について
スキル評価ツールは、開発者がさまざまなコーディングエージェントCLIにおけるエージェントスキルを厳密にテストし、ベンチマークするためのツールです。スクリプト出力の決定論的検証、スキルトリガーの精度テスト、スキル未使用時のベースラインに対する性能向上の測定を行います。スキルの品質検証、バージョン比較、評価スイートの構築にご利用ください。
クイックインストール
Claude Code
推奨npx skills add HeshamFS/materials-simulation-skills -a claude-code/plugin add https://github.com/HeshamFS/materials-simulation-skillsgit clone https://github.com/HeshamFS/materials-simulation-skills.git ~/.claude/skills/skill-evaluatorこのコマンドをClaude Codeにコピー&ペーストしてスキルをインストールします
ドキュメント
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):
| Layer | Question | Script | Needs a CLI? |
|---|---|---|---|
| 1. Deterministic | Do the scripts emit the documented numbers? | run_script_checks.py | No |
| 2. Trigger | Does the description activate on the right prompts? | run_trigger_eval.py | Yes |
| 3. Quality | Does following the SKILL.md beat no skill? | run_quality_eval.py → grade → aggregate_benchmark.py | Yes |
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 intograding.json.references/schemas.md— exact JSON shapes for every file.
Security
Input Validation
--agentis resolved against a fixed allowlist of known adapter ids/aliases (agent_adapters.py); unknown values are rejected (exit 2).--skillmust be a directory containingSKILL.mdor the runners exit 2.script_checksoperators and dotted paths are matched against fixed sets; no user string is evereval()'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 (nevershell=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-runfirst 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
--helpand--dry-run.
GitHub リポジトリ
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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