| name | output-eval-error-analysis |
| description | Systematically review workflow traces to identify failure modes before building evaluators. Use when starting an eval project, after significant pipeline changes, or when production quality drops. |
| allowed-tools | ["Bash","Read","Write","Edit"] |
Error Analysis for Workflow Evaluation
Overview
Review real workflow traces and categorize how your workflow fails before writing any evaluators. Evaluators built without error analysis target generic qualities ("is this good?") instead of the specific ways your workflow actually breaks. This skill walks you through the process.
When to Use
- Starting a new eval project for an existing workflow
- Production quality has dropped and you need to understand why
- After significant prompt, model, or pipeline changes
- Before building your first evaluator for a workflow
Step 1: Collect Traces
Gather 50-100 representative workflow executions. More traces = more reliable failure categories.
From recent runs
List recent workflow executions and pull their traces:
npx output workflow runs list <workflowName>
npx output workflow debug <workflowId> --json
From production (bulk download)
Download production traces directly into dataset YAML files:
npx output workflow dataset generate <workflowName> --download --limit 20
This creates YAML files in tests/datasets/ with the input and last_output fields populated from real executions.
From scenario-driven generation
If production traces are sparse, generate traces from scenario inputs:
npx output workflow dataset generate <workflowName> basic --name basic_trace
npx output workflow dataset generate <workflowName> --input '{"topic": "AI safety"}' --name ai_safety_trace
Run enough inputs to get 50+ traces. Prioritize diversity over volume — vary inputs across the dimensions you expect to matter.
Step 2: Review Traces Individually
Review each trace one at a time. For each trace, record:
| Field | What to write |
|---|
| Trace ID | The workflow execution ID |
| Verdict | Pass or Fail (binary — no "partial" at this stage) |
| Root cause | If Fail: what specifically went wrong and why |
| Notes | Anything surprising or worth remembering |
Review template
Create a file to track your reviews. A simple markdown table works:
# Error Analysis: <workflow_name>
# Date: YYYY-MM-DD
# Traces reviewed: 0 / 50
| # | Trace ID | Verdict | Root Cause | Notes |
|---|----------|---------|------------|-------|
| 1 | abc-123 | Fail | Hallucinated a URL that doesn't exist | Common with technical topics |
| 2 | def-456 | Pass | — | Clean output |
| 3 | ghi-789 | Fail | Ignored the "formal tone" requirement | Input had conflicting signals |
What to look for in each trace
Open the JSON trace and examine:
- Final output — Does it meet the user's intent? Is it correct?
- Step-by-step data flow — Did each step receive the right input and produce reasonable output?
- LLM responses — Did the model follow instructions? Did it hallucinate?
- Error states — Did any step fail, retry, or produce unexpected errors?
Critical rule: read first, categorize second
Review at least 30 traces before naming any failure categories. Premature categorization causes you to see patterns that aren't there and miss patterns that are. Just record what you observe.
Step 3: Group Into Failure Categories
After reviewing 30+ traces, patterns will emerge. Group your failures into 5-10 categories based on root cause, not surface symptoms.
Good categories (root cause)
- "Hallucinated URLs" — model invents links that don't exist
- "Tone mismatch" — output tone doesn't match the requested persona
- "Missing required section" — output omits a section the input explicitly requested
- "Factual error" — output contains verifiably wrong claims
- "Prompt injection leak" — user input manipulates the system prompt
Bad categories (surface symptoms)
- "Bad output" — too vague, not actionable
- "LLM error" — doesn't identify the specific failure
- "Quality issue" — could mean anything
Splitting and merging
- If a category has fewer than 3 examples, merge it into a broader category or note it as rare
- If a category has 15+ examples and contains distinct sub-patterns, split it
- Categories should be mutually exclusive — each failure belongs to exactly one category
Example categorization
For a blog generation workflow after reviewing 60 traces:
| Category | Count | Rate | Example |
|---|
| Hallucinated URLs | 8 | 13% | Invented links to non-existent pages |
| Tone mismatch | 6 | 10% | Casual tone when formal was requested |
| Off-topic drift | 5 | 8% | Blog about "AI" drifted to unrelated ML history |
| Missing sections | 4 | 7% | Skipped "conclusion" when explicitly requested |
| Too short | 3 | 5% | Under 200 words when 500+ requested |
| Total failures | 26 | 43% | |
| Passes | 34 | 57% | |
Step 4: Label Datasets
Add ground_truth labels to your dataset YAML files so evaluators can validate against them. Each failure category maps to a future evaluator name.
