Megacommit to move some memory code into kernel crate

changed page allocation to happen on page fault for performance reasons
Add tips on debugging/disassembling kernel sources
2025-02-28 02:13:50 +00:00 · 2025-02-27 23:57:23 +00:00 · 2025-02-27 23:32:05 +00:00 · 2025-02-27 22:58:10 +00:00 · 2025-02-27 21:57:58 +00:00 · 2025-02-27 16:52:31 +00:00
33 changed files with 762 additions and 508 deletions
@@ -10,7 +10,7 @@ git clone https://git.zxq5.dev/OsDev/FoundryOS.git
 * latest rust nightly release
 * all necessary rust components installed
 * xorriso: creates ISO images to be booted from.
-* (Optional / Recommended) Qemu: to run the kernel. (this may be packaged as qemu-desktop)
+* (Optional / Recommended) qemu: to run the kernel. (this may be packaged as qemu-desktop)
 * (Optional) GDB: for debugging the kernel.
 ```sh
@@ -20,12 +20,33 @@ rustup component add rust-src
 rustup component add llvm-tools-preview
 ```
-## Building & Running in Qemu:
+## Building & Running in qemu
 ```sh
 cargo run
 ```
-## Running in GDB:
+## Running in GDB
 ```sh
 USE_GDB=1 cargo run
 ```
 ## Build errors
 If you see a qemu error like this:
 ```
 qemu-system-x86_64: -drive if=pflash,format=raw,readonly=on,file=<...>/OVMF_CODE.fd: Could not open '<...>/OVMF_CODE.fd': No such file or directory
 ```
 Simply delete the ./build directory and try to rebuild the program. Using the runner script or `cargo run` will download the required files for you, this is because the script only checks for the presence of one file and not the VARS file.
 Alternatively, you may disable using a UEFI firmware with qemu like so:
 ```sh
 USE_LEGACY_BIOS=1 cargo run
 ```
 ## Debugging
 See [debugging](docs/Debugging/DEBUGGING.md) for some help with this, including commands to help with disassembly.
 If you have any other issues, feel free to create an issue or a PR.
@@ -1,5 +1,5 @@
 # Timeout in seconds that Limine will use before automatically booting.
-timeout: 1
+timeout: 0
 # The entry name that will be displayed in the boot menu.
 /foundry-os
@@ -0,0 +1,17 @@
 [0;32m[1m Running kernel in debug mode.
 [0;34m[1minfo[0m: Creating build directory structure
 [0;34m[1minfo[0m: Copying files to ISO root
 [0;32m[1m  Copying[0m: /home/fantasypvp/Projects/OSdev/FoundryOS/build/target/x86_64-kernel/debug/kernel to /home/fantasypvp/Projects/OSdev/FoundryOS/build/iso_root/boot/kernel
 [0;32m[1m  Copying[0m: /home/fantasypvp/Projects/OSdev/FoundryOS/config/limine.conf to /home/fantasypvp/Projects/OSdev/FoundryOS/build/iso_root/boot/limine/limine.conf
 [0;32m[1m  Copying[0m: /home/fantasypvp/Projects/OSdev/FoundryOS/build/limine/limine-bios-cd.bin to /home/fantasypvp/Projects/OSdev/FoundryOS/build/iso_root/boot/limine/
 [0;32m[1m  Copying[0m: /home/fantasypvp/Projects/OSdev/FoundryOS/build/limine/limine-uefi-cd.bin to /home/fantasypvp/Projects/OSdev/FoundryOS/build/iso_root/boot/limine/
 [0;32m[1m  Copying[0m: /home/fantasypvp/Projects/OSdev/FoundryOS/build/limine/limine-bios.sys to /home/fantasypvp/Projects/OSdev/FoundryOS/build/iso_root/boot/limine/
 [0;32m[1m  Copying[0m: /home/fantasypvp/Projects/OSdev/FoundryOS/build/limine/BOOTX64.EFI to /home/fantasypvp/Projects/OSdev/FoundryOS/build/iso_root/EFI/BOOT/
 [0;32m[1m  Copying[0m: /home/fantasypvp/Projects/OSdev/FoundryOS/build/limine/BOOTIA32.EFI to /home/fantasypvp/Projects/OSdev/FoundryOS/build/iso_root/EFI/BOOT/
 [0;32m[1mBuilding[0m: bootable ISO image
 [0;34m[1minfo[0m: Installing Limine bootloader
 [0;34m[1minfo[0m: KVM acceleration enabled
 [0;34m[1minfo[0m: Running OS in QEMU...
 [2J[01;01H[=3h[2J[01;01H[2J[01;01H[=3h[2J[01;01H[2J[01;01H[=3h[2J[01;01HBdsDxe: loading Boot0001 "UEFI QEMU DVD-ROM QM00005 " from PciRoot(0x0)/Pci(0x1F,0x2)/Sata(0x2,0xFFFF,0x0)
 BdsDxe: starting Boot0001 "UEFI QEMU DVD-ROM QM00005 " from PciRoot(0x0)/Pci(0x1F,0x2)/Sata(0x2,0xFFFF,0x0)
 [2J[01;01H[01;01H[2J[01;01H[01;01Hmap worked!got apic base
@@ -0,0 +1,16 @@
 # Debugging the Kernel
 Here we will add some helpful tips on debugging the kernel.
 ## Disassembling a public function
 To disassemble a public function, first we need a symbol in the public symbol table, so start by making the function fully public (including any parent modules). Do this as though you are trying to make a public function for a library crate (this includes the `kernel` crate). Simply mark the function and any parent modules as public, up until the point of [lib.rs (kernel link)](../../kernel/src/lib.rs).
 Then, we need to find the specific demangled symbol to disassemble, because the default objdump output can be very verbose.
 ```sh
 # Change as required, I pipe to less and /SEARCH FOR FUNCTION HERE.
 nm --demangle ./build/target/x86_64-kernel/debug/kernel | less
 # Now just paste the symbol where it says YOUR_SYMBOL_HERE and profit. Use -Mintel for Intel assembly syntax.
 objdump -Matt --source --line-numbers --visualize-jumps ./build/target/x86_64-kernel/debug/kernel --demangle=rust --disassemble="YOUR_SYMBOL_HERE"
 ```
@@ -0,0 +1,113 @@
 #![allow(unused)] // TODO: Remove this when ready.
