use core::task::Poll; use embassy_hal_common::{into_ref, PeripheralRef}; use embassy_sync::waitqueue::AtomicWaker; use futures::future::poll_fn; use crate::gpio::sealed::AFType; use crate::gpio::Speed; use crate::interrupt::{Interrupt, InterruptExt}; use crate::Peripheral; /// The level on the VSync pin when the data is not valid on the parallel interface. #[derive(Clone, Copy, PartialEq)] pub enum VSyncDataInvalidLevel { Low, High, } /// The level on the VSync pin when the data is not valid on the parallel interface. #[derive(Clone, Copy, PartialEq)] pub enum HSyncDataInvalidLevel { Low, High, } #[derive(Clone, Copy, PartialEq)] pub enum PixelClockPolarity { RisingEdge, FallingEdge, } pub struct State { waker: AtomicWaker, } impl State { const fn new() -> State { State { waker: AtomicWaker::new(), } } } static STATE: State = State::new(); #[derive(Debug, Eq, PartialEq, Copy, Clone)] #[cfg_attr(feature = "defmt", derive(defmt::Format))] #[non_exhaustive] pub enum Error { Overrun, PeripheralError, } #[non_exhaustive] pub struct Config { pub vsync_level: VSyncDataInvalidLevel, pub hsync_level: HSyncDataInvalidLevel, pub pixclk_polarity: PixelClockPolarity, } impl Default for Config { fn default() -> Self { Self { vsync_level: VSyncDataInvalidLevel::High, hsync_level: HSyncDataInvalidLevel::Low, pixclk_polarity: PixelClockPolarity::RisingEdge, } } } macro_rules! config_pins { ($($pin:ident),*) => { into_ref!($($pin),*); // NOTE(unsafe) Exclusive access to the registers critical_section::with(|_| unsafe { $( $pin.set_as_af($pin.af_num(), AFType::Input); $pin.set_speed(Speed::VeryHigh); )* }) }; } pub struct Dcmi<'d, T: Instance, Dma: FrameDma> { inner: PeripheralRef<'d, T>, dma: PeripheralRef<'d, Dma>, } impl<'d, T, Dma> Dcmi<'d, T, Dma> where T: Instance, Dma: FrameDma, { pub fn new_8bit( peri: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, irq: impl Peripheral

+ 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, d4: impl Peripheral

> + 'd, d5: impl Peripheral

> + 'd, d6: impl Peripheral

> + 'd, d7: impl Peripheral

> + 'd, v_sync: impl Peripheral

> + 'd, h_sync: impl Peripheral

> + 'd, pixclk: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(peri, dma, irq); config_pins!(d0, d1, d2, d3, d4, d5, d6, d7); config_pins!(v_sync, h_sync, pixclk); Self::new_inner(peri, dma, irq, config, false, 0b00) } pub fn new_10bit( peri: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, irq: impl Peripheral

+ 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, d4: impl Peripheral

> + 'd, d5: impl Peripheral

> + 'd, d6: impl Peripheral

> + 'd, d7: impl Peripheral

> + 'd, d8: impl Peripheral

> + 'd, d9: impl Peripheral

> + 'd, v_sync: impl Peripheral

> + 'd, h_sync: impl Peripheral

> + 'd, pixclk: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(peri, dma, irq); config_pins!(d0, d1, d2, d3, d4, d5, d6, d7, d8, d9); config_pins!(v_sync, h_sync, pixclk); Self::new_inner(peri, dma, irq, config, false, 0b01) } pub fn new_12bit( peri: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, irq: impl Peripheral

+ 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, d4: impl Peripheral

> + 'd, d5: impl Peripheral

> + 'd, d6: impl Peripheral

> + 'd, d7: impl Peripheral

> + 'd, d8: impl Peripheral

> + 'd, d9: impl Peripheral

> + 'd, d10: impl Peripheral

> + 'd, d11: impl Peripheral

> + 'd, v_sync: impl Peripheral

> + 'd, h_sync: impl Peripheral

> + 'd, pixclk: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(peri, dma, irq); config_pins!(d0, d1, d2, d3, d4, d5, d6, d7, d8, d9, d10, d11); config_pins!(v_sync, h_sync, pixclk); Self::new_inner(peri, dma, irq, config, false, 0b10) } pub fn new_14bit( peri: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, irq: impl Peripheral

