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188 lines
7.0 KiB
Rust
188 lines
7.0 KiB
Rust
// SPDX-License-Identifier: MIT OR Apache-2.0
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//
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// Copyright (c) 2018-2021 Andre Richter <andre.o.richter@gmail.com>
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// Rust embedded logo for `make doc`.
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#![doc(html_logo_url = "https://git.io/JeGIp")]
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//! The `kernel` library.
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//!
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//! Used to compose the final kernel binary.
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//!
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//! # Code organization and architecture
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//!
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//! The code is divided into different *modules*, each representing a typical **subsystem** of the
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//! `kernel`. Top-level module files of subsystems reside directly in the `src` folder. For example,
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//! `src/memory.rs` contains code that is concerned with all things memory management.
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//!
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//! ## Visibility of processor architecture code
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//!
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//! Some of the `kernel`'s subsystems depend on low-level code that is specific to the target
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//! processor architecture. For each supported processor architecture, there exists a subfolder in
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//! `src/_arch`, for example, `src/_arch/aarch64`.
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//!
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//! The architecture folders mirror the subsystem modules laid out in `src`. For example,
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//! architectural code that belongs to the `kernel`'s MMU subsystem (`src/memory/mmu.rs`) would go
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//! into `src/_arch/aarch64/memory/mmu.rs`. The latter file is loaded as a module in
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//! `src/memory/mmu.rs` using the `path attribute`. Usually, the chosen module name is the generic
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//! module's name prefixed with `arch_`.
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//!
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//! For example, this is the top of `src/memory/mmu.rs`:
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//!
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//! ```
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//! #[cfg(target_arch = "aarch64")]
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//! #[path = "../_arch/aarch64/memory/mmu.rs"]
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//! mod arch_mmu;
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//! ```
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//!
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//! Often times, items from the `arch_ module` will be publicly reexported by the parent module.
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//! This way, each architecture specific module can provide its implementation of an item, while the
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//! caller must not be concerned which architecture has been conditionally compiled.
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//!
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//! ## BSP code
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//!
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//! `BSP` stands for Board Support Package. `BSP` code is organized under `src/bsp.rs` and contains
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//! target board specific definitions and functions. These are things such as the board's memory map
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//! or instances of drivers for devices that are featured on the respective board.
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//!
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//! Just like processor architecture code, the `BSP` code's module structure tries to mirror the
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//! `kernel`'s subsystem modules, but there is no reexporting this time. That means whatever is
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//! provided must be called starting from the `bsp` namespace, e.g. `bsp::driver::driver_manager()`.
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//!
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//! ## Kernel interfaces
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//!
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//! Both `arch` and `bsp` contain code that is conditionally compiled depending on the actual target
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//! and board for which the kernel is compiled. For example, the `interrupt controller` hardware of
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//! the `Raspberry Pi 3` and the `Raspberry Pi 4` is different, but we want the rest of the `kernel`
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//! code to play nicely with any of the two without much hassle.
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//!
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//! In order to provide a clean abstraction between `arch`, `bsp` and `generic kernel code`,
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//! `interface` traits are provided *whenever possible* and *where it makes sense*. They are defined
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//! in the respective subsystem module and help to enforce the idiom of *program to an interface,
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//! not an implementation*. For example, there will be a common IRQ handling interface which the two
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//! different interrupt controller `drivers` of both Raspberrys will implement, and only export the
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//! interface to the rest of the `kernel`.
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//!
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//! ```
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//! +-------------------+
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//! | Interface (Trait) |
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//! | |
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//! +--+-------------+--+
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//! ^ ^
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//! | |
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//! | |
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//! +----------+--+ +--+----------+
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//! | kernel code | | bsp code |
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//! | | | arch code |
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//! +-------------+ +-------------+
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//! ```
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//!
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//! # Summary
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//!
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//! For a logical `kernel` subsystem, corresponding code can be distributed over several physical
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//! locations. Here is an example for the **memory** subsystem:
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//!
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//! - `src/memory.rs` and `src/memory/**/*`
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//! - Common code that is agnostic of target processor architecture and `BSP` characteristics.
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//! - Example: A function to zero a chunk of memory.
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//! - Interfaces for the memory subsystem that are implemented by `arch` or `BSP` code.
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//! - Example: An `MMU` interface that defines `MMU` function prototypes.
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//! - `src/bsp/__board_name__/memory.rs` and `src/bsp/__board_name__/memory/**/*`
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//! - `BSP` specific code.
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//! - Example: The board's memory map (physical addresses of DRAM and MMIO devices).
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//! - `src/_arch/__arch_name__/memory.rs` and `src/_arch/__arch_name__/memory/**/*`
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//! - Processor architecture specific code.
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//! - Example: Implementation of the `MMU` interface for the `__arch_name__` processor
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//! architecture.
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//!
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//! From a namespace perspective, **memory** subsystem code lives in:
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//!
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//! - `crate::memory::*`
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//! - `crate::bsp::memory::*`
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//!
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//! # Boot flow
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//!
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//! 1. The kernel's entry point is the function `cpu::boot::arch_boot::_start()`.
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//! - It is implemented in `src/_arch/__arch_name__/cpu/boot.s`.
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//! 2. Once finished with architectural setup, the arch code calls `kernel_init()`.
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#![allow(clippy::upper_case_acronyms)]
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#![allow(incomplete_features)]
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#![feature(const_fn_fn_ptr_basics)]
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#![feature(const_generics)]
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#![feature(const_panic)]
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#![feature(core_intrinsics)]
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#![feature(format_args_nl)]
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#![feature(global_asm)]
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#![feature(linkage)]
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#![feature(panic_info_message)]
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#![feature(trait_alias)]
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#![no_std]
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// Testing
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#![cfg_attr(test, no_main)]
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#![feature(custom_test_frameworks)]
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#![reexport_test_harness_main = "test_main"]
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#![test_runner(crate::test_runner)]
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mod panic_wait;
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mod synchronization;
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pub mod bsp;
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pub mod console;
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pub mod cpu;
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pub mod driver;
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pub mod exception;
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pub mod memory;
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pub mod print;
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pub mod time;
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//--------------------------------------------------------------------------------------------------
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// Public Code
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//--------------------------------------------------------------------------------------------------
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/// Version string.
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pub fn version() -> &'static str {
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concat!(
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env!("CARGO_PKG_NAME"),
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" version ",
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env!("CARGO_PKG_VERSION")
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)
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}
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#[cfg(not(test))]
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extern "Rust" {
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fn kernel_init() -> !;
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}
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//--------------------------------------------------------------------------------------------------
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// Testing
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//--------------------------------------------------------------------------------------------------
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/// The default runner for unit tests.
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pub fn test_runner(tests: &[&test_types::UnitTest]) {
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// This line will be printed as the test header.
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println!("Running {} tests", tests.len());
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for (i, test) in tests.iter().enumerate() {
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print!("{:>3}. {:.<58}", i + 1, test.name);
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// Run the actual test.
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(test.test_func)();
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// Failed tests call panic!(). Execution reaches here only if the test has passed.
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println!("[ok]")
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}
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}
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/// The `kernel_init()` for unit tests.
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#[cfg(test)]
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#[no_mangle]
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unsafe fn kernel_init() -> ! {
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exception::handling_init();
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bsp::console::qemu_bring_up_console();
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test_main();
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cpu::qemu_exit_success()
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}
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