Merge #591

591: PWM WS2812B example and flexible sequence config r=Dirbaio a=huntc I've permitted the PWM sequences to be mutated on stopping the PWM by associating them with a new `SingleSequencer` structure. This is so that we can perform effects on the LEDs (and other use-cases, I'm sure!). The example has been updated to illustrate the use of this by flashing a WS2812B LED. There's also a `Sequencer` structure for more sophisticated PWM interactions, along with a `pwm_double_sequence` example to illustrate. These changes should make it possible to attain all of the nRF PWM functionality available. Co-authored-by: huntc <huntchr@gmail.com>
2022-02-05 02:20:13 +00:00 · 2022-02-05 02:20:13 +00:00 · a1d6077446
commit a1d6077446
parent def3283e44 df5ba727f2
5 changed files with 368 additions and 129 deletions
--- a/embassy-nrf/src/pwm.rs
+++ b/embassy-nrf/src/pwm.rs
@ -45,6 +45,8 @@ pub enum Error {
    DMABufferNotInDataMemory,
 }
 const MAX_SEQUENCE_LEN: usize = 32767;
 impl<'d, T: Instance> SequencePwm<'d, T> {
    /// Creates the interface to a `SequencePwm`.
    ///
@ -62,7 +64,7 @@ impl<'d, T: Instance> SequencePwm<'d, T> {
        ch1: impl Unborrow<Target = impl GpioOptionalPin> + 'd,
        ch2: impl Unborrow<Target = impl GpioOptionalPin> + 'd,
        ch3: impl Unborrow<Target = impl GpioOptionalPin> + 'd,
-        config: SequenceConfig,
+        config: Config,
    ) -> Result<Self, Error> {
        unborrow!(ch0, ch1, ch2, ch3);
@ -117,16 +119,6 @@ impl<'d, T: Instance> SequencePwm<'d, T> {
        r.countertop
            .write(|w| unsafe { w.countertop().bits(config.max_duty) });
        r.seq0.refresh.write(|w| unsafe { w.bits(config.refresh) });
        r.seq0
            .enddelay
            .write(|w| unsafe { w.bits(config.end_delay) });
        r.seq1.refresh.write(|w| unsafe { w.bits(config.refresh) });
        r.seq1
            .enddelay
            .write(|w| unsafe { w.bits(config.end_delay) });
        Ok(Self {
            phantom: PhantomData,
            ch0: ch0.degrade_optional(),
@ -136,80 +128,6 @@ impl<'d, T: Instance> SequencePwm<'d, T> {
        })
    }
    /// Start or restart playback
    #[inline(always)]
    pub fn start(&mut self, sequence: &'d [u16], times: SequenceMode) -> Result<(), Error> {
        slice_in_ram_or(sequence, Error::DMABufferNotInDataMemory)?;
        if sequence.len() > 32767 {
            return Err(Error::SequenceTooLong);
        }
        if let SequenceMode::Times(0) = times {
            return Err(Error::SequenceTimesAtLeastOne);
        }
        self.stop();
        let r = T::regs();
        r.seq0
            .ptr
            .write(|w| unsafe { w.bits(sequence.as_ptr() as u32) });
        r.seq0
            .cnt
            .write(|w| unsafe { w.bits(sequence.len() as u32) });
        r.seq1
            .ptr
            .write(|w| unsafe { w.bits(sequence.as_ptr() as u32) });
        r.seq1
            .cnt
            .write(|w| unsafe { w.bits(sequence.len() as u32) });
        r.enable.write(|w| w.enable().enabled());
        // defensive before seqstart
        compiler_fence(Ordering::SeqCst);
        match times {
            // just the one time, no loop count
            SequenceMode::Times(1) => {
                r.loop_.write(|w| w.cnt().disabled());
                // tasks_seqstart() doesn't exist in all svds so write its bit instead
                r.tasks_seqstart[0].write(|w| unsafe { w.bits(0x01) });
            }
            // loop count is how many times to play BOTH sequences
            // 2 total  (1 x 2)
            // 3 total, (2 x 2) - 1
            SequenceMode::Times(n) => {
                let odd = n & 1 == 1;
                let times = if odd { (n / 2) + 1 } else { n / 2 };
                r.loop_.write(|w| unsafe { w.cnt().bits(times) });
                // we can subtract 1 by starting at seq1 instead of seq0
                if odd {
                    // tasks_seqstart() doesn't exist in all svds so write its bit instead
                    r.tasks_seqstart[1].write(|w| unsafe { w.bits(0x01) });
                } else {
                    // tasks_seqstart() doesn't exist in all svds so write its bit instead
                    r.tasks_seqstart[0].write(|w| unsafe { w.bits(0x01) });
                }
            }
            // to play infinitely, repeat the sequence one time, then have loops done self trigger seq0 again
            SequenceMode::Infinite => {
                r.loop_.write(|w| unsafe { w.cnt().bits(0x1) });
                r.shorts.write(|w| w.loopsdone_seqstart0().enabled());
                // tasks_seqstart() doesn't exist in all svds so write its bit instead
                r.tasks_seqstart[0].write(|w| unsafe { w.bits(0x01) });
            }
        }
        Ok(())
    }
    /// Returns reference to `Stopped` event endpoint for PPI.
