//! # UART IRQ Echo Example //! //! This application demonstrates how to use the UART Driver to talk to a serial //! connection. In this example, the IRQ owns the UART and you cannot do any UART //! access from the main thread. //! //! The pinouts are: //! //! * GPIO 0 - UART TX (out of the RP2040) //! * GPIO 1 - UART RX (in to the RP2040) //! * GPIO 25 - An LED we can blink (active high) //! //! See the `Cargo.toml` file for Copyright and license details. #![no_std] #![no_main] // These are the traits we need from Embedded HAL to treat our hardware // objects as generic embedded devices. use embedded_hal::{ digital::v2::OutputPin, serial::{Read, Write}, }; // We also need this for the 'Delay' object to work. use rp2040_hal::Clock; // The macro for our start-up function use rp_pico::entry; // Time handling traits use fugit::RateExtU32; // 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; // Our interrupt macro use hal::pac::interrupt; // Some short-cuts to useful types use core::cell::RefCell; use critical_section::Mutex; /// Import the GPIO pins we use use hal::gpio::pin::bank0::{Gpio0, Gpio1}; // UART related types use hal::uart::{DataBits, StopBits, UartConfig}; /// Alias the type for our UART pins to make things clearer. type UartPins = ( hal::gpio::Pin>, hal::gpio::Pin>, ); /// Alias the type for our UART to make things clearer. type Uart = hal::uart::UartPeripheral; /// 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; /// This how we transfer the UART into the Interrupt Handler static GLOBAL_UART: Mutex>> = Mutex::new(RefCell::new(None)); /// 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 writes to the UART in /// an infinite loop. #[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::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(); // Lets us wait for fixed periods of time let mut delay = cortex_m::delay::Delay::new(core.SYST, clocks.system_clock.freq().to_Hz()); // The single-cycle I/O block controls our GPIO pins let sio = hal::Sio::new(pac.SIO); // Set the pins to their default state let pins = rp_pico::Pins::new( pac.IO_BANK0, pac.PADS_BANK0, sio.gpio_bank0, &mut pac.RESETS, ); let uart_pins = ( // UART TX (characters sent from RP2040) on pin 1 (GPIO0) pins.gpio0.into_mode::(), // UART RX (characters received by RP2040) on pin 2 (GPIO1) pins.gpio1.into_mode::(), ); // Make a UART on the given pins let mut uart = hal::uart::UartPeripheral::new(pac.UART0, uart_pins, &mut pac.RESETS) .enable( UartConfig::new(9600.Hz(), DataBits::Eight, None, StopBits::One), clocks.peripheral_clock.freq(), ) .unwrap(); unsafe { // Enable the UART interrupt in the *Nested Vectored Interrupt // Controller*, which is part of the Cortex-M0+ core. pac::NVIC::unmask(hal::pac::Interrupt::UART0_IRQ); } // Tell the UART to raise its interrupt line on the NVIC when the RX FIFO // has data in it. uart.enable_rx_interrupt(); // Write something to the UART on start-up so we can check the output pin // is wired correctly. uart.write_full_blocking(b"uart_interrupt example started...\n"); // Now we give away the entire UART peripheral, via the variable // `GLOBAL_UART`. We can no longer access the UART from this main thread. critical_section::with(|cs| { GLOBAL_UART.borrow(cs).replace(Some(uart)); }); // But we can blink an LED. let mut led_pin = pins.led.into_push_pull_output(); loop { // The normal *Wait For Interrupts* (WFI) has a race-hazard - the // interrupt could occur between the CPU checking for interrupts and // the CPU going to sleep. We wait for events (and interrupts), and // then we set an event in every interrupt handler. This ensures we // always wake up correctly. cortex_m::asm::wfe(); // Light the LED to indicate we saw an interrupt. led_pin.set_high().unwrap(); delay.delay_ms(100); led_pin.set_low().unwrap(); } } #[interrupt] fn UART0_IRQ() { // This variable is special. It gets mangled by the `#[interrupt]` macro // into something that we can access without the `unsafe` keyword. It can // do this because this function cannot be called re-entrantly. We know // this because the function's 'real' name is unknown, and hence it cannot // be called from the main thread. We also know that the NVIC will not // re-entrantly call an interrupt. static mut UART: Option> = None; // This is one-time lazy initialisation. We steal the variable given to us // via `GLOBAL_UART`. if UART.is_none() { critical_section::with(|cs| { *UART = GLOBAL_UART.borrow(cs).take(); }); } // Check if we have a UART to work with if let Some(uart) = UART { // Echo the input back to the output until the FIFO is empty. Reading // from the UART should also clear the UART interrupt flag. while let Ok(byte) = uart.read() { let _ = uart.write(byte); } } // Set an event to ensure the main thread always wakes up, even if it's in // the process of going to sleep. cortex_m::asm::sev(); } // End of file