2020-06-09 09:52:27 +00:00
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//! Hardware Abstraction Layer (HAL) for the nRF52840 Development Kit
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2020-06-09 16:17:30 +00:00
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#![deny(missing_docs)]
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#![deny(warnings)]
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2020-06-09 09:52:27 +00:00
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#![no_std]
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use core::{
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sync::atomic::{AtomicU32, Ordering},
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time::Duration,
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};
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use cortex_m::asm;
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use embedded_hal::digital::v2::{OutputPin as _, StatefulOutputPin};
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pub use hal::ieee802154;
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pub use hal::target::{interrupt, Interrupt, NVIC_PRIO_BITS, RTC0};
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use hal::{
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clocks::{Clocks, ExternalOscillator, LfOscConfiguration, LfOscStarted},
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gpio::{p0, Level, Output, Pin, PushPull},
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ieee802154::Radio,
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rtc::{Rtc, RtcInterrupt},
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timer::OneShot,
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};
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use log::{LevelFilter, Log};
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use rtt_target::{rprintln, rtt_init_print};
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2020-06-09 16:17:30 +00:00
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use crate::{
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peripheral::{POWER, USBD},
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usbd::Ep0In,
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};
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2020-06-09 09:52:27 +00:00
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mod errata;
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pub mod peripheral;
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pub mod usbd;
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/// Components on the board
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pub struct Board {
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2020-06-09 16:17:30 +00:00
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/// LEDs
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2020-06-09 09:52:27 +00:00
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pub leds: Leds,
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2020-06-09 16:17:30 +00:00
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/// Radio interface
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2020-06-09 09:52:27 +00:00
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// TODO put behind feature flag (off in advanced workshop)
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pub radio: Radio<'static>,
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2020-06-09 16:17:30 +00:00
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/// Timer
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2020-06-09 09:52:27 +00:00
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pub timer: Timer,
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2020-06-09 16:17:30 +00:00
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/// USBD (Universal Serial Bus Device) peripheral
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2020-06-09 09:52:27 +00:00
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// TODO put behind feature flag (off in beginner workshop)
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pub usbd: USBD,
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2020-06-09 16:17:30 +00:00
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/// POWER (Power Supply) peripheral
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2020-06-09 09:52:27 +00:00
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pub power: POWER,
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2020-06-09 16:17:30 +00:00
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/// USB control endpoint 0
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pub ep0in: Ep0In,
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2020-06-09 09:52:27 +00:00
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}
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/// All LEDs on the board
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pub struct Leds {
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/// LED1: pin P0.13, green LED
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pub _1: Led,
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/// LED2: pin P0.14, green LED
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pub _2: Led,
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/// LED3: pin P0.15, green LED
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pub _3: Led,
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/// LED4: pin P0.16, green LED
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pub _4: Led,
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}
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/// A single LED
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pub struct Led {
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inner: Pin<Output<PushPull>>,
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}
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impl Led {
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/// Turns on the LED
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pub fn on(&mut self) {
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log::trace!(
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"setting P{}.{} low (LED on)",
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if self.inner.port { '1' } else { '0' },
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self.inner.pin
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);
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// NOTE this operations returns a `Result` but never returns the `Err` variant
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let _ = self.inner.set_low();
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}
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/// Turns off the LED
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pub fn off(&mut self) {
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log::trace!(
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"setting P{}.{} high (LED off)",
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if self.inner.port { '1' } else { '0' },
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self.inner.pin
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);
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// NOTE this operations returns a `Result` but never returns the `Err` variant
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let _ = self.inner.set_high();
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}
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/// Returns `true` if the LED is in the OFF state
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pub fn is_off(&self) -> bool {
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self.inner.is_set_high() == Ok(true)
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}
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/// Returns `true` if the LED is in the ON state
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pub fn is_on(&self) -> bool {
