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base: LowLevelDevs/FoundryOS:f502104a6ee9e628bd5f6d2740e84e07c4b7e774
Branches Tags
LowLevelDevs/FoundryOS:dev LowLevelDevs/FoundryOS:unified LowLevelDevs/FoundryOS:huge_refactor LowLevelDevs/FoundryOS:pmm LowLevelDevs/FoundryOS:main
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compare: LowLevelDevs/FoundryOS:unified
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LowLevelDevs/FoundryOS:unified LowLevelDevs/FoundryOS:dev LowLevelDevs/FoundryOS:huge_refactor LowLevelDevs/FoundryOS:pmm LowLevelDevs/FoundryOS:main

24 Commits
f502104a6e .. unified

Author SHA1 Message Date
zxq5 b80b400c19 fixed interrupts (temporary, we need to do a real fix for this) 2025-03-10 15:40:38 +00:00
nullndvoid 31f14e8aec Get rid of warning 2025-03-10 13:35:27 +00:00
nullndvoid 91e5602e82 Don't enable APIC yet 2025-03-10 13:29:07 +00:00
nullndvoid a83108a08e Clean up dead code 2025-03-08 18:43:43 +00:00
nullndvoid da6690fd8b Save failed stack trace code for future reference. 2025-03-08 18:40:05 +00:00
nullndvoid 4b8388c66d Update boot prints to be a little less noisy. 
TODO:

* Debugging, tracing support.
* Logging infra so we can may pass a loglevel like on Linux.
 2025-03-06 20:32:46 +00:00
nullndvoid 1d192adde0 Removed messy debug logging, added print_oneshot!() 2025-03-06 20:11:54 +00:00
zxq5 4bf31e653b Merge remote-tracking branch 'refs/remotes/origin/unified' into unified 2025-03-06 01:22:53 +00:00
nullndvoid 5aad3e6096 Fixed stack unwind bugs (works!) 2025-03-06 01:22:17 +00:00
zxq5 c06425949a Merge remote-tracking branch 'refs/remotes/origin/unified' into unified 2025-03-06 01:21:02 +00:00
zxq5 ecdc76b068 Merge remote-tracking branch 'origin' into unified 2025-03-06 01:18:43 +00:00
nullndvoid f197149d80 Forced unwind tables - still bugged 2025-03-06 01:01:04 +00:00
nullndvoid bc51f3ec43 Force rustc to generate unwind-tables - infinite loop :( 2025-03-05 22:37:19 +00:00
nullndvoid b26dc6de01 Wrote stack unwinder. NEEDTO: fix NoUnwindInfo 
Probably incorrect PC was set.
 2025-03-05 22:21:38 +00:00
zxq5 8ee4af1a48 someone broke a mod.rs so i fixed it. 2025-03-05 21:10:36 +00:00
zxq5 03c07cb5c4 Merging with origin/unified 2025-03-05 21:04:58 +00:00
zxq5 ef70bcf51e - heap allocator now makes sure virtual memory pages are mapped before using them. this means we no longer have to use page faults to allocate frames, it is done automatically. 
- fixed the apic code that caused a page fault. it now writes the correct values at the correct physical address
- improved startup logging including displaying how much RAM is installed.
 2025-03-05 20:49:21 +00:00
nullndvoid 2fb1741100 Begin setting up stack unwinding/tracing. 
This actually worked so I am chuffed, but it doesn't read the necessary
DWARF structures just yet. Still a good step forwards.
 2025-03-05 20:44:09 +00:00
nullndvoid af995d1d76 Tried and failed to use unwinding crate: shall do it myself tomorrow. 2025-03-05 03:24:26 +00:00
nullndvoid 014ec5310c Some more clippy fixes, warnings are noisy 2025-03-05 00:57:06 +00:00
nullndvoid d53661b9a0 Ran cargo fmt, clippy fixes, suppressed some warns 
I will start working on stack traces tonight and tomorrow.

We need to be able to 'unwind' by finding calling functions.
 2025-03-04 23:06:47 +00:00
zxq5 8704b5d249 FIXED THE APIC HELL YEAH 2025-03-04 12:44:42 +00:00
zxq5 2186b829aa - made improvements to memory code (refactored) 
- started on improvements to the page frame allocator. it should be able to provide a usable page for any given virtual memory address requested.
 2025-03-04 01:28:39 +00:00
aha480 e8237f4610 run_debug.sh now checks if it running on wsl and disables boot_flags if it is since it was causing issues with qemu 2025-03-01 12:49:42 +00:00
45 changed files with 1122 additions and 447 deletions
Expand all files Collapse all files
.cargo/config.toml
-3
View File
@@ -17,8 +17,5 @@ runner = "scripts/run_debug.sh"
[target.'cfg(all(target_arch = "x86_64", target_os = "none", not(debug_assertions)))']
runner = "scripts/run_release.sh"
# [registry]
# default = "gitea"
[registries.gitea]
index = "sparse+https://git.zxq5.dev/api/packages/OsDev/cargo/" # Sparse index
.idea/FoundryOS.iml
Generated
+1
View File
@@ -6,6 +6,7 @@
<sourceFolder url="file://$MODULE_DIR$/lib_example/src" isTestSource="false" />
<sourceFolder url="file://$MODULE_DIR$/libk/src" isTestSource="false" />
<sourceFolder url="file://$MODULE_DIR$/libm/src" isTestSource="false" />
<sourceFolder url="file://$MODULE_DIR$/kernel_fonts/src" isTestSource="false" />
<excludeFolder url="file://$MODULE_DIR$/target" />
</content>
<orderEntry type="inheritedJdk" />
.idea/codeStyles/codeStyleConfig.xml
Generated
+5
View File
@@ -0,0 +1,5 @@
<component name="ProjectCodeStyleConfiguration">
<state>
<option name="PREFERRED_PROJECT_CODE_STYLE" value="Default" />
</state>
</component>
.vscode/settings.json
Vendored
+2 -1
View File
@@ -5,5 +5,6 @@
"editor.defaultFormatter": "rust-lang.rust-analyzer",
"editor.formatOnSave": true
},
"rust-analyzer.check.command": "clippy"
"rust-analyzer.check.command": "clippy",
"rust-analyzer.cargo.buildScripts.enable": true
}
kernel/Cargo.toml
+5
View File
@@ -19,6 +19,11 @@ futures-util = { version = "0.3.31", default-features = false, features = [
"alloc",
] }
linked_list_allocator = { version = "0.10.5", features = ["use_spin"] }
# gimli = { version = "0.31.1", default-features = false, features = ["read"] }
# elf = { version = "0.7.4", default-features = false, features = ["nightly"] }
# fallible-iterator = "0.3.0"
# framehop = { version = "0.13.2", default-features = false }
# object = { version = "0.36.7", default-features = false, features = ["read"] }
[build-dependencies]
cc = "1.2.14"
kernel/linker.ld
+1 -2
View File
@@ -62,9 +62,8 @@ SECTIONS
*(COMMON)
} :data
/* Discard .note.* and .eh_frame* since they may cause issues on some hosts. */
/* Discard .note.* and ~~.eh_frame*~~ since they may cause issues on some hosts. */
/DISCARD/ : {
*(.eh_frame*)
*(.note .note.*)
}
}
kernel/src/arch/x86_64/cpu/apic.rs
+39 -43
View File
@@ -1,15 +1,20 @@
#![expect(unused)]
use core::arch::x86_64::__cpuid;
use crate::arch::x86_64::memory::memory_map::PHYSICAL_MEMORY_OFFSET;
use crate::serial_print;
use crate::arch::x86_64::{
cpu::msr::*,
memory::{
FRAME_ALLOCATOR, OFFSET_PAGE_TABLE, mapping::PHYSICAL_MEMORY_OFFSET,
},
};
use x86_64::structures::paging::Translate;
use x86_64::{
PhysAddr, VirtAddr,
structures::paging::{Mapper, Page, PageTableFlags, PhysFrame, Size4KiB},
};
use crate::arch::x86_64::cpu::msr::*;
use crate::arch::x86_64::memory::{FRAME_ALLOCATOR, OFFSET_PAGE_TABLE};
const IA32_APIC_BASE_MSR: u32 = 0x1b;
const IA32_APIC_BASE_MSR_BSP: u64 = 0x100;
const IA32_APIC_BASE_MSR_ENABLE: u64 = 0x800;
@@ -29,6 +34,7 @@ fn set_apic_base_enable(apic: PhysAddr) {
cpu_set_msr(IA32_APIC_BASE_MSR, rax);
}
#[allow(dead_code)]
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);
@@ -37,22 +43,27 @@ fn set_apic_base_disable(apic: PhysAddr) {
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) {
fn write_apic_register(apic_base: &PhysAddr, reg: u64, 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 };
let reg_addr = (apic_base & 0xFFFFF0000) + reg;
let virt_addr = unsafe { phys_to_virt(PhysAddr::new(reg_addr)) };
let phys_check =
OFFSET_PAGE_TABLE.get().unwrap().lock().translate(virt_addr);
unsafe { *(virt_addr.as_u64() as *mut u32) = value };
}
fn read_apic_register(apic_base: &VirtAddr, reg: u8) -> u32 {
fn read_apic_register(apic_base: &PhysAddr, reg: u64) -> 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) }
let reg_addr = (apic_base & 0xFFFFF0000) + reg;
let virt_addr = unsafe { phys_to_virt(PhysAddr::new(reg_addr)) };
unsafe { *(virt_addr.as_u64() as *const u32) }
}