YAML structure
name: ai_safety_trace
input:
topic: "AI safety"
tone: "formal"
min_length: 500
last_output:
output:
title: "Understanding AI Safety"
blog_post: "AI safety is super important and stuff..."
executionTimeMs: 3200
date: '2026-03-25T00:00:00.000Z'
ground_truth:
human_verdict: fail
failure_categories:
- tone_mismatch
notes: "Used casual language despite formal tone request"
evals:
check_tone:
expected_tone: formal
verdict: fail
check_length:
min_length: 500
verdict: pass
check_hallucinated_urls:
verdict: pass
The ground_truth.evals.<evaluator_name> fields map directly to the evaluator names you'll use in verify(). Each evaluator receives its own ground truth merged with the top-level ground truth via context.ground_truth.
Labeling efficiently
You don't need to label every dataset for every category. Focus on:
- Label all datasets with the global
human_verdict (pass/fail)
- Label datasets for the top 3 failure categories by rate
- Add per-evaluator labels as you build each evaluator
Step 5: Decide What to Fix vs. Evaluate
Not every failure category needs an evaluator. Use this decision tree:
Is this failure caused by a fixable prompt/tool gap?
├─ YES → Fix the prompt or add the missing tool first
│ Re-run error analysis after the fix
└─ NO → Will this failure recur and need ongoing monitoring?
├─ YES → Build an evaluator
│ Can it be checked with deterministic code?
│ ├─ YES → Use Verdict.* helpers (contains, matches, gte, etc.)
│ └─ NO → Use judgeVerdict() with an LLM judge prompt
└─ NO → Document it and move on (rare edge case)
Prioritize by failure rate
Build evaluators for the highest-rate failure categories first. A failure at 13% matters more than one at 2%.
Code-based checks first
Many failures that seem subjective have objective proxies:
| Failure | Seems like... | But you can check with... |
|---|
| "Too short" | Subjective | Verdict.gte(output.length, threshold) |
| "Missing section" | Needs LLM | Verdict.contains(output, "## Conclusion") |
| "Hallucinated URLs" | Needs LLM | Extract URLs with regex, verify with HTTP HEAD |
| "Wrong format" | Needs LLM | Verdict.matches(output, expectedPattern) |
Reserve LLM judges for genuinely subjective criteria: tone, relevance, faithfulness, coherence.
Step 6: Map Categories to Evaluators
Create a mapping document that connects your failure categories to planned evaluators:
# Evaluator Plan: blog_generator
| Category | Rate | Evaluator Type | Evaluator Name | Criticality |
|----------|------|----------------|----------------|-------------|
| Hallucinated URLs | 13% | Code (URL extraction + HTTP check) | check_urls | required |
| Tone mismatch | 10% | LLM judge | check_tone | required |
| Off-topic drift | 8% | LLM judge | check_topic | required |
| Missing sections | 7% | Code (string contains) | check_sections | required |
| Too short | 5% | Code (length check) | check_length | informational |
This becomes your implementation roadmap. Use criticality: 'required' for failure categories that should block a passing verdict. Use 'informational' for nice-to-have checks.
Next Steps
- Build evaluators — Follow
output-dev-eval-testing to implement each evaluator with verify() and wire them into evalWorkflow()
- Design judge prompts — For LLM-based evaluators, follow
output-eval-judge-prompt to write effective .prompt files
- Expand datasets — If your traces don't cover enough failure regions, follow
output-eval-dataset-design to generate diverse test cases
- Re-run after changes — After fixing prompts, switching models, or modifying pipeline logic, repeat this error analysis to find new failure modes
Anti-Patterns
- Building evaluators without error analysis — You'll evaluate the wrong things
- Categorizing before reviewing 30+ traces — Premature categories cause confirmation bias
- Surface-level categories ("bad output", "LLM error") — Split by root cause
- One giant evaluator — One evaluator per failure mode, not one evaluator for everything
- Skipping code-based checks — Don't use an LLM judge when
Verdict.contains() works
- Never re-running — Error analysis is not a one-time activity; repeat after significant changes
Related Skills
output-dev-eval-testing — Implement evaluators with verify(), Verdict, and evalWorkflow()
output-eval-judge-prompt — Design LLM judge prompts for subjective failure modes
output-eval-dataset-design — Generate diverse datasets when real traces are sparse
output-eval-validate-judge — Validate LLM judges against human labels
output-eval-audit — Audit an existing eval suite for trustworthiness
output-workflow-trace — Retrieve and analyze workflow execution traces