    #[inline(always)]
    pub fn event_stopped(&self) -> Event {
@ -309,30 +227,12 @@ impl<'d, T: Instance> SequencePwm<'d, T> {
        Task::from_reg(&r.tasks_stop)
    }
    /// Stop playback. Disables the peripheral. Does NOT clear the last duty
    /// cycle from the pin.
    #[inline(always)]
    pub fn stop(&self) {
        let r = T::regs();
        r.shorts.reset();
        compiler_fence(Ordering::SeqCst);
        // tasks_stop() doesn't exist in all svds so write its bit instead
        r.tasks_stop.write(|w| unsafe { w.bits(0x01) });
        r.enable.write(|w| w.enable().disabled());
    }
 }
 impl<'a, T: Instance> Drop for SequencePwm<'a, T> {
    fn drop(&mut self) {
        let r = T::regs();
        self.stop();
        if let Some(pin) = &self.ch0 {
            pin.set_low();
            pin.conf().reset();
@ -356,9 +256,9 @@ impl<'a, T: Instance> Drop for SequencePwm<'a, T> {
    }
 }
-/// Configure an infinite looping sequence for `SequencePwm`
+/// Configuration for the PWM as a whole.
 #[non_exhaustive]
-pub struct SequenceConfig {
+pub struct Config {
    /// Selects up mode or up-and-down mode for the counter
    pub counter_mode: CounterMode,
    /// Top value to be compared against buffer values
@ -367,6 +267,23 @@ pub struct SequenceConfig {
    pub prescaler: Prescaler,
    /// How a sequence is read from RAM and is spread to the compare register
    pub sequence_load: SequenceLoad,
 }
 impl Default for Config {
    fn default() -> Config {
        Config {
            counter_mode: CounterMode::Up,
            max_duty: 1000,
            prescaler: Prescaler::Div16,
            sequence_load: SequenceLoad::Common,
        }
    }
 }
 /// Configuration per sequence
 #[non_exhaustive]
 #[derive(Clone)]
 pub struct SequenceConfig {
    /// Number of PWM periods to delay between each sequence sample
    pub refresh: u32,
    /// Number of PWM periods after the sequence ends before starting the next sequence
@ -376,21 +293,215 @@ pub struct SequenceConfig {
 impl Default for SequenceConfig {
    fn default() -> SequenceConfig {
        SequenceConfig {
            counter_mode: CounterMode::Up,
            max_duty: 1000,
            prescaler: Prescaler::Div16,
            sequence_load: SequenceLoad::Common,
            refresh: 0,
            end_delay: 0,
        }
    }
 }
-/// How many times to run the sequence
+/// A composition of a sequence buffer and its configuration.
 #[non_exhaustive]
 pub struct Sequence<'s> {
    /// The words comprising the sequence. Must not exceed 32767 words.
    pub words: &'s [u16],
    /// Configuration associated with the sequence.
    pub config: SequenceConfig,
 }
 impl<'s> Sequence<'s> {
    pub fn new(words: &'s [u16], config: SequenceConfig) -> Self {
        Self { words, config }
    }
 }
 /// A single sequence that can be started and stopped.
 /// Takes at one sequence along with its configuration.
