: ["security-scan", "vulnerability-detection", "dependency-audit"]
},
{
type: "analyst",
name: "Performance Analyzer",
capabilities: ["profiling", "bottleneck-detection", "optimization"]
},
{
type: "analyst",
name: "Architecture Analyzer",
capabilities: ["dependency-analysis", "coupling-detection", "modularity-assessment"]
},
{
type: "documenter",
name: "Analysis Reporter",
capabilities: ["reporting", "visualization", "recommendations"]
}
]
analysisTeam.forEach(analyst => {
mcp__ruflo__agent_spawn({
type: analyst.type,
name: analyst.name,
capabilities: analyst.capabilities
})
})
Analysis Workflow
mcp__ruflo__parallel_execute({
"tasks": [
{ "id": "analyze-code", "command": "analyze codebase structure and quality" },
{ "id": "analyze-security", "command": "scan for security vulnerabilities" },
{ "id": "analyze-performance", "command": "identify performance bottlenecks" },
{ "id": "analyze-architecture", "command": "assess architectural patterns" }
]
})
mcp__ruflo__performance_report({
"format": "detailed",
"timeframe": "current"
})
mcp__ruflo__cost_analysis({
"timeframe": "30d"
})
Advanced Techniques
Error Handling and Fault Tolerance
mcp__ruflo__daa_fault_tolerance({
"agentId": "all",
"strategy": "auto-recovery"
})
try {
await mcp__ruflo__task_orchestrate({
"task": "complex operation",
"strategy": "parallel",
"priority": "high"
})
} catch (error) {
const status = await mcp__ruflo__swarm_status({})
await mcp__ruflo__error_analysis({
"logs": [error.message]
})
if (status.healthy) {
await mcp__ruflo__task_orchestrate({
"task": "retry failed operation",
"strategy": "sequential"
})
}
}
Memory and State Management
mcp__ruflo__memory_persist({
"sessionId": "swarm-session-001"
})
mcp__ruflo__memory_namespace({
"namespace": "research-swarm",
"action": "create"
})
mcp__ruflo__state_snapshot({
"name": "development-checkpoint-1"
})
mcp__ruflo__context_restore({
"snapshotId": "development-checkpoint-1"
})
mcp__ruflo__memory_backup({
"path": "/workspaces/claude-code-flow/backups/swarm-memory.json"
})
Neural Pattern Learning
mcp__ruflo__neural_train({
"pattern_type": "coordination",
"training_data": JSON.stringify(successfulWorkflows),
"epochs": 50
})
mcp__ruflo__learning_adapt({
"experience": {
"workflow": "research-to-report",
"success": true,
"duration": 3600,
"quality": 0.95
}
})
mcp__ruflo__pattern_recognize({
"data": workflowMetrics,
"patterns": ["bottleneck", "optimization-opportunity", "efficiency-gain"]
})
Workflow Automation
mcp__ruflo__workflow_create({
"name": "full-stack-development",
"steps": [
{ "phase": "design", "agents": ["architect"] },
{ "phase": "implement", "agents": ["backend-dev", "frontend-dev"], "parallel": true },
{ "phase": "test", "agents": ["tester", "security-tester"], "parallel": true },
{ "phase": "review", "agents": ["reviewer"] },
{ "phase": "deploy", "agents": ["devops"] }
],
"triggers": ["on-commit", "scheduled-daily"]
})
mcp__ruflo__automation_setup({
"rules": [
{
"trigger": "file-changed",
"pattern": "*.js",
"action": "run-tests"
},
{
"trigger": "PR-created",
"action": "code-review-swarm"
}
]
})
mcp__ruflo__trigger_setup({
"events": ["code-commit", "PR-merge", "deployment"],
"actions": ["test", "analyze", "document"]
})
Performance Optimization
mcp__ruflo__topology_optimize({
"swarmId": "current-swarm"
})
mcp__ruflo__load_balance({
"swarmId": "development-swarm",
"tasks": taskQueue
})
mcp__ruflo__coordination_sync({
"swarmId": "development-swarm"
})
mcp__ruflo__swarm_scale({
"swarmId": "development-swarm",
"targetSize": 12
})
Monitoring and Metrics
mcp__ruflo__swarm_monitor({
"swarmId": "active-swarm",
"interval": 3000
})
mcp__ruflo__metrics_collect({
"components": ["agents", "tasks", "memory", "performance"]
})
mcp__ruflo__health_check({
"components": ["swarm", "agents", "neural", "memory"]
})
mcp__ruflo__usage_stats({
"component": "swarm-orchestration"
})
mcp__ruflo__trend_analysis({
"metric": "agent-performance",
"period": "7d"
})
Best Practices
1. Choosing the Right Topology
- Mesh: Research, brainstorming, collaborative analysis
- Hierarchical: Structured development, sequential workflows
- Star: Testing, validation, centralized coordination
- Ring: Pipeline processing, staged workflows
2. Agent Specialization
- Assign specific capabilities to each agent
- Avoid overlapping responsibilities
- Use coordination agents for complex workflows
- Leverage memory for agent communication
3. Parallel Execution
- Identify independent tasks for parallelization
- Use sequential execution for dependent tasks
- Monitor resource usage during parallel execution
- Implement proper error handling
4. Memory Management
- Use namespaces to organize memory
- Set appropriate TTL values
- Create regular backups
- Implement state snapshots for checkpoints
5. Monitoring and Optimization
- Monitor swarm health regularly
- Collect and analyze metrics
- Optimize topology based on performance
- Use neural patterns to learn from success
6. Error Recovery
- Implement fault tolerance strategies
- Use auto-recovery mechanisms
- Analyze error patterns
- Create fallback workflows
Real-World Examples
Example 1: AI Research Project
mcp__ruflo__swarm_init({ topology: "mesh", maxAgents: 6 })
Example 2: Full-Stack Application
mcp__ruflo__swarm_init({ topology: "hierarchical", maxAgents: 8 })
Example 3: Security Audit
mcp__ruflo__swarm_init({ topology: "star", maxAgents: 5 })
Example 4: Performance Optimization
mcp__ruflo__swarm_init({ topology: "mesh", maxAgents: 4 })
Troubleshooting
Common Issues
Issue: Swarm agents not coordinating properly
Solution: Check topology selection, verify memory usage, enable monitoring
Issue: Parallel execution failing
Solution: Verify task dependencies, check resource limits, implement error handling
Issue: Memory persistence not working
Solution: Verify namespaces, check TTL settings, ensure backup configuration
Issue: Performance degradation
Solution: Optimize topology, reduce agent count, analyze bottlenecks
Related Skills
sparc-methodology - Systematic development workflow
github-integration - Repository management and automation
neural-patterns - AI-powered coordination optimization
memory-management - Cross-session state persistence
References
Version: 2.0.0
Last Updated: 2025-10-19
Skill Level: Advanced
Estimated Learning Time: 2-3 hours