time for big update from now on

dma_gpio/src/bin/main.rs

@@ -8,30 +8,38 @@ use embassy_executor::Spawner;
 use embassy_sync::{blocking_mutex::raw::CriticalSectionRawMutex, pipe::Pipe};
 use embassy_time::{Duration, Timer};
 use dma_gpio::dma_timer::init_tim6_for_uart;
+use dma_gpio::dma_timer::init_tim7_for_uart;
+use embassy_stm32::gpio::Input;
+use embassy_stm32::gpio::Pull;
+use dma_gpio::gpio_dma_uart_rx::GpioDmaRx;
 use {defmt_rtt as _, panic_probe as _};
 
 use embassy_stm32::{
     gpio::{Level, Output, Speed},
     peripherals::GPDMA1_CH0,
+    peripherals::GPDMA1_CH1,
 };
 use embassy_stm32::Peri;
 
-use dma_gpio::gpio_dma_uart::{
+use dma_gpio::gpio_dma_uart_tx::{
     write_uart_frames_to_pipe, GpioDmaBsrrTx, Parity, StopBits, UartConfig,
 };
 
-static PIPE: Pipe<CriticalSectionRawMutex, 256> = Pipe::new();
+static PIPE_TX: Pipe<CriticalSectionRawMutex, 256> = Pipe::new();
+static PIPE_RX: Pipe<CriticalSectionRawMutex, 256> = Pipe::new();
 
 // Baud rate: one TIM6 update equals one UART bit-time
 const BAUD: u32 = 115_200;
 const TX_PIN_BIT: u8 = 2; // PA2
-const OVERSAMPLE: u16 = 6;
+const TX_OVERSAMPLE: u16 = 1;
+const RX_OVERSAMPLE: u16 = 16;
 
 const UART_CFG: UartConfig = UartConfig {
     data_bits: 8,
     parity: Parity::None,
     stop_bits: StopBits::One,
 };
+static mut RX_DMA_BUF: [u32; 512] = [0; 512];
 
 fn dump_tim6_regs() {
     // PAC path for STM32U5: module `tim6`, type `Tim6` with ptr()
@@ -79,23 +87,28 @@ fn dump_dma_ch0_regs() {
 #[embassy_executor::main]
 async fn main(spawner: Spawner) {
     let p = embassy_stm32::init(Default::default());
-    info!("DMA Pipe -> GPIO UART-like TX");
+    info!("Hehe");
+
+    // PA3 as Rx "wire"
+    let pa3_rx = Input::new(p.PA3, Pull::Up);
 
     // PA2 is the TX "wire"
     let _pa2 = Output::new(p.PA2, Level::High, Speed::VeryHigh);
     // drop(_pa2);
-    init_tim6_for_uart(p.TIM6, BAUD, OVERSAMPLE);
+    init_tim6_for_uart(p.TIM6, BAUD, TX_OVERSAMPLE); // TX
+    init_tim7_for_uart(p.TIM7, BAUD, RX_OVERSAMPLE); // RX
     dump_tim6_regs();
 
     // Start DMA consumer task
-    spawner.spawn(dma_tx_task(p.GPDMA1_CH0)).unwrap();
+    spawner.spawn(tx_dma_task(p.GPDMA1_CH0)).unwrap();
+    spawner.spawn(rx_dma_task(p.GPDMA1_CH1)).unwrap();
 
     // Example: transmit a string as UART frames via the Pipe
     loop {
         write_uart_frames_to_pipe(
-            &PIPE,
+            &PIPE_TX,
             TX_PIN_BIT,
-            b"Hello, DMA UART (configurable)!\r\n",
+            b"Hello marshmallow\r\n",
             &UART_CFG,
         ).await;
         Timer::after(Duration::from_secs(2)).await;
@@ -103,14 +116,22 @@ async fn main(spawner: Spawner) {
 }
 
