ableos/ableos/src/arch/x86_64/interrupts.rs

/*
 * Copyright (c) 2022, able <abl3theabove@gmail.com>
 *
 * SPDX-License-Identifier: MPL-2.0
 */

use core::panic::PanicInfo;

use crate::{
    arch::gdt,
    devices::pci::{PciDevice, PCI_DEVICES},
    println,
    rhai_shell::KEYBUFF,
};
use cpuio::outb;
use pic8259::ChainedPics;
use qrcode::QrCode;
use seq_macro::seq;
use spin::Lazy;
use x86_64::structures::idt::{InterruptDescriptorTable, InterruptStackFrame};

use super::sloop;

pub const PIC_1_OFFSET: u8 = 32;
pub const PIC_2_OFFSET: u8 = PIC_1_OFFSET + 8;

pub static PICS: spin::Mutex<ChainedPics> =
    spin::Mutex::new(unsafe { ChainedPics::new(PIC_1_OFFSET, PIC_2_OFFSET) });

/// Interrupt offsets.
#[derive(Debug, Clone, Copy)]
#[repr(u8)]
pub enum InterruptIndex {
    Timer = PIC_1_OFFSET,
    Keyboard,
    /// Mouse offset
    Mouse = 44,

    /// Disk offset
    Disk = 46,

    // SecondInterrupt = PIC_2_OFFSET,
    Cmos = 0x70,
}

impl InterruptIndex {
    fn as_u8(self) -> u8 {
        self as u8
    }
    fn as_usize(self) -> usize {
        usize::from(self.as_u8())
    }
}

static IDT: Lazy<InterruptDescriptorTable> = Lazy::new(|| {
    reset_pit_for_cpu();
    let mut idt = InterruptDescriptorTable::new();

    seq!(N in 32..=255 {
        idt[N].set_handler_fn(undefined_handler_~N);
    });

    idt.breakpoint.set_handler_fn(breakpoint_handler);
    unsafe {
        idt.double_fault
            .set_handler_fn(double_fault_handler)
            .set_stack_index(gdt::DOUBLE_FAULT_IST_INDEX);
    }

    idt[InterruptIndex::Timer.as_usize()].set_handler_fn(timer_interrupt_handler);
    idt[InterruptIndex::Keyboard.as_usize()].set_handler_fn(keyboard_interrupt_handler);
    idt[InterruptIndex::Mouse.as_usize()].set_handler_fn(crate::hardware::mouse_interrupt_handler);

    // run `a + b + l + e + o + s print;` in ablescript and its 54 thats why this seemingly arbitrary number was chosen
    idt[54].set_handler_fn(software_int_handler);

    idt
});

seq!(N in 32..=255 {
    extern "x86-interrupt" fn undefined_handler_~N(stack_frame: InterruptStackFrame) {
        error!("INT {}: {:?}", N, stack_frame);
        unsafe {
            PICS.lock()
                .notify_end_of_interrupt(N);
        }
    }
});

extern "x86-interrupt" fn software_int_handler(stack_frame: InterruptStackFrame) {
    trace!("EXCEPTION: SOFTWARE INT\n{:#?}", stack_frame);
    unsafe {
        PICS.lock().notify_end_of_interrupt(54);
    }
}

extern "x86-interrupt" fn breakpoint_handler(stack_frame: InterruptStackFrame) {
    trace!("EXCEPTION: BREAKPOINT\n{:#?}", stack_frame);
}

extern "x86-interrupt" fn double_fault_handler(
    stack_frame: InterruptStackFrame,
    // NOTE(able): ignore this always is 0
    _error_code: u64,
) -> ! {
    bsod(BSODSource::DoubleFault(&stack_frame));
    // panic!("EXCEPTION: DOUBLE FAULT\n{:#?}", stack_frame);
}

/* SAFETY
* DO NOT TOUCH
* The `#[naked]` macro removes various error/bounds checks that
* the Rust compiler would normally add.
* *Early return* and *enabling interrupts* in this function are
* undefined behavior.
* As long as nothing in this function does something that would
* normally trigger an error, this function is relatively safe.
*/
extern "x86-interrupt" fn timer_interrupt_handler(_stack_frame: InterruptStackFrame) {
    crate::kmain::tick();
    unsafe {
        PICS.lock()
            .notify_end_of_interrupt(InterruptIndex::Timer.as_u8());
    }
}

