docs patch 2

Merge pull request 'doc fixes' (#48 ) from va108xx-embassy-doc-fix into main
Reviewed-on: #48
2025-02-13 15:47:50 +01:00 · 2025-02-13 15:38:50 +01:00 · 2025-02-13 15:38:38 +01:00 · 2025-02-13 15:26:41 +01:00 · 2025-02-13 15:26:24 +01:00 · 2025-02-13 15:25:01 +01:00
36 changed files with 917 additions and 124 deletions
--- a/README.md
+++ b/README.md
@ -14,6 +14,8 @@ This workspace contains the following released crates:
  crate containing basic low-level register definition.
 - The [`va108xx-hal`](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/va108xx-hal)
  HAL crate containing higher-level abstractions on top of the PAC register crate.
 - The [`va108xx-embassy`](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/va108xx-embassy)
  crate containing support for running the embassy-rs RTOS.
 - The [`vorago-reb1`](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/vorago-reb1)
  BSP crate containing support for the REB1 development board.
--- a/bootloader/Cargo.toml
+++ b/bootloader/Cargo.toml
@ -15,10 +15,12 @@ num_enum = { version = "0.7", default-features = false }
 static_assertions = "1"
 [dependencies.va108xx-hal]
-path = "../va108xx-hal"
+version = "0.9"
 # path = "../va108xx-hal"
 [dependencies.vorago-reb1]
-path = "../vorago-reb1"
+version = "0.7"
 # path = "../vorago-reb1"
 [features]
 default = []
--- a/examples/embassy/Cargo.toml
+++ b/examples/embassy/Cargo.toml
@ -9,7 +9,10 @@ cortex-m = { version = "0.7", features = ["critical-section-single-core"] }
 cortex-m-rt = "0.7"
 embedded-hal = "1"
 embedded-hal-async = "1"
 embedded-io = "0.6"
 embedded-io-async = "0.6"
 heapless = "0.8"
 static_cell = "2"
 rtt-target = "0.6"
 panic-rtt-target = "0.2"
@ -24,8 +27,8 @@ embassy-executor = { version = "0.7", features = [
  "executor-interrupt"
 ]}
-va108xx-hal = { path = "../../va108xx-hal" }
+va108xx-hal = "0.9"
-va108xx-embassy = { path = "../../va108xx-embassy", default-features = false }
+va108xx-embassy = "0.1"
 [features]
 default = ["ticks-hz-1_000", "va108xx-embassy/irq-oc30-oc31"]
--- a/examples/embassy/src/bin/async-uart-rx.rs
+++ b/examples/embassy/src/bin/async-uart-rx.rs
@ -0,0 +1,171 @@
 //! Asynchronous UART reception example application.
 //!
 //! This application receives data on two UARTs permanently using a ring buffer.
 //! The ring buffer are read them asynchronously. UART A is received on ports PA8 and PA9.
 //! UART B is received on ports PA2 and PA3.
 //!
 //! Instructions:
 //!
 //! 1. Tie a USB to UART converter with RX to PA9 and TX to PA8 for UART A.
 //!    Tie a USB to UART converter with RX to PA3 and TX to PA2 for UART B.
 //! 2. Connect to the serial interface by using an application like Putty or picocom. You can
 //!    type something in the terminal and check if the data is echoed back. You can also check the
 //!    RTT logs to see received data.
 #![no_std]
 #![no_main]
 use core::cell::RefCell;
 use critical_section::Mutex;
 use embassy_executor::Spawner;
 use embassy_time::Instant;
 use embedded_hal::digital::StatefulOutputPin;
 use embedded_io::Write;
 use embedded_io_async::Read;
 use heapless::spsc::{Consumer, Producer, Queue};
 use panic_rtt_target as _;
 use rtt_target::{rprintln, rtt_init_print};
 use va108xx_embassy::embassy;
 use va108xx_hal::{
    gpio::PinsA,
    pac::{self, interrupt},
    prelude::*,
    uart::{
        self, on_interrupt_uart_b_overwriting,
        rx_asynch::{on_interrupt_uart_a, RxAsync},
        RxAsyncSharedConsumer, Tx,
    },
    InterruptConfig,
 };
 const SYSCLK_FREQ: Hertz = Hertz::from_raw(50_000_000);
 static QUEUE_UART_A: static_cell::ConstStaticCell<Queue<u8, 256>> =
    static_cell::ConstStaticCell::new(Queue::new());
 static PRODUCER_UART_A: Mutex<RefCell<Option<Producer<u8, 256>>>> = Mutex::new(RefCell::new(None));
 static QUEUE_UART_B: static_cell::ConstStaticCell<Queue<u8, 256>> =
    static_cell::ConstStaticCell::new(Queue::new());
 static PRODUCER_UART_B: Mutex<RefCell<Option<Producer<u8, 256>>>> = Mutex::new(RefCell::new(None));
 static CONSUMER_UART_B: Mutex<RefCell<Option<Consumer<u8, 256>>>> = Mutex::new(RefCell::new(None));
 // main is itself an async function.
 #[embassy_executor::main]
 async fn main(spawner: Spawner) {
    rtt_init_print!();
    rprintln!("-- VA108xx Async UART RX Demo --");
    let mut dp = pac::Peripherals::take().unwrap();
    // Safety: Only called once here.
    unsafe {
        embassy::init(
            &mut dp.sysconfig,
            &dp.irqsel,
            SYSCLK_FREQ,
            dp.tim23,
            dp.tim22,
        );
    }
    let porta = PinsA::new(&mut dp.sysconfig, dp.porta);
    let mut led0 = porta.pa10.into_readable_push_pull_output();
    let mut led1 = porta.pa7.into_readable_push_pull_output();
    let mut led2 = porta.pa6.into_readable_push_pull_output();
    let tx_uart_a = porta.pa9.into_funsel_2();
    let rx_uart_a = porta.pa8.into_funsel_2();
    let uarta = uart::Uart::new_with_interrupt(
        &mut dp.sysconfig,
        50.MHz(),
        dp.uarta,
        (tx_uart_a, rx_uart_a),
        115200.Hz(),
        InterruptConfig::new(pac::Interrupt::OC2, true, true),
    );
    let tx_uart_b = porta.pa3.into_funsel_2();
    let rx_uart_b = porta.pa2.into_funsel_2();
    let uartb = uart::Uart::new_with_interrupt(
        &mut dp.sysconfig,
        50.MHz(),
        dp.uartb,
        (tx_uart_b, rx_uart_b),
        115200.Hz(),
        InterruptConfig::new(pac::Interrupt::OC3, true, true),
    );
    let (mut tx_uart_a, rx_uart_a) = uarta.split();
    let (tx_uart_b, rx_uart_b) = uartb.split();
    let (prod_uart_a, cons_uart_a) = QUEUE_UART_A.take().split();
    // Pass the producer to the interrupt handler.
    let (prod_uart_b, cons_uart_b) = QUEUE_UART_B.take().split();
    critical_section::with(|cs| {
        *PRODUCER_UART_A.borrow(cs).borrow_mut() = Some(prod_uart_a);
        *PRODUCER_UART_B.borrow(cs).borrow_mut() = Some(prod_uart_b);
        *CONSUMER_UART_B.borrow(cs).borrow_mut() = Some(cons_uart_b);
    });
    let mut async_rx_uart_a = RxAsync::new(rx_uart_a, cons_uart_a);
    let async_rx_uart_b = RxAsyncSharedConsumer::new(rx_uart_b, &CONSUMER_UART_B);
    spawner
        .spawn(uart_b_task(async_rx_uart_b, tx_uart_b))
        .unwrap();
    let mut buf = [0u8; 256];
    loop {
        rprintln!("Current time UART A: {}", Instant::now().as_secs());
        led0.toggle().ok();
        led1.toggle().ok();
        led2.toggle().ok();
        let read_bytes = async_rx_uart_a.read(&mut buf).await.unwrap();
        let read_str = core::str::from_utf8(&buf[..read_bytes]).unwrap();
        rprintln!(
            "Read {} bytes asynchronously on UART A: {:?}",
            read_bytes,
            read_str
        );
        tx_uart_a.write_all(read_str.as_bytes()).unwrap();
    }
 }
 #[embassy_executor::task]
 async fn uart_b_task(mut async_rx: RxAsyncSharedConsumer<pac::Uartb, 256>, mut tx: Tx<pac::Uartb>) {
    let mut buf = [0u8; 256];
    loop {
        rprintln!("Current time UART B: {}", Instant::now().as_secs());
        // Infallible asynchronous operation.
        let read_bytes = async_rx.read(&mut buf).await.unwrap();
        let read_str = core::str::from_utf8(&buf[..read_bytes]).unwrap();
        rprintln!(
            "Read {} bytes asynchronously on UART B: {:?}",
            read_bytes,
            read_str
        );
        tx.write_all(read_str.as_bytes()).unwrap();
    }
 }
 #[interrupt]
 #[allow(non_snake_case)]
 fn OC2() {
    let mut prod =
        critical_section::with(|cs| PRODUCER_UART_A.borrow(cs).borrow_mut().take().unwrap());
    let errors = on_interrupt_uart_a(&mut prod);
    critical_section::with(|cs| *PRODUCER_UART_A.borrow(cs).borrow_mut() = Some(prod));
    // In a production app, we could use a channel to send the errors to the main task.
    if let Err(errors) = errors {
        rprintln!("UART A errors: {:?}", errors);
    }
 }
 #[interrupt]
 #[allow(non_snake_case)]
 fn OC3() {
    let mut prod =
        critical_section::with(|cs| PRODUCER_UART_B.borrow(cs).borrow_mut().take().unwrap());
    let errors = on_interrupt_uart_b_overwriting(&mut prod, &CONSUMER_UART_B);
    critical_section::with(|cs| *PRODUCER_UART_B.borrow(cs).borrow_mut() = Some(prod));
    // In a production app, we could use a channel to send the errors to the main task.
    if let Err(errors) = errors {
        rprintln!("UART B errors: {:?}", errors);
    }
 }
--- a/examples/embassy/src/bin/async-uart-tx.rs
+++ b/examples/embassy/src/bin/async-uart-tx.rs
@ -1,3 +1,13 @@
 //! Asynchronous UART transmission example application.
 //!
 //! This application receives sends 4 strings with different sizes permanently using UART A.
