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stars:1,794
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updated:2026년 5월 25일 08:19
SKILL.md
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$ install --global
$ download --local
$ useful --forSOC
Regenerate high-resolution README screenshots from Storybook stories. Use this skill when Chromatic detects visual diffs in any story under "Docs/README Screenshots", or when story data/layout changes require updated documentation assets. Triggers on: Chromatic visual regressions in readme screenshot stories, changes to App.readmeScreenshots.stories.tsx, changes to mockFactory.ts that affect screenshot stories, or explicit user request to update README images.
Guidelines for creating and managing Pull Requests in this repo
Run isolated mux desktop (Electron) instances (temp MUX_ROOT + free ports)
Run multiple isolated mux dev-server instances (temp MUX_ROOT + free ports)
Testing doctrine, commands, and test layout conventions
Connects Mux mobile (Expo web/native) to an isolated dev-server sandbox with deterministic port setup, backend pairing, and Chrome MCP interaction. Use when implementing or validating mobile features against a sandboxed Mux backend.
| name | tbench |
| description | Terminal-Bench integration for Mux agent benchmarking and failure analysis |
This directory contains the mux agent adapter for Terminal-Bench 2.0, using Harbor as the evaluation harness.
When user asks to run a tbench, generally assume they mean in CI via workflow_dispatch.
# Run full benchmark suite
make benchmark-terminal
# Run specific tasks
make benchmark-terminal TB_TASK_NAMES="hello-world chess-best-move"
# Run with specific model and xhigh thinking
MUX_RUN_ARGS="--thinking xhigh" make benchmark-terminal TB_ARGS="--agent-kwarg model_name=anthropic/claude-opus-4-7"
# Run on Daytona cloud (high parallelism)
TB_ENV=daytona TB_CONCURRENCY=48 make benchmark-terminal
For faster benchmarks, use Daytona cloud sandboxes instead of local Docker:
# Set API key (get from https://app.daytona.io)
export DAYTONA_API_KEY="your-api-key"
# Run with 48 concurrent cloud sandboxes (~6x faster than local)
make benchmark-terminal TB_ENV=daytona TB_CONCURRENCY=48
# Run specific tasks on Daytona
make benchmark-terminal TB_ENV=daytona TB_CONCURRENCY=48 TB_TASK_NAMES="chess-best-move stockfish-elo"
Account limits (Tier 3): Pool of 250 vCPU / 500GB RAM. Most tasks require 1 vCPU / 2GB RAM, with a few needing up to 4 vCPU / 8GB RAM. Harbor automatically requests the correct per-task resources.
Speed comparison:
| Environment | Concurrency | Full suite time |
|---|---|---|
| Local Docker | 4 | ~90 min |
| Daytona Cloud | 48 | ~10-15 min |
TB_DATASET: Dataset to use (default: terminal-bench@2.0)TB_CONCURRENCY: Number of concurrent tasks (default: 4)TB_TIMEOUT: Global timeout in seconds (default: 1800 = 30 minutes)TB_ENV: Environment to run in (local or daytona)TB_TASK_NAMES: Space-separated task names to run (default: all tasks)TB_ARGS: Additional arguments passed to harborMUX_RUN_ARGS: CLI flags passed directly to mux run inside the container (e.g., --thinking high --use-1m --budget 5.00). This is the primary mechanism for all mux run flags — avoids per-flag plumbing.MUX_RUN_AS_GOAL: When set to 1, runs each task instruction as a strict mux run --goal objective while still piping the instruction to stdin. Use MUX_RUN_ARGS for goal limits such as --goal-turns and --goal-budget. Incomplete strict-goal exits are left scoreable so Harbor can verify the workspace.The benchmark uses Harbor's global timeout applied to all tasks. The default is 30 minutes (1800 seconds), which provides sufficient time for most tasks while catching genuinely stuck agents. The mux runner does not wrap the command in GNU timeout; Harbor must classify task timeouts as AgentTimeoutError so the workflow can distinguish timeout/infra cases from mux process failures.
Design Rationale:
Based on analysis of Oct 30, 2025 nightly runs:
blind-maze-explorer-algorithm.hard at 20 minutesThe 30-minute default provides comfortable headroom for complex tasks without excessive wait times for failed attempts.
Override timeout:
# Run with 60 minute timeout for very complex tasks
TB_TIMEOUT=3600 make benchmark-terminal
# Run with shorter 10 minute timeout for quick iteration
TB_TIMEOUT=600 make benchmark-terminal TB_SAMPLE_SIZE=5
Note: We prefer global timeout defaults over per-task configuration to avoid complexity and maintenance burden. If you find tasks consistently timing out, increase TB_TIMEOUT rather than adding per-task configuration.
