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Merge remote-tracking branch 'origin/main' into nrf-pdm

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This commit is contained in:
Quentin Smith
2023-07-17 21:31:43 -04:00
parent d896f80405 6b5df4523a
commit 6f02403184
863 changed files with 74741 additions and 28517 deletions
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9
examples/nrf52840/.cargo/config.toml Normal file
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[target.'cfg(all(target_arch = "arm", target_os = "none"))']
# replace nRF82840_xxAA with your chip as listed in `probe-rs chip list`
runner = "probe-rs run --chip nRF52840_xxAA"
[build]
target = "thumbv7em-none-eabi"
[env]
DEFMT_LOG = "trace"

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examples/nrf52840/Cargo.toml Normal file
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[package]
edition = "2021"
name = "embassy-nrf52840-examples"
version = "0.1.0"
license = "MIT OR Apache-2.0"
[features]
default = ["nightly"]
nightly = [
"embedded-hal-async",
"embassy-executor/nightly",
"embassy-nrf/nightly",
"embassy-net/nightly",
"embassy-net-esp-hosted",
"embassy-nrf/unstable-traits",
"embassy-time/nightly",
"embassy-time/unstable-traits",
"static_cell/nightly",
"embassy-usb",
"embedded-io/async",
"embassy-net",
"embassy-lora",
"lora-phy",
"lorawan-device",
"lorawan",
]
[dependencies]
embassy-futures = { version = "0.1.0", path = "../../embassy-futures" }
embassy-sync = { version = "0.2.0", path = "../../embassy-sync", features = ["defmt"] }
embassy-executor = { version = "0.2.0", path = "../../embassy-executor", features = ["arch-cortex-m", "executor-thread", "executor-interrupt", "defmt", "integrated-timers"] }
embassy-time = { version = "0.1.2", path = "../../embassy-time", features = ["defmt", "defmt-timestamp-uptime"] }
embassy-nrf = { version = "0.1.0", path = "../../embassy-nrf", features = ["defmt", "nrf52840", "time-driver-rtc1", "gpiote", "unstable-pac", "time"] }
embassy-net = { version = "0.1.0", path = "../../embassy-net", features = ["defmt", "tcp", "dhcpv4", "medium-ethernet"], optional = true }
embassy-usb = { version = "0.1.0", path = "../../embassy-usb", features = ["defmt", "msos-descriptor",], optional = true }
embedded-io = "0.4.0"
embassy-lora = { version = "0.1.0", path = "../../embassy-lora", features = ["time", "defmt"], optional = true }
lora-phy = { version = "1", optional = true }
lorawan-device = { version = "0.10.0", default-features = false, features = ["async", "external-lora-phy"], optional = true }
lorawan = { version = "0.7.3", default-features = false, features = ["default-crypto"], optional = true }
embassy-net-esp-hosted = { version = "0.1.0", path = "../../embassy-net-esp-hosted", features = ["defmt"], optional = true }
defmt = "0.3"
defmt-rtt = "0.4"
fixed = "1.10.0"
static_cell = "1.1"
cortex-m = { version = "0.7.6", features = ["inline-asm", "critical-section-single-core"] }
cortex-m-rt = "0.7.0"
panic-probe = { version = "0.3", features = ["print-defmt"] }
futures = { version = "0.3.17", default-features = false, features = ["async-await"] }
rand = { version = "0.8.4", default-features = false }
embedded-storage = "0.3.0"
usbd-hid = "0.6.0"
serde = { version = "1.0.136", default-features = false }
embedded-hal-async = { version = "0.2.0-alpha.2", optional = true }
num-integer = { version = "0.1.45", default-features = false }
microfft = "0.5.0"
[patch.crates-io]
lora-phy = { git = "https://github.com/embassy-rs/lora-phy", rev = "ad289428fd44b02788e2fa2116445cc8f640a265" }

35
examples/nrf52840/build.rs Normal file
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//! This build script copies the `memory.x` file from the crate root into
//! a directory where the linker can always find it at build time.
//! For many projects this is optional, as the linker always searches the
//! project root directory -- wherever `Cargo.toml` is. However, if you
//! are using a workspace or have a more complicated build setup, this
//! build script becomes required. Additionally, by requesting that
//! Cargo re-run the build script whenever `memory.x` is changed,
//! updating `memory.x` ensures a rebuild of the application with the
//! new memory settings.
use std::env;
use std::fs::File;
use std::io::Write;
use std::path::PathBuf;
fn main() {
// Put `memory.x` in our output directory and ensure it's
// on the linker search path.
let out = &PathBuf::from(env::var_os("OUT_DIR").unwrap());
File::create(out.join("memory.x"))
.unwrap()
.write_all(include_bytes!("memory.x"))
.unwrap();
println!("cargo:rustc-link-search={}", out.display());
// By default, Cargo will re-run a build script whenever
// any file in the project changes. By specifying `memory.x`
// here, we ensure the build script is only re-run when
// `memory.x` is changed.
println!("cargo:rerun-if-changed=memory.x");
println!("cargo:rustc-link-arg-bins=--nmagic");
println!("cargo:rustc-link-arg-bins=-Tlink.x");
println!("cargo:rustc-link-arg-bins=-Tdefmt.x");
}

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examples/nrf52840/memory.x Normal file
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MEMORY
{
/* NOTE 1 K = 1 KiBi = 1024 bytes */
/* These values correspond to the NRF52840 with Softdevices S140 7.0.1 */
FLASH : ORIGIN = 0x00000000, LENGTH = 1024K
RAM : ORIGIN = 0x20000000, LENGTH = 256K
}

21
examples/nrf52840/src/bin/blinky.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use embassy_executor::Spawner;
use embassy_nrf::gpio::{Level, Output, OutputDrive};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut led = Output::new(p.P0_13, Level::Low, OutputDrive::Standard);
loop {
led.set_high();
Timer::after(Duration::from_millis(300)).await;
led.set_low();
Timer::after(Duration::from_millis(300)).await;
}
}

54
examples/nrf52840/src/bin/buffered_uart.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::buffered_uarte::{self, BufferedUarte};
use embassy_nrf::{bind_interrupts, peripherals, uarte};
use embedded_io::asynch::Write;
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
UARTE0_UART0 => buffered_uarte::InterruptHandler<peripherals::UARTE0>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut config = uarte::Config::default();
config.parity = uarte::Parity::EXCLUDED;
config.baudrate = uarte::Baudrate::BAUD115200;
let mut tx_buffer = [0u8; 4096];
let mut rx_buffer = [0u8; 4096];
let mut u = BufferedUarte::new(
p.UARTE0,
p.TIMER0,
p.PPI_CH0,
p.PPI_CH1,
p.PPI_GROUP0,
Irqs,
p.P0_08,
p.P0_06,
config,
&mut rx_buffer,
&mut tx_buffer,
);
info!("uarte initialized!");
unwrap!(u.write_all(b"Hello!\r\n").await);
info!("wrote hello in uart!");
loop {
info!("reading...");
let buf = unwrap!(u.fill_buf().await);
info!("read done, got {}", buf);
// Read bytes have to be explicitly consumed, otherwise fill_buf() will return them again
let n = buf.len();
u.consume(n);
}
}

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examples/nrf52840/src/bin/channel.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::unwrap;
use embassy_executor::Spawner;
use embassy_nrf::gpio::{Level, Output, OutputDrive};
use embassy_sync::blocking_mutex::raw::ThreadModeRawMutex;
use embassy_sync::channel::Channel;
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
enum LedState {
On,
Off,
}
static CHANNEL: Channel<ThreadModeRawMutex, LedState, 1> = Channel::new();
#[embassy_executor::task]
async fn my_task() {
loop {
CHANNEL.send(LedState::On).await;
Timer::after(Duration::from_secs(1)).await;
CHANNEL.send(LedState::Off).await;
Timer::after(Duration::from_secs(1)).await;
}
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut led = Output::new(p.P0_13, Level::Low, OutputDrive::Standard);
unwrap!(spawner.spawn(my_task()));
loop {
match CHANNEL.recv().await {
LedState::On => led.set_high(),
LedState::Off => led.set_low(),
}
}
}

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examples/nrf52840/src/bin/channel_sender_receiver.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::unwrap;
use embassy_executor::Spawner;
use embassy_nrf::gpio::{AnyPin, Level, Output, OutputDrive, Pin};
use embassy_sync::blocking_mutex::raw::NoopRawMutex;
use embassy_sync::channel::{Channel, Receiver, Sender};
use embassy_time::{Duration, Timer};
use static_cell::StaticCell;
use {defmt_rtt as _, panic_probe as _};
enum LedState {
On,
Off,
}
static CHANNEL: StaticCell<Channel<NoopRawMutex, LedState, 1>> = StaticCell::new();
#[embassy_executor::task]
async fn send_task(sender: Sender<'static, NoopRawMutex, LedState, 1>) {
loop {
sender.send(LedState::On).await;
Timer::after(Duration::from_secs(1)).await;
sender.send(LedState::Off).await;
Timer::after(Duration::from_secs(1)).await;
}
}
#[embassy_executor::task]
async fn recv_task(led: AnyPin, receiver: Receiver<'static, NoopRawMutex, LedState, 1>) {
let mut led = Output::new(led, Level::Low, OutputDrive::Standard);
loop {
match receiver.recv().await {
LedState::On => led.set_high(),
LedState::Off => led.set_low(),
}
}
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let channel = CHANNEL.init(Channel::new());
unwrap!(spawner.spawn(send_task(channel.sender())));
unwrap!(spawner.spawn(recv_task(p.P0_13.degrade(), channel.receiver())));
}

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examples/nrf52840/src/bin/executor_fairness_test.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::future::poll_fn;
use core::task::Poll;
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_time::{Duration, Instant, Timer};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::task]
async fn run1() {
loop {
info!("DING DONG");
Timer::after(Duration::from_ticks(16000)).await;
}
}
#[embassy_executor::task]
async fn run2() {
loop {
Timer::at(Instant::from_ticks(0)).await;
}
}
#[embassy_executor::task]
async fn run3() {
poll_fn(|cx| {
cx.waker().wake_by_ref();
Poll::<()>::Pending
})
.await;
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let _p = embassy_nrf::init(Default::default());
unwrap!(spawner.spawn(run1()));
unwrap!(spawner.spawn(run2()));
unwrap!(spawner.spawn(run3()));
}

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examples/nrf52840/src/bin/gpiote_channel.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::info;
use embassy_executor::Spawner;
use embassy_nrf::gpio::{Input, Pull};
use embassy_nrf::gpiote::{InputChannel, InputChannelPolarity};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
info!("Starting!");
let ch1 = InputChannel::new(
p.GPIOTE_CH0,
Input::new(p.P0_11, Pull::Up),
InputChannelPolarity::HiToLo,
);
let ch2 = InputChannel::new(
p.GPIOTE_CH1,
Input::new(p.P0_12, Pull::Up),
InputChannelPolarity::LoToHi,
);
let ch3 = InputChannel::new(
p.GPIOTE_CH2,
Input::new(p.P0_24, Pull::Up),
InputChannelPolarity::Toggle,
);
let ch4 = InputChannel::new(
p.GPIOTE_CH3,
Input::new(p.P0_25, Pull::Up),
InputChannelPolarity::Toggle,
);
let button1 = async {
loop {
ch1.wait().await;
info!("Button 1 pressed")
}
};
let button2 = async {
loop {
ch2.wait().await;
info!("Button 2 released")
}
};
let button3 = async {
loop {
ch3.wait().await;
info!("Button 3 toggled")
}
};
let button4 = async {
loop {
ch4.wait().await;
info!("Button 4 toggled")
}
};
futures::join!(button1, button2, button3, button4);
}

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examples/nrf52840/src/bin/gpiote_port.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_nrf::gpio::{AnyPin, Input, Pin as _, Pull};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::task(pool_size = 4)]
async fn button_task(n: usize, mut pin: Input<'static, AnyPin>) {
loop {
pin.wait_for_low().await;
info!("Button {:?} pressed!", n);
pin.wait_for_high().await;
info!("Button {:?} released!", n);
}
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
info!("Starting!");
let btn1 = Input::new(p.P0_11.degrade(), Pull::Up);
let btn2 = Input::new(p.P0_12.degrade(), Pull::Up);
let btn3 = Input::new(p.P0_24.degrade(), Pull::Up);
let btn4 = Input::new(p.P0_25.degrade(), Pull::Up);
unwrap!(spawner.spawn(button_task(1, btn1)));
unwrap!(spawner.spawn(button_task(2, btn2)));
unwrap!(spawner.spawn(button_task(3, btn3)));
unwrap!(spawner.spawn(button_task(4, btn4)));
}

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examples/nrf52840/src/bin/i2s_effect.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::f32::consts::PI;
use defmt::{error, info};
use embassy_executor::Spawner;
use embassy_nrf::i2s::{self, Channels, Config, MasterClock, MultiBuffering, Sample as _, SampleWidth, I2S};
use embassy_nrf::{bind_interrupts, peripherals};
use {defmt_rtt as _, panic_probe as _};
type Sample = i16;
const NUM_BUFFERS: usize = 2;
const NUM_SAMPLES: usize = 4;
bind_interrupts!(struct Irqs {
I2S => i2s::InterruptHandler<peripherals::I2S>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let master_clock: MasterClock = i2s::ExactSampleRate::_50000.into();
let sample_rate = master_clock.sample_rate();
info!("Sample rate: {}", sample_rate);
let mut config = Config::default();
config.sample_width = SampleWidth::_16bit;
config.channels = Channels::MonoLeft;
let buffers_out = MultiBuffering::<Sample, NUM_BUFFERS, NUM_SAMPLES>::new();
let buffers_in = MultiBuffering::<Sample, NUM_BUFFERS, NUM_SAMPLES>::new();
let mut full_duplex_stream = I2S::new_master(p.I2S, Irqs, p.P0_25, p.P0_26, p.P0_27, master_clock, config)
.full_duplex(p.P0_29, p.P0_28, buffers_out, buffers_in);
let mut modulator = SineOsc::new();
modulator.set_frequency(8.0, 1.0 / sample_rate as f32);
modulator.set_amplitude(1.0);
full_duplex_stream.start().await.expect("I2S Start");
loop {
let (buff_out, buff_in) = full_duplex_stream.buffers();
for i in 0..NUM_SAMPLES {
let modulation = (Sample::SCALE as f32 * bipolar_to_unipolar(modulator.generate())) as Sample;
buff_out[i] = buff_in[i] * modulation;
}
if let Err(err) = full_duplex_stream.send_and_receive().await {
error!("{}", err);
}
}
}
struct SineOsc {
amplitude: f32,
modulo: f32,
phase_inc: f32,
}
impl SineOsc {
const B: f32 = 4.0 / PI;
const C: f32 = -4.0 / (PI * PI);
const P: f32 = 0.225;
pub fn new() -> Self {
Self {
amplitude: 1.0,
modulo: 0.0,
phase_inc: 0.0,
}
}
pub fn set_frequency(&mut self, freq: f32, inv_sample_rate: f32) {
self.phase_inc = freq * inv_sample_rate;
}
pub fn set_amplitude(&mut self, amplitude: f32) {
self.amplitude = amplitude;
}
pub fn generate(&mut self) -> f32 {
let signal = self.parabolic_sin(self.modulo);
self.modulo += self.phase_inc;
if self.modulo < 0.0 {
self.modulo += 1.0;
} else if self.modulo > 1.0 {
self.modulo -= 1.0;
}
signal * self.amplitude
}
fn parabolic_sin(&mut self, modulo: f32) -> f32 {
let angle = PI - modulo * 2.0 * PI;
let y = Self::B * angle + Self::C * angle * abs(angle);
Self::P * (y * abs(y) - y) + y
}
}
#[inline]
fn abs(value: f32) -> f32 {
if value < 0.0 {
-value
} else {
value
}
}
#[inline]
fn bipolar_to_unipolar(value: f32) -> f32 {
(value + 1.0) / 2.0
}

