What is the process of setting up interrupts for protected mode?

This link says one should:

  • Make space for the interrupt descriptor table
  • Tell the CPU where that space is (see GDT Tutorial: lidt works the very same way as lgdt)
  • Tell the PIC that you no longer want to use the BIOS defaults (see Programming the PIC chips)
  • Write a couple of ISR handlers (see Interrupt Service Routines) for both IRQs and exceptions
  • Put the addresses of the ISR handlers in the appropriate descriptors
  • Enable all supported interrupts in the IRQ mask (of the PIC)

The third step makes no sense to me (I looked at this link but there wasn't anything about telling the PIC anything) so I ignored it and completed the next two steps, only to be clueless once again when I reached the final step. However, from my understanding of interrupts, both of the steps I didn't understand relate to hardware interrupts from the PIC controller and shouldn't affect the interrupts raised by the PIT on IRQ 0. I therefore ignored this step as well.

When I ran my code it compiled fine and even ran in a virtual machine, but the interrupt seemed to fire only once. I then realised that I wasn't sending EOI to the PIC, preventing it from raising any more interrupts. However, adding mov al, 0x20 and out 0x20, al just before the iret instruction makes the virtual machine crash.

Here's my IDT:

; idt
idt_start :

    dw 0x00         ; The interrupt handler is located at absolute address 0x00
    dw CODE_SEG     ; CODE_SEG points to the GDT entry for code
    db 0x0          ; The unused byte
    db 0b11101001   ; 1110 Defines a 32 bit Interrupt gate, 0 is mandatory, privilege level = 0 (0b00), the last bit is one so that the CPU knows that the interrupt will be used
    dw 0x00         ; The higher part of the offset (0x00) is 0x00


idt_descriptor :
    dw idt_end - idt_start - 1 ; Size of our idt, always one less than the actual size
    dd idt_start ; Start address of our idt

Here's my interrupt handler (located at absolute location 0x00 in memory):

    push eax
    add [0x300], byte 
    mov al, 0x20
    out 0x20, al
    pop eax
    times 512-($-$$) db 0

This is the code I use to enter protected mode and load the GDT and IDT into memory:

[bits 16]


    lgdt [gdt_descriptor]
    lidt [idt_descriptor]
    mov eax, cr0
    or eax, 1
    mov cr0,eax
    jmp CODE_SEG:init_pm

[bits 32]

init_pm :

    mov ax, DATA_SEG
    mov ds, ax
    mov ss, ax
    mov es, ax
    mov fs, ax
    mov gs, ax
    mov ebp, 0x90000
    mov esp, ebp
    call BEGIN_PM

My main function (that checks the value of 0x300) is as follows:

void main() {
    char iii[15];
    int * aa = (int *)0x300;
    for (;;)
        setCursor(0, 0);
        print(itoab(*aa, iii));

By the way, I have verified using a memory dump that everything is loaded at the correct address and everything is exactly where it is expected. For example, 0x300 is a free part of memory used simply to simplify my code.

  • 1
    The third step refers to the usual procedure of remapping the interrupts from their standard BIOS mappings. Normally IRQ 0-7 are mapped to INT 8-15, and IRQ 8-15 are mapped to INT 0x70-0x77. The former mapping poses a problem because a number of CPU exceptions are in the INT 8-15 to range, so most operating systems remap a least IRQ 0-7 to something outside the range reserved for CPU exceptions – Ross Ridge Jan 2 '16 at 0:32
  • Note that that is means the PIT, which is connected to IRQ 0, generates INT 8. INT 0 is the integer divide overflow (divide by zero) exception. – Ross Ridge Jan 2 '16 at 0:38
  • It is highly recommended to perform step 3 to move the IRQ's above the first 32 IDT entries, as those are used for traps. I would also highly recommend putting some handler for those first 32, so you can see if you run into a problem. [And use volatiled for your aa variable! – Mats Petersson Jan 2 '16 at 0:42
  • @RossRidge so if I were to raise the PIT interrupt in my code I should raise int 0x08? Why do the IRQ lines overlap? – DividedByZero Jan 2 '16 at 0:43
  • Yes, if you don't change the PIC IRQ to INT mappings then INT 0x08 will invoke the same handler as used by IRQ 0. It's also the same handler that's invoked when the CPU double faults. If your code is really like what you've show and there's only one entry in your IDT, then it should result in a triple fault when the PIT signals an unmasked interrupt. If the entry for INT 8 is beyond the limit of the IDT, then the CPU will generate a general protection fault. The GP fault entry is also beyond the limit, so it generates a double fault, which is beyond the limit too. That causes a triple fault. – Ross Ridge Jan 2 '16 at 1:05

Let's look at how some comparably small kernel, i.e., Linux 0.01 does it!

