--- id: remote-hardware-service title: Remote Hardware Service sidebar_label: Remote Hardware --- :::warning GPIO access is fundamentally dangerous because invalid options can physically damage or destroy your hardware. Ensure that you fully understand the schematic for your particular device before trying this as we do not offer a warranty. Use at your own risk. ::: :::note This feature uses a preinstalled module in the device code and associated command line flags/classes in the python code. You'll need to be running at least version 1.2.23 (or later) of the python and device code to use this feature. ::: You can get the latest python tool/library with `pip3 install --upgrade meshtastic` on Windows/Linux/OS-X. See the [python section](/docs/software/python/python-installation) for more details. ## Supported operations in the initial release - Set any GPIO - Read any GPIO - Receive notification of changes in any GPIO ## Setup To prevent access from untrusted users, you must first make a `gpio` channel that is used for authenticated access to this feature. You'll need to install this channel on both the local and remote node. The procedure using the python command line tool is: 1. Connect local device via USB 2. Create a gpio channel ```shell meshtastic --ch-add gpio ``` :::tip If doing local testing, may want to change the speed of the channel at this time, too. (ex: "meshtastic --ch-mediumfast") ::: 3. Check the channel has been created and copy the long "Complete URL" that contains all the channels on that device ```shell meshtastic --info ``` 4. Connect the remote device via USB (or use the [remote admin](device-remote-admin) feature to reach it through the mesh) 5. Set it to join the gpio channel you created ```shell meshtastic --seturl theurlyoucopiedinstep3 ``` Now both devices should be able to talk over the `gpio` channel. Send a text message from one the other other verify. Also run "--nodes" to verify the second node shows up. ## A little bit of information about masks To determine the appropriate mask for the pin(s) that you want to know. The python program (and output) below might help: ``` >>> for i in range(1,45): ... print(f'GPIO:{i} mask:{hex(2**i)}') ... GPIO:1 mask:0x2 GPIO:2 mask:0x4 GPIO:3 mask:0x8 GPIO:4 mask:0x10 GPIO:5 mask:0x20 GPIO:6 mask:0x40 GPIO:7 mask:0x80 GPIO:8 mask:0x100 GPIO:9 mask:0x200 GPIO:10 mask:0x400 GPIO:11 mask:0x800 GPIO:12 mask:0x1000 GPIO:13 mask:0x2000 GPIO:14 mask:0x4000 GPIO:15 mask:0x8000 GPIO:16 mask:0x10000 GPIO:17 mask:0x20000 GPIO:18 mask:0x40000 GPIO:19 mask:0x80000 GPIO:20 mask:0x100000 GPIO:21 mask:0x200000 GPIO:22 mask:0x400000 GPIO:23 mask:0x800000 GPIO:24 mask:0x1000000 GPIO:25 mask:0x2000000 GPIO:26 mask:0x4000000 GPIO:27 mask:0x8000000 GPIO:28 mask:0x10000000 GPIO:29 mask:0x20000000 GPIO:30 mask:0x40000000 GPIO:31 mask:0x80000000 GPIO:32 mask:0x100000000 GPIO:33 mask:0x200000000 GPIO:34 mask:0x400000000 GPIO:35 mask:0x800000000 GPIO:36 mask:0x1000000000 GPIO:37 mask:0x2000000000 GPIO:38 mask:0x4000000000 GPIO:39 mask:0x8000000000 GPIO:40 mask:0x10000000000 GPIO:41 mask:0x20000000000 GPIO:42 mask:0x40000000000 GPIO:43 mask:0x80000000000 GPIO:44 mask:0x100000000000 ``` ## How to easily test GPIO operations? You can add a simple LED and resistor to validate that the GPIO operations work as expected. Used the tutorial at https://www.instructables.com/Slide-Switch-With-Arduino-Uno-R3/ as a guide. Need: - 2 Meshtastic devices (one device could be on a local computer, and the other one just has to be powered and is the one with the LED to be connected to it) - 2 wires (black and yellow; they can be any color but typically black is used for ground) - breadboard (optional) - 1 LED - 1 220Ω resistor (somewhat optional, but recommended) Prep: - disconnect the remote device from power (battery/usb) - add a resistor from yellow wire to the one end of the LED (either end of the resistor is ok, either end of the LED is ok) - add the yellow wire from a GPIO pin that will not cause any issues (ex: for TLoraV1, we can use GPIO21) - add the black "ground" wire from the ground pin on the device (ex: for TLoraV1 it is the end pin next to the RST button) to the other end of the LED - power on the device Validation: By default, the pin may be "off" or "on". (It will most likely "off".) See the steps below for running commands. In the example of GPIO21, the mask would be 0x200000. [T-Lora v1 with LED on GPIO 21](/img/LED_on_TLoraV1.jpg) ## Doing GPIO operations You can programmatically do operations from your own python code by using the Meshtastic `RemoteHardwareClient` class. See the [python API](/docs/software/python/python-installation) documentation for more details. ## Using GPIOs from the python CLI Writing a GPIO (ex: turn "on" GPIO4): ```shell title="Expected output" $ meshtastic --port /dev/ttyUSB0 --gpio-wrb 4 1 --dest \!28979058 Connected to radio Writing GPIO mask 0x10 with value 0x10 to !28979058 ``` Reading a GPIO (ex: read GPIO4): ```shell title="Expected output" $ meshtastic --port /dev/ttyUSB0 --gpio-rd 0x10 --dest \!28979058 Connected to radio Reading GPIO mask 0x10 from !28979058 GPIO read response gpio_value=16 ``` :::note If the mask and the gpio_value match, then the value is "on". If the gpio_value is 0, then the value is "off". ::: Watching for GPIO changes (ex: watching GPIO4 for changes): ```shell title="Expected output" $ meshtastic --port /dev/ttyUSB0 --gpio-watch 0x10 --dest \!28979058 Connected to radio Watching GPIO mask 0x10 from !28979058 Received RemoteHardware typ=GPIOS_CHANGED, gpio_value=16 Received RemoteHardware typ=GPIOS_CHANGED, gpio_value=0 Received RemoteHardware typ=GPIOS_CHANGED, gpio_value=16 < press ctrl-c to exit > ```