pub fn check_apic() -> bool {
@@ -64,39 +75,24 @@ pub fn check_apic() -> bool {
unsafe fn phys_to_virt(phys: PhysAddr) -> VirtAddr {
let phys = phys.as_u64();
phys.checked_add(*PHYSICAL_MEMORY_OFFSET)
.map_or_else(|| panic!(" overflow"), VirtAddr::new)
.map_or_else(|| panic!("Overflow"), VirtAddr::new)
}
pub fn enable_apic() {
let mut mapper = OFFSET_PAGE_TABLE.get().unwrap().lock();
let mut frame_allocator = FRAME_ALLOCATOR.get().unwrap().lock();
let apic_base_physical_addr = get_apic_base();
set_apic_base_enable(apic_base_physical_addr);
let apic_phys_addr = get_apic_base();
set_apic_base_enable(apic_phys_addr);
// map virt address of apic
enable_timer();
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, &mut *frame_allocator) {
Ok(_) => {}
Err(why) => panic!("failed to map apic: {:?}", why),
}
}
// // FIXME: this causes a page fault
// // TODO: map to virtual memory
let reg = read_apic_register(&apic_virt, 0xF0);
serial_print!("ok2");
write_apic_register(&apic_virt, 0xF0, reg | 0x100);
write_apic_register(
&apic_base_physical_addr,
0xF0,
read_apic_register(&apic_base_physical_addr, 0xF0) | 0x1FF,
);
}
pub struct Apic {}
pub enum ApicVector {}
pub fn enable_timer() {
let apic_base = get_apic_base();
let current = read_apic_register(&apic_base, 0x320);
write_apic_register(&get_apic_base(), 0x320, (current & 0xFFFFFF00) | 0x20);
}
kernel/src/arch/x86_64/cpu/msr.rs
+1
View File
@@ -1,3 +1,4 @@
#![expect(unused)]
use core::arch::x86_64::__cpuid;
use spin::Lazy;
use x86_64::registers::model_specific::Msr;
kernel/src/arch/x86_64/cpu/pic.rs
+2
View File
@@ -1,3 +1,5 @@
#![allow(clippy::missing_safety_doc)]
use x86_64::instructions::port::Port;
const CMD_INIT: u8 = 0x11;
kernel/src/arch/x86_64/drivers/ascii/mod.rs
+72 -15
View File
@@ -1,15 +1,19 @@
use core::fmt;
use core::fmt::{self, Write};
use spin::{Lazy, Mutex};
use x86_64::instructions::interrupts;
use crate::arch::x86_64::drivers::framebuffer::{colour::Colour, display::FRAMEBUFFER_WRITER};
use crate::arch::x86_64::drivers::framebuffer::{
colour::Colour, display::FRAMEBUFFER_WRITER,
};
use crate::resources::font::{FONT_SPLEEN_8X16, Font};
use crate::std::maths::geometry::Vec2;
static FONT_WIDTH: u32 = 8;
static FONT_HEIGHT: u32 = 16;
pub static WRITER: Lazy<Mutex<Writer>> = Lazy::new(|| Mutex::new(Writer::new()));
pub static WRITER: Lazy<Mutex<Writer>> =
Lazy::new(|| Mutex::new(Writer::new()));
pub fn screensize_chars() -> (u32, u32) {
let writer = WRITER.lock();
@@ -22,11 +26,8 @@ pub struct Writer {
screen_width: u32,
/// Measured in chars not pixels.
screen_height: u32,
/// 16 pixels tall.
text_line: u32,
/// 8 pixels wide.
text_col: u32,
fg_color: Colour,
bg_color: Colour,
}
@@ -59,6 +60,15 @@ impl Writer {
self.font = font;
}
pub const fn set_pos(&mut self, coords: Vec2<u32>) {
self.text_col = coords.x();
self.text_line = coords.y();
}
pub const fn pos(&self) -> Vec2<u32> {
Vec2::new(self.text_col, self.text_line)
}
/// This is sent when the user types a backspace.
const BACKSPACE: u8 = 8;
@@ -71,21 +81,31 @@ impl Writer {
return;
}
// Get the character data from the font array. -- each byte is a row of pixels
// Get the character data from the font array. -- each byte is a row of
// pixels
let data: &[u8] = self.font.glyph_for(c as u16);
if let Some(writer) = FRAMEBUFFER_WRITER.lock().as_mut() {
for (row, line) in data.iter().enumerate().take(16) {
for col in 0..8 {
let pixel_x: u32 = self.text_col * FONT_WIDTH + col;
let pixel_y: u32 = self.text_line * FONT_HEIGHT + row as u32;
let pixel_y: u32 =
self.text_line * FONT_HEIGHT + row as u32;
if line & (0x80 >> col) != 0 {
// Write the foreground color
writer.write_pixel(pixel_x as usize, pixel_y as usize, self.fg_color);
writer.write_pixel(
pixel_x as usize,
pixel_y as usize,
self.fg_color,
);
} else {
// Write the background color
writer.write_pixel(pixel_x as usize, pixel_y as usize, self.bg_color);
writer.write_pixel(
pixel_x as usize,
pixel_y as usize,
self.bg_color,
);
}
}
}
@@ -117,8 +137,8 @@ impl Writer {
}
}
/// Handles the backspace character. TODO: Implement VT-100 style terminal control
/// codes alongside a shell. Not simple.
/// Handles the backspace character. TODO: Implement VT-100 style terminal
/// control codes alongside a shell. Not simple.
pub fn backspace(&mut self) {
if self.text_col > 0 {
self.text_col -= 1;
@@ -193,6 +213,34 @@ pub fn clear_screen() {
});
}
/// Prints a string at a given `coords` before returning to original position.
///
/// These are 0 based indices and refer to character position, not pixel
/// positions.
pub fn _print_oneshot(
fg: Colour,
bg: Colour,
coords: Vec2<u32>,
args: fmt::Arguments,
) {
interrupts::without_interrupts(|| {
let mut writer = WRITER.lock();
// Save the old positions of `text_col` and `text_line`.
let old_pos = writer.pos();
// Also save the colors.
let old_fg_color = writer.fg_color;
let old_bg_color = writer.bg_color;
writer.set_pos(coords);
writer.set_colour(fg, bg);
writer.write_fmt(args).unwrap();
writer.set_colour(old_fg_color, old_bg_color);
writer.set_pos(old_pos);
});
}
pub fn reset_cursor() {
interrupts::without_interrupts(|| {
let mut writer = WRITER.lock();
@@ -201,6 +249,15 @@ pub fn reset_cursor() {
});
}
#[macro_export]
/// Prints a coloured string at a position before restoring previous position
/// and colour.
macro_rules! print_oneshot {
($position:expr, $fg:expr, $bg:expr, $($arg:tt)*) => {
$crate::arch::x86_64::drivers::ascii::_print_oneshot($fg, $bg, $position, format_args!($($arg)*));
};
}
#[macro_export]
macro_rules! println_log {
() => ($crate::print_log!("\n"));
@@ -224,12 +281,12 @@ macro_rules! print {
}
#[macro_export]
macro_rules! printlnerr {
macro_rules! eprintln {
() => ($crate::printerr!("\n"));
($($arg:tt)*) => ($crate::printerr!("{}\n", format_args!($($arg)*)));
($($arg:tt)*) => ($crate::eprint!("{}\n", format_args!($($arg)*)));
}
#[macro_export]
macro_rules! printerr {
macro_rules! eprint {
($($arg:tt)*) => ($crate::prelude::_print_err(format_args!($($arg)*)));
}
kernel/src/arch/x86_64/drivers/framebuffer/colour.rs
+10 -3
View File
@@ -19,9 +19,14 @@ impl From<Colour> for u32 {
fn from(val: Colour) -> Self {
match val {
Colour::ARGB(a, r, g, b) => {
(a as u32) << 24 | (r as u32) << 16 | (g as u32) << 8 | (b as u32)
(a as u32) << 24
| (r as u32) << 16
| (g as u32) << 8
| (b as u32)
}
Colour::RGB(r, g, b) => {
((r as u32) << 16) | (g as u32) << 8 | (b as u32)
}
Colour::RGB(r, g, b) => ((r as u32) << 16) | (g as u32) << 8 | (b as u32),
Colour::HexARGB(hex) => hex,
Colour::Black => 0xFF000000,
Colour::Blue => 0xFF0000FF,
@@ -38,7 +43,9 @@ impl From<Colour> for u32 {
impl core::fmt::Display for Colour {
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
match self {
Self::ARGB(r, g, b, a) => write!(f, "RGBA(#{:x}{:x}{:x}{:x})", r, g, b, a),
Self::ARGB(r, g, b, a) => {
write!(f, "RGBA(#{:x}{:x}{:x}{:x})", r, g, b, a)
}
Self::RGB(r, g, b) => write!(f, "RGB(#{:x}{:x}{:x})", r, g, b),
Self::HexARGB(hex) => write!(f, "Hex(#{:x})", hex),
Self::Black => write!(f, "Black"),
kernel/src/arch/x86_64/drivers/framebuffer/display.rs
+7 -4
View File
@@ -10,17 +10,19 @@ use core::panic;
use limine::framebuffer::Framebuffer;
use spin::{Lazy, Mutex};
pub static FRAMEBUFFER_WRITER: Lazy<Mutex<Option<FramebufferWriter>>> = Lazy::new(|| {
pub static FRAMEBUFFER_WRITER: Lazy<Mutex<Option<FramebufferWriter>>> =
Lazy::new(|| {
Mutex::new(FRAMEBUFFER_REQUEST.get_response().map_or_else(
|| {
panic!("Framebuffer request failed");
},
|framebuffer_response| {
let framebuffer = framebuffer_response.framebuffers().next().unwrap();
let framebuffer =
framebuffer_response.framebuffers().next().unwrap();
Some(FramebufferWriter::new(framebuffer))
},
))
});
});
/// The updated writer stores necessary fields from the [Framebuffer].