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examples/nrf52840/src/bin/i2s_monitor.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{debug, error, info};
use embassy_executor::Spawner;
use embassy_nrf::i2s::{self, Channels, Config, DoubleBuffering, MasterClock, Sample as _, SampleWidth, I2S};
use embassy_nrf::pwm::{Prescaler, SimplePwm};
use embassy_nrf::{bind_interrupts, peripherals};
use {defmt_rtt as _, panic_probe as _};
type Sample = i16;
const NUM_SAMPLES: usize = 500;
bind_interrupts!(struct Irqs {
I2S => i2s::InterruptHandler<peripherals::I2S>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let master_clock: MasterClock = i2s::ExactSampleRate::_50000.into();
let sample_rate = master_clock.sample_rate();
info!("Sample rate: {}", sample_rate);
let mut config = Config::default();
config.sample_width = SampleWidth::_16bit;
config.channels = Channels::MonoLeft;
let buffers = DoubleBuffering::<Sample, NUM_SAMPLES>::new();
let mut input_stream =
I2S::new_master(p.I2S, Irqs, p.P0_25, p.P0_26, p.P0_27, master_clock, config).input(p.P0_29, buffers);
// Configure the PWM to use the pins corresponding to the RGB leds
let mut pwm = SimplePwm::new_3ch(p.PWM0, p.P0_23, p.P0_22, p.P0_24);
pwm.set_prescaler(Prescaler::Div1);
pwm.set_max_duty(255);
let mut rms_online = RmsOnline::<NUM_SAMPLES>::default();
input_stream.start().await.expect("I2S Start");
loop {
let rms = rms_online.process(input_stream.buffer());
let rgb = rgb_from_rms(rms);
debug!("RMS: {}, RGB: {:?}", rms, rgb);
for i in 0..3 {
pwm.set_duty(i, rgb[i].into());
}
if let Err(err) = input_stream.receive().await {
error!("{}", err);
}
}
}
/// RMS from 0.0 until 0.75 will give green with a proportional intensity
/// RMS from 0.75 until 0.9 will give a blend between orange and red proportionally to the intensity
/// RMS above 0.9 will give a red with a proportional intensity
fn rgb_from_rms(rms: f32) -> [u8; 3] {
if rms < 0.75 {
let intensity = rms / 0.75;
[0, (intensity * 165.0) as u8, 0]
} else if rms < 0.9 {
let intensity = (rms - 0.75) / 0.15;
[200, 165 - (165.0 * intensity) as u8, 0]
} else {
let intensity = (rms - 0.9) / 0.1;
[200 + (55.0 * intensity) as u8, 0, 0]
}
}
pub struct RmsOnline<const N: usize> {
pub squares: [f32; N],
pub head: usize,
}
impl<const N: usize> Default for RmsOnline<N> {
fn default() -> Self {
RmsOnline {
squares: [0.0; N],
head: 0,
}
}
}
impl<const N: usize> RmsOnline<N> {
pub fn reset(&mut self) {
self.squares = [0.0; N];
self.head = 0;
}
pub fn process(&mut self, buf: &[Sample]) -> f32 {
buf.iter()
.for_each(|sample| self.push(*sample as f32 / Sample::SCALE as f32));
let sum_of_squares = self.squares.iter().fold(0.0, |acc, v| acc + *v);
Self::approx_sqrt(sum_of_squares / N as f32)
}
pub fn push(&mut self, signal: f32) {
let square = signal * signal;
self.squares[self.head] = square;
self.head = (self.head + 1) % N;
}
/// Approximated sqrt taken from [micromath]
///
/// [micromath]: https://docs.rs/micromath/latest/src/micromath/float/sqrt.rs.html#11-17
///
fn approx_sqrt(value: f32) -> f32 {
f32::from_bits((value.to_bits() + 0x3f80_0000) >> 1)
}
}

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examples/nrf52840/src/bin/i2s_waveform.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::f32::consts::PI;
use defmt::{error, info};
use embassy_executor::Spawner;
use embassy_nrf::i2s::{self, Channels, Config, DoubleBuffering, MasterClock, Sample as _, SampleWidth, I2S};
use embassy_nrf::{bind_interrupts, peripherals};
use {defmt_rtt as _, panic_probe as _};
type Sample = i16;
const NUM_SAMPLES: usize = 50;
bind_interrupts!(struct Irqs {
I2S => i2s::InterruptHandler<peripherals::I2S>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let master_clock: MasterClock = i2s::ExactSampleRate::_50000.into();
let sample_rate = master_clock.sample_rate();
info!("Sample rate: {}", sample_rate);
let mut config = Config::default();
config.sample_width = SampleWidth::_16bit;
config.channels = Channels::MonoLeft;
let buffers = DoubleBuffering::<Sample, NUM_SAMPLES>::new();
let mut output_stream =
I2S::new_master(p.I2S, Irqs, p.P0_25, p.P0_26, p.P0_27, master_clock, config).output(p.P0_28, buffers);
let mut waveform = Waveform::new(1.0 / sample_rate as f32);
waveform.process(output_stream.buffer());
output_stream.start().await.expect("I2S Start");
loop {
waveform.process(output_stream.buffer());
if let Err(err) = output_stream.send().await {
error!("{}", err);
}
}
}
struct Waveform {
inv_sample_rate: f32,
carrier: SineOsc,
freq_mod: SineOsc,
amp_mod: SineOsc,
}
impl Waveform {
fn new(inv_sample_rate: f32) -> Self {
let mut carrier = SineOsc::new();
carrier.set_frequency(110.0, inv_sample_rate);
let mut freq_mod = SineOsc::new();
freq_mod.set_frequency(1.0, inv_sample_rate);
freq_mod.set_amplitude(1.0);
let mut amp_mod = SineOsc::new();
amp_mod.set_frequency(16.0, inv_sample_rate);
amp_mod.set_amplitude(0.5);
Self {
inv_sample_rate,
carrier,
freq_mod,
amp_mod,
}
}
fn process(&mut self, buf: &mut [Sample]) {
for sample in buf.chunks_mut(1) {
let freq_modulation = bipolar_to_unipolar(self.freq_mod.generate());
self.carrier
.set_frequency(110.0 + 440.0 * freq_modulation, self.inv_sample_rate);
let amp_modulation = bipolar_to_unipolar(self.amp_mod.generate());
self.carrier.set_amplitude(amp_modulation);
let signal = self.carrier.generate();
sample[0] = (Sample::SCALE as f32 * signal) as Sample;
}
}
}
struct SineOsc {
amplitude: f32,
modulo: f32,
phase_inc: f32,
}
impl SineOsc {
const B: f32 = 4.0 / PI;
const C: f32 = -4.0 / (PI * PI);
const P: f32 = 0.225;
pub fn new() -> Self {
Self {
amplitude: 1.0,
modulo: 0.0,
phase_inc: 0.0,
}
}
pub fn set_frequency(&mut self, freq: f32, inv_sample_rate: f32) {
self.phase_inc = freq * inv_sample_rate;
}
pub fn set_amplitude(&mut self, amplitude: f32) {
self.amplitude = amplitude;
}
pub fn generate(&mut self) -> f32 {
let signal = self.parabolic_sin(self.modulo);
self.modulo += self.phase_inc;
if self.modulo < 0.0 {
self.modulo += 1.0;
} else if self.modulo > 1.0 {
self.modulo -= 1.0;
}
signal * self.amplitude
}
fn parabolic_sin(&mut self, modulo: f32) -> f32 {
let angle = PI - modulo * 2.0 * PI;
let y = Self::B * angle + Self::C * angle * abs(angle);
Self::P * (y * abs(y) - y) + y
}
}
#[inline]
fn abs(value: f32) -> f32 {
if value < 0.0 {
-value
} else {
value
}
}
#[inline]
fn bipolar_to_unipolar(value: f32) -> f32 {
(value + 1.0) / 2.0
}

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//! This example runs on the RAK4631 WisBlock, which has an nRF52840 MCU and Semtech Sx126x radio.
//! Other nrf/sx126x combinations may work with appropriate pin modifications.
//! It demonstrates LORA CAD functionality.
#![no_std]
#![no_main]
#![macro_use]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_lora::iv::GenericSx126xInterfaceVariant;
use embassy_nrf::gpio::{Input, Level, Output, OutputDrive, Pin as _, Pull};
use embassy_nrf::{bind_interrupts, peripherals, spim};
use embassy_time::{Delay, Duration, Timer};
use lora_phy::mod_params::*;
use lora_phy::sx1261_2::SX1261_2;
use lora_phy::LoRa;
use {defmt_rtt as _, panic_probe as _};
const LORA_FREQUENCY_IN_HZ: u32 = 903_900_000; // warning: set this appropriately for the region
bind_interrupts!(struct Irqs {
SPIM1_SPIS1_TWIM1_TWIS1_SPI1_TWI1 => spim::InterruptHandler<peripherals::TWISPI1>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut spi_config = spim::Config::default();
spi_config.frequency = spim::Frequency::M16;
let spim = spim::Spim::new(p.TWISPI1, Irqs, p.P1_11, p.P1_13, p.P1_12, spi_config);
let nss = Output::new(p.P1_10.degrade(), Level::High, OutputDrive::Standard);
let reset = Output::new(p.P1_06.degrade(), Level::High, OutputDrive::Standard);
let dio1 = Input::new(p.P1_15.degrade(), Pull::Down);
let busy = Input::new(p.P1_14.degrade(), Pull::Down);
let rf_switch_rx = Output::new(p.P1_05.degrade(), Level::Low, OutputDrive::Standard);
let rf_switch_tx = Output::new(p.P1_07.degrade(), Level::Low, OutputDrive::Standard);
let iv =
GenericSx126xInterfaceVariant::new(nss, reset, dio1, busy, Some(rf_switch_rx), Some(rf_switch_tx)).unwrap();
let mut delay = Delay;
let mut lora = {
match LoRa::new(SX1261_2::new(BoardType::Rak4631Sx1262, spim, iv), false, &mut delay).await {
Ok(l) => l,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
let mut debug_indicator = Output::new(p.P1_03, Level::Low, OutputDrive::Standard);
let mut start_indicator = Output::new(p.P1_04, Level::Low, OutputDrive::Standard);
start_indicator.set_high();
Timer::after(Duration::from_secs(5)).await;
start_indicator.set_low();
let mdltn_params = {
match lora.create_modulation_params(
SpreadingFactor::_10,
Bandwidth::_250KHz,
CodingRate::_4_8,
LORA_FREQUENCY_IN_HZ,
) {
Ok(mp) => mp,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
match lora.prepare_for_cad(&mdltn_params, true).await {
Ok(()) => {}
Err(err) => {
info!("Radio error = {}", err);
return;
}
};
match lora.cad().await {
Ok(cad_activity_detected) => {
if cad_activity_detected {
info!("cad successful with activity detected")
} else {
info!("cad successful without activity detected")
}
debug_indicator.set_high();
Timer::after(Duration::from_secs(5)).await;
debug_indicator.set_low();
}
Err(err) => info!("cad unsuccessful = {}", err),
}
}

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//! This example runs on the RAK4631 WisBlock, which has an nRF52840 MCU and Semtech Sx126x radio.
//! Other nrf/sx126x combinations may work with appropriate pin modifications.
//! It demonstrates LoRaWAN join functionality.
#![no_std]
#![no_main]
#![macro_use]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_lora::iv::GenericSx126xInterfaceVariant;
use embassy_lora::LoraTimer;
use embassy_nrf::gpio::{Input, Level, Output, OutputDrive, Pin as _, Pull};
use embassy_nrf::rng::Rng;
use embassy_nrf::{bind_interrupts, peripherals, rng, spim};
use embassy_time::Delay;
use lora_phy::mod_params::*;
use lora_phy::sx1261_2::SX1261_2;
use lora_phy::LoRa;
use lorawan::default_crypto::DefaultFactory as Crypto;
use lorawan_device::async_device::lora_radio::LoRaRadio;
use lorawan_device::async_device::{region, Device, JoinMode};
use {defmt_rtt as _, panic_probe as _};
const LORAWAN_REGION: region::Region = region::Region::EU868; // warning: set this appropriately for the region
bind_interrupts!(struct Irqs {
SPIM1_SPIS1_TWIM1_TWIS1_SPI1_TWI1 => spim::InterruptHandler<peripherals::TWISPI1>;
RNG => rng::InterruptHandler<peripherals::RNG>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut spi_config = spim::Config::default();
spi_config.frequency = spim::Frequency::M16;
let spim = spim::Spim::new(p.TWISPI1, Irqs, p.P1_11, p.P1_13, p.P1_12, spi_config);
let nss = Output::new(p.P1_10.degrade(), Level::High, OutputDrive::Standard);
let reset = Output::new(p.P1_06.degrade(), Level::High, OutputDrive::Standard);
let dio1 = Input::new(p.P1_15.degrade(), Pull::Down);
let busy = Input::new(p.P1_14.degrade(), Pull::Down);
let rf_switch_rx = Output::new(p.P1_05.degrade(), Level::Low, OutputDrive::Standard);
let rf_switch_tx = Output::new(p.P1_07.degrade(), Level::Low, OutputDrive::Standard);
let iv =
GenericSx126xInterfaceVariant::new(nss, reset, dio1, busy, Some(rf_switch_rx), Some(rf_switch_tx)).unwrap();
let mut delay = Delay;
let lora = {
match LoRa::new(SX1261_2::new(BoardType::Rak4631Sx1262, spim, iv), true, &mut delay).await {
Ok(l) => l,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
let radio = LoRaRadio::new(lora);
let region: region::Configuration = region::Configuration::new(LORAWAN_REGION);
let mut device: Device<_, Crypto, _, _> = Device::new(region, radio, LoraTimer::new(), Rng::new(p.RNG, Irqs));
defmt::info!("Joining LoRaWAN network");
// TODO: Adjust the EUI and Keys according to your network credentials
match device
.join(&JoinMode::OTAA {
deveui: [0, 0, 0, 0, 0, 0, 0, 0],
appeui: [0, 0, 0, 0, 0, 0, 0, 0],
appkey: [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0],
})
.await
{
Ok(()) => defmt::info!("LoRaWAN network joined"),
Err(err) => {
info!("Radio error = {}", err);
return;
}
};
}