extern "x86-interrupt" fn keyboard_interrupt_handler(_stack_frame: InterruptStackFrame) {
    use pc_keyboard::{
        layouts::Us104Key, DecodedKey, HandleControl, KeyCode, Keyboard, ScancodeSet1,
    };
    use spin::Mutex;
    use x86_64::instructions::port::Port;

    static KEYBOARD: Lazy<Mutex<Keyboard<Us104Key, ScancodeSet1>>> =
        Lazy::new(|| Mutex::new(Keyboard::new(Us104Key, ScancodeSet1, HandleControl::Ignore)));

    let mut keyboard = KEYBOARD.lock();
    if let Ok(Some(key)) = keyboard
        .add_byte(unsafe { Port::new(0x60).read() })
        .map(|x| x.and_then(|ev| keyboard.process_keyevent(ev)))
    {
        // trace!("{key:?}");
        match key {
            DecodedKey::Unicode(chr) => match chr {
                '\n' => {
                    KEYBUFF.lock().push('\n');
                }
                // Backspace
                '\u{8}' => {
                    // TODO: Fix this and apply to new term

                    KEYBUFF.lock().push(8.into());
                    // trace!("8");
                    // print!("\u{8}");
                }
                // '^' => KERNEL_STATE.lock().shutdown(),
                chr => {
                    KEYBUFF.lock().push(chr);
                    // trace!("{chr}");
                    // print!("{chr}");
                }
            },
            DecodedKey::RawKey(key) => {
                use KeyCode::*;
                match KeyCode::from(key) {
                    AltLeft | AltRight => (),
                    ArrowDown | ArrowRight | ArrowLeft | ArrowUp => {
                        // warn!("ArrowKeys are unsupported currently");
                    }

                    _kc => {
                        // trace!("Unprintable key: {kc:?}"),
                    }
                };
            }
        }
    }

    unsafe {
        PICS.lock()
            .notify_end_of_interrupt(InterruptIndex::Keyboard.as_u8());
    }
}

pub fn init_idt() {
    IDT.load();
}

/// https://wiki.osdev.org/Pit
///
const PIT_MAX_FREQ: u32 = 1193182;

pub fn set_pit_frequency(pit: u16, freq: u32) {
    // Dividing the maximum frequency by the desired frequency
    // gives roughly what the maximum value for the timer
    // counter should be to run at the desired frequency.
    let ret = (PIT_MAX_FREQ / freq).try_into();

    // Type-bounded counter maximum.
    let divisor: u16 = match ret {
        Ok(div) => div,
        Err(err) => {
            error!("{}", err);

            warn!("Defaulting to 1000 on PIT{}", pit);
            1000
        }
    };

    unsafe {
        outb(0x36, 0x43);

        outb((divisor & 0xFF) as u8, 0x39 + pit);
        outb((divisor >> 8) as u8, 0x40 + pit);
    }
}
pub fn set_pit_1(freq: u32) {
    set_pit_frequency(1, freq);
}
pub fn set_pit_2(freq: u32) {
    set_pit_frequency(2, freq);
}

pub fn set_pit_3(freq: u32) {
    set_pit_frequency(3, freq);
}

pub fn reset_pit_for_cpu() {
    set_pit_1(1000);
    set_pit_2(1000);
    set_pit_3(1000);
}
pub fn bsod(src: BSODSource) -> ! {
    let src1 = match src {
        BSODSource::DoubleFault(_) => "DoubleFault".to_string(),
        BSODSource::Panic(panic_info) => {
            let strr = format!("PANIC: {}", panic_info);
            strr
        }
    };

    let st = format!(
        "We fucked up ඞ : \n{}\nThe following qr code will link you to the wiki which hopefully solves your problems",
        src1
    );

    println!("\n{}", st);

    // let sf = format!("https://git.ablecorp.us/able/ableos/wiki/Double-Faults");

    let sd = match src {
        BSODSource::DoubleFault(_) => "https://git.ablecorp.us/able/ableos/wiki/Double-Faults",
        BSODSource::Panic(_) => {
            trace!("panic");
            "https://git.ablecorp.us/able/ableos/wiki/Panic"
        }
    };

    let code = QrCode::new(sd).unwrap();

    let image = code
        .render::<char>()
        .quiet_zone(false)
        .module_dimensions(2, 1)
        .build();

    println!("{}", image);

    sloop();
}

#[derive(Debug)]
pub enum BSODSource<'a> {
    DoubleFault(&'a InterruptStackFrame),
    Panic(&'a PanicInfo<'a>),
}