SKILL·A2B33E

skill-evaluator

HeshamFS
Aktualisiert 22 days ago
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Metawordaitestingdesign

Über

Der Skill-Evaluator ist ein Werkzeug für Entwickler, um Agent-Skills über verschiedene Coding-Agent-CLIs hinweg rigoros zu testen und zu benchmarken. Er führt deterministische Verifizierung von Skriptausgaben durch, testet die Genauigkeit der Skill-Auslösung und misst Leistungsverbesserungen gegenüber einer Baseline ohne Skill. Nutzen Sie ihn, um die Qualität von Skills zu validieren, Versionen zu vergleichen oder eine Evaluierungsumgebung einzurichten.

Schnellinstallation

Claude Code

Empfohlen
Primär
npx skills add HeshamFS/materials-simulation-skills -a claude-code
Plugin-BefehlAlternativ
/plugin add https://github.com/HeshamFS/materials-simulation-skills
Git CloneAlternativ
git clone https://github.com/HeshamFS/materials-simulation-skills.git ~/.claude/skills/skill-evaluator

Kopieren Sie diesen Befehl und fügen Sie ihn in Claude Code ein, um diese Fähigkeit zu installieren

Dokumentation

Skill Evaluator

Test whether a skill is correct, discoverable, and valuable — not just whether its unit tests pass. The harness is agent-agnostic: it drives whichever coding-agent CLI the user uses, because Agent Skills are portable across all of them.

When to use which layer

Three layers, increasing cost and fidelity (full rationale in references/methodology.md):

LayerQuestionScriptNeeds a CLI?
1. DeterministicDo the scripts emit the documented numbers?run_script_checks.pyNo
2. TriggerDoes the description activate on the right prompts?run_trigger_eval.pyYes
3. QualityDoes following the SKILL.md beat no skill?run_quality_eval.py → grade → aggregate_benchmark.pyYes

Always run Layer 1 (it's free). Add Layers 2–3 when you can run a coding-agent CLI.

Step 0 — pick the agent CLI

Ask the user which coding agent they use, then map it to an adapter id. Supported: claude-code, openai-codex, antigravity (the agy CLI that replaced Gemini CLI on 2026-06-18), cursor-cli, github-copilot-cli, amp, opencode, grok-cli. See the full matrix and auth in references/adapters.md, or run:

python scripts/agent_adapters.py list

Confirm the binary is installed and the auth env var is set (the matrix lists it). Before any real run, dry-run it to see the exact command:

python scripts/agent_adapters.py build <agent> --prompt "test" --workdir /tmp/wd

Step 1 — deterministic script checks (always)

python scripts/run_script_checks.py --skill <path-to-skill> --json

Runs the script_checks in the skill's evals/evals.json, executing each script and grading its --json output against machine-checkable assertions. Exit non-zero on any failure — safe for CI. If the skill has few/no script_checks, add them for every eval whose answer is computable (schema in references/schemas.md); this is the cheapest, most durable guard against doc↔code drift.

Step 2 — trigger / discovery eval

Does the description fire on the right prompts and stay quiet on near-misses?

# Dry-run first (prints the per-CLI commands, runs nothing):
python scripts/run_trigger_eval.py --skill <path> --agent <agent> --dry-run

# Real run with a labelled query set (~20: half should-trigger, half near-miss):
python scripts/run_trigger_eval.py --skill <path> --agent <agent> \
  --queries queries.json --runs-per-query 3 --json

Design the query set per references/methodology.md (positives + tricky negatives). Without --queries, the skill's eval prompts are used as should-trigger cases — add negatives for a real discrimination test.

Step 3 — output-quality eval (the with/without delta)

The headline measure: does an agent following the SKILL.md beat no skill?

# 1. Dry-run the plan (no tokens spent):
python scripts/run_quality_eval.py --skill <path> --agent <agent> \
  --workspace <skill>-workspace --dry-run

# 2. Real run: with-skill AND no-skill baseline, isolated clean dirs each:
python scripts/run_quality_eval.py --skill <path> --agent <agent> \
  --workspace <skill>-workspace --iteration 1 --json

This installs the skill into a temp project skills dir for the with-skill run, runs a clean baseline without it, and captures outputs/, response.txt, and timing.json per run.

