mirror of
https://github.com/italicsjenga/rp-hal-boards.git
synced 2024-12-24 21:21:31 +11:00
427344667e
* Add basic multicore fifo example * Add documentation for multicore * Send system_clock frequency to core1 over FIFO in example * Add Stack::new() to HAL. Use Stack::new() in example
184 lines
6.2 KiB
Rust
184 lines
6.2 KiB
Rust
//! # Multicore FIFO + GPIO 'Blinky' Example
|
|
//!
|
|
//! This application demonstrates FIFO communication between the CPU cores on the RP2040.
|
|
//! Core 0 will calculate and send a delay value to Core 1, which will then wait that long
|
|
//! before toggling the LED.
|
|
//! Core 0 will wait for Core 1 to complete this task and send an acknowledgement value.
|
|
//!
|
|
//! It may need to be adapted to your particular board layout and/or pin assignment.
|
|
//!
|
|
//! See the `Cargo.toml` file for Copyright and licence details.
|
|
|
|
#![no_std]
|
|
#![no_main]
|
|
|
|
// The macro for our start-up function
|
|
use cortex_m_rt::entry;
|
|
|
|
use embedded_time::fixed_point::FixedPoint;
|
|
use hal::clocks::Clock;
|
|
use hal::multicore::{Multicore, Stack};
|
|
use hal::sio::Sio;
|
|
// Ensure we halt the program on panic (if we don't mention this crate it won't
|
|
// be linked)
|
|
use panic_halt as _;
|
|
|
|
// Alias for our HAL crate
|
|
use rp2040_hal as hal;
|
|
|
|
// A shorter alias for the Peripheral Access Crate, which provides low-level
|
|
// register access
|
|
use hal::pac;
|
|
|
|
// Some traits we need
|
|
use embedded_hal::digital::v2::ToggleableOutputPin;
|
|
|
|
/// The linker will place this boot block at the start of our program image. We
|
|
// need this to help the ROM bootloader get our code up and running.
|
|
#[link_section = ".boot2"]
|
|
#[used]
|
|
pub static BOOT2: [u8; 256] = rp2040_boot2::BOOT_LOADER_W25Q080;
|
|
|
|
/// External high-speed crystal on the Raspberry Pi Pico board is 12 MHz. Adjust
|
|
/// if your board has a different frequency
|
|
const XTAL_FREQ_HZ: u32 = 12_000_000u32;
|
|
|
|
/// Value to indicate that Core 1 has completed its task
|
|
const CORE1_TASK_COMPLETE: u32 = 0xEE;
|
|
|
|
/// Stack for core 1
|
|
///
|
|
/// Core 0 gets its stack via the normal route - any memory not used by static values is
|
|
/// reserved for stack and initialised by cortex-m-rt.
|
|
/// To get the same for Core 1, we would need to compile everything seperately and
|
|
/// modify the linker file for both programs, and that's quite annoying.
|
|
/// So instead, core1.spawn takes a [usize] which gets used for the stack.
|
|
/// NOTE: We use the `Stack` struct here to ensure that it has 32-byte alignment, which allows
|
|
/// the stack guard to take up the least amount of usable RAM.
|
|
static mut CORE1_STACK: Stack<4096> = Stack::new();
|
|
|
|
fn core1_task() -> ! {
|
|
let mut pac = unsafe { pac::Peripherals::steal() };
|
|
let core = unsafe { pac::CorePeripherals::steal() };
|
|
|
|
let mut sio = Sio::new(pac.SIO);
|
|
let pins = hal::gpio::Pins::new(
|
|
pac.IO_BANK0,
|
|
pac.PADS_BANK0,
|
|
sio.gpio_bank0,
|
|
&mut pac.RESETS,
|
|
);
|
|
|
|
let mut led_pin = pins.gpio25.into_push_pull_output();
|
|
// The first thing core0 sends us is the system bus frequency.
|
|
// The systick is based on this frequency, so we need that to
|
|
// be accurate when sleeping via cortex_m::delay::Delay
|
|
let sys_freq = sio.fifo.read_blocking();
|
|
let mut delay = cortex_m::delay::Delay::new(core.SYST, sys_freq);
|
|
loop {
|
|
let input = sio.fifo.read();
|
|
if let Some(word) = input {
|
|
delay.delay_ms(word);
|
|
led_pin.toggle().unwrap();
|
|
sio.fifo.write_blocking(CORE1_TASK_COMPLETE);
|
|
};
|
|
}
|
|
}
|
|
|
|
/// Entry point to our bare-metal application.
