embassy/embassy-stm32/src/adc/v1.rs

use core::future::poll_fn;
use core::marker::PhantomData;
use core::task::Poll;

use embassy_hal_internal::into_ref;
use embedded_hal_02::blocking::delay::DelayUs;

use crate::adc::{Adc, AdcPin, Instance, Resolution, SampleTime};
use crate::interrupt::typelevel::Interrupt;
use crate::peripherals::ADC;
use crate::{interrupt, Peripheral};

pub const VDDA_CALIB_MV: u32 = 3300;
pub const VREF_INT: u32 = 1230;

/// Interrupt handler.
pub struct InterruptHandler<T: Instance> {
    _phantom: PhantomData<T>,
}

impl<T: Instance> interrupt::typelevel::Handler<T::Interrupt> for InterruptHandler<T> {
    unsafe fn on_interrupt() {
        if T::regs().isr().read().eoc() {
            T::regs().ier().modify(|w| w.set_eocie(false));
        } else {
            return;
        }

        T::state().waker.wake();
    }
}

pub struct Vbat;
impl AdcPin<ADC> for Vbat {}
impl super::sealed::AdcPin<ADC> for Vbat {
    fn channel(&self) -> u8 {
        18
    }
}

pub struct Vref;
impl AdcPin<ADC> for Vref {}
impl super::sealed::AdcPin<ADC> for Vref {
    fn channel(&self) -> u8 {
        17
    }
}

pub struct Temperature;
impl AdcPin<ADC> for Temperature {}
impl super::sealed::AdcPin<ADC> for Temperature {
    fn channel(&self) -> u8 {
        16
    }
}

impl<'d, T: Instance> Adc<'d, T> {
    pub fn new(
        adc: impl Peripheral<P = T> + 'd,
        _irq: impl interrupt::typelevel::Binding<T::Interrupt, InterruptHandler<T>> + 'd,
        delay: &mut impl DelayUs<u32>,
    ) -> Self {
        into_ref!(adc);
        T::enable();
        T::reset();

        // Delay 1μs when using HSI14 as the ADC clock.
        //
        // Table 57. ADC characteristics
        // tstab = 14 * 1/fadc
        delay.delay_us(1);

        // A.7.1 ADC calibration code example
        T::regs().cfgr1().modify(|reg| reg.set_dmaen(false));
        T::regs().cr().modify(|reg| reg.set_adcal(true));
        while T::regs().cr().read().adcal() {}

        // A.7.2 ADC enable sequence code example
        if T::regs().isr().read().adrdy() {
            T::regs().isr().modify(|reg| reg.set_adrdy(true));
        }
        T::regs().cr().modify(|reg| reg.set_aden(true));
        while !T::regs().isr().read().adrdy() {
            // ES0233, 2.4.3 ADEN bit cannot be set immediately after the ADC calibration
            // Workaround: When the ADC calibration is complete (ADCAL = 0), keep setting the
            // ADEN bit until the ADRDY flag goes high.
            T::regs().cr().modify(|reg| reg.set_aden(true));
        }

        T::Interrupt::unpend();
        unsafe {
            T::Interrupt::enable();
        }

        Self {
            adc,
            sample_time: Default::default(),
        }
    }

    pub fn enable_vbat(&self, _delay: &mut impl DelayUs<u32>) -> Vbat {
        // SMP must be ≥ 56 ADC clock cycles when using HSI14.
        //
        // 6.3.20 Vbat monitoring characteristics
        // ts_vbat ≥ 4μs
        T::regs().ccr().modify(|reg| reg.set_vbaten(true));
        Vbat
    }

    pub fn enable_vref(&self, delay: &mut impl DelayUs<u32>) -> Vref {
        // Table 28. Embedded internal reference voltage
        // tstart = 10μs
        T::regs().ccr().modify(|reg| reg.set_vrefen(true));
        delay.delay_us(10);
        Vref
    }