 #[embassy_executor::task]
-async fn dma_tx_task(ch: Peri<'static, GPDMA1_CH0>) {
+async fn rx_dma_task(ch: Peri<'static, GPDMA1_CH1>) {
+    let buf_ptr = core::ptr::addr_of_mut!(RX_DMA_BUF);
+    let buf = unsafe { &mut *buf_ptr };
+    let mut rx = GpioDmaRx::new(ch, 3 /*PA3 bit*/, buf, &PIPE_RX);
+    rx.run().await;
+}
+
+#[embassy_executor::task]
+async fn tx_dma_task(ch: Peri<'static, GPDMA1_CH0>) {
     let mut tx = GpioDmaBsrrTx::new(ch);
 
     info!("DMA task started, waiting for frames...");
     loop {
         // Read one 32-bit BSRR word (4 bytes) from the Pipe
         let mut b = [0u8; 4];
-        let n = PIPE.read(&mut b).await;
+        let n = PIPE_TX.read(&mut b).await;
         if n != 4 {
             continue;
         }
@@ -125,7 +146,7 @@ async fn dma_tx_task(ch: Peri<'static, GPDMA1_CH0>) {
         {
             Ok(()) => {}
             Err(_) => {
-                warn!("DMA timeout: no TIM6 request (wrong DMAMUX req?)");
+                warn!("DMA timeout: no TIM6 request");
                 dump_tim6_regs();
                 dump_dma_ch0_regs();
             }

dma_gpio/src/dma_timer.rs

@@ -1,51 +1,58 @@
 // src/dma_timer.rs
 
 use embassy_stm32::{
-    peripherals::TIM6,
+    peripherals::{TIM6, TIM7},
     rcc,
     timer::low_level::Timer,
     Peri,
 };
 use core::mem;
+use embassy_stm32::timer::BasicInstance;
 use embassy_stm32::pac::timer::vals::Urs;
 
 /// Initializes TIM6 to tick at `baud * oversample` frequency.
 /// Each TIM6 update event triggers one DMA beat.
 pub fn init_tim6_for_uart<'d>(tim6: Peri<'d, TIM6>, baud: u32, oversample: u16) {
-
     rcc::enable_and_reset::<TIM6>();
     let ll = Timer::new(tim6);
+    configure_basic_timer(&ll, baud, oversample);
+    mem::forget(ll);
+}
 
-    let f_tim6 = rcc::frequency::<TIM6>().0;
+/// Initializes TIM7 to tick at `baud * oversample` frequency.
+/// Each TIM7 update event triggers one DMA beat.
+pub fn init_tim7_for_uart<'d>(tim7: Peri<'d, TIM7>, baud: u32, oversample: u16) {
+    rcc::enable_and_reset::<TIM7>();
+    let ll = Timer::new(tim7);
+    configure_basic_timer(&ll, baud, oversample);
+    mem::forget(ll);
+}
+
+// Shared internal helper — identical CR1/ARR setup
+fn configure_basic_timer<T: BasicInstance>(ll: &Timer<'_, T>, baud: u32, oversample: u16) {
+    let f_timer = rcc::frequency::<T>().0;
     let target = baud.saturating_mul(oversample.max(1) as u32).max(1);
 
-    // Compute ARR (prescaler=0)
+    // Compute ARR (prescaler = 0)
-    let mut arr = (f_tim6 / target).saturating_sub(1) as u16;
+    let mut arr = (f_timer / target).saturating_sub(1) as u16;
-    if arr == 0 {
+    if arr == 0 { arr = 1; }
-        arr = 1;
-    }
 
     ll.regs_basic().cr1().write(|w| {
         w.set_cen(false);
         w.set_opm(false);
-        w.set_udis(false);          // boolean field: false = allow UEV
+        w.set_udis(false);
-        w.set_urs(Urs::ANY_EVENT);   // enum field: DMA+interrupts on any event
+        w.set_urs(Urs::ANY_EVENT);
     });
 
-    // Write prescaler directly (simple u16 register)
     ll.regs_basic().psc().write_value(0u16);
-
-    // Set ARR, enable DMA request, issue first update
     ll.regs_basic().arr().write(|w| w.set_arr(arr));
     ll.regs_basic().dier().modify(|w| w.set_ude(true));
     ll.regs_basic().egr().write(|w| w.set_ug(true));
 
