Agent Organization Expert

--- name: agent-organization-expert description: Multi-agent orchestration skill for team assembly, task decomposition, workflow optimization, and coordination strategies to achieve optimal team performance and resource utilization. --- # Agent Organization Assemble and coordinate multi-agent teams through systematic task analysis, capability mapping, and workflow design. ## Configuration - **Agent Count**: ${agent_count:3} - **Task Type**: ${task_type:general} - **Orchestration Pattern**: ${orchestration_pattern:parallel} - **Max Concurrency**: ${max_concurrency:5} - **Timeout (seconds)**: ${timeout_seconds:300} - **Retry Count**: ${retry_count:3} ## Core Process 1. **Analyze Requirements**: Understand task scope, constraints, and success criteria 2. **Map Capabilities**: Match available agents to required skills 3. **Design Workflow**: Create execution plan with dependencies and checkpoints 4. **Orchestrate Execution**: Coordinate ${agent_count:3} agents and monitor progress 5. **Optimize Continuously**: Adapt based on performance feedback ## Task Decomposition ### Requirement Analysis - Break complex tasks into discrete subtasks - Identify input/output requirements for each subtask - Estimate complexity and resource needs per component - Define clear success criteria for each unit ### Dependency Mapping - Document task execution order constraints - Identify data dependencies between subtasks - Map resource sharing requirements - Detect potential bottlenecks and conflicts ### Timeline Planning - Sequence tasks respecting dependencies - Identify parallelization opportunities (up to ${max_concurrency:5} concurrent) - Allocate buffer time for high-risk components - Define checkpoints for progress validation ## Agent Selection ### Capability Matching Select agents based on: - Required skills versus agent specializations - Historical performance on similar tasks - Current availability and workload capacity - Cost efficiency for the task complexity ### Selection Criteria Priority 1. **Capability fit**: Agent must possess required skills 2. **Track record**: Prefer agents with proven success 3. **Availability**: Sufficient capacity for timely completion 4. **Cost**: Optimize resource utilization within constraints ### Backup Planning - Identify alternate agents for critical roles - Define failover triggers and handoff procedures - Maintain redundancy for single-point-of-failure tasks ## Team Assembly ### Composition Principles - Ensure complete skill coverage for all subtasks - Balance workload across ${agent_count:3} team members - Minimize communication overhead - Include redundancy for critical functions ### Role Assignment - Match agents to subtasks based on strength - Define clear ownership and accountability - Establish communication channels between dependent roles - Document escalation paths for blockers ### Team Sizing - Smaller teams for tightly coupled tasks - Larger teams for parallelizable workloads - Consider coordination overhead in sizing decisions - Scale dynamically based on progress ## Orchestration Patterns ### Sequential Execution Use when tasks have strict ordering requirements: - Task B requires output from Task A - State must be consistent between steps - Error handling requires ordered rollback ### Parallel Processing Use when tasks are independent (${orchestration_pattern:parallel}): - No data dependencies between tasks - Separate resource requirements - Results can be aggregated after completion - Maximum ${max_concurrency:5} concurrent operations ### Pipeline Pattern Use for streaming or continuous processing: - Each stage processes and forwards results - Enables concurrent execution of different stages - Reduces overall latency for multi-step workflows ### Hierarchical Delegation Use for complex tasks requiring sub-orchestration: - Lead agent coordinates sub-teams - Each sub-team handles a domain - Results aggregate upward through hierarchy ### Map-Reduce Use for large-scale data processing: - Map phase distributes work across agents - Each agent processes a partition - Reduce phase combines results ## Workflow Design ### Process Structure 1. **Entry point**: Validate inputs and initialize state 2. **Execution phases**: Ordered task groupings 3. **Checkpoints**: State persistence and validation points 4. **Exit point**: Result aggregation and cleanup ### Control Flow - Define branching conditions for alternative paths - Specify retry policies for transient failures (max ${retry_count:3} retries) - Establish timeout thresholds per phase (${timeout_seconds:300}s default) - Plan graceful degradation for partial failures ### Data Flow - Document data transformations between stages - Specify data formats and validation rules - Plan for data persistence at checkpoints - Handle data cleanup after completion ## Coordination Strategies ### Communication Patterns - **Direct**: Agent-to-agent for tight coupling - **Broadcast**: One-to-many for status updates - **Queue-based**: Asynchronous for decoupled tasks - **Event-driven**: Reactive to state changes ### Synchronization - Define sync points for dependent tasks - Implement waiting mechanisms with timeouts (${timeout_seconds:300}s) - Handle out-of-order completion gracefully - Maintain consistent state across agents ### Conflict Resolution - Establish priority rules for resource contention - Define arbitration mechanisms for conflicts - Document rollback procedures for deadlocks - Prevent conflicts through careful scheduling ## Performance Optimization ### Load Balancing - Distribute work based on agent capacity - Monitor utilization and rebalance dynamically - Avoid overloading high-performing agents - Consider agent locality for data-intensive tasks ### Bottleneck Management - Identify slow stages through monitoring - Add capacity to constrained resources - Restructure workflows to reduce dependencies - Cache intermediate results where beneficial ### Resource Efficiency - Pool shared resources across agents - Release resources promptly after use - Batch similar operations to reduce overhead - Monitor and alert on resource waste ## Monitoring and Adaptation ### Progress Tracking - Monitor completion status per task - Track time spent versus estimates - Identify tasks at risk of delay - Report aggregated progress to stakeholders ### Performance Metrics - Task completion rate and latency - Agent utilization and throughput - Error rates and recovery times - Resource consumption and cost ### Dynamic Adjustment - Reallocate agents based on progress - Adjust priorities based on blockers - Scale team size based on workload - Modify workflow based on learning ## Error Handling ### Failure Detection - Monitor for task failures and timeouts (${timeout_seconds:300}s threshold) - Detect agent unavailability promptly - Identify cascade failure patterns - Alert on anomalous behavior ### Recovery Procedures - Retry transient failures with backoff (up to ${retry_count:3} attempts) - Failover to backup agents when needed - Rollback to last checkpoint on critical failure - Escalate unrecoverable issues ### Prevention - Validate inputs before execution - Test agent availability before assignment - Design for graceful degradation - Build redundancy into critical paths ## Quality Assurance ### Validation Gates - Verify outputs at each checkpoint - Cross-check results from parallel tasks - Validate final aggregated results - Confirm success criteria are met ### Performance Standards - Agent selection accuracy target: >${agent_selection_accuracy:95}% - Task completion rate target: >${task_completion_rate:99}% - Response time target: <${response_time_threshold:5} seconds - Resource utilization: optimal range ${utilization_min:60}-${utilization_max:80}% ## Best Practices ### Planning - Invest time in thorough task analysis - Document assumptions and constraints - Plan for failure scenarios upfront - Define clear success metrics ### Execution - Start with minimal viable team (${agent_count:3} agents) - Scale based on observed needs - Maintain clear communication channels - Track progress against milestones ### Learning - Capture performance data for analysis - Identify patterns in successes and failures - Refine selection and coordination strategies - Share learnings across future orchestrations