    pub fn enable_temperature(&self, delay: &mut impl DelayUs<u32>) -> Temperature {
        // SMP must be ≥ 56 ADC clock cycles when using HSI14.
        //
        // 6.3.19 Temperature sensor characteristics
        // tstart ≤ 10μs
        // ts_temp ≥ 4μs
        T::regs().ccr().modify(|reg| reg.set_tsen(true));
        delay.delay_us(10);
        Temperature
    }

    pub fn set_sample_time(&mut self, sample_time: SampleTime) {
        self.sample_time = sample_time;
    }

    pub fn set_resolution(&mut self, resolution: Resolution) {
        T::regs().cfgr1().modify(|reg| reg.set_res(resolution.into()));
    }

    pub async fn read(&mut self, pin: &mut impl AdcPin<T>) -> u16 {
        let channel = pin.channel();
        pin.set_as_analog();

        // A.7.5 Single conversion sequence code example - Software trigger
        T::regs().chselr().write(|reg| reg.set_chselx(channel as usize, true));

        self.convert().await
    }

    async fn convert(&mut self) -> u16 {
        T::regs().isr().modify(|reg| {
            reg.set_eoc(true);
            reg.set_eosmp(true);
        });

        T::regs().smpr().modify(|reg| reg.set_smp(self.sample_time.into()));
        T::regs().ier().modify(|w| w.set_eocie(true));
        T::regs().cr().modify(|reg| reg.set_adstart(true));

        poll_fn(|cx| {
            T::state().waker.register(cx.waker());

            if T::regs().isr().read().eoc() {
                Poll::Ready(())
            } else {
                Poll::Pending
            }
        })
        .await;

        T::regs().dr().read().data()
    }
}

impl<'d, T: Instance> Drop for Adc<'d, T> {
    fn drop(&mut self) {
        // A.7.3 ADC disable code example
        T::regs().cr().modify(|reg| reg.set_adstp(true));
        while T::regs().cr().read().adstp() {}

        T::regs().cr().modify(|reg| reg.set_addis(true));
        while T::regs().cr().read().aden() {}

        T::disable();
    }
}
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`use core::future::poll_fn;`
			`use core::marker::PhantomData;`
			`use core::task::Poll;`

Rename embassy-hal-common to embassy-hal-internal, document it's for internal use only. (#1700) 2023-07-28 11:23:22 +00:00			`use embassy_hal_internal::into_ref;`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`use embedded_hal_02::blocking::delay::DelayUs;`

stm32/adc: cleanup f1, f3, v1, and v2 2023-09-28 01:58:46 +00:00			`use crate::adc::{Adc, AdcPin, Instance, Resolution, SampleTime};`
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`use crate::interrupt::typelevel::Interrupt;`
Change ADC1 to ADC 2023-04-05 21:52:32 +00:00			`use crate::peripherals::ADC;`
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`use crate::{interrupt, Peripheral};`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00
			`pub const VDDA_CALIB_MV: u32 = 3300;`
			`pub const VREF_INT: u32 = 1230;`

stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`/// Interrupt handler.`
			`pub struct InterruptHandler<T: Instance> {`
			`_phantom: PhantomData<T>,`
			`}`

			`impl<T: Instance> interrupt::typelevel::Handler<T::Interrupt> for InterruptHandler<T> {`
			`unsafe fn on_interrupt() {`
			`if T::regs().isr().read().eoc() {`
			`T::regs().ier().modify(\|w\| w.set_eocie(false));`
			`} else {`
			`return;`
			`}`

			`T::state().waker.wake();`
			`}`
			`}`

Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`pub struct Vbat;`
stm32/adc: cleanup f1, f3, v1, and v2 2023-09-28 01:58:46 +00:00			`impl AdcPin<ADC> for Vbat {}`
			`impl super::sealed::AdcPin<ADC> for Vbat {`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`fn channel(&self) -> u8 {`
			`18`
			`}`
			`}`