 #[non_exhaustive]
 pub struct SingleSequencer<'d, 's, T: Instance> {
    pub sequencer: Sequencer<'d, 's, T>,
 }
 impl<'d, 's, T: Instance> SingleSequencer<'d, 's, T> {
    /// Create a new sequencer
    pub fn new(pwm: &'s mut SequencePwm<'d, T>, words: &'s [u16], config: SequenceConfig) -> Self {
        Self {
            sequencer: Sequencer::new(pwm, Sequence::new(words, config), None),
        }
    }
    /// Start or restart playback.
    #[inline(always)]
    pub fn start(&self, times: SingleSequenceMode) -> Result<(), Error> {
        let (start_seq, times) = match times {
            SingleSequenceMode::Times(n) if n == 1 => (StartSequence::One, SequenceMode::Loop(1)),
            SingleSequenceMode::Times(n) if n & 1 == 1 => {
                (StartSequence::One, SequenceMode::Loop((n / 2) + 1))
            }
            SingleSequenceMode::Times(n) => (StartSequence::Zero, SequenceMode::Loop(n / 2)),
            SingleSequenceMode::Infinite => (StartSequence::Zero, SequenceMode::Infinite),
        };
        self.sequencer.start(start_seq, times)
    }
    /// Stop playback. Disables the peripheral. Does NOT clear the last duty
    /// cycle from the pin. Returns any sequences previously provided to
    /// `start` so that they may be further mutated.
    #[inline(always)]
    pub fn stop(&self) {
        self.sequencer.stop();
    }
 }
 /// A composition of sequences that can be started and stopped.
 /// Takes at least one sequence along with its configuration.
 /// Optionally takes a second sequence and its configuration.
 /// In the case where no second sequence is provided then the first sequence
 /// is used.
 #[non_exhaustive]
 pub struct Sequencer<'d, 's, T: Instance> {
    _pwm: &'s mut SequencePwm<'d, T>,
    sequence0: Sequence<'s>,
    sequence1: Option<Sequence<'s>>,
 }
 impl<'d, 's, T: Instance> Sequencer<'d, 's, T> {
    /// Create a new double sequence. In the absence of sequence 1, sequence 0
    /// will be used twice in the one loop.
    pub fn new(
        pwm: &'s mut SequencePwm<'d, T>,
        sequence0: Sequence<'s>,
        sequence1: Option<Sequence<'s>>,
    ) -> Self {
        Sequencer {
            _pwm: pwm,
            sequence0,
            sequence1,
        }
    }
    /// Start or restart playback. The sequence mode applies to both sequences combined as one.
    #[inline(always)]
    pub fn start(&self, start_seq: StartSequence, times: SequenceMode) -> Result<(), Error> {
        let sequence0 = &self.sequence0;
        let alt_sequence = self.sequence1.as_ref().unwrap_or(&self.sequence0);
        slice_in_ram_or(sequence0.words, Error::DMABufferNotInDataMemory)?;
        slice_in_ram_or(alt_sequence.words, Error::DMABufferNotInDataMemory)?;
        if sequence0.words.len() > MAX_SEQUENCE_LEN || alt_sequence.words.len() > MAX_SEQUENCE_LEN {
            return Err(Error::SequenceTooLong);
        }
        if let SequenceMode::Loop(0) = times {
            return Err(Error::SequenceTimesAtLeastOne);
        }
        let _ = self.stop();
        let r = T::regs();
        r.seq0
            .refresh
            .write(|w| unsafe { w.bits(sequence0.config.refresh) });
        r.seq0
            .enddelay
            .write(|w| unsafe { w.bits(sequence0.config.end_delay) });
        r.seq0
            .ptr
            .write(|w| unsafe { w.bits(sequence0.words.as_ptr() as u32) });
        r.seq0
            .cnt
            .write(|w| unsafe { w.bits(sequence0.words.len() as u32) });
        r.seq1
            .refresh
            .write(|w| unsafe { w.bits(alt_sequence.config.refresh) });
        r.seq1
            .enddelay
            .write(|w| unsafe { w.bits(alt_sequence.config.end_delay) });
        r.seq1
            .ptr
            .write(|w| unsafe { w.bits(alt_sequence.words.as_ptr() as u32) });
        r.seq1
            .cnt
            .write(|w| unsafe { w.bits(alt_sequence.words.len() as u32) });
        r.enable.write(|w| w.enable().enabled());
        // defensive before seqstart
        compiler_fence(Ordering::SeqCst);
        let seqstart_index = if start_seq == StartSequence::One {
            1
        } else {
            0
        };
        match times {
            // just the one time, no loop count
            SequenceMode::Loop(n) => {
                r.loop_.write(|w| unsafe { w.cnt().bits(n) });
            }
            // to play infinitely, repeat the sequence one time, then have loops done self trigger seq0 again
            SequenceMode::Infinite => {
                r.loop_.write(|w| unsafe { w.cnt().bits(0x1) });
                r.shorts.write(|w| w.loopsdone_seqstart0().enabled());
            }
        }
        // tasks_seqstart() doesn't exist in all svds so write its bit instead
        r.tasks_seqstart[seqstart_index].write(|w| unsafe { w.bits(0x01) });
        Ok(())
    }
    /// Stop playback. Disables the peripheral. Does NOT clear the last duty
    /// cycle from the pin. Returns any sequences previously provided to
    /// `start` so that they may be further mutated.
