20

I found this line in the if.c of unix version 6.

ncom = "/usr/bin/xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx";

Why are there so many x's? And why would you set this?

29

The code you are talking of looks like this:

ncom = "/usr/bin/xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx";
while(c=nargv[0][i])  {
    ncom[9+i++] = c;
}
ncom[9+i] = '\0';

All those x's act as a buffer, they are overridden by the following loop. Therefore the code effectively adds "/usr/bin/" to the command in nargv[0].

With a little more context the code is doing this:

execv(nargv[0], nargv, np);
execv(ncom+4, nargv, np);
execv(ncom, nargv, np);

If the given command in nargv[0] is "foo" it will first try to run "foo" then "/bin/foo" and finally "/usr/bin/foo".


Be aware that above is a good example how to not do such things:

If the string in nargv[0] happens to be longer than the number of x's, the code will happily continue copying data. This will override other parts of the stack. The result is a good example of a buffer overflow. (You allocate a buffer of some size and write more data than allocated.)

This example will demonstrate the problem:

#include <stdio.h>
int main(){
  char s[]="abcde";
  int i;
  for(i=0;i<100;i++){
    printf("position %2d contains value %3d\n",i,s[i]);
    s[i]=0;
  }
  puts(s);
  return 0;
}

If you run it it will (most probably) output this:

position  0 contains value  97
position  1 contains value  98
position  2 contains value  99
position  3 contains value 100
position  4 contains value 101
position  5 contains value   0
position  6 contains value   0
position  7 contains value   0
position  8 contains value   0
position  9 contains value   0
position 10 contains value   0
position 11 contains value   0
position 12 contains value  12
position  1 contains value   0
position  2 contains value   0
position  3 contains value   0
position  4 contains value   0
position  5 contains value   0
position  6 contains value   0
position  7 contains value   0
[...]

It will fill the string (containing the ASCII values 97 to 101) with zeroes and continue writing the memory where it will find the position of the variable i it will also set it to zero. Now i is zero and therefore the loop starts again, overriding the the already overridden string again and again.

Not only local variables can be overriden, also the return address of a function might get overriden resulting in either a "segmentation fault" or execution of arbitrary code, which is often used by malware.

  • 2
    Why +9 and +4? Thank you michas :) – Joey Dec 30 '14 at 0:52
  • 4
    The numbers are positions in the string: "/usr" are 4 characters. "/usr/bin/" are 9 characters. – michas Dec 30 '14 at 0:55
  • 3
    What if we <strike>needed</strike> tried to run a command with a name longer than 35 chars? – n.st Dec 30 '14 at 1:56
  • 5
    Not to mention, ncom is pointing at a string literal which is then modified - a big no-no in modern-day C, where string literals are often stored in read-only memory. – Jonathon Reinhart Dec 30 '14 at 9:18
  • 6
    Although the ncom code here is not an example of good defensive programming, in practice the string was long enough for a user using the program properly, because in V6, you'd never need to run a pathname-less command (one without a '/' character somewhere in the command name) that was longer than 14 characters, because that was the longest an entry in a directory could be. Used improperly, I guess it would overwrite data used by libc. – Mark Plotnick Dec 30 '14 at 11:07

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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