|
|
///
|
|
/// The `#[entry]` macro ensures the Cortex-M start-up code calls this function
|
|
/// as soon as all global variables are initialised.
|
|
///
|
|
/// The function configures the RP2040 peripherals, then toggles a GPIO pin in
|
|
/// an infinite loop. If there is an LED connected to that pin, it will blink.
|
|
#[entry]
|
|
fn main() -> ! {
|
|
// Grab our singleton objects
|
|
let mut pac = pac::Peripherals::take().unwrap();
|
|
let _core = pac::CorePeripherals::take().unwrap();
|
|
|
|
// Set up the watchdog driver - needed by the clock setup code
|
|
let mut watchdog = hal::watchdog::Watchdog::new(pac.WATCHDOG);
|
|
|
|
// Configure the clocks
|
|
let clocks = hal::clocks::init_clocks_and_plls(
|
|
XTAL_FREQ_HZ,
|
|
pac.XOSC,
|
|
pac.CLOCKS,
|
|
pac.PLL_SYS,
|
|
pac.PLL_USB,
|
|
&mut pac.RESETS,
|
|
&mut watchdog,
|
|
)
|
|
.ok()
|
|
.unwrap();
|
|
|
|
// The single-cycle I/O block controls our GPIO pins
|
|
let mut sio = hal::sio::Sio::new(pac.SIO);
|
|
|
|
let mut mc = Multicore::new(&mut pac.PSM, &mut pac.PPB, &mut sio);
|
|
let cores = mc.cores();
|
|
let core1 = &mut cores[1];
|
|
let _test = core1.spawn(core1_task, unsafe { &mut CORE1_STACK.mem });
|
|
|
|
// Let core1 know how fast the system clock is running
|
|
let sys_freq = clocks.system_clock.freq().integer();
|
|
sio.fifo.write_blocking(sys_freq);
|
|
/// How much we adjust the LED period every cycle
|
|
const LED_PERIOD_INCREMENT: i32 = 2;
|
|
|
|
/// The minimum LED toggle interval we allow for.
|
|
const LED_PERIOD_MIN: i32 = 0;
|
|
|
|
/// The maximum LED toggle interval period we allow for. Keep it reasonably short so it's easy to see.
|
|
const LED_PERIOD_MAX: i32 = 100;
|
|
|
|
// Our current LED period. It starts at the shortest period, which is the highest blink frequency
|
|
let mut led_period: i32 = LED_PERIOD_MIN;
|
|
|
|
// The direction we're incrementing our LED period.
|
|
// Since we start at the minimum value, start by counting up
|
|
let mut count_up = true;
|
|
|
|
loop {
|
|
if count_up {
|
|
// Increment our period
|
|
led_period += LED_PERIOD_INCREMENT;
|
|
|
|
// Change direction of increment if we hit the limit
|
|
if led_period > LED_PERIOD_MAX {
|
|
led_period = LED_PERIOD_MAX;
|
|
count_up = false;
|
|
}
|
|
} else {
|
|
// Decrement our period
|
|
led_period -= LED_PERIOD_INCREMENT;
|
|
|
|
// Change direction of increment if we hit the limit
|
|
if led_period < LED_PERIOD_MIN {
|
|
led_period = LED_PERIOD_MIN;
|
|
count_up = true;
|
|
}
|
|
}
|
|
|
|
// It should not be possible for led_period to go negative, but let's ensure that.
|
|
if led_period < 0 {
|
|
led_period = 0;
|
|
}
|
|
|
|
// Send the new delay time to Core 1. We convert it
|
|
sio.fifo.write(led_period as u32);
|
|
|
|
// Sleep until Core 1 sends a message to tell us it is done
|
|
let ack = sio.fifo.read_blocking();
|
|
if ack != CORE1_TASK_COMPLETE {
|
|
// In a real application you might want to handle the case
|
|
// where the CPU sent the wrong message - we're going to
|
|
// ignore it here.
|
|
}
|
|
}
|
|
}
|
|
|
|
// End of file
|