use libk::drivers::apic::enable_apic;
use libk::drivers::pic::ChainedPics;
use libk::prelude::*;
use x86_64::registers::control::Cr2;
use x86_64::structures::idt::{InterruptDescriptorTable, InterruptStackFrame, PageFaultErrorCode};

use spin::{Lazy, Mutex};

use super::gdt;

static IDT: Lazy<InterruptDescriptorTable> = Lazy::new(|| {
    let mut idt = InterruptDescriptorTable::new();
    idt.breakpoint.set_handler_fn(breakpoint_handler);

    unsafe {
        idt.double_fault
            .set_handler_fn(double_fault_handler)
            .set_stack_index(gdt::DOUBLE_FAULT_1ST_INDEX);
    }

    idt.general_protection_fault
        .set_handler_fn(general_protection_fault_handler);
    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
});

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

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

#[derive(Debug, Clone, Copy)]
#[repr(u8)]
pub enum InterruptIndex {
    Timer = PIC_1_OFFSET,
    Keyboard,
}

impl InterruptIndex {
    const fn as_u8(self) -> u8 {
        self as u8
    }

    fn _as_usize(self) -> usize {
        usize::from(self.as_u8())
    }
}

pub fn init_idt() {
    IDT.load();
    // enable_apic();
    // TODO: fix apic
    unsafe {
        PICS.lock().initialize();
        PICS.lock().write_masks(0xfc, 0xff);
    }
}

extern "x86-interrupt" fn breakpoint_handler(stack_frame: InterruptStackFrame) {
    serial_println!("Exception: Breakpoint\n{:#?}", stack_frame);
    println_log!("Exception: Breakpoint\n{:#?}", stack_frame);
}

extern "x86-interrupt" fn general_protection_fault_handler(
    stack_frame: InterruptStackFrame,
    _error_code: u64,
) {
    serial_println!("Exception: General Protection Fault\n{:#?}", stack_frame);
    panic!("Exception: General Protection Fault\n{:#?}", stack_frame);
}

extern "x86-interrupt" fn double_fault_handler(
    stack_frame: InterruptStackFrame,
    _error_code: u64,
) -> ! {
    serial_println!("Exception: Double Fault\n{:#?}", stack_frame);
    panic!("Exception: Double Fault\n{:#?}", stack_frame);
}

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(|| {
        Mutex::new(Keyboard::new(
            ScancodeSet1::new(),
            layouts::Uk105Key,
            HandleControl::Ignore,
        ))
    });

    let _keyboard = KEYBOARD.lock();
    let mut port = Port::new(0x60);

    let scancode: u8 = unsafe { port.read() };
    libk::drivers::io::keyboard::add_scancode(scancode);

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

extern "x86-interrupt" fn timer_interrupt_handler(_stack_frame: InterruptStackFrame) {
    unsafe {
        PICS.lock()
            .notify_end_of_interrupt(InterruptIndex::Timer.as_u8());
    }
}

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);

    crate::hcf();
}