2022-12-08 20:22:50 +01:00
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#![no_std]
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#![no_main]
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#![feature(type_alias_impl_trait)]
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use core::f32::consts::PI;
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use defmt::{error, info};
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use embassy_executor::Spawner;
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use embassy_nrf::i2s::{self, Channels, Config, MasterClock, MultiBuffering, Sample as _, SampleWidth, I2S};
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2023-03-05 20:40:13 +01:00
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use embassy_nrf::{bind_interrupts, peripherals};
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2022-12-08 20:22:50 +01:00
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use {defmt_rtt as _, panic_probe as _};
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type Sample = i16;
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const NUM_BUFFERS: usize = 2;
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const NUM_SAMPLES: usize = 4;
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2023-03-05 20:40:13 +01:00
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bind_interrupts!(struct Irqs {
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I2S => i2s::InterruptHandler<peripherals::I2S>;
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});
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2022-12-08 20:22:50 +01:00
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#[embassy_executor::main]
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async fn main(_spawner: Spawner) {
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let p = embassy_nrf::init(Default::default());
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let master_clock: MasterClock = i2s::ExactSampleRate::_50000.into();
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let sample_rate = master_clock.sample_rate();
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info!("Sample rate: {}", sample_rate);
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2023-02-01 00:48:33 +01:00
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let mut config = Config::default();
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config.sample_width = SampleWidth::_16bit;
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config.channels = Channels::MonoLeft;
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2022-12-08 20:22:50 +01:00
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let buffers_out = MultiBuffering::<Sample, NUM_BUFFERS, NUM_SAMPLES>::new();
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let buffers_in = MultiBuffering::<Sample, NUM_BUFFERS, NUM_SAMPLES>::new();
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2023-03-05 20:40:13 +01:00
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let mut full_duplex_stream = I2S::new_master(p.I2S, Irqs, p.P0_25, p.P0_26, p.P0_27, master_clock, config)
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.full_duplex(p.P0_29, p.P0_28, buffers_out, buffers_in);
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2022-12-08 20:22:50 +01:00
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let mut modulator = SineOsc::new();
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modulator.set_frequency(8.0, 1.0 / sample_rate as f32);
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modulator.set_amplitude(1.0);
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full_duplex_stream.start().await.expect("I2S Start");
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loop {
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let (buff_out, buff_in) = full_duplex_stream.buffers();
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for i in 0..NUM_SAMPLES {
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let modulation = (Sample::SCALE as f32 * bipolar_to_unipolar(modulator.generate())) as Sample;
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buff_out[i] = buff_in[i] * modulation;
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}
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if let Err(err) = full_duplex_stream.send_and_receive().await {
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error!("{}", err);
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}
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}
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}
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struct SineOsc {
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amplitude: f32,
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modulo: f32,
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phase_inc: f32,
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}
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impl SineOsc {
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const B: f32 = 4.0 / PI;
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const C: f32 = -4.0 / (PI * PI);
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const P: f32 = 0.225;
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pub fn new() -> Self {
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Self {
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amplitude: 1.0,
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modulo: 0.0,
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phase_inc: 0.0,
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}
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}
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pub fn set_frequency(&mut self, freq: f32, inv_sample_rate: f32) {
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self.phase_inc = freq * inv_sample_rate;
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}
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pub fn set_amplitude(&mut self, amplitude: f32) {
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self.amplitude = amplitude;
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}
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pub fn generate(&mut self) -> f32 {
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let signal = self.parabolic_sin(self.modulo);
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self.modulo += self.phase_inc;
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if self.modulo < 0.0 {
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self.modulo += 1.0;
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} else if self.modulo > 1.0 {
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self.modulo -= 1.0;
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}
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signal * self.amplitude
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}
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fn parabolic_sin(&mut self, modulo: f32) -> f32 {
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let angle = PI - modulo * 2.0 * PI;
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let y = Self::B * angle + Self::C * angle * abs(angle);
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Self::P * (y * abs(y) - y) + y
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}
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}
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#[inline]
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fn abs(value: f32) -> f32 {
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if value < 0.0 {
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-value
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} else {
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value
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}
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}
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#[inline]
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fn bipolar_to_unipolar(value: f32) -> f32 {
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(value + 1.0) / 2.0
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}
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