/// This ensures that the contained types are Send, as Framebuffer was
@@ -28,7 +30,8 @@ pub static FRAMEBUFFER_WRITER: Lazy<Mutex<Option<FramebufferWriter>>> = Lazy::ne
///
/// It also avoids the requirement for lifetimes.
///
/// Note this does not implement Writer as these functions only handle drawing pixels.
/// Note this does not implement Writer as these functions only handle drawing
/// pixels.
pub struct FramebufferWriter {
pitch: u64,
bpp: u16,
kernel/src/arch/x86_64/drivers/keyboard.rs
+11 -4
View File
@@ -6,20 +6,24 @@ use core::{
use crate::println;
use crossbeam::queue::ArrayQueue;
use futures_util::{Stream, StreamExt, task::AtomicWaker};
use pc_keyboard::{DecodedKey, HandleControl, KeyCode, Keyboard, ScancodeSet1, layouts::Uk105Key};
use pc_keyboard::{
DecodedKey, HandleControl, KeyCode, Keyboard, ScancodeSet1,
layouts::Uk105Key,
};
use spin::{Lazy, Mutex, Once};
static KBD_QUEUE: Once<ArrayQueue<u8>> = Once::new();
static WAKER: AtomicWaker = AtomicWaker::new();
pub static KEYBOARD: Lazy<Mutex<Keyboard<Uk105Key, ScancodeSet1>>> = Lazy::new(|| {
pub static KEYBOARD: Lazy<Mutex<Keyboard<Uk105Key, ScancodeSet1>>> =
Lazy::new(|| {
Mutex::new(Keyboard::new(
ScancodeSet1::new(),
// TODO: Expose an API to change the default KB layout.
Uk105Key,
HandleControl::Ignore,
))
});
});
pub static SCANCODE_STREAM: Lazy<Mutex<ScancodeStream>> =
Lazy::new(|| Mutex::new(ScancodeStream::new()));
@@ -59,7 +63,10 @@ impl Default for ScancodeStream {
impl Stream for ScancodeStream {
type Item = u8;
fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
fn poll_next(
self: Pin<&mut Self>,
cx: &mut Context<'_>,
) -> Poll<Option<Self::Item>> {
let queue = KBD_QUEUE.get().unwrap();
if let Some(scancode) = queue.pop() {
kernel/src/arch/x86_64/interrupts.rs
+24 -12
View File
@@ -1,9 +1,13 @@
use crate::serial_print;
use crate::{debug, serial_print};
use pic8259::ChainedPics;
use x86_64::registers::control::Cr2;
use x86_64::structures::idt::{InterruptDescriptorTable, InterruptStackFrame, PageFaultErrorCode};
use x86_64::structures::idt::{
InterruptDescriptorTable, InterruptStackFrame, PageFaultErrorCode,
};
use x86_64::structures::paging::mapper::MapperFlushAll;
use x86_64::structures::paging::{FrameAllocator, Mapper, Page, PageTableFlags, Size4KiB};
use x86_64::structures::paging::{
FrameAllocator, Mapper, Page, PageTableFlags, Size4KiB,
};
use super::gdt;
use crate::arch::x86_64::memory::{FRAME_ALLOCATOR, OFFSET_PAGE_TABLE};
@@ -25,7 +29,8 @@ static IDT: Lazy<InterruptDescriptorTable> = Lazy::new(|| {
idt.page_fault.set_handler_fn(page_fault_handler);
idt[InterruptIndex::Timer.as_u8()].set_handler_fn(timer_interrupt_handler);
idt[InterruptIndex::Keyboard.as_u8()].set_handler_fn(keyboard_interrupt_handler);
idt[InterruptIndex::Keyboard.as_u8()]
.set_handler_fn(keyboard_interrupt_handler);
idt
});
@@ -90,13 +95,16 @@ extern "x86-interrupt" fn double_fault_handler(
panic!("Exception: Double Fault\n{:#?}", stack_frame);
}
extern "x86-interrupt" fn keyboard_interrupt_handler(_stack_frame: InterruptStackFrame) {
extern "x86-interrupt" fn keyboard_interrupt_handler(
_stack_frame: InterruptStackFrame,
) {
use pc_keyboard::{HandleControl, Keyboard, ScancodeSet1, layouts};
// use pc_keyboard::DecodedKey;
use spin::Mutex;
use x86_64::instructions::port::Port;
static KEYBOARD: Lazy<Mutex<Keyboard<layouts::Uk105Key, ScancodeSet1>>> = Lazy::new(|| {
static KEYBOARD: Lazy<Mutex<Keyboard<layouts::Uk105Key, ScancodeSet1>>> =
Lazy::new(|| {
Mutex::new(Keyboard::new(
ScancodeSet1::new(),
layouts::Uk105Key,
@@ -116,7 +124,10 @@ extern "x86-interrupt" fn keyboard_interrupt_handler(_stack_frame: InterruptStac
}
}
extern "x86-interrupt" fn timer_interrupt_handler(_stack_frame: InterruptStackFrame) {
extern "x86-interrupt" fn timer_interrupt_handler(
_stack_frame: InterruptStackFrame,
) {
// debug!("Timer Interrupt");
unsafe {
PICS.lock()
.notify_end_of_interrupt(InterruptIndex::Timer.as_u8());
@@ -127,17 +138,18 @@ extern "x86-interrupt" fn page_fault_handler(
_stack_frame: InterruptStackFrame,
_error_code: PageFaultErrorCode,
) {
serial_println!("Exception: Page Fault");
serial_println!("Accessed Address: {:?}", Cr2::read());
serial_println!("Error Code: {:?}", _error_code);
serial_println!("{:#?}", _stack_frame);
// serial_println!("Exception: Page Fault");
// serial_println!("Accessed Address: {:?}", Cr2::read());
// serial_println!("Error Code: {:?}", _error_code);
// serial_println!("{:#?}", _stack_frame);
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());
let page: Page<Size4KiB> =
Page::containing_address(Cr2::read().unwrap());
unsafe {
let mut mapper = OFFSET_PAGE_TABLE.get().unwrap().lock();
kernel/src/arch/x86_64/memory/allocation/heap_alloc.rs
+87 -17
View File
@@ -1,21 +1,51 @@
use crate::arch::x86_64::memory::allocation::page_alloc::FoundryOSFrameAllocator;
use crate::arch::x86_64::memory::units::MemoryUnits;
use crate::arch::x86_64::memory::{
FRAME_ALLOCATOR, HEAP_SIZE, HEAP_VIRTUAL_SPACE,
};
use crate::debugln;
use core::alloc::{GlobalAlloc, Layout};
use core::ptr;
use spin::{Mutex, MutexGuard};
use x86_64::structures::paging::{Size4KiB, mapper::MapToError};
use x86_64::VirtAddr;
use x86_64::structures::paging::{
PageTableFlags, Size4KiB, mapper::MapToError,
};
/// We are currently using a linked list heap allocator which uses our underlying page allocator.
/// We are currently using a linked list heap allocator which uses our
/// underlying page allocator.
#[global_allocator]
/// This is now Rust's global allocator, so we can use stuff requiring heap allocations.
static ALLOCATOR: Locked<FoundryAllocator> = Locked::new(FoundryAllocator::new());
/// This is now Rust's global allocator, so we can use stuff requiring heap
/// allocations.
static ALLOCATOR: Locked<FoundryAllocator> =
Locked::new(FoundryAllocator::new());
pub const HEAP_START: usize = 0x4444_4444_0000;
pub const HEAP_SIZE: usize = 1024 * 1024 * 1024;
/// Sets up the heap using the backing page frame allocator.
/// Initializes the heap.
///
/// This function must be called once, before any functions that
/// require a heap are called. It sets up the heap by allocating
/// the necessary frames from the page allocator. The heap is
/// then ready for use.
///
/// # Safety
///
/// This function must be called only once, and must be called before any types
/// are constructed that require dynamic memory allocation.
///
/// # Parameters
///
/// None
///
/// # Returns
///
/// Returns a `Result` containing a `MapToError` if the heap
/// could not be initialized, or `Ok` if the heap was
/// initialized successfully.
pub unsafe fn init_heap() -> Result<(), MapToError<Size4KiB>> {
unsafe {
// code to allocate frames is now done in the page fault interrupt handler!
ALLOCATOR.lock().init(HEAP_START, HEAP_SIZE);
// code to allocate frames is now done in the page fault interrupt
// handler!
ALLOCATOR.lock().init(HEAP_VIRTUAL_SPACE, HEAP_SIZE);
Ok(())
}
}
@@ -36,7 +66,7 @@ impl<T> Locked<T> {
}
}
const BLOCK_SIZES: &[usize] = &[8, 16, 32, 64, 128, 256, 512, 1024, 2048];
const BLOCK_SIZES: &[usize] = &[8, 16, 32, 64, 128, 256, 512, 1024, 2048, 4096];
struct ListNode {
next: Option<&'static mut ListNode>,
@@ -61,7 +91,17 @@ impl FoundryAllocator {
fallback: Locked::new(FoundryFallbackAllocator::new()),
}
}
/// Initializes the fallback allocator with the given heap start address and
/// size.
