Ryan Malloy
c0bedde54b
Complete ctypes bindings for all 45 libcp210xmanufacturing functions including structs (BAUD_CONFIG, PORT_CONFIG, DUAL_PORT_CONFIG, QUAD_PORT_CONFIG, FIRMWARE_T), part-number gating, bitmask helpers, and three-tier safety model (none/normal/strict elicitation). New tools: set_vid, set_pid, get/set_interface_string, get/set_flush_buffer_config, get/set_device_mode, get_firmware_version, set_device_version, get/set_baud_rate_config, set_baud_rate_alias, get/set_port_config, get/set_raw_config, create_hex_file, update_firmware.
mcp210x
It's MCP. It's CP210x. It was right there the whole time.
An MCP server for customizing Silicon Labs CP210x USB-UART bridge devices — product strings, serial numbers, power config, udev rules, and device locking — through natural language in Claude Code.
Built on FastMCP with Python ctypes bindings to Silicon Labs' native libcp210xmanufacturing library.
The problem
You plug in three CP2102 boards. They all enumerate as:
Bus 001 Device 004: ID 10c4:ea60 Silicon Labs CP2102 USB to UART Bridge Controller
Bus 001 Device 005: ID 10c4:ea60 Silicon Labs CP2102 USB to UART Bridge Controller
Bus 001 Device 006: ID 10c4:ea60 Silicon Labs CP2102 USB to UART Bridge Controller
Which one is which? Unplug, replug, guess. /dev/ttyUSB0 becomes /dev/ttyUSB2 after a reboot. You write udev rules that match on nothing unique. The Silicon Labs GUI customization tool is 32-bit only and hasn't been updated since 2015.
The fix
> What CP210x devices are connected?
Two devices found:
[0] RYLR998 0033001104645C0B00001130 (serial: 0001)
[1] RYLR998 0033001104645C0B00000D27 (serial: 0001)
> Set up a udev rule for device 0 so it always appears at /dev/rylr998-1130
Each device gets a unique product string baked into its USB descriptor EPROM. Udev rules match on that string to create stable symlinks. Devices survive reboots, port reordering, and hub changes.
Features
- List and inspect connected CP210x devices (part number, VID/PID, strings, power, lock state)
- Write USB descriptors — product string, manufacturer, serial number
- Configure power — max current draw, self-powered vs bus-powered
- Generate udev rules — stable
/dev/symlinks based on product string - Reset device — trigger USB re-enumeration after changes
- Lock device — permanently freeze configuration (with strict confirmation gate)
Safety model
CP210x descriptor EPROM is one-time-programmable with limited write cycles. Writes can't be undone. Locks are permanent. The server enforces a tiered confirmation model:
| Operation | Confirmation |
|---|---|
| Reads | None |
| Writes (strings, power) | MCP elicitation if client supports it; proceeds otherwise |
| Lock | Elicitation required; hard-refuses without it |
The lock gate isn't just a warning — it returns an error and does not proceed if the MCP client can't present a confirmation dialog.
Requirements
- Linux x86_64
libcp210xmanufacturing.so— Silicon Labs CP210x manufacturing library- Python 3.10+
- uv
Installation
1. Native library
Arch Linux (AUR package included):
cd aur/cp210xmanufacturing
makepkg -si
This installs the shared library, headers, and udev rules for non-root USB access.
From source:
cd AN721SW/Linux/LibrarySourcePackages/cp210xmanufacturing
make LIB_ARCH=64
sudo make install
sudo ldconfig
You'll also need udev rules for non-root device access — copy aur/cp210xmanufacturing/SiliconLabs.rules to /usr/lib/udev/rules.d/ and reload.
2. MCP server
uv tool install .
3. Claude Code
claude mcp add cp210x -- uvx mcp210x
For development (runs from source):
claude mcp add cp210x-local -- uv run --directory /path/to/this-repo mcp210x
Tools
| Tool | Description |
|---|---|
list_devices |
List connected CP210x devices with description and serial |
get_device_info |
Full device details — part number, VID/PID, strings, power, lock state |
set_product_string |
Write USB product string (max 126 chars) |
set_manufacturer_string |
Write USB manufacturer string (max 45 chars) |
set_serial_number |
Write USB serial number (max 63 chars) |
set_max_power |
Set max USB power draw in mA (0-500, rounded to nearest 2) |
set_self_powered |
Toggle self-powered vs bus-powered reporting |
reset_device |
USB disconnect/reconnect to apply changes |
lock_device |
Permanently freeze device configuration |
setup_udev_rule |
Generate and install a udev rule for a stable /dev/ symlink |
Architecture
Claude Code ──stdio──▶ FastMCP server (server.py)
│
▼
Python ctypes (bindings.py)
│
▼
libcp210xmanufacturing.so
│
▼
libusb ──▶ CP210x device
The native library uses libusb for device access, separate from the kernel's cp210x serial driver. Both coexist — you can read/write UART data over /dev/ttyUSB0 while customizing USB descriptors through this server.
Project structure
mcp210x/
├── src/mcp210x/
│ ├── server.py # FastMCP tool definitions and elicitation logic
│ ├── bindings.py # ctypes wrapper for libcp210xmanufacturing.so
│ └── __init__.py
├── aur/cp210xmanufacturing/
│ ├── PKGBUILD # Arch Linux package for the native library
│ └── SiliconLabs.rules # udev rules for non-root USB access
├── AN721SW/ # Silicon Labs toolkit (library source)
├── docs/ # Datasheets and application notes
└── pyproject.toml
Complementary tools
This server handles device customization (USB descriptors, power config). For serial communication (sending/receiving data over UART), use mcserial.
Reference
- CP2102 Datasheet
- AN721: Device Customization Guide — source for
libcp210xmanufacturing - AN197: Serial Communication Guide
License
MIT