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//! This example runs on the RAK4631 WisBlock, which has an nRF52840 MCU and Semtech Sx126x radio.
//! Other nrf/sx126x combinations may work with appropriate pin modifications.
//! It demonstrates LORA P2P receive functionality in conjunction with the lora_p2p_send example.
#![no_std]
#![no_main]
#![macro_use]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_lora::iv::GenericSx126xInterfaceVariant;
use embassy_nrf::gpio::{Input, Level, Output, OutputDrive, Pin as _, Pull};
use embassy_nrf::{bind_interrupts, peripherals, spim};
use embassy_time::{Delay, Duration, Timer};
use lora_phy::mod_params::*;
use lora_phy::sx1261_2::SX1261_2;
use lora_phy::LoRa;
use {defmt_rtt as _, panic_probe as _};
const LORA_FREQUENCY_IN_HZ: u32 = 903_900_000; // warning: set this appropriately for the region
bind_interrupts!(struct Irqs {
SPIM1_SPIS1_TWIM1_TWIS1_SPI1_TWI1 => spim::InterruptHandler<peripherals::TWISPI1>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut spi_config = spim::Config::default();
spi_config.frequency = spim::Frequency::M16;
let spim = spim::Spim::new(p.TWISPI1, Irqs, p.P1_11, p.P1_13, p.P1_12, spi_config);
let nss = Output::new(p.P1_10.degrade(), Level::High, OutputDrive::Standard);
let reset = Output::new(p.P1_06.degrade(), Level::High, OutputDrive::Standard);
let dio1 = Input::new(p.P1_15.degrade(), Pull::Down);
let busy = Input::new(p.P1_14.degrade(), Pull::Down);
let rf_switch_rx = Output::new(p.P1_05.degrade(), Level::Low, OutputDrive::Standard);
let rf_switch_tx = Output::new(p.P1_07.degrade(), Level::Low, OutputDrive::Standard);
let iv =
GenericSx126xInterfaceVariant::new(nss, reset, dio1, busy, Some(rf_switch_rx), Some(rf_switch_tx)).unwrap();
let mut delay = Delay;
let mut lora = {
match LoRa::new(SX1261_2::new(BoardType::Rak4631Sx1262, spim, iv), false, &mut delay).await {
Ok(l) => l,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
let mut debug_indicator = Output::new(p.P1_03, Level::Low, OutputDrive::Standard);
let mut start_indicator = Output::new(p.P1_04, Level::Low, OutputDrive::Standard);
start_indicator.set_high();
Timer::after(Duration::from_secs(5)).await;
start_indicator.set_low();
let mut receiving_buffer = [00u8; 100];
let mdltn_params = {
match lora.create_modulation_params(
SpreadingFactor::_10,
Bandwidth::_250KHz,
CodingRate::_4_8,
LORA_FREQUENCY_IN_HZ,
) {
Ok(mp) => mp,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
let rx_pkt_params = {
match lora.create_rx_packet_params(4, false, receiving_buffer.len() as u8, true, false, &mdltn_params) {
Ok(pp) => pp,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
match lora
.prepare_for_rx(&mdltn_params, &rx_pkt_params, None, true, false, 0, 0x00ffffffu32)
.await
{
Ok(()) => {}
Err(err) => {
info!("Radio error = {}", err);
return;
}
};
loop {
receiving_buffer = [00u8; 100];
match lora.rx(&rx_pkt_params, &mut receiving_buffer).await {
Ok((received_len, _rx_pkt_status)) => {
if (received_len == 3)
&& (receiving_buffer[0] == 0x01u8)
&& (receiving_buffer[1] == 0x02u8)
&& (receiving_buffer[2] == 0x03u8)
{
info!("rx successful");
debug_indicator.set_high();
Timer::after(Duration::from_secs(5)).await;
debug_indicator.set_low();
} else {
info!("rx unknown packet");
}
}
Err(err) => info!("rx unsuccessful = {}", err),
}
}
}

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//! This example runs on the RAK4631 WisBlock, which has an nRF52840 MCU and Semtech Sx126x radio.
//! Other nrf/sx126x combinations may work with appropriate pin modifications.
//! It demonstrates LoRa Rx duty cycle functionality in conjunction with the lora_p2p_send example.
#![no_std]
#![no_main]
#![macro_use]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_lora::iv::GenericSx126xInterfaceVariant;
use embassy_nrf::gpio::{Input, Level, Output, OutputDrive, Pin as _, Pull};
use embassy_nrf::{bind_interrupts, peripherals, spim};
use embassy_time::{Delay, Duration, Timer};
use lora_phy::mod_params::*;
use lora_phy::sx1261_2::SX1261_2;
use lora_phy::LoRa;
use {defmt_rtt as _, panic_probe as _};
const LORA_FREQUENCY_IN_HZ: u32 = 903_900_000; // warning: set this appropriately for the region
bind_interrupts!(struct Irqs {
SPIM1_SPIS1_TWIM1_TWIS1_SPI1_TWI1 => spim::InterruptHandler<peripherals::TWISPI1>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut spi_config = spim::Config::default();
spi_config.frequency = spim::Frequency::M16;
let spim = spim::Spim::new(p.TWISPI1, Irqs, p.P1_11, p.P1_13, p.P1_12, spi_config);
let nss = Output::new(p.P1_10.degrade(), Level::High, OutputDrive::Standard);
let reset = Output::new(p.P1_06.degrade(), Level::High, OutputDrive::Standard);
let dio1 = Input::new(p.P1_15.degrade(), Pull::Down);
let busy = Input::new(p.P1_14.degrade(), Pull::Down);
let rf_switch_rx = Output::new(p.P1_05.degrade(), Level::Low, OutputDrive::Standard);
let rf_switch_tx = Output::new(p.P1_07.degrade(), Level::Low, OutputDrive::Standard);
let iv =
GenericSx126xInterfaceVariant::new(nss, reset, dio1, busy, Some(rf_switch_rx), Some(rf_switch_tx)).unwrap();
let mut delay = Delay;
let mut lora = {
match LoRa::new(SX1261_2::new(BoardType::Rak4631Sx1262, spim, iv), false, &mut delay).await {
Ok(l) => l,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
let mut debug_indicator = Output::new(p.P1_03, Level::Low, OutputDrive::Standard);
let mut start_indicator = Output::new(p.P1_04, Level::Low, OutputDrive::Standard);
start_indicator.set_high();
Timer::after(Duration::from_secs(5)).await;
start_indicator.set_low();
let mut receiving_buffer = [00u8; 100];
let mdltn_params = {
match lora.create_modulation_params(
SpreadingFactor::_10,
Bandwidth::_250KHz,
CodingRate::_4_8,
LORA_FREQUENCY_IN_HZ,
) {
Ok(mp) => mp,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
let rx_pkt_params = {
match lora.create_rx_packet_params(4, false, receiving_buffer.len() as u8, true, false, &mdltn_params) {
Ok(pp) => pp,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
// See "RM0453 Reference manual STM32WL5x advanced Arm®-based 32-bit MCUs with sub-GHz radio solution" for the best explanation of Rx duty cycle processing.
match lora
.prepare_for_rx(
&mdltn_params,
&rx_pkt_params,
Some(&DutyCycleParams {
rx_time: 300_000, // 300_000 units * 15.625 us/unit = 4.69 s
sleep_time: 200_000, // 200_000 units * 15.625 us/unit = 3.13 s
}),
false,
false,
0,
0,
)
.await
{
Ok(()) => {}
Err(err) => {
info!("Radio error = {}", err);
return;
}
};
receiving_buffer = [00u8; 100];
match lora.rx(&rx_pkt_params, &mut receiving_buffer).await {
Ok((received_len, _rx_pkt_status)) => {
if (received_len == 3)
&& (receiving_buffer[0] == 0x01u8)
&& (receiving_buffer[1] == 0x02u8)
&& (receiving_buffer[2] == 0x03u8)
{
info!("rx successful");
debug_indicator.set_high();
Timer::after(Duration::from_secs(5)).await;
debug_indicator.set_low();
} else {
info!("rx unknown packet")
}
}
Err(err) => info!("rx unsuccessful = {}", err),
}
}

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//! This example runs on the RAK4631 WisBlock, which has an nRF52840 MCU and Semtech Sx126x radio.
//! Other nrf/sx126x combinations may work with appropriate pin modifications.
//! It demonstrates LORA P2P send functionality.
#![no_std]
#![no_main]
#![macro_use]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_lora::iv::GenericSx126xInterfaceVariant;
use embassy_nrf::gpio::{Input, Level, Output, OutputDrive, Pin as _, Pull};
use embassy_nrf::{bind_interrupts, peripherals, spim};
use embassy_time::Delay;
use lora_phy::mod_params::*;
use lora_phy::sx1261_2::SX1261_2;
use lora_phy::LoRa;
use {defmt_rtt as _, panic_probe as _};
const LORA_FREQUENCY_IN_HZ: u32 = 903_900_000; // warning: set this appropriately for the region
bind_interrupts!(struct Irqs {
SPIM1_SPIS1_TWIM1_TWIS1_SPI1_TWI1 => spim::InterruptHandler<peripherals::TWISPI1>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut spi_config = spim::Config::default();
spi_config.frequency = spim::Frequency::M16;
let spim = spim::Spim::new(p.TWISPI1, Irqs, p.P1_11, p.P1_13, p.P1_12, spi_config);
let nss = Output::new(p.P1_10.degrade(), Level::High, OutputDrive::Standard);
let reset = Output::new(p.P1_06.degrade(), Level::High, OutputDrive::Standard);
let dio1 = Input::new(p.P1_15.degrade(), Pull::Down);
let busy = Input::new(p.P1_14.degrade(), Pull::Down);
let rf_switch_rx = Output::new(p.P1_05.degrade(), Level::Low, OutputDrive::Standard);
let rf_switch_tx = Output::new(p.P1_07.degrade(), Level::Low, OutputDrive::Standard);
let iv =
GenericSx126xInterfaceVariant::new(nss, reset, dio1, busy, Some(rf_switch_rx), Some(rf_switch_tx)).unwrap();
let mut delay = Delay;
let mut lora = {
match LoRa::new(SX1261_2::new(BoardType::Rak4631Sx1262, spim, iv), false, &mut delay).await {
Ok(l) => l,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
let mdltn_params = {
match lora.create_modulation_params(
SpreadingFactor::_10,
Bandwidth::_250KHz,
CodingRate::_4_8,
LORA_FREQUENCY_IN_HZ,
) {
Ok(mp) => mp,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
let mut tx_pkt_params = {
match lora.create_tx_packet_params(4, false, true, false, &mdltn_params) {
Ok(pp) => pp,
Err(err) => {
info!("Radio error = {}", err);
return;
}
}
};
match lora.prepare_for_tx(&mdltn_params, 20, false).await {
Ok(()) => {}
Err(err) => {
info!("Radio error = {}", err);
return;
}
};
let buffer = [0x01u8, 0x02u8, 0x03u8];
match lora.tx(&mdltn_params, &mut tx_pkt_params, &buffer, 0xffffff).await {
Ok(()) => {
info!("TX DONE");
}
Err(err) => {
info!("Radio error = {}", err);
return;
}
};
match lora.sleep(&mut delay).await {
Ok(()) => info!("Sleep successful"),
Err(err) => info!("Sleep unsuccessful = {}", err),
}
}

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// This example showcases how to manually create an executor.
// This is what the #[embassy::main] macro does behind the scenes.
#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use cortex_m_rt::entry;
use defmt::{info, unwrap};
use embassy_executor::Executor;
use embassy_time::{Duration, Timer};
use static_cell::StaticCell;
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::task]
async fn run1() {
loop {
info!("BIG INFREQUENT TICK");
Timer::after(Duration::from_ticks(64000)).await;
}
}
#[embassy_executor::task]
async fn run2() {
loop {
info!("tick");
Timer::after(Duration::from_ticks(13000)).await;
}
}
static EXECUTOR: StaticCell<Executor> = StaticCell::new();
#[entry]
fn main() -> ! {
info!("Hello World!");
let _p = embassy_nrf::init(Default::default());
// Create the executor and put it in a StaticCell, because `run` needs `&'static mut Executor`.
let executor = EXECUTOR.init(Executor::new());
// Run it.
// `run` calls the closure then runs the executor forever. It never returns.
executor.run(|spawner| {
// Here we get access to a spawner to spawn the initial tasks.
unwrap!(spawner.spawn(run1()));
unwrap!(spawner.spawn(run2()));
});
}

