embassy/examples/rp/src/bin/pio_hd44780.rs

//! This example shows powerful PIO module in the RP2040 chip to communicate with a HD44780 display.
//! See (https://www.sparkfun.com/datasheets/LCD/HD44780.pdf)

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

use core::fmt::Write;

use embassy_executor::Spawner;
use embassy_rp::dma::{AnyChannel, Channel};
use embassy_rp::peripherals::PIO0;
use embassy_rp::pio::{
    Config, Direction, FifoJoin, InterruptHandler, Pio, PioPin, ShiftConfig, ShiftDirection, StateMachine,
};
use embassy_rp::pwm::{self, Pwm};
use embassy_rp::{bind_interrupts, into_ref, Peripheral, PeripheralRef};
use embassy_time::{Instant, Timer};
use {defmt_rtt as _, panic_probe as _};

bind_interrupts!(pub struct Irqs {
    PIO0_IRQ_0 => InterruptHandler<PIO0>;
});

#[embassy_executor::main]
async fn main(_spawner: Spawner) {
    // this test assumes a 2x16 HD44780 display attached as follow:
    //   rs  = PIN0
    //   rw  = PIN1
    //   e   = PIN2
    //   db4 = PIN3
    //   db5 = PIN4
    //   db6 = PIN5
    //   db7 = PIN6
    // additionally a pwm signal for a bias voltage charge pump is provided on pin 15,
    // allowing direct connection of the display to the RP2040 without level shifters.
    let p = embassy_rp::init(Default::default());

    let _pwm = Pwm::new_output_b(p.PWM_CH7, p.PIN_15, {
        let mut c = pwm::Config::default();
        c.divider = 125.into();
        c.top = 100;
        c.compare_b = 50;
        c
    });

    let mut hd = HD44780::new(
        p.PIO0, Irqs, p.DMA_CH3, p.PIN_0, p.PIN_1, p.PIN_2, p.PIN_3, p.PIN_4, p.PIN_5, p.PIN_6,
    )
    .await;

    loop {
        struct Buf<const N: usize>([u8; N], usize);
        impl<const N: usize> Write for Buf<N> {
            fn write_str(&mut self, s: &str) -> Result<(), core::fmt::Error> {
                for b in s.as_bytes() {
                    if self.1 >= N {
                        return Err(core::fmt::Error);
                    }
                    self.0[self.1] = *b;
                    self.1 += 1;
                }
                Ok(())
            }
        }
        let mut buf = Buf([0; 16], 0);
        write!(buf, "up {}s", Instant::now().as_micros() as f32 / 1e6).unwrap();
        hd.add_line(&buf.0[0..buf.1]).await;
        Timer::after_secs(1).await;
    }
}

pub struct HD44780<'l> {
    dma: PeripheralRef<'l, AnyChannel>,
    sm: StateMachine<'l, PIO0, 0>,

    buf: [u8; 40],
}

impl<'l> HD44780<'l> {
    pub async fn new(
        pio: impl Peripheral<P = PIO0> + 'l,
        irq: Irqs,
        dma: impl Peripheral<P = impl Channel> + 'l,
        rs: impl PioPin,
        rw: impl PioPin,
        e: impl PioPin,
        db4: impl PioPin,
        db5: impl PioPin,
        db6: impl PioPin,
        db7: impl PioPin,
    ) -> HD44780<'l> {
        into_ref!(dma);

        let Pio {
            mut common,
            mut irq0,
            mut sm0,
            ..
        } = Pio::new(pio, irq);

        // takes command words (<wait:24> <command:4> <0:4>)
        let prg = pio_proc::pio_asm!(
            r#"
                .side_set 1 opt
                .origin 20

                loop:
                    out x,     24
                delay:
                    jmp x--,   delay
                    out pins,  4     side 1
                    out null,  4     side 0
                    jmp !osre, loop
                irq 0
            "#,
        );

        let rs = common.make_pio_pin(rs);
        let rw = common.make_pio_pin(rw);
        let e = common.make_pio_pin(e);
        let db4 = common.make_pio_pin(db4);
        let db5 = common.make_pio_pin(db5);
        let db6 = common.make_pio_pin(db6);
        let db7 = common.make_pio_pin(db7);