///
/// # Safety
///
/// This function is unsafe because it does not check whether the given heap
/// start address and size are valid.
pub unsafe fn init(&mut self, heap_start: usize, heap_size: usize) {
debugln!(" => Start: {:?}", VirtAddr::new(heap_start as u64));
debugln!(" => Size: {}", MemoryUnits::from_bytes(heap_size));
unsafe {
self.fallback.lock().init(heap_start, heap_size);
}
@@ -86,14 +126,18 @@ unsafe impl GlobalAlloc for Locked<FoundryAllocator> {
match allocator.list_heads[index].take() {
Some(node) => {
allocator.list_heads[index] = node.next.take();
node as *mut ListNode as *mut u8
let ptr = node as *mut ListNode as *mut u8;
ensure_mapped(VirtAddr::new(ptr as u64));
ptr
}
None => {
// no block exists in list => allocate new block
let block_size = BLOCK_SIZES[index];
// only works if all block sizes are a power of 2
let block_align = block_size;
let layout = Layout::from_size_align(block_size, block_align).unwrap();
let layout =
Layout::from_size_align(block_size, block_align)
.unwrap();
unsafe { allocator.fallback_alloc(layout) }
}
}
@@ -157,6 +201,12 @@ impl FoundryFallbackAllocator {
}
}
/// Initializes the allocator with a given heap start address and size.
///
/// # Safety
///
/// This function is unsafe because it does not check whether the given heap
/// start address and size are valid.
pub unsafe fn init(&mut self, heap_start: usize, heap_size: usize) {
unsafe { self.add_region(heap_start, heap_size) };
}
@@ -165,6 +215,10 @@ impl FoundryFallbackAllocator {
unsafe {
let mut node = FallbackListNode::new(size);
node.next = self.head.next.take();
let virt_addr = VirtAddr::new(addr as u64);
ensure_mapped(virt_addr);
let node_ptr = addr as *mut FallbackListNode;
node_ptr.write(node);
self.head.next = Some(&mut *node_ptr);
@@ -179,7 +233,9 @@ impl FoundryFallbackAllocator {
let mut current = &mut self.head;
// look for a large enough memory region in linked list
while let Some(ref mut region) = current.next {
if let Ok(alloc_start) = Self::alloc_from_region(region, size, align) {
if let Ok(alloc_start) =
Self::alloc_from_region(region, size, align)
{
// region suitable for allocation -> remove node from list
let next = region.next.take();
let ret = Some((current.next.take().unwrap(), alloc_start));
@@ -232,13 +288,16 @@ unsafe impl GlobalAlloc for Locked<FoundryFallbackAllocator> {
// perform layout adjustments
let (size, align) = FoundryFallbackAllocator::size_align(layout);
if let Some((region, alloc_start)) = allocator.find_region(size, align) {
if let Some((region, alloc_start)) = allocator.find_region(size, align)
{
let alloc_end = alloc_start.checked_add(size).expect("overflow");
let excess_size = region.end_addr() - alloc_end;
if excess_size > 0 {
unsafe { allocator.add_region(alloc_end, excess_size) };
}
alloc_start as *mut u8
let ptr = alloc_start as *mut u8;
ensure_mapped(VirtAddr::new(ptr as u64));
ptr
} else {
ptr::null_mut()
}
@@ -249,7 +308,18 @@ unsafe impl GlobalAlloc for Locked<FoundryFallbackAllocator> {
// perform layout adjustments
let (size, _) = FoundryFallbackAllocator::size_align(layout);
unsafe { allocator.add_region(ptr as usize, size) }
}
}
fn ensure_mapped(virt_addr: VirtAddr) {
if !FoundryOSFrameAllocator::is_mapped(virt_addr) {
let mut foundry_alloc = FRAME_ALLOCATOR.get().unwrap().lock();
foundry_alloc
.allocate_page(
virt_addr,
PageTableFlags::PRESENT | PageTableFlags::WRITABLE,
)
.unwrap();
}
}
kernel/src/arch/x86_64/memory/allocation/mod.rs
+1
View File
@@ -1,2 +1,3 @@
pub mod heap_alloc;
pub(crate) mod page_alloc;
pub mod stack_alloc;
kernel/src/arch/x86_64/memory/allocation/page_alloc.rs
+102
View File
@@ -0,0 +1,102 @@
use crate::arch::x86_64::memory::{FRAME_ALLOCATOR, OFFSET_PAGE_TABLE};
use limine::memory_map::EntryType;
use limine::response::MemoryMapResponse;
use spin::Mutex;
use x86_64::structures::paging::mapper::{MapToError, TranslateResult};
use x86_64::structures::paging::{
FrameAllocator, Mapper, Page, PageTableFlags, PhysFrame, Size4KiB,
Translate,
};
use x86_64::{PhysAddr, VirtAddr};
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 fn init(memory_map: &'static MemoryMapResponse) {
FRAME_ALLOCATOR.call_once(|| {
Mutex::new(Self {
memory_map,
next: 0,
})
});
}
pub fn count_usable_frames(&self) -> u64 {
self.usable_frames().count() as u64
}
pub fn available_memory(&self) -> u64 {
self.memory_map
.entries()
.iter()
.map(|region| region.base..region.base + region.length)
.flat_map(|r| r.step_by(4096))
.count() as u64
* 4096
}
/// 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 page map.
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()
})
}
pub(crate) fn is_mapped(virt_addr: VirtAddr) -> bool {
let mapper = OFFSET_PAGE_TABLE.get().unwrap().lock();
matches!(mapper.translate(virt_addr), TranslateResult::Mapped { .. })
}
pub(crate) fn allocate_page(
&mut self,
start_addr: VirtAddr,
flags: PageTableFlags,
) -> Result<(), MapToError<Size4KiB>> {
let page = Page::containing_address(start_addr);
let frame = self
.allocate_frame()
.ok_or(MapToError::<Size4KiB>::FrameAllocationFailed)?;
let mut mapper = OFFSET_PAGE_TABLE.get().unwrap().lock();
unsafe { mapper.map_to(page, frame, flags, self)? }.flush();
Ok(())
}
}
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
}
}
kernel/src/arch/x86_64/memory/allocation/stack_alloc.rs
+33 -10
View File
@@ -1,10 +1,15 @@
use x86_64::structures::paging::{mapper, FrameAllocator, Mapper, Page, Size4KiB};
use crate::arch::x86_64::memory::STACK_VIRTUAL_SPACE;
use x86_64::VirtAddr;
use x86_64::structures::paging::{
FrameAllocator, Mapper, Page, Size4KiB, mapper,
};
fn reserve_stack_memory(size_in_pages: u64) -> Page {
use core::sync::atomic::{AtomicU64, Ordering};
static STACK_ALLOC_NEXT: AtomicU64 = AtomicU64::new(0x_5555_5555_0000);
let start_addr = VirtAddr::new(STACK_ALLOC_NEXT.fetch_add(
static STACK_ALLOC_NEXT: AtomicU64 =
AtomicU64::new(STACK_VIRTUAL_SPACE as u64);
let start_addr =
VirtAddr::new(STACK_ALLOC_NEXT.fetch_add(
size_in_pages * Page::<Size4KiB>::SIZE,
Ordering::Relaxed,
));
@@ -12,17 +17,35 @@ fn reserve_stack_memory(size_in_pages: u64) -> Page {
.expect("`STACK_ALLOC_NEXT` not page aligned")
}
/// Allocates a stack in the virtual address space, mapped to physical pages.
///
/// This function allocates a stack in the virtual address space, mapped to
/// physical pages. The stack is allocated as a sequence of pages, with the
/// first page allocated as a guard page. The stack is then mapped to the
/// allocated physical frame.
///
/// The function takes the size of the stack in pages, a mutable reference to a
/// mapper, and a mutable reference to a frame allocator. It returns a `Result`
/// containing a `StackBounds` struct, which contains the start and end virtual
/// addresses of the allocated stack.
///
/// # Safety
///
/// This function is unsafe because it maps physical frames to virtual addresses
/// without any protection. This can lead to bugs if the physical frames are not
/// correctly allocated, or if the virtual addresses are not correctly aligned.
///
/// # Panics
///
/// This function will panic if the allocation of the physical frame fails.
pub unsafe fn alloc_stack(
size_in_pages: u64,
mapper: &mut impl Mapper<Size4KiB>,
frame_allocator: &mut impl FrameAllocator<Size4KiB>,
) -> Result<StackBounds, mapper::MapToError<Size4KiB>> { unsafe {
) -> Result<StackBounds, mapper::MapToError<Size4KiB>> {
unsafe {
use x86_64::structures::paging::PageTableFlags as Flags;
let guard_page = reserve_stack_memory(size_in_pages + 1);
let stack_start = guard_page + 1;
let stack_end = stack_start + size_in_pages;
@@ -39,8 +62,8 @@ pub unsafe fn alloc_stack(
start: stack_start.start_address(),
end: stack_end.start_address(),
})
}}
}
}
#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord)]
pub struct StackBounds {
kernel/src/arch/x86_64/memory/memory_map.rs → kernel/src/arch/x86_64/memory/mapping.rs
+2 -1
View File
@@ -16,7 +16,8 @@ static HIGHER_HALF_DIRECT_MAP_REQUEST: HhdmRequest = HhdmRequest::new();
#[used]
#[unsafe(link_section = ".requests")]
static KERNEL_ADDRESS_REQUEST: KernelAddressRequest = KernelAddressRequest::new();
pub static KERNEL_ADDRESS_REQUEST: KernelAddressRequest =
KernelAddressRequest::new();
/// ```rs
/// let virt_addr = phys_addr + offset;
kernel/src/arch/x86_64/memory/mod.rs
+18 -61
View File
@@ -1,17 +1,25 @@
pub mod allocation;
pub mod memory_map;
pub mod mapping;
pub mod units;
// use lib_alloc::allocator::FoundryAllocator;
use limine::{memory_map::EntryType, response::MemoryMapResponse};
use allocation::page_alloc::FoundryOSFrameAllocator;
use spin::{Mutex, Once};
use units::MemoryUnits::*;
use x86_64::{
PhysAddr, VirtAddr,
VirtAddr,
registers::control::Cr3,
structures::paging::{FrameAllocator, OffsetPageTable, PageTable, PhysFrame, Size4KiB},
structures::paging::{OffsetPageTable, PageTable},
};
/// Start address of the memory space where we store allocated stacks.
pub const STACK_VIRTUAL_SPACE: usize = 0x5555_5555_0000;
/// Start address of heap allocated memory.
pub const HEAP_VIRTUAL_SPACE: usize = 0x4444_4444_0000;
pub const HEAP_SIZE: usize = MiB(1).to_bytes();
pub static FRAME_ALLOCATOR: Once<Mutex<FoundryOSFrameAllocator>> = Once::new();
pub static OFFSET_PAGE_TABLE: Once<Mutex<OffsetPageTable>> = Once::new();
/// Returns a mutable reference to the current level 4 page table.
