embassy/tests/rp/src/bin/uart_dma.rs

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

use defmt::{assert_eq, *};
use embassy_executor::Spawner;
use embassy_rp::gpio::{Level, Output};
use embassy_rp::interrupt;
use embassy_rp::uart::{Async, Config, Error, Instance, Parity, Uart, UartRx};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};

async fn read<const N: usize>(uart: &mut Uart<'_, impl Instance, Async>) -> Result<[u8; N], Error> {
    let mut buf = [255; N];
    uart.read(&mut buf).await?;
    Ok(buf)
}

async fn read1<const N: usize>(uart: &mut UartRx<'_, impl Instance, Async>) -> Result<[u8; N], Error> {
    let mut buf = [255; N];
    uart.read(&mut buf).await?;
    Ok(buf)
}

async fn send(pin: &mut Output<'_, impl embassy_rp::gpio::Pin>, v: u8, parity: Option<bool>) {
    pin.set_low();
    Timer::after(Duration::from_millis(1)).await;
    for i in 0..8 {
        if v & (1 << i) == 0 {
            pin.set_low();
        } else {
            pin.set_high();
        }
        Timer::after(Duration::from_millis(1)).await;
    }
    if let Some(b) = parity {
        if b {
            pin.set_high();
        } else {
            pin.set_low();
        }
        Timer::after(Duration::from_millis(1)).await;
    }
    pin.set_high();
    Timer::after(Duration::from_millis(1)).await;
}

#[embassy_executor::main]
async fn main(_spawner: Spawner) {
    let mut p = embassy_rp::init(Default::default());
    info!("Hello World!");

    let (mut tx, mut rx, mut uart) = (p.PIN_0, p.PIN_1, p.UART0);
    let mut irq = interrupt::take!(UART0_IRQ);

    // We can't send too many bytes, they have to fit in the FIFO.
    // This is because we aren't sending+receiving at the same time.
    {
        let config = Config::default();
        let mut uart = Uart::new(
            &mut uart,
            &mut tx,
            &mut rx,
            &mut irq,
            &mut p.DMA_CH0,
            &mut p.DMA_CH1,
            config,
        );

        let data = [0xC0, 0xDE];
        uart.write(&data).await.unwrap();

        let mut buf = [0; 2];
        uart.read(&mut buf).await.unwrap();
        assert_eq!(buf, data);
    }

    info!("test overflow detection");
    {
        let config = Config::default();
        let mut uart = Uart::new(
            &mut uart,
            &mut tx,
            &mut rx,
            &mut irq,
            &mut p.DMA_CH0,
            &mut p.DMA_CH1,
            config,
        );

        uart.blocking_write(&[42; 32]).unwrap();
        uart.blocking_write(&[1, 2, 3]).unwrap();
        uart.blocking_flush().unwrap();

        // can receive regular fifo contents
        assert_eq!(read(&mut uart).await, Ok([42; 16]));
        assert_eq!(read(&mut uart).await, Ok([42; 16]));
        // receiving the rest fails with overrun
        assert_eq!(read::<16>(&mut uart).await, Err(Error::Overrun));
        // new data is accepted, latest overrunning byte first
        assert_eq!(read(&mut uart).await, Ok([3]));
        uart.blocking_write(&[8, 9]).unwrap();
        Timer::after(Duration::from_millis(1)).await;
        assert_eq!(read(&mut uart).await, Ok([8, 9]));
    }

    info!("test break detection");
    {
        let config = Config::default();
        let (mut tx, mut rx) = Uart::new(
            &mut uart,
            &mut tx,
            &mut rx,
            &mut irq,
            &mut p.DMA_CH0,
            &mut p.DMA_CH1,
            config,
        )
        .split();

        // break before read
        tx.send_break(20).await;
        tx.write(&[64]).await.unwrap();
        assert_eq!(read1::<1>(&mut rx).await.unwrap_err(), Error::Break);
        assert_eq!(read1(&mut rx).await.unwrap(), [64]);

