rtic/examples/stm32f411_rtc_interrupt/src/main.rs

#![deny(unsafe_code)]
#![deny(warnings)]
#![no_main]
#![no_std]
#![feature(type_alias_impl_trait)]

use panic_halt as _;

#[rtic::app(device = stm32f4xx_hal::pac, peripherals = true)]
mod app {

    use stm32f4xx_hal::{
        gpio::{self, Edge, Input, Output, PushPull},
        pac::TIM1,
        prelude::*,
        rtc::{Rtc, Event},
        timer,
    };

    use defmt_rtt as _;

    // Resources shared between tasks
    #[shared]
    struct Shared {
        delayval: u32,
        rtc: Rtc,
    }

    // Local resources to specific tasks (cannot be shared)
    #[local]
    struct Local {
        button: gpio::PA0<Input>,
        led: gpio::PC13<Output<PushPull>>,
        delay: timer::DelayMs<TIM1>,
    }

    
    #[init]
    fn init(ctx: init::Context) -> (Shared, Local) {

        let mut dp = ctx.device;

        // Configure and obtain handle for delay abstraction
        // 1) Promote RCC structure to HAL to be able to configure clocks
        let rcc = dp.RCC.constrain();

        // 2) Configure the system clocks
        // 25 MHz must be used for HSE on the Blackpill-STM32F411CE board according to manual
        let clocks = rcc.cfgr.use_hse(25.MHz()).freeze();
        
        //Configure RTC
        let mut rtc = Rtc::new(dp.RTC, &mut dp.PWR);

        //Set date and time
        let _ = rtc.set_year(2023);
        let _ = rtc.set_month(11);
        let _ = rtc.set_day(25);
        let _ = rtc.set_hours(22);
        let _ = rtc.set_minutes(46);
        let _ = rtc.set_seconds(00);

        //Start listening to WAKE UP INTERRUPTS
        rtc.enable_wakeup(10.secs());
        rtc.listen(&mut dp.EXTI, Event::Wakeup);
        

        // 3) Create delay handle
        let delay = dp.TIM1.delay_ms(&clocks);

        // Configure the LED pin as a push pull ouput and obtain handle
        // On the Blackpill STM32F411CEU6 there is an on-board LED connected to pin PC13
        // 1) Promote the GPIOC PAC struct
        let gpioc = dp.GPIOC.split();

        // 2) Configure PORTC OUTPUT Pins and Obtain Handle
        let led = gpioc.pc13.into_push_pull_output();

        // Configure the button pin as input and obtain handle
        // On the Blackpill STM32F411CEU6 there is a button connected to pin PA0
        // 1) Promote the GPIOA PAC struct
        let gpioa: gpio::gpioa::Parts = dp.GPIOA.split();
        // 2) Configure Pin and Obtain Handle
        let mut button = gpioa.pa0.into_pull_up_input();


        // Configure Button Pin for Interrupts
        // 1) Promote SYSCFG structure to HAL to be able to configure interrupts
        let mut syscfg = dp.SYSCFG.constrain();
        // 2) Make button an interrupt source
        button.make_interrupt_source(&mut syscfg);
        // 3) Configure the interruption to be triggered on a rising edge
        button.trigger_on_edge(&mut dp.EXTI, Edge::Rising);
        // 4) Enable gpio interrupt for button
        button.enable_interrupt(&mut dp.EXTI);


        (
            // Initialization of shared resources
            Shared { delayval: 2000_u32, rtc},
            // Initialization of task local resources
            Local { button, led, delay},
        )
        
    }

    // Background task, runs whenever no other tasks are running
    #[idle(local = [led, delay], shared = [delayval])]
    fn idle(mut ctx: idle::Context) -> ! {
        let led = ctx.local.led;
        let delay = ctx.local.delay;
        loop {
            // Turn On LED
            led.set_high();
            // Obtain shared delay variable and delay
            delay.delay_ms(ctx.shared.delayval.lock(|del| *del));
            // Turn off LED
            led.set_low();
            // Obtain shared delay variable and delay
            delay.delay_ms(ctx.shared.delayval.lock(|del| *del));
        }
    }

    #[task(binds = EXTI0, local = [button], shared=[delayval, rtc])]
    fn gpio_interrupt_handler(mut ctx: gpio_interrupt_handler::Context) {

        ctx.shared.delayval.lock(|del| {
            *del = *del - 100_u32;
            if *del < 200_u32 {
                *del = 2000_u32;
            }
            *del
        });

        ctx.shared.rtc.lock(|rtc|{
            let current_time = rtc.get_datetime();
            
            defmt::info!("CURRENT TIME {:?}", current_time.as_hms());
            rtc.disable_wakeup();
        });
        
        ctx.local.button.clear_interrupt_pending_bit();

    }

    #[task(binds = RTC_WKUP, shared = [rtc])]
    fn rtc_wakeup(mut ctx: rtc_wakeup::Context) {
        defmt::warn!("RTC INTERRUPT!!!!");
        ctx.shared.rtc.lock(|rtc|{
            let current_time = rtc.get_datetime();
            rtc.clear_interrupt(Event::Wakeup);
            defmt::info!("Current time {:?}", current_time.as_hms() );
        });
        // Your RTC wakeup interrupt handling code here        
    }
}
Add RTC interrupt example for stm32f411 (#853) * Add RTC example for stm32f411 * Remove svd file --------- Co-authored-by: Milton Eduardo Sosa <milton.eduardo.sosa@gmail.com, milton@switch-ev.com> 2023-12-04 18:19:24 +01:00			`#![deny(unsafe_code)]`
			`#![deny(warnings)]`
			`#![no_main]`
			`#![no_std]`
			`#![feature(type_alias_impl_trait)]`