///
/// # Safety
@@ -19,7 +27,9 @@ pub static OFFSET_PAGE_TABLE: Once<Mutex<OffsetPageTable>> = Once::new();
/// 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 {
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();
@@ -48,61 +58,8 @@ unsafe fn active_l4_table(physical_memory_offset: VirtAddr) -> &'static mut Page
pub fn init_page_table(physical_memory_offset: VirtAddr) {
unsafe {
let l4_table = active_l4_table(physical_memory_offset);
let offset_table = OffsetPageTable::new(l4_table, physical_memory_offset);
let offset_table =
OffsetPageTable::new(l4_table, physical_memory_offset);
OFFSET_PAGE_TABLE.call_once(|| Mutex::new(offset_table));
}
}
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 unsafe fn init(memory_map: &'static MemoryMapResponse) { unsafe {
FRAME_ALLOCATOR.call_once(|| Mutex::new(Self {
memory_map,
next: 0,
}));
}}
pub fn count_usable_frames(&self) -> u32 {
self.usable_frames().count() as u32
}
/// 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
}
}
kernel/src/arch/x86_64/memory/units.rs
+49
View File
@@ -0,0 +1,49 @@
pub enum MemoryUnits {
B(usize),
KiB(usize),
MiB(usize),
GiB(usize),
}
impl MemoryUnits {
pub const fn to_bytes(&self) -> usize {
match self {
Self::B(b) => *b,
Self::KiB(kib) => *kib * 1024,
Self::MiB(mib) => *mib * 1024 * 1024,
Self::GiB(gib) => *gib * 1024 * 1024 * 1024,
}
}
pub const fn from_bytes(bytes: usize) -> Self {
if bytes < 1024 {
Self::B(bytes)
} else if bytes < 1024 * 1024 {
Self::KiB(bytes / 1024)
} else if bytes < 1024 * 1024 * 1024 {
Self::MiB(bytes / (1024 * 1024))
} else {
Self::GiB(bytes / (1024 * 1024 * 1024))
}
}
pub const fn convert(&mut self) {
match self {
Self::B(b) if *b > 1024 => *self = Self::KiB(*b / 1024),
Self::KiB(kib) if *kib > 1024 => *self = Self::MiB(*kib / 1024),
Self::MiB(mib) if *mib > 1024 => *self = Self::GiB(*mib / 1024),
_ => (),
}
}
}
impl core::fmt::Display for MemoryUnits {
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
match self {
Self::B(b) => write!(f, "{} B", b),
Self::KiB(kib) => write!(f, "{} KiB", kib),
Self::MiB(mib) => write!(f, "{} MiB", mib),
Self::GiB(gib) => write!(f, "{} GiB", gib),
}
}
}
kernel/src/arch/x86_64/processing/async_io/task.rs
+7 -5
View File
@@ -2,7 +2,6 @@
//!
//! Written by @zxq5 for the most part with code from
//! [here](https://github.com/phil-opp/blog_os/).
//!
use alloc::boxed::Box;
use alloc::collections::BTreeMap;
@@ -81,9 +80,9 @@ impl Executor {
Some(task) => task,
None => continue, // task no longer exists
};
let waker = waker_cache
.entry(task_id)
.or_insert_with(|| TaskWaker::new_waker(task_id, task_queue.clone()));
let waker = waker_cache.entry(task_id).or_insert_with(|| {
TaskWaker::new_waker(task_id, task_queue.clone())
});
let mut context = Context::from_waker(waker);
match task.poll(&mut context) {
Poll::Ready(()) => {
@@ -129,7 +128,10 @@ impl TaskWaker {
self.task_queue.push(self.task_id).expect("task_queue full");
}
fn new_waker(task_id: TaskId, task_queue: Arc<ArrayQueue<TaskId>>) -> Waker {
fn new_waker(
task_id: TaskId,
task_queue: Arc<ArrayQueue<TaskId>>,
) -> Waker {
Waker::from(Arc::new(Self {
task_id,
task_queue,
kernel/src/arch/x86_64/processing/mod.rs
+2 -1
View File
@@ -1,3 +1,4 @@
#![expect(unused)]
pub mod async_io;
pub mod threading;
mod taskrunner;
pub mod threading;
kernel/src/arch/x86_64/processing/taskrunner/mod.rs
+2 -2
View File
@@ -6,7 +6,7 @@ pub struct Task {
}
impl Task {
pub fn new() {}
// pub const fn new() {}
pub fn run() {}
pub const fn run() {}
}
kernel/src/arch/x86_64/processing/threading/mod.rs
+1 -3
View File
@@ -1,5 +1,5 @@
use x86_64::VirtAddr;
use crate::arch::x86_64::memory::allocation::stack_alloc::StackBounds;
use x86_64::VirtAddr;
mod switch;
@@ -10,8 +10,6 @@ pub struct Thread {
stack_bounds: Option<StackBounds>,
}
#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord)]
pub struct ThreadId(u64);
kernel/src/lib.rs
+94 -52
View File
@@ -1,5 +1,5 @@
#![no_std]
#![feature(abi_x86_interrupt)]
#![feature(abi_x86_interrupt, breakpoint)]
#![warn(
clippy::correctness,
clippy::nursery,
@@ -12,45 +12,52 @@
)]
extern crate alloc;
use crate::{
arch::x86_64::memory::init_page_table,
arch::x86_64::{
// cpu::apic::enable_apic,
drivers::{
ascii::screensize_chars, framebuffer::display::screensize_px,
},
gdt,
interrupts,
memory::{
FRAME_ALLOCATOR,
allocation::{
heap_alloc::init_heap, page_alloc::FoundryOSFrameAllocator,
},
init_page_table, mapping,
units::MemoryUnits,
},
},
prelude::*,
};
use arch::x86_64::memory::allocation::heap_alloc::init_heap;
use arch::x86_64::memory::memory_map;
use alloc::{boxed::Box, format};
use core::arch::asm;
use limine::BaseRevision;
use x86_64::VirtAddr;
use crate::arch::x86_64::memory::FoundryOSFrameAllocator;
pub mod arch;
/// Commonly used re-exports.
pub mod prelude;
pub mod resources;
#[allow(unused)] // We aren't using much of this right now.
// We aren't using much of this right now.
#[allow(unused)]
pub mod std;
mod step;
pub mod util;
pub mod prelude {
pub use crate::std::io::{_print, _print_log, _serial_write};
pub use crate::{
print, print_log, printerr, println, println_log, printlnerr, serial_print, serial_println,
};
}
/// Sets the base revision to the latest revision supported by the crate.
/// See specification for further info.
/// Be sure to mark all limine requests with #[used], otherwise they may be removed by the compiler.
/// Be sure to mark all limine requests with #[used], otherwise they may be
/// removed by the compiler.
#[used]
// The .requests section allows limine to find the requests faster and more safely.
// The .requests section allows limine to find the requests faster and more
// safely.
#[unsafe(link_section = ".requests")]
static BASE_REVISION: BaseRevision = BaseRevision::new();
#[panic_handler]
fn rust_panic(_info: &core::panic::PanicInfo) -> ! {
println!("Kernel panic: {}", _info);
serial_println!("Kernel panic: {}", _info);
hcf();
}
pub fn hcf() -> ! {
loop {
unsafe {
@@ -60,60 +67,95 @@ pub fn hcf() -> ! {
}
}
pub fn boot() -> Result<(), &'static str> {
#[derive(Debug)]
pub struct NoError {}
impl core::fmt::Display for NoError {
fn fmt(&self, _f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
Ok(())
}
}
pub struct NoTags;
impl core::error::Error for NoError {}
/// Panicking before this is initialised is unwise. We should probably extract
/// very early init into it's own function because Stack Traces may require
/// allocations etc.
