Crates.io | ruspiro-console |
lib.rs | ruspiro-console |
version | 0.5.3 |
source | src |
created_at | 2019-07-30 07:52:33.413618 |
updated_at | 2021-01-30 21:31:26.536281 |
description | Lightweight console abstraction for bare metal implementations to print strings to an output channel that could be easely configured/attached. |
homepage | |
repository | https://github.com/RusPiRo/ruspiro-console/tree/v0.5.3 |
max_upload_size | |
id | 152844 |
size | 36,730 |
This crate provides a console abstraction to enable string output to a configurable output channel. It also provides the convinient macros (print!
and println!
) to output text that are usually not available in [no_std]
environments. However this crate also provide macros to indicate the severity of the message that shall be printed. Those are info!
, warn!
and error!
.
This crate uses macros to provide formatted strings. This formatting requires a memory allocator to be present (as part of the alloc
crate). So when using this crate provide an allocator such as ruspiro_allocator
.
To use the crate just add the following dependency to your Cargo.toml
file:
[dependencies]
ruspiro-console = "0.5.3"
Once the console crate is available the common macros used to output strings print!
and println
could be used.
However, without actually setting a console output those statements will not write any data anywhere:
use ruspiro_console::*;
fn demo() {
let num: u32 = 10;
println!("This is some text with a number: {}", num);
}
To actually set an active output channel you need to provide a structure that implements the core::fmt::Write
trait. This
for example is done in the Uart like so:
impl core::fmt::Write for Uart1 {
fn write_str(&mut self, s: &str) -> core::fmt::Result {
self.send_string(s);
Ok(())
}
}
If this trait has been implemented this structure can be used as actual console. To use it there should be the following code written at the earliest possible point in the main crate of the binary (e.g. the kernel)
use ruspiro_console::*;
use ruspiro_uart::*; // as we demonstrate the usage with the Uart.
fn demo() {
let mut uart = Uart1::new(); // create a new uart struct
if uart.initialize(250_000_000, 115_200).is_ok() { // initialize the Uart with fixed core rate and baud rate
CONSOLE.with_mut(|cons| cons.replace(uart)); // from this point CONSOLE takes ownership of Uart
// uncommenting the following line will give compiler error as uart is moved
// uart.send_string("I'm assigned to a console");
}
// if everything went fine uart should be assigned to the console for generic output
println!("Console is ready and display's through uart");
}
You can also use the console crate to initialize logging to the Uart when using the info!
, warn!
or error!
macros from the log.
use ruspiro_console::*;
use ruspiro_uart::*; // as we demonstrate the usage with the Uart.
fn demo() {
let mut uart = Uart1::new(); // create a new uart struct
if uart.initialize(250_000_000, 115_200).is_ok() { // initialize the Uart with fixed core rate and baud rate
init_logger(LevelFilter::Error, uart); // from this point the logger takes ownership of uart
}
// if everything went fine uart should be assigned to the console for generic output
println!("Console is ready and display's through uart");
}
!HINT! As the
Write
trait requires the structure to be mutable when writing to the output channel the console operations are blocking operations -> thus requiring atomic operations to be possible -> thus requiring the MMU to be activated before using the console abstraction is possible. Otherwise execution will hang as atomics are not able to be processed by the CPU.
Licensed under Apache License, Version 2.0, (LICENSE-APACHE or http://www.apache.org/licenses/LICENSE-2.0) or MIT (LICENSE-MIT or http://opensource.org/licenses/MIT)) at your choice.