#kernel #risc-v #r3 #embedded-systems #port #rtos #r3-os

nightly no-std r3_port_riscv

RISC-V port for the R3-OS original kernel

8 releases

0.3.1 Nov 16, 2022
0.3.0 Aug 16, 2022
0.2.1 Mar 19, 2022
0.1.3 Oct 29, 2021
0.1.0 Nov 2, 2020

#1817 in Embedded development

MIT/Apache

1MB
19K SLoC

R3 Real-Time Operating System

Experimental static component-oriented RTOS for deeply embedded systems

Try it on Repl.it

R3-OS (or simply R3) is an experimental static RTOS that utilizes Rust's compile-time function evaluation mechanism for static configuration (creation of kernel objects and memory allocation) and const traits to decouple kernel interfaces from implementation.

  • All kernel objects are defined statically for faster boot times, compile-time checking, predictable execution, reduced RAM consumption, no runtime allocation failures, and extra security.
  • A kernel and its configurator don't require an external build tool or a specialized procedural macro, maintaining transparency and inter-crate composability.
  • The kernel API is not tied to any specific kernel implementations. Kernels are provided as separate crates, one of which an application chooses and instantiates using the trait system.
  • Leverages Rust's type safety for access control of kernel objects. Safe code can't access an object that it doesn't own.

R3 API

  • Tasks are the standard way to spawn application threads. They are kernel objects encapsulating the associated threads' execution states and can be activated by application code or automatically at boot time. Tasks have dynamic priorities and can block to relinquish the processor for lower-priority tasks.

  • R3 provides a unified interface to control interrupt lines and register interrupt handlers. Some kernels (e.g., the Arm M-Profile port of the original kernel) support unmanaged interrupt lines, which aren't masked when the kernel is handling a system call and thus provide superior real-time performance.

  • R3 supports common synchronization primitives such as mutexes, semaphores, and event groups. The mutexes can use the priority ceiling protocol to avoid unbounded priority inversion and mutual deadlock. Tasks can park themselves.

  • The kernel timing mechanism drives software timers and a system-global clock with microsecond precision. The system clock can be rewound or fast-forwarded for drift compensation.

  • Bindings are a statically-defined storage with runtime initialization and configuration-time borrow checking. They can be bound to tasks and other objects to provide safe mutable access.

  • Procedural kernel configuration facilitates componentization. The utility library includes safe container types such as Mutex and RecursiveMutex, which are built upon low-level synchronization primitives.

The Kernel

The R3 original kernel is provided as a separate package r3_kernel.

  • Traditional uniprocessor tickless real-time kernel with preemptive scheduling

  • Implements a software-based scheduler supporting a customizable number of task priorities (up to 2¹⁵ levels on a 32-bit target, though the implementation is heavily optimized for a smaller number of priorities) and an unlimited number of tasks.

  • Provides a scalable kernel timing mechanism with a logarithmic time complexity. This implementation is robust against a large interrupt processing delay.

  • Supports Arm M-Profile (all versions shipped so far), Armv7-A (no FPU), RISC-V as well as the simulator port that runs on a host system.

Example

#![feature(const_refs_to_cell)]
#![feature(const_trait_impl)]
#![feature(naked_functions)]
#![feature(const_mut_refs)]
#![feature(asm_const)]
#![no_std]
#![no_main]

// ----------------------------------------------------------------

// Instantiate the Armv7-M port
use r3_port_arm_m as port;

type System = r3_kernel::System<SystemTraits>;
port::use_port!(unsafe struct SystemTraits);
port::use_rt!(unsafe SystemTraits);
port::use_systick_tickful!(unsafe impl PortTimer for SystemTraits);

impl port::ThreadingOptions for SystemTraits {}

impl port::SysTickOptions for SystemTraits {
    // STMF401 default clock configuration
    // SysTick = AHB/8, AHB = HSI (internal 16-MHz RC oscillator)
    const FREQUENCY: u64 = 2_000_000;
}

// ----------------------------------------------------------------

use r3::{bind::bind, kernel::StaticTask, prelude::*};

struct Objects {
    task: StaticTask<System>,
}

// Instantiate the kernel, allocate object IDs
const COTTAGE: Objects = r3_kernel::build!(SystemTraits, configure_app => Objects);

/// Root configuration
const fn configure_app(b: &mut r3_kernel::Cfg<SystemTraits>) -> Objects {
    System::configure_systick(b);

    // Runtime-initialized static storage
    let count = bind((), || 1u32).finish(b);

    Objects {
        // Create a task, giving the ownership of `count`
        task: StaticTask::define()
            .start_with_bind((count.borrow_mut(),), task_body)
            .priority(2)
            .active(true)
            .finish(b),
    }
}

fn task_body(count: &mut u32) {
    // ...
}

Explore the examples directory for example projects.

Prerequisites

You need a Nightly Rust compiler. This project is heavily reliant on unstable features, so it might or might not work with a newer compiler version. See the file rust-toolchain.toml to find out which compiler version this project is currently tested with.

You also need to install Rust's cross-compilation support for your target architecture. If it's not installed, you will see a compile error like this:

error[E0463]: can't find crate for `core`
  |
  = note: the `thumbv7m-none-eabi` target may not be installed

In this case, you need to run rustup target add thumbv7m-none-eabi.

Dependencies

~2.6–4.5MB
~92K SLoC