webots-mcp-kit 0.10.5

Windows-first Webots developer toolkit with CLI, MCP server, controller SDK, and bundled benchmarks.

webots-mcp-kit

webots-mcp-kit is a Windows-first developer toolkit for connecting LLM agents to Webots.

It combines:

• a pip-installable CLI
• an MCP server with Webots session tools
• a controller-side SDK for structured telemetry and manual overrides
• bundled example scenarios and benchmarks

The bundled line follower is not the product itself. It is the first reference example. The toolkit is meant to be reusable across other Webots robots, controllers, and worlds.

Current release

v0.10.5

Current focus:

• Windows-first local development
• Webots R2025a
• direct Webots integration without ROS2
• stable controller-side integration through ControllerAgent
• bundled scenarios plus registry-backed benchmark thresholds
• hosted-safe CI with separate self-hosted runtime smoke
• release pipeline for GitHub Release, TestPyPI, and PyPI
• public-contract regression coverage and external-user onboarding
• MCP reliability for LLM-driven Webots sessions
• zero-to-sim foundations through template-driven project and scenario generation
• standardized runtime artifact and replay bundles for exported sessions
• centralized clean-user acceptance flow for package and publish smoke
• explicit no-mock v1.0.0 gate validation for real runtime workflows

Operational runtime model:

• interactive-webots is the single supported runtime execution path for real Webots sessions, benchmarks, and runtime smoke
• Windows service mode is not a supported runtime path at the active pre-v1.0.0 contract line

Current support

Supported now:

• Windows
• Webots R2025a
• Python 3.11+
• interactive self-hosted runtime through the interactive-webots runner label as the only supported runtime execution model
• experimental-foundation zero-to-sim commands: project/scenario/import/replay

Not supported in the pre-v1.0.0 line:

• Windows service runner runtime
• Linux/macOS runtime support
• ROS2 integration
• multi-robot orchestration

Bundled scenarios

• line-follower
  • camera-based line tracking
  • example world: examples/line-follower
• obstacle-avoidance
  • proximity-sensor obstacle avoidance
  • example world: examples/obstacle-avoidance
• waypoint-nav
  • fixed-waypoint navigation in an open arena
  • example world: examples/waypoint-nav

Install

Use an isolated virtual environment. The toolkit depends on mcp, which may pull shared web stack packages into your global Python install.

python -m venv .venv
.venv\Scripts\Activate.ps1
pip install webots-mcp-kit

Development install:

python -m venv .venv
.venv\Scripts\Activate.ps1
pip install -e .[dev]

Optional CI or slow-machine tuning:

$env:WEBOTS_KIT_SESSION_START_TIMEOUT='90'

Quick start

I want to connect an agent to Webots

webots-kit doctor
webots-kit session start --scenario line-follower --controller example --mode fast --render off
webots-kit mcp serve
webots-kit benchmark list
webots-kit benchmark run line-follower --controller example --output .\report.json --duration-s 3
webots-kit benchmark report .\report.json

I want to integrate my own controller

webots-kit controller scaffold .\controllers\my_agent.py --scenario line-follower
webots-kit controller validate .\controllers\my_agent.py --scenario line-follower --strict --json
webots-kit benchmark run line-follower --controller .\controllers\my_agent.py --output .\report.json

I want to generate a scenario from a spec

webots-kit project init .\my-webots-project
webots-kit scenario init .\my-webots-project\scenarios\warehouse-demo --template epuck-waypoint
webots-kit scenario validate .\my-webots-project\scenarios\warehouse-demo\webots-kit.scenario.json
webots-kit scenario build .\my-webots-project\scenarios\warehouse-demo\webots-kit.scenario.json
webots-kit scenario doctor .\my-webots-project\scenarios\warehouse-demo\webots-kit.scenario.json

I want to import and replay

webots-kit project import --world .\worlds\demo.wbt --controller .\controllers\demo_agent.py
webots-kit session export <session-id> --output .\artifacts\exports\<session-id>
webots-kit session replay .\artifacts\exports\<session-id>

CLI surface

• webots-kit doctor [--json]
• webots-kit session start --scenario <name> --world <path> --controller <path-or-id> [--robot-name <name>] [--robot-def <def>] [--mode fast|realtime|pause] [--render on|off]
• webots-kit session inspect --session <id>
• webots-kit session logs --session <id> [--name <file>] [--tail <n>]
• webots-kit session export <id> [--output <path>]
• webots-kit session replay <export-path> [--json]
• webots-kit session stop --session <id>
• webots-kit benchmark list
• webots-kit benchmark run <scenario> --controller <path-or-id> --output <report.json> [--duration-s <seconds>] [--world <path>] [--robot-name <name>] [--robot-def <def>]
• webots-kit benchmark report <report.json>
• webots-kit controller validate <path> [--scenario <name>] [--strict] [--json]
• webots-kit controller scaffold <path> [--scenario <name>] [--force]
• webots-kit project init <path> [--name <name>] [--force]
• webots-kit project import --world <path> --controller <path> [--project-root <path>]
• webots-kit scenario init <path> --template <template> [--force]
• webots-kit scenario validate <spec-path> [--json]
• webots-kit scenario build <spec-path> [--force]
• webots-kit scenario describe <spec-path>
• webots-kit scenario doctor <spec-path> [--json]
• webots-kit mcp serve