			`pub struct Vref;`
stm32/adc: cleanup f1, f3, v1, and v2 2023-09-28 01:58:46 +00:00			`impl AdcPin<ADC> for Vref {}`
			`impl super::sealed::AdcPin<ADC> for Vref {`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`fn channel(&self) -> u8 {`
			`17`
			`}`
			`}`

			`pub struct Temperature;`
stm32/adc: cleanup f1, f3, v1, and v2 2023-09-28 01:58:46 +00:00			`impl AdcPin<ADC> for Temperature {}`
			`impl super::sealed::AdcPin<ADC> for Temperature {`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`fn channel(&self) -> u8 {`
			`16`
			`}`
			`}`

			`impl<'d, T: Instance> Adc<'d, T> {`
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`pub fn new(`
			`adc: impl Peripheral<P = T> + 'd,`
			`_irq: impl interrupt::typelevel::Binding<T::Interrupt, InterruptHandler<T>> + 'd,`
			`delay: &mut impl DelayUs<u32>,`
			`) -> Self {`
wip 2023-04-05 19:31:32 +00:00			`into_ref!(adc);`
Properly enable and reset adc 2023-04-05 20:28:42 +00:00			`T::enable();`
			`T::reset();`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00
			`// Delay 1μs when using HSI14 as the ADC clock.`
			`//`
			`// Table 57. ADC characteristics`
			`// tstab = 14 * 1/fadc`
			`delay.delay_us(1);`

stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`// A.7.1 ADC calibration code example`
			`T::regs().cfgr1().modify(\|reg\| reg.set_dmaen(false));`
			`T::regs().cr().modify(\|reg\| reg.set_adcal(true));`
			`while T::regs().cr().read().adcal() {}`

			`// A.7.2 ADC enable sequence code example`
			`if T::regs().isr().read().adrdy() {`
			`T::regs().isr().modify(\|reg\| reg.set_adrdy(true));`
			`}`
			`T::regs().cr().modify(\|reg\| reg.set_aden(true));`
			`while !T::regs().isr().read().adrdy() {`
			`// ES0233, 2.4.3 ADEN bit cannot be set immediately after the ADC calibration`
			`// Workaround: When the ADC calibration is complete (ADCAL = 0), keep setting the`
			`// ADEN bit until the ADRDY flag goes high.`
			`T::regs().cr().modify(\|reg\| reg.set_aden(true));`
			`}`

			`T::Interrupt::unpend();`
			`unsafe {`
			`T::Interrupt::enable();`
			`}`

			`Self {`
wip 2023-04-05 19:31:32 +00:00			`adc,`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`sample_time: Default::default(),`
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`}`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`}`

			`pub fn enable_vbat(&self, _delay: &mut impl DelayUs<u32>) -> Vbat {`
			`// SMP must be ≥ 56 ADC clock cycles when using HSI14.`
			`//`
			`// 6.3.20 Vbat monitoring characteristics`
			`// ts_vbat ≥ 4μs`
stm32: update stm32-metapac. 2023-06-19 01:07:26 +00:00			`T::regs().ccr().modify(\|reg\| reg.set_vbaten(true));`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`Vbat`
			`}`

			`pub fn enable_vref(&self, delay: &mut impl DelayUs<u32>) -> Vref {`
			`// Table 28. Embedded internal reference voltage`
			`// tstart = 10μs`
stm32: update stm32-metapac. 2023-06-19 01:07:26 +00:00			`T::regs().ccr().modify(\|reg\| reg.set_vrefen(true));`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`delay.delay_us(10);`
			`Vref`
			`}`

			`pub fn enable_temperature(&self, delay: &mut impl DelayUs<u32>) -> Temperature {`
			`// SMP must be ≥ 56 ADC clock cycles when using HSI14.`
			`//`
			`// 6.3.19 Temperature sensor characteristics`
			`// tstart ≤ 10μs`
			`// ts_temp ≥ 4μs`
stm32: update stm32-metapac. 2023-06-19 01:07:26 +00:00			`T::regs().ccr().modify(\|reg\| reg.set_tsen(true));`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`delay.delay_us(10);`
			`Temperature`
			`}`

