dev/kernel/HALKit/AMD64/HalDescriptorLoader.cc


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/* -------------------------------------------

  Copyright (C) 2024-2025, Amlal El Mahrouss, all rights reserved.

------------------------------------------- */

#include <ArchKit/ArchKit.h>
#include <FSKit/NeFS.h>
#include <HALKit/AMD64/Processor.h>

#define kPITDefaultTicks (1000U)

namespace Kernel::HAL {
namespace Detail {
  STATIC ::Kernel::Detail::AMD64::InterruptDescriptorAMD64 kInterruptVectorTable[kKernelIdtSize] =
      {};

  STATIC ATTRIBUTE(unused) void hal_set_irq_mask(UInt8 irql) [[maybe_unused]] {
    UInt16 port;
    UInt8  value;

    if (irql < 8) {
      port = kPICData;
    } else {
      port = kPIC2Data;
      irql -= 8;
    }

    value = rt_in8(port) | (1 << irql);
    rt_out8(port, value);
  }

  STATIC void hal_clear_irq_mask(UInt8 irql) [[maybe_unused]] {
    UInt16 port;
    UInt8  value;

    if (irql < 8) {
      port = kPICData;
    } else {
      port = kPIC2Data;
      irql -= 8;
    }

    value = rt_in8(port) & ~(1 << irql);
    rt_out8(port, value);
  }

  STATIC Void hal_enable_pit(UInt16 ticks) noexcept {
    if (ticks == 0) ticks = kPITDefaultTicks;

    // Configure PIT to receieve scheduler interrupts.

    UInt16 kPITCommDivisor = kPITFrequency / ticks;  // 100 Hz.

    HAL::rt_out8(kPITControlPort, 0x36);                            // Command to PIT
    HAL::rt_out8(kPITChannel0Port, kPITCommDivisor & 0xFF);         // Send low byte
    HAL::rt_out8(kPITChannel0Port, (kPITCommDivisor >> 8) & 0xFF);  // Send high byte

    hal_clear_irq_mask(32);
  }
}  // namespace Detail

/// @brief Loads the provided Global Descriptor Table.
/// @param gdt
/// @return
Void GDTLoader::Load(Register64& gdt) {
#ifndef __NE_MODULAR_KERNEL_COMPONENTS__
  hal_load_gdt(gdt);
#endif  // __NE_MODULAR_KERNEL_COMPONENTS__
}

Void IDTLoader::Load(Register64& idt) {
  rt_cli();

  const Int16 kPITTickForScheduler = kPITDefaultTicks;

  volatile ::Kernel::UIntPtr** ptr_ivt = (volatile ::Kernel::UIntPtr**) idt.Base;

  for (SizeT idt_indx = 0; idt_indx < kKernelIdtSize; ++idt_indx) {
    Detail::kInterruptVectorTable[idt_indx].Selector       = kIDTSelector;
    Detail::kInterruptVectorTable[idt_indx].Ist            = 0;
    Detail::kInterruptVectorTable[idt_indx].TypeAttributes = kInterruptGate;
    Detail::kInterruptVectorTable[idt_indx].OffsetLow      = ((UIntPtr) ptr_ivt[idt_indx] & 0xFFFF);
    Detail::kInterruptVectorTable[idt_indx].OffsetMid =
        (((UIntPtr) ptr_ivt[idt_indx] >> 16) & 0xFFFF);
    Detail::kInterruptVectorTable[idt_indx].OffsetHigh =
        (((UIntPtr) ptr_ivt[idt_indx] >> 32) & 0xFFFFFFFF);

    Detail::kInterruptVectorTable[idt_indx].Zero = 0;
  }

  idt.Base  = (UIntPtr) &Detail::kInterruptVectorTable[0];
  idt.Limit = sizeof(::Kernel::Detail::AMD64::InterruptDescriptorAMD64) * (kKernelIdtSize);

  Detail::hal_enable_pit(kPITTickForScheduler);

#ifndef __NE_MODULAR_KERNEL_COMPONENTS__
  hal_load_idt(idt);
#endif  // __NE_MODULAR_KERNEL_COMPONENTS__

  rt_sti();
}

/// @brief Loads the Global Descriptor Table into the CPU.
/// @param gdt GDT register wrapped in a ref.
void GDTLoader::Load(Ref<Register64>& gdt) {
  if (!gdt) return;

  GDTLoader::Load(gdt.Leak());
}

/// @brief Loads the IDT, for interupts.
/// @param idt IDT register wrapped in a ref.
void IDTLoader::Load(Ref<Register64>& idt) {
  if (!idt) return;

  IDTLoader::Load(idt.Leak());
}
}  // namespace Kernel::HAL