#[inline(never)]
pub fn boot() -> Result<(), Box<dyn core::error::Error>> {
if !BASE_REVISION.is_supported() {
return Err("base revision not supported");
return Err("Base revision not supported.".into());
}
use arch::x86_64::{gdt, interrupts};
let memory_map = memory_map::get_memory_map();
let memory_map = mapping::get_memory_map();
print_log!(" Initialising Serial... ");
if arch::x86_64::drivers::serial::init().is_err() {
println_log!("[Not Detected]")
let res = arch::x86_64::drivers::serial::init();
serial_print!(" Initialising Serial... ");
if res.is_err() {
debugln!("[Not Detected]")
} else {
println_log!("[Success]");
debugln!("[Success]");
}
print_log!(" Setting Up Global Descriptor Table... ");
debugln!(
"Display is {:?} chars, {:?} px.",
screensize_chars(),
screensize_px()
);
debug!(" Setting Up Global Descriptor Table... ");
gdt::init();
println_log!("[Success]");
debugln!("[Success]");
print_log!(" Setting Up Interrupt Descriptor Table... ");
debug!(" Setting Up Interrupt Descriptor Table... ");
interrupts::init_idt();
println_log!("[Success]");
debugln!("[Success]");
print_log!(" Initialising Memory Subsystem... ");
let physical_memory_offset = VirtAddr::new(*memory_map::PHYSICAL_MEMORY_OFFSET);
debugln!(" Initialising Memory Subsystem... ");
let physical_memory_offset =
VirtAddr::new(*mapping::PHYSICAL_MEMORY_OFFSET);
init_page_table(physical_memory_offset);
println_log!("[Success]");
FoundryOSFrameAllocator::init(memory_map);
let available_bytes =
FRAME_ALLOCATOR.get().unwrap().lock().available_memory();
print_log!(" Setting Up Page Table... ");
unsafe { FoundryOSFrameAllocator::init(memory_map) };
println_log!("[Success]");
debugln!(
" => Available Memory: {}",
MemoryUnits::from_bytes(available_bytes as usize)
);
print_log!(" Initialising Heap... ");
if unsafe { init_heap() }.is_err() {
return Err("Failed to initialise heap: error");
// Allocations should be all fine past this point.
debugln!(" Initialising Heap... ");
match unsafe { init_heap() } {
Ok(_) => debugln!(" [Success]"),
Err(why) => return Err(format!("{:?}", why).into()),
}
println_log!("[Success]");
print_log!(" Enabling PICs... ");
debug!(" Enabling PICs... ");
interrupts::enable_pic();
println_log!("[Success]");
debugln!("[Success]");
// print_log!(" Disabling PICs... ");
// debug!(" Disabling PICs... ");
// interrupts::disable_pic();
// println_log!("[Success]");
// debugln!("[Success]");
// print_log!(" Initialising APIC");
// debug!(" Initialising APIC... ");
// enable_apic();
// println_log!("[Success]");
// debugln!("[Success]");
print_log!(" Enabling Interrupts... ");
debug!(" Enabling Interrupts... ");
x86_64::instructions::interrupts::enable();
println_log!("[Success]");
debugln!("[Success]");
Ok(())
}
#[panic_handler]
fn panic(_info: &core::panic::PanicInfo<'_>) -> ! {
debugln!("{:?}", _info);
hcf()
}
kernel/src/main.rs
+9 -13
View File
@@ -2,11 +2,12 @@
#![no_main]
extern crate alloc;
use foundry_os::arch::x86_64::drivers::ascii::screensize_chars;
use foundry_os::arch::x86_64::drivers::framebuffer::display::screensize_px;
use foundry_os::arch::x86_64::processing::async_io::task::{Executor, Task};
use foundry_os::util::shell::shell;
use foundry_os::{println, println_log};
use foundry_os::{
arch::x86_64::processing::async_io::task::{Executor, Task},
prelude::*,
util::shell::shell,
};
#[unsafe(no_mangle)]
extern "C" fn kmain() -> ! {
@@ -14,14 +15,7 @@ extern "C" fn kmain() -> ! {
if let Err(err) = foundry_os::boot() {
panic!("{}", err);
}
println_log!("[ Kernel Initialised Successfully ] ");
let dimensions = screensize_chars();
let dimensions2 = screensize_px();
println!("Dimensions: {}x{} (px)", dimensions2.0, dimensions2.1);
println!("Dimensions: {}x{} (chars)", dimensions.0, dimensions.1);
println_log!(" [ Kernel Initialised Successfully ] ");
// println!("TESTING :: Allocation");
// let somevec = vec![0; 1_000_000];
@@ -29,6 +23,8 @@ extern "C" fn kmain() -> ! {
// println!("{}", somevec.len());
// println!("PASSED!");
// test1();
let mut executor = Executor::new();
executor.spawn(Task::new(shell()));
executor.run()
kernel/src/prelude.rs
+7
View File
@@ -0,0 +1,7 @@
pub use crate::{
arch::x86_64::drivers::framebuffer::colour::Colour,
debug, debugln, eprint, eprintln, hcf, print, print_log, print_oneshot,
println, println_log, serial_print, serial_println,
std::debug::_debug,
std::io::{_print, _print_err, _print_log, _serial_write},
};
kernel/src/resources/font/mod.rs
+6 -4
View File
@@ -1,8 +1,8 @@
use libm::include_font;
pub static FONT_SPLEEN_8X16: Font =
pub const FONT_SPLEEN_8X16: Font =
Font::new(include_font!("../../../resources/font/spleen-8x16.psf"));
pub static FONT_CP850_8X16: Font =
pub const FONT_CP850_8X16: Font =
Font::new(include_font!("../../../resources/font/cp850-8x16.psf"));
// pub struct Font(pub [[u8; 16]; 512]);
@@ -39,8 +39,10 @@ impl Font {
pub const fn height(&self) -> usize {
self.height
}
}
pub fn default() -> &'static Self {
&FONT_CP850_8X16
impl Default for Font {
fn default() -> Self {
FONT_CP850_8X16
}
}
kernel/src/std/application.rs
+4 -1
View File
@@ -8,7 +8,10 @@ pub mod window;
pub trait Application {
type Output;
fn run(&mut self, args: Vec<String>) -> impl Future<Output = Result<Self::Output, Error>> + Send;
fn run(
&mut self,
args: Vec<String>,
) -> impl Future<Output = Result<Self::Output, Error>> + Send;
}
#[derive(Debug)]
kernel/src/std/application/frame.rs
+15 -4
View File
@@ -11,20 +11,31 @@ pub struct Frame<'f> {
impl<'a> Frame<'a> {
pub fn new(window: &'a Window) -> Self {
Self {
data: vec![vec![Colour::Black; window.dimensions().x()]; window.dimensions().y()],
data: vec![
vec![Colour::Black; window.dimensions().x()];
window.dimensions().y()
],
window,
}
}
pub fn render(&self) -> Result<(), RenderError> {
let data: Vec<&[Colour]> = self.data.iter().map(|v| v.as_slice()).collect::<Vec<_>>();
let data: Vec<&[Colour]> =
self.data.iter().map(|v| v.as_slice()).collect::<Vec<_>>();
self.window
.render(data.as_slice())
.map_err(|_| RenderError::Generic)
}
pub fn write_pixel(&mut self, x: usize, y: usize, color: Colour) -> Result<(), RenderError> {
if x >= self.window.dimensions().x() || y >= self.window.dimensions().y() {
pub fn write_pixel(
&mut self,
x: usize,
y: usize,
color: Colour,
) -> Result<(), RenderError> {
if x >= self.window.dimensions().x()
|| y >= self.window.dimensions().y()
{
return Err(RenderError::Generic);
}
self.data[y][x] = color;
kernel/src/std/application/window.rs
+2 -1
View File
@@ -24,7 +24,8 @@ impl Window {
}
pub fn render(&self, _data: &[&[Colour]]) -> Result<(), RenderError> {
// TODO: error handling!! the kernel should return an error in some cases
// TODO: error handling!! the kernel should return an error in some
// cases
if let Some(fb) = FRAMEBUFFER_WRITER.lock().as_mut() {
fb.render_frame(_data);
}
kernel/src/std/ascii.rs
+5 -1
View File
@@ -46,7 +46,11 @@ impl<'a> Writer<'a> {
if line & (0x80 >> col) != 0 {
for i in 0..scale {
for j in 0..scale {
frame.write_pixel(pixel_x + i, pixel_y + j, Colour::White)?;
frame.write_pixel(
pixel_x + i,
pixel_y + j,
Colour::White,
)?;
}
}
}
kernel/src/std/debug.rs
+21
View File
@@ -0,0 +1,21 @@
use crate::prelude::{_print_log, _serial_write};
use core::fmt;
use x86_64::instructions::interrupts;
#[macro_export]
macro_rules! debugln {
() => ($crate::print_log!("\n"));
($($arg:tt)*) => ($crate::debug!("{}\n", format_args!($($arg)*)));
}
#[macro_export]
macro_rules! debug {
($($arg:tt)*) => ($crate::prelude::_debug(format_args!($($arg)*)));
}
pub fn _debug(args: fmt::Arguments) {
interrupts::without_interrupts(|| {
_print_log(args);
_serial_write(args);
});
}
kernel/src/std/elf/mod.rs
+168
View File
@@ -0,0 +1,168 @@
//! Basic ELF parsing functionality using the `elf` crate.
//!
//! This may be extended in the future to support loading programs, however we
//! currently use this for getting the sizes of sections in our kernel ELF at
//! runtime.
//!
//! This is used for implementing stacktraces in std::unwind.
//!
//! # TODO
//!
//! * Add support for loading binary programs (this should probably be written
//! in a different module)
use alloc::{format, vec::Vec};
use elf::{
ElfBytes, ParseError,
endian::LittleEndian,
parse::{ParseAt, ParsingTable},
section::{SectionHeader, SectionHeaderTable},
string_table::StringTable,
symbol::{Symbol, SymbolTable},
};
use limine::request::KernelFileRequest;
use crate::prelude::*;
#[cfg(target_arch = "x86_64")]
/// The length of the ELF header in bytes.
pub const ELF_HEADER_LEN: usize = 64;
/// Information about our own ELF file to make ELF parsing easier, such as the
/// length of the file and a pointer to the contents.