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!self.is_off()
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}
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/// Toggles the state (on/off) of the LED
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pub fn toggle(&mut self) {
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if self.is_off() {
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self.on();
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} else {
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self.off()
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}
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}
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}
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/// A timer for blocking delay
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pub struct Timer {
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inner: hal::Timer<hal::target::TIMER0, OneShot>,
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}
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impl Timer {
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/// Blocks program execution for at least the specified `duration`
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pub fn wait(&mut self, duration: Duration) {
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log::trace!("blocking for {:?} ...", duration);
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// 1 cycle = 1 microsecond
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const NANOS_IN_ONE_MICRO: u32 = 1_000;
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let subsec_micros = duration.subsec_nanos() / NANOS_IN_ONE_MICRO;
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if subsec_micros != 0 {
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self.inner.delay(subsec_micros);
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}
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const MICROS_IN_ONE_SEC: u32 = 1_000_000;
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// maximum number of seconds that fit in a single `delay` call without overflowing the `u32`
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// argument
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const MAX_SECS: u32 = u32::MAX / MICROS_IN_ONE_SEC;
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let mut secs = duration.as_secs();
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while secs != 0 {
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let cycles = if secs > MAX_SECS as u64 {
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secs -= MAX_SECS as u64;
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MAX_SECS * MICROS_IN_ONE_SEC
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} else {
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let cycles = secs as u32 * MICROS_IN_ONE_SEC;
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secs = 0;
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cycles
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};
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self.inner.delay(cycles)
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}
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log::trace!("... DONE");
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}
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}
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// add Instant API
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/// Initializes the board
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///
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/// This return an `Err`or if called more than once
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pub fn init() -> Result<Board, ()> {
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if let (Some(mut core), Some(periph)) = (
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cortex_m::Peripherals::take(),
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hal::target::Peripherals::take(),
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) {
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2020-06-09 16:17:30 +00:00
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// NOTE(static mut) this branch runs at most once
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static mut EP0IN_BUF: [u8; 64] = [0; 64];
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2020-06-09 09:52:27 +00:00
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static mut CLOCKS: Option<Clocks<ExternalOscillator, ExternalOscillator, LfOscStarted>> =
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None;
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// NOTE this must be executed as early as possible or the tool will timeout
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// NOTE the unsafety of this macro is incorrect; it must be run at most once
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rtt_init_print!(NoBlockSkip, 2048);
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log::set_logger(&Logger).unwrap();
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// if not configured in the application we default to the `Info` level
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if log::max_level() == LevelFilter::Off {
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log::set_max_level(LevelFilter::Info)
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}
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log::debug!("Initializing the board");
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let clocks = Clocks::new(periph.CLOCK);
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let clocks = clocks.enable_ext_hfosc();
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let clocks = clocks.set_lfclk_src_external(LfOscConfiguration::NoExternalNoBypass);
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let clocks = clocks.start_lfclk();
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// extend lifetime to `'static`
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let clocks = unsafe { CLOCKS.get_or_insert(clocks.enable_ext_hfosc()) };
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log::debug!("Clocks configured");
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let mut rtc = Rtc::new(periph.RTC0);
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rtc.enable_interrupt(RtcInterrupt::Overflow, Some(&mut core.NVIC));
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rtc.enable_counter();
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log::debug!("RTC started");
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let pins = p0::Parts::new(periph.P0);
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// NOTE LEDs turn on when the pin output level is low
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let _1 = pins.p0_13.degrade().into_push_pull_output(Level::High);
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let _2 = pins.p0_14.degrade().into_push_pull_output(Level::High);
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let _3 = pins.p0_15.degrade().into_push_pull_output(Level::High);
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let _4 = pins.p0_16.degrade().into_push_pull_output(Level::High);
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log::debug!("I/O pins have been configured for digital output");
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let timer = hal::Timer::new(periph.TIMER0);
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let mut radio = Radio::init(periph.RADIO, clocks);
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// set TX power to its maximum value
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radio.set_txpower(ieee802154::TxPower::Pos8dBm);
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log::debug!("Radio initialized and configured with TX power set to the maximum value");
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Ok(Board {
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leds: Leds {