The agent adapter accepts a few Harbor kwargs (passed via --agent-kwarg):
model_name: Model to use (e.g., anthropic/claude-opus-4-7, openai/gpt-5.5)experiments: Experiments to enable, comma-separated (e.g., programmatic-tool-calling)All other mux run CLI flags (thinking level, mode, runtime, budget, etc.) are passed via MUX_RUN_ARGS — no per-flag plumbing needed.
CI dispatch (primary method):
# Run with model, thinking, and 1M context
gh workflow run terminal-bench.yml \
-f model_name=anthropic/claude-opus-4-7 \
-f mux_run_args="--thinking xhigh --use-1m"
# Run GPT-5.5 with budget cap and high thinking
gh workflow run terminal-bench.yml \
-f model_name=openai/gpt-5.5 \
-f mux_run_args="--thinking high --budget 5.00"
Strict goal-mode runs:
# Run a single task as a strict CLI Goal Run
MUX_RUN_AS_GOAL=1 \
MUX_RUN_ARGS="--thinking high --goal-turns 30 --goal-budget 10.00" \
make benchmark-terminal TB_TASK_NAMES="chess-best-move"
# CI dispatch
gh workflow run terminal-bench.yml \
-f model_name=anthropic/claude-sonnet-4-5 \
-f task_names=chess-best-move \
-f mux_run_as_goal=true \
-f mux_run_args="--thinking high --goal-turns 30 --goal-budget 10.00"
Local runs:
# Pass flags via MUX_RUN_ARGS env var
MUX_RUN_ARGS="--thinking high --use-1m" make benchmark-terminal
# Model and experiments via TB_ARGS
MUX_RUN_ARGS="--thinking high" make benchmark-terminal TB_ARGS="--agent-kwarg model_name=openai/gpt-5.5 --agent-kwarg experiments=programmatic-tool-calling"
Results are saved to runs/YYYY-MM-DD__HH-MM-SS/:
results.json: Aggregate results with pass/fail ratesrun_metadata.json: Run configuration and metadata<task-id>/: Per-task directories containing:
sessions/agent.log: Full agent execution logsessions/agent.cast: Asciinema recording of agent sessionsessions/tests.log: Test execution outputresults.json: Per-trial resultsMux Terminal-Bench results are uploaded to BigQuery after CI runs. Query via bq CLI after authenticating with gcloud auth login and setting project to mux-benchmarks.
Table: mux-benchmarks.benchmarks.tbench_results
Schema: run_id (STRING), task_id (STRING), model_name (STRING), thinking_level (STRING: off/low/medium/high), mode (STRING: plan/exec), dataset (STRING), experiments (STRING), passed (BOOL), score (FLOAT), n_input_tokens (INT), n_output_tokens (INT), github_run_id (INT), github_sha (STRING), ingested_at (TIMESTAMP).
See .github/workflows/terminal-bench.yml and .github/workflows/nightly-terminal-bench.yml for GitHub Actions integration.
Nightly workflow runs both Claude and GPT models on the full task suite, uploading results as artifacts.
To submit mux results to the Terminal-Bench 2.0 leaderboard:
The leaderboard computes pass@k from multiple attempts per task. Provide multiple runs so each becomes its own job folder inside the submission.
# Download latest 5 successful nightly runs (recommended for submission)
python3 benchmarks/terminal_bench/prepare_leaderboard_submission.py --n-runs 5
# Use specific run IDs (each becomes a separate job folder)
python3 benchmarks/terminal_bench/prepare_leaderboard_submission.py --run-id 111 222 333 444 555
# Use multiple existing artifact directories
python3 benchmarks/terminal_bench/prepare_leaderboard_submission.py --artifacts-dir ./run1 ./run2
# Download latest single run (quick iteration)
python3 benchmarks/terminal_bench/prepare_leaderboard_submission.py
# Only prepare specific models
python3 benchmarks/terminal_bench/prepare_leaderboard_submission.py --n-runs 5 --models anthropic/claude-opus-4-7
This creates a properly structured submission folder at leaderboard_submission/ containing:
submissions/terminal-bench/2.0/Mux__<model>/
metadata.yaml # Agent and model info
<job-folder-1>/ # Results from run 1
config.json
result.json
<trial-1>/
config.json
result.json
agent/
verifier/
...
<job-folder-2>/ # Results from run 2
...
The hf upload CLI tends to timeout on large submissions due to LFS file handling.
Use the Python API with an extended timeout instead:
# Install huggingface_hub (via uv or pip)
pip install huggingface_hub
# Authenticate (one-time setup)
hf auth login
import httpx
from huggingface_hub import HfApi
from huggingface_hub.utils import configure_http_backend
configure_http_backend(
backend_factory=lambda: httpx.Client(timeout=httpx.Timeout(300.0, connect=60.0))
)
api = HfApi()
api.upload_folder(
repo_id="alexgshaw/terminal-bench-2-leaderboard",
folder_path="./leaderboard_submission/submissions",
path_in_repo="submissions",
repo_type="dataset",
create_pr=True,
commit_message="Add Mux + <Model> submission",
commit_description="- Agent: Mux (Coder)\n- Model: <model>\n- <N> tasks × <K> attempts",
)
The PR will be automatically validated by the leaderboard bot. Once merged, results appear on the leaderboard.