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//! This example showcases how to create multiple Executor instances to run tasks at
//! different priority levels.
//!
//! Low priority executor runs in thread mode (not interrupt), and uses `sev` for signaling
//! there's work in the queue, and `wfe` for waiting for work.
//!
//! Medium and high priority executors run in two interrupts with different priorities.
//! Signaling work is done by pending the interrupt. No "waiting" needs to be done explicitly, since
//! when there's work the interrupt will trigger and run the executor.
//!
//! Sample output below. Note that high priority ticks can interrupt everything else, and
//! medium priority computations can interrupt low priority computations, making them to appear
//! to take significantly longer time.
//!
//! ```not_rust
//! [med] Starting long computation
//! [med] done in 992 ms
//! [high] tick!
//! [low] Starting long computation
//! [med] Starting long computation
//! [high] tick!
//! [high] tick!
//! [med] done in 993 ms
//! [med] Starting long computation
//! [high] tick!
//! [high] tick!
//! [med] done in 993 ms
//! [low] done in 3972 ms
//! [med] Starting long computation
//! [high] tick!
//! [high] tick!
//! [med] done in 993 ms
//! ```
//!
//! For comparison, try changing the code so all 3 tasks get spawned on the low priority executor.
//! You will get an output like the following. Note that no computation is ever interrupted.
//!
//! ```not_rust
//! [high] tick!
//! [med] Starting long computation
//! [med] done in 496 ms
//! [low] Starting long computation
//! [low] done in 992 ms
//! [med] Starting long computation
//! [med] done in 496 ms
//! [high] tick!
//! [low] Starting long computation
//! [low] done in 992 ms
//! [high] tick!
//! [med] Starting long computation
//! [med] done in 496 ms
//! [high] tick!
//! ```
//!
#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use cortex_m_rt::entry;
use defmt::{info, unwrap};
use embassy_executor::{Executor, InterruptExecutor};
use embassy_nrf::interrupt;
use embassy_nrf::interrupt::{InterruptExt, Priority};
use embassy_time::{Duration, Instant, Timer};
use static_cell::StaticCell;
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::task]
async fn run_high() {
loop {
info!(" [high] tick!");
Timer::after(Duration::from_ticks(27374)).await;
}
}
#[embassy_executor::task]
async fn run_med() {
loop {
let start = Instant::now();
info!(" [med] Starting long computation");
// Spin-wait to simulate a long CPU computation
cortex_m::asm::delay(32_000_000); // ~1 second
let end = Instant::now();
let ms = end.duration_since(start).as_ticks() / 33;
info!(" [med] done in {} ms", ms);
Timer::after(Duration::from_ticks(23421)).await;
}
}
#[embassy_executor::task]
async fn run_low() {
loop {
let start = Instant::now();
info!("[low] Starting long computation");
// Spin-wait to simulate a long CPU computation
cortex_m::asm::delay(64_000_000); // ~2 seconds
let end = Instant::now();
let ms = end.duration_since(start).as_ticks() / 33;
info!("[low] done in {} ms", ms);
Timer::after(Duration::from_ticks(32983)).await;
}
}
static EXECUTOR_HIGH: InterruptExecutor = InterruptExecutor::new();
static EXECUTOR_MED: InterruptExecutor = InterruptExecutor::new();
static EXECUTOR_LOW: StaticCell<Executor> = StaticCell::new();
#[interrupt]
unsafe fn SWI1_EGU1() {
EXECUTOR_HIGH.on_interrupt()
}
#[interrupt]
unsafe fn SWI0_EGU0() {
EXECUTOR_MED.on_interrupt()
}
#[entry]
fn main() -> ! {
info!("Hello World!");
let _p = embassy_nrf::init(Default::default());
// High-priority executor: SWI1_EGU1, priority level 6
interrupt::SWI1_EGU1.set_priority(Priority::P6);
let spawner = EXECUTOR_HIGH.start(interrupt::SWI1_EGU1);
unwrap!(spawner.spawn(run_high()));
// Medium-priority executor: SWI0_EGU0, priority level 7
interrupt::SWI0_EGU0.set_priority(Priority::P7);
let spawner = EXECUTOR_MED.start(interrupt::SWI0_EGU0);
unwrap!(spawner.spawn(run_med()));
// Low priority executor: runs in thread mode, using WFE/SEV
let executor = EXECUTOR_LOW.init(Executor::new());
executor.run(|spawner| {
unwrap!(spawner.spawn(run_low()));
});
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_sync::blocking_mutex::raw::ThreadModeRawMutex;
use embassy_sync::mutex::Mutex;
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
static MUTEX: Mutex<ThreadModeRawMutex, u32> = Mutex::new(0);
#[embassy_executor::task]
async fn my_task() {
loop {
{
let mut m = MUTEX.lock().await;
info!("start long operation");
*m += 1000;
// Hold the mutex for a long time.
Timer::after(Duration::from_secs(1)).await;
info!("end long operation: count = {}", *m);
}
Timer::after(Duration::from_secs(1)).await;
}
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let _p = embassy_nrf::init(Default::default());
unwrap!(spawner.spawn(my_task()));
loop {
Timer::after(Duration::from_millis(300)).await;
let mut m = MUTEX.lock().await;
*m += 1;
info!("short operation: count = {}", *m);
}
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_nrf::nvmc::Nvmc;
use embassy_time::{Duration, Timer};
use embedded_storage::nor_flash::{NorFlash, ReadNorFlash};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
info!("Hello NVMC!");
// probe-rs run breaks without this, I'm not sure why.
Timer::after(Duration::from_secs(1)).await;
let mut f = Nvmc::new(p.NVMC);
const ADDR: u32 = 0x80000;
info!("Reading...");
let mut buf = [0u8; 4];
unwrap!(f.read(ADDR, &mut buf));
info!("Read: {=[u8]:x}", buf);
info!("Erasing...");
unwrap!(f.erase(ADDR, ADDR + 4096));
info!("Reading...");
let mut buf = [0u8; 4];
unwrap!(f.read(ADDR, &mut buf));
info!("Read: {=[u8]:x}", buf);
info!("Writing...");
unwrap!(f.write(ADDR, &[1, 2, 3, 4]));
info!("Reading...");
let mut buf = [0u8; 4];
unwrap!(f.read(ADDR, &mut buf));
info!("Read: {=[u8]:x}", buf);
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::info;
use embassy_executor::Spawner;
use embassy_nrf::pdm::{self, Config, Pdm};
use embassy_nrf::{bind_interrupts, peripherals};
use embassy_time::{Duration, Timer};
use fixed::types::I7F1;
use num_integer::Roots;
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
PDM => pdm::InterruptHandler<peripherals::PDM>;
});
#[embassy_executor::main]
async fn main(_p: Spawner) {
let p = embassy_nrf::init(Default::default());
let config = Config::default();
let mut pdm = Pdm::new(p.PDM, Irqs, p.P0_01, p.P0_00, config);
loop {
for gain in [I7F1::from_num(-20), I7F1::from_num(0), I7F1::from_num(20)] {
pdm.set_gain(gain, gain);
info!("Gain = {} dB", defmt::Debug2Format(&gain));
pdm.start().await;
// wait some time till the microphon settled
Timer::after(Duration::from_millis(1000)).await;
const SAMPLES: usize = 2048;
let mut buf = [0i16; SAMPLES];
pdm.sample(&mut buf).await.unwrap();
let mean = (buf.iter().map(|v| i32::from(*v)).sum::<i32>() / buf.len() as i32) as i16;
info!(
"{} samples, min {=i16}, max {=i16}, mean {=i16}, AC RMS {=i16}",
buf.len(),
buf.iter().min().unwrap(),
buf.iter().max().unwrap(),
mean,
(
buf.iter().map(|v| i32::from(*v - mean).pow(2)).fold(0i32, |a,b| a.saturating_add(b))
/ buf.len() as i32).sqrt() as i16,
);
info!("samples: {:?}", &buf);
pdm.stop().await;
Timer::after(Duration::from_millis(100)).await;
}
}
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::info;
use core::cmp::Ordering;
use embassy_executor::Spawner;
use embassy_nrf::{bind_interrupts, peripherals};
use embassy_nrf::pdm::{self, Config, OperationMode, Pdm, SamplerState, Frequency, Ratio};
use fixed::types::I7F1;
use num_integer::Roots;
use microfft::real::rfft_1024;
use {defmt_rtt as _, panic_probe as _};
// Demonstrates both continuous sampling and scanning multiple channels driven by a PPI linked timer
bind_interrupts!(struct Irqs {
PDM => pdm::InterruptHandler<peripherals::PDM>;
});
#[embassy_executor::main]
async fn main(_p: Spawner) {
let mut p = embassy_nrf::init(Default::default());
let mut config = Config::default();
// Pins are correct for the onboard microphone on the Feather nRF52840 Sense.
config.frequency = Frequency::_1280K; // 16 kHz sample rate
config.ratio = Ratio::RATIO80;
config.operation_mode = OperationMode::Mono;
config.gain_left = I7F1::from_bits(5); // 2.5 dB
let mut pdm = Pdm::new(p.PDM, Irqs, &mut p.P0_00, &mut p.P0_01, config);
let mut bufs = [[0; 1024]; 2];
pdm
.run_task_sampler(
&mut bufs,
move |buf| {
// NOTE: It is important that the time spent within this callback
// does not exceed the time taken to acquire the 1500 samples we
// have in this example, which would be 10us + 2us per
// sample * 1500 = 18ms. You need to measure the time taken here
// and set the sample buffer size accordingly. Exceeding this
// time can lead to the peripheral re-writing the other buffer.
let mean = (buf.iter().map(|v| i32::from(*v)).sum::<i32>() / buf.len() as i32) as i16;
let (peak_freq_index, peak_mag) = fft_peak_freq(&buf);
let peak_freq = peak_freq_index * 16000 / buf.len();
info!(
"{} samples, min {=i16}, max {=i16}, mean {=i16}, AC RMS {=i16}, peak {} @ {} Hz",
buf.len(),
buf.iter().min().unwrap(),
buf.iter().max().unwrap(),
mean,
(
buf.iter().map(|v| i32::from(*v - mean).pow(2)).fold(0i32, |a,b| a.saturating_add(b))
/ buf.len() as i32).sqrt() as i16,
peak_mag, peak_freq,
);
SamplerState::Sampled
},
)
.await.unwrap();
}
fn fft_peak_freq(input: &[i16; 1024]) -> (usize, u32) {
let mut f = [0f32; 1024];
for i in 0..input.len() {
f[i] = (input[i] as f32) / 32768.0;
}
// N.B. rfft_1024 does the FFT in-place so result is actually also a reference to f.
let result = rfft_1024(&mut f);
result[0].im = 0.0;
result
.iter()
.map(|c| c.norm_sqr())
.enumerate()
.max_by(|(_, a), (_, b)| a.partial_cmp(b).unwrap_or(Ordering::Equal))
.map(|(i, v)| (i, ((v*32768.0) as u32).sqrt()))
.unwrap()
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::future::pending;
use defmt::info;
use embassy_executor::Spawner;
use embassy_nrf::gpio::{Input, Level, Output, OutputDrive, Pull};
use embassy_nrf::gpiote::{self, InputChannel, InputChannelPolarity};
use embassy_nrf::ppi::Ppi;
use gpiote::{OutputChannel, OutputChannelPolarity};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
info!("Starting!");
let button1 = InputChannel::new(
p.GPIOTE_CH0,
Input::new(p.P0_11, Pull::Up),
InputChannelPolarity::HiToLo,
);
let button2 = InputChannel::new(
p.GPIOTE_CH1,
Input::new(p.P0_12, Pull::Up),
InputChannelPolarity::HiToLo,
);
let button3 = InputChannel::new(
p.GPIOTE_CH2,
Input::new(p.P0_24, Pull::Up),
InputChannelPolarity::HiToLo,
);
let button4 = InputChannel::new(
p.GPIOTE_CH3,
Input::new(p.P0_25, Pull::Up),
InputChannelPolarity::HiToLo,
);
let led1 = OutputChannel::new(
p.GPIOTE_CH4,
Output::new(p.P0_13, Level::Low, OutputDrive::Standard),
OutputChannelPolarity::Toggle,
);
let led2 = OutputChannel::new(
p.GPIOTE_CH5,
Output::new(p.P0_14, Level::Low, OutputDrive::Standard),
OutputChannelPolarity::Toggle,
);
let mut ppi = Ppi::new_one_to_one(p.PPI_CH0, button1.event_in(), led1.task_out());
ppi.enable();
let mut ppi = Ppi::new_one_to_one(p.PPI_CH1, button2.event_in(), led1.task_clr());
ppi.enable();
let mut ppi = Ppi::new_one_to_one(p.PPI_CH2, button3.event_in(), led1.task_set());
ppi.enable();
let mut ppi = Ppi::new_one_to_two(p.PPI_CH3, button4.event_in(), led1.task_out(), led2.task_out());
ppi.enable();
info!("PPI setup!");
info!("Press button 1 to toggle LED 1");
info!("Press button 2 to turn on LED 1");
info!("Press button 3 to turn off LED 1");
info!("Press button 4 to toggle LEDs 1 and 2");
// Block forever so the above drivers don't get dropped
pending::<()>().await;
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::unwrap;
use embassy_executor::Spawner;
use embassy_sync::blocking_mutex::raw::ThreadModeRawMutex;
use embassy_sync::pubsub::{DynSubscriber, PubSubChannel, Subscriber};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
/// Create the message bus. It has a queue of 4, supports 3 subscribers and 1 publisher
static MESSAGE_BUS: PubSubChannel<ThreadModeRawMutex, Message, 4, 3, 1> = PubSubChannel::new();
#[derive(Clone, defmt::Format)]
enum Message {
A,
B,
C,
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let _p = embassy_nrf::init(Default::default());
defmt::info!("Hello World!");
// It's good to set up the subscribers before publishing anything.
// A subscriber will only yield messages that have been published after its creation.
spawner.must_spawn(fast_logger(unwrap!(MESSAGE_BUS.subscriber())));
spawner.must_spawn(slow_logger(unwrap!(MESSAGE_BUS.dyn_subscriber())));
spawner.must_spawn(slow_logger_pure(unwrap!(MESSAGE_BUS.dyn_subscriber())));
// Get a publisher
let message_publisher = unwrap!(MESSAGE_BUS.publisher());
// We can't get more (normal) publishers
// We can have an infinite amount of immediate publishers. They can't await a publish, only do an immediate publish
defmt::assert!(MESSAGE_BUS.publisher().is_err());
let mut index = 0;
loop {
Timer::after(Duration::from_millis(500)).await;
let message = match index % 3 {
0 => Message::A,
1 => Message::B,
2..=u32::MAX => Message::C,
};
// We publish immediately and don't await anything.
// If the queue is full, it will cause the oldest message to not be received by some/all subscribers
message_publisher.publish_immediate(message);
// Try to comment out the last one and uncomment this line below.
// The behaviour will change:
// - The subscribers won't miss any messages any more
// - Trying to publish now has some wait time when the queue is full
// message_publisher.publish(message).await;
index += 1;
}
}
/// A logger task that just awaits the messages it receives
///
/// This takes the generic `Subscriber`. This is most performant, but requires you to write down all of the generics
#[embassy_executor::task]
async fn fast_logger(mut messages: Subscriber<'static, ThreadModeRawMutex, Message, 4, 3, 1>) {
loop {
let message = messages.next_message().await;
defmt::info!("Received message at fast logger: {:?}", message);
}
}
/// A logger task that awaits the messages, but also does some other work.
/// Because of this, depending on how the messages were published, the subscriber might miss some messages.
///
/// This takes the dynamic `DynSubscriber`. This is not as performant as the generic version, but let's you ignore some of the generics.
#[embassy_executor::task]
async fn slow_logger(mut messages: DynSubscriber<'static, Message>) {
loop {
// Do some work
Timer::after(Duration::from_millis(2000)).await;
// If the publisher has used the `publish_immediate` function, then we may receive a lag message here
let message = messages.next_message().await;
defmt::info!("Received message at slow logger: {:?}", message);
// If the previous one was a lag message, then we should receive the next message here immediately
let message = messages.next_message().await;
defmt::info!("Received message at slow logger: {:?}", message);
}
}
/// Same as `slow_logger` but it ignores lag results
#[embassy_executor::task]
async fn slow_logger_pure(mut messages: DynSubscriber<'static, Message>) {
loop {
// Do some work
Timer::after(Duration::from_millis(2000)).await;
// Instead of receiving lags here, we just ignore that and read the next message
let message = messages.next_message_pure().await;
defmt::info!("Received message at slow logger pure: {:?}", message);
}
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::pwm::{Prescaler, SimplePwm};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
// for i in range(1024): print(int((math.sin(i/512*math.pi)*0.4+0.5)**2*32767), ', ', end='')
static DUTY: [u16; 1024] = [
8191, 8272, 8353, 8434, 8516, 8598, 8681, 8764, 8847, 8931, 9015, 9099, 9184, 9269, 9354, 9440, 9526, 9613, 9700,
9787, 9874, 9962, 10050, 10139, 10227, 10316, 10406, 10495, 10585, 10675, 10766, 10857, 10948, 11039, 11131, 11223,
11315, 11407, 11500, 11592, 11685, 11779, 11872, 11966, 12060, 12154, 12248, 12343, 12438, 12533, 12628, 12723,
12818, 12914, 13010, 13106, 13202, 13298, 13394, 13491, 13587, 13684, 13781, 13878, 13975, 14072, 14169, 14266,
14364, 14461, 14558, 14656, 14754, 14851, 14949, 15046, 15144, 15242, 15339, 15437, 15535, 15632, 15730, 15828,
15925, 16023, 16120, 16218, 16315, 16412, 16510, 16607, 16704, 16801, 16898, 16995, 17091, 17188, 17284, 17380,
17477, 17572, 17668, 17764, 17859, 17955, 18050, 18145, 18239, 18334, 18428, 18522, 18616, 18710, 18803, 18896,
18989, 19082, 19174, 19266, 19358, 19449, 19540, 19631, 19722, 19812, 19902, 19991, 20081, 20169, 20258, 20346,
20434, 20521, 20608, 20695, 20781, 20867, 20952, 21037, 21122, 21206, 21290, 21373, 21456, 21538, 21620, 21701,
21782, 21863, 21943, 22022, 22101, 22179, 22257, 22335, 22412, 22488, 22564, 22639, 22714, 22788, 22861, 22934,
23007, 23079, 23150, 23220, 23290, 23360, 23429, 23497, 23564, 23631, 23698, 23763, 23828, 23892, 23956, 24019,
24081, 24143, 24204, 24264, 24324, 24383, 24441, 24499, 24555, 24611, 24667, 24721, 24775, 24828, 24881, 24933,
24983, 25034, 25083, 25132, 25180, 25227, 25273, 25319, 25363, 25407, 25451, 25493, 25535, 25575, 25615, 25655,
25693, 25731, 25767, 25803, 25838, 25873, 25906, 25939, 25971, 26002, 26032, 26061, 26089, 26117, 26144, 26170,
26195, 26219, 26242, 26264, 26286, 26307, 26327, 26346, 26364, 26381, 26397, 26413, 26427, 26441, 26454, 26466,
26477, 26487, 26496, 26505, 26512, 26519, 26525, 26530, 26534, 26537, 26539, 26540, 26541, 26540, 26539, 26537,
26534, 26530, 26525, 26519, 26512, 26505, 26496, 26487, 26477, 26466, 26454, 26441, 26427, 26413, 26397, 26381,
26364, 26346, 26327, 26307, 26286, 26264, 26242, 26219, 26195, 26170, 26144, 26117, 26089, 26061, 26032, 26002,
25971, 25939, 25906, 25873, 25838, 25803, 25767, 25731, 25693, 25655, 25615, 25575, 25535, 25493, 25451, 25407,
25363, 25319, 25273, 25227, 25180, 25132, 25083, 25034, 24983, 24933, 24881, 24828, 24775, 24721, 24667, 24611,
24555, 24499, 24441, 24383, 24324, 24264, 24204, 24143, 24081, 24019, 23956, 23892, 23828, 23763, 23698, 23631,
23564, 23497, 23429, 23360, 23290, 23220, 23150, 23079, 23007, 22934, 22861, 22788, 22714, 22639, 22564, 22488,
22412, 22335, 22257, 22179, 22101, 22022, 21943, 21863, 21782, 21701, 21620, 21538, 21456, 21373, 21290, 21206,
21122, 21037, 20952, 20867, 20781, 20695, 20608, 20521, 20434, 20346, 20258, 20169, 20081, 19991, 19902, 19812,
19722, 19631, 19540, 19449, 19358, 19266, 19174, 19082, 18989, 18896, 18803, 18710, 18616, 18522, 18428, 18334,
18239, 18145, 18050, 17955, 17859, 17764, 17668, 17572, 17477, 17380, 17284, 17188, 17091, 16995, 16898, 16801,
16704, 16607, 16510, 16412, 16315, 16218, 16120, 16023, 15925, 15828, 15730, 15632, 15535, 15437, 15339, 15242,
15144, 15046, 14949, 14851, 14754, 14656, 14558, 14461, 14364, 14266, 14169, 14072, 13975, 13878, 13781, 13684,
13587, 13491, 13394, 13298, 13202, 13106, 13010, 12914, 12818, 12723, 12628, 12533, 12438, 12343, 12248, 12154,
12060, 11966, 11872, 11779, 11685, 11592, 11500, 11407, 11315, 11223, 11131, 11039, 10948, 10857, 10766, 10675,
10585, 10495, 10406, 10316, 10227, 10139, 10050, 9962, 9874, 9787, 9700, 9613, 9526, 9440, 9354, 9269, 9184, 9099,
9015, 8931, 8847, 8764, 8681, 8598, 8516, 8434, 8353, 8272, 8191, 8111, 8031, 7952, 7873, 7794, 7716, 7638, 7561,
7484, 7407, 7331, 7255, 7180, 7105, 7031, 6957, 6883, 6810, 6738, 6665, 6594, 6522, 6451, 6381, 6311, 6241, 6172,
6104, 6036, 5968, 5901, 5834, 5767, 5702, 5636, 5571, 5507, 5443, 5379, 5316, 5253, 5191, 5130, 5068, 5008, 4947,
4888, 4828, 4769, 4711, 4653, 4596, 4539, 4482, 4426, 4371, 4316, 4261, 4207, 4153, 4100, 4047, 3995, 3943, 3892,
3841, 3791, 3741, 3691, 3642, 3594, 3546, 3498, 3451, 3404, 3358, 3312, 3267, 3222, 3178, 3134, 3090, 3047, 3005,
2962, 2921, 2879, 2839, 2798, 2758, 2719, 2680, 2641, 2603, 2565, 2528, 2491, 2454, 2418, 2382, 2347, 2312, 2278,
2244, 2210, 2177, 2144, 2112, 2080, 2048, 2017, 1986, 1956, 1926, 1896, 1867, 1838, 1810, 1781, 1754, 1726, 1699,
1673, 1646, 1620, 1595, 1570, 1545, 1520, 1496, 1472, 1449, 1426, 1403, 1380, 1358, 1336, 1315, 1294, 1273, 1252,
1232, 1212, 1192, 1173, 1154, 1135, 1117, 1099, 1081, 1063, 1046, 1029, 1012, 996, 980, 964, 948, 933, 918, 903,
888, 874, 860, 846, 833, 819, 806, 793, 781, 768, 756, 744, 733, 721, 710, 699, 688, 677, 667, 657, 647, 637, 627,
618, 609, 599, 591, 582, 574, 565, 557, 549, 541, 534, 526, 519, 512, 505, 498, 492, 485, 479, 473, 467, 461, 455,
450, 444, 439, 434, 429, 424, 419, 415, 410, 406, 402, 398, 394, 390, 386, 383, 379, 376, 373, 370, 367, 364, 361,
359, 356, 354, 351, 349, 347, 345, 343, 342, 340, 338, 337, 336, 334, 333, 332, 331, 330, 330, 329, 328, 328, 328,
327, 327, 327, 327, 327, 328, 328, 328, 329, 330, 330, 331, 332, 333, 334, 336, 337, 338, 340, 342, 343, 345, 347,
349, 351, 354, 356, 359, 361, 364, 367, 370, 373, 376, 379, 383, 386, 390, 394, 398, 402, 406, 410, 415, 419, 424,
429, 434, 439, 444, 450, 455, 461, 467, 473, 479, 485, 492, 498, 505, 512, 519, 526, 534, 541, 549, 557, 565, 574,
582, 591, 599, 609, 618, 627, 637, 647, 657, 667, 677, 688, 699, 710, 721, 733, 744, 756, 768, 781, 793, 806, 819,
833, 846, 860, 874, 888, 903, 918, 933, 948, 964, 980, 996, 1012, 1029, 1046, 1063, 1081, 1099, 1117, 1135, 1154,
1173, 1192, 1212, 1232, 1252, 1273, 1294, 1315, 1336, 1358, 1380, 1403, 1426, 1449, 1472, 1496, 1520, 1545, 1570,
1595, 1620, 1646, 1673, 1699, 1726, 1754, 1781, 1810, 1838, 1867, 1896, 1926, 1956, 1986, 2017, 2048, 2080, 2112,
2144, 2177, 2210, 2244, 2278, 2312, 2347, 2382, 2418, 2454, 2491, 2528, 2565, 2603, 2641, 2680, 2719, 2758, 2798,
2839, 2879, 2921, 2962, 3005, 3047, 3090, 3134, 3178, 3222, 3267, 3312, 3358, 3404, 3451, 3498, 3546, 3594, 3642,
3691, 3741, 3791, 3841, 3892, 3943, 3995, 4047, 4100, 4153, 4207, 4261, 4316, 4371, 4426, 4482, 4539, 4596, 4653,
4711, 4769, 4828, 4888, 4947, 5008, 5068, 5130, 5191, 5253, 5316, 5379, 5443, 5507, 5571, 5636, 5702, 5767, 5834,
5901, 5968, 6036, 6104, 6172, 6241, 6311, 6381, 6451, 6522, 6594, 6665, 6738, 6810, 6883, 6957, 7031, 7105, 7180,
7255, 7331, 7407, 7484, 7561, 7638, 7716, 7794, 7873, 7952, 8031, 8111,
];
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut pwm = SimplePwm::new_4ch(p.PWM0, p.P0_13, p.P0_14, p.P0_16, p.P0_15);
pwm.set_prescaler(Prescaler::Div1);
pwm.set_max_duty(32767);
info!("pwm initialized!");
let mut i = 0;
loop {
i += 1;
pwm.set_duty(0, DUTY[i % 1024]);
pwm.set_duty(1, DUTY[(i + 256) % 1024]);
pwm.set_duty(2, DUTY[(i + 512) % 1024]);
pwm.set_duty(3, DUTY[(i + 768) % 1024]);
Timer::after(Duration::from_millis(3)).await;
}
}

