304 lines
9.2 KiB
Rust
304 lines
9.2 KiB
Rust
#![deny(warnings)]
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#![no_std]
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#![no_main]
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use generic_array::typenum::U4;
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use serde::Deserialize;
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use dsp::{Accu, Complex, ComplexExt, Lockin, RPLL};
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use stabilizer::net;
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use stabilizer::hardware::{
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design_parameters, setup, Adc0Input, Adc1Input, AfeGain, Dac0Output,
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Dac1Output, InputStamper, AFE0, AFE1,
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};
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use miniconf::Miniconf;
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use stabilizer::net::{Action, MqttInterface};
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// A constant sinusoid to send on the DAC output.
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// Full-scale gives a +/- 10.24V amplitude waveform. Scale it down to give +/- 1V.
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const ONE: i16 = ((1.0 / 10.24) * u16::MAX as f32) as _;
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const SQRT2: i16 = (ONE as f32 * 0.707) as _;
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const DAC_SEQUENCE: [i16; design_parameters::SAMPLE_BUFFER_SIZE] =
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[ONE, SQRT2, 0, -SQRT2, -ONE, -SQRT2, 0, SQRT2];
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#[derive(Copy, Clone, Debug, Deserialize, Miniconf)]
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enum Conf {
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Power,
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Phase,
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PllFrequency,
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FrequencyDiscriminator,
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QuadratureReal,
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QuadratureImaginary,
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Reference,
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}
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#[derive(Copy, Clone, Debug, Miniconf, Deserialize, PartialEq)]
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enum LockinMode {
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Internal,
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External,
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}
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#[derive(Copy, Clone, Debug, Deserialize, Miniconf)]
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pub struct Settings {
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afe: [AfeGain; 2],
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lockin_mode: LockinMode,
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pll_tc: [u8; 2],
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lockin_tc: u8,
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lockin_harmonic: i32,
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lockin_phase: i32,
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output_conf: [Conf; 2],
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telemetry_period_secs: u16,
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}
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impl Default for Settings {
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fn default() -> Self {
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Self {
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afe: [AfeGain::G1; 2],
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lockin_mode: LockinMode::External,
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pll_tc: [21, 21], // frequency and phase settling time (log2 counter cycles)
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lockin_tc: 6, // lockin lowpass time constant
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lockin_harmonic: -1, // Harmonic index of the LO: -1 to _de_modulate the fundamental (complex conjugate)
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lockin_phase: 0, // Demodulation LO phase offset
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output_conf: [Conf::QuadratureReal, Conf::QuadratureImaginary],
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telemetry_period_secs: 10,
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}
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}
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}
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#[rtic::app(device = stm32h7xx_hal::stm32, peripherals = true, monotonic = rtic::cyccnt::CYCCNT)]
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const APP: () = {
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struct Resources {
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afes: (AFE0, AFE1),
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adcs: (Adc0Input, Adc1Input),
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dacs: (Dac0Output, Dac1Output),
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mqtt: MqttInterface<Settings>,
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settings: Settings,
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timestamper: InputStamper,
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pll: RPLL,
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lockin: Lockin<U4>,
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}
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#[init(spawn=[settings_update])]
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fn init(c: init::Context) -> init::LateResources {
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// Configure the microcontroller
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let (mut stabilizer, _pounder) = setup(c.core, c.device);
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let mqtt = MqttInterface::new(
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stabilizer.net.stack,
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"",
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&net::get_device_prefix(
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env!("CARGO_BIN_NAME"),
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stabilizer.net.mac_address,
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),
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stabilizer.net.phy,
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stabilizer.cycle_counter,
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);
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let settings = Settings::default();
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let pll = RPLL::new(
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design_parameters::ADC_SAMPLE_TICKS_LOG2
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+ design_parameters::SAMPLE_BUFFER_SIZE_LOG2,
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);
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// Spawn a settings update for default settings.
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c.spawn.settings_update().unwrap();
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// Enable ADC/DAC events
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stabilizer.adcs.0.start();
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stabilizer.adcs.1.start();
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stabilizer.dacs.0.start();
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stabilizer.dacs.1.start();
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// Start recording digital input timestamps.
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stabilizer.timestamp_timer.start();
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// Start sampling ADCs.
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stabilizer.adc_dac_timer.start();
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// Enable the timestamper.
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stabilizer.timestamper.start();
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init::LateResources {
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afes: stabilizer.afes,
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adcs: stabilizer.adcs,
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dacs: stabilizer.dacs,
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mqtt,
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timestamper: stabilizer.timestamper,
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settings,
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pll,
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lockin: Lockin::default(),
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}
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}
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/// Main DSP processing routine.
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///
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/// See `dual-iir` for general notes on processing time and timing.
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///
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/// This is an implementation of a externally (DI0) referenced PLL lockin on the ADC0 signal.
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/// It outputs either I/Q or power/phase on DAC0/DAC1. Data is normalized to full scale.
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/// PLL bandwidth, filter bandwidth, slope, and x/y or power/phase post-filters are available.