    #[inline(always)]
    pub fn stop(&self) {
        let r = T::regs();
        r.shorts.reset();
        compiler_fence(Ordering::SeqCst);
        // tasks_stop() doesn't exist in all svds so write its bit instead
        r.tasks_stop.write(|w| unsafe { w.bits(0x01) });
        r.enable.write(|w| w.enable().disabled());
    }
 }
 impl<'d, 's, T: Instance> Drop for Sequencer<'d, 's, T> {
    fn drop(&mut self) {
        let _ = self.stop();
    }
 }
 /// How many times to run a single sequence
 #[derive(Debug, Eq, PartialEq, Clone, Copy)]
 pub enum SingleSequenceMode {
    /// Run a single sequence n Times total.
    Times(u16),
    /// Repeat until `stop` is called.
    Infinite,
 }
 /// Which sequence to start a loop with
 #[derive(Debug, Eq, PartialEq, Clone, Copy)]
 pub enum StartSequence {
    /// Start with Sequence 0
    Zero,
    /// Start with Sequence 1
    One,
 }
 /// How many loops to run two sequences
 #[derive(Debug, Eq, PartialEq, Clone, Copy)]
 pub enum SequenceMode {
-    /// Run sequence n Times total
+    /// Run two sequences n loops i.e. (n * (seq0 + seq1.unwrap_or(seq0)))
-    Times(u16),
+    Loop(u16),
    /// Repeat until `stop` is called.
    Infinite,
 }
--- a/examples/nrf/src/bin/pwm_double_sequence.rs
+++ b/examples/nrf/src/bin/pwm_double_sequence.rs
@ -0,0 +1,46 @@
 #![no_std]
 #![no_main]
 #![feature(type_alias_impl_trait)]
 #[path = "../example_common.rs"]
 mod example_common;
 use defmt::*;
 use embassy::executor::Spawner;
 use embassy::time::{Duration, Timer};
 use embassy_nrf::gpio::NoPin;
 use embassy_nrf::pwm::{
    Config, Prescaler, Sequence, SequenceConfig, SequenceMode, SequencePwm, Sequencer,
    StartSequence,
 };
 use embassy_nrf::Peripherals;
 #[embassy::main]
 async fn main(_spawner: Spawner, p: Peripherals) {
    let seq_words_0: [u16; 5] = [1000, 250, 100, 50, 0];
    let seq_words_1: [u16; 4] = [50, 100, 250, 1000];
    let mut config = Config::default();
    config.prescaler = Prescaler::Div128;
    // 1 period is 1000 * (128/16mhz = 0.000008s = 0.008ms) = 8us
    // but say we want to hold the value for 5000ms
    // so we want to repeat our value as many times as necessary until 5000ms passes
    // want 5000/8 = 625 periods total to occur, so 624 (we get the one period for free remember)
    let mut seq_config = SequenceConfig::default();
    seq_config.refresh = 624;
    // thus our sequence takes 5 * 5000ms or 25 seconds
    let mut pwm = unwrap!(SequencePwm::new(
        p.PWM0, p.P0_13, NoPin, NoPin, NoPin, config,
    ));
    let sequence_0 = Sequence::new(&seq_words_0, seq_config.clone());
    let sequence_1 = Sequence::new(&seq_words_1, seq_config);
    let sequencer = Sequencer::new(&mut pwm, sequence_0, Some(sequence_1));
    unwrap!(sequencer.start(StartSequence::Zero, SequenceMode::Loop(1)));
    // we can abort a sequence if we need to before its complete with pwm.stop()
    // or stop is also implicitly called when the pwm peripheral is dropped
    // when it goes out of scope
    Timer::after(Duration::from_millis(40000)).await;
    info!("pwm stopped early!");
 }
--- a/examples/nrf/src/bin/pwm_sequence.rs
+++ b/examples/nrf/src/bin/pwm_sequence.rs
@ -8,34 +8,31 @@ use defmt::*;