        sm0.set_pin_dirs(Direction::Out, &[&rs, &rw, &e, &db4, &db5, &db6, &db7]);

        let mut cfg = Config::default();
        cfg.use_program(&common.load_program(&prg.program), &[&e]);
        cfg.clock_divider = 125u8.into();
        cfg.set_out_pins(&[&db4, &db5, &db6, &db7]);
        cfg.shift_out = ShiftConfig {
            auto_fill: true,
            direction: ShiftDirection::Left,
            threshold: 32,
        };
        cfg.fifo_join = FifoJoin::TxOnly;
        sm0.set_config(&cfg);

        sm0.set_enable(true);
        // init to 8 bit thrice
        sm0.tx().push((50000 << 8) | 0x30);
        sm0.tx().push((5000 << 8) | 0x30);
        sm0.tx().push((200 << 8) | 0x30);
        // init 4 bit
        sm0.tx().push((200 << 8) | 0x20);
        // set font and lines
        sm0.tx().push((50 << 8) | 0x20);
        sm0.tx().push(0b1100_0000);

        irq0.wait().await;
        sm0.set_enable(false);

        // takes command sequences (<rs:1> <count:7>, data...)
        // many side sets are only there to free up a delay bit!
        let prg = pio_proc::pio_asm!(
            r#"
                .origin 27
                .side_set 1

                .wrap_target
                pull     side 0
                out  x 1 side 0 ; !rs
                out  y 7 side 0 ; #data - 1

                ; rs/rw to e: >= 60ns
                ; e high time: >= 500ns
                ; e low time: >= 500ns
                ; read data valid after e falling: ~5ns
                ; write data hold after e falling: ~10ns

                loop:
                    pull                 side 0
                    jmp  !x       data   side 0
                command:
                    set  pins     0b00   side 0
                    jmp  shift           side 0
                data:
                    set  pins     0b01   side 0
                shift:
                    out  pins     4      side 1 [9]
                    nop                  side 0 [9]
                    out  pins     4      side 1 [9]
                    mov  osr      null   side 0 [7]
                    out  pindirs  4      side 0
                    set  pins     0b10   side 0
                busy:
                    nop                  side 1 [9]
                    jmp  pin      more   side 0 [9]
                    mov  osr      ~osr   side 1 [9]
                    nop                  side 0 [4]
                    out  pindirs  4      side 0
                    jmp  y--      loop   side 0
                .wrap
                more:
                    nop                  side 1 [9]
                    jmp busy             side 0 [9]
            "#
        );

        let mut cfg = Config::default();
        cfg.use_program(&common.load_program(&prg.program), &[&e]);
        cfg.clock_divider = 8u8.into(); // ~64ns/insn
        cfg.set_jmp_pin(&db7);
        cfg.set_set_pins(&[&rs, &rw]);
        cfg.set_out_pins(&[&db4, &db5, &db6, &db7]);
        cfg.shift_out.direction = ShiftDirection::Left;
        cfg.fifo_join = FifoJoin::TxOnly;
        sm0.set_config(&cfg);

        sm0.set_enable(true);

        // display on and cursor on and blinking, reset display
        sm0.tx().dma_push(dma.reborrow(), &[0x81u8, 0x0f, 1]).await;

        Self {
            dma: dma.map_into(),
            sm: sm0,
            buf: [0x20; 40],
        }
    }

    pub async fn add_line(&mut self, s: &[u8]) {
        // move cursor to 0:0, prepare 16 characters
        self.buf[..3].copy_from_slice(&[0x80, 0x80, 15]);
        // move line 2 up
        self.buf.copy_within(22..38, 3);
        // move cursor to 1:0, prepare 16 characters
        self.buf[19..22].copy_from_slice(&[0x80, 0xc0, 15]);
        // file line 2 with spaces
        self.buf[22..38].fill(0x20);
        // copy input line
        let len = s.len().min(16);
        self.buf[22..22 + len].copy_from_slice(&s[0..len]);
        // set cursor to 1:15
        self.buf[38..].copy_from_slice(&[0x80, 0xcf]);

        self.sm.tx().dma_push(self.dma.reborrow(), &self.buf).await;
    }
}
Add descriptions to all RP2040 examples. Some need hardware that was not specified. 2023-07-13 11:16:11 +02:00			`//! This example shows powerful PIO module in the RP2040 chip to communicate with a HD44780 display.`
			`//! See (https://www.sparkfun.com/datasheets/LCD/HD44780.pdf)`

rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`#![no_std]`
			`#![no_main]`
			`#![feature(type_alias_impl_trait)]`