 use core::arch::x86_64::__cpuid;
 use x86_64::{
    PhysAddr, VirtAddr,
    structures::paging::{Mapper, Size4KiB},
 };
 use crate::serial_print;
 use super::{cpu::model_specific_registers::*, mem::memmap::PHYSICAL_MEMORY_OFFSET};
 const IA32_APIC_BASE_MSR: u32 = 0x1b;
 const IA32_APIC_BASE_MSR_BSP: u64 = 0x100;
 const IA32_APIC_BASE_MSR_ENABLE: u64 = 0x800;
 const IA32_APIC_BASE_MSR_DISABLE: u64 = !IA32_APIC_BASE_MSR_ENABLE;
 const CPUID_FEAT_EDX_APIC: u64 = 1 << 9; // the cpuid instruction will return this flag if it supports APIC
 // const APIC_VIRTUAL_ADDRESS: Lazy<VirtAddr> = Lazy::new(|| {
 //     let apic_base = get_apic_base();
 //     let virt_addr = unsafe { phys_to_virt(apic_base) };
 //     virt_addr
 // });
 fn set_apic_base_enable(apic: PhysAddr) {
    let rax = (apic.as_u64() & 0xfffff0000) | IA32_APIC_BASE_MSR_ENABLE;
    cpu_set_msr(IA32_APIC_BASE_MSR, rax);
 }
 fn set_apic_base_disable(apic: PhysAddr) {
    let rax = (apic.as_u64() & 0xfffff0000) & IA32_APIC_BASE_MSR_DISABLE;
    cpu_set_msr(IA32_APIC_BASE_MSR, rax);
 }
 fn get_apic_base() -> PhysAddr {
    let mut value: u64 = 0;
    cpu_get_msr(IA32_APIC_BASE_MSR, &mut value);
    PhysAddr::new(value & 0xfffff0000)
 }
 fn write_apic_register(apic_base: &VirtAddr, reg: u8, value: u32) {
    let apic_base = apic_base.as_u64();
    let reg_addr = (apic_base & 0xFFFFF0000) + reg as u64;
    unsafe { *(reg_addr as *mut u32) = value };
 }
 fn read_apic_register(apic_base: &VirtAddr, reg: u8) -> u32 {
    let apic_base = apic_base.as_u64();
    serial_print!("got apic base");
    let reg_addr = (apic_base & 0xFFFFF0000) + reg as u64;
    unsafe { *(reg_addr as *const u32) }
 }
 pub fn check_apic() -> bool {
    let res = unsafe { __cpuid(1) };
    res.edx as u64 & CPUID_FEAT_EDX_APIC != 0
 }
 #[inline(always)]
 unsafe fn phys_to_virt(phys: PhysAddr) -> VirtAddr {
    let phys = phys.as_u64();
    phys.checked_add(*PHYSICAL_MEMORY_OFFSET).map_or_else(
        || {
            serial_print!("THIS IS A PROBLEM");
            panic!("overflow")
        },
        |virt| {
            serial_print!("map worked!");
            VirtAddr::new(virt)
        },
    )
 }
 pub fn enable_apic(
    _mapper: &mut impl Mapper<Size4KiB>,
    // TODO: Fix this function.
    // frame_allocator: &mut FoundryOSFrameAllocator,
 ) {
    unimplemented!();
    // let apic_phys_addr = get_apic_base();
    // set_apic_base_enable(apic_phys_addr);
    // map virt address of apic
    // let apic_virt = unsafe { phys_to_virt(apic_phys_addr) };
    // let page: Page<Size4KiB> = Page::containing_address(apic_virt);
    // let frame: PhysFrame<Size4KiB> = PhysFrame::containing_address(apic_phys_addr);
    // let flags: PageTableFlags = PageTableFlags::PRESENT | PageTableFlags::WRITABLE;
    // unsafe {
    //     match mapper.map_to(page, frame, flags, frame_allocator) {
    //         Ok(_) => {}
    //         Err(why) => panic!("failed to map apic: {:?}", why),
    //     }
    // }
    // // FIXME: this causes a page fault
    // // TODO: map to virtual memor
    // let reg = read_apic_register(&apic_virt, 0xF0);
    // serial_print!("ok2");
    // write_apic_register(&apic_virt, 0xF0, reg | 0x100);
 }
 pub struct Apic {}
 pub enum ApicVector {}
@@ -0,0 +1,26 @@
 pub mod model_specific_registers {
    use core::arch::x86_64::__cpuid;
    use spin::Lazy;
    use x86_64::registers::model_specific::Msr;
    const _CPUID_FLAG_MSR: u32 = 1 << 5;
    static _EDX: Lazy<u32> = Lazy::new(|| unsafe { __cpuid(1).edx });
    pub fn _cpu_has_msr() -> bool {
        *_EDX & _CPUID_FLAG_MSR != 0
    }
    pub fn cpu_get_msr(msr: u32, value: &mut u64) {
        let msr = Msr::new(msr);
        unsafe {
            *value = msr.read();
        }
    }
    pub fn cpu_set_msr(msr: u32, value: u64) {
        let mut msr = Msr::new(msr);
        unsafe {
            msr.write(value);
        }
    }
 }
@@ -1,8 +1,8 @@
 // use libk::drivers::mem::{FRAME_ALLOCATOR, OFFSET_PAGE_TABLE};
 use libk::prelude::*;
-use x86_64::registers::control::Cr2;
+use pic8259::ChainedPics;
 use x86_64::structures::idt::{InterruptDescriptorTable, InterruptStackFrame, PageFaultErrorCode};
 use pic8259::ChainedPics;
 use spin::{Lazy, Mutex};
 use super::gdt;
@@ -51,12 +51,22 @@ impl InterruptIndex {
 pub fn init_idt() {
    IDT.load();
 }
 pub fn enable_pic() {
    unsafe {
        PICS.lock().initialize();
        PICS.lock().write_masks(0xfc, 0xff);
    }
 }
 #[expect(unused)]
 pub fn disable_pic() {
    unsafe {
        PICS.lock().disable();
    }
 }
 extern "x86-interrupt" fn breakpoint_handler(stack_frame: InterruptStackFrame) {
    serial_println!("Exception: Breakpoint\n{:#?}", stack_frame);
    println_log!("Exception: Breakpoint\n{:#?}", stack_frame);
@@ -112,13 +122,32 @@ extern "x86-interrupt" fn timer_interrupt_handler(_stack_frame: InterruptStackFr
 }
 extern "x86-interrupt" fn page_fault_handler(
-    stack_frame: InterruptStackFrame,
+    _stack_frame: InterruptStackFrame,
-    error_code: PageFaultErrorCode,
+    _error_code: PageFaultErrorCode,
 ) {
-    serial_println!("Exception: Page Fault");
+    todo!("Get this working again.")
-    serial_println!("Accessed Address: {:?}", Cr2::read());
+    // serial_println!("Exception: Page Fault");
-    serial_println!("Error Code: {:?}", error_code);
+    // serial_println!("Accessed Address: {:?}", Cr2::read());
-    serial_println!("{:#?}", stack_frame);
+    // serial_println!("Error Code: {:?}", error_code);
    // serial_println!("{:#?}", stack_frame);
-    crate::hcf();
+    // if let Some(frame_allocator) = FRAME_ALLOCATOR.get() {
    //     let mut f = frame_allocator.lock();
    //     let frame = f.allocate_frame().unwrap();
    //     let flags = PageTableFlags::PRESENT | PageTableFlags::WRITABLE;
    //     let page: Page<Size4KiB> = Page::containing_address(Cr2::read().unwrap());
    //     unsafe {
    //         let mut mapper = OFFSET_PAGE_TABLE.get().unwrap().lock();
    //         match mapper.map_to(page, frame, flags, &mut *f) {
    //             Ok(_) => {}
    //             Err(why) => panic!("failed to map page: {:?}", why),
    //         }
    //     }
    //     MapperFlushAll::new().flush_all();
    // } else {
    //     panic!("failed to get frame allocator");
    // }
 }
@@ -14,6 +14,10 @@ static MEMORY_MAP_REQUEST: MemoryMapRequest = MemoryMapRequest::new();
 #[unsafe(link_section = ".requests")]
 static HIGHER_HALF_DIRECT_MAP_REQUEST: HhdmRequest = HhdmRequest::new();
 #[used]
 #[unsafe(link_section = ".requests")]
 static KERNEL_ADDRESS_REQUEST: KernelAddressRequest = KernelAddressRequest::new();
 /// ```rs
 /// let virt_addr = phys_addr + offset;
 /// let phys_addr = virt_addr - offset; // (given VA is in the HHDM). Do not use for executable code.