  • Make space for the interrupt descriptor table

This is done two times (well, technically only one time): first, the bootloader (the path is /boot/boot.s) initializes the IDTR, so the CPU is happy when jumping into Protected Mode. The IDTR content is as follows:

    .word   0            | idt limit=0
    .word   0,0        | idt base=0L

The IDTR is loaded like this:

lidt     idt_48     | load idt with 0,0

Now, the jump can be performed.
Note that there is no IDT here. It's just a dummy, so no error occurs somewhere in the kernel.

Afterwards, the real IDT is initialized (the path is /boot/head.s). The space is allocated like this:

_idt:   .fill 256,8,0       # idt is uninitialized
  • Tell the CPU where that space is (see GDT Tutorial: lidt works the very same way as lgdt)

lidt expects a linear address containing the content of the IDTR. That content looks like this:

    .word 256*8-1       # idt contains 256 entries
    .long _idt

The IDTR is initialized as follows:

lidt idt_descr
  • Tell the PIC that you no longer want to use the BIOS defaults (see Programming the PIC chips)

As @RossRidge mentioned in the comments to your question, that means remapping the IRQ interrupt vectors (IVs).
Since the PIC IVs overlap with the Intel x86 exception addresses, we have to remap one of them. The exception addresses are hard-wired, so we need to remap the PIC vectors.
See also this comment right above the corresponding code by Linus:

| well, that went ok, I hope. Now we have to reprogram the interrupts :-(
| we put them right after the intel-reserved hardware interrupts, at
| int 0x20-0x2F. There they won't mess up anything. Sadly IBM really
| messed this up with the original PC, and they haven't been able to
| rectify it afterwards. Thus the bios puts interrupts at 0x08-0x0f,
| which is used for the internal hardware interrupts as well. We just
| have to reprogram the 8259's, and it isn't fun.

Now, here's the real code. The jmps in between are for synchronizing CPU and PIC, so the CPU won't send data the PIC cannot receive yet. This is comparable to wait states when writing to memory: when the CPU is faster than the memory/memory arbiter, it needs to wait some time before accessing memory the next time.

mov al,#0x11        | initialization sequence
out #0x20,al        | send it to 8259A-1
.word   0x00eb,0x00eb       | jmp $+2, jmp $+2
out #0xA0,al        | and to 8259A-2
.word   0x00eb,0x00eb
mov al,#0x20        | start of hardware int's (0x20)
out #0x21,al
.word   0x00eb,0x00eb
mov al,#0x28        | start of hardware int's 2 (0x28)
out #0xA1,al
.word   0x00eb,0x00eb
mov al,#0x04        | 8259-1 is master
out #0x21,al
.word   0x00eb,0x00eb
mov al,#0x02        | 8259-2 is slave
out #0xA1,al
.word   0x00eb,0x00eb
mov al,#0x01        | 8086 mode for both
out #0x21,al
.word   0x00eb,0x00eb
out #0xA1,al
.word   0x00eb,0x00eb
mov al,#0xFF        | mask off all interrupts for now
out #0x21,al
.word   0x00eb,0x00eb
out #0xA1,al
  • Write a couple of ISR handlers (see Interrupt Service Routines) for both IRQs and exceptions

For exceptions, you can find the handler code in /kernel/traps.c and /kernel/asm.s.
Some exceptions push an error code on the stack prior to jumping to the handler, which you have to pop off or the iret instruction will fail. A page fault also writes the corresponding virtual address to cr2 in addition.
The IRQ handlers are spread across the whole system. -.- The timer and disk interrupt handlers are in /kernel/system_call.s, the keyboard interrupt handler is in /kernel/keyboard.s, for example.

  • Put the addresses of the ISR handlers in the appropriate descriptors

The initialization for exceptions is done in /kernel/traps.c in the trap_init function:

void trap_init(void)
    int i;

    set_system_gate(3,&int3);   /* int3-5 can be called from all */
    for (i=17;i<32;i++)
/*  __asm__("movl $0x3ff000,%%eax\n\t"
        "movl %%eax,%%db0\n\t"
        "movl $0x000d0303,%%eax\n\t"
        "movl %%eax,%%db7"

The IRQ handler entry initializations are again spread across several files. sched_init from /kernel/sched.c initializes the timer interrupt handler's address, for instance.

  • Enable all supported interrupts in the IRQ mask (of the PIC)

This is done in /init/main.c in the main function with the macro sti. It is defined in /asm/system.h as follows:

#define sti() __asm__ ("sti"::) 
  • Thanks for the detailed answer! Everything seems to be working now, only, hardware interrupts aren't firing - calling int 32 fires the PIT interrupt handler, however even after the sti instruction the PIT interrupt never fires.. – DividedByZero Jan 3 '16 at 0:07

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