			`use core::fmt::Write;`

			`use embassy_executor::Spawner;`
			`use embassy_rp::dma::{AnyChannel, Channel};`
			`use embassy_rp::peripherals::PIO0;`
rp/pio: use bind_interrupts for irqs closes #1338 2023-07-07 04:30:46 +02:00			`use embassy_rp::pio::{`
			`Config, Direction, FifoJoin, InterruptHandler, Pio, PioPin, ShiftConfig, ShiftDirection, StateMachine,`
			`};`
rp/pio: configure state machines with Config struct the many individual sets aren't very efficient, and almost no checks were done to ensure that the configuration written to the hardware was actually valid. this adresses both of these. 2023-05-06 11:36:07 +02:00			`use embassy_rp::pwm::{self, Pwm};`
rp/pio: use bind_interrupts for irqs closes #1338 2023-07-07 04:30:46 +02:00			`use embassy_rp::{bind_interrupts, into_ref, Peripheral, PeripheralRef};`
time: Update examples, tests, and other code to use new Timer::after_x convenience methods 2023-10-15 01:57:25 +02:00			`use embassy_time::{Instant, Timer};`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`use {defmt_rtt as _, panic_probe as _};`

rp/pio: use bind_interrupts for irqs closes #1338 2023-07-07 04:30:46 +02:00			`bind_interrupts!(pub struct Irqs {`
			`PIO0_IRQ_0 => InterruptHandler<PIO0>;`
			`});`

rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`#[embassy_executor::main]`
			`async fn main(_spawner: Spawner) {`
			`// this test assumes a 2x16 HD44780 display attached as follow:`
			`// rs = PIN0`
			`// rw = PIN1`
			`// e = PIN2`
			`// db4 = PIN3`
			`// db5 = PIN4`
			`// db6 = PIN5`
			`// db7 = PIN6`
			`// additionally a pwm signal for a bias voltage charge pump is provided on pin 15,`
			`// allowing direct connection of the display to the RP2040 without level shifters.`
			`let p = embassy_rp::init(Default::default());`

			`let _pwm = Pwm::new_output_b(p.PWM_CH7, p.PIN_15, {`
rp/pio: configure state machines with Config struct the many individual sets aren't very efficient, and almost no checks were done to ensure that the configuration written to the hardware was actually valid. this adresses both of these. 2023-05-06 11:36:07 +02:00			`let mut c = pwm::Config::default();`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`c.divider = 125.into();`
			`c.top = 100;`
			`c.compare_b = 50;`
			`c`
			`});`

			`let mut hd = HD44780::new(`
rp/pio: use bind_interrupts for irqs closes #1338 2023-07-07 04:30:46 +02:00			`p.PIO0, Irqs, p.DMA_CH3, p.PIN_0, p.PIN_1, p.PIN_2, p.PIN_3, p.PIN_4, p.PIN_5, p.PIN_6,`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`)`
			`.await;`

			`loop {`
			`struct Buf<const N: usize>([u8; N], usize);`
			`impl<const N: usize> Write for Buf<N> {`
			`fn write_str(&mut self, s: &str) -> Result<(), core::fmt::Error> {`
			`for b in s.as_bytes() {`
			`if self.1 >= N {`
			`return Err(core::fmt::Error);`
			`}`
			`self.0[self.1] = *b;`
			`self.1 += 1;`
			`}`
			`Ok(())`
			`}`
			`}`
			`let mut buf = Buf([0; 16], 0);`
			`write!(buf, "up {}s", Instant::now().as_micros() as f32 / 1e6).unwrap();`
			`hd.add_line(&buf.0[0..buf.1]).await;`
time: Update examples, tests, and other code to use new Timer::after_x convenience methods 2023-10-15 01:57:25 +02:00			`Timer::after_secs(1).await;`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`}`
			`}`