@@ -25,10 +29,6 @@ pub static PHYSICAL_MEMORY_OFFSET: Lazy<u64> = Lazy::new(|| {
        .offset()
 });
 #[used]
 #[unsafe(link_section = ".requests")]
 static KERNEL_ADDRESS_REQUEST: KernelAddressRequest = KernelAddressRequest::new();
 /// Converts virtual addresses in the kernel to a physical address like this:
 /// ```rs
 /// let phys_addr = virt_addr - virtual_base + physical_base;
@@ -0,0 +1,2 @@
 pub mod memmap;
 pub mod pmm;
@@ -1,141 +0,0 @@
 // use lib_alloc::allocator::FoundryAllocator;
 use limine::{memory_map::EntryType, response::MemoryMapResponse};
 use x86_64::{
    PhysAddr,
    VirtAddr,
    // addr,
    registers::control::Cr3,
    structures::paging::{
        // page_table::FrameError,
        FrameAllocator,
        OffsetPageTable,
        PageTable,
        PhysFrame,
        Size4KiB,
    },
 };
 /// Returns a mutable reference to the current level 4 page table.
 ///
 /// # Safety
 ///
 /// The caller must ensure that the level 4 page table is not modified
 /// simultaneously. The caller must also ensure that the physical memory offset
 /// is correct, to ensure that the correct virtual address is constructed.
 unsafe fn active_l4_table(physical_memory_offset: VirtAddr) -> &'static mut PageTable {
    let (level_4_frame, _) = Cr3::read();
    let phys_addr = level_4_frame.start_address();
    let virt = phys_addr.as_u64() + physical_memory_offset.as_u64();
    unsafe { &mut *(virt as *mut PageTable) }
 }
 /// Initializes the `OffsetPageTable` for the current CPU architecture.
 ///
 /// # Safety
 ///
 /// This function must be called only once and should be called before any
 /// memory operations are performed that rely on virtual memory management.
 /// The provided `physical_memory_offset` must be accurate to ensure correct
 /// translation of physical addresses.
 ///
 /// # Parameters
 ///
 /// - `physical_memory_offset`: The offset to convert physical addresses to
 ///   virtual addresses in the higher-half direct map.
 ///
 /// # Returns
 ///
 /// Returns an `OffsetPageTable` that allows for manipulation of the page
 /// tables for the current CPU architecture.
 pub unsafe fn init(physical_memory_offset: VirtAddr) -> OffsetPageTable<'static> {
    unsafe {
        let l4_table = active_l4_table(physical_memory_offset);
        OffsetPageTable::new(l4_table, physical_memory_offset)
    }
 }
 pub struct FoundryOSFrameAllocator {
    memory_map: &'static MemoryMapResponse,
    next: usize,
 }
 impl FoundryOSFrameAllocator {
    /// Creates a new `FoundryOSFrameAllocator` from a memory map.
    ///
    /// This function takes a reference to a `MemoryMapResponse` and initializes a
    /// `FoundryOSFrameAllocator` with it. The `next` field is set to 0, indicating that
    /// the first frame to be allocated is the first frame in the memory map.
    pub const unsafe fn init(memory_map: &'static MemoryMapResponse) -> Self {
        Self {
            memory_map,
            next: 0,
        }
    }
    /// An iterator over all usable frames in the memory map.
    ///
    /// Yields one `PhysFrame` for each available 4KiB frame in the memory map.
    ///
    /// This function is used to allocate frames for the pagemap.
    fn usable_frames(&self) -> impl Iterator<Item = PhysFrame> + use<> {
        let regions = self.memory_map.entries().iter();
        let usable_regions = regions.filter(|region| region.entry_type == EntryType::USABLE);
        let addr_ranges = usable_regions.map(|region| region.base..region.base + region.length);
        let frame_addresses = addr_ranges.flat_map(|r| r.step_by(4096));
        frame_addresses.map(|addr| PhysFrame::from_start_address(PhysAddr::new(addr)).unwrap())
    }
 }
 unsafe impl FrameAllocator<Size4KiB> for FoundryOSFrameAllocator {
    /// Allocates a frame from the list of usable frames.
    ///
    /// This function returns the next available `PhysFrame` from the memory map,
    /// if one exists. Once a frame is allocated, the internal counter is incremented
    /// to point to the next frame for future allocations.
    ///
    /// # Returns
    ///
    /// - `Some(PhysFrame)`: If a usable frame is available.
    /// - `None`: If there are no more usable frames to allocate.
    fn allocate_frame(&mut self) -> Option<PhysFrame> {
        let frame = self.usable_frames().nth(self.next);
        self.next += 1;
        frame
    }
 }
 // pub unsafe fn translate_addr(addr: VirtAddr, physical_memory_offset: VirtAddr) -> Option<PhysAddr> {
 //     translate_addr_inner(addr, physical_memory_offset)
 // }
 // fn translate_addr_inner(addr: VirtAddr, physical_memory_offset: VirtAddr) -> Option<PhysAddr> {
 //     let (l4_table_frame, _) = Cr3::read();
 //     let table_indexes = [
 //         addr.p4_index(),
 //         addr.p3_index(),
 //         addr.p2_index(),
 //         addr.p1_index(),
 //     ];
 //     let mut frame = l4_table_frame;
 //     for &i in &table_indexes {
 //         let virt = physical_memory_offset + frame.start_address().as_u64();
 //         let table_ptr: *const PageTable = virt.as_ptr();
 //         let table = unsafe { &*table_ptr };
 //         let entry = &table[i];
 //         frame = match entry.frame() {
 //             Ok(frame) => frame,
 //             Err(FrameError::FrameNotPresent) => return None,
 //             Err(FrameError::HugeFrame) => panic!("huge frames are not supported!"),
 //         };
 //     }
 //     Some(frame.start_address() + u64::from(addr.page_offset()))
 // }
@@ -1,7 +1,5 @@
 pub mod apic;
 pub mod cpu;
 pub mod gdt;
 pub mod interrupts;
-
+pub mod mem;
 pub mod memory;
 pub mod memmap;
@@ -13,14 +13,14 @@
 extern crate alloc;
 // use arch::x86_64::apic::enable_apic;
 use core::arch::asm;
 // use libk::drivers::mem::pmm;
 use limine::BaseRevision;
-use libk::drivers::kalloc::allocator::init_heap;
+// use libk::drivers::alloc::allocator::init_heap;
 use libk::prelude::*;
 use x86_64::VirtAddr;
 mod arch;
 /// Sets the base revision to the latest revision supported by the crate.
@@ -56,9 +56,9 @@ pub fn boot() -> Result<(), &'static str> {
        return Err("base revision not supported");
    }
-    use arch::x86_64::{gdt, interrupts, memmap, memory};
+    use arch::x86_64::{gdt, interrupts, mem::memmap};
-    let memory_map = memmap::get_memory_map();
+    let _memory_map = memmap::get_memory_map();
    print_log!("    Initialising Serial... ");
    if libk::drivers::io::serial::init().is_err() {
@@ -75,21 +75,34 @@ pub fn boot() -> Result<(), &'static str> {
    interrupts::init_idt();
    println_log!("[Success]");
-    print_log!("    Setting Up Page Table... ");
+    print_log!("    Initialising Memory Subsystem... ");
-    let mut frame_allocator = unsafe { memory::FoundryOSFrameAllocator::init(memory_map) };
+    // let physical_memory_offset = VirtAddr::new(*memmap::PHYSICAL_MEMORY_OFFSET);
    // pmm::init_page_table(physical_memory_offset);
    println_log!("[Success]");
-    print_log!("    Initialising Memory Subsystem... ");
+    print_log!("    Setting Up Page Table... ");
-    let physical_memory_offset = VirtAddr::new(*memmap::PHYSICAL_MEMORY_OFFSET);
+    // pmm::init_frame_allocator(memory_map);
    let mut l4_table = unsafe { memory::init(physical_memory_offset) };
    println_log!("[Success]");
    print_log!("    Initialising Heap... ");
-    if init_heap(&mut l4_table, &mut frame_allocator).is_err() {
+    // TODO: Reenable the heap.