 //! Ports PA8 and PA9 are used for this.
 //!
 //! Instructions:
 //!
 //! 1. Tie a USB to UART converter with RX to PA9 and TX to PA8 for UART A.
 //! 2. Connect to the serial interface by using an application like Putty or picocom. You can
 //!    can verify the correctness of the sent strings.
 #![no_std]
 #![no_main]
 use embassy_executor::Spawner;
@ -28,7 +38,7 @@ const STR_LIST: &[&str] = &[
 #[embassy_executor::main]
 async fn main(_spawner: Spawner) {
    rtt_init_print!();
-    rprintln!("-- VA108xx Embassy Demo --");
+    rprintln!("-- VA108xx Async UART TX Demo --");
    let mut dp = pac::Peripherals::take().unwrap();
--- a/examples/rtic/Cargo.toml
+++ b/examples/rtic/Cargo.toml
@ -22,5 +22,5 @@ rtic-sync = { version = "1.3", features = ["defmt-03"] }
 once_cell = {version = "1", default-features = false, features = ["critical-section"]}
 ringbuf = { version = "0.4.7", default-features = false, features = ["portable-atomic"] }
-va108xx-hal = { version = "0.8", path = "../../va108xx-hal" }
+va108xx-hal = "0.9"
-vorago-reb1 = { path = "../../vorago-reb1" }
+vorago-reb1 = "0.7"
--- a/examples/simple/Cargo.toml
+++ b/examples/simple/Cargo.toml
@ -16,9 +16,8 @@ embedded-io = "0.6"
 cortex-m-semihosting = "0.5.0"
 [dependencies.va108xx-hal]
-path = "../../va108xx-hal"
+version = "0.9"
 version = "0.8"
 features = ["rt", "defmt"]
 [dependencies.vorago-reb1]
-path = "../../vorago-reb1"
+version = "0.7"
--- a/examples/simple/examples/uart.rs
+++ b/examples/simple/examples/uart.rs
@ -27,15 +27,15 @@ fn main() -> ! {
    let gpioa = PinsA::new(&mut dp.sysconfig, dp.porta);
    let tx = gpioa.pa9.into_funsel_2();
    let rx = gpioa.pa8.into_funsel_2();
-
+    let uart = uart::Uart::new_without_interrupt(
    let uarta = uart::Uart::new_without_interrupt(
        &mut dp.sysconfig,
        50.MHz(),
        dp.uarta,
        (tx, rx),
        115200.Hz(),
    );
-    let (mut tx, mut rx) = uarta.split();
+
    let (mut tx, mut rx) = uart.split();
    writeln!(tx, "Hello World\r").unwrap();
    loop {
        // Echo what is received on the serial link.
--- a/flashloader/Cargo.toml
+++ b/flashloader/Cargo.toml
@ -29,7 +29,9 @@ rtic-monotonics = { version = "2", features = ["cortex-m-systick"] }
 rtic-sync = {version = "1", features = ["defmt-03"]}
 [dependencies.va108xx-hal]
-path = "../va108xx-hal"
+version = "0.9"
 # path = "../va108xx-hal"
 [dependencies.vorago-reb1]
-path = "../vorago-reb1"
+version = "0.7"
 # path = "../vorago-reb1"
--- a/va108xx-embassy/CHANGELOG.md
+++ b/va108xx-embassy/CHANGELOG.md
@ -0,0 +1,17 @@
 Change Log
 =======
 All notable changes to this project will be documented in this file.
 The format is based on [Keep a Changelog](http://keepachangelog.com/)
 and this project adheres to [Semantic Versioning](http://semver.org/).
 ## [unreleased]
 ## [v0.1.2] and [v0.1.1] 2025-02-13
 Docs patch
 ## [v0.1.0] 2025-02-13
 Initial release
--- a/va108xx-embassy/Cargo.toml
+++ b/va108xx-embassy/Cargo.toml
@ -1,11 +1,17 @@
 [package]
 name = "va108xx-embassy"
-version = "0.1.0"
+version = "0.1.2"
 edition = "2021"
 authors = ["Robin Mueller <muellerr@irs.uni-stuttgart.de>"]
 description = "Embassy-rs support for the Vorago VA108xx family of microcontrollers"
 homepage = "https://egit.irs.uni-stuttgart.de/rust/va108xx-rs"
 repository = "https://egit.irs.uni-stuttgart.de/rust/va108xx-rs"
 license = "Apache-2.0"
 keywords = ["no-std", "hal", "cortex-m", "vorago", "va108xx"]
 categories = ["aerospace", "embedded", "no-std", "hardware-support"]
 [dependencies]
 critical-section = "1"
 portable-atomic = { version = "1", features = ["unsafe-assume-single-core"]}
 embassy-sync = "0.6"
 embassy-executor = "0.7"
@ -14,8 +20,12 @@ embassy-time-queue-utils = "0.1"
 once_cell = { version = "1", default-features = false, features = ["critical-section"] }
-[dependencies.va108xx-hal]
+va108xx-hal = "0.9"
-path = "../va108xx-hal"
+
 [target.'cfg(all(target_arch = "arm", target_os = "none"))'.dependencies]
 portable-atomic = { version = "1", features = ["unsafe-assume-single-core"] }
 [target.'cfg(not(all(target_arch = "arm", target_os = "none")))'.dependencies]
 portable-atomic = "1"
 [features]
 default = ["irq-oc30-oc31"]
@ -25,3 +35,6 @@ irqs-in-lib = []
 irq-oc28-oc29 = ["irqs-in-lib"]
 irq-oc29-oc30 = ["irqs-in-lib"]
 irq-oc30-oc31 = ["irqs-in-lib"]
 [package.metadata.docs.rs]
 rustdoc-args = ["--generate-link-to-definition"]
--- a/va108xx-embassy/docs.sh
+++ b/va108xx-embassy/docs.sh
@ -0,0 +1,3 @@
 #!/bin/sh
 export RUSTDOCFLAGS="--cfg docsrs --generate-link-to-definition -Z unstable-options"
 cargo +nightly doc --open
--- a/va108xx-embassy/src/lib.rs
+++ b/va108xx-embassy/src/lib.rs
@ -23,14 +23,15 @@
 //!
 //! You can disable the default features and then specify one of the features above to use the
 //! documented combination of IRQs. It is also possible to specify custom IRQs by importing and
-//! using the [embassy::embassy_time_driver_irqs] macro to declare the IRQ handlers in the
+//! using the [embassy_time_driver_irqs] macro to declare the IRQ handlers in the
 //! application code. If this is done, [embassy::init_with_custom_irqs] must be used
 //! method to pass the IRQ numbers to the library.
 //!
 //! ## Examples
 //!
-//! [embassy example project](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/embassy)
+//! [embassy example projects](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/embassy)
 #![no_std]
 #![cfg_attr(docsrs, feature(doc_auto_cfg))]
 use core::cell::{Cell, RefCell};
 use critical_section::CriticalSection;
 use embassy_sync::blocking_mutex::CriticalSectionMutex as Mutex;
@ -62,7 +63,7 @@ time_driver_impl!(
 /// the feature flags specified. However, the macro is exported to allow users to specify the
 /// interrupt handlers themselves.
 ///
-/// Please note that you have to explicitely import the [va108xx_hal::pac::interrupt]
+/// Please note that you have to explicitely import the [macro@va108xx_hal::pac::interrupt]
 /// macro in the application code in case this macro is used there.
 #[macro_export]
 macro_rules! embassy_time_driver_irqs {
@ -299,7 +300,7 @@ impl TimerDriver {
                        .cnt_value()
                        .write(|w| unsafe { w.bits(remaining_ticks.unwrap() as u32) });
                    alarm_tim.ctrl().modify(|_, w| w.irq_enb().set_bit());
-                    alarm_tim.enable().write(|w| unsafe { w.bits(1) })
+                    alarm_tim.enable().write(|w| unsafe { w.bits(1) });
                }
            }
        })
--- a/va108xx-hal/CHANGELOG.md
+++ b/va108xx-hal/CHANGELOG.md
@ -10,6 +10,10 @@ and this project adheres to [Semantic Versioning](http://semver.org/).
 ## [v0.9.0]
 ## Fixed
 - Important bugfix for UART driver which causes UART B drivers not to work.
 ## Removed
 - Deleted some HAL re-exports in the PWM module
@ -38,6 +42,7 @@ and this project adheres to [Semantic Versioning](http://semver.org/).
 - `enable_interrupt` and `disable_interrupt` renamed to `enable_nvic_interrupt` and
  `disable_nvic_interrupt` to distinguish them from peripheral interrupts more clearly.
 - `port_mux` renamed to `port_function_select`
 - Renamed `IrqUartErrors` to `UartErrors`.
 ## Added
@ -45,6 +50,7 @@ and this project adheres to [Semantic Versioning](http://semver.org/).
  methods.
 - Asynchronous GPIO support.
 - Asynchronous UART TX support.
 - Asynchronous UART RX support.
 - Add new `get_tim_raw` unsafe method to retrieve TIM peripheral blocks.
 - `Uart::with_with_interrupt` and `Uart::new_without_interrupt`
--- a/va108xx-hal/Cargo.toml
+++ b/va108xx-hal/Cargo.toml
@ -1,6 +1,6 @@
 [package]
 name = "va108xx-hal"
-version = "0.8.0"
+version = "0.9.0"
 authors = ["Robin Mueller <muellerr@irs.uni-stuttgart.de>"]
 edition = "2021"
 description = "HAL for the Vorago VA108xx family of microcontrollers"
@ -24,10 +24,12 @@ fugit = "0.3"
 typenum = "1"
 critical-section = "1"
 delegate = ">=0.12, <=0.13"
 heapless = "0.8"
 static_cell = "2"
 thiserror = { version = "2", default-features = false }
 void = { version = "1", default-features = false }
 once_cell = {version = "1", default-features = false }
-va108xx = { version = "0.3", default-features = false, features = ["critical-section"] }
+va108xx = { version = "0.4", default-features = false, features = ["critical-section"] }
 embassy-sync = "0.6"
 defmt = { version = "0.3", optional = true }
--- a/va108xx-hal/README.md
+++ b/va108xx-hal/README.md
@ -25,12 +25,6 @@ rustup target add thumbv6m-none-eabi
 After that, you can use `cargo build` to build the development version of the crate.
