# Write the Uarte implementation ## Step-by-Step Solution ### Step 1: Check Documentation. The UART protocol requires four pins, they are usually labelled: * RXD * TXD * CTS * RTS Check the User Guide in section 7.2 to find to find out which pins are reserved for these and what their configuration needs to be. ### Step 2: Explore the `nrf-hal` to find out what needs to be done. The `nrf52840-hal` is a crate that exports all the `52840` flagged features from the `nrf-hal-common`. Let's take a look at the nRF-Hal [Uarte module](https://github.com/nrf-rs/nrf-hal/blob/v0.14.1/nrf-hal-common/src/uarte.rs). In line 16 we see, that the nRF52840 uses the `hal::pac::UARTE1` peripheral. In line 44 you find the `struct Uarte(T)`, the interface to a UARTE instance `T`. Besides the instance `T`, the instantiating method takes variables of the following types as arguments: `Pins`, `Parity` and `Baudrate`. A quick search of the document reveals where to find all of them: * `Pins`: Line 463 * `Parity` and `Baudrate`: Re-export on line 34 Add the following lines as import: ``` use hal::pac::uarte0::{ baudrate::BAUDRATE_A as Baudrate, config::PARITY_A as Parity}; use hal::uarte; ``` ### Step 3: Add `struct Uarte` that serves as a wrapper for the `UARTE1` instance. The struct has one field labelled `inner`, it contains the `UARTE1` instance: `hal::Uarte`. ### Step 4: Bring up the peripheral in the `fn init()` Take a closer look at the definition of the `uarte::Pins` struct in the `nrf-hal`. Compare the pin type configurations with the ones you have already imported in `lib.rs`. Add the ones you're missing. Create an instance of this struct in `fn init()` with the appropriate pins and configurations. Set the output pin's level to `Level::High`. Note, that the third and fourth pin are each wrapped in an `Option`. Create an interface to the UARTE1 instance with `uarte::Uarte::new(...)` that you bind to a variable. This instantiating method takes four arguments: * The `UARTE1` instance can be found in the `periph` variable. * Your instance of the `uarte::Pins` struct. * Set parity to `Parity::INCLUDED` * set the baud rate to `Baudrate::BAUD115200`. ### Step 5: Board struct Add a field for the `Uarte` struct in the `Board` struct. add the field to the instance of the `Board` struct in `fn init()`. ### Step 6: Implementing the `fmt::Write` trait We can't just write to the `Uarte` instance. A simple write would write from flash memory. This does not work because of EasyDMA. We have to write a function that implements the `fmt::Write` trait. This trait guarantees that the buffer is fully and successfully written on a stack allocated buffer, before it returns. Add `use::core::fmt;` to your imports. Create a public method `write_str`. It takes a mutable reference to self and a `&str` as argument. It returns an `fmt::Result` Create a buffer. The type is an `array` of 16 u8, set to all 0. To copy all data into an on-stack buffer, iterate over every chunk of the string to copy it into the buffer: ```rust for block in string.as_bytes().chunks(16) { buf[..block.len()].copy_from_slice(block); self.inner.write(&buf[..block.len()]).map_err(|_| fmt::Error)?; } ``` return `Ok(())` ### Step 7: Connect your computer to the virtual UART [directions for mac present, linux and windows are missing.] Use the following command to find the address of the nRF52840-DK on your computer. ``` ls /dev/tty.usbmodem* ``` Run the following command to run `screen` with the nRF52840-DK with 115200 baud. ``` screen
115200 ``` ### Step 7: Run the example. In another terminal window go into the folder `down-the-stack/apps`. Use the following command. ``` cargo run --bin uarte_print ``` On your terminal window where `screen` runs, "Hello, World" should appear. You need to terminate `screen` manually.