//! HAL interface to the UARTE peripheral //! //! See product specification: //! //! - nrf52832: Section 35 //! - nrf52840: Section 6.34 use core::cell::UnsafeCell; use core::cmp::min; use core::marker::PhantomPinned; use core::ops::Deref; use core::pin::Pin; use core::ptr; use core::sync::atomic::{compiler_fence, Ordering}; use core::task::{Context, Poll}; use embedded_hal::digital::v2::OutputPin; use crate::hal::gpio::{Floating, Input, Output, Pin as GpioPin, Port as GpioPort, PushPull}; use crate::interrupt; use crate::interrupt::CriticalSection; #[cfg(any(feature = "52833", feature = "52840", feature = "9160"))] use crate::pac::UARTE1; use crate::pac::{uarte0, Interrupt, UARTE0}; // Re-export SVD variants to allow user to directly set values pub use uarte0::{baudrate::BAUDRATE_A as Baudrate, config::PARITY_A as Parity}; use embassy::io::{AsyncBufRead, AsyncWrite, Result}; use embassy::util::WakerStore; use defmt::{assert, panic, todo, *}; //use crate::trace; const RINGBUF_SIZE: usize = 512; struct RingBuf { buf: [u8; RINGBUF_SIZE], start: usize, end: usize, empty: bool, } impl RingBuf { fn new() -> Self { RingBuf { buf: [0; RINGBUF_SIZE], start: 0, end: 0, empty: true, } } fn push_buf(&mut self) -> &mut [u8] { if self.start == self.end && !self.empty { trace!(" ringbuf: push_buf empty"); return &mut self.buf[..0]; } let n = if self.start <= self.end { RINGBUF_SIZE - self.end } else { self.start - self.end }; trace!(" ringbuf: push_buf {:?}..{:?}", self.end, self.end + n); &mut self.buf[self.end..self.end + n] } fn push(&mut self, n: usize) { trace!(" ringbuf: push {:?}", n); if n == 0 { return; } self.end = Self::wrap(self.end + n); self.empty = false; } fn pop_buf(&mut self) -> &mut [u8] { if self.empty { trace!(" ringbuf: pop_buf empty"); return &mut self.buf[..0]; } let n = if self.end <= self.start { RINGBUF_SIZE - self.start } else { self.end - self.start }; trace!(" ringbuf: pop_buf {:?}..{:?}", self.start, self.start + n); &mut self.buf[self.start..self.start + n] } fn pop(&mut self, n: usize) { trace!(" ringbuf: pop {:?}", n); if n == 0 { return; } self.start = Self::wrap(self.start + n); self.empty = self.start == self.end; } fn wrap(n: usize) -> usize { assert!(n <= RINGBUF_SIZE); if n == RINGBUF_SIZE { 0 } else { n } } } #[derive(Copy, Clone, Debug, PartialEq)] enum RxState { Idle, Receiving, ReceivingReady, Stopping, } #[derive(Copy, Clone, Debug, PartialEq)] enum TxState { Idle, Transmitting(usize), } /// Interface to a UARTE instance /// /// This is a very basic interface that comes with the following limitations: /// - The UARTE instances share the same address space with instances of UART. /// You need to make sure that conflicting instances /// are disabled before using `Uarte`. See product specification: /// - nrf52832: Section 15.2 /// - nrf52840: Section 6.1.2 pub struct Uarte { started: bool, state: UnsafeCell>, } // public because it needs to be used in Instance::{get_state, set_state}, but // should not be used outside the module #[doc(hidden)] pub struct UarteState { inner: T, rx: RingBuf, rx_state: RxState, rx_waker: WakerStore, tx: RingBuf, tx_state: TxState, tx_waker: WakerStore, _pin: PhantomPinned, } #[cfg(any(feature = "52833", feature = "52840"))] fn port_bit(port: GpioPort) -> bool { match port { GpioPort::Port0 => false, GpioPort::Port1 => true, } } impl Uarte { pub fn new(uarte: T, mut