			`pub struct HD44780<'l> {`
			`dma: PeripheralRef<'l, AnyChannel>,`
rp/pio: drop Pio prefix from almost all names it's only any good for PioPin because there it follows a pattern of gpio pin alternate functions being named like that, everything else can just as well be referred to as `pio::Thing` 2023-05-03 17:16:35 +02:00			`sm: StateMachine<'l, PIO0, 0>,`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00
			`buf: [u8; 40],`
			`}`

			`impl<'l> HD44780<'l> {`
			`pub async fn new(`
rp/pio: PioInstance::split -> Pio::new not requiring a PioInstance for splitting lets us split from a PeripheralRef or borrowed PIO as well, mirroring every other peripheral in embassy_rp. pio pins still have to be constructed from owned pin instances for now. 2023-04-26 19:43:57 +02:00			`pio: impl Peripheral<P = PIO0> + 'l,`
rp/pio: use bind_interrupts for irqs closes #1338 2023-07-07 04:30:46 +02:00			`irq: Irqs,`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`dma: impl Peripheral<P = impl Channel> + 'l,`
rp/pio: add PioPin trait pio can only access pins in bank 0, so it doesn't make sense to even allow wrapping of other banks' pins. 2023-05-03 08:15:46 +02:00			`rs: impl PioPin,`
			`rw: impl PioPin,`
			`e: impl PioPin,`
			`db4: impl PioPin,`
			`db5: impl PioPin,`
			`db6: impl PioPin,`
			`db7: impl PioPin,`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`) -> HD44780<'l> {`
			`into_ref!(dma);`

rp/pio: PioInstance::split -> Pio::new not requiring a PioInstance for splitting lets us split from a PeripheralRef or borrowed PIO as well, mirroring every other peripheral in embassy_rp. pio pins still have to be constructed from owned pin instances for now. 2023-04-26 19:43:57 +02:00			`let Pio {`
rp/pio: split irqs from state machines we can only have one active waiter for any given irq at any given time. allowing waits for irqs on state machines bypasses this limitation and causes lost events for all but the latest waiter for a given irq. splitting this out also allows us to signal from state machines to other parts of the application without monopolizing state machine access for the irq wait, as would be necessary to make irq waiting sound. 2023-04-27 02:12:49 +02:00			`mut common,`
			`mut irq0,`
			`mut sm0,`
			`..`
rp/pio: use bind_interrupts for irqs closes #1338 2023-07-07 04:30:46 +02:00			`} = Pio::new(pio, irq);`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00
			`// takes command words (<wait:24> <command:4> <0:4>)`
			`let prg = pio_proc::pio_asm!(`
			`r#"`
			`.side_set 1 opt`
rp/pio: allow wrap-around program loading execution wraps around after the end of instruction memory and wrapping works with this, so we may as well allow program loading across this boundary. could be useful for reusing chunks of instruction memory. 2023-05-06 20:53:06 +02:00			`.origin 20`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00
			`loop:`
			`out x, 24`
			`delay:`
			`jmp x--, delay`
			`out pins, 4 side 1`
			`out null, 4 side 0`
			`jmp !osre, loop`
			`irq 0`
			`"#,`
			`);`

			`let rs = common.make_pio_pin(rs);`
			`let rw = common.make_pio_pin(rw);`
			`let e = common.make_pio_pin(e);`
			`let db4 = common.make_pio_pin(db4);`
			`let db5 = common.make_pio_pin(db5);`
			`let db6 = common.make_pio_pin(db6);`
			`let db7 = common.make_pio_pin(db7);`

