atsamd & atsame support for Rust
This repository holds various crates that support/enable working with Atmel samd11
, samd21
, samd51
and same5x
based devices using Rust.
The Peripheral Access Crates (PACs) are automatically generated, and provide low-level access to the peripherals specified by a device's SVD file.
The Hardware Abstraction Layer (HAL) is the result of reading the datasheet for the device and encoding a type-safe layer over the raw PACs. This crate implements traits specified by the embedded-hal project, making it compatible with various drivers in the embedded rust ecosystem.
In addition to the PACs and HAL, there numerous Board Support Packages (BSPs) for popular development boards. They aim to rename pins to match silk screens or Arduino pin assignments, add helpers for initialization, and re-export the atsamd-hal
crate. These BSPs are listed beside their respective PACs below.
Building
Make sure that you have a new enough version of the gcc toolchain; the one installable even on recent versions of Ubuntu can fail to correctly link the vector table:
$ sudo add-apt-repository ppa:team-gcc-arm-embedded/ppa -y
$ sudo apt update
$ sudo apt install gcc-arm-embedded
You'll need to add the proper compilation target prior to building as well:
$ # for samd11, samd21:
$ rustup target add thumbv6m-none-eabi
$ # for samd51, same51, same53, same54:
$ rustup target add thumbv7em-none-eabihf
Since a number of different MCUs are used, building the examples requires changing directory into one of the board support package directories prior to building. For example:
$ cd metro_m0
$ cargo build --examples
$ cd ../gemma_m0
$ cargo build --examples
Building everything locally
If you'd like to build all the same things that the CI would build but on your local system, you can run:
$ ./build-all.py
Please note that this script requires Python 3.
Getting code onto the device: Gemma M0
If you want to flash the device using the tools that come with the Adafruit arduino support package:
$ cd gemma_m0
$ cargo build --example blinky_basic
$ arm-none-eabi-objcopy -O binary \
target/thumbv6m-none-eabi/debug/examples/blinky_basic \
target/thumbv6m-none-eabi/debug/examples/blinky_basic.bin
$ stty -F /dev/ttyACM1 ospeed 1200
$ ~/.arduino15/packages/arduino/tools/bossac/1.7.0/bossac -i -d \
--port=ttyACM1 -U -e -w -v \
target/thumbv6m-none-eabi/debug/examples/blinky_basic.bin -R
This same technique should work for all of the Adafruit M0/M4 boards, as they all ship with a bossac compatible bootloader. Note that M0 devices may need -o 0x2000
and M4 devices may need -o 0x4000
added to the bossac
parameter lists.
Getting code onto the device: JLink
If you have a board with a SWD debug header, such as the Metro M0, or if you attached the header yourself, you can use your JLink together with gdb. @wez prefers using the JLinkGDBServer, but you can also use OpenOCD.
In one window, run JLinkGDBServer -if SWD -device ATSAMD21G18
, then in another, run these commands from the root of this repo so that you pick up its .gdbinit
file:
$ cargo build --manifest-path metro_m0/Cargo.toml --example blinky_basic
$ arm-none-eabi-gdb metro_m0/target/thumbv6m-none-eabi/debug/examples/blinky_basic
If you prefer or otherwise need to use OpenOCD, then you'd run it in place of the JLinkGDBServer and then modify the .gdbinit
file to comment out the JLink section and uncomment the OpenOCD section.
Semihosting
If you want to enable semihosting to be able to see debugging messages, this will enable them in some of the example crates. Note that when you enable semihosting, the resultant firmware will only run when a debugger is attached to your board; it will fault the MCU if the debugger is absent:
$ cargo build --manifest-path metro_m0/Cargo.toml \
--example blinky_basic --features use_semihosting
Getting code onto the devices with bootloaders: hf2-rs
hf2-rs implements Microsofts HID Flashing Format (HF2) to upload firmware to UF2 bootloaders. UF2 is factory programmed extensively by Microsoft MakeCode and Adafruit hardware.
The cargo-hf2
crate replaces the cargo build
command to include flashing over USB to connected UF2 devices, using hf2 flashing over HID protocol.
$ cargo install cargo-hf2
$ cargo hf2 --manifest-path metro_m0/Cargo.toml \
--example blinky_basic --features unproven --release
For more information, refer to the README
files for each crate:
Getting code onto the devices with bootloaders: uf2conv-rs
uf2conv adds a uf2 header Microsofts HID Flashing Format (UF2) for copying over to UF2 bootloader mass storage devices. UF2 is factory programmed extensively by Microsoft MakeCode and Adafruit hardware.
cargo-binutils replaces the cargo build
command to find and convert elf files into binary.
Install the dependencies
$ rustup component add llvm-tools-preview
$ cargo install uf2conv cargo-binutils
Then for say, metro_m0 examples
$ cargo objcopy --example blinky_basic --features unproven --release -- -O binary blinky_basic.bin
$ uf2conv blinky_basic.bin --base 0x2000 --output blinky_basic.uf2
$ cp blinky_basic.uf2 /Volumes/PYGAMERBOOT/
For more information, refer to the README
files for each crate:
Adding a new board
See our wiki page for a complete guide on adding a new board.
License
The included SVD files are sourced from http://packs.download.atmel.com/ and are licensed under the Apache License, Version 2.0 (LICENSE-APACHE or http://www.apache.org/licenses/LICENSE-2.0).
The remainder of the code is licensed under either of:
- Apache License, Version 2.0 (LICENSE-APACHE or http://www.apache.org/licenses/LICENSE-2.0)
- MIT license (LICENSE-MIT or http://opensource.org/licenses/MIT)
at your option.
Contribution
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.