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#[task(binds=DMA1_STR4, resources=[adcs, dacs, lockin, timestamper, pll, settings], priority=2)]
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fn process(c: process::Context) {
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let adc_samples = [
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c.resources.adcs.0.acquire_buffer(),
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c.resources.adcs.1.acquire_buffer(),
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];
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let dac_samples = [
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c.resources.dacs.0.acquire_buffer(),
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c.resources.dacs.1.acquire_buffer(),
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];
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let lockin = c.resources.lockin;
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let settings = c.resources.settings;
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let mut pll_frequency = 0;
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let (sample_phase, sample_frequency) = match settings.lockin_mode {
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LockinMode::External => {
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let timestamp =
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c.resources.timestamper.latest_timestamp().unwrap_or(None); // Ignore data from timer capture overflows.
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let (pll_phase, frequency) = c.resources.pll.update(
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timestamp.map(|t| t as i32),
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settings.pll_tc[0],
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settings.pll_tc[1],
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);
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pll_frequency = frequency;
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let sample_frequency = ((pll_frequency
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>> design_parameters::SAMPLE_BUFFER_SIZE_LOG2)
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as i32)
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.wrapping_mul(settings.lockin_harmonic);
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let sample_phase = settings.lockin_phase.wrapping_add(
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pll_phase.wrapping_mul(settings.lockin_harmonic),
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);
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(sample_phase, sample_frequency)
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}
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LockinMode::Internal => {
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// Reference phase and frequency are known.
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let pll_phase = 0i32;
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let pll_frequency =
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1i32 << (32 - design_parameters::SAMPLE_BUFFER_SIZE_LOG2);
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// Demodulation LO phase offset
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let phase_offset: i32 = 1 << 30;
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let sample_frequency = (pll_frequency as i32)
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.wrapping_mul(settings.lockin_harmonic);
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let sample_phase = phase_offset.wrapping_add(
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pll_phase.wrapping_mul(settings.lockin_harmonic),
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);
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(sample_phase, sample_frequency)
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}
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};
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let output: Complex<i32> = adc_samples[0]
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.iter()
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// Zip in the LO phase.
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.zip(Accu::new(sample_phase, sample_frequency))
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// Convert to signed, MSB align the ADC sample, update the Lockin (demodulate, filter)
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.map(|(&sample, phase)| {
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let s = (sample as i16 as i32) << 16;
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lockin.update(s, phase, settings.lockin_tc)
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})
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// Decimate
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.last()
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.unwrap()
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* 2; // Full scale assuming the 2f component is gone.
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// Convert to DAC data.
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for i in 0..dac_samples[0].len() {
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for channel in 0..2 {
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let value = match settings.output_conf[0] {
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Conf::Power => output.abs_sqr() as i32 >> 16,
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Conf::Phase => output.arg() >> 16,
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Conf::FrequencyDiscriminator => {
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(output.log2() << 24) as i32 >> 16
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}
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Conf::PllFrequency => pll_frequency as i32 >> 16,
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Conf::QuadratureReal => output.re >> 16,
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Conf::QuadratureImaginary => output.im >> 16,
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Conf::Reference => DAC_SEQUENCE[i] as i32,
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};
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dac_samples[channel][i] = value as u16 ^ 0x8000;
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}
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}
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}
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#[idle(resources=[mqtt], spawn=[settings_update])]
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fn idle(mut c: idle::Context) -> ! {
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loop {
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match c.resources.mqtt.lock(|mqtt| mqtt.update()) {
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Some(Action::Sleep) => cortex_m::asm::wfi(),
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Some(Action::UpdateSettings) => {
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c.spawn.settings_update().unwrap()
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}
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_ => {}
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}
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}
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}
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#[task(priority = 1, resources=[mqtt, settings, afes])]
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fn settings_update(mut c: settings_update::Context) {
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let settings = c.resources.mqtt.settings();
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c.resources.afes.0.set_gain(settings.afe[0]);
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c.resources.afes.1.set_gain(settings.afe[1]);
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c.resources.settings.lock(|current| *current = *settings);
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}
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#[task(binds = ETH, priority = 1)]
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fn eth(_: eth::Context) {
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unsafe { stm32h7xx_hal::ethernet::interrupt_handler() }
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}
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#[task(binds = SPI2, priority = 3)]
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fn spi2(_: spi2::Context) {
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panic!("ADC0 input overrun");
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}
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#[task(binds = SPI3, priority = 3)]
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fn spi3(_: spi3::Context) {
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panic!("ADC1 input overrun");
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}
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#[task(binds = SPI4, priority = 3)]
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fn spi4(_: spi4::Context) {
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panic!("DAC0 output error");
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}
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#[task(binds = SPI5, priority = 3)]
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fn spi5(_: spi5::Context) {
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panic!("DAC1 output error");
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}
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extern "C" {
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// hw interrupt handlers for RTIC to use for scheduling tasks
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// one per priority
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fn DCMI();
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fn JPEG();
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fn SDMMC();
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}
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};
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