embassy/examples/stm32l4/src/bin/dac_dma.rs

#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]

use defmt::*;
use embassy_executor::Spawner;
use embassy_stm32::dac::{DacChannel, ValueArray};
use embassy_stm32::pac::timer::vals::{Mms, Opm};
use embassy_stm32::peripherals::{TIM6, TIM7};
use embassy_stm32::rcc::low_level::RccPeripheral;
use embassy_stm32::time::Hertz;
use embassy_stm32::timer::low_level::Basic16bitInstance;
use micromath::F32Ext;
use static_cell::StaticCell;
use {defmt_rtt as _, panic_probe as _};

pub type Dac1Type<'d> =
    embassy_stm32::dac::DacCh1<'d, embassy_stm32::peripherals::DAC1, embassy_stm32::peripherals::DMA1_CH3>;

pub type Dac2Type<'d> =
    embassy_stm32::dac::DacCh2<'d, embassy_stm32::peripherals::DAC1, embassy_stm32::peripherals::DMA1_CH4>;

#[embassy_executor::main]
async fn main(spawner: Spawner) {
    let config = embassy_stm32::Config::default();

    // Initialize the board and obtain a Peripherals instance
    let p: embassy_stm32::Peripherals = embassy_stm32::init(config);

    // Obtain two independent channels (p.DAC1 can only be consumed once, though!)
    let (dac_ch1, dac_ch2) = embassy_stm32::dac::Dac::new(p.DAC1, p.DMA1_CH3, p.DMA1_CH4, p.PA4, p.PA5).split();

    let dac1 = {
        type T = impl Sized;
        static STATIC_CELL: StaticCell<T> = StaticCell::new();
        STATIC_CELL.init(dac_ch1)
    };

    let dac2 = {
        type T = impl Sized;
        static STATIC_CELL: StaticCell<T> = StaticCell::new();
        STATIC_CELL.init(dac_ch2)
    };

    spawner.spawn(dac_task1(dac1)).ok();
    spawner.spawn(dac_task2(dac2)).ok();
}

#[embassy_executor::task]
async fn dac_task1(dac: &'static mut Dac1Type<'static>) {
    let data: &[u8; 256] = &calculate_array::<256>();

    info!("TIM6 frequency is {}", TIM6::frequency());
    const FREQUENCY: Hertz = Hertz::hz(200);
    let reload: u32 = (TIM6::frequency().0 / FREQUENCY.0) / data.len() as u32;

    // Depends on your clock and on the specific chip used, you may need higher or lower values here
    if reload < 10 {
        error!("Reload value {} below threshold!", reload);
    }

    dac.select_trigger(embassy_stm32::dac::Ch1Trigger::Tim6).unwrap();
    dac.enable_channel().unwrap();

    TIM6::enable();
    TIM6::regs().arr().modify(|w| w.set_arr(reload as u16 - 1));
    TIM6::regs().cr2().modify(|w| w.set_mms(Mms::UPDATE));
    TIM6::regs().cr1().modify(|w| {
        w.set_opm(Opm::DISABLED);
        w.set_cen(true);
    });

    debug!(
        "TIM6 Frequency {}, Target Frequency {}, Reload {}, Reload as u16 {}, Samples {}",
        TIM6::frequency(),
        FREQUENCY,
        reload,
        reload as u16,
        data.len()
    );

    // Loop technically not necessary if DMA circular mode is enabled
    loop {
        info!("Loop DAC1");
        if let Err(e) = dac.write(ValueArray::Bit8(data), true).await {
            error!("Could not write to dac: {}", e);
        }
    }
}

#[embassy_executor::task]
async fn dac_task2(dac: &'static mut Dac2Type<'static>) {
    let data: &[u8; 256] = &calculate_array::<256>();
    
    info!("TIM7 frequency is {}", TIM7::frequency());

    const FREQUENCY: Hertz = Hertz::hz(600);
    let reload: u32 = (TIM7::frequency().0 / FREQUENCY.0) / data.len() as u32;

    if reload < 10 {
        error!("Reload value {} below threshold!", reload);
    }