-        return Err("Failed to initialise heap: error");
+    // if init_heap().is_err() {
-    }
+    // return Err("Failed to initialise heap: error");
    // }
    println_log!("[Success]");
    print_log!("    Enabling PICs... ");
    interrupts::enable_pic();
    println_log!("[Success]");
    // print_log!("    Disabling PICs... ");
    // interrupts::disable_pic();
    // println_log!("[Success]");
    //
    // print_log!("    Initialising APIC");
    // enable_apic(&mut l4_table, &mut frame_allocator);
    // println_log!("[Success]");
    print_log!("    Enabling Interrupts... ");
    x86_64::instructions::interrupts::enable();
    println_log!("[Success]");
@@ -5,8 +5,8 @@ extern crate alloc;
 use libk::{
    drivers::{
        async_io::task::{Executor, Task},
        io,
        scheduling::task::{Executor, Task},
    },
    prelude::*,
    util::shell::shell,
@@ -28,6 +28,13 @@ extern "C" fn kmain() -> ! {
    println!("Dimensions: {}x{} (chars)", dimensions.0, dimensions.1);
    let mut executor = Executor::new();
    let mut v = Vec::with_capacity(1000 * 1000);
    for i in 0..1000 * 1000 {
        v.push(i);
    }
    println!("v.len(): {}", v.len());
    executor.spawn(Task::new(shell()));
    executor.run();
 }
@@ -1,3 +1,8 @@
 //! Allows creation of asynchronous IO bound tasks.
 //!
 //! Written by @zxq5 for the most part with code from
 //! [here](https://github.com/phil-opp/blog_os/).
 //!
 use crate::prelude::*;
 use alloc::collections::BTreeMap;
 use alloc::sync::Arc;
@@ -72,7 +72,7 @@ impl Writer {
        }
        // Get the character data from the font array. -- each byte is a row of pixels
-        let data: &[u8] = &self.font.0[c as usize];
+        let data: &[u8] = &self.font.glyphs[c as usize];
        if let Some(writer) = FRAMEBUFFER_WRITER.lock().as_mut() {
            for (row, line) in data.iter().enumerate().take(16) {
@@ -1,45 +0,0 @@
 use linked_list_allocator::LockedHeap;
 use x86_64::{
    VirtAddr,
    structures::paging::{
        FrameAllocator, Mapper, Page, PageTableFlags, Size4KiB, mapper::MapToError,
    },
 };
 /// We are currently using a linked list heap allocator which uses our underlying page allocator.
 pub type FoundryAllocator = LockedHeap;
 #[global_allocator]
 /// This is now Rust's global allocator, so we can use stuff requiring heap allocations.
 static ALLOCATOR: FoundryAllocator = FoundryAllocator::empty();
 pub const HEAP_START: usize = 0x4444_4444_0000;
 pub const HEAP_SIZE: usize = 1000 * 1024;
 /// Sets up the heap using the backing page frame allocator.
 pub fn init_heap(
    mapper: &mut impl Mapper<Size4KiB>,
    frame_allocator: &mut impl FrameAllocator<Size4KiB>,
 ) -> Result<(), MapToError<Size4KiB>> {
    let range = {
        let heap_start = VirtAddr::new(HEAP_START as u64);
        let heap_end = heap_start + HEAP_SIZE as u64 - 1u64;
        let heap_start_page = Page::<Size4KiB>::containing_address(heap_start);
        let heap_end_page = Page::<Size4KiB>::containing_address(heap_end);
        Page::range_inclusive(heap_start_page, heap_end_page)
    };
    for page in range {
        let frame = frame_allocator
            .allocate_frame()
            .ok_or(MapToError::FrameAllocationFailed)?;
        let flags = PageTableFlags::PRESENT | PageTableFlags::WRITABLE;
        unsafe { mapper.map_to(page, frame, flags, frame_allocator)?.flush() };
    }
    unsafe {
        ALLOCATOR.lock().init(HEAP_START as *mut u8, HEAP_SIZE);
    }
    Ok(())
 }
@@ -1 +0,0 @@
 pub mod allocator;
@@ -1,3 +1,3 @@
 pub mod async_io;
 pub mod io;
-pub mod kalloc;
+pub mod pic;
 pub mod scheduling;
@@ -0,0 +1,146 @@
 use x86_64::instructions::port::Port;
 const CMD_INIT: u8 = 0x11;
 const CMD_END_OF_INT: u8 = 0x20;
 const MODE_8086: u8 = 0x01;
 struct Pic {
    offset: u8,
    data: Port<u8>,
    command: Port<u8>,
 }
 impl Pic {
    /// Are we in charge of handling the specified interrupt?
    /// (Each PIC handles 8 interrupts.)
    const fn handles_interrupt(&self, interrupt_id: u8) -> bool {
        self.offset <= interrupt_id && interrupt_id < self.offset + 8
    }
    /// Notify us that an interrupt has been handled and that we're ready
    /// for more.
    unsafe fn end_of_interrupt(&mut self) {
        unsafe { self.command.write(CMD_END_OF_INT) };
    }
    /// Reads the interrupt mask of this PIC.
    unsafe fn read_mask(&mut self) -> u8 {
        unsafe { self.data.read() }
    }
    /// Writes the interrupt mask of this PIC.
    unsafe fn write_mask(&mut self, mask: u8) {
        unsafe { self.data.write(mask) }
    }
 }
 /// A pair of chained PICs.  This is the standard setup on x86.
 pub struct ChainedPics {
    pics: [Pic; 2],
 }
 impl ChainedPics {
    pub const fn new(offset1: u8, offset2: u8) -> Self {
        Self {
            pics: [
                Pic {
                    offset: offset1,
                    command: Port::new(0x20),
                    data: Port::new(0x21),
                },
                Pic {
                    offset: offset2,
                    command: Port::new(0xA0),
                    data: Port::new(0xA1),
                },
            ],
        }
    }
    pub const fn new_contiguous(primary_offset: u8) -> Self {
        Self::new(primary_offset, primary_offset + 8)
    }
    /// # Safety
    ///
    /// This should be safe if called just once on initialisation, however
    /// sending data to IO ports tends to have side-effects.
    pub unsafe fn initialize(&mut self) {
        unsafe {
            let mut wait_port: Port<u8> = Port::new(0x80);
            let mut wait = || wait_port.write(0);
            // Save our original interrupt masks, because I'm too lazy to
            // figure out reasonable values. We'll restore these when we're
            // done.
            let saved_masks = self.read_masks();
            // Tell each PIC that we're going to send it a three-byte
            // initialization sequence on its data port.
            self.pics[0].command.write(CMD_INIT);
            wait();
            self.pics[1].command.write(CMD_INIT);
            wait();
            // Byte 1: Set up our base offsets.
