--- description: > Analyze workflow patterns using the Agent Monitor's workflow intelligence API — orchestration DAGs, tool flow transitions, subagent effectiveness, model delegation patterns, error propagation by depth, concurrency lanes, compaction impact, and agent co-occurrence. Produces prioritized optimization recommendations with quantified impact. --- # Workflow Optimizer Analyze Claude Code workflows using the Agent Monitor's workflow intelligence engine. ## Input The user provides: **$ARGUMENTS** Options: "analyze", a session ID for single-session analysis, or a focus: "tools", "subagents", "cost", "errors". ## Data Sources | Endpoint | Returns | |----------|---------| | `GET /api/sessions?limit=100` | Session list with metadata | | `GET /api/workflows/{sessionId}` | **11 workflow datasets** (see below) | | `GET /api/analytics` | Tool usage top 20, event types, agent types | | `GET /api/pricing` | Model pricing rules for cost comparison | ### Workflow Intelligence API (`GET /api/workflows/{sessionId}`) Returns these 11 datasets per session: | Dataset | Content | |---------|---------| | `stats` | Aggregate session stats: tool count, agent depth, event count | | `orchestration` | **DAG**: agent nodes with parent/child edges, depths, types | | `toolFlow` | **Transition matrix**: tool A → tool B with counts (common sequences) | | `effectiveness` | **Subagent success**: per-type completion rates, avg duration, task success | | `patterns` | **Recurring sequences**: detected workflow patterns with frequency | | `modelDelegation` | **Model choices**: which models are delegated which tasks | | `errorPropagation` | **Error flow by depth**: where in the agent tree errors originate and propagate | | `concurrency` | **Concurrency lanes**: overlapping agent execution timelines | | `complexity` | **Complexity score**: numerical score based on depth, breadth, tool diversity | | `compaction` | **Compaction impact**: token savings, frequency, context health | | `cooccurrence` | **Agent pairs**: which agents frequently run together | ## Optimization Analyses ### 1. Tool Flow Optimization From `toolFlow` transition data: - Identify the most common tool sequences (e.g., Read → Edit → Bash) - Find redundant transitions (same tool called repeatedly = retries) - Detect anti-patterns: high-frequency failure loops - Recommend tool chain shortcuts ### 2. Subagent Strategy From `effectiveness` + `orchestration`: - Which subagent types (task, explore, code-review) have highest completion rates - Average duration per subagent type — are subagents taking too long? - Underutilized types: tasks that could benefit from delegation - Over-spawning: too many subagents for simple tasks ### 3. Model Delegation Analysis From `modelDelegation`: - Which models handle which task types - Cost-per-task comparison across models - Opportunities to delegate simple tasks to cheaper models (Haiku/Sonnet instead of Opus) - Calculate estimated savings from model rebalancing ### 4. Error Prevention From `errorPropagation`: - Where errors originate (agent depth level) - How errors cascade to parent agents - Error types (APIError, tool failure) by frequency - Defensive strategies: which patterns lead to fewer errors ### 5. Concurrency Optimization From `concurrency`: - Which agents run in parallel vs sequential - Bottlenecks: sequential agents that could be parallelized - Resource contention: overlapping heavy tasks ### 6. Context Health From `compaction`: - How often compaction occurs per session - Token recovery from compaction baselines - Sessions that hit context limits — suggest breaking into smaller tasks ## Output Prioritized recommendations table: | # | Recommendation | Source Data | Impact | Effort | Est. Savings | |---|---------------|-------------|--------|--------|-------------| Top 5 recommendations with detailed explanation, supporting data from the workflow API, and implementation steps.