rp/pio: add set-pin-{values,dirs} convenience functions these are needed a lot during state machine setup, it makes sense to provide convenience functions for them. 2023-05-05 20:45:02 +02:00			`sm0.set_pin_dirs(Direction::Out, &[&rs, &rw, &e, &db4, &db5, &db6, &db7]);`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00
rp/pio: configure state machines with Config struct the many individual sets aren't very efficient, and almost no checks were done to ensure that the configuration written to the hardware was actually valid. this adresses both of these. 2023-05-06 11:36:07 +02:00			`let mut cfg = Config::default();`
rp: relocate programs implicitly during load this removed the RelocatedProgram construction step from pio uses. there's not all that much to be said for the extra step because the origin can be set on the input program itself, and the remaining information exposed by RelocatedProgram can be exposed from LoadedProgram instead (even though it's already available on the pio_asm programs, albeit perhaps less convenient). we do lose access to the relocated instruction iterator, but we also cannot think of anything this iterator would actually be useful for outside of program loading. 2023-07-28 18:45:57 +02:00			`cfg.use_program(&common.load_program(&prg.program), &[&e]);`
rp/pio: configure state machines with Config struct the many individual sets aren't very efficient, and almost no checks were done to ensure that the configuration written to the hardware was actually valid. this adresses both of these. 2023-05-06 11:36:07 +02:00			`cfg.clock_divider = 125u8.into();`
			`cfg.set_out_pins(&[&db4, &db5, &db6, &db7]);`
			`cfg.shift_out = ShiftConfig {`
			`auto_fill: true,`
			`direction: ShiftDirection::Left,`
			`threshold: 32,`
			`};`
			`cfg.fifo_join = FifoJoin::TxOnly;`
			`sm0.set_config(&cfg);`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00
			`sm0.set_enable(true);`
			`// init to 8 bit thrice`
rp/pio: wrap sm rx, tx in structs and allow splitting this finally allows sound implementions of bidirectional transfers without blocking. the futures previously allowed only a single direction to be active at any given time, and the dma transfers didn't take a mutable reference and were thus unsound. 2023-05-03 12:49:55 +02:00			`sm0.tx().push((50000 << 8) \| 0x30);`
			`sm0.tx().push((5000 << 8) \| 0x30);`
			`sm0.tx().push((200 << 8) \| 0x30);`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`// init 4 bit`
rp/pio: wrap sm rx, tx in structs and allow splitting this finally allows sound implementions of bidirectional transfers without blocking. the futures previously allowed only a single direction to be active at any given time, and the dma transfers didn't take a mutable reference and were thus unsound. 2023-05-03 12:49:55 +02:00			`sm0.tx().push((200 << 8) \| 0x20);`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`// set font and lines`
rp/pio: wrap sm rx, tx in structs and allow splitting this finally allows sound implementions of bidirectional transfers without blocking. the futures previously allowed only a single direction to be active at any given time, and the dma transfers didn't take a mutable reference and were thus unsound. 2023-05-03 12:49:55 +02:00			`sm0.tx().push((50 << 8) \| 0x20);`
			`sm0.tx().push(0b1100_0000);`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00
rp/pio: split irqs from state machines we can only have one active waiter for any given irq at any given time. allowing waits for irqs on state machines bypasses this limitation and causes lost events for all but the latest waiter for a given irq. splitting this out also allows us to signal from state machines to other parts of the application without monopolizing state machine access for the irq wait, as would be necessary to make irq waiting sound. 2023-04-27 02:12:49 +02:00			`irq0.wait().await;`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`sm0.set_enable(false);`

			`// takes command sequences (<rs:1> <count:7>, data...)`
			`// many side sets are only there to free up a delay bit!`
			`let prg = pio_proc::pio_asm!(`
			`r#"`
rp/pio: allow wrap-around program loading execution wraps around after the end of instruction memory and wrapping works with this, so we may as well allow program loading across this boundary. could be useful for reusing chunks of instruction memory. 2023-05-06 20:53:06 +02:00			`.origin 27`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`.side_set 1`

			`.wrap_target`
			`pull side 0`
			`out x 1 side 0 ; !rs`
			`out y 7 side 0 ; #data - 1`

			`; rs/rw to e: >= 60ns`
			`; e high time: >= 500ns`
			`; e low time: >= 500ns`
			`; read data valid after e falling: ~5ns`
			`; write data hold after e falling: ~10ns`