Then grade each run against its assertions and write grading.json (references/grader.md — re-derive numbers, require concrete evidence, no partial credit, critique weak assertions). For mechanically checkable assertions, reuse Layer 1 rather than eyeballing.

Then aggregate into the benchmark with the delta:

python scripts/aggregate_benchmark.py <skill>-workspace/iteration-1 \
  --skill-name <name> --agent <agent> --json

run_summary.delta.pass_rate is the value of the skill. Surface patterns the averages hide (references/methodology.md): non-discriminating assertions, high-variance evals, time/token tradeoffs. Put outputs in front of the user before concluding.

Step 4 — iterate

Improve the skill from the signals (failed assertions, weak-assertion feedback, transcripts, human review), generalizing rather than overfitting, keeping it lean, explaining the why, and bundling repeated work into scripts. Rerun into iteration-<N+1>/ and compare. Stop when results satisfy the user, feedback is empty, or gains plateau. For "is the new version actually better?", use the blind comparison described in references/methodology.md.

Outputs to report

  • Layer 1: checks passed / assertions passed; any doc↔code drift found.
  • Layer 2: trigger pass rate (positives that fired, negatives that stayed quiet).
  • Layer 3: with-skill vs. without-skill pass rate delta, plus time/token cost.

Reference files

  • references/adapters.md — per-CLI headless command, skills dir, auth, caveats.
  • references/methodology.md — the rigorous practices (read for non-trivial evals).
  • references/grader.md — how to grade a run into grading.json.
  • references/schemas.md — exact JSON shapes for every file.

Security

Input Validation

  • --agent is resolved against a fixed allowlist of known adapter ids/aliases (agent_adapters.py); unknown values are rejected (exit 2).
  • --skill must be a directory containing SKILL.md or the runners exit 2.
  • script_checks operators and dotted paths are matched against fixed sets; no user string is ever eval()'d or passed to a shell.

File Access

  • The deterministic layer runs a skill's own scripts with the real interpreter and reads only that skill's evals/evals.json.
  • The quality/trigger layers create isolated working directories under a user-supplied workspace, copy the skill into them, and write results there.

Tool Restrictions

  • Bash: runs the harness Python scripts and the selected coding-agent CLI.
  • Read/Grep/Glob: inspect skills and results. Write: scaffold workspaces.

Safety Measures

  • No eval()/exec(); subprocess calls use explicit argument lists (never shell=True); commands are built from the adapter spec, not string-concatenated.
  • The trigger/quality layers pass each CLI's auto-approve flag (e.g. --dangerously-skip-permissions), which runs the agent with reduced safeguards. Only evaluate skills you trust, ideally inside a sandbox/container. Always --dry-run first to inspect the exact command. Auth is read from environment variables, never passed as command arguments.

Limitations

  • Layers 2–3 require a supported CLI installed and authenticated; otherwise use Layer 1 only.
  • Trigger detection is a cross-tool heuristic (did the transcript consult the skill?); for the most precise detection on Claude Code, parse its stream-json tool-use events.
  • Token accounting is best-effort — only some CLIs report usage in headless output.
  • New CLIs (Antigravity, Grok) are medium confidence; verify flags with the vendor --help and --dry-run.

GitHub Repository

HeshamFS/materials-simulation-skills
Pfad: skills/meta/skill-evaluator
0
agent-skillsagentscli-toolscomputational-sciencellmmaterials-science
FAQ

Frequently asked questions

What is the skill-evaluator skill?

skill-evaluator is a Claude Skill by HeshamFS. Skills package instructions and resources that Claude loads on demand, so Claude can perform skill-evaluator-related tasks without extra prompting.

How do I install skill-evaluator?

Use the install commands on this page: add skill-evaluator to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.

What category does skill-evaluator belong to?

skill-evaluator is in the Meta category, tagged word, ai, testing and design.

Is skill-evaluator free to use?

Yes. skill-evaluator is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.

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