            self.pics[0].data.write(self.pics[0].offset);
            wait();
            self.pics[1].data.write(self.pics[1].offset);
            wait();
            // Byte 2: Configure chaining between PIC1 and PIC2.
            self.pics[0].data.write(4);
            wait();
            self.pics[1].data.write(2);
            wait();
            // Byte 3: Set our mode.
            self.pics[0].data.write(MODE_8086);
            wait();
            self.pics[1].data.write(MODE_8086);
            wait();
            // Restore our saved masks.
            self.write_masks(saved_masks[0], saved_masks[1])
        }
    }
    /// Reads the interrupt masks of both PICs.
    pub fn read_masks(&mut self) -> [u8; 2] {
        unsafe { [self.pics[0].read_mask(), self.pics[1].read_mask()] }
    }
    /// Writes the interrupt masks of both PICs.
    pub fn write_masks(&mut self, mask1: u8, mask2: u8) {
        unsafe {
            self.pics[0].write_mask(mask1);
            self.pics[1].write_mask(mask2);
        }
    }
    /// Disables both PICs by masking all interrupts.
    pub fn disable(&mut self) {
        self.write_masks(u8::MAX, u8::MAX)
    }
    /// Do we handle this interrupt?
    pub fn handles_interrupt(&self, interrupt_id: u8) -> bool {
        self.pics.iter().any(|p| p.handles_interrupt(interrupt_id))
    }
    /// Figure out which (if any) PICs in our chain need to know about this
    /// interrupt.  This is tricky, because all interrupts from `pics[1]`
    /// get chained through `pics[0]`.
    pub fn notify_end_of_interrupt(&mut self, interrupt_id: u8) {
        if self.handles_interrupt(interrupt_id) {
            if self.pics[1].handles_interrupt(interrupt_id) {
                unsafe {
                    self.pics[1].end_of_interrupt();
                }
            }
            unsafe {
                self.pics[0].end_of_interrupt();
            }
        }
    }
 }
@@ -1,6 +1,4 @@
 #![no_std]
 #![allow(async_fn_in_trait)]
 #![warn(tail_expr_drop_order)]
 #![warn(
    clippy::correctness,
    clippy::nursery,
@@ -9,18 +7,15 @@
    clippy::suspicious,
    clippy::perf,
    rustdoc::missing_errors_doc,
-    rustdoc::missing_panics_doc
+    rustdoc::missing_panics_doc,
    tail_expr_drop_order
 )]
 // alloc
 // io : serial, framebuffer, ascii(?), keyboard
 // ?????
 // scheduling / tasks : async
 extern crate alloc;
 pub mod drivers;
 pub mod resources;
 pub mod threads;
 pub mod util;
 #[allow(unused)] // We aren't using much of this right now.
@@ -41,3 +36,12 @@ pub use crate::drivers::io::{
    ascii::{_print, _print_log},
    serial::_serial_write,
 };
 pub type FoundryAllocator = linked_list_allocator::LockedHeap;
 #[global_allocator]
 /// This is now Rust's global allocator, so we can use stuff requiring heap allocations.
 static ALLOCATOR: FoundryAllocator = FoundryAllocator::empty();
 pub const HEAP_START: usize = 0x4444_4444_0000;
 pub const HEAP_SIZE: usize = 1024 * 1024 * 1024;
@@ -1,13 +1,26 @@
 // use libm::include_font;
 use libm::include_font;
 pub mod ibm_vga_8x16;
-pub static FONT_SPLEEN_8X16: Font = Font(include_font!(
+pub static FONT_SPLEEN_8X16: Font =
-    "./libk/resources/font/spleen-8x16.psf"
+    Font::new(include_font!("./libk/resources/font/spleen-8x16.psf"));
 ));
-pub static FONT_CP850_8X16: Font = Font(include_font!(
+pub static FONT_CP850_8X16: Font = Font::new(include_font!("./libk/resources/font/cp850-8x16.psf"));
    "./libk/resources/font/cp850-8x16.psf"
 ));
-pub struct Font(pub [[u8; 16]; 512]);
+pub struct Font {
    pub glyphs: [[u8; 16]; 512],
 }
 impl Default for Font {
    fn default() -> Self {
        Self::new([[0; 16]; 512])
    }
 }
 impl Font {
    pub const fn new(glyphs: [[u8; 16]; 512]) -> Self {
        Self { glyphs }
    }
 }
@@ -7,7 +7,10 @@ mod window;
 pub trait Application {
    type Output;
-    async fn run(&mut self, args: Vec<String>) -> Result<Self::Output, Error>;
+    fn run(
        &mut self,
        args: Vec<String>,
    ) -> impl core::future::Future<Output = Result<Self::Output, Error>> + Send;
 }
 #[derive(Debug)]
@@ -1,2 +0,0 @@
 mod io;
 pub use io::*;
@@ -0,0 +1,113 @@
 use core::arch::asm;
 #[repr(C)]
 pub struct Thread {
    id: usize,
    /// This shall be default before the program is interrupted, otherwise it will store
    /// CPU registers etc to be restored on context switch.
    ctx: ThreadContext,
 }
 /// CPU state to be saved on context switches.
 #[repr(C)]
 #[derive(Default)]
 pub struct ThreadContext {
    /// Accumulator register.
    rax: u64,
    /// Base register.
    rbx: u64,
    /// Counter register.
    rcx: u64,
    /// Data register.
    rdx: u64,
    /// Source index register.
    rsi: u64,
    /// Destination index register.
    rdi: u64,
    /// Base pointer register.
    rbp: u64,
    /// Stack pointer register.
    rsp: u64,
    /// An extended register.
    r8: u64,
    /// An extended register.
    r9: u64,
    /// An extended register.
    r10: u64,
    /// An extended register.
    r11: u64,
    /// An extended register.
    r12: u64,
    /// An extended register.
    r13: u64,
    /// An extended register.
    r14: u64,
    /// An extended register.
    r15: u64,
    /// The instruction pointer.
    rip: u64,
    /// RFLAGS register.
    rflags: u64,
 }
 impl ThreadContext {
    /// Saves the current registers of the CPU before a context switch
    /// to be restored later.
    ///
    /// # Notes
    ///
    /// This function should ONLY be called in interrupt handlers such
    /// as that of the timer. This will then save registers as required
    ///
    ///
    /// # Safety
    ///
    /// This function is unsafe because of the usage of inline ASM.
