use core::cmp::min; use acpi::rsdp::Rsdp; use alloc::string::String; use system_error::SystemError; use crate::{ arch::init::ArchBootParams, driver::video::fbdev::base::BootTimeScreenInfo, libs::lazy_init::Lazy, mm::{PhysAddr, VirtAddr}, }; use super::boot_params; #[derive(Debug)] pub struct BootParams { pub screen_info: BootTimeScreenInfo, bootloader_name: Option, #[allow(dead_code)] pub arch: ArchBootParams, boot_command_line: [u8; Self::BOOT_COMMAND_LINE_SIZE], pub acpi: BootloaderAcpiArg, } impl BootParams { const DEFAULT: Self = BootParams { screen_info: BootTimeScreenInfo::DEFAULT, bootloader_name: None, arch: ArchBootParams::DEFAULT, boot_command_line: [0u8; Self::BOOT_COMMAND_LINE_SIZE], acpi: BootloaderAcpiArg::NotProvided, }; /// 开机命令行参数字符串最大大小 pub const BOOT_COMMAND_LINE_SIZE: usize = 2048; pub(super) const fn new() -> Self { Self::DEFAULT } /// 开机命令行参数(原始字节数组) #[allow(dead_code)] pub fn boot_cmdline(&self) -> &[u8] { &self.boot_command_line } /// 开机命令行参数字符串 pub fn boot_cmdline_str(&self) -> &str { core::str::from_utf8(&self.boot_cmdline()[..self.boot_cmdline_len()]).unwrap() } #[allow(dead_code)] pub fn bootloader_name(&self) -> Option<&str> { self.bootloader_name.as_deref() } pub fn boot_cmdline_len(&self) -> usize { self.boot_command_line .iter() .position(|&x| x == 0) .unwrap_or(self.boot_command_line.len()) } /// 追加开机命令行参数 /// /// 如果开机命令行参数已经满了,则不会追加。 /// 如果超过了最大长度,则截断。 /// /// ## 参数 /// /// - `data`:追加的数据 pub fn boot_cmdline_append(&mut self, data: &[u8]) { if data.is_empty() { return; } let mut pos: Option = None; // 寻找结尾 for (i, x) in self.boot_command_line.iter().enumerate() { if *x == 0 { pos = Some(i); break; } } let pos = pos.unwrap_or(self.boot_command_line.len() - 1) as isize; let avail = self.boot_command_line.len() as isize - pos - 1; if avail <= 0 { return; } let len = min(avail as usize, data.len()); let pos = pos as usize; self.boot_command_line[pos..pos + len].copy_from_slice(&data[0..len]); self.boot_command_line[pos + len] = 0; } /// 获取FDT的虚拟地址 #[allow(dead_code)] pub fn fdt(&self) -> Option { #[cfg(target_arch = "riscv64")] return Some(self.arch.arch_fdt()); #[cfg(target_arch = "x86_64")] return None; } /// 获取FDT的物理地址 #[allow(dead_code)] pub fn fdt_paddr(&self) -> Option { #[cfg(target_arch = "riscv64")] return Some(self.arch.fdt_paddr); #[cfg(target_arch = "x86_64")] return None; } } /// 开机引导回调,用于初始化内核启动参数 pub trait BootCallbacks: Send + Sync { /// 初始化引导程序名称 fn init_bootloader_name(&self) -> Result, SystemError>; /// 初始化ACPI参数 fn init_acpi_args(&self) -> Result; /// 初始化内核命令行参数 /// /// 该函数应该把内核命令行参数追加到`boot_params().boot_cmdline`中 fn init_kernel_cmdline(&self) -> Result<(), SystemError>; /// 初始化帧缓冲区信息 /// /// - 该函数应该把帧缓冲区信息写入`scinfo`中。 /// - 该函数应该在内存管理初始化之前调用。 fn early_init_framebuffer_info( &self, scinfo: &mut BootTimeScreenInfo, ) -> Result<(), SystemError>; /// 初始化内存块 fn early_init_memory_blocks(&self) -> Result<(), SystemError>; } static BOOT_CALLBACKS: Lazy<&'static dyn BootCallbacks> = Lazy::new(); /// 注册开机引导回调 pub fn register_boot_callbacks(callbacks: &'static dyn BootCallbacks) { BOOT_CALLBACKS.init(callbacks); } /// 获取开机引导回调 pub fn boot_callbacks() -> &'static dyn BootCallbacks { let p = BOOT_CALLBACKS .try_get() .expect("Boot callbacks not initialized"); *p } pub(super) fn boot_callback_except_early() { let mut boot_params = boot_params().write(); boot_params.bootloader_name = boot_callbacks() .init_bootloader_name() .expect("Failed to init bootloader name"); boot_params.acpi = boot_callbacks() .init_acpi_args() .unwrap_or(BootloaderAcpiArg::NotProvided); } /// ACPI information from the bootloader. #[derive(Copy, Clone, Debug)] pub enum BootloaderAcpiArg { /// The bootloader does not provide one, a manual search is needed. NotProvided, /// Physical address of the RSDP. #[allow(dead_code)] Rsdp(PhysAddr), /// Address of RSDT provided in RSDP v1. Rsdt(Rsdp), /// Address of XSDT provided in RSDP v2+. Xsdt(Rsdp), }