 If you have not done this yet, it is recommended to read some of the excellent resources
 available to learn Rust:
 - [Rust Embedded Book](https://docs.rust-embedded.org/book/)
 - [Rust Discovery Book](https://docs.rust-embedded.org/discovery/)
 ## Setting up your own binary crate
 If you have a custom board, you might be interested in setting up a new binary crate for your
@ -65,3 +59,11 @@ is contained within the
 7. Flashing the board might work differently for different boards and there is usually
   more than one way. You can find example instructions in primary README.
 ## Embedded Rust
 If you have not done this yet, it is recommended to read some of the excellent resources available
 to learn Rust:
 - [Rust Embedded Book](https://docs.rust-embedded.org/book/)
 - [Rust Discovery Book](https://docs.rust-embedded.org/discovery/)
--- a/va108xx-hal/src/clock.rs
+++ b/va108xx-hal/src/clock.rs
@ -11,6 +11,7 @@ static SYS_CLOCK: Mutex<OnceCell<Hertz>> = Mutex::new(OnceCell::new());
 pub type PeripheralClocks = PeripheralSelect;
 #[derive(Debug, PartialEq, Eq)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum FilterClkSel {
    SysClk = 0,
    Clk1 = 1,
@ -39,13 +40,27 @@ pub fn get_sys_clock() -> Option<Hertz> {
 pub fn set_clk_div_register(syscfg: &mut va108xx::Sysconfig, clk_sel: FilterClkSel, div: u32) {
    match clk_sel {
        FilterClkSel::SysClk => (),
-        FilterClkSel::Clk1 => syscfg.ioconfig_clkdiv1().write(|w| unsafe { w.bits(div) }),
+        FilterClkSel::Clk1 => {
-        FilterClkSel::Clk2 => syscfg.ioconfig_clkdiv2().write(|w| unsafe { w.bits(div) }),
+            syscfg.ioconfig_clkdiv1().write(|w| unsafe { w.bits(div) });
-        FilterClkSel::Clk3 => syscfg.ioconfig_clkdiv3().write(|w| unsafe { w.bits(div) }),
+        }
-        FilterClkSel::Clk4 => syscfg.ioconfig_clkdiv4().write(|w| unsafe { w.bits(div) }),
+        FilterClkSel::Clk2 => {
-        FilterClkSel::Clk5 => syscfg.ioconfig_clkdiv5().write(|w| unsafe { w.bits(div) }),
+            syscfg.ioconfig_clkdiv2().write(|w| unsafe { w.bits(div) });
-        FilterClkSel::Clk6 => syscfg.ioconfig_clkdiv6().write(|w| unsafe { w.bits(div) }),
+        }
-        FilterClkSel::Clk7 => syscfg.ioconfig_clkdiv7().write(|w| unsafe { w.bits(div) }),
+        FilterClkSel::Clk3 => {
            syscfg.ioconfig_clkdiv3().write(|w| unsafe { w.bits(div) });
        }
        FilterClkSel::Clk4 => {
            syscfg.ioconfig_clkdiv4().write(|w| unsafe { w.bits(div) });
        }
        FilterClkSel::Clk5 => {
            syscfg.ioconfig_clkdiv5().write(|w| unsafe { w.bits(div) });
        }
        FilterClkSel::Clk6 => {
            syscfg.ioconfig_clkdiv6().write(|w| unsafe { w.bits(div) });
        }
        FilterClkSel::Clk7 => {
            syscfg.ioconfig_clkdiv7().write(|w| unsafe { w.bits(div) });
        }
    }
 }
--- a/va108xx-hal/src/gpio/asynch.rs
+++ b/va108xx-hal/src/gpio/asynch.rs
@ -4,7 +4,7 @@
 //! the [embedded_hal_async::digital::Wait] trait. These types allow for asynchronous waiting
 //! on GPIO pins. Please note that this module does not specify/declare the interrupt handlers
 //! which must be provided for async support to work. However, it provides one generic
-//! [handler][handle_interrupt_for_async_gpio] which should be called in ALL user interrupt handlers
+//! [handler][on_interrupt_for_asynch_gpio] which should be called in ALL user interrupt handlers
 //! which handle GPIO interrupts.
 //!
 //! # Example
@ -90,7 +90,7 @@ pub struct InputPinFuture {
 impl InputPinFuture {
    /// # Safety
    ///
-    /// This calls [Self::new] but uses [pac::Peripherals::steal] to get the system configuration
+    /// This calls [Self::new_with_dyn_pin] but uses [pac::Peripherals::steal] to get the system configuration
    /// and IRQ selection peripherals. Users must ensure that the registers and configuration
    /// related to this input pin are not being used elsewhere concurrently.
    pub unsafe fn new_unchecked_with_dyn_pin(
@ -127,7 +127,7 @@ impl InputPinFuture {
    /// # Safety
    ///
-    /// This calls [Self::new] but uses [pac::Peripherals::steal] to get the system configuration
+    /// This calls [Self::new_with_pin] but uses [pac::Peripherals::steal] to get the system configuration
    /// and IRQ selection peripherals. Users must ensure that the registers and configuration
    /// related to this input pin are not being used elsewhere concurrently.
    pub unsafe fn new_unchecked_with_pin<I: PinId, C: InputConfig>(
@ -200,7 +200,7 @@ impl InputDynPinAsync {
    /// passed as well and is used to route and enable the interrupt.
    ///
    /// Please note that the interrupt handler itself must be provided by the user and the
-    /// generic [handle_interrupt_for_async_gpio] function must be called inside that function for
+    /// generic [on_interrupt_for_asynch_gpio] function must be called inside that function for
    /// the asynchronous functionality to work.
    pub fn new(pin: DynPin, irq: pac::Interrupt) -> Result<Self, InvalidPinTypeError> {
        if !pin.is_input_pin() {
@ -335,7 +335,7 @@ impl<I: PinId, C: InputConfig> InputPinAsync<I, C> {
    /// passed as well and is used to route and enable the interrupt.
    ///
    /// Please note that the interrupt handler itself must be provided by the user and the
-    /// generic [handle_interrupt_for_async_gpio] function must be called inside that function for
+    /// generic [on_interrupt_for_asynch_gpio] function must be called inside that function for
    /// the asynchronous functionality to work.
    pub fn new(pin: Pin<I, pin::Input<C>>, irq: pac::Interrupt) -> Self {
        Self { pin, irq }
--- a/va108xx-hal/src/gpio/dynpin.rs
+++ b/va108xx-hal/src/gpio/dynpin.rs
@ -69,6 +69,7 @@ use crate::{clock::FilterClkSel, enable_nvic_interrupt, pac, FunSel, InterruptCo
 /// Value-level `enum` for disabled configurations
 #[derive(PartialEq, Eq, Clone, Copy)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum DynDisabled {
    Floating,
    PullDown,
@ -156,14 +157,16 @@ pub const DYN_ALT_FUNC_3: DynPinMode = DynPinMode::Alternate(DynAlternate::Sel3)
 //==================================================================================================
 /// Value-level `enum` for pin groups
-#[derive(PartialEq, Eq, Clone, Copy)]
+#[derive(Debug, PartialEq, Eq, Clone, Copy)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum DynGroup {
    A,
    B,
 }
 /// Value-level `struct` representing pin IDs
-#[derive(PartialEq, Eq, Clone, Copy)]
+#[derive(Debug, PartialEq, Eq, Clone, Copy)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct DynPinId {
    pub group: DynGroup,
    pub num: u8,
@ -177,6 +180,7 @@ pub struct DynPinId {
 ///
 /// This `struct` takes ownership of a [`DynPinId`] and provides an API to
 /// access the corresponding regsiters.
 #[derive(Debug)]
 pub(crate) struct DynRegisters(DynPinId);
 // [`DynRegisters`] takes ownership of the [`DynPinId`], and [`DynPin`]
@ -209,6 +213,7 @@ impl DynRegisters {
 ///
 /// This type acts as a type-erased version of [`Pin`]. Every pin is represented
 /// by the same type, and pins are tracked and distinguished at run-time.