-    // Start timer
     ll.regs_basic().cr1().write(|w| {
         w.set_opm(false);
         w.set_cen(true);
         w.set_udis(false);
         w.set_urs(Urs::ANY_EVENT);
     });
-    mem::forget(ll);
 }

dma_gpio/src/gpio_dma_uart_rx.rs

@@ -0,0 +1,57 @@
+// src/gpio_dma_uart_rx.rs
+use embassy_stm32::{
+    dma::{Request, Transfer, TransferOptions},
+    peripherals::GPDMA1_CH1,
+    Peri,
+};
+use embassy_sync::{blocking_mutex::raw::CriticalSectionRawMutex, pipe::Pipe};
+
+// RM0456 tabulka 137
+pub const TIM7_UP_REQ: Request = 5;
+
+pub struct GpioDmaRx<'d, const N: usize> {
+    ch: Peri<'d, GPDMA1_CH1>,
+    pin_bit: u8,
+    buf: &'d mut [u32; N],
+    opts: TransferOptions,
+    pipe_rx: &'d Pipe<CriticalSectionRawMutex, 256>,
+}
+
+impl<'d, const N: usize> GpioDmaRx<'d, N> {
+    pub fn new(
+        ch: Peri<'d, GPDMA1_CH1>,
+        pin_bit: u8,
+        buf: &'d mut [u32; N],
+        pipe_rx: &'d Pipe<CriticalSectionRawMutex, 256>,
+    ) -> Self {
+        Self {
+            ch,
+            pin_bit,
+            buf,
+            opts: TransferOptions::default(),
+            pipe_rx,
+        }
+    }
+
+    pub async fn run(&mut self) -> ! {
+        loop {
+            let gpioa_idr_addr = embassy_stm32::pac::GPIOA.as_ptr() as *mut u32;
+
+            unsafe {
+                Transfer::new_read(
+                    self.ch.reborrow(),
+                    TIM7_UP_REQ,
+                    gpioa_idr_addr,
+                    &mut self.buf[..],
+                    self.opts,
+                )
+            }
+            .await;
+
+            for &word in self.buf.iter() {
+                let bit_high = ((word >> self.pin_bit) & 1) as u8;
+                self.pipe_rx.write(&[bit_high]).await;
+            }
+        }
+    }
+}

dma_gpio/src/gpio_dma_uart_tx.rs

@@ -6,6 +6,7 @@ use embassy_stm32::{
 };
 use embassy_sync::{blocking_mutex::raw::CriticalSectionRawMutex, pipe::Pipe};
 
+// kapitola 17.4.11 - 2 casovace pre 2 DMA
 pub const TIM6_UP_REQ: Request = 4; // Table 137: tim6_upd_dma, strana 687 STM32U5xx datasheet
 
 #[derive(Clone, Copy, Debug, PartialEq, Eq)]

dma_gpio/src/lib.rs

@@ -1,7 +1,9 @@
 #![no_std]
 
-pub mod gpio_dma_uart;
+pub mod gpio_dma_uart_tx;
-pub use gpio_dma_uart::*;
+pub mod gpio_dma_uart_rx;
-
 pub mod dma_timer;
+
+pub use gpio_dma_uart_tx::*;
+pub use gpio_dma_uart_rx::*;
 pub use dma_timer::*;

usart_async_buffered_generalized2/src/bin/main.rs

@@ -1,93 +1,51 @@
 // src/bin/main.rs
 #![no_std]
 #![no_main]
+
 use defmt::*;
+use {defmt_rtt as _, panic_probe as _};
+
 use embassy_executor::Spawner;
+use embassy_stm32::usart::{BufferedInterruptHandler, BufferedUart, Config};
 use embassy_stm32::bind_interrupts;
 use embassy_stm32::peripherals;
-use embassy_stm32::usart::{BufferedInterruptHandler, BufferedUart, Config};
+use embassy_time::Instant;
-use embedded_io_async::{Read, Write};
-use embassy_time::{Timer, Duration, Instant};
 use static_cell::StaticCell;
-use embassy_futures::yield_now;
-use {defmt_rtt as _, panic_probe as _};
-use embassy_futures::select::{select, Either};
-use embassy_sync::blocking_mutex::raw::CriticalSectionRawMutex;
-use embassy_sync::pipe::Pipe;
-use async_uart::safety::{preflight_and_suggest_yield_period, RX_PIPE_CAP, TX_PIPE_CAP};
 
-static UART_TX: Pipe<CriticalSectionRawMutex, TX_PIPE_CAP> = Pipe::new();
+use async_uart::uart::usart1;
-static UART_RX: Pipe<CriticalSectionRawMutex, RX_PIPE_CAP> = Pipe::new();
 