41
examples/nrf52840/src/bin/pwm_double_sequence.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::pwm::{
Config, Prescaler, Sequence, SequenceConfig, SequenceMode, SequencePwm, Sequencer, StartSequence,
};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
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_1ch(p.PWM0, p.P0_13, 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!");
}

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examples/nrf52840/src/bin/pwm_sequence.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::pwm::{Config, Prescaler, SequenceConfig, SequencePwm, SingleSequenceMode, SingleSequencer};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let seq_words: [u16; 5] = [1000, 250, 100, 50, 0];
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_1ch(p.PWM0, p.P0_13, config,));
let sequencer = SingleSequencer::new(&mut pwm, &seq_words, seq_config);
unwrap!(sequencer.start(SingleSequenceMode::Times(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(20000)).await;
info!("pwm stopped early!");
}

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examples/nrf52840/src/bin/pwm_sequence_ppi.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::future::pending;
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::gpio::{Input, Pull};
use embassy_nrf::gpiote::{InputChannel, InputChannelPolarity};
use embassy_nrf::ppi::Ppi;
use embassy_nrf::pwm::{Config, Prescaler, SequenceConfig, SequencePwm, SingleSequenceMode, SingleSequencer};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let seq_words: [u16; 5] = [1000, 250, 100, 50, 0];
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
let mut seq_config = SequenceConfig::default();
seq_config.refresh = 30;
let mut pwm = unwrap!(SequencePwm::new_1ch(p.PWM0, p.P0_13, config));
// 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
let button1 = InputChannel::new(
p.GPIOTE_CH0,
Input::new(p.P0_11, Pull::Up),
InputChannelPolarity::HiToLo,
);
let button2 = InputChannel::new(
p.GPIOTE_CH1,
Input::new(p.P0_12, Pull::Up),
InputChannelPolarity::HiToLo,
);
// messing with the pwm tasks is ill advised
// Times::Ininite and Times even are seq0, Times odd is seq1
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();
let mut ppi2 = Ppi::new_one_to_one(p.PPI_CH0, button2.event_in(), stop);
ppi2.enable();
info!("PPI setup!");
info!("Press button 1 to start LED 1");
info!("Press button 2 to stop LED 1");
info!("Note! task_stop stops the sequence, but not the pin output");
// Block forever so the above drivers don't get dropped
pending::<()>().await;
}

75
examples/nrf52840/src/bin/pwm_sequence_ws2812b.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::pwm::{
Config, Prescaler, SequenceConfig, SequenceLoad, SequencePwm, SingleSequenceMode, SingleSequencer,
};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
// 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_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
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_1ch(p.PWM0, p.P1_05, 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;
}
}

47
examples/nrf52840/src/bin/pwm_servo.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::pwm::{Prescaler, SimplePwm};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut pwm = SimplePwm::new_1ch(p.PWM0, p.P0_05);
// sg90 microervo requires 50hz or 20ms period
// set_period can only set down to 125khz so we cant use it directly
// Div128 is 125khz or 0.000008s or 0.008ms, 20/0.008 is 2500 is top
pwm.set_prescaler(Prescaler::Div128);
pwm.set_max_duty(2500);
info!("pwm initialized!");
Timer::after(Duration::from_millis(5000)).await;
// 1ms 0deg (1/.008=125), 1.5ms 90deg (1.5/.008=187.5), 2ms 180deg (2/.008=250),
loop {
info!("45 deg");
// poor mans inverting, subtract our value from max_duty
pwm.set_duty(0, 2500 - 156);
Timer::after(Duration::from_millis(5000)).await;
info!("90 deg");
pwm.set_duty(0, 2500 - 187);
Timer::after(Duration::from_millis(5000)).await;
info!("135 deg");
pwm.set_duty(0, 2500 - 218);
Timer::after(Duration::from_millis(5000)).await;
info!("180 deg");
pwm.set_duty(0, 2500 - 250);
Timer::after(Duration::from_millis(5000)).await;
info!("0 deg");
pwm.set_duty(0, 2500 - 125);
Timer::after(Duration::from_millis(5000)).await;
}
}

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examples/nrf52840/src/bin/qdec.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::info;
use embassy_executor::Spawner;
use embassy_nrf::qdec::{self, Qdec};
use embassy_nrf::{bind_interrupts, peripherals};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
QDEC => qdec::InterruptHandler<peripherals::QDEC>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let config = qdec::Config::default();
let mut rotary_enc = Qdec::new(p.QDEC, Irqs, p.P0_31, p.P0_30, config);
info!("Turn rotary encoder!");
let mut value = 0;
loop {
value += rotary_enc.read().await;
info!("Value: {}", value);
}
}

82
examples/nrf52840/src/bin/qspi.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{assert_eq, info, unwrap};
use embassy_executor::Spawner;
use embassy_nrf::qspi::Frequency;
use embassy_nrf::{bind_interrupts, peripherals, qspi};
use {defmt_rtt as _, panic_probe as _};
const PAGE_SIZE: usize = 4096;
// Workaround for alignment requirements.
// Nicer API will probably come in the future.
#[repr(C, align(4))]
struct AlignedBuf([u8; 4096]);
bind_interrupts!(struct Irqs {
QSPI => qspi::InterruptHandler<peripherals::QSPI>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
// Config for the MX25R64 present in the nRF52840 DK
let mut config = qspi::Config::default();
config.capacity = 8 * 1024 * 1024; // 8 MB
config.frequency = Frequency::M32;
config.read_opcode = qspi::ReadOpcode::READ4IO;
config.write_opcode = qspi::WriteOpcode::PP4IO;
config.write_page_size = qspi::WritePageSize::_256BYTES;
let mut q = qspi::Qspi::new(
p.QSPI, Irqs, p.P0_19, p.P0_17, p.P0_20, p.P0_21, p.P0_22, p.P0_23, config,
);
let mut id = [1; 3];
unwrap!(q.custom_instruction(0x9F, &[], &mut id).await);
info!("id: {}", id);
// Read status register
let mut status = [4; 1];
unwrap!(q.custom_instruction(0x05, &[], &mut status).await);
info!("status: {:?}", status[0]);
if status[0] & 0x40 == 0 {
status[0] |= 0x40;
unwrap!(q.custom_instruction(0x01, &status, &mut []).await);
info!("enabled quad in status");
}
let mut buf = AlignedBuf([0u8; PAGE_SIZE]);
let pattern = |a: u32| (a ^ (a >> 8) ^ (a >> 16) ^ (a >> 24)) as u8;
for i in 0..8 {
info!("page {:?}: erasing... ", i);
unwrap!(q.erase(i * PAGE_SIZE as u32).await);
for j in 0..PAGE_SIZE {
buf.0[j] = pattern((j as u32 + i * PAGE_SIZE as u32) as u32);
}
info!("programming...");
unwrap!(q.write(i * PAGE_SIZE as u32, &buf.0).await);
}
for i in 0..8 {
info!("page {:?}: reading... ", i);
unwrap!(q.read(i * PAGE_SIZE as u32, &mut buf.0).await);
info!("verifying...");
for j in 0..PAGE_SIZE {
assert_eq!(buf.0[j], pattern((j as u32 + i * PAGE_SIZE as u32) as u32));
}
}
info!("done!")
}

84
examples/nrf52840/src/bin/qspi_lowpower.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::mem;
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_nrf::qspi::Frequency;
use embassy_nrf::{bind_interrupts, peripherals, qspi};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
// Workaround for alignment requirements.
// Nicer API will probably come in the future.
#[repr(C, align(4))]
struct AlignedBuf([u8; 64]);
bind_interrupts!(struct Irqs {
QSPI => qspi::InterruptHandler<peripherals::QSPI>;
});
#[embassy_executor::main]
async fn main(_p: Spawner) {
let mut p = embassy_nrf::init(Default::default());
loop {
// Config for the MX25R64 present in the nRF52840 DK
let mut config = qspi::Config::default();
config.capacity = 8 * 1024 * 1024; // 8 MB
config.frequency = Frequency::M32;
config.read_opcode = qspi::ReadOpcode::READ4IO;
config.write_opcode = qspi::WriteOpcode::PP4IO;
config.write_page_size = qspi::WritePageSize::_256BYTES;
config.deep_power_down = Some(qspi::DeepPowerDownConfig {
enter_time: 3, // tDP = 30uS
exit_time: 3, // tRDP = 35uS
});
let mut q = qspi::Qspi::new(
&mut p.QSPI,
Irqs,
&mut p.P0_19,
&mut p.P0_17,
&mut p.P0_20,
&mut p.P0_21,
&mut p.P0_22,
&mut p.P0_23,
config,
);
let mut id = [1; 3];
unwrap!(q.custom_instruction(0x9F, &[], &mut id).await);
info!("id: {}", id);
// Read status register
let mut status = [4; 1];
unwrap!(q.custom_instruction(0x05, &[], &mut status).await);
info!("status: {:?}", status[0]);
if status[0] & 0x40 == 0 {
status[0] |= 0x40;
unwrap!(q.custom_instruction(0x01, &status, &mut []).await);
info!("enabled quad in status");
}
let mut buf = AlignedBuf([0u8; 64]);
info!("reading...");
unwrap!(q.read(0, &mut buf.0).await);
info!("read: {=[u8]:x}", buf.0);
// Drop the QSPI instance. This disables the peripehral and deconfigures the pins.
// This clears the borrow on the singletons, so they can now be used again.
mem::drop(q);
// Sleep for 1 second. The executor ensures the core sleeps with a WFE when it has nothing to do.
// During this sleep, the nRF chip should only use ~3uA
Timer::after(Duration::from_secs(1)).await;
}
}

