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I'm reading about the difference in assembly between x86 and x64.

On x86, the system call number is placed in eax, then int 80h is executed to generate a software interrupt.

But on x64, the system call number is placed in rax, then syscall is executed.

I'm told that syscall is lighter and faster than generating a software interrupt.

Why it is faster on x64 than x86, and can I make a system call on x64 using int 80h?

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To clarify: rax is eax for 64bit. Basically you have rax (full 64 bit), eax (32 bit, or the lower 32 bit), ax (16 bit or the lower 16 bit), {ah,al} (upper and lower 8 bit) which all point to the same register, only different portions (sizes). –  nemo Mar 2 '13 at 0:00
    
Also possible duplicate: stackoverflow.com/questions/9136028/… –  nemo Mar 2 '13 at 0:06

2 Answers 2

up vote 7 down vote accepted

General part

EDIT: Linux irrelevant parts removed

While not totally wrong narrowing down to int 0x80 and syscall oversimplifies the question as with sysenter there is at least a 3rd option.

Using 0x80 and eax for syscall number, ebx, ecx, edx, esi, edi, and ebp to pass parameters is just one of many possible other choices to implement a system call.

Before taking a closer look at the techniques involved, it should be stated that they all circle around the problem of escaping the privilege prison every process runs in.

Another choice to the ones presented here offered by the x86 architecture would have been the use of a call gate (see: http://en.wikipedia.org/wiki/Call_gate)

The only other possibility present on all i386 machines is using a software interrupt, which allows the ISR to run in a different privilege level than before.

Software Interrupt

What exactly happens once an interrupt is triggered depends on whether switching to the ISR requires a privilege change or not:

(Intel® 64 and IA-32 Architectures Software Developer’s Manual)

6.4.1 Call and Return Operation for Interrupt or Exception Handling Procedures

...

If the code segment for the handler procedure has the same privilege level as the currently executing program or task, the handler procedure uses the current stack; if the handler executes at a more privileged level, the processor switches to the stack for the handler’s privilege level.

....

If a stack switch does occur, the processor does the following:

  1. Temporarily saves (internally) the current contents of the SS, ESP, EFLAGS, CS, and > EIP registers.

  2. Loads the segment selector and stack pointer for the new stack (that is, the stack for the privilege level being called) from the TSS into the SS and ESP registers and switches to the new stack.

  3. Pushes the temporarily saved SS, ESP, EFLAGS, CS, and EIP values for the interrupted procedure’s stack onto the new stack.

  4. Pushes an error code on the new stack (if appropriate).

  5. Loads the segment selector for the new code segment and the new instruction pointer (from the interrupt gate or trap gate) into the CS and EIP registers, respectively.

  6. If the call is through an interrupt gate, clears the IF flag in the EFLAGS register.

  7. Begins execution of the handler procedure at the new privilege level.

... sigh this seems to be a lot to do and even once we're done it doesn't get too much better:

(excerpt taken from the same source as mentioned above: Intel® 64 and IA-32 Architectures Software Developer’s Manual)

When executing a return from an interrupt or exception handler from a different privilege level than the interrupted procedure, the processor performs these actions:

  1. Performs a privilege check.

  2. Restores the CS and EIP registers to their values prior to the interrupt or exception.

  3. Restores the EFLAGS register.

  4. Restores the SS and ESP registers to their values prior to the interrupt or exception, resulting in a stack switch back to the stack of the interrupted procedure.

  5. Resumes execution of the interrupted procedure.

Sysenter

Another option on the 32-bit platform not mentioned in your question at all, but nevertheless utilized by the Linux kernel is the sysenter instruction.

(Intel® 64 and IA-32 Architectures Software Developer’s Manual Volume 2 (2A, 2B & 2C): Instruction Set Reference, A-Z)

Description Executes a fast call to a level 0 system procedure or routine. SYSENTER is a companion instruction to SYSEXIT. The instruction is optimized to provide the maximum performance for system calls from user code running at privilege level 3 to operating system or executive procedures running at privilege level 0.