pins: Pins, parity: Parity, baudrate: Baudrate) -> Self { // Select pins uarte.psel.rxd.write(|w| { let w = unsafe { w.pin().bits(pins.rxd.pin()) }; #[cfg(any(feature = "52833", feature = "52840"))] let w = w.port().bit(port_bit(pins.rxd.port())); w.connect().connected() }); pins.txd.set_high().unwrap(); uarte.psel.txd.write(|w| { let w = unsafe { w.pin().bits(pins.txd.pin()) }; #[cfg(any(feature = "52833", feature = "52840"))] let w = w.port().bit(port_bit(pins.txd.port())); w.connect().connected() }); // Optional pins uarte.psel.cts.write(|w| { if let Some(ref pin) = pins.cts { let w = unsafe { w.pin().bits(pin.pin()) }; #[cfg(any(feature = "52833", feature = "52840"))] let w = w.port().bit(port_bit(pin.port())); w.connect().connected() } else { w.connect().disconnected() } }); uarte.psel.rts.write(|w| { if let Some(ref pin) = pins.rts { let w = unsafe { w.pin().bits(pin.pin()) }; #[cfg(any(feature = "52833", feature = "52840"))] let w = w.port().bit(port_bit(pin.port())); w.connect().connected() } else { w.connect().disconnected() } }); // Enable UARTE instance uarte.enable.write(|w| w.enable().enabled()); // Enable interrupts uarte.intenset.write(|w| w.endrx().set().endtx().set()); // Configure let hardware_flow_control = pins.rts.is_some() && pins.cts.is_some(); uarte .config .write(|w| w.hwfc().bit(hardware_flow_control).parity().variant(parity)); // Configure frequency uarte.baudrate.write(|w| w.baudrate().variant(baudrate)); Uarte { started: false, state: UnsafeCell::new(UarteState { inner: uarte, rx: RingBuf::new(), rx_state: RxState::Idle, rx_waker: WakerStore::new(), tx: RingBuf::new(), tx_state: TxState::Idle, tx_waker: WakerStore::new(), _pin: PhantomPinned, }), } } fn with_state<'a, R>( self: Pin<&'a mut Self>, f: impl FnOnce(Pin<&'a mut UarteState>) -> R, ) -> R { let Self { state, started } = unsafe { self.get_unchecked_mut() }; interrupt::free(|cs| { let ptr = state.get(); if !*started { T::set_state(cs, ptr); *started = true; // safety: safe because critical section ensures only one *mut UartState // exists at the same time. unsafe { Pin::new_unchecked(&mut *ptr) }.start(); } // safety: safe because critical section ensures only one *mut UartState // exists at the same time. f(unsafe { Pin::new_unchecked(&mut *ptr) }) }) } } impl Drop for Uarte { fn drop(&mut self) { // stop DMA before dropping, because DMA is using the buffer in `self`. todo!() } } impl AsyncBufRead for Uarte { fn poll_fill_buf(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll> { self.with_state(|s| s.poll_fill_buf(cx)) } fn consume(self: Pin<&mut Self>, amt: usize) { self.with_state(|s| s.consume(amt)) } } impl AsyncWrite for Uarte { fn poll_write(self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &[u8]) -> Poll> { self.with_state(|s| s.poll_write(cx, buf)) } } impl UarteState { pub fn start(self: Pin<&mut Self>) { interrupt::set_priority(T::interrupt(), interrupt::Priority::Level7); interrupt::enable(T::interrupt()); interrupt::pend(T::interrupt()); } fn poll_fill_buf(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll> { let this = unsafe { self.get_unchecked_mut() }; // Conservative compiler fence to prevent optimizations that do not // take in to account actions by DMA. The fence has been placed here, // before any DMA action has started compiler_fence(Ordering::SeqCst); trace!