Robin Mueller
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Monorepo for Rust support of VA416XX family of radiation hardened MCUs
110 lines
3.8 KiB
Markdown
110 lines
3.8 KiB
Markdown
[![build](https://github.com/us-irs/va416xx-rs/actions/workflows/ci.yml/badge.svg)](https://github.com/us-irs/va416xx-rs/actions/workflows/ci.yml)
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Vorago VA416xx Rust Support
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=========
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This crate collection provided support to write Rust applications for the VA416XX family
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of devices.
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## List of crates
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This workspace contains the following crates:
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- The [`va416xx`](https://egit.irs.uni-stuttgart.de/rust/va416xx-rs/src/branch/main/va416xx)
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PAC crate containing basic low-level register definition
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- The [`va416xx-hal`](https://egit.irs.uni-stuttgart.de/rust/va416xx-rs/src/branch/main/va416xx-hal)
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HAL crate containing higher-level abstractions on top of the PAC register crate.
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- The [`vorago-peb1`](https://egit.irs.uni-stuttgart.de/rust/va416xx-rs/src/branch/main/vorago-peb1)
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BSP crate containing support for the PEB1 development board.
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It also contains the following helper crates:
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- The `examples` crates contains various example applications for the HAL and the PAC.
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## Using the `.cargo/config.toml` file
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Use the following command to have a starting `config.toml` file
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```sh
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cp .cargo/def-config.toml .cargo/config.toml
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```
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You then can adapt the `config.toml` to your needs. For example, you can configure runners
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to conveniently flash with `cargo run`.
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## Using the sample VS Code files
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Use the following command to have a starting configuration for VS Code:
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```sh
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cp -rT vscode .vscode
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```
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You can then adapt the files in `.vscode` to your needs.
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## Flashing, running and debugging the software
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You can use CLI or VS Code for flashing, running and debugging. In any case, take
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care of installing the pre-requisites first.
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### Pre-Requisites
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1. [SEGGER J-Link tools](https://www.segger.com/downloads/jlink/) installed
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2. [gdb-multiarch](https://packages.debian.org/sid/gdb-multiarch) or similar
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cross-architecture debugger installed. All commands here assume `gdb-multiarch`.
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### Using CLI
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You can build the blinky example application with the following command
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```sh
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cargo build --example blinky
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```
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Start the GDB server first. The server needs to be started with a certain configuration and with
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a JLink script to disable ROM protection.
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For example, on Debian based system the following command can be used to do this (this command
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is also run when running the `jlink-gdb.sh` script)
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```sh
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JLinkGDBServer -select USB -device Cortex-M4 -endian little -if SWD -speed 2000 \
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-LocalhostOnly -vd -jlinkscriptfile ./jlink/JLinkSettings.JLinkScript
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```
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After this, you can flash and debug the application with the following command
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```sh
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gdb-mutliarch -q -x jlink/jlink.gdb target/thumbv7em-none-eabihf/debug/examples/blinky
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```
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Please note that you can automate all steps except starting the GDB server by using a cargo
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runner configuration, for example with the following lines in your `.cargo/config.toml` file:
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```toml
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[target.'cfg(all(target_arch = "arm", target_os = "none"))']
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runner = "gdb-multiarch -q -x jlink/jlink.gdb"
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```
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After that, you can simply use `cargo run --example blinky` to flash the blinky
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example.
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### Using VS Code
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Assuming a working debug connection to your VA108xx board, you can debug using VS Code with
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the [`Cortex-Debug` plugin](https://marketplace.visualstudio.com/items?itemName=marus25.cortex-debug).
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Some sample configuration files for VS code were provided and can be used by running
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`cp -rT vscode .vscode` like specified above. After that, you can use `Run and Debug`
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to automatically rebuild and flash your application.
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If you would like to use a custom GDB application, you can specify the gdb binary in the following
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configuration variables in your `settings.json`:
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- `"cortex-debug.gdbPath"`
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- `"cortex-debug.gdbPath.linux"`
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- `"cortex-debug.gdbPath.windows"`
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- `"cortex-debug.gdbPath.osx"`
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The provided VS Code configurations also provide an integrated RTT logger, which you can access
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via the terminal at `RTT Ch:0 console`.
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