Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

Can someone explain what the following assembly code does?

 int 0x80
share|improve this question

7 Answers 7

up vote 24 down vote accepted

It passes control to interrupt vector 0x80


On Linux, have a look at this: it was used to handle system_call. Of course on another OS this could mean something totally different.

share|improve this answer
Note that int 0x80 is the older way to do a syscall, but there is also the SYSENTER instruction. Some links of interest: – asveikau Nov 30 '09 at 3:06
@asveikau: thanks for your links! – jldupont Nov 30 '09 at 3:37
by shorten long story that's instructions mean DO IT for instruction was before. – Gunslinger_ Apr 30 '11 at 21:18

int means interrupt, and the number 0x80 is the interrupt number. An interrupt transfers the program flow to whomever is handling that interrupt, which is interrupt 0x80 in this case. In Linux, 0x80 interrupt handler is the kernel, and is used to make system calls to the kernel by other programs.

The kernel is notified about which system call the program wants to make, by examining the value in the register %eax (gas syntax, and EAX in Intel syntax). Each system call have different requirements about the use of the other registers. For example, a value of 1 in %eax means a system call of exit(), and the value in %ebx holds the value of the status code for exit().

share|improve this answer
good explanation.. – pradipta Nov 27 '12 at 8:55
Aaah, a perfect answer :) i was misunderstanding that int is integer as it is in HTML! :D – Afzaal Ahmad Zeeshan Oct 20 '13 at 0:00
HTML as an example of "int as integer" is very... amusing, to say the least :P – MestreLion Feb 17 at 9:41

int 0x80 is the assembly language instruction that is used to invoke system calls in Linux on x86 (i.e., Intel-compatible) processors.

share|improve this answer
This is the correct answer. – Koray Tugay Feb 28 at 17:01

You can see here that INT is just one of the many instructions (actually the Assembly Language representation of it) that exists in the x86 instruction set. You can also find more information about this instruction in Intel's own manual found here.

To summarize from the PDF:

INT n/INTO/INT 3—Call to Interrupt Procedure

The INT n instruction generates a call to the interrupt or exception handler specified with the destination operand. The destination operand specifies a vector from 0 to 255, encoded as an 8-bit unsigned intermediate value. The INT n instruction is the general mnemonic for executing a software-generated call to an interrupt handler.

As you can see 80 is the destination operand in your question. At this point the CPU knows that it should execute some code that resides in the Kernel, but what code? That is determined by the Interrupt Vector in Linux.

One of the most useful DOS software interrupts was interrupt 0x21. By calling it with different parameters in the registers (mostly ah and al) you could access various IO operations, string output and more.

Most Unix systems and derivatives do not use software interrupts, with the exception of interrupt 0x80, used to make system calls. This is accomplished by entering a 32-bit value corresponding to a kernel function into the EAX register of the processor and then executing INT 0x80.

Take a look at this please where other available values in the interrupt handler tables are shown:

enter image description here

As you can see the table points the CPU to execute a system call. You can find the Linux System Call table here.

So by moving the value 0x1 to EAX register and calling the INT 0x80 in your program, you can make the process go execute the code in Kernel which will stop (exit) the current running process (on Linux, x86 Intel CPU).

A hardware interrupt must not be confused with a software interrupt. Here is a very good answer on this regard.

This also is good source.

You can see int 80h in action here.

share|improve this answer

As mentioned, it causes control to jump to interrupt vector 0x80. In practice what this means (at least under Linux) is that a system call is invoked; the exact system call and arguments are defined by the contents of the registers. For example, exit() can be invoked by setting %eax to 1 followed by 'int 0x80'.

share|improve this answer

It tells the cpu to activate interrupt vector 0x80, which on Linux OSes is the system-call interrupt, used to invoke system functions like open() for files, et cetera.

share|improve this answer
Strictly speaking, it doesn't tell the kernel... It tells the CPU, which looks up the handler in the IDT, which ends up being a pointer to some kernel code. – asveikau Nov 30 '09 at 2:56
True. I suppose the better phrasing would be it tells the CPU to activate the vector, and the vector (as part of the kernel) invokes the function. – Amber Nov 30 '09 at 2:58
Down for "tells the kernel". – Andy Dec 1 '09 at 6:28
which ends up doing this, which inturn ends up doing that, which then does this, which then goes there confused. :/ Amber has an answer that is understandable..thats it.. – Afzaal Ahmad Zeeshan Oct 20 '13 at 0:04

Minimal 16-bit example

First learn how to create a minimal bootloader OS and run it on QEMU and real hardware as I've explained here:

Now you can run in 16-bit real mode:

    movw $handler0, 0x00
    mov %cs, 0x02
    movw $handler1, 0x04
    mov %cs, 0x06
    int $0
    int $1
    /* Do 0. */
    /* Do 1. */

This would do in order:

  • Do 0.
  • Do 1.
  • hlt: stop executing

Note how the processor looks for the first handler at address 0, and the second one at 4: that is a table of handlers called the IVT, and each entry has 4 bytes.

Minimal example that does some IO to make handlers visible.

Protected mode

Modern operating systems run in the so called protected mode.

The handling has more options in this mode, so it is more complex, but the spirit is the same.

Minimal example

Linux usage of 0x80

Linux sets up the interrupt handler for 0x80 such that it implements system calls, a way for userland programs to communicate with the kernel.

You cannot set your own handlers directly from userland because you only have ring 3 and Linux prevents you from doing so.

Hello world example:

        .ascii "hello world\n"
        len = . - s
    .global _start

        movl $4, %eax   /* write system call number */
        movl $1, %ebx   /* stdout */
        movl $s, %ecx   /* the data to print */
        movl $len, %edx /* length of the buffer */
        int $0x80

        movl $1, %eax   /* exit system call number */
        movl $0, %ebx   /* exit status */
        int $0x80

Compile and run with:

gcc main.S  as -o main.o main.s
ld -o main.out -s main.o

int 0x80 works, but has been deprecated by better ones: first sysenter, then VDSO. See also: What is better "int 0x80" or "syscall"?

x86_64 uses syscall.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.