			`pub fn set_sample_time(&mut self, sample_time: SampleTime) {`
			`self.sample_time = sample_time;`
			`}`

			`pub fn set_resolution(&mut self, resolution: Resolution) {`
stm32: update stm32-metapac. 2023-06-19 01:07:26 +00:00			`T::regs().cfgr1().modify(\|reg\| reg.set_res(resolution.into()));`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`}`

stm32/adc: cleanup f1, f3, v1, and v2 2023-09-28 01:58:46 +00:00			`pub async fn read(&mut self, pin: &mut impl AdcPin<T>) -> u16 {`
Differentiate between `read` and `read_internal` for STM32F0 ADC The internal channels (vbat, vref, and temperature) are not real pins and do not have the `set_as_analog` method. They must be read using the `read_internal` method. 2022-10-03 18:18:37 +00:00			`let channel = pin.channel();`
stm32: update stm32-metapac. 2023-06-19 01:07:26 +00:00			`pin.set_as_analog();`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00
stm32/adc: cleanup f1, f3, v1, and v2 2023-09-28 01:58:46 +00:00			`// A.7.5 Single conversion sequence code example - Software trigger`
			`T::regs().chselr().write(\|reg\| reg.set_chselx(channel as usize, true));`

			`self.convert().await`
Differentiate between `read` and `read_internal` for STM32F0 ADC The internal channels (vbat, vref, and temperature) are not real pins and do not have the `set_as_analog` method. They must be read using the `read_internal` method. 2022-10-03 18:18:37 +00:00			`}`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`async fn convert(&mut self) -> u16 {`
Differentiate between `read` and `read_internal` for STM32F0 ADC The internal channels (vbat, vref, and temperature) are not real pins and do not have the `set_as_analog` method. They must be read using the `read_internal` method. 2022-10-03 18:18:37 +00:00			`T::regs().isr().modify(\|reg\| {`
			`reg.set_eoc(true);`
			`reg.set_eosmp(true);`
			`});`

wip 2023-04-05 19:31:32 +00:00			`T::regs().smpr().modify(\|reg\| reg.set_smp(self.sample_time.into()));`
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`T::regs().ier().modify(\|w\| w.set_eocie(true));`
Differentiate between `read` and `read_internal` for STM32F0 ADC The internal channels (vbat, vref, and temperature) are not real pins and do not have the `set_as_analog` method. They must be read using the `read_internal` method. 2022-10-03 18:18:37 +00:00			`T::regs().cr().modify(\|reg\| reg.set_adstart(true));`

stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`poll_fn(\|cx\| {`
			`T::state().waker.register(cx.waker());`

			`if T::regs().isr().read().eoc() {`
			`Poll::Ready(())`
			`} else {`
			`Poll::Pending`
			`}`
			`})`
			`.await;`

			`T::regs().dr().read().data()`
			`}`
			`}`

			`impl<'d, T: Instance> Drop for Adc<'d, T> {`
			`fn drop(&mut self) {`
Differentiate between `read` and `read_internal` for STM32F0 ADC The internal channels (vbat, vref, and temperature) are not real pins and do not have the `set_as_analog` method. They must be read using the `read_internal` method. 2022-10-03 18:18:37 +00:00			`// A.7.3 ADC disable code example`
			`T::regs().cr().modify(\|reg\| reg.set_adstp(true));`
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`while T::regs().cr().read().adstp() {}`

Differentiate between `read` and `read_internal` for STM32F0 ADC The internal channels (vbat, vref, and temperature) are not real pins and do not have the `set_as_analog` method. They must be read using the `read_internal` method. 2022-10-03 18:18:37 +00:00			`T::regs().cr().modify(\|reg\| reg.set_addis(true));`
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`while T::regs().cr().read().aden() {}`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00
stm32/adc: make v1 async and leave en 2023-09-20 21:07:35 +00:00			`T::disable();`
Add implementation of STM32 v1 ADC 2022-09-14 03:08:03 +00:00			`}`
			`}`