("poll_read"); // We have data ready in buffer? Return it. let buf = this.rx.pop_buf(); if buf.len() != 0 { trace!(" got {:?} {:?}", buf.as_ptr() as u32, buf.len()); return Poll::Ready(Ok(buf)); } trace!(" empty"); if this.rx_state == RxState::ReceivingReady { trace!(" stopping"); this.rx_state = RxState::Stopping; this.inner.tasks_stoprx.write(|w| unsafe { w.bits(1) }); } this.rx_waker.store(cx.waker()); Poll::Pending } fn consume(self: Pin<&mut Self>, amt: usize) { let this = unsafe { self.get_unchecked_mut() }; trace!("consume {:?}", amt); this.rx.pop(amt); interrupt::pend(T::interrupt()); } fn poll_write(self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &[u8]) -> Poll> { let this = unsafe { self.get_unchecked_mut() }; trace!("poll_write: {:?}", buf.len()); let tx_buf = this.tx.push_buf(); if tx_buf.len() == 0 { trace!("poll_write: pending"); this.tx_waker.store(cx.waker()); return Poll::Pending; } let n = min(tx_buf.len(), buf.len()); tx_buf[..n].copy_from_slice(&buf[..n]); this.tx.push(n); trace!("poll_write: queued {:?}", n); // Conservative compiler fence to prevent optimizations that do not // take in to account actions by DMA. The fence has been placed here, // before any DMA action has started compiler_fence(Ordering::SeqCst); interrupt::pend(T::interrupt()); Poll::Ready(Ok(n)) } fn on_interrupt(&mut self) { trace!("irq: start"); let mut more_work = true; while more_work { more_work = false; match self.rx_state { RxState::Idle => { trace!(" irq_rx: in state idle"); if self.inner.events_rxdrdy.read().bits() != 0 { trace!(" irq_rx: rxdrdy?????"); self.inner.events_rxdrdy.reset(); } if self.inner.events_endrx.read().bits() != 0 { panic!("unexpected endrx"); } let buf = self.rx.push_buf(); if buf.len() != 0 { trace!(" irq_rx: starting {:?}", buf.len()); self.rx_state = RxState::Receiving; // Set up the DMA read self.inner.rxd.ptr.write(|w| // The PTR field is a full 32 bits wide and accepts the full range // of values. unsafe { w.ptr().bits(buf.as_ptr() as u32) }); self.inner.rxd.maxcnt.write(|w| // We're giving it the length of the buffer, so no danger of // accessing invalid memory. We have verified that the length of the // buffer fits in an `u8`, so the cast to `u8` is also fine. // // The MAXCNT field is at least 8 bits wide and accepts the full // range of values. unsafe { w.maxcnt().bits(buf.len() as _) }); trace!(" irq_rx: buf {:?} {:?}", buf.as_ptr() as u32, buf.len()); // Enable RXRDY interrupt. self.inner.events_rxdrdy.reset(); self.inner.intenset.write(|w| w.rxdrdy().set()); // Start UARTE Receive transaction self.inner.tasks_startrx.write(|w| // `1` is a valid value to write to task registers. unsafe { w.bits(1) }); } } RxState::Receiving => { trace!(" irq_rx: in state receiving"); if self.inner.events_rxdrdy.read().bits() != 0 { trace!(" irq_rx: rxdrdy"); // Disable the RXRDY event interrupt // RXRDY is triggered for every byte, but we only care about whether we have // some bytes or not. So as soon as we have at least one, disable it, to avoid // wasting CPU cycles in interrupts. self.inner.intenclr.write(|w| w.rxdrdy().clear()); self.inner.events_rxdrdy.reset(); self.rx_waker.wake(); self.rx_state = RxState::ReceivingReady; more_work = true; // in case we also have endrx pending } } RxState::ReceivingReady | RxState::Stopping => { trace!(" irq_rx: in state ReceivingReady"); if self.inner.events_rxdrdy.read().bits() != 0 { trace!