			`loop:`
			`pull side 0`
			`jmp !x data side 0`
			`command:`
			`set pins 0b00 side 0`
			`jmp shift side 0`
			`data:`
			`set pins 0b01 side 0`
			`shift:`
			`out pins 4 side 1 [9]`
			`nop side 0 [9]`
			`out pins 4 side 1 [9]`
			`mov osr null side 0 [7]`
			`out pindirs 4 side 0`
			`set pins 0b10 side 0`
			`busy:`
			`nop side 1 [9]`
			`jmp pin more side 0 [9]`
			`mov osr ~osr side 1 [9]`
			`nop side 0 [4]`
			`out pindirs 4 side 0`
			`jmp y-- loop side 0`
			`.wrap`
			`more:`
			`nop side 1 [9]`
			`jmp busy side 0 [9]`
			`"#`
			`);`

rp/pio: configure state machines with Config struct the many individual sets aren't very efficient, and almost no checks were done to ensure that the configuration written to the hardware was actually valid. this adresses both of these. 2023-05-06 11:36:07 +02:00			`let mut cfg = Config::default();`
rp: relocate programs implicitly during load this removed the RelocatedProgram construction step from pio uses. there's not all that much to be said for the extra step because the origin can be set on the input program itself, and the remaining information exposed by RelocatedProgram can be exposed from LoadedProgram instead (even though it's already available on the pio_asm programs, albeit perhaps less convenient). we do lose access to the relocated instruction iterator, but we also cannot think of anything this iterator would actually be useful for outside of program loading. 2023-07-28 18:45:57 +02:00			`cfg.use_program(&common.load_program(&prg.program), &[&e]);`
rp/pio: configure state machines with Config struct the many individual sets aren't very efficient, and almost no checks were done to ensure that the configuration written to the hardware was actually valid. this adresses both of these. 2023-05-06 11:36:07 +02:00			`cfg.clock_divider = 8u8.into(); // ~64ns/insn`
			`cfg.set_jmp_pin(&db7);`
			`cfg.set_set_pins(&[&rs, &rw]);`
			`cfg.set_out_pins(&[&db4, &db5, &db6, &db7]);`
			`cfg.shift_out.direction = ShiftDirection::Left;`
			`cfg.fifo_join = FifoJoin::TxOnly;`
			`sm0.set_config(&cfg);`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00
			`sm0.set_enable(true);`

			`// display on and cursor on and blinking, reset display`
rp/pio: wrap sm rx, tx in structs and allow splitting this finally allows sound implementions of bidirectional transfers without blocking. the futures previously allowed only a single direction to be active at any given time, and the dma transfers didn't take a mutable reference and were thus unsound. 2023-05-03 12:49:55 +02:00			`sm0.tx().dma_push(dma.reborrow(), &[0x81u8, 0x0f, 1]).await;`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00
			`Self {`
			`dma: dma.map_into(),`
			`sm: sm0,`
			`buf: [0x20; 40],`
			`}`
			`}`

			`pub async fn add_line(&mut self, s: &[u8]) {`
			`// move cursor to 0:0, prepare 16 characters`
			`self.buf[..3].copy_from_slice(&[0x80, 0x80, 15]);`
			`// move line 2 up`
			`self.buf.copy_within(22..38, 3);`
			`// move cursor to 1:0, prepare 16 characters`
			`self.buf[19..22].copy_from_slice(&[0x80, 0xc0, 15]);`
			`// file line 2 with spaces`
			`self.buf[22..38].fill(0x20);`
			`// copy input line`
			`let len = s.len().min(16);`
			`self.buf[22..22 + len].copy_from_slice(&s[0..len]);`
			`// set cursor to 1:15`
			`self.buf[38..].copy_from_slice(&[0x80, 0xcf]);`

rp/pio: wrap sm rx, tx in structs and allow splitting this finally allows sound implementions of bidirectional transfers without blocking. the futures previously allowed only a single direction to be active at any given time, and the dma transfers didn't take a mutable reference and were thus unsound. 2023-05-03 12:49:55 +02:00			`self.sm.tx().dma_push(self.dma.reborrow(), &self.buf).await;`
rp/pio: add hd44780 example add an hd44780 example for pio. hd44780 with busy polling is a pretty complicated protocol if the busy polling is to be done by the peripheral, and this example exercises many pio features that we don't have good examples for yet. 2023-05-02 10:44:00 +02:00			`}`
			`}`