        // break during read
        {
            let r = read1::<2>(&mut rx);
            tx.write(&[2]).await.unwrap();
            tx.send_break(20).await;
            tx.write(&[3]).await.unwrap();
            assert_eq!(r.await.unwrap_err(), Error::Break);
            assert_eq!(read1(&mut rx).await.unwrap(), [3]);
        }

        // break after read
        {
            let r = read1(&mut rx);
            tx.write(&[2]).await.unwrap();
            tx.send_break(20).await;
            tx.write(&[3]).await.unwrap();
            assert_eq!(r.await.unwrap(), [2]);
            assert_eq!(read1::<1>(&mut rx).await.unwrap_err(), Error::Break);
            assert_eq!(read1(&mut rx).await.unwrap(), [3]);
        }
    }

    // parity detection. here we bitbang to not require two uarts.
    info!("test parity error detection");
    {
        let mut pin = Output::new(&mut tx, Level::High);
        // choose a very slow baud rate to make tests reliable even with O0
        let mut config = Config::default();
        config.baudrate = 1000;
        config.parity = Parity::ParityEven;
        let mut uart = UartRx::new(&mut uart, &mut rx, &mut irq, &mut p.DMA_CH0, config);

        async fn chr(pin: &mut Output<'_, impl embassy_rp::gpio::Pin>, v: u8, parity: u32) {
            send(pin, v, Some(parity != 0)).await;
        }

        // first check that we can send correctly
        chr(&mut pin, 32, 1).await;
        assert_eq!(read1(&mut uart).await.unwrap(), [32]);

        // parity error before read
        chr(&mut pin, 32, 0).await;
        chr(&mut pin, 31, 1).await;
        assert_eq!(read1::<1>(&mut uart).await.unwrap_err(), Error::Parity);
        assert_eq!(read1(&mut uart).await.unwrap(), [31]);

        // parity error during read
        {
            let r = read1::<2>(&mut uart);
            chr(&mut pin, 2, 1).await;
            chr(&mut pin, 32, 0).await;
            chr(&mut pin, 3, 0).await;
            assert_eq!(r.await.unwrap_err(), Error::Parity);
            assert_eq!(read1(&mut uart).await.unwrap(), [3]);
        }

        // parity error after read
        {
            let r = read1(&mut uart);
            chr(&mut pin, 2, 1).await;
            chr(&mut pin, 32, 0).await;
            chr(&mut pin, 3, 0).await;
            assert_eq!(r.await.unwrap(), [2]);
            assert_eq!(read1::<1>(&mut uart).await.unwrap_err(), Error::Parity);
            assert_eq!(read1(&mut uart).await.unwrap(), [3]);
        }
    }

    // framing error detection. here we bitbang because there's no other way.
    info!("test framing error detection");
    {
        let mut pin = Output::new(&mut tx, Level::High);
        // choose a very slow baud rate to make tests reliable even with O0
        let mut config = Config::default();
        config.baudrate = 1000;
        let mut uart = UartRx::new(&mut uart, &mut rx, &mut irq, &mut p.DMA_CH0, config);

        async fn chr(pin: &mut Output<'_, impl embassy_rp::gpio::Pin>, v: u8, good: bool) {
            if good {
                send(pin, v, None).await;
            } else {
                send(pin, v, Some(false)).await;
            }
        }

        // first check that we can send correctly
        chr(&mut pin, 32, true).await;
        assert_eq!(read1(&mut uart).await.unwrap(), [32]);

        // parity error before read
        chr(&mut pin, 32, false).await;
        chr(&mut pin, 31, true).await;
        assert_eq!(read1::<1>(&mut uart).await.unwrap_err(), Error::Framing);
        assert_eq!(read1(&mut uart).await.unwrap(), [31]);

        // parity error during read
        {
            let r = read1::<2>(&mut uart);
            chr(&mut pin, 2, true).await;
            chr(&mut pin, 32, false).await;
            chr(&mut pin, 3, true).await;
            assert_eq!(r.await.unwrap_err(), Error::Framing);
            assert_eq!(read1(&mut uart).await.unwrap(), [3]);
        }

