Jacdac implementation for STM32F0 and similar
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README.md

Jacdac for STM32F0xx and STM32G0xx

This repository contains firmware for Jacdac modules based on STM32F0xx and STM32G0xx chips and is part of the Jacdac Module Development Kit.

(The STM32G0xx support is still a work in progress.)

Bootloader

This repository contains both the firmware for running services (eg., accelerometer service) on a Jacdac module, and a bootloader which allows for updating the firmware using the Jacdac protocol. This update process can be performed by the user from the Jacdac website (while developing firmware you will typically use a debugger to deploy both the bootloader and the firmware).

Building

The top-level repo to build is jacdac-msr-modules. It imports as submodules this repo (jacdac-stm32x0) and jacdac-c (which contains platform-independent code implementing Jacdac services, as well as various I2C drivers).

When building your own firmware, you will need to create your own repository from jacdac-msr-modules template. You can do it by following this link https://github.com/microsoft/jacdac-msr-modules/generate or using the green "Use this template" button in top-right corner at https://github.com/microsoft/jacdac-msr-modules If you're just playing around, you can simply clone jacdac-msr-modules.

All the instructions below use your copy of jacdac-msr-modules as the root folder. You typically will not need to fork jacdac-stm32x0 nor jacdac-c.

The build instructions are here, and not in jacdac-msr-modules, to avoid them getting stale in its various copies.

You will need a Unix-like environment to build the firmware (see below for instructions on how to get that on Windows).

  • install arm-none-eabi-gcc (we've been using 9-2019-q4-major); please note that gcc-arm-none-eabi that comes with Ubuntu won't work
  • install openocd (optional when using Black Magic Probe)
  • install node.js (some linux distros have old versions of Node; get at least 14.5.2 from NodeSource)
  • install GNU Make
  • run make; you should get a successful build

Upon first run of make, a Makefile.user file will be created. You will want to adjust the settings in there - there are comments in there that should guide you through the process.

To deploy the firmware to a module you will need a debugger interface. You have three options:

  • Black Magic Probe; you can also re-program other debuggers with BMP firmware
  • a CMSIS-DAP debugger; we've been using Particle Debugger
  • an ST-LINK/V2 or one of its clones You will want to set the right interface in Makefile.user.

Following commands can be used to deploy firmware:

  • make run BL=1 - deploy bootloader
  • make run - deploy firmware
  • make full-flash - deploy both bootloader and firmware
  • make flash-loop - run flashing process in a loop - you can flash multiple devices in a row this way

Aliases:

  • make r for make run
  • make l for make flash-loop
  • make ff for make full-flash

Other than the building/deployment targets, the following might be of note:

  • make st - print RAM/flash stats for the current firmware
  • make stf - same, but break it up by function, not only file
  • make gdb - run GDB debugger
  • make clean - clean (duh!)
  • make drop - build all firmware images specified in DROP_TARGETS

Building on Windows

You will need a Unix-like environment to build the firmware. Luckily, you most likely already have one - it comes with Git for Windows. If you do not have Git for Windows yet, install it. Then you will need to install GNU Make:

  • download GNU Make (without guile) from EzWinPorts
  • open Administrator command prompt
  • run cd "\Program Files\Git\usr"
  • run bin\unzip.exe c:\Users\<you>\Downloads\make-4.3-without-guile-w32-bin.zip replacing <you> with your user name

Head to Start -> Git Bash. When you type make you should now see make: *** No targets specified and no makefile found. Stop..

Now install GNU Arm Embedded Toolchain version 9-2019-q4-major (do not use other versions for now). Get the .exe installer, and agree to adding the tools to your PATH variable. If the installer fails to add to PATH, then do so yourself, adding: C:\Program Files (x86)\GNU Tools Arm Embedded\9 2019-q4-major\bin

You will also need to install node.js - take the Windows .msi 64 bit installer.

If you run Git Bash again (it has to be restarted to see change in PATH), and type arm-none-eabi-gcc --version you should see something about 9-2019-q4-major, and if you type node --version you should get its version number.

If using Black Magic Probe, connect it to your computer. You should see two COM ports that correspond to it in Device Manager (for example COM7 and COM8) You will want to use the lower numbered one (for example COM7).

If using stlink or cmsis/dap, you'll need to install openocd (TODO: this currently doesn't work):

If you want to extract somewhere else, make sure to add the bin somefolder to PATH.

Now, follow the usual build instructions above.

Note: using WSL2 instead of the bash shell etc coming with Git is not recommended since it cannot access USB for deployment and debugging.

Adding new modules

  • create a new repo from jacdac-msr-modules; let's say the new repo is called jacdac-acme-corp-modules
  • replace string jacdac-msr-modules with jacdac-acme-corp-modules in package.json
  • copy targets/_example/ to targets/acme-corp/ (replaceing acme-corp with the name of the series of modules)
  • edit targets/acme-corp/board.h to match your module
  • you likely do not need to edit targets/acme-corp/config.mk, even if using a beefier MCU from the F03x family - they should be backward-compatible
  • edit targets/acme-corp/profile/module.c to include your module name and used services (follow comments in module.c); see jd_services.h for list of services
  • rename module.c to match the type of module (eg. servo.c)
  • if you have several modules with non-conflicting board.h definitions, you can create more files under targets/acme-corp/profile/; otherwise you'll need to create targets/acme-corp-2 or something similar
  • edit Makefile.user to set TRG, eg. TRG = acme-corp servo
  • run make; this will generate a new unique identifier and place as an argument of FIRMWARE_IDENTIFIER macro
  • make sure to never change the firmware identifier number, as that will break future firmware updates

If you copy targets/jm-*/profiles/something.c to start your own module, remember to rename it, and set the FIRMWARE_IDENTIFIER to 0 (the one in targets/_examples already has it set to 0). This way, the build process will generate a new firmware identifier.

Now, edit DROP_TARGETS in Makefile to only include your acme-corp folder (and in future acme-corp-v2 etc.). You don't need to build jm-* modules, so remove them from DROP_TARGETS.

When you run make drop now, you should get a .uf2 file combining firmware for all your modules.

Adding new services and drivers

This topic is covered in jacdac-c. When adding services or drivers, you can put them in addons/ folder of your modules repo, or submit them as PRs in jacdac-c.

Contributing

This project welcomes contributions and suggestions. Most contributions require you to agree to a Contributor License Agreement (CLA) declaring that you have the right to, and actually do, grant us the rights to use your contribution. For details, visit https://cla.opensource.microsoft.com.

When you submit a pull request, a CLA bot will automatically determine whether you need to provide a CLA and decorate the PR appropriately (e.g., status check, comment). Simply follow the instructions provided by the bot. You will only need to do this once across all repos using our CLA.

This project has adopted the Microsoft Open Source Code of Conduct. For more information see the Code of Conduct FAQ or contact opencode@microsoft.com with any additional questions or comments.