One disadvantage of using this solution is, that it is not present on all 32-bit machines, so the int 0x80 method still has to be provided in case the CPU doesn't know about it.

The SYSENTER and SYSEXIT instructions were introduced into the IA-32 architecture in the Pentium II processor. The availability of these instructions on a processor is indicated with the SYSENTER/SYSEXIT present (SEP) feature flag returned to the EDX register by the CPUID instruction. An operating system that qualifies the SEP flag must also qualify the processor family and model to ensure that the SYSENTER/SYSEXIT instructions are actually present

Syscall

The last possibility, the syscall instruction, pretty much allows for the same functionality as the sysenter instruction. The existence of both is due to the fact that one (systenter) was introduced by Intel while the other (syscall) was introduced by AMD.

Linux specific

In the Linux kernel any of the three possibilities mentioned above may be chosen to realize a system call.

As already stated above, the int 0x80 method is the only one of the 3 chosen implementations, that can run on any i386 CPU so this is the only one that is always available.

To allow to switch between all 3 choices every process run is given access to a special shared object that gives access to the system call implementation chosen for the running system. This is the strange looking linux-gate.so.1 you already might have encountered as unresolved library when using ldd or the like.

(arch/x86/vdso/vdso32-setup.c)

 if (vdso32_syscall()) {                                                                               
        vsyscall = &vdso32_syscall_start;                                                                 
        vsyscall_len = &vdso32_syscall_end - &vdso32_syscall_start;                                       
    } else if (vdso32_sysenter()){                                                                        
        vsyscall = &vdso32_sysenter_start;                                                                
        vsyscall_len = &vdso32_sysenter_end - &vdso32_sysenter_start;                                     
    } else {                                                                                              
        vsyscall = &vdso32_int80_start;                                                                   
        vsyscall_len = &vdso32_int80_end - &vdso32_int80_start;                                           
    }   

To utilize it all you have to do is load all your registers system call number in eax, parameters in ebx, ecx, edx, esi, edi as with int 0x80 system call implementation and call the main routine.

Unfortunately it is not all that easy, as to minimize the security risk of a fixed predefined address the location at which the vdso will be visible in a process is randomized, so you will have to figure out the correct location first.

This address individual to each process is passed to it, once it is started.

In case you didn't know, when started in Linux, every process gets pointers to the parameters passed once it was started and pointers to a description of the environment variables it is running under passed on its stack - each of them terminated by NULL.

Additionally to these a third block of so called elf-auxiliary-vectors gets passed following the ones mentioned before. The correct location is encoded in one of these carrying the type-identifier AT_SYSINFO.

So stack layout looks like this:

  • parameter-0
  • ...
  • parameter-m
  • NULL
  • environment-0
  • ....
  • environment-n
  • NULL
  • ...
  • auxilliary elf vector: AT_SYSINFO
  • ...
  • auxilliary elf vector: AT_NULL

Usage example

To find the correct address you will have to first skip all arguments and all environment pointers and then start scanning for AT_SYSINFO as shown in the example below:

#include <stdio.h>
#include <elf.h>

void putc_1 (char c) {
  __asm__ ("movl $0x04, %%eax\n"
           "movl $0x01, %%ebx\n"
           "movl $0x01, %%edx\n"
           "int $0x80"
           :: "c" (&c)
           : "eax", "ebx", "edx");
}

void putc_2 (char c, void *addr) {
  __asm__ ("movl $0x04, %%eax\n"
           "movl $0x01, %%ebx\n"
           "movl $0x01, %%edx\n"
           "call *%%esi"
           :: "c" (&c), "S" (addr)
           : "eax", "ebx", "edx");
}


int main (int argc, char *argv[]) {

  /* using int 0x80 */
  putc_1 ('1');


  /* rather nasty search for jump address */
  argv += argc + 1;     /* skip args */
  while (*argv != NULL) /* skip env */
    ++argv;            