    #[inline(always)]
    pub unsafe fn save_registers() -> Self {
        let mut context = Self::default();
        unsafe {
            asm!(
                "mov {0}, rax",
                "mov {1}, rbx",
                "mov {2}, rcx",
                "mov {3}, rdx",
                "mov {4}, rsi",
                "mov {5}, rdi",
                "mov {6}, rbp",
                "mov {7}, rsp",
                "mov {8}, r8",
                "mov {9}, r9",
                "mov {10}, r10",
                "mov {11}, r11",
                "mov {12}, r12",
                "mov {13}, r13",
                "mov {14}, r14",
                "mov {15}, r15",
                "lea {16}, [rip]",
                "pushf",
                "pop {17}",
                out(reg) context.rax,
                out(reg) context.rbx,
                out(reg) context.rcx,
                out(reg) context.rdx,
                out(reg) context.rsi,
                out(reg) context.rdi,
                out(reg) context.rbp,
                out(reg) context.rsp,
                out(reg) context.r8,
                out(reg) context.r9,
                out(reg) context.r10,
                out(reg) context.r11,
                out(reg) context.r12,
                out(reg) context.r13,
                out(reg) context.r14,
                out(reg) context.r15,
                out(reg) context.rip,
                out(reg) context.rflags,
            );
        }
        context
    }
 }
@@ -1,4 +1,4 @@
-use x86_64::registers::rflags::read;
+// use x86_64::registers::rflags::read;
 use crate::{drivers::io::ascii::clear_screen, prelude::stdin::read_line, print, println};
@@ -0,0 +1,109 @@
 #!/bin/bash
 # Colors
 GREEN='\033[0;32m'
 BLUE='\033[0;34m'
 YELLOW='\033[0;33m'
 RED='\033[0;31m'
 BOLD='\033[1m'
 NC='\033[0m' # No Color
 # Error handling
 set -e
 trap 'echo -e "${RED}${BOLD}error${NC}: build failed" >&2' ERR
 # Get absolute path to project root
 project_root=$(cd "$script_dir/.." &>/dev/null && pwd)
 build_dir="$project_root/build"
 iso_root="$build_dir/iso_root"
 # Logging functions
 info() {
    echo -e "${BLUE}${BOLD}info${NC}: $1"
 }
 compiling() {
    echo -e "${GREEN}${BOLD}Compiling${NC}: $1"
 }
 warning() {
    echo -e "${YELLOW}${BOLD}warning${NC}: $1" >&2
 }
 building() {
    echo -e "${GREEN}${BOLD}Building${NC}: $1"
 }
 copying() {
    echo -e "${GREEN}${BOLD}  Copying${NC}: $1 to $2"
 }
 error() {
    echo -e "${RED}${BOLD}error${NC}: $1" >&2
    exit 1
 }
 copy_file() {
    copying $1 $2
    cp "$1" "$2" || error $3
 }
 # Check if we're running tests
 if [[ $1 == *"deps"* ]]; then
    kernel_path="$1"
 else
    # Build the kernel normally
    cd "$project_root"
    # cargo build
    kernel_path="$build_dir/target/x86_64-kernel/debug/kernel"
 fi
 # Check for required tools
 check_tools() {
    local missing=0
    for tool in xorriso git qemu-system-x86_64; do
        if ! command -v $tool >/dev/null 2>&1; then
            error "required tool '$tool' is not installed"
            missing=1
        fi
    done
    if [ $missing -eq 1 ]; then
        error "missing required tools"
    fi
 }
 # Create build directory structure
 info "Creating build directory structure"
 mkdir -p "$iso_root/boot/limine"
 mkdir -p "$iso_root/EFI/BOOT"
 # Clone Limine if needed
 if [ ! -d "$build_dir/limine" ]; then
    compiling "limine bootloader"
    cd "$build_dir"
    git clone https://github.com/limine-bootloader/limine.git --branch=v9.x-binary --depth=1 "$build_dir/limine" || error "failed to clone limine"
    make -C "$build_dir/limine" || error "failed to build limine"
    cd "$project_root"
 fi
 # Copy files
 info "Copying files to ISO root"
 copy_file "$kernel_path" "$iso_root/boot/kernel" "failed to copy kernel"
 copy_file "$project_root/config/limine.conf" "$iso_root/boot/limine/limine.conf" "failed to copy limine config"
 copy_file "$build_dir/limine/limine-bios-cd.bin" "$iso_root/boot/limine/" "failed to copy limine-bios-cd.bin"
 copy_file "$build_dir/limine/limine-uefi-cd.bin" "$iso_root/boot/limine/" "failed to copy limine-uefi-cd.bin"
 copy_file "$build_dir/limine/limine-bios.sys" "$iso_root/boot/limine/" "failed to copy limine-bios.sys"
 copy_file "$build_dir/limine/BOOTX64.EFI" "$iso_root/EFI/BOOT/" "failed to copy BOOTX64.EFI"
 copy_file "$build_dir/limine/BOOTIA32.EFI" "$iso_root/EFI/BOOT/" "failed to copy BOOTIA32.EFI"
 # Create ISO
 building "bootable ISO image"
 xorriso -as mkisofs -R -r -J -b boot/limine/limine-bios-cd.bin \
        -no-emul-boot -boot-load-size 4 -boot-info-table -hfsplus \
        -apm-block-size 2048 --efi-boot boot/limine/limine-uefi-cd.bin \
        -efi-boot-part --efi-boot-image --protective-msdos-label \
        "$iso_root" -o "$build_dir/image.iso" || error "failed to create ISO"
 # Install Limine
 info "Installing Limine bootloader"
 "$build_dir/limine/limine" bios-install "$build_dir/image.iso" || error "failed to install limine"
@@ -0,0 +1,20 @@
 #!/bin/bash
 script_dir=$(cd -- "$(dirname -- "${BASH_SOURCE[0]}")" &>/dev/null && pwd)
 source scripts/build.sh
 warning "This script will OVERWRITE whatever media you throw at it\nwith the built ISO."
 info "sudo ./hardware.sh /dev/yourdisk"
 if ! echo "$1" | grep -q "/dev"; then
    error "invalid device"
 fi
 read -p "Confirm (y/n): " confirmation
 if [ "$confirmation" != "y" ]; then
    exit 0
 fi
 dd if=./build/image.iso of="$1"
@@ -1,2 +0,0 @@
 #!/bin/bash
 sudo dd if=./build/image.iso of="$1"
@@ -2,120 +2,16 @@
 # Script originally written by zxq5, I added separate scripts to remove `jq` dependency.
-# Colors
+script_dir=$(cd -- "$(dirname -- "${BASH_SOURCE[0]}")" &>/dev/null && pwd)
-GREEN='\033[0;32m'
+
-BLUE='\033[0;34m'
+source $script_dir/build.sh
 YELLOW='\033[0;33m'
 RED='\033[0;31m'
 BOLD='\033[1m'
 NC='\033[0m' # No Color
 # Error handling
 set -e
 trap 'echo -e "${RED}${BOLD}error${NC}: build failed" >&2' ERR
 # Get absolute path to project root
 script_dir=$(cd -- "$(dirname -- "${BASH_SOURCE[0]}")" &>/dev/null && pwd)
 project_root=$(cd "$script_dir/.." &>/dev/null && pwd)
 echo -e "${GREEN}${BOLD} Running kernel in debug mode."