 #[derive(Debug)]
 pub struct DynPin {
    pub(crate) regs: DynRegisters,
    mode: DynPinMode,
--- a/va108xx-hal/src/gpio/pin.rs
+++ b/va108xx-hal/src/gpio/pin.rs
@ -119,8 +119,11 @@ pub trait InputConfig: Sealed {
    const DYN: DynInput;
 }
 #[derive(Debug)]
 pub enum Floating {}
 #[derive(Debug)]
 pub enum PullDown {}
 #[derive(Debug)]
 pub enum PullUp {}
 impl InputConfig for Floating {
@ -148,6 +151,7 @@ pub type InputPullUp = Input<PullUp>;
 ///
 /// Type `C` is one of three input configurations: [`Floating`], [`PullDown`] or
 /// [`PullUp`]
 #[derive(Debug)]
 pub struct Input<C: InputConfig> {
    cfg: PhantomData<C>,
 }
@ -177,13 +181,17 @@ pub trait OutputConfig: Sealed {
 pub trait ReadableOutput: Sealed {}
 /// Type-level variant of [`OutputConfig`] for a push-pull configuration
 #[derive(Debug)]
 pub enum PushPull {}
 /// Type-level variant of [`OutputConfig`] for an open drain configuration
 #[derive(Debug)]
 pub enum OpenDrain {}
 /// Type-level variant of [`OutputConfig`] for a readable push-pull configuration
 #[derive(Debug)]
 pub enum ReadablePushPull {}
 /// Type-level variant of [`OutputConfig`] for a readable open-drain configuration
 #[derive(Debug)]
 pub enum ReadableOpenDrain {}
 impl Sealed for PushPull {}
@ -210,6 +218,7 @@ impl OutputConfig for ReadableOpenDrain {
 ///
 /// Type `C` is one of four output configurations: [`PushPull`], [`OpenDrain`] or
 /// their respective readable versions
 #[derive(Debug)]
 pub struct Output<C: OutputConfig> {
    cfg: PhantomData<C>,
 }
@ -304,6 +313,7 @@ macro_rules! pin_id {
        // Need paste macro to use ident in doc attribute
        paste! {
            #[doc = "Pin ID representing pin " $Id]
            #[derive(Debug)]
            pub enum $Id {}
            impl Sealed for $Id {}
            impl PinId for $Id {
@ -321,6 +331,7 @@ macro_rules! pin_id {
 //==================================================================================================
 /// A type-level GPIO pin, parameterized by [PinId] and [PinMode] types
 #[derive(Debug)]
 pub struct Pin<I: PinId, M: PinMode> {
    inner: DynPin,
    phantom: PhantomData<(I, M)>,
@ -741,6 +752,7 @@ macro_rules! pins {
    ) => {
        paste!(
            /// Collection of all the individual [`Pin`]s for a given port (PORTA or PORTB)
            #[derive(Debug)]
            pub struct $PinsName {
                port: $Port,
                $(
--- a/va108xx-hal/src/gpio/reg.rs
+++ b/va108xx-hal/src/gpio/reg.rs
@ -304,7 +304,7 @@ pub(super) unsafe trait RegisterInterface {
        unsafe {
            portreg
                .datamask()
-                .modify(|r, w| w.bits(r.bits() | self.mask_32()))
+                .modify(|r, w| w.bits(r.bits() | self.mask_32()));
        }
    }
@ -316,7 +316,7 @@ pub(super) unsafe trait RegisterInterface {
        unsafe {
            portreg
                .datamask()
-                .modify(|r, w| w.bits(r.bits() & !self.mask_32()))
+                .modify(|r, w| w.bits(r.bits() & !self.mask_32()));
        }
    }
--- a/va108xx-hal/src/i2c.rs
+++ b/va108xx-hal/src/i2c.rs
@ -18,6 +18,7 @@ const CLK_400K: Hertz = Hertz::from_raw(400_000);
 const MIN_CLK_400K: Hertz = Hertz::from_raw(8_000_000);
 #[derive(Debug, PartialEq, Eq, Copy, Clone)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum FifoEmptyMode {
    Stall = 0,
    EndTransaction = 1,
@ -89,18 +90,21 @@ enum I2cCmd {
 }
 #[derive(Debug, PartialEq, Eq, Copy, Clone)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum I2cSpeed {
    Regular100khz = 0,
    Fast400khz = 1,
 }
 #[derive(Debug, PartialEq, Eq)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum I2cDirection {
    Send = 0,
    Read = 1,
 }
 #[derive(Debug, PartialEq, Eq, Copy, Clone)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum I2cAddress {
    Regular(u8),
    TenBit(u16),
@ -141,9 +145,12 @@ impl Instance for pac::I2cb {
 // Config
 //==================================================================================================
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct TrTfThighTlow(u8, u8, u8, u8);
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct TsuStoTsuStaThdStaTBuf(u8, u8, u8, u8);
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct TimingCfg {
    // 4 bit max width
    tr: u8,
@ -218,6 +225,7 @@ impl Default for TimingCfg {
    }
 }
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct MasterConfig {
    pub tx_fe_mode: FifoEmptyMode,
    pub rx_fe_mode: FifoEmptyMode,
@ -384,12 +392,12 @@ impl<I2c: Instance> I2cBase<I2c> {
            let (addr, addr_mode_mask) = Self::unwrap_addr(addr_b);
            self.i2c
                .s0_addressb()
-                .write(|w| unsafe { w.bits((addr << 1) as u32 | addr_mode_mask) })
+                .write(|w| unsafe { w.bits((addr << 1) as u32 | addr_mode_mask) });
        }
        if let Some(addr_b_mask) = sl_cfg.addr_b_mask {
            self.i2c
                .s0_addressmaskb()
-                .write(|w| unsafe { w.bits((addr_b_mask << 1) as u32) })
+                .write(|w| unsafe { w.bits((addr_b_mask << 1) as u32) });
        }
    }
--- a/va108xx-hal/src/lib.rs
+++ b/va108xx-hal/src/lib.rs
@ -51,8 +51,8 @@ pub enum PeripheralSelect {
 /// Generic interrupt config which can be used to specify whether the HAL driver will
 /// use the IRQSEL register to route an interrupt, and whether the IRQ will be unmasked in the
-/// Cortex-M0 NVIC. Both are generally necessary for IRQs to work, but the user might perform
+/// Cortex-M0 NVIC. Both are generally necessary for IRQs to work, but the user might want to
-/// this steps themselves
+/// perform those steps themselves.
 #[derive(Debug, PartialEq, Eq, Clone, Copy)]
 pub struct InterruptConfig {
    /// Interrupt target vector. Should always be set, might be required for disabling IRQs
@ -77,6 +77,7 @@ impl InterruptConfig {
 pub type IrqCfg = InterruptConfig;
 #[derive(Debug, PartialEq, Eq)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct InvalidPin(pub(crate) ());
 /// Can be used to manually manipulate the function select of port pins
--- a/va108xx-hal/src/pwm.rs
+++ b/va108xx-hal/src/pwm.rs
@ -15,7 +15,9 @@ use crate::{clock::enable_peripheral_clock, gpio::DynPinId};
 const DUTY_MAX: u16 = u16::MAX;
-pub struct PwmCommon {
+#[derive(Debug)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub(crate) struct PwmCommon {
    sys_clk: Hertz,
    /// For PWMB, this is the upper limit
    current_duty: u16,
--- a/va108xx-hal/src/spi.rs
+++ b/va108xx-hal/src/spi.rs
@ -37,6 +37,7 @@ pub const BMSTART_BMSTOP_MASK: u32 = 1 << 31;
 pub const DEFAULT_CLK_DIV: u16 = 2;
 #[derive(Debug, PartialEq, Eq, Copy, Clone)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum HwChipSelectId {
    Id0 = 0,
    Id1 = 1,
@ -50,6 +51,7 @@ pub enum HwChipSelectId {
 }
 #[derive(Debug)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum SpiPort {
    Porta = 0,
    Portb = 1,
@ -58,6 +60,7 @@ pub enum SpiPort {
 }
 #[derive(Debug, PartialEq, Eq, Copy, Clone)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum WordSize {
    OneBit = 0x00,
    FourBits = 0x03,
@ -789,7 +792,7 @@ where
    // initialization. Returns the amount of written bytes.
    fn initial_send_fifo_pumping_with_words(&self, words: &[Word]) -> usize {
        if self.blockmode {
-            self.spi.ctrl1().modify(|_, w| w.mtxpause().set_bit())
+            self.spi.ctrl1().modify(|_, w| w.mtxpause().set_bit());
        }
        // Fill the first half of the write FIFO
        let mut current_write_idx = 0;
@ -803,7 +806,7 @@ where
            current_write_idx += 1;
        }
        if self.blockmode {
-            self.spi.ctrl1().modify(|_, w| w.mtxpause().clear_bit())
+            self.spi.ctrl1().modify(|_, w| w.mtxpause().clear_bit());
        }
        current_write_idx
    }
@ -812,7 +815,7 @@ where
    // initialization.
    fn initial_send_fifo_pumping_with_fill_words(&self, send_len: usize) -> usize {
        if self.blockmode {
-            self.spi.ctrl1().modify(|_, w| w.mtxpause().set_bit())
+            self.spi.ctrl1().modify(|_, w| w.mtxpause().set_bit());
        }
        // Fill the first half of the write FIFO
        let mut current_write_idx = 0;
@ -826,7 +829,7 @@ where
            current_write_idx += 1;
        }
        if self.blockmode {
-            self.spi.ctrl1().modify(|_, w| w.mtxpause().clear_bit())
+            self.spi.ctrl1().modify(|_, w| w.mtxpause().clear_bit());
        }
        current_write_idx
    }
--- a/va108xx-hal/src/sysconfig.rs
+++ b/va108xx-hal/src/sysconfig.rs
@ -20,7 +20,7 @@ pub fn enable_rom_scrubbing(
 }
 pub fn disable_rom_scrubbing(syscfg: &mut pac::Sysconfig) {
-    syscfg.rom_scrub().write(|w| unsafe { w.bits(0) })
+    syscfg.rom_scrub().write(|w| unsafe { w.bits(0) });
 }
 /// Enable scrubbing for the RAM
@ -39,7 +39,7 @@ pub fn enable_ram_scrubbing(
 }
 pub fn disable_ram_scrubbing(syscfg: &mut pac::Sysconfig) {
-    syscfg.ram_scrub().write(|w| unsafe { w.bits(0) })
+    syscfg.ram_scrub().write(|w| unsafe { w.bits(0) });
 }
 /// Clear the reset bit. This register is active low, so doing this will hold the peripheral
--- a/va108xx-hal/src/timer.rs
+++ b/va108xx-hal/src/timer.rs
@ -79,6 +79,7 @@ pub enum Event {
 }
 #[derive(Default, Debug, PartialEq, Eq, Copy, Clone)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct CascadeCtrl {
    /// Enable Cascade 0 signal active as a requirement for counting
    pub enb_start_src_csd0: bool,
@ -108,6 +109,7 @@ pub struct CascadeCtrl {
 }
 #[derive(Debug, PartialEq, Eq)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum CascadeSel {
    Csd0 = 0,
    Csd1 = 1,
@ -319,7 +321,7 @@ pub unsafe trait TimRegInterface {
            va108xx::Peripherals::steal()
                .sysconfig
                .tim_reset()
-                .modify(|r, w| w.bits(r.bits() & !self.mask_32()))
+                .modify(|r, w| w.bits(r.bits() & !self.mask_32()));
        }
    }
@ -330,7 +332,7 @@ pub unsafe trait TimRegInterface {
            va108xx::Peripherals::steal()
                .sysconfig
                .tim_reset()
-                .modify(|r, w| w.bits(r.bits() | self.mask_32()))
+                .modify(|r, w| w.bits(r.bits() | self.mask_32()));
        }
    }
 }
--- a/va108xx-hal/src/uart/mod.rs
+++ b/va108xx-hal/src/uart/mod.rs
@ -7,7 +7,6 @@