  Elf32_auxv_t *aux = (Elf32_auxv_t*) ++argv; /* aux vector start */

  while (aux->a_type != AT_SYSINFO) {
    if (aux->a_type == AT_NULL)
      return 1;
    ++aux;
  }

  putc_2 ('2', (void*) aux->a_un.a_val);

  return 0;
}

As you will see by taking a look at the following snippet of /usr/include/asm/unistd_32.h on my system:

#define __NR_restart_syscall 0
#define __NR_exit            1
#define __NR_fork            2
#define __NR_read            3
#define __NR_write           4
#define __NR_open            5
#define __NR_close           6

The syscall I used is the one numbered 4 (write) as passed in the eax register. Taking filedescriptor (ebx = 1), data-pointer (ecx = &c) and size (edx = 1) as its arguments, each passed in the corresponding register.

To put a long story short

Comparing a supposedly slow running int 0x80 system call on any Intel CPU with a (hopefully) much faster implementation using the (genuinely invented by AMD) syscall instruction is comparing apples to oranges.

IMHO: Most probably the sysenter instruction instead of int 0x80 should be to the test here.

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1  
OP has included 'linux' tag, so discussion on int 21h used by DOS probably is not relevant. Further, the question is not at all about different ways to how system calls could be implemented in different operating systems, but specifically about int 80h and syscall in Linux and the x86/x86-64 differences on these. –  nrz Mar 2 '13 at 0:35
    
@nrz oops, I obviously missed that –  mikyra Mar 2 '13 at 0:38
1  
@nrz: according to your feedback I removed any reference to non-Linux syscall implementations and refined on the Linux ones. –  mikyra Mar 2 '13 at 4:12
    
@mikyra: That's deep. Cannot not +1! Nice job! –  user405725 Mar 2 '13 at 4:13

There are three things that needs to happen when you call the kernel (making a system call): 1. The system goes from "user mode" to "kernel mode" (ring 0). 2. The stack switches from "user mode" to "kernel mode". 3. A jump is made to a suitable part of the kernel.

Obviously, once inside the kernel, the kernel code will need to know what you actually want the kernel to do, hence putting something in EAX, and often more things in other registers since there are things like "name of the file you want to open" or "buffer to read data from a file into" etc, etc.

Different processors have different ways to achieve the above three steps. In x86, there are several choices, but the two most popular are the int 0xnn or syscall (there's also sysenter)

The syscall instruction was introduced with the x86-64 architecture as a faster way to enter a system call. It has a set of registers (using the x86 MSR mechanisms) that contain the address for EIP/RIP we wish to jump to, what values to load into CS and SS, for doing the Ring3 to Ring0 transition, and the stack pointer value. It also stores the return address in ECX/RCX. [Please read the instruction set manual for all the details of this instruction - it is not entirely trivial!]. Since the processor knows this will switch to Ring0, it can directly do the right thing.

When returning using the SYSRET instruction, the values are restored from predetermined values in registers, so again, it's quick, because the processor just has to set a few registers up. The processor knows that it will change from Ring0 to Ring3, so can do the right things quickly.

The int 0x80 variant used in 32-bit mode will decide what to do based on the value in the interrupt descriptor table, which means reading from memory. There it finds the new CS and EIP/RIP values. The new CS register determines the new "ring" level - Ring0 in this case. It will then use the new CS value to look into the Task State Segment (based on the TR register) to find out which stack pointer (ESP/RSP and SS), and then finally jumps to the new address. Since this is a less direct and more generic solution it is also slower. The old EIP/RIP and CS is stored on the new stack, along with the old values of the SS and ESP/RSP.

When returning, using the IRET instructon,the processor reads the return address and the stack pointer values from the stack, loading the new stack segment and code segment values from the stack as well. Again, the process is generic, and takes quite a few memory reads. Since it's generic, the processor also will have to check "are we changing mode from Ring0 to Ring3, if so change these things".

So, in summary, it's faster because it was meant to work that way.

For 32-bit code, yes, you can definitely use int 0x80. For 64-bit code, I don't think it works, but I'm not certain. I'm certain there is little meaning in doing so - why would you want to make it slower? You will need to change the code anyway, so I really don't see any meaning in using int 0x80 on a 64-bit piece of code.

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