 use embassy::executor::Spawner;
 use embassy::time::{Duration, Timer};
 use embassy_nrf::gpio::NoPin;
-use embassy_nrf::pwm::{Prescaler, SequenceConfig, SequenceMode, SequencePwm};
+use embassy_nrf::pwm::{
    Config, Prescaler, SequenceConfig, SequencePwm, SingleSequenceMode, SingleSequencer,
 };
 use embassy_nrf::Peripherals;
 #[embassy::main]
 async fn main(_spawner: Spawner, p: Peripherals) {
-    let seq_values_1: [u16; 5] = [1000, 250, 100, 50, 0];
+    let seq_words: [u16; 5] = [1000, 250, 100, 50, 0];
    let seq_values_2: [u16; 5] = [0, 50, 100, 250, 1000];
-    let mut config = SequenceConfig::default();
+    let mut config = Config::default();
    config.prescaler = Prescaler::Div128;
    // 1 period is 1000 * (128/16mhz = 0.000008s = 0.008ms) = 8us
    // but say we want to hold the value for 5000ms
    // so we want to repeat our value as many times as necessary until 5000ms passes
    // want 5000/8 = 625 periods total to occur, so 624 (we get the one period for free remember)
-    config.refresh = 624;
+    let mut seq_config = SequenceConfig::default();
    seq_config.refresh = 624;
    // thus our sequence takes 5 * 5000ms or 25 seconds
    let mut pwm = unwrap!(SequencePwm::new(
        p.PWM0, p.P0_13, NoPin, NoPin, NoPin, config,
    ));
    let _ = pwm.start(&seq_values_1, SequenceMode::Infinite);
-    info!("pwm started!");
+    let sequencer = SingleSequencer::new(&mut pwm, &seq_words, seq_config);
-
+    unwrap!(sequencer.start(SingleSequenceMode::Times(1)));
    Timer::after(Duration::from_millis(20000)).await;
    info!("pwm starting with another sequence!");
    let _ = pwm.start(&seq_values_2, SequenceMode::Infinite);
    // we can abort a sequence if we need to before its complete with pwm.stop()
    // or stop is also implicitly called when the pwm peripheral is dropped
--- a/examples/nrf/src/bin/pwm_sequence_ppi.rs
+++ b/examples/nrf/src/bin/pwm_sequence_ppi.rs
@ -11,26 +11,28 @@ use embassy::executor::Spawner;
 use embassy_nrf::gpio::{Input, NoPin, Pull};
 use embassy_nrf::gpiote::{InputChannel, InputChannelPolarity};
 use embassy_nrf::ppi::Ppi;
-use embassy_nrf::pwm::{Prescaler, SequenceConfig, SequenceMode, SequencePwm};
+use embassy_nrf::pwm::{
    Config, Prescaler, SequenceConfig, SequencePwm, SingleSequenceMode, SingleSequencer,
 };
 use embassy_nrf::Peripherals;
 #[embassy::main]
 async fn main(_spawner: Spawner, p: Peripherals) {
-    let seq_values: [u16; 5] = [1000, 250, 100, 50, 0];
+    let seq_words: [u16; 5] = [1000, 250, 100, 50, 0];
-    let mut config = SequenceConfig::default();
+    let mut config = Config::default();
    config.prescaler = Prescaler::Div128;
    // 1 period is 1000 * (128/16mhz = 0.000008s = 0.008ms) = 8us
    // but say we want to hold the value for 250ms 250ms/8 = 31.25 periods
    // so round to 31 - 1 (we get the one period for free remember)
    // thus our sequence takes 5 * 250ms or 1.25 seconds
-    config.refresh = 30;
+    let mut seq_config = SequenceConfig::default();
    seq_config.refresh = 30;
    let mut pwm = unwrap!(SequencePwm::new(
        p.PWM0, p.P0_13, NoPin, NoPin, NoPin, config,
    ));
    let _ = pwm.start(&seq_values, SequenceMode::Times(1));