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_1: Led { inner: _1 },
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_2: Led { inner: _2 },
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_3: Led { inner: _3 },
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_4: Led { inner: _4 },
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},
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radio,
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timer: Timer { inner: timer },
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usbd: periph.USBD,
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power: periph.POWER,
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2020-06-09 16:17:30 +00:00
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ep0in: unsafe { Ep0In::new(&mut EP0IN_BUF) },
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2020-06-09 09:52:27 +00:00
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})
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} else {
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Err(())
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}
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}
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struct Logger;
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impl Log for Logger {
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fn enabled(&self, metadata: &log::Metadata) -> bool {
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metadata.level() <= log::STATIC_MAX_LEVEL
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}
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fn log(&self, record: &log::Record) {
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if !self.enabled(record.metadata()) {
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return;
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}
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rprintln!(
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"{}:{} -- {}",
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record.level(),
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record.target(),
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record.args()
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);
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}
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fn flush(&self) {}
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}
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// Counter of OVERFLOW events -- an OVERFLOW occurs every (1<<24) ticks
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static OVERFLOWS: AtomicU32 = AtomicU32::new(0);
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// NOTE this will at the highest priority, higher priority than RTIC tasks
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#[interrupt]
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fn RTC0() {
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let curr = OVERFLOWS.load(Ordering::Relaxed);
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OVERFLOWS.store(curr + 1, Ordering::Relaxed);
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// clear the EVENT register
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unsafe { core::mem::transmute::<_, RTC0>(()).events_ovrflw.reset() }
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}
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/// Exits the application and prints a backtrace when the program is executed through the `dk-run`
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/// Cargo runner
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pub fn exit() -> ! {
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loop {
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asm::bkpt()
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}
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}
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/// Returns the time elapsed since the call to the `dk::init` function
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///
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/// The clock that is read to compute this value has a resolution of 30 microseconds.
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///
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/// Calling this function before calling `dk::init` will return a value of `0` nanoseconds.
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pub fn uptime() -> Duration {
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// here we are going to perform a 64-bit read of the number of ticks elapsed
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//
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// a 64-bit load operation cannot performed in a single instruction so the operation can be
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// preempted by the RTC0 interrupt handler (which increases the OVERFLOWS counter)
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//
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// the loop below will load both the lower and upper parts of the 64-bit value while preventing
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// the issue of mixing a low value with an "old" high value -- note that, due to interrupts, an
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// arbitrary amount of time may elapse between the `hi1` load and the `low` load
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let overflows = &OVERFLOWS as *const AtomicU32 as *const u32;
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let ticks = loop {
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unsafe {
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// NOTE volatile is used to order these load operations among themselves
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let hi1 = overflows.read_volatile();
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let low = core::mem::transmute::<_, RTC0>(())
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.counter
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.read()
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.counter()
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.bits();
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let hi2 = overflows.read_volatile();
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if hi1 == hi2 {
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break u64::from(low) | (u64::from(hi1) << 24);
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}
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}
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};
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// 2**15 ticks = 1 second
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let freq = 1 << 15;
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let secs = ticks / freq;
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// subsec ticks
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let ticks = (ticks % freq) as u32;
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// one tick is equal to `1e9 / 32768` nanos
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// the fraction can be reduced to `1953125 / 64`
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// which can be further decomposed as `78125 * (5 / 4) * (5 / 4) * (1 / 4)`.
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// Doing the operation this way we can stick to 32-bit arithmetic without overflowing the value
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// at any stage
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let nanos =
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(((ticks % 32768).wrapping_mul(78125) >> 2).wrapping_mul(5) >> 2).wrapping_mul(5) >> 2;
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Duration::new(secs, nanos as u32)
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}
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