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https://github.com/rust-osdev/bootloader

An experimental pure-Rust x86 bootloader
https://github.com/rust-osdev/bootloader

Last synced: about 2 months ago
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An experimental pure-Rust x86 bootloader

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README 

        
# bootloader



[![Docs](https://docs.rs/bootloader/badge.svg)](https://docs.rs/bootloader)

[![Build Status](https://github.com/rust-osdev/bootloader/actions/workflows/build.yml/badge.svg)](https://github.com/rust-osdev/bootloader/actions/workflows/build.yml)

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An experimental x86_64 bootloader that works on both BIOS and UEFI systems. Written in Rust and some inline assembly, buildable on all platforms without additional build-time dependencies (just some `rustup` components).



## Requirements



You need a nightly [Rust](https://www.rust-lang.org) compiler with the `llvm-tools-preview` component, which can be installed through `rustup component add llvm-tools-preview`.



## Usage



To use this crate, you need to adjust your kernel to be bootable first. Then you can create a bootable disk image from your compiled kernel. These steps are explained in detail below.



If you're already using an older version of the `bootloader` crate, follow our [migration guides](docs/migration).



### Kernel



To make your kernel compatible with `bootloader`:



- Add a dependency on the `bootloader_api` crate in your kernel's `Cargo.toml`.

- Your kernel binary should be `#![no_std]` and `#![no_main]`.

- Define an entry point function with the signature `fn kernel_main(boot_info: &'static mut bootloader_api::BootInfo) -> !`. The function name can be arbitrary.

  - The `boot_info` argument provides information about available memory, the framebuffer, and more. See the API docs for `bootloader_api` crate for details.

- Use the `entry_point` macro to register the entry point function: `bootloader_api::entry_point!(kernel_main);`

  - The macro checks the signature of your entry point function and generates a `_start` entry point symbol for it. (If you use a linker script, make sure that you don't change the entry point name to something else.)

  - To use non-standard configuration, you can pass a second argument of type `&'static bootloader_api::BootloaderConfig` to the `entry_point` macro. For example, you can require a specific stack size for your kernel:

    ```rust

    const CONFIG: bootloader_api::BootloaderConfig = {

        let mut config = bootloader_api::BootloaderConfig::new_default();

        config.kernel_stack_size = 100 * 1024; // 100 KiB

        config

    };

    bootloader_api::entry_point!(kernel_main, config = &CONFIG);

    ```

- Compile your kernel to an ELF executable by running **`cargo build --target x86_64-unknown-none`**. You might need to run `rustup target add x86_64-unknown-none` before to download precompiled versions of the `core` and `alloc` crates.

- Thanks to the `entry_point` macro, the compiled executable contains a special section with metadata and the serialized config, which will enable the `bootloader` crate to load it.



### Booting



To combine your kernel with a bootloader and create a bootable disk image, follow these steps:



- Move your full kernel code into a `kernel` subdirectory.

- Create a new `os` crate at the top level that defines a [workspace](https://doc.rust-lang.org/cargo/reference/workspaces.html).

- Add a `build-dependencies` on the `bootloader` crate.

- Create a [`build.rs`](https://doc.rust-lang.org/cargo/reference/build-scripts.html) build script.

- Set up an [artifact dependency](https://doc.rust-lang.org/nightly/cargo/reference/unstable.html#artifact-dependencies) to add your `kernel` crate as a `build-dependency`:

  ```toml

  # in Cargo.toml

  [build-dependencies]

  kernel = { path = "kernel", artifact = "bin", target = "x86_64-unknown-none" }

  ```

  ```toml

  # .cargo/config.toml



  [unstable]

  # enable the unstable artifact-dependencies feature, see

  # https://doc.rust-lang.org/nightly/cargo/reference/unstable.html#artifact-dependencies

  bindeps = true

  ```

  Alternatively, you can use [`std::process::Command`](https://doc.rust-lang.org/stable/std/process/struct.Command.html) to invoke the build command of your kernel in the `build.rs` script. 

- Obtain the path to the kernel executable. When using an artifact dependency, you can retrieve this path using `std::env::var_os("CARGO_BIN_FILE_MY_KERNEL_my-kernel")`

- Use `bootloader::UefiBoot` and/or `bootloader::BiosBoot` to create a bootable disk image with your kernel.

- Do something with the bootable disk images in your `main.rs` function. For example, run them with QEMU.



See our [disk image creation template](docs/create-disk-image.md) for a more detailed example.



## Architecture



This project is split into three separate entities:



- A [`bootloader_api`](./api) library with the entry point, configuration, and boot info definitions.

  - Kernels should include this library as a normal cargo dependency.

  - The provided `entry_point` macro will encode the configuration settings into a separate ELF section of the compiled kernel executable.

- [BIOS](./bios) and [UEFI](./uefi) binaries that contain the actual bootloader implementation.

  - The implementations share a higher-level [common library](./common).

  - Both implementations load the kernel at runtime from a FAT partition. This FAT partition is created

  - The configuration is read from a special section of the kernel's ELF file, which is created by the `entry_point` macro of the `bootloader_api` library.

- A `bootloader` library to create bootable disk images that run a given kernel. This library is the top-level crate in this project.

  - The library builds the BIOS and UEFI implementations in the [`build.rs`](./build.rs).

  - It provides functions to create FAT-formatted bootable disk images, based on the compiled BIOS and UEFI bootloaders.



## License



Licensed under either of



- Apache License, Version 2.0 ([LICENSE-APACHE](LICENSE-APACHE) or

  http://www.apache.org/licenses/LICENSE-2.0)

- MIT license ([LICENSE-MIT](LICENSE-MIT) or http://opensource.org/licenses/MIT)



at your option.



Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.