    TIM7::enable();
    TIM7::regs().arr().modify(|w| w.set_arr(reload as u16 - 1));
    TIM7::regs().cr2().modify(|w| w.set_mms(Mms::UPDATE));
    TIM7::regs().cr1().modify(|w| {
        w.set_opm(Opm::DISABLED);
        w.set_cen(true);
    });

    dac.select_trigger(embassy_stm32::dac::Ch2Trigger::Tim7).unwrap();

    debug!(
        "TIM7 Frequency {}, Target Frequency {}, Reload {}, Reload as u16 {}, Samples {}",
        TIM7::frequency(),
        FREQUENCY,
        reload,
        reload as u16,
        data.len()
    );

    if let Err(e) = dac.write(ValueArray::Bit8(data), true).await {
        error!("Could not write to dac: {}", e);
    }
}

fn to_sine_wave(v: u8) -> u8 {
    if v >= 128 {
        // top half
        let r = 3.14 * ((v - 128) as f32 / 128.0);
        (r.sin() * 128.0 + 127.0) as u8
    } else {
        // bottom half
        let r = 3.14 + 3.14 * (v as f32 / 128.0);
        (r.sin() * 128.0 + 127.0) as u8
    }
}

fn calculate_array<const N: usize>() -> [u8; N] {
    let mut res = [0; N];
    let mut i = 0;
    while i < N {
        res[i] = to_sine_wave(i as u8);
        i += 1;
    }
    res
}
Update DAC examples, add DAC + DMA example 2023-06-28 11:58:25 +02:00			`#![no_std]`
			`#![no_main]`
			`#![feature(type_alias_impl_trait)]`

			`use defmt::*;`
			`use embassy_executor::Spawner;`
			`use embassy_stm32::dac::{DacChannel, ValueArray};`
			`use embassy_stm32::pac::timer::vals::{Mms, Opm};`
			`use embassy_stm32::peripherals::{TIM6, TIM7};`
			`use embassy_stm32::rcc::low_level::RccPeripheral;`
			`use embassy_stm32::time::Hertz;`
			`use embassy_stm32::timer::low_level::Basic16bitInstance;`
			`use micromath::F32Ext;`
			`use static_cell::StaticCell;`
			`use {defmt_rtt as _, panic_probe as _};`

			`pub type Dac1Type<'d> =`
			`embassy_stm32::dac::DacCh1<'d, embassy_stm32::peripherals::DAC1, embassy_stm32::peripherals::DMA1_CH3>;`

			`pub type Dac2Type<'d> =`
			`embassy_stm32::dac::DacCh2<'d, embassy_stm32::peripherals::DAC1, embassy_stm32::peripherals::DMA1_CH4>;`

			`#[embassy_executor::main]`
			`async fn main(spawner: Spawner) {`
			`let config = embassy_stm32::Config::default();`

			`// Initialize the board and obtain a Peripherals instance`
			`let p: embassy_stm32::Peripherals = embassy_stm32::init(config);`

			`// Obtain two independent channels (p.DAC1 can only be consumed once, though!)`
			`let (dac_ch1, dac_ch2) = embassy_stm32::dac::Dac::new(p.DAC1, p.DMA1_CH3, p.DMA1_CH4, p.PA4, p.PA5).split();`

			`let dac1 = {`
			`type T = impl Sized;`
			`static STATIC_CELL: StaticCell<T> = StaticCell::new();`
			`STATIC_CELL.init(dac_ch1)`
			`};`

			`let dac2 = {`
			`type T = impl Sized;`
			`static STATIC_CELL: StaticCell<T> = StaticCell::new();`
			`STATIC_CELL.init(dac_ch2)`
			`};`

			`spawner.spawn(dac_task1(dac1)).ok();`
			`spawner.spawn(dac_task2(dac2)).ok();`
			`}`