Supported zero-to-sim templates:

• epuck-arena
• epuck-line-track
• epuck-waypoint
• epuck-obstacle-course

Foundation status for the zero-to-sim surface:

• CLI command names are now treated as stable
• the underlying JSON ScenarioSpec schema is still experimental-foundation
• the schema is documented and supported, but not yet frozen for additive refinement before v1.1.0

Controller integration

There are two supported usage paths:

• bundled example controllers under examples/
• user-supplied Python controllers that integrate with ControllerAgent

The public controller-side entrypoint is ControllerAgent. The stable public contract is:

• ControllerAgent.from_robot(...)
• begin_step()
• report_step(...)

Minimal integration shape:

from controller import Robot
from webots_mcp_kit.agent import ControllerAgent

robot = Robot()
agent = ControllerAgent.from_robot(robot, default_camera="camera")

while robot.step(int(robot.getBasicTimeStep())) != -1:
    override = agent.begin_step()
    # apply your control logic, optionally overriding wheel commands
    agent.report_step(
        sensors={},
        metrics={},
        actuators={},
        camera_frames=None,
    )

Use webots-kit controller validate <path> to check whether a controller follows the expected integration pattern. Use webots-kit controller scaffold when you want a working starter file based on a bundled scenario.

MCP tools

• webots_session_start
• webots_session_stop
• webots_list_robots
• webots_list_devices
• webots_get_state
• webots_get_sensors
• webots_capture_camera
• webots_set_motor_velocity
• webots_step
• webots_pause_resume
• webots_reset
• webots_run_benchmark

Stable payload shapes:

• webots_session_start -> stable session/readiness top-level keys with additive extras only
• webots_get_state -> { session, session_state, control_paused, runtime_summary, runtimes }
• webots_list_devices -> { robot, scenario, devices }
• webots_get_sensors -> { robot, scenario, state, sensors, metrics, actuators, meta }
• webots_capture_camera -> { path, width, height }
• webots_run_benchmark -> stable benchmark report top-level keys with additive extra_metrics
• failed MCP tool calls -> { ok: false, error: { code, message, details, retriable } }
• existing MCP/runtime failure codes will not be renamed before v1.0.0; new codes may only be added

Reference docs:

• Onboarding flows
• v1.0.0 gate
• First hour guide
• MCP contracts
• Self-hosted runtime smoke
• Custom controller integration
• Add a new scenario
• Zero-to-sim guide
• Project import and session replay
• Failed runtime smoke triage
• PyPI install and upgrade
• Release checklist
• Runner maintenance
• Packaging verification

Testing

Unit tests:

python -m pytest -q

Hosted-safe smoke tests:

$env:WEBOTS_KIT_RUN_SMOKE='1'
python -m pytest -q -k mcp_tool_list_smoke

Full runtime smoke tests with real Webots execution:

$env:WEBOTS_KIT_RUN_RUNTIME_SMOKE='1'
python -m pytest -q -k "session_start_inspect_stop_smoke or benchmark_smoke or generated_scenario_smoke or imported_project_smoke"

The self-hosted GitHub workflow for runtime smoke expects a Windows runner labeled interactive-webots. That runner must be started from an interactive user session. Windows service mode is not sufficient for Webots runtime smoke because Webots exits during OpenGL initialization before controllers connect. The self-hosted runtime workflow also auto-triggers for runtime-affecting changes and still supports manual dispatch. Packaging and release verification are handled by GitHub workflows:

• Packaging CI
• Release

Troubleshooting

• If doctor fails, ensure WEBOTS_HOME is set or Webots is installed in C:\Program Files\Webots.
• If MCP or session startup closes immediately, inspect session logs for the session artifacts.
• Session failures now report structured error codes such as render-init-failed, agent-connect-timeout, and supervisor-connect-timeout.
• If package installation changes global Python web dependencies, recreate a dedicated virtual environment and reinstall there.
• GitHub-hosted windows-latest runners are only used for unit tests, doctor, and MCP handshake smoke. Real Webots runtime smoke is exposed as a separate manual workflow for self-hosted Windows runners with Webots installed.
• Runtime-affecting changes now also path-trigger the self-hosted runtime workflow when the interactive-webots runner is available.
• examples/ contains runnable demo assets; benchmark thresholds and pass/fail logic live in the benchmark registry inside the toolkit code.
• Wheel installs use bundled package-local scenario assets; source checkouts continue to use repo-local examples/.
• The self-hosted machine standard for runtime smoke is the runner-owned Python install at D:\actions-runner\python311-shared.