-bind_interrupts!(
+bind_interrupts!(struct Irqs {
-    struct Irqs {
+    USART1 => BufferedInterruptHandler<peripherals::USART1>;
-        USART1 => BufferedInterruptHandler<peripherals::USART1>;
+});
-    }
-);
-
-#[embassy_executor::task]
-async fn uart_task(mut uart: BufferedUart<'static>) {
-    let mut rx_byte = [0u8; 1];
-    let mut tx_buf = [0u8; 64];
-    loop {
-        // Wait for either RX or TX events.
-        let rx_fut = uart.read(&mut rx_byte);
-        let tx_fut = async {
-            // Until there's outgoing data in TX pipe
-            let n = UART_TX.read(&mut tx_buf).await;
-            n
-        };
-        match select(rx_fut, tx_fut).await {
-            // Incoming data from UART hardware
-            Either::First(res) => {
-                if let Ok(_) = res {
-                    // Forward to RX pipe
-                    let _ = UART_RX.write(&rx_byte).await;
-                    let _ = UART_TX.try_write(&rx_byte);
-                }
-            }
-            // Outgoing data waiting in TX pipe
-            Either::Second(n) => {
-                unwrap!(uart.write(&tx_buf[..n]).await);
-            }
-        }
-    }
-}
 
 #[embassy_executor::main]
 async fn main(spawner: Spawner) {
-    info!("tititititi");
+    info!("boot");
     let p = embassy_stm32::init(Default::default());
-    static TX_BUF: StaticCell<[u8; 256]> = StaticCell::new();
+
-    static RX_BUF: StaticCell<[u8; 256]> = StaticCell::new();
-    let tx_buf = TX_BUF.init([0; 256]);
-    let rx_buf = RX_BUF.init([0; 256]);
     let mut cfg = Config::default();
     cfg.baudrate = 230_400;
 
-    // Call preflight and get the computed yield period
+    static TX_BUF: StaticCell<[u8; 256]> = StaticCell::new();
-    let yield_period = preflight_and_suggest_yield_period(cfg.baudrate);
+    static RX_BUF: StaticCell<[u8; 256]> = StaticCell::new();
 
-    let usart = BufferedUart::new(
+    let uart = 
-        p.USART1,
+        BufferedUart::new(
-        p.PA10, // RX
+            p.USART1,
-        p.PA9,  // TX
+            p.PA10,
-        tx_buf,
+            p.PA9,
-        rx_buf,
+            TX_BUF.init([0; 256]),
-        Irqs,
+            RX_BUF.init([0; 256]),
-        cfg,
+            Irqs,
-    ).unwrap();
+            cfg,
-    info!("starting uart task");
+        ).unwrap();
-    spawner.spawn(uart_task(usart)).unwrap();
+    let handle = usart1::setup_and_spawn(&spawner, uart, cfg.baudrate);
 
-    let mut counter: u32 = 0;
     let mut rx_buf = [0u8; 64];
     let mut last_yield = Instant::now();
 
     loop {
-        counter = counter.wrapping_add(1);
+        if let Ok(n) = handle.rx.try_read(&mut rx_buf) {
-        // Poll RX pipe for new data (non-blocking)
-        if let Ok(n) = UART_RX.try_read(&mut rx_buf) {
             if n > 0 {
                 if let Ok(s) = core::str::from_utf8(&rx_buf[..n]) {
                     info!("RX got: {}", s);
@@ -97,13 +55,9 @@ async fn main(spawner: Spawner) {
             }
         }
 
-        // Guaranteed to yield before ISR RX buffer can overflow
+        if Instant::now().duration_since(last_yield) >= handle.yield_period {
-        if Instant::now().duration_since(last_yield) >= yield_period {
+            embassy_futures::yield_now().await;
-            yield_now().await;
             last_yield = Instant::now();
-            // info!("Yield mf {}", counter);
         }
-        // Timer::after(Duration::from_micros(1)).await;
-        // Timer::after(Duration::from_secs(5)).await;
     }
 }

usart_async_buffered_generalized2/src/lib.rs

@@ -1,2 +1,2 @@
 #![no_std]
-pub mod safety;
+pub mod uart;