 //! - [Flashloader exposing a CCSDS interface via UART](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/flashloader)
 use core::{convert::Infallible, ops::Deref};
 use fugit::RateExtU32;
 use va108xx::Uarta;
 pub use crate::InterruptConfig;
 use crate::{
@ -23,6 +22,13 @@ use crate::{
 };
 use embedded_hal_nb::serial::Read;
 #[derive(Debug)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub enum Bank {
    A = 0,
    B = 1,
 }
 //==================================================================================================
 // Type-Level support
 //==================================================================================================
@ -232,6 +238,7 @@ impl From<Hertz> for Config {
 //==================================================================================================
 #[derive(Debug, Copy, Clone)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct IrqContextTimeoutOrMaxSize {
    rx_idx: usize,
    mode: IrqReceptionMode,
@ -257,17 +264,19 @@ impl IrqContextTimeoutOrMaxSize {
 /// This struct is used to return the default IRQ handler result to the user
 #[derive(Debug, Default)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct IrqResult {
    pub bytes_read: usize,
-    pub errors: Option<IrqUartError>,
+    pub errors: Option<UartErrors>,
 }
 /// This struct is used to return the default IRQ handler result to the user
 #[derive(Debug, Default)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct IrqResultMaxSizeOrTimeout {
    complete: bool,
    timeout: bool,
-    pub errors: Option<IrqUartError>,
+    pub errors: Option<UartErrors>,
    pub bytes_read: usize,
 }
@ -314,20 +323,22 @@ impl IrqResultMaxSizeOrTimeout {
 }
 #[derive(Debug, PartialEq, Copy, Clone)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 enum IrqReceptionMode {
    Idle,
    Pending,
 }
 #[derive(Default, Debug, Copy, Clone)]
-pub struct IrqUartError {
+#[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct UartErrors {
    overflow: bool,
    framing: bool,
    parity: bool,
    other: bool,
 }
-impl IrqUartError {
+impl UartErrors {
    #[inline(always)]
    pub fn overflow(&self) -> bool {
        self.overflow
@ -349,7 +360,7 @@ impl IrqUartError {
    }
 }
-impl IrqUartError {
+impl UartErrors {
    #[inline(always)]
    pub fn error(&self) -> bool {
        self.overflow || self.framing || self.parity
@ -401,7 +412,7 @@ impl Instance for pac::Uarta {
    }
    #[inline(always)]
    fn ptr() -> *const uart_base::RegisterBlock {
-        Uarta::ptr() as *const _
+        Self::ptr() as *const _
    }
 }
@ -416,7 +427,7 @@ impl Instance for pac::Uartb {
    }
    #[inline(always)]
    fn ptr() -> *const uart_base::RegisterBlock {
-        Uarta::ptr() as *const _
+        Self::ptr() as *const _
    }
 }
@ -752,6 +763,34 @@ where
    }
 }
 #[inline(always)]
 pub fn enable_rx(uart: &uart_base::RegisterBlock) {
    uart.enable().modify(|_, w| w.rxenable().set_bit());
 }
 #[inline(always)]
 pub fn disable_rx(uart: &uart_base::RegisterBlock) {
    uart.enable().modify(|_, w| w.rxenable().clear_bit());
 }
 #[inline(always)]
 pub fn enable_rx_interrupts(uart: &uart_base::RegisterBlock) {
    uart.irq_enb().modify(|_, w| {
        w.irq_rx().set_bit();
        w.irq_rx_to().set_bit();
        w.irq_rx_status().set_bit()
    });
 }
 #[inline(always)]
 pub fn disable_rx_interrupts(uart: &uart_base::RegisterBlock) {
    uart.irq_enb().modify(|_, w| {
        w.irq_rx().clear_bit();
        w.irq_rx_to().clear_bit();
        w.irq_rx_status().clear_bit()
    });
 }
 /// Serial receiver.
 ///
 /// Can be created by using the [Uart::split] or [UartBase::split] API.
@ -760,6 +799,7 @@ pub struct Rx<Uart> {
 }
 impl<Uart: Instance> Rx<Uart> {
    #[inline(always)]
    fn new(uart: Uart) -> Self {
        Self { uart }
    }
@ -769,6 +809,7 @@ impl<Uart: Instance> Rx<Uart> {
    /// # Safety
    ///
    /// You must ensure that only registers related to the operation of the RX side are used.
    #[inline(always)]
    pub unsafe fn uart(&self) -> &Uart {
        &self.uart
    }
@ -778,14 +819,23 @@ impl<Uart: Instance> Rx<Uart> {
        self.uart.fifo_clr().write(|w| w.rxfifo().set_bit());
    }
    #[inline]
    pub fn disable_interrupts(&mut self) {
        disable_rx_interrupts(unsafe { Uart::reg_block() });
    }
    #[inline]
    pub fn enable_interrupts(&mut self) {
        enable_rx_interrupts(unsafe { Uart::reg_block() });
    }
    #[inline]
    pub fn enable(&mut self) {
-        self.uart.enable().modify(|_, w| w.rxenable().set_bit());
+        enable_rx(unsafe { Uart::reg_block() });
    }
    #[inline]
    pub fn disable(&mut self) {
-        self.uart.enable().modify(|_, w| w.rxenable().clear_bit());
+        disable_rx(unsafe { Uart::reg_block() });
    }
    /// Low level function to read a word from the UART FIFO.
@ -819,6 +869,7 @@ impl<Uart: Instance> Rx<Uart> {
        RxWithInterrupt::new(self)
    }
    #[inline(always)]
    pub fn release(self) -> Uart {
        self.uart
    }
@ -877,14 +928,17 @@ impl<Uart: Instance> embedded_io::Read for Rx<Uart> {
    }
 }
 #[inline(always)]
 pub fn enable_tx(uart: &uart_base::RegisterBlock) {
    uart.enable().modify(|_, w| w.txenable().set_bit());
 }
 #[inline(always)]
 pub fn disable_tx(uart: &uart_base::RegisterBlock) {
    uart.enable().modify(|_, w| w.txenable().clear_bit());
 }
 #[inline(always)]
 pub fn enable_tx_interrupts(uart: &uart_base::RegisterBlock) {
    uart.irq_enb().modify(|_, w| {
        w.irq_tx().set_bit();
@ -893,6 +947,7 @@ pub fn enable_tx_interrupts(uart: &uart_base::RegisterBlock) {
    });
 }
 #[inline(always)]
 pub fn disable_tx_interrupts(uart: &uart_base::RegisterBlock) {
    uart.irq_enb().modify(|_, w| {
        w.irq_tx().clear_bit();
@ -914,12 +969,14 @@ impl<Uart: Instance> Tx<Uart> {
    /// # Safety
    ///
    /// Circumvents the HAL safety guarantees.
    #[inline(always)]
    pub unsafe fn steal() -> Self {
        Self {
            uart: Uart::steal(),
        }
    }
    #[inline(always)]
    fn new(uart: Uart) -> Self {
        Self { uart }
    }
@ -929,6 +986,7 @@ impl<Uart: Instance> Tx<Uart> {
    /// # Safety
    ///
    /// You must ensure that only registers related to the operation of the TX side are used.
    #[inline(always)]
    pub unsafe fn uart(&self) -> &Uart {
        &self.uart
    }
@ -1055,10 +1113,10 @@ impl<Uart: Instance> embedded_io::Write for Tx<Uart> {
 ///
 ///  1. The first way simply empties the FIFO on an interrupt into a user provided buffer. You
 ///     can simply use [Self::start] to prepare the peripheral and then call the
-///     [Self::irq_handler] in the interrupt service routine.
+///     [Self::on_interrupt] in the interrupt service routine.
 ///  2. The second way reads packets bounded by a maximum size or a baudtick based timeout. You
 ///     can use [Self::read_fixed_len_or_timeout_based_using_irq] to prepare the peripheral and
-///     then call the [Self::irq_handler_max_size_or_timeout_based] in the interrupt service
+///     then call the [Self::on_interrupt_max_size_or_timeout_based] in the interrupt service
 ///     routine. You have to call [Self::read_fixed_len_or_timeout_based_using_irq] in the ISR to
 ///     start reading the next packet.
 pub struct RxWithInterrupt<Uart>(Rx<Uart>);
@ -1069,7 +1127,7 @@ impl<Uart: Instance> RxWithInterrupt<Uart> {
    }
    /// This function should be called once at initialization time if the regular
-    /// [Self::irq_handler] is used to read the UART receiver to enable and start the receiver.
+    /// [Self::on_interrupt] is used to read the UART receiver to enable and start the receiver.
    pub fn start(&mut self) {
        self.0.enable();
        self.enable_rx_irq_sources(true);
@ -1080,13 +1138,13 @@ impl<Uart: Instance> RxWithInterrupt<Uart> {
        &self.0.uart
    }
-    /// This function is used together with the [Self::irq_handler_max_size_or_timeout_based]
+    /// This function is used together with the [Self::on_interrupt_max_size_or_timeout_based]
    /// function to read packets with a maximum size or variable sized packets by using the
    /// receive timeout of the hardware.
    ///
    /// This function should be called once at initialization to initiate the context state
    /// and to [Self::start] the receiver. After that, it should be called after each
-    /// completed [Self::irq_handler_max_size_or_timeout_based] call to restart the reception
+    /// completed [Self::on_interrupt_max_size_or_timeout_based] call to restart the reception
    /// of a packet.
    pub fn read_fixed_len_or_timeout_based_using_irq(
        &mut self,
@ -1266,7 +1324,7 @@ impl<Uart: Instance> RxWithInterrupt<Uart> {
    fn read_handler(
        &self,
-        errors: &mut Option<IrqUartError>,
+        errors: &mut Option<UartErrors>,
        read_res: &nb::Result<u8, RxError>,
    ) -> Option<u8> {
        match read_res {
@ -1274,7 +1332,7 @@ impl<Uart: Instance> RxWithInterrupt<Uart> {
            Err(nb::Error::WouldBlock) => None,
            Err(nb::Error::Other(e)) => {
                // Ensure `errors` is Some(IrqUartError), initializing if it's None
-                let err = errors.get_or_insert(IrqUartError::default());
+                let err = errors.get_or_insert(UartErrors::default());
                // Now we can safely modify fields inside `err`
                match e {
@ -1287,14 +1345,14 @@ impl<Uart: Instance> RxWithInterrupt<Uart> {
        }
    }
-    fn check_for_errors(&self, errors: &mut Option<IrqUartError>) {
+    fn check_for_errors(&self, errors: &mut Option<UartErrors>) {
        let rx_status = self.uart().rxstatus().read();
        if rx_status.rxovr().bit_is_set()
            || rx_status.rxfrm().bit_is_set()
            || rx_status.rxpar().bit_is_set()
        {
-            let err = errors.get_or_insert(IrqUartError::default());
+            let err = errors.get_or_insert(UartErrors::default());
            if rx_status.rxovr().bit_is_set() {
                err.overflow = true;
@ -1331,5 +1389,8 @@ impl<Uart: Instance> RxWithInterrupt<Uart> {
    }
 }
-pub mod asynch;
+pub mod tx_asynch;
-pub use asynch::*;
+pub use tx_asynch::*;
 pub mod rx_asynch;
 pub use rx_asynch::*;
--- a/va108xx-hal/src/uart/rx_asynch.rs
+++ b/va108xx-hal/src/uart/rx_asynch.rs
@ -0,0 +1,419 @@
 //! # Async UART reception functionality for the VA108xx family.