(" irq_rx: rxdrdy"); self.inner.events_rxdrdy.reset(); } if self.inner.events_endrx.read().bits() != 0 { let n: usize = self.inner.rxd.amount.read().amount().bits() as usize; trace!(" irq_rx: endrx {:?}", n); self.rx.push(n); self.inner.events_endrx.reset(); self.rx_waker.wake(); self.rx_state = RxState::Idle; more_work = true; // start another rx if possible } } } } more_work = true; while more_work { more_work = false; match self.tx_state { TxState::Idle => { trace!(" irq_tx: in state Idle"); let buf = self.tx.pop_buf(); if buf.len() != 0 { trace!(" irq_tx: starting {:?}", buf.len()); self.tx_state = TxState::Transmitting(buf.len()); // Set up the DMA write self.inner.txd.ptr.write(|w| // The PTR field is a full 32 bits wide and accepts the full range // of values. unsafe { w.ptr().bits(buf.as_ptr() as u32) }); self.inner.txd.maxcnt.write(|w| // We're giving it the length of the buffer, so no danger of // accessing invalid memory. We have verified that the length of the // buffer fits in an `u8`, so the cast to `u8` is also fine. // // The MAXCNT field is 8 bits wide and accepts the full range of // values. unsafe { w.maxcnt().bits(buf.len() as _) }); // Start UARTE Transmit transaction self.inner.tasks_starttx.write(|w| // `1` is a valid value to write to task registers. unsafe { w.bits(1) }); } } TxState::Transmitting(n) => { trace!(" irq_tx: in state Transmitting"); if self.inner.events_endtx.read().bits() != 0 { self.inner.events_endtx.reset(); trace!(" irq_tx: endtx {:?}", n); self.tx.pop(n); self.tx_waker.wake(); self.tx_state = TxState::Idle; more_work = true; // start another tx if possible } } } } trace!("irq: end"); } } pub struct Pins { pub rxd: GpioPin>, pub txd: GpioPin>, pub cts: Option>>, pub rts: Option>>, } mod private { pub trait Sealed {} impl Sealed for crate::pac::UARTE0 {} #[cfg(any(feature = "52833", feature = "52840", feature = "9160"))] impl Sealed for crate::pac::UARTE1 {} } pub trait Instance: Deref + Sized + private::Sealed { fn interrupt() -> Interrupt; #[doc(hidden)] fn get_state(_cs: &CriticalSection) -> *mut UarteState; #[doc(hidden)] fn set_state(_cs: &CriticalSection, state: *mut UarteState); } #[interrupt] unsafe fn UARTE0_UART0() { interrupt::free(|cs| UARTE0::get_state(cs).as_mut().unwrap().on_interrupt()); } #[cfg(any(feature = "52833", feature = "52840", feature = "9160"))] #[interrupt] unsafe fn UARTE1() { interrupt::free(|cs| UARTE1::get_state(cs).as_mut().unwrap().on_interrupt()); } static mut UARTE0_STATE: *mut UarteState = ptr::null_mut(); #[cfg(any(feature = "52833", feature = "52840", feature = "9160"))] static mut UARTE1_STATE: *mut UarteState = ptr::null_mut(); impl Instance for UARTE0 { fn interrupt() -> Interrupt { Interrupt::UARTE0_UART0 } fn get_state(_cs: &CriticalSection) -> *mut UarteState { unsafe { UARTE0_STATE } // Safe because of CriticalSection } fn set_state(_cs: &CriticalSection, state: *mut UarteState) { unsafe { UARTE0_STATE = state } // Safe because of CriticalSection } } #[cfg(any(feature = "52833", feature = "52840", feature = "9160"))] impl Instance for UARTE1 { fn interrupt() -> Interrupt { Interrupt::UARTE1 } fn get_state(_cs: &CriticalSection) -> *mut UarteState { unsafe { UARTE1_STATE } // Safe because of CriticalSection } fn set_state(_cs: &CriticalSection, state: *mut UarteState) { unsafe { UARTE1_STATE = state } // Safe because of CriticalSection } }