usart_async_buffered_generalized2/src/uart/driver.rs

@@ -0,0 +1,65 @@
+// src/uart/driver.rs
+use defmt::unwrap;
+use embassy_executor::Spawner;
+use embassy_futures::select::{select, Either};
+use embassy_stm32::usart::BufferedUart;
+use embassy_sync::blocking_mutex::raw::CriticalSectionRawMutex;
+use embassy_sync::pipe::Pipe;
+use embassy_time::Duration;
+use embedded_io_async::{Read, Write};
+
+use crate::uart::safety::{RX_PIPE_CAP, TX_PIPE_CAP};
+
+pub struct UartHandle {
+    pub tx: &'static Pipe<CriticalSectionRawMutex, TX_PIPE_CAP>,
+    pub rx: &'static Pipe<CriticalSectionRawMutex, RX_PIPE_CAP>,
+    pub yield_period: Duration,
+}
+
+#[embassy_executor::task]
+pub async fn uart_task(
+    mut uart: BufferedUart<'static>,
+    tx_pipe: &'static Pipe<CriticalSectionRawMutex, TX_PIPE_CAP>,
+    rx_pipe: &'static Pipe<CriticalSectionRawMutex, RX_PIPE_CAP>,
+) {
+    let mut rx_byte = [0u8; 1];
+    let mut tx_buf = [0u8; 64];
+
+    loop {
+        let rx_fut = uart.read(&mut rx_byte);
+        let tx_fut = async {
+            let n = tx_pipe.read(&mut tx_buf).await;
+            n
+        };
+
+        match select(rx_fut, tx_fut).await {
+            // Incoming data from UART hardware
+            Either::First(res) => {
+                if let Ok(_) = res {
+                    // Forward to RX pipe and echo to TX pipe (same behavior as before)
+                    let _ = rx_pipe.write(&rx_byte).await;
+                    let _ = tx_pipe.try_write(&rx_byte);
+                }
+            }
+            // Outgoing data waiting in TX pipe
+            Either::Second(n) => {
+                unwrap!(uart.write(&tx_buf[..n]).await);
+            }
+        }
+    }
+}
+
+pub fn spawn_for(
+    spawner: &Spawner,
+    uart: BufferedUart<'static>,
+    tx_pipe: &'static Pipe<CriticalSectionRawMutex, TX_PIPE_CAP>,
+    rx_pipe: &'static Pipe<CriticalSectionRawMutex, RX_PIPE_CAP>,
+    yield_period: Duration,
+) -> UartHandle {
+    spawner.spawn(uart_task(uart, tx_pipe, rx_pipe)).unwrap();
+    UartHandle {
+        tx: tx_pipe,
+        rx: rx_pipe,
+        yield_period,
+    }
+}

usart_async_buffered_generalized2/src/uart/mod.rs

@@ -0,0 +1,4 @@
+// src/uart/mod.rs
+pub mod driver;
+pub mod usart1;
+pub mod safety;

usart_async_buffered_generalized2/src/uart/usart1.rs

@@ -0,0 +1,23 @@
+// src/uart/usart1.rs
+use defmt::info;
+use embassy_executor::Spawner;
+use embassy_sync::blocking_mutex::raw::CriticalSectionRawMutex;
+use embassy_sync::pipe::Pipe;
+use embassy_time::Duration;
+
+use crate::uart::safety::{preflight_and_suggest_yield_period, RX_PIPE_CAP, TX_PIPE_CAP};
+use crate::uart::driver::{spawn_for, UartHandle};
+
+// Static pipes and buffers
+static UART1_TX_PIPE: Pipe<CriticalSectionRawMutex, TX_PIPE_CAP> = Pipe::new();
+static UART1_RX_PIPE: Pipe<CriticalSectionRawMutex, RX_PIPE_CAP> = Pipe::new();
+
+pub fn setup_and_spawn(
+    spawner: &Spawner,
+    uart: embassy_stm32::usart::BufferedUart<'static>,
+    baudrate: u32,
+) -> UartHandle {
+    let yield_period: Duration = preflight_and_suggest_yield_period(baudrate);
+    info!("USART1 initialized");
+    spawn_for(spawner, uart, &UART1_TX_PIPE, &UART1_RX_PIPE, yield_period)
+}