 //!
 //! This module provides the [RxAsync] and [RxAsyncSharedConsumer] struct which both implement the
 //! [embedded_io_async::Read] trait.
 //! This trait allows for asynchronous reception of data streams. Please note that this module does
 //! not specify/declare the interrupt handlers which must be provided for async support to work.
 //! However, it provides four interrupt handlers:
 //!
 //! - [on_interrupt_uart_a]
 //! - [on_interrupt_uart_b]
 //! - [on_interrupt_uart_a_overwriting]
 //! - [on_interrupt_uart_b_overwriting]
 //!
 //! The first two are used for the [RxAsync] struct, while the latter two are used with the
 //! [RxAsyncSharedConsumer] struct. The later two will overwrite old values in the used ring buffer.
 //!
 //! Error handling is performed in the user interrupt handler by checking the [AsyncUartErrors]
 //! structure returned by the interrupt handlers.
 //!
 //! # Example
 //!
 //! - [Async UART RX example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/embassy/src/bin/async-uart-rx.rs)
 use core::{cell::RefCell, convert::Infallible, future::Future, sync::atomic::Ordering};
 use critical_section::Mutex;
 use embassy_sync::waitqueue::AtomicWaker;
 use embedded_io::ErrorType;
 use heapless::spsc::Consumer;
 use portable_atomic::AtomicBool;
 use va108xx as pac;
 use super::{Instance, Rx, RxError, UartErrors};
 static UART_RX_WAKERS: [AtomicWaker; 2] = [const { AtomicWaker::new() }; 2];
 static RX_READ_ACTIVE: [AtomicBool; 2] = [const { AtomicBool::new(false) }; 2];
 static RX_HAS_DATA: [AtomicBool; 2] = [const { AtomicBool::new(false) }; 2];
 struct RxFuture {
    uart_idx: usize,
 }
 impl RxFuture {
    pub fn new<Uart: Instance>(_rx: &mut Rx<Uart>) -> Self {
        RX_READ_ACTIVE[Uart::IDX as usize].store(true, Ordering::Relaxed);
        Self {
            uart_idx: Uart::IDX as usize,
        }
    }
 }
 impl Future for RxFuture {
    type Output = Result<(), RxError>;
    fn poll(
        self: core::pin::Pin<&mut Self>,
        cx: &mut core::task::Context<'_>,
    ) -> core::task::Poll<Self::Output> {
        UART_RX_WAKERS[self.uart_idx].register(cx.waker());
        if RX_HAS_DATA[self.uart_idx].load(Ordering::Relaxed) {
            return core::task::Poll::Ready(Ok(()));
        }
        core::task::Poll::Pending
    }
 }
 #[derive(Debug, Clone, Copy)]
 #[cfg_attr(feature = "defmt", derive(defmt::Format))]
 pub struct AsyncUartErrors {
    /// Queue has overflowed, data might have been lost.
    pub queue_overflow: bool,
    /// UART errors.
    pub uart_errors: UartErrors,
 }
 fn on_interrupt_handle_rx_errors<Uart: Instance>(uart: &Uart) -> Option<UartErrors> {
    let rx_status = uart.rxstatus().read();
    if rx_status.rxovr().bit_is_set()
        || rx_status.rxfrm().bit_is_set()
        || rx_status.rxpar().bit_is_set()
    {
        let mut errors_val = UartErrors::default();
        if rx_status.rxovr().bit_is_set() {
            errors_val.overflow = true;
        }
        if rx_status.rxfrm().bit_is_set() {
            errors_val.framing = true;
        }
        if rx_status.rxpar().bit_is_set() {
            errors_val.parity = true;
        }
        return Some(errors_val);
    }
    None
 }
 fn on_interrupt_rx_common_post_processing<Uart: Instance>(
    uart: &Uart,
    rx_enabled: bool,
    read_some_data: bool,
    irq_end: u32,
 ) -> Option<UartErrors> {
    if read_some_data {
        RX_HAS_DATA[Uart::IDX as usize].store(true, Ordering::Relaxed);
        if RX_READ_ACTIVE[Uart::IDX as usize].load(Ordering::Relaxed) {
            UART_RX_WAKERS[Uart::IDX as usize].wake();
        }
    }
    let mut errors = None;
    // Check for RX errors
    if rx_enabled {
        errors = on_interrupt_handle_rx_errors(uart);
    }
    // Clear the interrupt status bits
    uart.irq_clr().write(|w| unsafe { w.bits(irq_end) });
    errors
 }
 /// Interrupt handler for UART A.
 ///
 /// Should be called in the user interrupt handler to enable
 /// asynchronous reception. This variant will overwrite old data in the ring buffer in case
 /// the ring buffer is full.
 pub fn on_interrupt_uart_a_overwriting<const N: usize>(
    prod: &mut heapless::spsc::Producer<u8, N>,
    shared_consumer: &Mutex<RefCell<Option<heapless::spsc::Consumer<'static, u8, N>>>>,
 ) -> Result<(), AsyncUartErrors> {
    on_interrupt_rx_async_heapless_queue_overwriting(
        unsafe { pac::Uarta::steal() },
        prod,
        shared_consumer,
    )
 }
 /// Interrupt handler for UART B.
 ///
 /// Should be called in the user interrupt handler to enable
 /// asynchronous reception. This variant will overwrite old data in the ring buffer in case
 /// the ring buffer is full.
 pub fn on_interrupt_uart_b_overwriting<const N: usize>(
    prod: &mut heapless::spsc::Producer<u8, N>,
    shared_consumer: &Mutex<RefCell<Option<heapless::spsc::Consumer<'static, u8, N>>>>,
 ) -> Result<(), AsyncUartErrors> {
    on_interrupt_rx_async_heapless_queue_overwriting(
        unsafe { pac::Uartb::steal() },
        prod,
        shared_consumer,
    )
 }
 pub fn on_interrupt_rx_async_heapless_queue_overwriting<Uart: Instance, const N: usize>(
    uart: Uart,
    prod: &mut heapless::spsc::Producer<u8, N>,
    shared_consumer: &Mutex<RefCell<Option<heapless::spsc::Consumer<'static, u8, N>>>>,
 ) -> Result<(), AsyncUartErrors> {
    let irq_end = uart.irq_end().read();
    let enb_status = uart.enable().read();
    let rx_enabled = enb_status.rxenable().bit_is_set();
    let mut read_some_data = false;
    let mut queue_overflow = false;
    // Half-Full interrupt. We have a guaranteed amount of data we can read.
    if irq_end.irq_rx().bit_is_set() {
        let available_bytes = uart.rxfifoirqtrg().read().bits() as usize;
        // If this interrupt bit is set, the trigger level is available at the very least.
        // Read everything as fast as possible
        for _ in 0..available_bytes {
            let byte = uart.data().read().bits();
            if !prod.ready() {
                queue_overflow = true;
                critical_section::with(|cs| {
                    let mut cons_ref = shared_consumer.borrow(cs).borrow_mut();
                    cons_ref.as_mut().unwrap().dequeue();
                });
            }
            prod.enqueue(byte as u8).ok();
        }
        read_some_data = true;
    }
    // Timeout, empty the FIFO completely.
    if irq_end.irq_rx_to().bit_is_set() {
        while uart.rxstatus().read().rdavl().bit_is_set() {
            // While there is data in the FIFO, write it into the reception buffer
            let byte = uart.data().read().bits();
            if !prod.ready() {
                queue_overflow = true;
                critical_section::with(|cs| {
                    let mut cons_ref = shared_consumer.borrow(cs).borrow_mut();
                    cons_ref.as_mut().unwrap().dequeue();
                });
            }
            prod.enqueue(byte as u8).ok();
        }
        read_some_data = true;
    }
    let uart_errors =
        on_interrupt_rx_common_post_processing(&uart, rx_enabled, read_some_data, irq_end.bits());
    if uart_errors.is_some() || queue_overflow {
        return Err(AsyncUartErrors {
            queue_overflow,
            uart_errors: uart_errors.unwrap_or_default(),
        });
    }
    Ok(())
 }
 /// Interrupt handler for UART A.
 ///
 /// Should be called in the user interrupt handler to enable asynchronous reception.
 pub fn on_interrupt_uart_a<const N: usize>(
    prod: &mut heapless::spsc::Producer<'_, u8, N>,
 ) -> Result<(), AsyncUartErrors> {
    on_interrupt_rx_async_heapless_queue(unsafe { pac::Uarta::steal() }, prod)
 }
 /// Interrupt handler for UART B.
 ///
 /// Should be called in the user interrupt handler to enable asynchronous reception.
 pub fn on_interrupt_uart_b<const N: usize>(
    prod: &mut heapless::spsc::Producer<'_, u8, N>,
 ) -> Result<(), AsyncUartErrors> {
    on_interrupt_rx_async_heapless_queue(unsafe { pac::Uartb::steal() }, prod)
 }
 pub fn on_interrupt_rx_async_heapless_queue<Uart: Instance, const N: usize>(
    uart: Uart,
    prod: &mut heapless::spsc::Producer<'_, u8, N>,
 ) -> Result<(), AsyncUartErrors> {
    //let uart = unsafe { Uart::steal() };
    let irq_end = uart.irq_end().read();
    let enb_status = uart.enable().read();
    let rx_enabled = enb_status.rxenable().bit_is_set();
    let mut read_some_data = false;
    let mut queue_overflow = false;
    // Half-Full interrupt. We have a guaranteed amount of data we can read.
    if irq_end.irq_rx().bit_is_set() {
        let available_bytes = uart.rxfifoirqtrg().read().bits() as usize;
        // If this interrupt bit is set, the trigger level is available at the very least.