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examples/nrf52840/src/bin/raw_spawn.rs Normal file
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#![no_std]
#![no_main]
use core::mem;
use cortex_m_rt::entry;
use defmt::{info, unwrap};
use embassy_executor::raw::TaskStorage;
use embassy_executor::Executor;
use embassy_time::{Duration, Timer};
use static_cell::StaticCell;
use {defmt_rtt as _, panic_probe as _};
async fn run1() {
loop {
info!("BIG INFREQUENT TICK");
Timer::after(Duration::from_ticks(64000)).await;
}
}
async fn run2() {
loop {
info!("tick");
Timer::after(Duration::from_ticks(13000)).await;
}
}
static EXECUTOR: StaticCell<Executor> = StaticCell::new();
#[entry]
fn main() -> ! {
info!("Hello World!");
let _p = embassy_nrf::init(Default::default());
let executor = EXECUTOR.init(Executor::new());
let run1_task = TaskStorage::new();
let run2_task = TaskStorage::new();
// Safety: these variables do live forever if main never returns.
let run1_task = unsafe { make_static(&run1_task) };
let run2_task = unsafe { make_static(&run2_task) };
executor.run(|spawner| {
unwrap!(spawner.spawn(run1_task.spawn(|| run1())));
unwrap!(spawner.spawn(run2_task.spawn(|| run2())));
});
}
unsafe fn make_static<T>(t: &T) -> &'static T {
mem::transmute(t)
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use embassy_executor::Spawner;
use embassy_nrf::rng::Rng;
use embassy_nrf::{bind_interrupts, peripherals, rng};
use rand::Rng as _;
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
RNG => rng::InterruptHandler<peripherals::RNG>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut rng = Rng::new(p.RNG, Irqs);
// Async API
let mut bytes = [0; 4];
rng.fill_bytes(&mut bytes).await;
defmt::info!("Some random bytes: {:?}", bytes);
// Sync API with `rand`
defmt::info!("A random number from 1 to 10: {:?}", rng.gen_range(1..=10));
let mut bytes = [0; 1024];
rng.fill_bytes(&mut bytes).await;
let zero_count: u32 = bytes.iter().fold(0, |acc, val| acc + val.count_zeros());
let one_count: u32 = bytes.iter().fold(0, |acc, val| acc + val.count_ones());
defmt::info!("Chance of zero: {}%", zero_count * 100 / (bytes.len() as u32 * 8));
defmt::info!("Chance of one: {}%", one_count * 100 / (bytes.len() as u32 * 8));
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::info;
use embassy_executor::Spawner;
use embassy_nrf::saadc::{ChannelConfig, Config, Saadc};
use embassy_nrf::{bind_interrupts, saadc};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
SAADC => saadc::InterruptHandler;
});
#[embassy_executor::main]
async fn main(_p: Spawner) {
let mut p = embassy_nrf::init(Default::default());
let config = Config::default();
let channel_config = ChannelConfig::single_ended(&mut p.P0_02);
let mut saadc = Saadc::new(p.SAADC, Irqs, config, [channel_config]);
loop {
let mut buf = [0; 1];
saadc.sample(&mut buf).await;
info!("sample: {=i16}", &buf[0]);
Timer::after(Duration::from_millis(100)).await;
}
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::info;
use embassy_executor::Spawner;
use embassy_nrf::saadc::{CallbackResult, ChannelConfig, Config, Saadc};
use embassy_nrf::timer::Frequency;
use embassy_nrf::{bind_interrupts, saadc};
use embassy_time::Duration;
use {defmt_rtt as _, panic_probe as _};
// Demonstrates both continuous sampling and scanning multiple channels driven by a PPI linked timer
bind_interrupts!(struct Irqs {
SAADC => saadc::InterruptHandler;
});
#[embassy_executor::main]
async fn main(_p: Spawner) {
let mut p = embassy_nrf::init(Default::default());
let config = Config::default();
let channel_1_config = ChannelConfig::single_ended(&mut p.P0_02);
let channel_2_config = ChannelConfig::single_ended(&mut p.P0_03);
let channel_3_config = ChannelConfig::single_ended(&mut p.P0_04);
let mut saadc = Saadc::new(
p.SAADC,
Irqs,
config,
[channel_1_config, channel_2_config, channel_3_config],
);
// This delay demonstrates that starting the timer prior to running
// the task sampler is benign given the calibration that follows.
embassy_time::Timer::after(Duration::from_millis(500)).await;
saadc.calibrate().await;
let mut bufs = [[[0; 3]; 500]; 2];
let mut c = 0;
let mut a: i32 = 0;
saadc
.run_task_sampler(
&mut p.TIMER0,
&mut p.PPI_CH0,
&mut p.PPI_CH1,
Frequency::F1MHz,
1000, // We want to sample at 1KHz
&mut bufs,
move |buf| {
// NOTE: It is important that the time spent within this callback
// does not exceed the time taken to acquire the 1500 samples we
// have in this example, which would be 10us + 2us per
// sample * 1500 = 18ms. You need to measure the time taken here
// and set the sample buffer size accordingly. Exceeding this
// time can lead to the peripheral re-writing the other buffer.
for b in buf {
a += b[0] as i32;
}
c += buf.len();
if c > 1000 {
a = a / c as i32;
info!("channel 1: {=i32}", a);
c = 0;
a = 0;
}
CallbackResult::Continue
},
)
.await;
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
mod config {
pub const MY_TASK_POOL_SIZE: usize = 2;
}
#[embassy_executor::task(pool_size = config::MY_TASK_POOL_SIZE)]
async fn my_task(spawner: Spawner, n: u32) {
Timer::after(Duration::from_secs(1)).await;
info!("Spawning self! {}", n);
unwrap!(spawner.spawn(my_task(spawner, n + 1)));
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let _p = embassy_nrf::init(Default::default());
info!("Hello World!");
unwrap!(spawner.spawn(my_task(spawner, 0)));
}

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examples/nrf52840/src/bin/self_spawn_current_executor.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::task(pool_size = 2)]
async fn my_task(n: u32) {
Timer::after(Duration::from_secs(1)).await;
info!("Spawning self! {}", n);
unwrap!(Spawner::for_current_executor().await.spawn(my_task(n + 1)));
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let _p = embassy_nrf::init(Default::default());
info!("Hello World!");
unwrap!(spawner.spawn(my_task(0)));
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_nrf::gpio::{Level, Output, OutputDrive};
use embassy_nrf::{bind_interrupts, peripherals, spim};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
SPIM3 => spim::InterruptHandler<peripherals::SPI3>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
info!("running!");
let mut config = spim::Config::default();
config.frequency = spim::Frequency::M16;
let mut spim = spim::Spim::new(p.SPI3, Irqs, p.P0_29, p.P0_28, p.P0_30, config);
let mut ncs = Output::new(p.P0_31, Level::High, OutputDrive::Standard);
// Example on how to talk to an ENC28J60 chip
// softreset
cortex_m::asm::delay(10);
ncs.set_low();
cortex_m::asm::delay(5);
let tx = [0xFF];
unwrap!(spim.transfer(&mut [], &tx).await);
cortex_m::asm::delay(10);
ncs.set_high();
cortex_m::asm::delay(100000);
let mut rx = [0; 2];
// read ESTAT
cortex_m::asm::delay(5000);
ncs.set_low();
cortex_m::asm::delay(5000);
let tx = [0b000_11101, 0];
unwrap!(spim.transfer(&mut rx, &tx).await);
cortex_m::asm::delay(5000);
ncs.set_high();
info!("estat: {=[?]}", rx);
// Switch to bank 3
cortex_m::asm::delay(10);
ncs.set_low();
cortex_m::asm::delay(5);
let tx = [0b100_11111, 0b11];
unwrap!(spim.transfer(&mut rx, &tx).await);
cortex_m::asm::delay(10);
ncs.set_high();
// read EREVID
cortex_m::asm::delay(10);
ncs.set_low();
cortex_m::asm::delay(5);
let tx = [0b000_10010, 0];
unwrap!(spim.transfer(&mut rx, &tx).await);
cortex_m::asm::delay(10);
ncs.set_high();
info!("erevid: {=[?]}", rx);
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::info;
use embassy_executor::Spawner;
use embassy_nrf::spis::{Config, Spis};
use embassy_nrf::{bind_interrupts, peripherals, spis};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
SPIM2_SPIS2_SPI2 => spis::InterruptHandler<peripherals::SPI2>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
info!("Running!");
let mut spis = Spis::new(p.SPI2, Irqs, p.P0_31, p.P0_29, p.P0_28, p.P0_30, Config::default());
loop {
let mut rx_buf = [0_u8; 64];
let tx_buf = [1_u8, 2, 3, 4, 5, 6, 7, 8];
if let Ok((n_rx, n_tx)) = spis.transfer(&mut rx_buf, &tx_buf).await {
info!("RX: {:?}", rx_buf[..n_rx]);
info!("TX: {:?}", tx_buf[..n_tx]);
}
}
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::info;
use embassy_executor::Spawner;
use embassy_nrf::temp::Temp;
use embassy_nrf::{bind_interrupts, temp};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
TEMP => temp::InterruptHandler;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut temp = Temp::new(p.TEMP, Irqs);
loop {
let value = temp.read().await;
info!("temperature: {}℃", value.to_num::<u16>());
Timer::after(Duration::from_secs(1)).await;
}
}

31
examples/nrf52840/src/bin/timer.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{info, unwrap};
use embassy_executor::Spawner;
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::task]
async fn run1() {
loop {
info!("BIG INFREQUENT TICK");
Timer::after(Duration::from_ticks(64000)).await;
}
}
#[embassy_executor::task]
async fn run2() {
loop {
info!("tick");
Timer::after(Duration::from_ticks(13000)).await;
}
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let _p = embassy_nrf::init(Default::default());
unwrap!(spawner.spawn(run1()));
unwrap!(spawner.spawn(run2()));
}

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examples/nrf52840/src/bin/twim.rs Normal file
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//! Example on how to read a 24C/24LC i2c eeprom.
//!
//! Connect SDA to P0.03, SCL to P0.04
#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::twim::{self, Twim};
use embassy_nrf::{bind_interrupts, peripherals};
use {defmt_rtt as _, panic_probe as _};
const ADDRESS: u8 = 0x50;
bind_interrupts!(struct Irqs {
SPIM0_SPIS0_TWIM0_TWIS0_SPI0_TWI0 => twim::InterruptHandler<peripherals::TWISPI0>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
info!("Initializing TWI...");
let config = twim::Config::default();
let mut twi = Twim::new(p.TWISPI0, Irqs, p.P0_03, p.P0_04, config);
info!("Reading...");
let mut buf = [0u8; 16];
unwrap!(twi.blocking_write_read(ADDRESS, &mut [0x00], &mut buf));
info!("Read: {=[u8]:x}", buf);
}

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//! Example on how to read a 24C/24LC i2c eeprom with low power consumption.
//! The eeprom is read every 1 second, while ensuring lowest possible power while
//! sleeping between reads.
//!
//! Connect SDA to P0.03, SCL to P0.04
#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::mem;
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::twim::{self, Twim};
use embassy_nrf::{bind_interrupts, peripherals};
use embassy_time::{Duration, Timer};
use {defmt_rtt as _, panic_probe as _};
const ADDRESS: u8 = 0x50;
bind_interrupts!(struct Irqs {
SPIM0_SPIS0_TWIM0_TWIS0_SPI0_TWI0 => twim::InterruptHandler<peripherals::TWISPI0>;
});
#[embassy_executor::main]
async fn main(_p: Spawner) {
let mut p = embassy_nrf::init(Default::default());
info!("Started!");
loop {
info!("Initializing TWI...");
let config = twim::Config::default();
// Create the TWIM instance with borrowed singletons, so they're not consumed.
let mut twi = Twim::new(&mut p.TWISPI0, Irqs, &mut p.P0_03, &mut p.P0_04, config);
info!("Reading...");
let mut buf = [0u8; 16];
unwrap!(twi.blocking_write_read(ADDRESS, &mut [0x00], &mut buf));
info!("Read: {=[u8]:x}", buf);
// Drop the TWIM instance. This disables the peripehral and deconfigures the pins.
// This clears the borrow on the singletons, so they can now be used again.
mem::drop(twi);
// Sleep for 1 second. The executor ensures the core sleeps with a WFE when it has nothing to do.
// During this sleep, the nRF chip should only use ~3uA
Timer::after(Duration::from_secs(1)).await;
}
}

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//! TWIS example
#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::twis::{self, Command, Twis};
use embassy_nrf::{bind_interrupts, peripherals};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
SPIM0_SPIS0_TWIM0_TWIS0_SPI0_TWI0 => twis::InterruptHandler<peripherals::TWISPI0>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut config = twis::Config::default();
config.address0 = 0x55; // Set i2c address
let mut i2c = Twis::new(p.TWISPI0, Irqs, p.P0_03, p.P0_04, config);
info!("Listening...");
loop {
let response = [1, 2, 3, 4, 5, 6, 7, 8];
// This buffer is used if the i2c master performs a Write or WriteRead
let mut buf = [0u8; 16];
match i2c.listen(&mut buf).await {
Ok(Command::Read) => {
info!("Got READ command. Respond with data:\n{:?}\n", response);
if let Err(e) = i2c.respond_to_read(&response).await {
error!("{:?}", e);
}
}
Ok(Command::Write(n)) => info!("Got WRITE command with data:\n{:?}\n", buf[..n]),
Ok(Command::WriteRead(n)) => {
info!("Got WRITE/READ command with data:\n{:?}", buf[..n]);
info!("Respond with data:\n{:?}\n", response);
if let Err(e) = i2c.respond_to_read(&response).await {
error!("{:?}", e);
}
}
Err(e) => error!("{:?}", e),
}
}
}

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examples/nrf52840/src/bin/uart.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::{bind_interrupts, peripherals, uarte};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
UARTE0_UART0 => uarte::InterruptHandler<peripherals::UARTE0>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut config = uarte::Config::default();
config.parity = uarte::Parity::EXCLUDED;
config.baudrate = uarte::Baudrate::BAUD115200;
let mut uart = uarte::Uarte::new(p.UARTE0, Irqs, p.P0_08, p.P0_06, config);
info!("uarte initialized!");
// Message must be in SRAM
let mut buf = [0; 8];
buf.copy_from_slice(b"Hello!\r\n");
unwrap!(uart.write(&buf).await);
info!("wrote hello in uart!");
loop {
info!("reading...");
unwrap!(uart.read(&mut buf).await);
info!("writing...");
unwrap!(uart.write(&buf).await);
}
}

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examples/nrf52840/src/bin/uart_idle.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::peripherals::UARTE0;
use embassy_nrf::{bind_interrupts, uarte};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
UARTE0_UART0 => uarte::InterruptHandler<UARTE0>;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut config = uarte::Config::default();
config.parity = uarte::Parity::EXCLUDED;
config.baudrate = uarte::Baudrate::BAUD115200;
let uart = uarte::Uarte::new(p.UARTE0, Irqs, p.P0_08, p.P0_06, config);
let (mut tx, mut rx) = uart.split_with_idle(p.TIMER0, p.PPI_CH0, p.PPI_CH1);
info!("uarte initialized!");
// Message must be in SRAM
let mut buf = [0; 8];
buf.copy_from_slice(b"Hello!\r\n");
unwrap!(tx.write(&buf).await);
info!("wrote hello in uart!");
loop {
info!("reading...");
let n = unwrap!(rx.read_until_idle(&mut buf).await);
info!("got {} bytes", n);
}
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::peripherals::UARTE0;
use embassy_nrf::uarte::UarteRx;
use embassy_nrf::{bind_interrupts, uarte};
use embassy_sync::blocking_mutex::raw::ThreadModeRawMutex;
use embassy_sync::channel::Channel;
use {defmt_rtt as _, panic_probe as _};
static CHANNEL: Channel<ThreadModeRawMutex, [u8; 8], 1> = Channel::new();
bind_interrupts!(struct Irqs {
UARTE0_UART0 => uarte::InterruptHandler<UARTE0>;
});
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let mut config = uarte::Config::default();
config.parity = uarte::Parity::EXCLUDED;
config.baudrate = uarte::Baudrate::BAUD115200;
let uart = uarte::Uarte::new(p.UARTE0, Irqs, p.P0_08, p.P0_06, config);
let (mut tx, rx) = uart.split();
info!("uarte initialized!");
// Spawn a task responsible purely for reading
unwrap!(spawner.spawn(reader(rx)));
// Message must be in SRAM
{
let mut buf = [0; 23];
buf.copy_from_slice(b"Type 8 chars to echo!\r\n");
unwrap!(tx.write(&buf).await);
info!("wrote hello in uart!");
}
// Continue reading in this main task and write
// back out the buffer we receive from the read
// task.
loop {
let buf = CHANNEL.recv().await;
info!("writing...");
unwrap!(tx.write(&buf).await);
}
}
#[embassy_executor::task]
async fn reader(mut rx: UarteRx<'static, UARTE0>) {
let mut buf = [0; 8];
loop {
info!("reading...");
unwrap!(rx.read(&mut buf).await);
CHANNEL.send(buf).await;
}
}