			`use panic_halt as _;`

			`#[rtic::app(device = stm32f4xx_hal::pac, peripherals = true)]`
			`mod app {`

			`use stm32f4xx_hal::{`
			`gpio::{self, Edge, Input, Output, PushPull},`
			`pac::TIM1,`
			`prelude::*,`
			`rtc::{Rtc, Event},`
			`timer,`
			`};`

			`use defmt_rtt as _;`

			`// Resources shared between tasks`
			`#[shared]`
			`struct Shared {`
			`delayval: u32,`
			`rtc: Rtc,`
			`}`

			`// Local resources to specific tasks (cannot be shared)`
			`#[local]`
			`struct Local {`
			`button: gpio::PA0<Input>,`
			`led: gpio::PC13<Output<PushPull>>,`
			`delay: timer::DelayMs<TIM1>,`
			`}`


			`#[init]`
			`fn init(ctx: init::Context) -> (Shared, Local) {`

			`let mut dp = ctx.device;`

			`// Configure and obtain handle for delay abstraction`
			`// 1) Promote RCC structure to HAL to be able to configure clocks`
			`let rcc = dp.RCC.constrain();`

			`// 2) Configure the system clocks`
			`// 25 MHz must be used for HSE on the Blackpill-STM32F411CE board according to manual`
			`let clocks = rcc.cfgr.use_hse(25.MHz()).freeze();`

			`//Configure RTC`
			`let mut rtc = Rtc::new(dp.RTC, &mut dp.PWR);`

			`//Set date and time`
			`let _ = rtc.set_year(2023);`
			`let _ = rtc.set_month(11);`
			`let _ = rtc.set_day(25);`
			`let _ = rtc.set_hours(22);`
			`let _ = rtc.set_minutes(46);`
			`let _ = rtc.set_seconds(00);`

			`//Start listening to WAKE UP INTERRUPTS`
			`rtc.enable_wakeup(10.secs());`
			`rtc.listen(&mut dp.EXTI, Event::Wakeup);`


			`// 3) Create delay handle`
			`let delay = dp.TIM1.delay_ms(&clocks);`

			`// Configure the LED pin as a push pull ouput and obtain handle`
			`// On the Blackpill STM32F411CEU6 there is an on-board LED connected to pin PC13`
			`// 1) Promote the GPIOC PAC struct`
			`let gpioc = dp.GPIOC.split();`

			`// 2) Configure PORTC OUTPUT Pins and Obtain Handle`
			`let led = gpioc.pc13.into_push_pull_output();`

			`// Configure the button pin as input and obtain handle`
			`// On the Blackpill STM32F411CEU6 there is a button connected to pin PA0`
			`// 1) Promote the GPIOA PAC struct`
			`let gpioa: gpio::gpioa::Parts = dp.GPIOA.split();`
			`// 2) Configure Pin and Obtain Handle`
			`let mut button = gpioa.pa0.into_pull_up_input();`


			`// Configure Button Pin for Interrupts`
			`// 1) Promote SYSCFG structure to HAL to be able to configure interrupts`
			`let mut syscfg = dp.SYSCFG.constrain();`
			`// 2) Make button an interrupt source`
			`button.make_interrupt_source(&mut syscfg);`
			`// 3) Configure the interruption to be triggered on a rising edge`
			`button.trigger_on_edge(&mut dp.EXTI, Edge::Rising);`
			`// 4) Enable gpio interrupt for button`
			`button.enable_interrupt(&mut dp.EXTI);`


			`(`
			`// Initialization of shared resources`
			`Shared { delayval: 2000_u32, rtc},`
			`// Initialization of task local resources`
			`Local { button, led, delay},`
			`)`

			`}`

			`// Background task, runs whenever no other tasks are running`
			`#[idle(local = [led, delay], shared = [delayval])]`
			`fn idle(mut ctx: idle::Context) -> ! {`
			`let led = ctx.local.led;`
			`let delay = ctx.local.delay;`
			`loop {`
			`// Turn On LED`
			`led.set_high();`
			`// Obtain shared delay variable and delay`
			`delay.delay_ms(ctx.shared.delayval.lock(\|del\| *del));`
			`// Turn off LED`
			`led.set_low();`
			`// Obtain shared delay variable and delay`
			`delay.delay_ms(ctx.shared.delayval.lock(\|del\| *del));`
			`}`
			`}`

			`#[task(binds = EXTI0, local = [button], shared=[delayval, rtc])]`
			`fn gpio_interrupt_handler(mut ctx: gpio_interrupt_handler::Context) {`

			`ctx.shared.delayval.lock(\|del\| {`
			`del = del - 100_u32;`
			`if *del < 200_u32 {`
			`*del = 2000_u32;`
			`}`
			`*del`
			`});`

			`ctx.shared.rtc.lock(\|rtc\|{`
			`let current_time = rtc.get_datetime();`

			`defmt::info!("CURRENT TIME {:?}", current_time.as_hms());`
			`rtc.disable_wakeup();`
			`});`

			`ctx.local.button.clear_interrupt_pending_bit();`

			`}`

			`#[task(binds = RTC_WKUP, shared = [rtc])]`
			`fn rtc_wakeup(mut ctx: rtc_wakeup::Context) {`
			`defmt::warn!("RTC INTERRUPT!!!!");`
			`ctx.shared.rtc.lock(\|rtc\|{`
			`let current_time = rtc.get_datetime();`
			`rtc.clear_interrupt(Event::Wakeup);`
			`defmt::info!("Current time {:?}", current_time.as_hms() );`
			`});`
			`// Your RTC wakeup interrupt handling code here`
			`}`
			`}`