 # Logging functions
 info() {
    echo -e "${BLUE}${BOLD}info${NC}: $1"
 }
 compiling() {
    echo -e "${GREEN}${BOLD}Compiling${NC}: $1"
 }
 warning() {
    echo -e "${YELLOW}${BOLD}warning${NC}: $1" >&2
 }
 building() {
    echo -e "${GREEN}${BOLD}Building${NC}: $1"
 }
 copying() {
    echo -e "${GREEN}${BOLD}  Copying${NC}: $1 to $2"
 }
 error() {
    echo -e "${RED}${BOLD}error${NC}: $1" >&2
    exit 1
 }
 copy_file() {
    copying $1 $2
    cp "$1" "$2" || error $3
 }
 build_dir="$project_root/build"
 iso_root="$build_dir/iso_root"
 # Check if we're running tests
 is_test=0
 if [[ $1 == *"deps"* ]]; then
    is_test=1
    kernel_path="$1"
 else
    # Build the kernel normally
    cd "$project_root"
    # cargo build
    kernel_path="$build_dir/target/x86_64-kernel/debug/kernel"
 fi
 # Check for required tools
 check_tools() {
    local missing=0
    for tool in xorriso git qemu-system-x86_64; do
        if ! command -v $tool >/dev/null 2>&1; then
            error "required tool '$tool' is not installed"
            missing=1
        fi
    done
    if [ $missing -eq 1 ]; then
        error "missing required tools"
    fi
 }
 # Create build directory structure
 info "Creating build directory structure"
 mkdir -p "$iso_root/boot/limine"
 mkdir -p "$iso_root/EFI/BOOT"
 # Clone Limine if needed
 if [ ! -d "$build_dir/limine" ]; then
    compiling "limine bootloader"
    cd "$build_dir"
    git clone https://github.com/limine-bootloader/limine.git --branch=v9.x-binary --depth=1 "$build_dir/limine" || error "failed to clone limine"
    make -C "$build_dir/limine" || error "failed to build limine"
    cd "$project_root"
 fi
 # Copy files
 info "Copying files to ISO root"
 copy_file "$kernel_path" "$iso_root/boot/kernel" "failed to copy kernel"
 copy_file "$project_root/config/limine.conf" "$iso_root/boot/limine/limine.conf" "failed to copy limine config"
 copy_file "$build_dir/limine/limine-bios-cd.bin" "$iso_root/boot/limine/" "failed to copy limine-bios-cd.bin"
 copy_file "$build_dir/limine/limine-uefi-cd.bin" "$iso_root/boot/limine/" "failed to copy limine-uefi-cd.bin"
 copy_file "$build_dir/limine/limine-bios.sys" "$iso_root/boot/limine/" "failed to copy limine-bios.sys"
 copy_file "$build_dir/limine/BOOTX64.EFI" "$iso_root/EFI/BOOT/" "failed to copy BOOTX64.EFI"
 copy_file "$build_dir/limine/BOOTIA32.EFI" "$iso_root/EFI/BOOT/" "failed to copy BOOTIA32.EFI"
 # Create ISO
 building "bootable ISO image"
 xorriso -as mkisofs -R -r -J -b boot/limine/limine-bios-cd.bin \
        -no-emul-boot -boot-load-size 4 -boot-info-table -hfsplus \
        -apm-block-size 2048 --efi-boot boot/limine/limine-uefi-cd.bin \
        -efi-boot-part --efi-boot-image --protective-msdos-label \
        "$iso_root" -o "$build_dir/image.iso" || error "failed to create ISO"
 # Install Limine
 info "Installing Limine bootloader"
 "$build_dir/limine/limine" bios-install "$build_dir/image.iso" || error "failed to install limine"
 # Check if KVM is available
 if [ "${KVM_FLAG:-enable}" = "disable" ]; then
    warning "KVM acceleration disabled by user"
@@ -145,6 +41,31 @@ else
    serial_flags="-serial stdio"
 fi
 # Set up VM memory
 if [ $VM_MEMORY ]; then
    vm_memory_flag="-m $VM_MEMORY"
 else
    vm_memory_flag="-m 2G"
 fi
 # Set up boot flags
 if [ $USE_LEGACY_BIOS ]; then
    boot_flags=""
 else
 #   Check for the presence of the OVMF firmware.
    if [ ! -f $build_dir/RELEASEX64_OVMF_CODE.fd ]; then
        info "Downloading OVMF UEFI firmware for QEMU"
        info "To disable this, set USE_LEGACY_BIOS=1."
        pushd $build_dir
        curl https://retrage.github.io/edk2-nightly/bin/RELEASEX64_OVMF_CODE.fd -LO || error "failed to download OVMF firmware for UEFI"
        curl https://retrage.github.io/edk2-nightly/bin/RELEASEX64_OVMF_VARS.fd -LO || error "failed to download OVMF firmware for UEFI"
        popd
    fi
    boot_flags="-drive if=pflash,format=raw,readonly=on,file=$build_dir/RELEASEX64_OVMF_CODE.fd \
                -drive if=pflash,format=raw,file=$build_dir/RELEASEX64_OVMF_VARS.fd"
 fi
 # Run in QEMU
 if [[ ${QEMU_FLAGS} == *-S* ]]; then
    info "Running OS in QEMU with GDB debugging enabled"
@@ -171,23 +92,18 @@ check_test_res() {
    fi
 }
 kvm_flag=""
 trap 'check_test_res "tests completed"' ERR
    # $build_dir/image.iso
 cd "$project_root"
 qemu-system-x86_64 -M q35 \
    -cdrom "$build_dir/image.iso" \
    ${kvm_flag} \
    -boot d \
-    -m 2G \
+    ${vm_memory_flag} \
    ${serial_flags} \
    -no-reboot \
    ${test_flags} \
    ${debug_flags} \
    ${boot_flags} \
    ${QEMU_FLAGS:-}
@@ -2,120 +2,23 @@
 # Script originally written by zxq5, I added separate scripts to remove `jq` dependency.
-# Colors
+script_dir=$(cd -- "$(dirname -- "${BASH_SOURCE[0]}")" &>/dev/null && pwd)
-GREEN='\033[0;32m'
+
-BLUE='\033[0;34m'
+source $script_dir/build.sh
 YELLOW='\033[0;33m'
 RED='\033[0;31m'
 BOLD='\033[1m'
 NC='\033[0m' # No Color
 # Error handling
 set -e
 trap 'echo -e "${RED}${BOLD}error${NC}: build failed" >&2' ERR
 # Get absolute path to project root
 script_dir=$(cd -- "$(dirname -- "${BASH_SOURCE[0]}")" &>/dev/null && pwd)
 project_root=$(cd "$script_dir/.." &>/dev/null && pwd)
 echo -e "${GREEN}${BOLD} Running kernel in release mode."