        // parity error after read
        {
            let r = read1(&mut uart);
            chr(&mut pin, 2, true).await;
            chr(&mut pin, 32, false).await;
            chr(&mut pin, 3, true).await;
            assert_eq!(r.await.unwrap(), [2]);
            assert_eq!(read1::<1>(&mut uart).await.unwrap_err(), Error::Framing);
            assert_eq!(read1(&mut uart).await.unwrap(), [3]);
        }
    }

    info!("Test OK");
    cortex_m::asm::bkpt();
}
Add HIL tests of DMA & UART, and correctly set DREQ for uart DMA 2022-08-26 12:50:12 +02:00			`#![no_std]`
			`#![no_main]`
			`#![feature(type_alias_impl_trait)]`

			`use defmt::{assert_eq, *};`
			`use embassy_executor::Spawner;`
rp/uart: report errors from dma receive 2023-04-29 10:30:04 +02:00			`use embassy_rp::gpio::{Level, Output};`
			`use embassy_rp::interrupt;`
			`use embassy_rp::uart::{Async, Config, Error, Instance, Parity, Uart, UartRx};`
			`use embassy_time::{Duration, Timer};`
Add HIL tests of DMA & UART, and correctly set DREQ for uart DMA 2022-08-26 12:50:12 +02:00			`use {defmt_rtt as _, panic_probe as _};`

rp/uart: report errors from dma receive 2023-04-29 10:30:04 +02:00			`async fn read<const N: usize>(uart: &mut Uart<'_, impl Instance, Async>) -> Result<[u8; N], Error> {`
			`let mut buf = [255; N];`
			`uart.read(&mut buf).await?;`
			`Ok(buf)`
			`}`

			`async fn read1<const N: usize>(uart: &mut UartRx<'_, impl Instance, Async>) -> Result<[u8; N], Error> {`
			`let mut buf = [255; N];`
			`uart.read(&mut buf).await?;`
			`Ok(buf)`
			`}`

			`async fn send(pin: &mut Output<'_, impl embassy_rp::gpio::Pin>, v: u8, parity: Option<bool>) {`
			`pin.set_low();`
			`Timer::after(Duration::from_millis(1)).await;`
			`for i in 0..8 {`
			`if v & (1 << i) == 0 {`
			`pin.set_low();`
			`} else {`
			`pin.set_high();`
			`}`
			`Timer::after(Duration::from_millis(1)).await;`
			`}`
			`if let Some(b) = parity {`
			`if b {`
			`pin.set_high();`
			`} else {`
			`pin.set_low();`
			`}`
			`Timer::after(Duration::from_millis(1)).await;`
			`}`
			`pin.set_high();`
			`Timer::after(Duration::from_millis(1)).await;`
			`}`

Add HIL tests of DMA & UART, and correctly set DREQ for uart DMA 2022-08-26 12:50:12 +02:00			`#[embassy_executor::main]`
			`async fn main(_spawner: Spawner) {`
rp/uart: report errors from dma receive 2023-04-29 10:30:04 +02:00			`let mut p = embassy_rp::init(Default::default());`
Add HIL tests of DMA & UART, and correctly set DREQ for uart DMA 2022-08-26 12:50:12 +02:00			`info!("Hello World!");`

rp/uart: report errors from dma receive 2023-04-29 10:30:04 +02:00			`let (mut tx, mut rx, mut uart) = (p.PIN_0, p.PIN_1, p.UART0);`
			`let mut irq = interrupt::take!(UART0_IRQ);`
Add HIL tests of DMA & UART, and correctly set DREQ for uart DMA 2022-08-26 12:50:12 +02:00
			`// We can't send too many bytes, they have to fit in the FIFO.`
			`// This is because we aren't sending+receiving at the same time.`
rp/uart: report errors from dma receive 2023-04-29 10:30:04 +02:00			`{`
			`let config = Config::default();`
			`let mut uart = Uart::new(`
			`&mut uart,`
			`&mut tx,`
			`&mut rx,`
			`&mut irq,`
			`&mut p.DMA_CH0,`
			`&mut p.DMA_CH1,`
			`config,`
			`);`