#[used]
pub static KERNEL_FILE_REQUEST: KernelFileRequest = KernelFileRequest::new();
/// A list of errors that may occur when parsing ELF files.
#[derive(Debug)]
pub enum ElfError {
/// Returned if a section did not exist in [ElfReader::get_section_size].
SectionNotExists,
/// Returned if we failed to fetch the symbol table.
Symtab,
/// Parse errors returned by the `elf` crate.
OtherParseError(elf::ParseError),
}
impl From<elf::ParseError> for ElfError {
fn from(err: elf::ParseError) -> Self {
Self::OtherParseError(err)
}
}
pub struct ElfReader {
/// The underlying bytes for the ELF file.
pub bytes: &'static [u8],
/// Structure returned by the `elf` crate having parsed the ELF header.
pub elf: ElfBytes<'static, LittleEndian>,
/// A sorted list of symbols to binary search.
pub sorted_syms: Vec<Symbol>,
/// The string table for looking up symbol names.
pub symbol_strtab: StringTable<'static>,
}
impl ElfReader {
/// Parses the ELF file for the kernel, this uses data from Limine's Kernel
/// File Request to get a slice over the whole executable file.
///
/// # Safety
///
/// Assumes a properly formed ELF file, and that Limine returns a correct
/// pointer to the start of the file as well as a valid length in bytes.
///
/// Both of these should be satisfied, but this function is marked unsafe
/// just in case, because we are derefererencing arbitrary pointers.
pub unsafe fn new() -> Result<Self, ElfError> {
// Store this for use with other libraries.
let bytes = get_elf_slice();
let elf: ElfBytes<'static, LittleEndian> =
elf::ElfBytes::minimal_parse(bytes)?;
let Some((symtab, strtab)) = elf.symbol_table()? else {
return Err(ElfError::Symtab);
};
// Sort the symtab for later use and store the strtab.
let mut symbols = symtab.into_iter().collect::<Vec<Symbol>>();
symbols.sort_by_key(|sym| sym.st_value);
Ok(Self {
elf,
sorted_syms: symbols,
symbol_strtab: strtab,
bytes,
})
}
pub fn get_symbol_table(
&self,
) -> Result<
Option<(SymbolTable<'static, LittleEndian>, StringTable<'static>)>,
ElfError,
> {
Ok(self.elf.symbol_table()?)
}
/// Gets the section size of `section_name` in bytes.
pub fn get_section_size(
&self,
section_name: &'static str,
) -> Result<u64, ElfError> {
Ok(self.get_section_header(section_name)?.sh_size)
}
/// Gets the start address of the section `section_name` in memory.
pub fn get_section_addr(
&self,
section_name: &'static str,
) -> Result<*const u8, ElfError> {
Ok(self.get_section_header(section_name)?.sh_addr as *const u8)
}
/// Gets the section header of `section_name`.
pub fn get_section_header(
&self,
section_name: &str,
) -> Result<SectionHeader, ElfError> {
let section_hdr = self
.elf
.section_header_by_name(section_name)
.map_err(|_e| ElfError::SectionNotExists)?;
section_hdr.ok_or(ElfError::SectionNotExists)
}
pub fn search_symbol(&self, address: u64) -> Option<elf::symbol::Symbol> {
let entries = self.sorted_syms.iter().collect::<Vec<_>>();
let idx = entries
.as_slice()
.binary_search_by_key(&address, |sym| sym.st_value)
.ok()?;
Some(entries[idx].clone())
}
pub fn get_symbol_name(
&self,
sym: elf::symbol::Symbol,
) -> Option<&'static str> {
self.symbol_strtab.get(sym.st_name as usize).ok()
}
}
/// Gets a slice of the bytes of the kernel ELF file.
pub fn get_elf_slice() -> &'static [u8] {
let response = KERNEL_FILE_REQUEST
.get_response()
.expect("Didn't get the kernel file from Limine. That's odd.");
// We fetch these from Limine and use them to parse our own ELF file.
let file = response.file();
let file_start_ptr = file.addr();
let file_size = file.size() as usize;
// Safety: This slice should contain the whole bytes of the ELF file.
(unsafe { core::slice::from_raw_parts(file_start_ptr, file_size) }) as _
}
kernel/src/std/io.rs
-83
View File
@@ -1,83 +0,0 @@
pub use crate::arch::x86_64::drivers::{
ascii::{_print, _print_err, _print_log},
serial::_serial_write,
};
pub mod stdin {
use crate::arch::x86_64::drivers::{
ascii::WRITER,
keyboard::{
get_keystroke_async, get_keystroke_optional, KeyStroke,
}
};
use alloc::string::String;
/// Reads a line of input from standard input asynchronously, returning a `String` containing
/// the input line. Does not include the newline character at the end of the line.
///
/// If the user presses the abort key (usually Ctrl+C), the returned string will be empty.
///
/// This function is currently unimplemented.
pub async fn read_line() -> String {
let mut writer = WRITER.lock();
let mut buff = String::new();
loop {
match get_keystroke_async().await {
KeyStroke::Char(c) => match c {
'\n' => {
writer.write_glyph(c as u8);
return buff;
}
'\r' => {
writer.write_glyph(c as u8);
return buff;
}
'\x08' => {
if !buff.is_empty() {
buff.pop();
writer.backspace();
}
}
c => {
writer.write_glyph(c as u8);
buff.push(c)
}
},
KeyStroke::Enter => {
writer.write_glyph(b'\n');
return buff;
}
KeyStroke::Backspace => {
if !buff.is_empty() {
buff.pop();
writer.backspace();
}
}
_ => continue,
}
}
}
/// Reads a character from standard input and blocks the current task until a character is
/// available.
///
/// # Note
///
/// This function is not yet implemented.
pub async fn async_keystroke() -> KeyStroke {
get_keystroke_async().await
}
/// Attempt to read a character from standard input without blocking the current task.
///
/// If no character is available, returns `None`.
///
/// # Note
///
/// This function is not yet implemented.
pub fn keystroke() -> Option<KeyStroke> {
get_keystroke_optional()
}
}
kernel/src/std/io/mod.rs
+6
View File
@@ -0,0 +1,6 @@
pub use crate::arch::x86_64::drivers::{
ascii::{_print, _print_err, _print_log},
serial::_serial_write,
};
pub mod stdin;
kernel/src/std/io/stdin.rs
+75
View File
@@ -0,0 +1,75 @@
use crate::arch::x86_64::drivers::{
ascii::WRITER,
keyboard::{KeyStroke, get_keystroke_async, get_keystroke_optional},
};
use alloc::string::String;
/// Reads a line of input from standard input asynchronously, returning a
/// `String` containing the input line. Does not include the newline
/// character at the end of the line.
///
/// If the user presses the abort key (usually Ctrl+C), the returned string
/// will be empty.
pub async fn read_line() -> String {
let mut writer = WRITER.lock();
let mut buff = String::new();
loop {
match get_keystroke_async().await {
KeyStroke::Char(c) => match c {
'\n' => {
writer.write_glyph(c as u8);
return buff;
}
'\r' => {
writer.write_glyph(c as u8);
return buff;
}
'\x08' => {
if !buff.is_empty() {
buff.pop();
writer.backspace();
}
}
c => {
writer.write_glyph(c as u8);
buff.push(c)
}
},
KeyStroke::Enter => {
writer.write_glyph(b'\n');
return buff;
}
KeyStroke::Backspace => {
if !buff.is_empty() {
buff.pop();
writer.backspace();
}
}
_ => continue,
}
}
}
/// Reads a character from standard input and blocks the current task until
/// a character is available.
///
/// # Note
///
/// This function is not yet implemented.
pub async fn async_keystroke() -> KeyStroke {
get_keystroke_async().await
}
/// Attempt to read a character from standard input without blocking the
/// current task.
///
/// If no character is available, returns `None`.
///
/// # Note
///
/// This function is not yet implemented.
pub fn keystroke() -> Option<KeyStroke> {
get_keystroke_optional()
}
kernel/src/std/maths/geometry.rs
+8
View File
@@ -42,6 +42,14 @@ impl<T: Coordinate> Vec2<T> {
pub const fn y(&self) -> T {
self.y
}
pub const fn set_x(&mut self, x: T) {
self.x = x;
}
pub const fn set_y(&mut self, y: T) {
self.y = y;
}
}
impl<T: Coordinate> AddAssign for Vec2<T> {
kernel/src/std/mod.rs
+1
View File
@@ -1,4 +1,5 @@
pub mod application;
pub mod ascii;
pub mod debug;
pub mod io;
pub mod maths;
kernel/src/step.rs
+104
View File
@@ -0,0 +1,104 @@
/* //! Defines the [Step] struct which may be used when initialising the system.
//!
//! # Warning
//!
//! Use of alloc is currently required, so early initialisation will need a
//! different method. We should possibly abstract some functionality so that
//! consumers don't need to worry or care about the difference.
use alloc::{borrow::ToOwned, boxed::Box, string::String, vec::Vec};
use crate::{arch::x86_64::drivers::ascii::WRITER, prelude::*};
/// Represents a [Step] when initialising the system.
///
/// Handles printing various information to the framebuffer using steps.
///
/// # Example
///
/// ```rs
/// // Setup a Step for Foo.
