Can someone point out the difference between gcc -D_FORTIFY_SOURCE=1 and -D_FORTIFY_SOURCE=2? I guess =2 is more secure? I haven't been able to find a list which lists differences point by point.

I have also read that -D_FORTIFY_SOURCE=2 should be used with -O2, otherwise not all features would be available. Also here i haven't found a list which would specify the regressions in detail. I would especially be interested to compile with -Os as the target is a device with not so much flash memory.

Any hints on where this is documented welcome!

  • 10
    Not sure if you have seen these so: (1) The patch which included GCC support for this (with some details on differences between =1 and =2) is here; (2) The 'feature test macros' man page with an entry about _FORTIFY_SOURCE is here. Nov 22, 2012 at 18:38

2 Answers 2


From the manual page for the Feature Test Macros (man 7 feature_test_macros)

_FORTIFY_SOURCE (since glibc 2.3.4)

Defining this macro causes some lightweight checks to be performed to detect some buffer overflow errors when employing various string and memory manipulation functions (for example, memcpy, memset, stpcpy, strcpy, strncpy, strcat, strncat, sprintf, snprintf, vsprintf, vsnprintf, gets, and wide character variants thereof). For some functions, argument consistency is checked; for example, a check is made that open has been supplied with a mode argument when the specified flags include O_CREAT. Not all problems are detected, just some common cases.

If _FORTIFY_SOURCE is set to 1, with compiler optimization level 1 (gcc -O1) and above, checks that shouldn't change the behavior of conforming programs are performed.

With _FORTIFY_SOURCE set to 2, some more checking is added, but some conforming programs might fail.

Some of the checks can be performed at compile time (via macros logic implemented in header files), and result in compiler warnings; other checks take place at run time, and result in a run-time error if the check fails.

Use of this macro requires compiler support, available with gcc since version 4.0.

Moreover, the article Enhance application security with FORTIFY_SOURCE (March 2014) says:

  • gcc -D_FORTIFY_SOURCE=1 adds checks at compile-time only (some headers are necessary as #include <string.h>)
  • gcc -D_FORTIFY_SOURCE=2 also adds checks at run-time (detected buffer overflow terminates the program)

Essentially, _FORTIFY_SOURCE level 2 is more secure, but is a slightly riskier compilation strategy; if you use it, make sure you have very strong regression tests for your compiled code to prove the compiler hasn't introduced any unexpected behaviour.

  • 9
    Is there any indication, on when the conforming programs might fail?
    – user857990
    Apr 13, 2017 at 13:47
  • 3
    -D_FORTIFY_SOURCE=1 adds at least one runtime check: It enables use of __longjmp_chk instead of __longjmp, that former of which checks that you don't jump "downwards" in the stack. Sep 19, 2019 at 12:06
  • "level 2 is more secure, but is a slightly riskier" — what sounds risky is the potential overflows; is level 2 non-conformant assuming you have software that has no code with buffer overflows? May 19, 2021 at 0:33

http://gcc.gnu.org/ml/gcc-patches/2004-09/msg02055.html goes into more detail than feature_test_macros(7).

Here's the relevant excerpt, lightly edited/reformatted for clarity:

The difference between -D_FORTIFY_SOURCE=1 and -D_FORTIFY_SOURCE=2 is e.g. for

  struct S {
      struct T {
        char buf[5];
        int x;
      } t;
      char buf[20];
  } var;


  strcpy (&var.t.buf[1], "abcdefg");

is not considered an overflow (object is whole var), while with -D_FORTIFY_SOURCE=2

  strcpy (&var.t.buf[1], "abcdefg");

will be considered a buffer overflow.

Another difference is that with -D_FORTIFY_SOURCE=2, %n in format strings of the most common *printf family functions is allowed only if it is stored in read-only memory (usually string literals, gettext's _("%s string %n") is fine too), but usually when an attacker attempts to exploit a format string vulnerability, %n will be somewhere where the attacker could write it into.

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