			`let data = [0xC0, 0xDE];`
			`uart.write(&data).await.unwrap();`

			`let mut buf = [0; 2];`
			`uart.read(&mut buf).await.unwrap();`
			`assert_eq!(buf, data);`
			`}`

			`info!("test overflow detection");`
			`{`
			`let config = Config::default();`
			`let mut uart = Uart::new(`
			`&mut uart,`
			`&mut tx,`
			`&mut rx,`
			`&mut irq,`
			`&mut p.DMA_CH0,`
			`&mut p.DMA_CH1,`
			`config,`
			`);`

			`uart.blocking_write(&[42; 32]).unwrap();`
			`uart.blocking_write(&[1, 2, 3]).unwrap();`
			`uart.blocking_flush().unwrap();`

			`// can receive regular fifo contents`
			`assert_eq!(read(&mut uart).await, Ok([42; 16]));`
			`assert_eq!(read(&mut uart).await, Ok([42; 16]));`
			`// receiving the rest fails with overrun`
			`assert_eq!(read::<16>(&mut uart).await, Err(Error::Overrun));`
			`// new data is accepted, latest overrunning byte first`
			`assert_eq!(read(&mut uart).await, Ok([3]));`
			`uart.blocking_write(&[8, 9]).unwrap();`
			`Timer::after(Duration::from_millis(1)).await;`
			`assert_eq!(read(&mut uart).await, Ok([8, 9]));`
			`}`

			`info!("test break detection");`
			`{`
			`let config = Config::default();`
			`let (mut tx, mut rx) = Uart::new(`
			`&mut uart,`
			`&mut tx,`
			`&mut rx,`
			`&mut irq,`
			`&mut p.DMA_CH0,`
			`&mut p.DMA_CH1,`
			`config,`
			`)`
			`.split();`

			`// break before read`
			`tx.send_break(20).await;`
			`tx.write(&[64]).await.unwrap();`
			`assert_eq!(read1::<1>(&mut rx).await.unwrap_err(), Error::Break);`
			`assert_eq!(read1(&mut rx).await.unwrap(), [64]);`

			`// break during read`
			`{`
			`let r = read1::<2>(&mut rx);`
			`tx.write(&[2]).await.unwrap();`
			`tx.send_break(20).await;`
			`tx.write(&[3]).await.unwrap();`
			`assert_eq!(r.await.unwrap_err(), Error::Break);`
			`assert_eq!(read1(&mut rx).await.unwrap(), [3]);`
			`}`

			`// break after read`
			`{`
			`let r = read1(&mut rx);`
			`tx.write(&[2]).await.unwrap();`
			`tx.send_break(20).await;`
			`tx.write(&[3]).await.unwrap();`
			`assert_eq!(r.await.unwrap(), [2]);`
			`assert_eq!(read1::<1>(&mut rx).await.unwrap_err(), Error::Break);`
			`assert_eq!(read1(&mut rx).await.unwrap(), [3]);`
			`}`
			`}`

			`// parity detection. here we bitbang to not require two uarts.`
			`info!("test parity error detection");`
			`{`
			`let mut pin = Output::new(&mut tx, Level::High);`
			`// choose a very slow baud rate to make tests reliable even with O0`
			`let mut config = Config::default();`
			`config.baudrate = 1000;`
			`config.parity = Parity::ParityEven;`
			`let mut uart = UartRx::new(&mut uart, &mut rx, &mut irq, &mut p.DMA_CH0, config);`

			`async fn chr(pin: &mut Output<'_, impl embassy_rp::gpio::Pin>, v: u8, parity: u32) {`
			`send(pin, v, Some(parity != 0)).await;`
			`}`

			`// first check that we can send correctly`
			`chr(&mut pin, 32, 1).await;`
			`assert_eq!(read1(&mut uart).await.unwrap(), [32]);`