/// let foo_step: Step<Foo, FooError> = Step::new("foo", Foo::init()).register_tag(|foo| { foo.bar().to_string() });
/// // This returns a Result<T, E>
/// let foo = foo_step.run()?;
/// ```
///
/// # TODOs
///
/// * If T = Option<T> and None is returned, we print `"[Not found]"`, otherwise
/// `"[Success]`".
pub struct Step<T: Clone + ToOwned> {
/// The initialisation function for the Step, usually this is a closure.
init_fn: fn() -> T,
/// A list of tag generator functions to display under the Step on success.
/// They are displayed like:
/// ```
/// Initialising module... [Success]
/// => Some information here.
/// ```
///
/// # TODOs
///
/// * Support tags without alloc being initialised.
tags: Vec<Box<dyn Fn(T) -> String>>,
/// The name of the module being initialised.
task: &'static str,
}
// This impl block might be so horrible it needs its own file.
impl<T: ToOwned + Clone> Step<T> {
pub fn new(
task: &'static str,
init_fn: fn() -> T,
tags: Vec<Box<dyn Fn(T) -> String>>,
) -> Self {
Self {
init_fn,
tags,
task,
}
}
/// Runs the initialisation function and logs where required.
///
/// This function is a little messy but it just handles pretty printing the
/// [Step] to the terminal for us.
pub fn run(self) -> T {
print_log!(" {}", self.task);
let mut success_position = WRITER.lock().pos();
success_position.set_x(success_position.x() + 1);
let ret = (self.init_fn)();
println!();
for tag in &self.tags[..] {
// Calls the closure on the return value.
println_log!(" => {}", (tag)(ret.clone()));
}
// Print whether or not the step succeeded.
print_oneshot!(
success_position,
Colour::Green,
Colour::Black,
"[Success]"
);
ret
}
/// Registers a 'tag' or note to display under the line which says
/// `Initialising module... [Success]`.
///
/// # Notes
///
/// The tag is a closure taking in a reference to T and returning a
/// presumably formatted String.
#[allow(unused)]
pub fn register_tag(&mut self, tag: Box<dyn Fn(T) -> String>) -> &Self {
self.tags.push(tag);
self
}
}
*/
kernel/src/util/editor.rs
+20 -11
View File
@@ -1,15 +1,14 @@
use crate::serial_print;
use crate::arch::x86_64::drivers::keyboard::{KeyStroke, get_keystroke_async};
use crate::resources::font::Font;
use crate::std::application::frame::Frame;
use crate::std::application::render::RenderError;
use crate::std::application::window::Window;
use crate::std::application::{Application, Error};
use crate::serial_print;
use crate::serial_println;
use crate::std::application::{
Application, Error, frame::Frame, render::RenderError, window::Window,
};
use crate::std::ascii::Writer;
use crate::std::maths::geometry::Vec2;
use alloc::string::{String, ToString};
use alloc::vec::Vec;
use crate::serial_println;
pub struct Editor {
cursor_line: usize,
@@ -42,7 +41,8 @@ impl<'a> Editor {
fn render(&'a self) -> Result<Frame<'a>, RenderError> {
let mut frame = Frame::new(&self.window);
let writer = Writer::new(Font::default());
let font = Font::default();
let writer = Writer::new(&font);
let (width, height) = writer.font_size().into();
@@ -65,7 +65,10 @@ impl<'a> Editor {
writer.render_glyph(
&mut frame,
Vec2::new(col * width + Self::PADDING, line * height + Self::PADDING),
Vec2::new(
col * width + Self::PADDING,
line * height + Self::PADDING,
),
ch as u8,
scale,
)?;
@@ -124,7 +127,8 @@ impl<'a> Editor {
fn get_char_idx(&self) -> usize {
let frame = Frame::new(&self.window);
let writer = Writer::new(Font::default());
let font = Font::default();
let writer = Writer::new(&font);
let (width, _height) = writer.font_size().into();
let mut col = 0;
@@ -157,7 +161,10 @@ impl<'a> Editor {
impl Application for Editor {
type Output = ();
async fn run(&mut self, _args: Vec<alloc::string::String>) -> Result<Self::Output, Error> {
async fn run(
&mut self,
_args: Vec<alloc::string::String>,
) -> Result<Self::Output, Error> {
self.window.set_dimensions(Vec2::new(1280, 800));
self.window.set_position(Vec2::new(0, 0));
self.window.open();
@@ -167,7 +174,9 @@ impl Application for Editor {
loop {
if let Err(_err) = self.render().and_then(|frame| frame.render()) {
// TODO: Handle error
return Err(Error::ApplicationFailed("Rendering failed".to_string()));
return Err(Error::ApplicationFailed(
"Rendering failed".to_string(),
));
}
let keystroke = get_keystroke_async().await;
libm/src/lib.rs
+40 -51
View File
@@ -1,3 +1,4 @@
#![allow(dead_code)]
#![feature(proc_macro_span)]
#![warn(
clippy::correctness,
@@ -10,9 +11,6 @@
rustdoc::missing_panics_doc
)]
use std::fs::File;
use std::io::{Read, Seek, SeekFrom};
use proc_macro::{Span, TokenStream};
use quote::quote;
use std::path::PathBuf;
@@ -36,17 +34,18 @@ pub fn include_font(item: TokenStream) -> TokenStream {
let source_filepath: PathBuf = source_file.path();
let file_path = format!(
"{}/{}",
source_filepath.parent().unwrap_or_else(|| panic!("Expected to find the calling source file in a folder like src! Got: {}", source_filepath.display())).display(),
source_filepath.parent()
.unwrap_or_else(|| panic!("Expected to find the calling source file in a folder like src! Got: {}", source_filepath.display())).display(),
filename.value()
);
let font_bytes = match load_file(file_path) {
let font_bytes = match std::fs::read(file_path) {
Ok(bytes) => bytes,
Err(why) => panic!("{}", why),
};
let font_data = match Font::new(font_bytes) {
Ok(font) => font.0,
let font_data = match FontBuilder::load(font_bytes) {
Ok(font) => font.data,
Err(why) => panic!("{}", why),
};
@@ -66,40 +65,44 @@ struct FontData {
width: u8,
height: u8,
length: u16,
data: Vec<Glyph>,
unicode_table: [[u8; 2]; 512],
pub data: [[u8; 16]; 512],
}
struct Glyph {
bytes: Vec<u8>,
}
enum FontBuilder {
Psf1,
Psf2,
Psf1(FontData),
Psf2(FontData),
}
impl FontBuilder {
const PSF1_MAGIC: u16 = 0x3604;
const PSF2_MAGIC: u32 = 0x72b54a86;
pub fn load() -> Option<Self> {
None
fn revision(data: &[u8]) -> u8 {
if (data[0] as u16) << 8 | data[1] as u16 == Self::PSF1_MAGIC {
1
} else if (data[0] as u32) << 24
| (data[1] as u32) << 16
| (data[2] as u32) << 8
| data[3] as u32
== Self::PSF2_MAGIC
{
2
} else {
0
}
}
}
impl Font {
const MAGIC: u16 = 0x3604;
pub fn load(data: Vec<u8>) -> Result<FontData, &'static str> {
match Self::revision(&data[0..4]) {
1 => Self::parse_psf1(&data),
2 => Self::parse_psf2(&data),
_ => panic!("invalid font revision result"),
}
}
pub fn new(data: [u8; (32 + 2) * 512 + 4]) -> Result<Self, &'static str> {
let magic: u16 = (data[0] as u16) << 8 | data[1] as u16;
fn parse_psf1(data: &[u8]) -> Result<FontData, &'static str> {
let mode = data[2];
let size = data[3];
if magic != Self::MAGIC {
return Err("Magic value is invalid!");
}
let has_512_glyphs = (mode & 0x01) != 0;
let mut glyphs = [[0; 16]; 512];
let glyph_count = if has_512_glyphs { 512 } else { 256 };
@@ -112,29 +115,15 @@ impl Font {
glyphs[i] = buff;
}
Ok(Self(glyphs))
Ok(FontData {
width: 8,
height: size,
length: glyph_count,
data: glyphs,
})
}
const fn parse_psf2(_data: &[u8]) -> Result<FontData, &'static str> {
Err("PSF2 support is not implemented yet!")
}
}
type FileContents = [u8; (32 + 2) * 512 + 4];
fn load_file(filename: String) -> Result<FileContents, std::io::Error> {
let mut buf = [0; (32 + 2) * 512 + 4];
let mut f = File::open(filename).unwrap();
f.seek(SeekFrom::Start(0)).unwrap();
loop {
match f.read(&mut buf) {
Ok(read) => {
if read == 0 {
break;
}
}
Err(why) => {
eprintln!("Failed to read PS1 font file: {}", why);
return Err(why);
}
}
}
Ok(buf)
}
rustfmt.toml
+5
View File
@@ -0,0 +1,5 @@
wrap_comments = true
max_width = 80
comment_width = 80
format_code_in_doc_comments = true
doc_comment_code_block_width = 80
scripts/run_debug.sh
+10 -1
View File
@@ -32,7 +32,7 @@ else
fi
# Set up test-specific flags
if [ $is_test -eq 1 ]; then
if [$is_test]; then
test_flags="-device isa-debug-exit,iobase=0xf4,iosize=0x04 -display none"
serial_flags="-serial stdio"
else
@@ -94,6 +94,15 @@ check_test_res() {
trap 'check_test_res "tests completed"' ERR
# NOTE(ali): For some reason the values in `boot_flags` were causing issues
# on WSL, so they've been eradicated.
systemInfo=$(uname -r)
if [[ $systemInfo == *"WSL"* ]]; then
echo "Running on WSL2"
boot_flags=""
fi
cd "$project_root"
qemu-system-x86_64 -M q35 \
-cdrom "$build_dir/image.iso" \