+ 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, d4: impl Peripheral

> + 'd, d5: impl Peripheral

> + 'd, d6: impl Peripheral

> + 'd, d7: impl Peripheral

> + 'd, d8: impl Peripheral

> + 'd, d9: impl Peripheral

> + 'd, d10: impl Peripheral

> + 'd, d11: impl Peripheral

> + 'd, d12: impl Peripheral

> + 'd, d13: impl Peripheral

> + 'd, v_sync: impl Peripheral

> + 'd, h_sync: impl Peripheral

> + 'd, pixclk: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(peri, dma, irq); config_pins!(d0, d1, d2, d3, d4, d5, d6, d7, d8, d9, d10, d11, d12, d13); config_pins!(v_sync, h_sync, pixclk); Self::new_inner(peri, dma, irq, config, false, 0b11) } pub fn new_es_8bit( peri: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, irq: impl Peripheral

+ 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, d4: impl Peripheral

> + 'd, d5: impl Peripheral

> + 'd, d6: impl Peripheral

> + 'd, d7: impl Peripheral

> + 'd, pixclk: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(peri, dma, irq); config_pins!(d0, d1, d2, d3, d4, d5, d6, d7); config_pins!(pixclk); Self::new_inner(peri, dma, irq, config, true, 0b00) } pub fn new_es_10bit( peri: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, irq: impl Peripheral

+ 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, d4: impl Peripheral

> + 'd, d5: impl Peripheral

> + 'd, d6: impl Peripheral

> + 'd, d7: impl Peripheral

> + 'd, d8: impl Peripheral

> + 'd, d9: impl Peripheral

> + 'd, pixclk: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(peri, dma, irq); config_pins!(d0, d1, d2, d3, d4, d5, d6, d7, d8, d9); config_pins!(pixclk); Self::new_inner(peri, dma, irq, config, true, 0b01) } pub fn new_es_12bit( peri: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, irq: impl Peripheral

+ 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, d4: impl Peripheral

> + 'd, d5: impl Peripheral

> + 'd, d6: impl Peripheral

> + 'd, d7: impl Peripheral

> + 'd, d8: impl Peripheral

> + 'd, d9: impl Peripheral

> + 'd, d10: impl Peripheral

> + 'd, d11: impl Peripheral

> + 'd, pixclk: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(peri, dma, irq); config_pins!(d0, d1, d2, d3, d4, d5, d6, d7, d8, d9, d10, d11); config_pins!(pixclk); Self::new_inner(peri, dma, irq, config, true, 0b10) } pub fn new_es_14bit( peri: impl Peripheral

