atsamd_hal

Module async_hal

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§Asynchronous HAL APIs

This HAL provides a comprehensive and efficient way to interact with the underlying peripherals in an asynchronous fashion, enabling concurrent and non-blocking programming through the use of async/await APIs.

This module provides the basis for interacting with peripherals through async APIs. Notably, in order to function correctly and wake an awaiting Future, peripherals must be able to signal when their respective interrupts fire. Traditionally, the user manually writes their own interrupt handlers. When using async APIs, the peripherals effectively take control of their own interrupt handlers in order to wake tasks at the appropriate time.

§Using the async APIs

To use the asynchronous APIs provided by the HAL, enable the async Cargo feature. Note that this uses a certain amount of static RAM in order to initialize wakers for each peripheral.

§Supported peripherals

Note: The asynchronous APIs for the individual peripherals are provided in their respective modules. This module only deals with the generalities of using async constructs throughout the HAL.

§Declaring interrupt bindings

In order for the peripherals to wake their respective tasks, the interrupt sources must be bound to their handler at compile time. A struct that implements Binding must be passed to an async peripheral in order to prove to the compiler that the correct interrupt handlers have been bound.

This module provides convenient macros that generate the interrupt bindings. Use bind_interrupts to bind single interrupt sources to handlers. See also Declaring multiple interrupt source bindings.

§Declaring multiple interrupt source bindings

For some thumbv7em peripherals, there are multiple interrupt sources used by a single peripheral. In these cases, we must provide a binding to an interrupt handler for each of these interrupt sources in order for the peripheral driver to function properly. The HAL defines only one interrupt “source” per peripheral. Your job is to tell it where to find all the relevant interrupts it must use to operate the peripheral properly. Use bind_multiple_interrupts to bind multiple interrupts to a single handler.

Currently, the supported peripherals which have multiple interrupts per peripheral (thumbv7em targets only):

  • SERCOMx: [SERCOMx_0, SERCOMx_1, SERCOMx_2, SERCOMx_OTHER]
  • DMAC: [DMAC_0, DMAC_1, DMAC_2, DMAC_OTHER]

§Complete example using the feather_m0 BSP and the Embassy executor

#![no_std]
#![no_main]

use defmt_rtt as _;
use panic_probe as _;

use bsp::hal;
use bsp::pac;
use feather_m0 as bsp;
use fugit::MillisDuration;
use hal::{
    clock::GenericClockController,
    dmac::{DmaController, PriorityLevel},
    prelude::*,
    sercom::Sercom4,
};
use rtic_monotonics::systick::Systick;

atsamd_hal::bind_interrupts!(struct Irqs {
    SERCOM4 => atsamd_hal::sercom::spi::InterruptHandler<Sercom4>;
    DMAC => atsamd_hal::dmac::InterruptHandler;
});

#[embassy_executor::main]
async fn main(_s: embassy_executor::Spawner) {
    let mut peripherals = pac::Peripherals::take().unwrap();
    let _core = pac::CorePeripherals::take().unwrap();

    let mut clocks = GenericClockController::with_external_32kosc(
        peripherals.gclk,
        &mut peripherals.pm,
        &mut peripherals.sysctrl,
        &mut peripherals.nvmctrl,
    );

    let pins = bsp::Pins::new(peripherals.port);

    // Take SPI pins
    let (miso, mosi, sclk) = (pins.miso, pins.mosi, pins.sclk);

    // Initialize DMA Controller
    let dmac = DmaController::init(peripherals.dmac, &mut peripherals.pm);

    // Turn dmac into an async controller
    let mut dmac = dmac.into_future(Irqs);
    // Get individual handles to DMA channels
    let channels = dmac.split();

    // Initialize DMA Channels 0 and 1
    let channel0 = channels.0.init(PriorityLevel::Lvl0);
    let channel1 = channels.1.init(PriorityLevel::Lvl0);

    let mut spi = bsp::spi_master(
        &mut clocks,
        100.kHz(),
        peripherals.sercom4,
        &mut peripherals.pm,
        sclk,
        mosi,
        miso,
    )
    .into_future(Irqs)
    .with_dma_channels(channel0, channel1);

    loop {
        defmt::info!("Sending 0x00 to SPI device...");
        spi.write(&[0x00]).await.unwrap();

        defmt::info!("Sent 0x00.");

        let mut buffer = [0xff; 4];
        spi.read(&mut buffer).await.unwrap();
        defmt::info!("Read buffer: {:#x}", buffer);
        Systick::delay(MillisDuration::<u32>::from_ticks(500).convert()).await;
    }
}

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