Tips from past submissions:
*.log files (they trigger HF LFS and cause timeouts)--artifacts-dir accepts raw job folders directly (e.g., an extracted tarball root)revision="refs/pr/<N>" instead of create_pr=Trueapi.delete_folder(..., revision="refs/pr/<N>")mux_agent.py: Main agent adapter implementing Harbor's BaseInstalledAgent interfacemux-run.sh: Shell script that sets up environment and invokes mux CLImux_payload.py: Helper to package mux app for containerized executionmux_setup.sh.j2: Jinja2 template for agent installation scriptprepare_leaderboard_submission.py: Script to prepare results for leaderboard submissionanalyze_failure_rates.py: Analyze failure rates to find optimization opportunitiesdownload_run_logs.py: Download and inspect raw agent logs from nightly runsWhen investigating why Mux fails on a task more than other agents, consider this workflow:
# Find tasks where Mux underperforms (high M/O ratio = Mux fails more than others)
python benchmarks/terminal_bench/analyze_failure_rates.py --top 20
# Authenticate and set project
gcloud auth login && gcloud config set project mux-benchmarks
# Query pass/fail by model for specific task (strip __hash suffix mentally)
bq query --use_legacy_sql=false '
SELECT model_name, passed, COUNT(*) as runs
FROM `mux-benchmarks.benchmarks.tbench_results`
WHERE REGEXP_REPLACE(task_id, r"__[a-zA-Z0-9]+$", "") = "TASK_NAME_HERE"
AND github_workflow = "Nightly Terminal-Bench"
AND passed IS NOT NULL
GROUP BY model_name, passed
ORDER BY model_name, passed
'
# List recent nightly runs
python benchmarks/terminal_bench/download_run_logs.py --list-runs
# Download latest run and filter to failing task
python benchmarks/terminal_bench/download_run_logs.py --task TASK_NAME --failures-only
# Download specific run, filter to specific model
python benchmarks/terminal_bench/download_run_logs.py --run-id 21230456195 --model opus --task TASK_NAME
# Verbose mode shows stderr from agent execution
python benchmarks/terminal_bench/download_run_logs.py --task TASK_NAME -v
Logs are cached in .run_logs/<run-id>/. Inspect:
agent/command-0/stdout.txt — Full agent output (JSONL stream)agent/command-0/stderr.txt — Errors during executionresult.json — Trial result with verifier_result and exception_info# Clone leaderboard repo from HuggingFace (cached in .leaderboard_cache/)
cd benchmarks/terminal_bench
git clone https://huggingface.co/datasets/alexgshaw/terminal-bench-2-leaderboard .leaderboard_cache/terminal-bench-2-leaderboard 2>/dev/null
# Find passing submissions for the task
find .leaderboard_cache -path "*TASK_NAME*" -name "result.json" -exec sh -c '
agent=$(echo "$1" | cut -d/ -f5)
reward=$(cat "$1" | python3 -c "import json,sys; print(json.load(sys.stdin).get(\"verifier_result\",{}).get(\"rewards\",{}).get(\"reward\",0))")
echo "$agent: reward=$reward"
' _ {} \;
To identify where Mux underperforms relative to other top agents, use the analysis script:
# Run analysis (requires bq CLI for Mux results, git for leaderboard data)
python benchmarks/terminal_bench/analyze_failure_rates.py
# Show more results
python benchmarks/terminal_bench/analyze_failure_rates.py --top 50
# Filter to specific Mux model
python benchmarks/terminal_bench/analyze_failure_rates.py --mux-model sonnet
# Force refresh of cached data
python benchmarks/terminal_bench/analyze_failure_rates.py --refresh
# Output as JSON for further processing
python benchmarks/terminal_bench/analyze_failure_rates.py --json > opportunities.json
The script computes the M/O ratio for each task:
M/O ratio = Mux failure rate / Average failure rate of top 10 agents
Tasks with high M/O ratio are where Mux underperforms relative to competitors—these represent the best optimization opportunities.
Example output:
================================================================================
OPTIMIZATION OPPORTUNITIES (sorted by M/O ratio)
================================================================================
Task ID Mux Fail% Avg Other% M/O Ratio Agent
--------------------------------------------------------------------------------
some-difficult-task 100.0% 10.0% 9.09 Mux__Claude-Sonnet-4.5
another-task 80.0% 20.0% 3.64 Mux__Claude-Sonnet-4.5
...
================================================================================
SUMMARY
================================================================================
Total tasks with Mux failures: 42
High priority (M/O > 2.0): 12
Medium priority (1.0 < M/O ≤ 2.0): 8