			`#[embassy_executor::task]`
			`async fn dac_task1(dac: &'static mut Dac1Type<'static>) {`
			`let data: &[u8; 256] = &calculate_array::<256>();`

			`info!("TIM6 frequency is {}", TIM6::frequency());`
			`const FREQUENCY: Hertz = Hertz::hz(200);`
			`let reload: u32 = (TIM6::frequency().0 / FREQUENCY.0) / data.len() as u32;`

			`// Depends on your clock and on the specific chip used, you may need higher or lower values here`
			`if reload < 10 {`
			`error!("Reload value {} below threshold!", reload);`
			`}`

			`dac.select_trigger(embassy_stm32::dac::Ch1Trigger::Tim6).unwrap();`
			`dac.enable_channel().unwrap();`

			`TIM6::enable();`
			`TIM6::regs().arr().modify(\|w\| w.set_arr(reload as u16 - 1));`
			`TIM6::regs().cr2().modify(\|w\| w.set_mms(Mms::UPDATE));`
			`TIM6::regs().cr1().modify(\|w\| {`
			`w.set_opm(Opm::DISABLED);`
			`w.set_cen(true);`
			`});`

			`debug!(`
			`"TIM6 Frequency {}, Target Frequency {}, Reload {}, Reload as u16 {}, Samples {}",`
			`TIM6::frequency(),`
			`FREQUENCY,`
			`reload,`
			`reload as u16,`
			`data.len()`
			`);`

			`// Loop technically not necessary if DMA circular mode is enabled`
			`loop {`
			`info!("Loop DAC1");`
			`if let Err(e) = dac.write(ValueArray::Bit8(data), true).await {`
			`error!("Could not write to dac: {}", e);`
			`}`
			`}`
			`}`

			`#[embassy_executor::task]`
			`async fn dac_task2(dac: &'static mut Dac2Type<'static>) {`
			`let data: &[u8; 256] = &calculate_array::<256>();`

			`info!("TIM7 frequency is {}", TIM7::frequency());`

			`const FREQUENCY: Hertz = Hertz::hz(600);`
			`let reload: u32 = (TIM7::frequency().0 / FREQUENCY.0) / data.len() as u32;`

			`if reload < 10 {`
			`error!("Reload value {} below threshold!", reload);`
			`}`

			`TIM7::enable();`
			`TIM7::regs().arr().modify(\|w\| w.set_arr(reload as u16 - 1));`
			`TIM7::regs().cr2().modify(\|w\| w.set_mms(Mms::UPDATE));`
			`TIM7::regs().cr1().modify(\|w\| {`
			`w.set_opm(Opm::DISABLED);`
			`w.set_cen(true);`
			`});`

			`dac.select_trigger(embassy_stm32::dac::Ch2Trigger::Tim7).unwrap();`

			`debug!(`
			`"TIM7 Frequency {}, Target Frequency {}, Reload {}, Reload as u16 {}, Samples {}",`
			`TIM7::frequency(),`
			`FREQUENCY,`
			`reload,`
			`reload as u16,`
			`data.len()`
			`);`

			`if let Err(e) = dac.write(ValueArray::Bit8(data), true).await {`
			`error!("Could not write to dac: {}", e);`
			`}`
			`}`

			`fn to_sine_wave(v: u8) -> u8 {`
			`if v >= 128 {`
			`// top half`
			`let r = 3.14 * ((v - 128) as f32 / 128.0);`
			`(r.sin() * 128.0 + 127.0) as u8`
			`} else {`
			`// bottom half`
			`let r = 3.14 + 3.14 * (v as f32 / 128.0);`
			`(r.sin() * 128.0 + 127.0) as u8`
			`}`
			`}`

			`fn calculate_array<const N: usize>() -> [u8; N] {`
			`let mut res = [0; N];`
			`let mut i = 0;`
			`while i < N {`
			`res[i] = to_sine_wave(i as u8);`
			`i += 1;`
			`}`
			`res`
			`}`