⚠️ Note: The stm32l0xx HAL team is looking for more maintainers! Do you think you could help out with reviewing contributions and improving the codebase? If yes, please let us know in issue #211!
stm32l0xx-hal is a Hardware Abstraction Layer (HAL) for the STMicro STM32L0xx family of microcontrollers.
This crate relies on Adam Greig's stm32l0 crate to provide appropriate register definitions and implements a partial set of the embedded-hal traits.
Based on the stm32l1xx-hal crate by Vitaly Domnikov and the stm32f4xx-hal crate by Daniel Egger.
Add the stm32l0xx-hal
crate to your
dependencies in Cargo.toml
and make sure to pick the appropriate mcu-*
Cargo feature to enjoy the full feature set for your MCU (see next section
"Supported Configurations" for more details).
For example, when using the STM32L071KBTx MCU:
[dependencies]
stm32l0xx-hal = { version = "0.10.0", features = ["mcu-STM32L071KBTx", "rt"] }
The STM32L0 family consists of different subfamilies with different peripherals
and I/O configurations. Superficially, the family can be grouped into the
groups stm32l0x1
, stm32l0x2
and stm32l0x3
. However, some aspects like
alternate function mappings for I/O pins do not follow these groups.
In order for the HAL to properly support all those MCUs, we generate some peripheral mappings and corresponding Cargo features using cube-parse.
The easiest way for you to get started, is to use your appropriate mcu-*
feature. For example, when using the STM32L071KBTx MCU, you just set the
mcu-STM32L071KBTx
feature in Cargo.toml
:
# Cargo.toml
[dependencies]
stm32l0xx-hal = { version = "0.10.0", features = ["mcu-STM32L071KBTx", "rt"] }
If you take a look at the Cargo.toml
file, you
can see that mcu-STM32L071KBTx
is just an alias for ["io-STM32L071", "eeprom-6144", "flash-128", "ram-20"]
.
The io-*
features are based on the GPIO peripheral version. This determines
the pin function mapping of the MCU. The features seem to correspond to the
product categories.
Right now, the following features are supported:
io-STM32L021
(Product category 1)io-STM32L031
(Product category 2)io-STM32L051
(Product category 3)io-STM32L071
(Product category 5)
The product categories should be listed in your MCU family datasheet. The name
of the io-*
feature itself is derived from the internal name used in the
STM32CubeMX database. It does not necessarily match the name of the MCU,
for example the STM32L062K8Tx
uses the GPIO peripheral version named
io-STM32L051
.
Flash and RAM sizes are automatically configured by using the appropriate
mcu-*
Cargo feature, as described further up.
If you have an MCU that does not yet have a corresponding mcu-*
feature, or
if the default configuration is incorrect, you can override the memory.x
of
stm32l0xx-hal
by providing your own:
In your crate root, add a file called memory.x
with the correct
configuration. For example:
MEMORY
{
FLASH : ORIGIN = 0x08000000, LENGTH = 64K
RAM : ORIGIN = 0x20000000, LENGTH = 8K
}
Add a build.rs
file with the following content:
use std::env;
use std::fs::File;
use std::io::Write;
use std::path::PathBuf;
fn main() {
// Put the linker script somewhere the linker can find it
let out = &PathBuf::from(env::var_os("OUT_DIR").unwrap());
File::create(out.join("memory.x"))
.unwrap()
.write_all(include_bytes!("memory.x"))
.unwrap();
println!("cargo:rustc-link-search={}", out.display());
println!("cargo:rerun-if-changed=build.rs");
println!("cargo:rerun-if-changed=memory.x");
}
And finally add the disable-linker-script
feature to your stm32l0xx-hal
dependency:
# Cargo.toml
[dependencies]
stm32l0xx-hal = { version = "0.10.0", features = ["mcu-STM32L071K8Ux", "disable-linker-script"] }
rtc
: Enable the RTC API based on rtcc. Enabled by default.
In order to use this HAL, you need the following Setup:
-
Install Rustup
See rustup.rs for details. You may als be able to install Rustup directly through your distro.
-
Install the
arm-none-eabi
compiler toolchainhttps://developer.arm.com/open-source/gnu-toolchain/gnu-rm/downloads
If you cannot install the toolchain directly through your OS / distro, we recommend installing the precompiled binaries to '/usr/local/opt'. Add the bin folders (/bin & /arm-none-eabi/bin) to your environments variable 'PATH'.
-
Install the
thumbv6m-none-eabi
target for RustSimply run
rustup target add thumbv6m-none-eabi
-
Install probe-run to run examples.
cargo install probe-run
For more instructions on how to get started with ARM / Cortex-M programming using Rust, check out the Embedded Rust Book.
You can build examples through Cargo:
$ cargo build --release --examples --features stm32l0x1,rt
Note that not all examples are compatible with all MCUs. You might need to peek into the example source code.
This crate uses probe-run to run examples on target hardware.
To run the blinky
example on an STM32L053 Nucleo:
cargo run --example blinky --features mcu-STM32L053R8Tx -- --chip STM32L053R8Tx
The following instructions outline how-to on flashing the 'serial' example code. This can be extended to any other example code.
- Flash the microcontroller using the flash script
$ ./flash.sh target/thumbv6m-none-eabi/release/examples/serial
- Flash the microcontroller using the openocd flash script
$ ./openocd_flash.sh target/thumbv6m-none-eabi/release/examples/serial
- Revert local dependencies to external cargo and uncomment configurations before committing
0-Clause BSD License, see LICENSE-0BSD.txt for more details.