+ 'd, dma: impl Peripheral

+ 'd, irq: impl Peripheral

+ 'd, d0: impl Peripheral

> + 'd, d1: impl Peripheral

> + 'd, d2: impl Peripheral

> + 'd, d3: impl Peripheral

> + 'd, d4: impl Peripheral

> + 'd, d5: impl Peripheral

> + 'd, d6: impl Peripheral

> + 'd, d7: impl Peripheral

> + 'd, d8: impl Peripheral

> + 'd, d9: impl Peripheral

> + 'd, d10: impl Peripheral

> + 'd, d11: impl Peripheral

> + 'd, d12: impl Peripheral

> + 'd, d13: impl Peripheral

> + 'd, pixclk: impl Peripheral

> + 'd, config: Config, ) -> Self { into_ref!(peri, dma, irq); config_pins!(d0, d1, d2, d3, d4, d5, d6, d7, d8, d9, d10, d11, d12, d13); config_pins!(pixclk); Self::new_inner(peri, dma, irq, config, true, 0b11) } fn new_inner( peri: PeripheralRef<'d, T>, dma: PeripheralRef<'d, Dma>, irq: PeripheralRef<'d, T::Interrupt>, config: Config, use_embedded_synchronization: bool, edm: u8, ) -> Self { T::reset(); T::enable(); unsafe { peri.regs().cr().modify(|r| { r.set_cm(true); // disable continuous mode (snapshot mode) r.set_ess(use_embedded_synchronization); r.set_pckpol(config.pixclk_polarity == PixelClockPolarity::RisingEdge); r.set_vspol(config.vsync_level == VSyncDataInvalidLevel::High); r.set_hspol(config.hsync_level == HSyncDataInvalidLevel::High); r.set_fcrc(0x00); // capture every frame r.set_edm(edm); // extended data mode }); } irq.set_handler(Self::on_interrupt); irq.unpend(); irq.enable(); Self { inner: peri, dma } } unsafe fn on_interrupt(_: *mut ()) { let ris = crate::pac::DCMI.ris().read(); if ris.err_ris() { trace!("DCMI IRQ: Error."); crate::pac::DCMI.ier().modify(|ier| ier.set_err_ie(false)); } if ris.ovr_ris() { trace!("DCMI IRQ: Overrun."); crate::pac::DCMI.ier().modify(|ier| ier.set_ovr_ie(false)); } if ris.frame_ris() { trace!("DCMI IRQ: Frame captured."); crate::pac::DCMI.ier().modify(|ier| ier.set_frame_ie(false)); } STATE.waker.wake(); } unsafe fn toggle(enable: bool) { crate::pac::DCMI.cr().modify(|r| { r.set_enable(enable); r.set_capture(enable); }) } fn enable_irqs() { unsafe { crate::pac::DCMI.ier().modify(|r| { r.set_err_ie(true); r.set_ovr_ie(true); r.set_frame_ie(true); }); } } fn clear_interrupt_flags() { unsafe { crate::pac::DCMI.icr().write(|r| { r.set_ovr_isc(true); r.set_err_isc(true); r.set_frame_isc(true); }) } } /// This method starts the capture and finishes when both the dma transfer and DCMI finish the frame transfer. /// The implication is that the input buffer size must be exactly the size of the captured frame. /// /// Note that when `buffer.len() > 0xffff` the capture future requires some real-time guarantees to be upheld /// (must be polled fast enough so the buffers get switched before data is overwritten). /// It is therefore recommended that it is run on higher priority executor. pub async fn capture(&mut self, buffer: &mut [u32]) -> Result<(), Error> { if buffer.len() <= 0xffff { return self.capture_small(buffer).await; } else { return self.capture_giant(buffer).await; } } async fn capture_small(&mut self, buffer: &mut [u32]) -> Result<(), Error> { let channel = &mut self.dma; let request = channel.request(); let r = self.inner.regs(); let src = r.dr().ptr() as *mut u32; let dma_read = crate::dma::read(channel, request, src, buffer); Self::clear_interrupt_flags(); Self::enable_irqs(); unsafe { Self::toggle(true) }; let result = poll_fn(|cx| { STATE.waker.register(cx.waker()); let ris = unsafe { crate::pac::DCMI.ris().read() }; if ris.err_ris() { unsafe { crate::pac::DCMI.icr().write(|r| { r.set_err_isc(true); }) }; Poll::Ready(Err(Error::PeripheralError)) } else if ris.ovr_ris() { unsafe { crate::pac::DCMI.icr().write(|r| { r.set_ovr_isc(true); }) }; Poll::Ready(Err(Error::Overrun)) } else if ris.frame_ris() { unsafe { crate::pac::DCMI.icr().write(|r| { r.set_frame_isc(true); }) }; Poll::Ready(Ok(())) } else { Poll::Pending } }); let (_, result) = futures::future::join(dma_read, result).await; unsafe { Self::toggle(false) }; result } async fn capture_giant(&mut self, buffer: &mut [u32]) -> Result<(), Error> { use crate::dma::TransferOptions; let data_len = buffer.len(); let chunk_estimate = data_len / 0xffff; let mut chunks = chunk_estimate + 1; while data_len % chunks != 0 { chunks += 1; } let chunk_size = data_len / chunks; let mut remaining_chunks = chunks - 2; let mut m0ar = buffer.as_mut_ptr(); let mut m1ar = unsafe { buffer.as_mut_ptr().add(chunk_size) }; let channel = &mut self.dma; let request = channel.request(); let r = self.inner.regs(); let src = r.dr().ptr() as *mut u32; unsafe { channel.start_double_buffered_read(request, src, m0ar, m1ar, chunk_size, TransferOptions::default()); } let mut last_chunk_set_for_transfer = false; let mut buffer0_last_accessible = false; let dma_result = poll_fn(|cx| { channel.set_waker(cx.waker()); let buffer0_currently_accessible = unsafe { channel.is_buffer0_accessible() }; // check if the accessible buffer changed since last poll if buffer0_last_accessible == buffer0_currently_accessible { return Poll::Pending; } buffer0_last_accessible = !buffer0_last_accessible; if remaining_chunks != 0 { if remaining_chunks % 2 == 0 && buffer0_currently_accessible { m0ar = unsafe { m0ar.add(2 * chunk_size) }; unsafe { channel.set_buffer0(m0ar) } remaining_chunks -= 1; } else if !buffer0_currently_accessible { m1ar = unsafe { m1ar.add(2 * chunk_size) }; unsafe { channel.set_buffer1(m1ar) }; remaining_chunks -= 1; } } else { if buffer0_currently_accessible { unsafe { channel.set_buffer0(buffer.as_mut_ptr()) } } else { unsafe { channel.set_buffer1(buffer.as_mut_ptr()) } } if last_chunk_set_for_transfer { channel.request_stop(); return Poll::Ready(()); } last_chunk_set_for_transfer = true; } Poll::Pending }); Self::clear_interrupt_flags(); Self::enable_irqs(); let result = poll_fn(|cx| { STATE.waker.register(cx.waker()); let ris = unsafe { crate::pac::DCMI.ris().read() }; if ris.err_ris() { unsafe { crate::pac::DCMI.icr().write(|r| { r.set_err_isc(true); }) }; Poll::Ready(Err(Error::PeripheralError)) } else if ris.ovr_ris() { unsafe { crate::pac::DCMI.icr().write(|r| { r.set_ovr_isc(true); }) }; Poll::Ready(Err(Error::Overrun)) } else if ris.frame_ris() { unsafe { crate::pac::DCMI.icr().write(|r| { r.set_frame_isc(true); }) }; Poll::Ready(Ok(())) } else { Poll::Pending } }); unsafe { Self::toggle(true) }; let (_, result) = futures::future::join(dma_result, result).await; unsafe { Self::toggle(false) }; result } } mod sealed { pub trait Instance: crate::rcc::RccPeripheral { fn regs(&self) -> crate::pac::dcmi::Dcmi; } } pub trait Instance: sealed::Instance + 'static { type Interrupt: Interrupt; } pin_trait!(D0Pin, Instance); pin_trait!(D1Pin, Instance); pin_trait!(D2Pin, Instance); pin_trait!(D3Pin, Instance); pin_trait!(D4Pin, Instance); pin_trait!(D5Pin, Instance); pin_trait!(D6Pin, Instance); pin_trait!(D7Pin, Instance); pin_trait!(D8Pin, Instance); pin_trait!(D9Pin, Instance); pin_trait!(D10Pin, Instance); pin_trait!(D11Pin, Instance); pin_trait!(D12Pin, Instance); pin_trait!(D13Pin, Instance); pin_trait!(HSyncPin, Instance); pin_trait!(VSyncPin, Instance); pin_trait!(PixClkPin, Instance); // allow unused as U5 sources do not contain interrupt nor dma data #[allow(unused)] macro_rules! impl_peripheral { ($inst:ident, $irq:ident) => { impl sealed::Instance for crate::peripherals::$inst { fn regs(&self) -> crate::pac::dcmi::Dcmi { crate::pac::$inst } } impl Instance for crate::peripherals::$inst { type Interrupt = crate::interrupt::$irq; } }; } foreach_interrupt! { ($inst:ident, dcmi, $block:ident, GLOBAL, $irq:ident) => { impl_peripheral!($inst, $irq); }; } dma_trait!(FrameDma, Instance);