For these parts, the program needs to know more about the power supply scheme in order to successfully transition from Run* mode to Run mode. For an explaination of Run* mode, see RM0433 Rev 7 Section 6.6.1 "System/D3 domain modes".
For your own code, see the
documentation
for the builder methods on pwr. However to make things easier for the
examples, there are feature flags that set common power configurations.
| Flag | Situation | Applicable Boards (non-exhaustive) |
|---|---|---|
example-smps |
Board uses Internal SMPS | Any Nucleo with -Q suffix |
example-ldo |
Board uses LDO, internal SMPS unconnected | |
| none | Parts without internal SMPS |
The results of using the wrong power configuration for your hardware are undefined(!). If you can still access the debug port, load a simple example with the correct power configuration and power cycle the board.
Example specific features have been defined to enable different logging outputs for the examples. If no logging feature is selected logging will be disabled and the panic handler will be halt. Supported logging methods are:
Compile with the feature log-rtt
cargo build --features=stm32h750v,rt,log-rtt --examples
Compile with the feature log-semihost. Note this method of logging is very slow.
cargo build --features=stm32h750v,rt,log-semihost --examples
Compile with the feature log-itm
cargo build --features=stm32h750v,rt,log-itm --examples
Note that you may need to configure your debugger to output ITM, and/or configure the ITM yourself. See ITM.md
If you select this feature flag, then the call to logger::init() internally
configures the ITM peripheral. If you also interact with the ITM peripheral
yourself, you should be aware that it has already been configured.
Although you can compile the provided examples directly, for your own project it is recommended to make a new binary crate or start one based on existing board specific examples / BSPs. Most examples will require tweaks to work for your particular board. You should copy the examples into your binary crate and make any necessary adjustments.
If you can find a suitable BSP, these usually also supply files which make development easier. They might also contain board specific code or adaptions required to make the examples work for your particular board.
The hello world of embedded development is usually to blink a LED. This example is contained within the examples folder.
-
Make sure you have the required Rust cross-compiler installed. If you have not done this yet, you can run the following command to install it
rustup target add thumbv7em-none-eabihf
-
Create a new binary crate with
cargo init -
To ensure that
cargo buildcross-compiles, it is recommended to create a.cargo/config.tomlfile. You can use theconfig.tomlprovided in the cortex-m-quickstart repository and uncommenttarget = "thumbv7em-none-eabihf". -
Copy
memory.xinto your project. This file contains information required by the linker. -
Copy
blinky.rsto thesrc/main.rsin your binary crate and remove references to theutilitiesmodule. -
Add a dependency on the HAL in
Cargo.toml. Make sure to replace the configuration featurestm32h743vto match the part you are using:[dependencies.stm32h7xx-hal] version = "^0" features = ["stm32h743v"]
You should also add dependencies for the other crates you need, such as
cortex-m-rtorembedded-hal. -
Build the application with
cargo build
-
Flashing the MCU typically works differently for different boards. You can usually find instructions in the board specific crates or BSPs.