    // pwm.stop() deconfigures pins, and then the task_start_seq0 task cant work
    // so its going to have to start running in order load the configuration
@ -51,6 +53,9 @@ async fn main(_spawner: Spawner, p: Peripherals) {
    let start = unsafe { pwm.task_start_seq0() };
    let stop = unsafe { pwm.task_stop() };
    let sequencer = SingleSequencer::new(&mut pwm, &seq_words, seq_config);
    unwrap!(sequencer.start(SingleSequenceMode::Infinite));
    let mut ppi = Ppi::new_one_to_one(p.PPI_CH1, button1.event_in(), start);
    ppi.enable();
--- a/examples/nrf/src/bin/pwm_sequence_ws2812b.rs
+++ b/examples/nrf/src/bin/pwm_sequence_ws2812b.rs
@ -0,0 +1,80 @@
 #![no_std]
 #![no_main]
 #![feature(type_alias_impl_trait)]
 #[path = "../example_common.rs"]
 mod example_common;
 use defmt::*;
 use embassy::executor::Spawner;
 use embassy::time::{Duration, Timer};
 use embassy_nrf::gpio::NoPin;
 use embassy_nrf::pwm::{
    Config, Prescaler, SequenceConfig, SequenceLoad, SequencePwm, SingleSequenceMode,
    SingleSequencer,
 };
 use embassy_nrf::Peripherals;
 // WS2812B LED light demonstration. Drives just one light.
 // The following reference on WS2812B may be of use:
 // https://cdn-shop.adafruit.com/datasheets/WS2812B.pdf.
 // This demo lights up a single LED in blue. It then proceeds
 // to pulsate the LED rapidly.
 // In the following declarations, setting the high bit tells the PWM
 // to reverse polarity, which is what the WS2812B expects.
 const T1H: u16 = 0x8000 | 13; // Duty = 13/20 ticks (0.8us/1.25us) for a 1
 const T0H: u16 = 0x8000 | 7; // Duty 7/20 ticks (0.4us/1.25us) for a 0
 const RES: u16 = 0x8000;
 // Provides data to a WS2812b (Neopixel) LED and makes it go blue. The data
 // line is assumed to be P1_05.
 #[embassy::main]
 async fn main(_spawner: Spawner, p: Peripherals) {
    let mut config = Config::default();
    config.sequence_load = SequenceLoad::Common;
    config.prescaler = Prescaler::Div1;
    config.max_duty = 20; // 1.25us (1s / 16Mhz * 20)
    let mut pwm = unwrap!(SequencePwm::new(
        p.PWM0, p.P1_05, NoPin, NoPin, NoPin, config,
    ));
    // Declare the bits of 24 bits in a buffer we'll be
    // mutating later.
    let mut seq_words = [
        T0H, T0H, T0H, T0H, T0H, T0H, T0H, T0H, // G
        T0H, T0H, T0H, T0H, T0H, T0H, T0H, T0H, // R
        T1H, T1H, T1H, T1H, T1H, T1H, T1H, T1H, // B
        RES,
    ];
    let mut seq_config = SequenceConfig::default();
    seq_config.end_delay = 799; // 50us (20 ticks * 40) - 1 tick because we've already got one RES;
    let mut color_bit = 16;
    let mut bit_value = T0H;
    loop {
        let sequences = SingleSequencer::new(&mut pwm, &seq_words, seq_config.clone());
        unwrap!(sequences.start(SingleSequenceMode::Times(1)));
        Timer::after(Duration::from_millis(50)).await;
        if bit_value == T0H {
            if color_bit == 20 {
                bit_value = T1H;
            } else {
                color_bit += 1;
            }
        } else {
            if color_bit == 16 {
                bit_value = T0H;
            } else {
                color_bit -= 1;
            }
        }
        drop(sequences);
        seq_words[color_bit] = bit_value;
    }
 }