        // Read everything as fast as possible
        for _ in 0..available_bytes {
            let byte = uart.data().read().bits();
            if !prod.ready() {
                queue_overflow = true;
            }
            prod.enqueue(byte as u8).ok();
        }
        read_some_data = true;
    }
    // Timeout, empty the FIFO completely.
    if irq_end.irq_rx_to().bit_is_set() {
        while uart.rxstatus().read().rdavl().bit_is_set() {
            // While there is data in the FIFO, write it into the reception buffer
            let byte = uart.data().read().bits();
            if !prod.ready() {
                queue_overflow = true;
            }
            prod.enqueue(byte as u8).ok();
        }
        read_some_data = true;
    }
    let uart_errors =
        on_interrupt_rx_common_post_processing(&uart, rx_enabled, read_some_data, irq_end.bits());
    if uart_errors.is_some() || queue_overflow {
        return Err(AsyncUartErrors {
            queue_overflow,
            uart_errors: uart_errors.unwrap_or_default(),
        });
    }
    Ok(())
 }
 struct ActiveReadGuard(usize);
 impl Drop for ActiveReadGuard {
    fn drop(&mut self) {
        RX_READ_ACTIVE[self.0].store(false, Ordering::Relaxed);
    }
 }
 /// Core data structure to allow asynchronous UART reception.
 ///
 /// If the ring buffer becomes full, data will be lost.
 pub struct RxAsync<Uart: Instance, const N: usize> {
    rx: Rx<Uart>,
    pub queue: heapless::spsc::Consumer<'static, u8, N>,
 }
 impl<Uart: Instance, const N: usize> ErrorType for RxAsync<Uart, N> {
    /// Error reporting is done using the result of the interrupt functions.
    type Error = Infallible;
 }
 impl<Uart: Instance, const N: usize> RxAsync<Uart, N> {
    /// Create a new asynchronous receiver.
    ///
    /// The passed [heapless::spsc::Consumer] will be used to asynchronously receive data which
    /// is filled by the interrupt handler.
    pub fn new(mut rx: Rx<Uart>, queue: heapless::spsc::Consumer<'static, u8, N>) -> Self {
        rx.disable_interrupts();
        rx.disable();
        rx.clear_fifo();
        // Enable those together.
        critical_section::with(|_| {
            rx.enable_interrupts();
            rx.enable();
        });
        Self { rx, queue }
    }
 }
 impl<Uart: Instance, const N: usize> embedded_io_async::Read for RxAsync<Uart, N> {
    async fn read(&mut self, buf: &mut [u8]) -> Result<usize, Self::Error> {
        // Need to wait for the IRQ to read data and set this flag. If the queue is not
        // empty, we can read data immediately.
        if self.queue.len() == 0 {
            RX_HAS_DATA[Uart::IDX as usize].store(false, Ordering::Relaxed);
        }
        let _guard = ActiveReadGuard(Uart::IDX as usize);
        let mut handle_data_in_queue = |consumer: &mut heapless::spsc::Consumer<'static, u8, N>| {
            let data_to_read = consumer.len().min(buf.len());
            for byte in buf.iter_mut().take(data_to_read) {
                // We own the consumer and we checked that the amount of data is guaranteed to be available.
                *byte = unsafe { consumer.dequeue_unchecked() };
            }
            data_to_read
        };
        let fut = RxFuture::new(&mut self.rx);
        // Data is available, so read that data immediately.
        let read_data = handle_data_in_queue(&mut self.queue);
        if read_data > 0 {
            return Ok(read_data);
        }
        // Await data.
        let _ = fut.await;
        Ok(handle_data_in_queue(&mut self.queue))
    }
 }
 /// Core data structure to allow asynchronous UART reception.
 ///
 /// If the ring buffer becomes full, the oldest data will be overwritten when using the
 /// [on_interrupt_uart_a_overwriting] and [on_interrupt_uart_b_overwriting] interrupt handlers.
 pub struct RxAsyncSharedConsumer<Uart: Instance, const N: usize> {
    rx: Rx<Uart>,
    queue: &'static Mutex<RefCell<Option<Consumer<'static, u8, N>>>>,
 }
 impl<Uart: Instance, const N: usize> ErrorType for RxAsyncSharedConsumer<Uart, N> {
    /// Error reporting is done using the result of the interrupt functions.
    type Error = Infallible;
 }
 impl<Uart: Instance, const N: usize> RxAsyncSharedConsumer<Uart, N> {
    /// Create a new asynchronous receiver.
    ///
    /// The passed shared [heapless::spsc::Consumer] will be used to asynchronously receive data
    /// which is filled by the interrupt handler. The shared property allows using it in the
    /// interrupt handler to overwrite old data.
    pub fn new(
        mut rx: Rx<Uart>,
        queue: &'static Mutex<RefCell<Option<heapless::spsc::Consumer<'static, u8, N>>>>,
    ) -> Self {
        rx.disable_interrupts();
        rx.disable();
        rx.clear_fifo();
        // Enable those together.
        critical_section::with(|_| {
            rx.enable_interrupts();
            rx.enable();
        });
        Self { rx, queue }
    }
 }
 impl<Uart: Instance, const N: usize> embedded_io_async::Read for RxAsyncSharedConsumer<Uart, N> {
    async fn read(&mut self, buf: &mut [u8]) -> Result<usize, Self::Error> {
        // Need to wait for the IRQ to read data and set this flag. If the queue is not
        // empty, we can read data immediately.
        critical_section::with(|cs| {
            let queue = self.queue.borrow(cs);
            if queue.borrow().as_ref().unwrap().len() == 0 {
                RX_HAS_DATA[Uart::IDX as usize].store(false, Ordering::Relaxed);
            }
        });
        let _guard = ActiveReadGuard(Uart::IDX as usize);
        let mut handle_data_in_queue = || {
            critical_section::with(|cs| {
                let mut consumer_ref = self.queue.borrow(cs).borrow_mut();
                let consumer = consumer_ref.as_mut().unwrap();
                let data_to_read = consumer.len().min(buf.len());
                for byte in buf.iter_mut().take(data_to_read) {
                    // We own the consumer and we checked that the amount of data is guaranteed to be available.
                    *byte = unsafe { consumer.dequeue_unchecked() };
                }
                data_to_read
            })
        };
        let fut = RxFuture::new(&mut self.rx);
        // Data is available, so read that data immediately.
        let read_data = handle_data_in_queue();
        if read_data > 0 {
            return Ok(read_data);
        }
        // Await data.
        let _ = fut.await;
        let read_data = handle_data_in_queue();
        Ok(read_data)
    }
 }
--- a/va108xx-hal/src/uart/tx_asynch.rs
+++ b/va108xx-hal/src/uart/tx_asynch.rs
@ -1,4 +1,4 @@
-//! # Async GPIO functionality for the VA108xx family.
+//! # Async UART transmission functionality for the VA108xx family.
 //!
 //! This module provides the [TxAsync] struct which implements the [embedded_io_async::Write] trait.
 //! This trait allows for asynchronous sending of data streams. Please note that this module does
@ -13,7 +13,7 @@
 //!
 //! # Example
 //!
-//! - [Async UART example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/async-gpio/examples/embassy/src/bin/async-uart.rs)
+//! - [Async UART TX example](https://egit.irs.uni-stuttgart.de/rust/va108xx-rs/src/branch/main/examples/embassy/src/bin/async-uart-tx.rs)
 use core::{cell::RefCell, future::Future};
 use critical_section::Mutex;
@ -23,7 +23,7 @@ use portable_atomic::AtomicBool;
 use super::*;
-static UART_WAKERS: [AtomicWaker; 2] = [const { AtomicWaker::new() }; 2];
+static UART_TX_WAKERS: [AtomicWaker; 2] = [const { AtomicWaker::new() }; 2];
 static TX_CONTEXTS: [Mutex<RefCell<TxContext>>; 2] =
    [const { Mutex::new(RefCell::new(TxContext::new())) }; 2];
 // Completion flag. Kept outside of the context structure as an atomic to avoid
@ -72,7 +72,7 @@ fn on_interrupt_uart_tx<Uart: Instance>(uart: Uart) {
        });
        // Transfer is done.
        TX_DONE[Uart::IDX as usize].store(true, core::sync::atomic::Ordering::Relaxed);
-        UART_WAKERS[Uart::IDX as usize].wake();
+        UART_TX_WAKERS[Uart::IDX as usize].wake();
        return;
    }
    // Safety: We documented that the user provided slice must outlive the future, so we convert
@ -199,7 +199,7 @@ impl Future for TxFuture {
        self: core::pin::Pin<&mut Self>,
        cx: &mut core::task::Context<'_>,
    ) -> core::task::Poll<Self::Output> {
-        UART_WAKERS[self.uart_idx].register(cx.waker());
+        UART_TX_WAKERS[self.uart_idx].register(cx.waker());
        if TX_DONE[self.uart_idx].swap(false, core::sync::atomic::Ordering::Relaxed) {
            let progress = critical_section::with(|cs| {
                TX_CONTEXTS[self.uart_idx].borrow(cs).borrow().progress
--- a/vorago-reb1/CHANGELOG.md
+++ b/vorago-reb1/CHANGELOG.md
@ -8,6 +8,12 @@ and this project adheres to [Semantic Versioning](http://semver.org/).
 ## [unreleased]
 ## [v0.7.0] 2025-02-13
 - Bumped `va108xx-hal` dependency to 0.9
 - Minor adjustments to `Button` API.
 - `Button`, `Led` and `Leds` now simply wrap a type using a tuple struct.