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examples/nrf52840/src/bin/usb_ethernet.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::mem;
use defmt::*;
use embassy_executor::Spawner;
use embassy_net::tcp::TcpSocket;
use embassy_net::{Stack, StackResources};
use embassy_nrf::rng::Rng;
use embassy_nrf::usb::vbus_detect::HardwareVbusDetect;
use embassy_nrf::usb::Driver;
use embassy_nrf::{bind_interrupts, pac, peripherals, rng, usb};
use embassy_usb::class::cdc_ncm::embassy_net::{Device, Runner, State as NetState};
use embassy_usb::class::cdc_ncm::{CdcNcmClass, State};
use embassy_usb::{Builder, Config, UsbDevice};
use embedded_io::asynch::Write;
use static_cell::make_static;
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
USBD => usb::InterruptHandler<peripherals::USBD>;
POWER_CLOCK => usb::vbus_detect::InterruptHandler;
RNG => rng::InterruptHandler<peripherals::RNG>;
});
type MyDriver = Driver<'static, peripherals::USBD, HardwareVbusDetect>;
const MTU: usize = 1514;
#[embassy_executor::task]
async fn usb_task(mut device: UsbDevice<'static, MyDriver>) -> ! {
device.run().await
}
#[embassy_executor::task]
async fn usb_ncm_task(class: Runner<'static, MyDriver, MTU>) -> ! {
class.run().await
}
#[embassy_executor::task]
async fn net_task(stack: &'static Stack<Device<'static, MTU>>) -> ! {
stack.run().await
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let clock: pac::CLOCK = unsafe { mem::transmute(()) };
info!("Enabling ext hfosc...");
clock.tasks_hfclkstart.write(|w| unsafe { w.bits(1) });
while clock.events_hfclkstarted.read().bits() != 1 {}
// Create the driver, from the HAL.
let driver = Driver::new(p.USBD, Irqs, HardwareVbusDetect::new(Irqs));
// Create embassy-usb Config
let mut config = Config::new(0xc0de, 0xcafe);
config.manufacturer = Some("Embassy");
config.product = Some("USB-Ethernet example");
config.serial_number = Some("12345678");
config.max_power = 100;
config.max_packet_size_0 = 64;
// Required for Windows support.
config.composite_with_iads = true;
config.device_class = 0xEF;
config.device_sub_class = 0x02;
config.device_protocol = 0x01;
// Create embassy-usb DeviceBuilder using the driver and config.
let mut builder = Builder::new(
driver,
config,
&mut make_static!([0; 256])[..],
&mut make_static!([0; 256])[..],
&mut make_static!([0; 256])[..],
&mut make_static!([0; 128])[..],
&mut make_static!([0; 128])[..],
);
// Our MAC addr.
let our_mac_addr = [0xCC, 0xCC, 0xCC, 0xCC, 0xCC, 0xCC];
// Host's MAC addr. This is the MAC the host "thinks" its USB-to-ethernet adapter has.
let host_mac_addr = [0x88, 0x88, 0x88, 0x88, 0x88, 0x88];
// Create classes on the builder.
let class = CdcNcmClass::new(&mut builder, make_static!(State::new()), host_mac_addr, 64);
// Build the builder.
let usb = builder.build();
unwrap!(spawner.spawn(usb_task(usb)));
let (runner, device) = class.into_embassy_net_device::<MTU, 4, 4>(make_static!(NetState::new()), our_mac_addr);
unwrap!(spawner.spawn(usb_ncm_task(runner)));
let config = embassy_net::Config::dhcpv4(Default::default());
// let config = embassy_net::Config::ipv4_static(embassy_net::StaticConfigV4 {
// address: Ipv4Cidr::new(Ipv4Address::new(10, 42, 0, 61), 24),
// dns_servers: Vec::new(),
// gateway: Some(Ipv4Address::new(10, 42, 0, 1)),
// });
// Generate random seed
let mut rng = Rng::new(p.RNG, Irqs);
let mut seed = [0; 8];
rng.blocking_fill_bytes(&mut seed);
let seed = u64::from_le_bytes(seed);
// Init network stack
let stack = &*make_static!(Stack::new(
device,
config,
make_static!(StackResources::<2>::new()),
seed
));
unwrap!(spawner.spawn(net_task(stack)));
// And now we can use it!
let mut rx_buffer = [0; 4096];
let mut tx_buffer = [0; 4096];
let mut buf = [0; 4096];
loop {
let mut socket = TcpSocket::new(stack, &mut rx_buffer, &mut tx_buffer);
socket.set_timeout(Some(embassy_time::Duration::from_secs(10)));
info!("Listening on TCP:1234...");
if let Err(e) = socket.accept(1234).await {
warn!("accept error: {:?}", e);
continue;
}
info!("Received connection from {:?}", socket.remote_endpoint());
loop {
let n = match socket.read(&mut buf).await {
Ok(0) => {
warn!("read EOF");
break;
}
Ok(n) => n,
Err(e) => {
warn!("read error: {:?}", e);
break;
}
};
info!("rxd {:02x}", &buf[..n]);
match socket.write_all(&buf[..n]).await {
Ok(()) => {}
Err(e) => {
warn!("write error: {:?}", e);
break;
}
};
}
}
}

229
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::mem;
use core::sync::atomic::{AtomicBool, Ordering};
use defmt::*;
use embassy_executor::Spawner;
use embassy_futures::join::join;
use embassy_futures::select::{select, Either};
use embassy_nrf::gpio::{Input, Pin, Pull};
use embassy_nrf::usb::vbus_detect::HardwareVbusDetect;
use embassy_nrf::usb::Driver;
use embassy_nrf::{bind_interrupts, pac, peripherals, usb};
use embassy_sync::blocking_mutex::raw::CriticalSectionRawMutex;
use embassy_sync::signal::Signal;
use embassy_usb::class::hid::{HidReaderWriter, ReportId, RequestHandler, State};
use embassy_usb::control::OutResponse;
use embassy_usb::{Builder, Config, Handler};
use usbd_hid::descriptor::{KeyboardReport, SerializedDescriptor};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
USBD => usb::InterruptHandler<peripherals::USBD>;
POWER_CLOCK => usb::vbus_detect::InterruptHandler;
});
static SUSPENDED: AtomicBool = AtomicBool::new(false);
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let clock: pac::CLOCK = unsafe { mem::transmute(()) };
info!("Enabling ext hfosc...");
clock.tasks_hfclkstart.write(|w| unsafe { w.bits(1) });
while clock.events_hfclkstarted.read().bits() != 1 {}
// Create the driver, from the HAL.
let driver = Driver::new(p.USBD, Irqs, HardwareVbusDetect::new(Irqs));
// Create embassy-usb Config
let mut config = Config::new(0xc0de, 0xcafe);
config.manufacturer = Some("Embassy");
config.product = Some("HID keyboard example");
config.serial_number = Some("12345678");
config.max_power = 100;
config.max_packet_size_0 = 64;
config.supports_remote_wakeup = true;
// Create embassy-usb DeviceBuilder using the driver and config.
// It needs some buffers for building the descriptors.
let mut device_descriptor = [0; 256];
let mut config_descriptor = [0; 256];
let mut bos_descriptor = [0; 256];
let mut msos_descriptor = [0; 256];
let mut control_buf = [0; 64];
let request_handler = MyRequestHandler {};
let mut device_handler = MyDeviceHandler::new();
let mut state = State::new();
let mut builder = Builder::new(
driver,
config,
&mut device_descriptor,
&mut config_descriptor,
&mut bos_descriptor,
&mut msos_descriptor,
&mut control_buf,
);
builder.handler(&mut device_handler);
// Create classes on the builder.
let config = embassy_usb::class::hid::Config {
report_descriptor: KeyboardReport::desc(),
request_handler: Some(&request_handler),
poll_ms: 60,
max_packet_size: 64,
};
let hid = HidReaderWriter::<_, 1, 8>::new(&mut builder, &mut state, config);
// Build the builder.
let mut usb = builder.build();
let remote_wakeup: Signal<CriticalSectionRawMutex, _> = Signal::new();
// Run the USB device.
let usb_fut = async {
loop {
usb.run_until_suspend().await;
match select(usb.wait_resume(), remote_wakeup.wait()).await {
Either::First(_) => (),
Either::Second(_) => unwrap!(usb.remote_wakeup().await),
}
}
};
let mut button = Input::new(p.P0_11.degrade(), Pull::Up);
let (reader, mut writer) = hid.split();
// Do stuff with the class!
let in_fut = async {
loop {
button.wait_for_low().await;
info!("PRESSED");
if SUSPENDED.load(Ordering::Acquire) {
info!("Triggering remote wakeup");
remote_wakeup.signal(());
} else {
let report = KeyboardReport {
keycodes: [4, 0, 0, 0, 0, 0],
leds: 0,
modifier: 0,
reserved: 0,
};
match writer.write_serialize(&report).await {
Ok(()) => {}
Err(e) => warn!("Failed to send report: {:?}", e),
};
}
button.wait_for_high().await;
info!("RELEASED");
let report = KeyboardReport {
keycodes: [0, 0, 0, 0, 0, 0],
leds: 0,
modifier: 0,
reserved: 0,
};
match writer.write_serialize(&report).await {
Ok(()) => {}
Err(e) => warn!("Failed to send report: {:?}", e),
};
}
};
let out_fut = async {
reader.run(false, &request_handler).await;
};
// Run everything concurrently.
// If we had made everything `'static` above instead, we could do this using separate tasks instead.
join(usb_fut, join(in_fut, out_fut)).await;
}
struct MyRequestHandler {}
impl RequestHandler for MyRequestHandler {
fn get_report(&self, id: ReportId, _buf: &mut [u8]) -> Option<usize> {
info!("Get report for {:?}", id);
None
}
fn set_report(&self, id: ReportId, data: &[u8]) -> OutResponse {
info!("Set report for {:?}: {=[u8]}", id, data);
OutResponse::Accepted
}
fn set_idle_ms(&self, id: Option<ReportId>, dur: u32) {
info!("Set idle rate for {:?} to {:?}", id, dur);
}
fn get_idle_ms(&self, id: Option<ReportId>) -> Option<u32> {
info!("Get idle rate for {:?}", id);
None
}
}
struct MyDeviceHandler {
configured: AtomicBool,
}
impl MyDeviceHandler {
fn new() -> Self {
MyDeviceHandler {
configured: AtomicBool::new(false),
}
}
}
impl Handler for MyDeviceHandler {
fn enabled(&mut self, enabled: bool) {
self.configured.store(false, Ordering::Relaxed);
SUSPENDED.store(false, Ordering::Release);
if enabled {
info!("Device enabled");
} else {
info!("Device disabled");
}
}
fn reset(&mut self) {
self.configured.store(false, Ordering::Relaxed);
info!("Bus reset, the Vbus current limit is 100mA");
}
fn addressed(&mut self, addr: u8) {
self.configured.store(false, Ordering::Relaxed);
info!("USB address set to: {}", addr);
}
fn configured(&mut self, configured: bool) {
self.configured.store(configured, Ordering::Relaxed);
if configured {
info!("Device configured, it may now draw up to the configured current limit from Vbus.")
} else {
info!("Device is no longer configured, the Vbus current limit is 100mA.");
}
}
fn suspended(&mut self, suspended: bool) {
if suspended {
info!("Device suspended, the Vbus current limit is 500µA (or 2.5mA for high-power devices with remote wakeup enabled).");
SUSPENDED.store(true, Ordering::Release);
} else {
SUSPENDED.store(false, Ordering::Release);
if self.configured.load(Ordering::Relaxed) {
info!("Device resumed, it may now draw up to the configured current limit from Vbus");
} else {
info!("Device resumed, the Vbus current limit is 100mA");
}
}
}
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::mem;
use defmt::*;
use embassy_executor::Spawner;
use embassy_futures::join::join;
use embassy_nrf::usb::vbus_detect::HardwareVbusDetect;
use embassy_nrf::usb::Driver;
use embassy_nrf::{bind_interrupts, pac, peripherals, usb};
use embassy_time::{Duration, Timer};
use embassy_usb::class::hid::{HidWriter, ReportId, RequestHandler, State};
use embassy_usb::control::OutResponse;
use embassy_usb::{Builder, Config};
use usbd_hid::descriptor::{MouseReport, SerializedDescriptor};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
USBD => usb::InterruptHandler<peripherals::USBD>;
POWER_CLOCK => usb::vbus_detect::InterruptHandler;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let clock: pac::CLOCK = unsafe { mem::transmute(()) };
info!("Enabling ext hfosc...");
clock.tasks_hfclkstart.write(|w| unsafe { w.bits(1) });
while clock.events_hfclkstarted.read().bits() != 1 {}
// Create the driver, from the HAL.
let driver = Driver::new(p.USBD, Irqs, HardwareVbusDetect::new(Irqs));
// Create embassy-usb Config
let mut config = Config::new(0xc0de, 0xcafe);
config.manufacturer = Some("Embassy");
config.product = Some("HID mouse example");
config.serial_number = Some("12345678");
config.max_power = 100;
config.max_packet_size_0 = 64;
// Create embassy-usb DeviceBuilder using the driver and config.
// It needs some buffers for building the descriptors.
let mut device_descriptor = [0; 256];
let mut config_descriptor = [0; 256];
let mut bos_descriptor = [0; 256];
let mut msos_descriptor = [0; 256];
let mut control_buf = [0; 64];
let request_handler = MyRequestHandler {};
let mut state = State::new();
let mut builder = Builder::new(
driver,
config,
&mut device_descriptor,
&mut config_descriptor,
&mut bos_descriptor,
&mut msos_descriptor,
&mut control_buf,
);
// Create classes on the builder.
let config = embassy_usb::class::hid::Config {
report_descriptor: MouseReport::desc(),
request_handler: Some(&request_handler),
poll_ms: 60,
max_packet_size: 8,
};
let mut writer = HidWriter::<_, 5>::new(&mut builder, &mut state, config);
// Build the builder.
let mut usb = builder.build();
// Run the USB device.
let usb_fut = usb.run();
// Do stuff with the class!
let hid_fut = async {
let mut y: i8 = 5;
loop {
Timer::after(Duration::from_millis(500)).await;
y = -y;
let report = MouseReport {
buttons: 0,
x: 0,
y,
wheel: 0,
pan: 0,
};
match writer.write_serialize(&report).await {
Ok(()) => {}
Err(e) => warn!("Failed to send report: {:?}", e),
}
}
};
// Run everything concurrently.
// If we had made everything `'static` above instead, we could do this using separate tasks instead.
join(usb_fut, hid_fut).await;
}
struct MyRequestHandler {}
impl RequestHandler for MyRequestHandler {
fn get_report(&self, id: ReportId, _buf: &mut [u8]) -> Option<usize> {
info!("Get report for {:?}", id);
None
}
fn set_report(&self, id: ReportId, data: &[u8]) -> OutResponse {
info!("Set report for {:?}: {=[u8]}", id, data);
OutResponse::Accepted
}
fn set_idle_ms(&self, id: Option<ReportId>, dur: u32) {
info!("Set idle rate for {:?} to {:?}", id, dur);
}
fn get_idle_ms(&self, id: Option<ReportId>) -> Option<u32> {
info!("Get idle rate for {:?}", id);
None
}
}