 # Logging functions
 info() {
    echo -e "${BLUE}${BOLD}info${NC}: $1"
 }
-compiling() {
+if [ $VM_MEMORY ]; then
-    echo -e "${GREEN}${BOLD}Compiling${NC}: $1"
+    vm_memory_flag="-m $VM_MEMORY"
 }
 warning() {
    echo -e "${YELLOW}${BOLD}warning${NC}: $1" >&2
 }
 building() {
    echo -e "${GREEN}${BOLD}Building${NC}: $1"
 }
 copying() {
    echo -e "${GREEN}${BOLD}  Copying${NC}: $1 to $2"
 }
 error() {
    echo -e "${RED}${BOLD}error${NC}: $1" >&2
    exit 1
 }
 copy_file() {
    copying $1 $2
    cp "$1" "$2" || error $3
 }
 build_dir="$project_root/build"
 iso_root="$build_dir/iso_root"
 # Check if we're running tests
 is_test=0
 if [[ $1 == *"deps"* ]]; then
    is_test=1
    kernel_path="$1"
 else
-    # Build the kernel normally
+    vm_memory_flag="-m 2G"
    cd "$project_root"
    # cargo build
    kernel_path="$build_dir/target/x86_64-kernel/release/kernel"
 fi
 # Check for required tools
 check_tools() {
    local missing=0
    for tool in xorriso git qemu-system-x86_64; do
        if ! command -v $tool >/dev/null 2>&1; then
            error "required tool '$tool' is not installed"
            missing=1
        fi
    done
    if [ $missing -eq 1 ]; then
        error "missing required tools"
    fi
 }
 # Create build directory structure
 info "Creating build directory structure"
 mkdir -p "$iso_root/boot/limine"
 mkdir -p "$iso_root/EFI/BOOT"
 # Clone Limine if needed
 if [ ! -d "$build_dir/limine" ]; then
    compiling "limine bootloader"
    cd "$build_dir"
    git clone https://github.com/limine-bootloader/limine.git --branch=v9.x-binary --depth=1 "$build_dir/limine" || error "failed to clone limine"
    make -C "$build_dir/limine" || error "failed to build limine"
    cd "$project_root"
 fi
 # Copy files
 info "Copying files to ISO root"
 copy_file "$kernel_path" "$iso_root/boot/kernel" "failed to copy kernel"
 copy_file "$project_root/config/limine.conf" "$iso_root/boot/limine/limine.conf" "failed to copy limine config"
 copy_file "$build_dir/limine/limine-bios-cd.bin" "$iso_root/boot/limine/" "failed to copy limine-bios-cd.bin"
 copy_file "$build_dir/limine/limine-uefi-cd.bin" "$iso_root/boot/limine/" "failed to copy limine-uefi-cd.bin"
 copy_file "$build_dir/limine/limine-bios.sys" "$iso_root/boot/limine/" "failed to copy limine-bios.sys"
 copy_file "$build_dir/limine/BOOTX64.EFI" "$iso_root/EFI/BOOT/" "failed to copy BOOTX64.EFI"
 copy_file "$build_dir/limine/BOOTIA32.EFI" "$iso_root/EFI/BOOT/" "failed to copy BOOTIA32.EFI"
 # Create ISO
 building "bootable ISO image"
 xorriso -as mkisofs -R -r -J -b boot/limine/limine-bios-cd.bin \
        -no-emul-boot -boot-load-size 4 -boot-info-table -hfsplus \
        -apm-block-size 2048 --efi-boot boot/limine/limine-uefi-cd.bin \
        -efi-boot-part --efi-boot-image --protective-msdos-label \
        "$iso_root" -o "$build_dir/image.iso" || error "failed to create ISO"
 # Install Limine
 info "Installing Limine bootloader"
 "$build_dir/limine/limine" bios-install "$build_dir/image.iso" || error "failed to install limine"
 # Check if KVM is available
 if [ "${KVM_FLAG:-enable}" = "disable" ]; then
    warning "KVM acceleration disabled by user"
@@ -128,59 +31,30 @@ else
    kvm_flag=""
 fi
-# I'm lazy but I just remove GDB flags when running this script.
+if [ $USE_LEGACY_BIOS ]; then
-debug_flags=""
+    boot_flags=""
 # Set up test-specific flags
 if [ $is_test -eq 1 ]; then
    test_flags="-device isa-debug-exit,iobase=0xf4,iosize=0x04 -display none"
    serial_flags="-serial stdio"
 else
-    test_flags=""
+#   Check for the presence of the OVMF firmware.
-    # serial_flags="-serial tcp:127.0.0.1:1234,server -monitor telnet:127.0.0.1:1235,server"
+    if [ ! -f $build_dir/RELEASEX64_OVMF_CODE.fd ]; then
-    serial_flags="-serial stdio"
+        info "Downloading OVMF UEFI firmware for QEMU"
-fi
+        info "To disable this, set USE_LEGACY_BIOS=1."
-
+        pushd $build_dir
-# Run in QEMU
+        curl https://retrage.github.io/edk2-nightly/bin/RELEASEX64_OVMF_CODE.fd -LO || error "failed to download OVMF firmware for UEFI"
-if [[ ${QEMU_FLAGS} == *-S* ]]; then
+        curl https://retrage.github.io/edk2-nightly/bin/RELEASEX64_OVMF_VARS.fd -LO || error "failed to download OVMF firmware for UEFI"
-    info "Running OS in QEMU with GDB debugging enabled"
+        popd
    info "To connect GDB, run: gdb"
    info "At the GDB prompt, type: target remote localhost:1234"
 else
    info "Running OS in QEMU..."
 fi
 check_test_res() {
    qemu_exit_code=$?
    if [ $qemu_exit_code -eq 33 ]; then
        # Success case (0x10 << 1) | 1 = 33
        info "All tests passed"
        exit 0
    elif [ $qemu_exit_code -eq 35 ]; then
        # Failure case (0x11 << 1) | 1 = 35
        warning "Some tests failed"
        exit 1
    else
        # Any other exit code is treated as a failure
        warning "Some tests failed"
        exit 1
    fi
 }
    boot_flags="-drive if=pflash,format=raw,readonly=on,file=$build_dir/RELEASEX64_OVMF_CODE.fd \
                -drive if=pflash,format=raw,file=$build_dir/RELEASEX64_OVMF_VARS.fd"
 fi
 kvm_flag=""
 trap 'check_test_res "tests completed"' ERR
 cd "$project_root"
 qemu-system-x86_64 -M q35 \
    ${kvm_flag} \
    -cdrom "$build_dir/image.iso" \
    -boot d \
-    -m 2G \
+    ${vm_memory_flag} \
    ${serial_flags} \
    -no-reboot \
-    ${test_flags} \
+    ${boot_flags}
    ${debug_flags} \
    ${QEMU_FLAGS:-}
Author	SHA1	Message	Date
nullndvoid	92fe618a99	Megacommit to move some memory code into kernel crate	2025-02-28 02:13:50 +00:00
zxq5	192100be7a	changed page allocation to happen on page fault for performance reasons	2025-02-27 23:57:23 +00:00
nullndvoid	2915d0c879	Add tips on debugging/disassembling kernel sources	2025-02-27 23:32:05 +00:00
zxq5	9852cb14eb	updated build scripts	2025-02-27 22:58:10 +00:00
zxq5	db8dbff9f2	added memory allocation flag to run command ```VM_MEMORY=<amount>G cargo run```	2025-02-27 21:57:58 +00:00
zxq5	2178215a01	fixed triple fault	2025-02-27 16:52:31 +00:00
zxq5	821759ec63	apic broken pushing to debug	2025-02-27 16:19:43 +00:00
zxq5	ac0b47a45c	merge	2025-02-26 04:00:00 +00:00
zxq5	15f59e68d5	initial apic implementaion (Commented out / NOT WORKING)	2025-02-26 03:48:11 +00:00
nullndvoid	b7397d8a1b	Remove unused clippy lints	2025-02-25 03:20:05 +00:00
nullndvoid	4fe6109e5b	Rename scheduling to 'async_io', general cleanup	2025-02-25 03:18:12 +00:00
nullndvoid	e294a13a91	Cleanup the README a little more	2025-02-25 02:59:55 +00:00
nullndvoid	752800a3ca	Merge UEFI support for qemu into our runner scripts/build system	2025-02-25 02:56:48 +00:00
nullndvoid	177fddcf7d	Add warnings to hardware script (dd implies 'doubly dangerous')	2025-02-25 02:55:52 +00:00
nullndvoid	375c5aa561	Update limine.conf to boot up faster	2025-02-25 02:54:19 +00:00
nullndvoid	b945416665	Add qemu UEFI firmware support.	2025-02-25 02:53:28 +00:00
`@@ -1,4 +1,4 @@`
	`use x86_64::registers::rflags::read;`	`// use x86_64::registers::rflags::read;`

	`use crate::{drivers::io::ascii::clear_screen, prelude::stdin::read_line, print, println};`	`use crate::{drivers::io::ascii::clear_screen, prelude::stdin::read_line, print, println};`
		`@@ -1,2 +0,0 @@`
			`#!/bin/bash`
			`sudo dd if=./build/image.iso of="$1"`