			`// parity error before read`
			`chr(&mut pin, 32, 0).await;`
			`chr(&mut pin, 31, 1).await;`
			`assert_eq!(read1::<1>(&mut uart).await.unwrap_err(), Error::Parity);`
			`assert_eq!(read1(&mut uart).await.unwrap(), [31]);`

			`// parity error during read`
			`{`
			`let r = read1::<2>(&mut uart);`
			`chr(&mut pin, 2, 1).await;`
			`chr(&mut pin, 32, 0).await;`
			`chr(&mut pin, 3, 0).await;`
			`assert_eq!(r.await.unwrap_err(), Error::Parity);`
			`assert_eq!(read1(&mut uart).await.unwrap(), [3]);`
			`}`

			`// parity error after read`
			`{`
			`let r = read1(&mut uart);`
			`chr(&mut pin, 2, 1).await;`
			`chr(&mut pin, 32, 0).await;`
			`chr(&mut pin, 3, 0).await;`
			`assert_eq!(r.await.unwrap(), [2]);`
			`assert_eq!(read1::<1>(&mut uart).await.unwrap_err(), Error::Parity);`
			`assert_eq!(read1(&mut uart).await.unwrap(), [3]);`
			`}`
			`}`

			`// framing error detection. here we bitbang because there's no other way.`
			`info!("test framing error detection");`
			`{`
			`let mut pin = Output::new(&mut tx, Level::High);`
			`// choose a very slow baud rate to make tests reliable even with O0`
			`let mut config = Config::default();`
			`config.baudrate = 1000;`
			`let mut uart = UartRx::new(&mut uart, &mut rx, &mut irq, &mut p.DMA_CH0, config);`

			`async fn chr(pin: &mut Output<'_, impl embassy_rp::gpio::Pin>, v: u8, good: bool) {`
			`if good {`
			`send(pin, v, None).await;`
			`} else {`
			`send(pin, v, Some(false)).await;`
			`}`
			`}`

			`// first check that we can send correctly`
			`chr(&mut pin, 32, true).await;`
			`assert_eq!(read1(&mut uart).await.unwrap(), [32]);`

			`// parity error before read`
			`chr(&mut pin, 32, false).await;`
			`chr(&mut pin, 31, true).await;`
			`assert_eq!(read1::<1>(&mut uart).await.unwrap_err(), Error::Framing);`
			`assert_eq!(read1(&mut uart).await.unwrap(), [31]);`
Add HIL tests of DMA & UART, and correctly set DREQ for uart DMA 2022-08-26 12:50:12 +02:00
rp/uart: report errors from dma receive 2023-04-29 10:30:04 +02:00			`// parity error during read`
			`{`
			`let r = read1::<2>(&mut uart);`
			`chr(&mut pin, 2, true).await;`
			`chr(&mut pin, 32, false).await;`
			`chr(&mut pin, 3, true).await;`
			`assert_eq!(r.await.unwrap_err(), Error::Framing);`
			`assert_eq!(read1(&mut uart).await.unwrap(), [3]);`
			`}`
Add HIL tests of DMA & UART, and correctly set DREQ for uart DMA 2022-08-26 12:50:12 +02:00
rp/uart: report errors from dma receive 2023-04-29 10:30:04 +02:00			`// parity error after read`
			`{`
			`let r = read1(&mut uart);`
			`chr(&mut pin, 2, true).await;`
			`chr(&mut pin, 32, false).await;`
			`chr(&mut pin, 3, true).await;`
			`assert_eq!(r.await.unwrap(), [2]);`
			`assert_eq!(read1::<1>(&mut uart).await.unwrap_err(), Error::Framing);`
			`assert_eq!(read1(&mut uart).await.unwrap(), [3]);`
			`}`
			`}`
Add HIL tests of DMA & UART, and correctly set DREQ for uart DMA 2022-08-26 12:50:12 +02:00
			`info!("Test OK");`
			`cortex_m::asm::bkpt();`
			`}`