115
examples/nrf52840/src/bin/usb_serial.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::mem;
use defmt::{info, panic};
use embassy_executor::Spawner;
use embassy_futures::join::join;
use embassy_nrf::usb::vbus_detect::{HardwareVbusDetect, VbusDetect};
use embassy_nrf::usb::{Driver, Instance};
use embassy_nrf::{bind_interrupts, pac, peripherals, usb};
use embassy_usb::class::cdc_acm::{CdcAcmClass, State};
use embassy_usb::driver::EndpointError;
use embassy_usb::{Builder, Config};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
USBD => usb::InterruptHandler<peripherals::USBD>;
POWER_CLOCK => usb::vbus_detect::InterruptHandler;
});
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let clock: pac::CLOCK = unsafe { mem::transmute(()) };
info!("Enabling ext hfosc...");
clock.tasks_hfclkstart.write(|w| unsafe { w.bits(1) });
while clock.events_hfclkstarted.read().bits() != 1 {}
// Create the driver, from the HAL.
let driver = Driver::new(p.USBD, Irqs, HardwareVbusDetect::new(Irqs));
// Create embassy-usb Config
let mut config = Config::new(0xc0de, 0xcafe);
config.manufacturer = Some("Embassy");
config.product = Some("USB-serial example");
config.serial_number = Some("12345678");
config.max_power = 100;
config.max_packet_size_0 = 64;
// Required for windows compatibility.
// https://developer.nordicsemi.com/nRF_Connect_SDK/doc/1.9.1/kconfig/CONFIG_CDC_ACM_IAD.html#help
config.device_class = 0xEF;
config.device_sub_class = 0x02;
config.device_protocol = 0x01;
config.composite_with_iads = true;
// Create embassy-usb DeviceBuilder using the driver and config.
// It needs some buffers for building the descriptors.
let mut device_descriptor = [0; 256];
let mut config_descriptor = [0; 256];
let mut bos_descriptor = [0; 256];
let mut msos_descriptor = [0; 256];
let mut control_buf = [0; 64];
let mut state = State::new();
let mut builder = Builder::new(
driver,
config,
&mut device_descriptor,
&mut config_descriptor,
&mut bos_descriptor,
&mut msos_descriptor,
&mut control_buf,
);
// Create classes on the builder.
let mut class = CdcAcmClass::new(&mut builder, &mut state, 64);
// Build the builder.
let mut usb = builder.build();
// Run the USB device.
let usb_fut = usb.run();
// Do stuff with the class!
let echo_fut = async {
loop {
class.wait_connection().await;
info!("Connected");
let _ = echo(&mut class).await;
info!("Disconnected");
}
};
// Run everything concurrently.
// If we had made everything `'static` above instead, we could do this using separate tasks instead.
join(usb_fut, echo_fut).await;
}
struct Disconnected {}
impl From<EndpointError> for Disconnected {
fn from(val: EndpointError) -> Self {
match val {
EndpointError::BufferOverflow => panic!("Buffer overflow"),
EndpointError::Disabled => Disconnected {},
}
}
}
async fn echo<'d, T: Instance + 'd, P: VbusDetect + 'd>(
class: &mut CdcAcmClass<'d, Driver<'d, T, P>>,
) -> Result<(), Disconnected> {
let mut buf = [0; 64];
loop {
let n = class.read_packet(&mut buf).await?;
let data = &buf[..n];
info!("data: {:x}", data);
class.write_packet(data).await?;
}
}

109
examples/nrf52840/src/bin/usb_serial_multitask.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::mem;
use defmt::{info, panic, unwrap};
use embassy_executor::Spawner;
use embassy_nrf::usb::vbus_detect::HardwareVbusDetect;
use embassy_nrf::usb::Driver;
use embassy_nrf::{bind_interrupts, pac, peripherals, usb};
use embassy_usb::class::cdc_acm::{CdcAcmClass, State};
use embassy_usb::driver::EndpointError;
use embassy_usb::{Builder, Config, UsbDevice};
use static_cell::make_static;
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
USBD => usb::InterruptHandler<peripherals::USBD>;
POWER_CLOCK => usb::vbus_detect::InterruptHandler;
});
type MyDriver = Driver<'static, peripherals::USBD, HardwareVbusDetect>;
#[embassy_executor::task]
async fn usb_task(mut device: UsbDevice<'static, MyDriver>) {
device.run().await;
}
#[embassy_executor::task]
async fn echo_task(mut class: CdcAcmClass<'static, MyDriver>) {
loop {
class.wait_connection().await;
info!("Connected");
let _ = echo(&mut class).await;
info!("Disconnected");
}
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let clock: pac::CLOCK = unsafe { mem::transmute(()) };
info!("Enabling ext hfosc...");
clock.tasks_hfclkstart.write(|w| unsafe { w.bits(1) });
while clock.events_hfclkstarted.read().bits() != 1 {}
// Create the driver, from the HAL.
let driver = Driver::new(p.USBD, Irqs, HardwareVbusDetect::new(Irqs));
// Create embassy-usb Config
let mut config = Config::new(0xc0de, 0xcafe);
config.manufacturer = Some("Embassy");
config.product = Some("USB-serial example");
config.serial_number = Some("12345678");
config.max_power = 100;
config.max_packet_size_0 = 64;
// Required for windows compatibility.
// https://developer.nordicsemi.com/nRF_Connect_SDK/doc/1.9.1/kconfig/CONFIG_CDC_ACM_IAD.html#help
config.device_class = 0xEF;
config.device_sub_class = 0x02;
config.device_protocol = 0x01;
config.composite_with_iads = true;
let state = make_static!(State::new());
// Create embassy-usb DeviceBuilder using the driver and config.
let mut builder = Builder::new(
driver,
config,
&mut make_static!([0; 256])[..],
&mut make_static!([0; 256])[..],
&mut make_static!([0; 256])[..],
&mut make_static!([0; 128])[..],
&mut make_static!([0; 128])[..],
);
// Create classes on the builder.
let class = CdcAcmClass::new(&mut builder, state, 64);
// Build the builder.
let usb = builder.build();
unwrap!(spawner.spawn(usb_task(usb)));
unwrap!(spawner.spawn(echo_task(class)));
}
struct Disconnected {}
impl From<EndpointError> for Disconnected {
fn from(val: EndpointError) -> Self {
match val {
EndpointError::BufferOverflow => panic!("Buffer overflow"),
EndpointError::Disabled => Disconnected {},
}
}
}
async fn echo(class: &mut CdcAcmClass<'static, MyDriver>) -> Result<(), Disconnected> {
let mut buf = [0; 64];
loop {
let n = class.read_packet(&mut buf).await?;
let data = &buf[..n];
info!("data: {:x}", data);
class.write_packet(data).await?;
}
}

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examples/nrf52840/src/bin/usb_serial_winusb.rs Normal file
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use core::mem;
use defmt::{info, panic};
use embassy_executor::Spawner;
use embassy_futures::join::join;
use embassy_nrf::usb::vbus_detect::{HardwareVbusDetect, VbusDetect};
use embassy_nrf::usb::{Driver, Instance};
use embassy_nrf::{bind_interrupts, pac, peripherals, usb};
use embassy_usb::class::cdc_acm::{CdcAcmClass, State};
use embassy_usb::driver::EndpointError;
use embassy_usb::msos::{self, windows_version};
use embassy_usb::types::InterfaceNumber;
use embassy_usb::{Builder, Config};
use {defmt_rtt as _, panic_probe as _};
bind_interrupts!(struct Irqs {
USBD => usb::InterruptHandler<peripherals::USBD>;
POWER_CLOCK => usb::vbus_detect::InterruptHandler;
});
// This is a randomly generated GUID to allow clients on Windows to find our device
const DEVICE_INTERFACE_GUIDS: &[&str] = &["{EAA9A5DC-30BA-44BC-9232-606CDC875321}"];
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
let clock: pac::CLOCK = unsafe { mem::transmute(()) };
info!("Enabling ext hfosc...");
clock.tasks_hfclkstart.write(|w| unsafe { w.bits(1) });
while clock.events_hfclkstarted.read().bits() != 1 {}
// Create the driver, from the HAL.
let driver = Driver::new(p.USBD, Irqs, HardwareVbusDetect::new(Irqs));
// Create embassy-usb Config
let mut config = Config::new(0xc0de, 0xcafe);
config.manufacturer = Some("Embassy");
config.product = Some("USB-serial example");
config.serial_number = Some("12345678");
config.max_power = 100;
config.max_packet_size_0 = 64;
// Required for windows compatibility.
// https://developer.nordicsemi.com/nRF_Connect_SDK/doc/1.9.1/kconfig/CONFIG_CDC_ACM_IAD.html#help
config.device_class = 0xEF;
config.device_sub_class = 0x02;
config.device_protocol = 0x01;
config.composite_with_iads = true;
// Create embassy-usb DeviceBuilder using the driver and config.
// It needs some buffers for building the descriptors.
let mut device_descriptor = [0; 256];
let mut config_descriptor = [0; 256];
let mut bos_descriptor = [0; 256];
let mut msos_descriptor = [0; 256];
let mut control_buf = [0; 64];
let mut state = State::new();
let mut builder = Builder::new(
driver,
config,
&mut device_descriptor,
&mut config_descriptor,
&mut bos_descriptor,
&mut msos_descriptor,
&mut control_buf,
);
builder.msos_descriptor(windows_version::WIN8_1, 2);
// Create classes on the builder.
let mut class = CdcAcmClass::new(&mut builder, &mut state, 64);
// Since we want to create MS OS feature descriptors that apply to a function that has already been added to the
// builder, need to get the MsOsDescriptorWriter from the builder and manually add those descriptors.
// Inside a class constructor, you would just need to call `FunctionBuilder::msos_feature` instead.
let msos_writer = builder.msos_writer();
msos_writer.configuration(0);
msos_writer.function(InterfaceNumber(0));
msos_writer.function_feature(msos::CompatibleIdFeatureDescriptor::new("WINUSB", ""));
msos_writer.function_feature(msos::RegistryPropertyFeatureDescriptor::new(
"DeviceInterfaceGUIDs",
msos::PropertyData::RegMultiSz(DEVICE_INTERFACE_GUIDS),
));
// Build the builder.
let mut usb = builder.build();
// Run the USB device.
let usb_fut = usb.run();
// Do stuff with the class!
let echo_fut = async {
loop {
class.wait_connection().await;
info!("Connected");
let _ = echo(&mut class).await;
info!("Disconnected");
}
};
// Run everything concurrently.
// If we had made everything `'static` above instead, we could do this using separate tasks instead.
join(usb_fut, echo_fut).await;
}
struct Disconnected {}
impl From<EndpointError> for Disconnected {
fn from(val: EndpointError) -> Self {
match val {
EndpointError::BufferOverflow => panic!("Buffer overflow"),
EndpointError::Disabled => Disconnected {},
}
}
}
async fn echo<'d, T: Instance + 'd, P: VbusDetect + 'd>(
class: &mut CdcAcmClass<'d, Driver<'d, T, P>>,
) -> Result<(), Disconnected> {
let mut buf = [0; 64];
loop {
let n = class.read_packet(&mut buf).await?;
let data = &buf[..n];
info!("data: {:x}", data);
class.write_packet(data).await?;
}
}

41
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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::*;
use embassy_executor::Spawner;
use embassy_nrf::gpio::{Input, Pull};
use embassy_nrf::wdt::{Config, Watchdog};
use {defmt_rtt as _, panic_probe as _};
#[embassy_executor::main]
async fn main(_spawner: Spawner) {
let p = embassy_nrf::init(Default::default());
info!("Hello World!");
let mut config = Config::default();
config.timeout_ticks = 32768 * 3; // 3 seconds
// This is needed for `probe-rs run` to be able to catch the panic message
// in the WDT interrupt. The core resets 2 ticks after firing the interrupt.
config.run_during_debug_halt = false;
let (_wdt, [mut handle]) = match Watchdog::try_new(p.WDT, config) {
Ok(x) => x,
Err(_) => {
info!("Watchdog already active with wrong config, waiting for it to timeout...");
loop {}
}
};
let mut button = Input::new(p.P0_11, Pull::Up);
info!("Watchdog started, press button 1 to pet it or I'll reset in 3 seconds!");
loop {
button.wait_for_high().await;
button.wait_for_low().await;
info!("Button pressed, petting watchdog!");
handle.pet();
}
}

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait)]
use defmt::{info, unwrap, warn};
use embassy_executor::Spawner;
use embassy_net::tcp::TcpSocket;
use embassy_net::{Stack, StackResources};
use embassy_nrf::gpio::{AnyPin, Input, Level, Output, OutputDrive, Pin, Pull};
use embassy_nrf::rng::Rng;
use embassy_nrf::spim::{self, Spim};
use embassy_nrf::{bind_interrupts, peripherals};
use embassy_time::Delay;
use embedded_hal_async::spi::ExclusiveDevice;
use embedded_io::asynch::Write;
use static_cell::make_static;
use {defmt_rtt as _, embassy_net_esp_hosted as hosted, panic_probe as _};
const WIFI_NETWORK: &str = "EmbassyTest";
const WIFI_PASSWORD: &str = "V8YxhKt5CdIAJFud";
bind_interrupts!(struct Irqs {
SPIM3 => spim::InterruptHandler<peripherals::SPI3>;
RNG => embassy_nrf::rng::InterruptHandler<peripherals::RNG>;
});
#[embassy_executor::task]
async fn wifi_task(
runner: hosted::Runner<
'static,
ExclusiveDevice<Spim<'static, peripherals::SPI3>, Output<'static, peripherals::P0_31>, Delay>,
Input<'static, AnyPin>,
Output<'static, peripherals::P1_05>,
>,
) -> ! {
runner.run().await
}
#[embassy_executor::task]
async fn net_task(stack: &'static Stack<hosted::NetDriver<'static>>) -> ! {
stack.run().await
}
#[embassy_executor::main]
async fn main(spawner: Spawner) {
info!("Hello World!");
let p = embassy_nrf::init(Default::default());
let miso = p.P0_28;
let sck = p.P0_29;
let mosi = p.P0_30;
let cs = Output::new(p.P0_31, Level::High, OutputDrive::HighDrive);
let handshake = Input::new(p.P1_01.degrade(), Pull::Up);
let ready = Input::new(p.P1_04.degrade(), Pull::None);
let reset = Output::new(p.P1_05, Level::Low, OutputDrive::Standard);
let mut config = spim::Config::default();
config.frequency = spim::Frequency::M32;
config.mode = spim::MODE_2; // !!!
let spi = spim::Spim::new(p.SPI3, Irqs, sck, miso, mosi, config);
let spi = ExclusiveDevice::new(spi, cs, Delay);
let (device, mut control, runner) = embassy_net_esp_hosted::new(
make_static!(embassy_net_esp_hosted::State::new()),
spi,
handshake,
ready,
reset,
)
.await;
unwrap!(spawner.spawn(wifi_task(runner)));
control.init().await;
control.join(WIFI_NETWORK, WIFI_PASSWORD).await;
let config = embassy_net::Config::dhcpv4(Default::default());
// let config = embassy_net::Config::ipv4_static(embassy_net::StaticConfigV4 {
// address: Ipv4Cidr::new(Ipv4Address::new(10, 42, 0, 61), 24),
// dns_servers: Vec::new(),
// gateway: Some(Ipv4Address::new(10, 42, 0, 1)),
// });
// Generate random seed
let mut rng = Rng::new(p.RNG, Irqs);
let mut seed = [0; 8];
rng.blocking_fill_bytes(&mut seed);
let seed = u64::from_le_bytes(seed);
// Init network stack
let stack = &*make_static!(Stack::new(
device,
config,
make_static!(StackResources::<2>::new()),
seed
));
unwrap!(spawner.spawn(net_task(stack)));
// And now we can use it!
let mut rx_buffer = [0; 4096];
let mut tx_buffer = [0; 4096];
let mut buf = [0; 4096];
loop {
let mut socket = TcpSocket::new(stack, &mut rx_buffer, &mut tx_buffer);
socket.set_timeout(Some(embassy_time::Duration::from_secs(10)));
info!("Listening on TCP:1234...");
if let Err(e) = socket.accept(1234).await {
warn!("accept error: {:?}", e);
continue;
}
info!("Received connection from {:?}", socket.remote_endpoint());
loop {
let n = match socket.read(&mut buf).await {
Ok(0) => {
warn!("read EOF");
break;
}
Ok(n) => n,
Err(e) => {
warn!("read error: {:?}", e);
break;
}
};
info!("rxd {:02x}", &buf[..n]);
match socket.write_all(&buf[..n]).await {
Ok(()) => {}
Err(e) => {
warn!("write error: {:?}", e);
break;
}
};
}
}
}