 ## [v0.6.0] 2024-09-30
 - Added M95M01 EEPROM module/API
--- a/vorago-reb1/Cargo.toml
+++ b/vorago-reb1/Cargo.toml
@ -1,6 +1,6 @@
 [package]
 name = "vorago-reb1"
-version = "0.6.0"
+version = "0.7.0"
 authors = ["Robin Mueller <muellerr@irs.uni-stuttgart.de>"]
 edition = "2021"
 description = "Board Support Crate for the Vorago REB1 development board"
@ -19,8 +19,7 @@ bitfield = ">=0.17, <=0.18"
 max116xx-10bit = "0.3"
 [dependencies.va108xx-hal]
-path = "../va108xx-hal"
+version = "0.9"
 version = ">=0.8, <0.9"
 features = ["rt"]
 [features]
--- a/vorago-reb1/src/button.rs
+++ b/vorago-reb1/src/button.rs
@ -10,23 +10,22 @@ use va108xx_hal::{
    pac, InterruptConfig,
 };
-pub struct Button {
+#[derive(Debug)]
-    button: Pin<PA11, InputFloating>,
+pub struct Button(pub Pin<PA11, InputFloating>);
 }
 impl Button {
    pub fn new(pin: Pin<PA11, InputFloating>) -> Button {
-        Button { button: pin }
+        Button(pin)
    }
    #[inline]
    pub fn pressed(&mut self) -> bool {
-        self.button.is_low().ok().unwrap()
+        self.0.is_low().ok().unwrap()
    }
    #[inline]
    pub fn released(&mut self) -> bool {
-        self.button.is_high().ok().unwrap()
+        self.0.is_high().ok().unwrap()
    }
    /// Configures an IRQ on edge.
@ -37,7 +36,7 @@ impl Button {
        syscfg: Option<&mut pac::Sysconfig>,
        irqsel: Option<&mut pac::Irqsel>,
    ) {
-        self.button
+        self.0
            .configure_edge_interrupt(edge_type, irq_cfg, syscfg, irqsel);
    }
@ -49,7 +48,7 @@ impl Button {
        syscfg: Option<&mut pac::Sysconfig>,
        irqsel: Option<&mut pac::Irqsel>,
    ) {
-        self.button
+        self.0
            .configure_level_interrupt(level, irq_cfg, syscfg, irqsel);
    }
@ -58,6 +57,6 @@ impl Button {
    /// Please note that you still have to set a clock divisor yourself using the
    /// [`va108xx_hal::clock::set_clk_div_register`] function in order for this to work.
    pub fn configure_filter_type(&mut self, filter: FilterType, clksel: FilterClkSel) {
-        self.button.configure_filter_type(filter, clksel);
+        self.0.configure_filter_type(filter, clksel);
    }
 }
--- a/vorago-reb1/src/leds.rs
+++ b/vorago-reb1/src/leds.rs
@ -15,15 +15,12 @@ pub type LD2 = Pin<PA10, PushPullOutput>;
 pub type LD3 = Pin<PA7, PushPullOutput>;
 pub type LD4 = Pin<PA6, PushPullOutput>;
-pub struct Leds {
+#[derive(Debug)]
-    leds: [Led; 3],
+pub struct Leds(pub [Led; 3]);
 }
 impl Leds {
    pub fn new(led_pin1: LD2, led_pin2: LD3, led_pin3: LD4) -> Leds {
-        Leds {
+        Leds([led_pin1.into(), led_pin2.into(), led_pin3.into()])
            leds: [led_pin1.into(), led_pin2.into(), led_pin3.into()],
        }
    }
 }
@ -31,13 +28,13 @@ impl core::ops::Deref for Leds {
    type Target = [Led];
    fn deref(&self) -> &[Led] {
-        &self.leds
+        &self.0
    }
 }
 impl core::ops::DerefMut for Leds {
    fn deref_mut(&mut self) -> &mut [Led] {
-        &mut self.leds
+        &mut self.0
    }
 }
@ -45,28 +42,25 @@ impl core::ops::Index<usize> for Leds {
    type Output = Led;
    fn index(&self, i: usize) -> &Led {
-        &self.leds[i]
+        &self.0[i]
    }
 }
 impl core::ops::IndexMut<usize> for Leds {
    fn index_mut(&mut self, i: usize) -> &mut Led {
-        &mut self.leds[i]
+        &mut self.0[i]
    }
 }
-pub struct Led {
+#[derive(Debug)]
-    pin: DynPin,
+pub struct Led(pub DynPin);
 }
 macro_rules! ctor {
 	($($ldx:ident),+) => {
 		$(
 			impl From<$ldx> for Led {
 				fn from(led: $ldx) -> Self {
-					Led {
+					Led(led.into())
 						pin: led.into()
 					}
 				}
 			}
 		)+
@ -79,18 +73,18 @@ impl Led {
    /// Turns the LED off. Setting the pin high actually turns the LED off
    #[inline]
    pub fn off(&mut self) {
-        self.pin.set_high().ok();
+        self.0.set_high().ok();
    }
    /// Turns the LED on. Setting the pin low actually turns the LED on
    #[inline]
    pub fn on(&mut self) {
-        self.pin.set_low().ok();
+        self.0.set_low().ok();
    }
    /// Toggles the LED
    #[inline]
    pub fn toggle(&mut self) {
-        self.pin.toggle_with_toggle_reg().ok();
+        self.0.toggle_with_toggle_reg().ok();
    }
 }
--- a/vscode/launch.json
+++ b/vscode/launch.json
@ -526,13 +526,37 @@
        {
            "type": "cortex-debug",
            "request": "launch",
-            "name": "Async UART",
+            "name": "Async UART TX",
            "servertype": "jlink",
            "cwd": "${workspaceRoot}",
            "device": "Cortex-M0",
            "svdFile": "./va108xx/svd/va108xx.svd.patched",
-            "preLaunchTask": "async-uart",
+            "preLaunchTask": "async-uart-tx",
-            "executable": "${workspaceFolder}/target/thumbv6m-none-eabi/debug/async-uart",
+            "executable": "${workspaceFolder}/target/thumbv6m-none-eabi/debug/async-uart-tx",
            "interface": "jtag",
            "runToEntryPoint": "main",
            "rttConfig": {
                "enabled": true,
                "address": "auto",
                "decoders": [
                    {
                        "port": 0,
                        "timestamp": true,
                        "type": "console"
                    }
                ]
            }
        },
        {
            "type": "cortex-debug",
            "request": "launch",
            "name": "Async UART RX",
            "servertype": "jlink",
            "cwd": "${workspaceRoot}",
            "device": "Cortex-M0",
            "svdFile": "./va108xx/svd/va108xx.svd.patched",
            "preLaunchTask": "async-uart-rx",
            "executable": "${workspaceFolder}/target/thumbv6m-none-eabi/debug/async-uart-rx",
            "interface": "jtag",
            "runToEntryPoint": "main",
            "rttConfig": {
--- a/vscode/tasks.json
+++ b/vscode/tasks.json
@ -277,13 +277,23 @@
      ]
    },
    {
-      "label": "async-uart",
+      "label": "async-uart-tx",
      "type": "shell",
      "command": "~/.cargo/bin/cargo", // note: full path to the cargo
      "args": [
        "build",
        "--bin",
-        "async-uart"
+        "async-uart-tx"
      ]
    },
    {
      "label": "async-uart-rx",
      "type": "shell",
      "command": "~/.cargo/bin/cargo", // note: full path to the cargo
      "args": [
        "build",
        "--bin",
        "async-uart-rx"
      ]
    },
    {
Author	SHA1	Message	Date
Robin Mueller	b4f1512463	docs patch 2	2025-02-13 15:47:50 +01:00
Robin Müller	e9ec01fc60	Merge pull request 'doc fixes' (#48 ) from va108xx-embassy-doc-fix into main Reviewed-on: #48	2025-02-13 15:38:50 +01:00
Robin Mueller	d57cd383cd	doc fixes	2025-02-13 15:38:38 +01:00
Robin Müller	df4e943f48	Merge pull request 'use released package versions' (#47 ) from use-released-package-versions into main Reviewed-on: #47	2025-02-13 15:26:41 +01:00
Robin Mueller	93b67a4795	README update	2025-02-13 15:26:24 +01:00
Robin Mueller	a9f2e6dcee	use released package versions	2025-02-13 15:25:01 +01:00
Robin Müller	271c853df1	Merge pull request 'prepare va108xx-embassy release' (#46 ) from prepare-va108xx-embassy-release into main Reviewed-on: #46	2025-02-13 15:22:36 +01:00
Robin Mueller	107189b166	prepare va108xx-embassy release	2025-02-13 15:22:18 +01:00
Robin Müller	872944bebf	Merge pull request 'prepare BSP release' (#45 ) from vorago-reb1-release into main Reviewed-on: #45	2025-02-13 15:08:22 +01:00
Robin Mueller	d077bb6210	prepare BSP release	2025-02-13 15:06:02 +01:00
Robin Müller	bd286bdb2a	Merge pull request 'small README tweak' (#44 ) from readme-tweak into main Reviewed-on: #44	2025-02-13 14:56:48 +01:00
Robin Mueller	d3cc00a4a5	small README tweak	2025-02-13 14:56:24 +01:00
Robin Müller	1018a65447	Merge pull request 'add more defmt features' (#42 ) from add-more-defmt-features into main Reviewed-on: #42	2025-02-13 14:52:03 +01:00
Robin Mueller	0a31b637e6	add more defmt features	2025-02-13 14:51:54 +01:00
Robin Müller	6e1ae70054	Merge pull request 'add various debug impls' (#43 ) from add-various-debug-impls into main Reviewed-on: #43	2025-02-13 14:51:27 +01:00
Robin Mueller	8ae2d6189a	add various debug impls	2025-02-13 14:50:00 +01:00
Robin Müller	549a98dbaf	Merge pull request 'all doc fixes' (#41 ) from doc-fixes into main Reviewed-on: #41	2025-02-13 12:23:56 +01:00
Robin Mueller	e24fc608a3	all doc fixes	2025-02-13 11:44:14 +01:00
Robin Müller	7b74312013	Merge pull request 'completed async RX support as well' (#39 ) from async-uart-rx into main Reviewed-on: #39	2025-02-13 11:33:36 +01:00
Robin Mueller	417f5b7f67	completed async RX support as well	2025-02-13 11:31:17 +01:00
Robin Müller	3e796ef22b	Merge pull request 'UART B hotfix' (#40 ) from uart-b-hotfix into main Reviewed-on: #40	2025-02-13 11:30:37 +01:00
Robin Mueller	b145047b95	UART B hotfix	2025-02-13 11:14:39 +01:00
Robin Müller	82b4c16f8e	Merge pull request 'bump PAC version' (#38 ) from bump-va108xx-version into main Reviewed-on: #38	2025-02-12 14:57:53 +01:00
Robin Mueller	189ac2d256	bump PAC version	2025-02-12 14:47:18 +01:00