251

How does one determine where the mistake is in the code that causes a segmentation fault?

Can my compiler (gcc) show the location of the fault in the program?

1
  • 11
    No gcc/gdb cannot. You can find out where the segfault occured, but the actual error could be at a totally different location.
    – Aryabhatta
    Commented May 20, 2010 at 18:51

9 Answers 9

350

GCC can't do that but GDB (a debugger) sure can. Compile you program using the -g switch, like this:

gcc program.c -g

Then use gdb:

$ gdb ./a.out
(gdb) run
<segfault happens here>
(gdb) backtrace
<offending code is shown here>

Here is a nice tutorial to get you started with GDB.

Where the segfault occurs is generally only a clue as to where "the mistake which causes" it is in the code. The given location is not necessarily where the problem resides.

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  • 44
    Note that where the segfault occurs is generally only a clue as to where "the mistake which causes" it is in the code. An important clue, but it's not necessarily where the problem resides.
    – mpez0
    Commented May 20, 2010 at 18:55
  • 16
    You can also use ( bt full ) to get more details.
    – ant2009
    Commented May 21, 2010 at 3:37
  • 4
    I find this useful: gnu.org/software/gcc/bugs/segfault.html Commented Dec 10, 2016 at 5:25
  • 5
    Use bt as a shorthand for backtrace.
    – rustyx
    Commented May 27, 2019 at 7:53
  • 1
    @MehdiCharife You get a segfault when dereferencing a bad pointer, not when the pointer information is bad. That is, your valid pointer can go bad because the target is freed, moved, or otherwise no longer valid, or because the pointer itself is not initialized or is changed and now invalid. The system can not detect those events, only the bad dereference that occurs later.
    – mpez0
    Commented Feb 1, 2023 at 22:38
88

Also, you can give valgrind a try: if you install valgrind and run

valgrind --leak-check=full <program>

then it will run your program and display stack traces for any segfaults, as well as any invalid memory reads or writes and memory leaks. It's really quite useful.

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  • 7
    +1 , Valgrind is so much faster / easier to use to spot memory errors. On non-optimized builds with debugging symbols, it tells you exactly where a segfault happened and why.
    – user50049
    Commented May 21, 2010 at 16:38
  • 1
    Sadly my segfault disappears when compiling with -g -O0 and combined with valgrind.
    – JohnMudd
    Commented Jan 19, 2018 at 22:30
  • 5
    --leak-check=full will not help to debug segfaults. It is useful only for debugging memory leaks.
    – ks1322
    Commented Sep 4, 2018 at 9:49
  • @JohnMudd I have a segfault only appear about 1% of the input files tested, if you repeat the failed input it will not fail. My problem was caused by multithreading. So far I have not figured out the line of code causing this problem. I am using retry to cover up this problem for now. If use -g option, fault goes away!
    – Kemin Zhou
    Commented Apr 14, 2020 at 19:25
35

There are a number of tools available which help debugging segmentation faults and I would like to add my favorite tool to the list: Address Sanitizers (often abbreviated ASAN).

Modern¹ compilers come with the handy -fsanitize=address flag, adding some compile time and run time overhead which does more error checking.

According to the documentation these checks include catching segmentation faults by default. The advantage here is that you get a stack trace similar to gdb's output, but without running the program inside a debugger. An example:

int main() {
  volatile int *ptr = (int*)0;
  *ptr = 0;
}
$ gcc -g -fsanitize=address main.c
$ ./a.out
AddressSanitizer:DEADLYSIGNAL
=================================================================
==4848==ERROR: AddressSanitizer: SEGV on unknown address 0x000000000000 (pc 0x5654348db1a0 bp 0x7ffc05e39240 sp 0x7ffc05e39230 T0)
==4848==The signal is caused by a WRITE memory access.
==4848==Hint: address points to the zero page.
    #0 0x5654348db19f in main /tmp/tmp.s3gwjqb8zT/main.c:3
    #1 0x7f0e5a052b6a in __libc_start_main (/lib/x86_64-linux-gnu/libc.so.6+0x26b6a)
    #2 0x5654348db099 in _start (/tmp/tmp.s3gwjqb8zT/a.out+0x1099)

AddressSanitizer can not provide additional info.
SUMMARY: AddressSanitizer: SEGV /tmp/tmp.s3gwjqb8zT/main.c:3 in main
==4848==ABORTING

The output is slightly more complicated than what gdb would output but there are upsides:

  • There is no need to reproduce the problem to receive a stack trace. Simply enabling the flag during development is enough.

  • ASANs catch a lot more than just segmentation faults. Many out of bounds accesses will be caught even if that memory area was accessible to the process.


¹ That is Clang 3.1+ and GCC 4.8+.

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  • 3
    This is most helpful to me. I have a very subtle bug that happen randomly with a frequency about 1%. I process large number of input files with (16 major steps; each one done by a different C or C++ binary). One later step will trigger segmentation fault only randomly because of multi-threading. It is hard to debug. This option triggered the debug information output at least it gave me a start point for code review to find the location of the bug.
    – Kemin Zhou
    Commented Apr 15, 2020 at 3:15
27

You could also use a core dump and then examine it with gdb. To get useful information you also need to compile with the -g flag.

Whenever you get the message:

 Segmentation fault (core dumped)

a core file is written into your current directory. And you can examine it with the command

 gdb your_program core_file

The file contains the state of the memory when the program crashed. A core dump can be useful during the deployment of your software.

Make sure your system doesn't set the core dump file size to zero. You can set it to unlimited with:

ulimit -c unlimited

Careful though! that core dumps can become huge.

4
  • I switched to arch-linux recently. My current directory doesn't contain the core dump file. How can I generate it?
    – Abhinav
    Commented Nov 30, 2016 at 5:44
  • You don't generate it; Linux does. Core dumps are stored at different location on differnt Linuces - Google around. For Arch Linux, read this wiki.archlinux.org/index.php/Core_dump
    – Mawg
    Commented Jan 24, 2017 at 16:35
  • 1
    I had to use gdb --core=core.
    – Julia
    Commented Mar 2, 2021 at 16:32
  • 1
    You can check the current status with ulimit -c, to see more use ulimit -a. Commented Jul 15, 2021 at 0:02
9

All of the above answers are correct and recommended; this answer is intended only as a last-resort if none of the aforementioned approaches can be used.

If all else fails, you can always recompile your program with various temporary debug-print statements (e.g. fprintf(stderr, "CHECKPOINT REACHED @ %s:%i\n", __FILE__, __LINE__);) sprinkled throughout what you believe to be the relevant parts of your code. Then run the program, and observe what the was last debug-print printed just before the crash occurred -- you know your program got that far, so the crash must have happened after that point. Add or remove debug-prints, recompile, and run the test again, until you have narrowed it down to a single line of code. At that point you can fix the bug and remove all of the temporary debug-prints.

It's quite tedious, but it has the advantage of working just about anywhere -- the only times it might not is if you don't have access to stdout or stderr for some reason, or if the bug you are trying to fix is a race-condition whose behavior changes when the timing of the program changes (since the debug-prints will slow down the program and change its timing)

3

Lucas's answer about core dumps is good. In my .cshrc I have:

alias core 'ls -lt core; echo where | gdb -core=core -silent; echo "\n"'

to display the backtrace by entering 'core'. And the date stamp, to ensure I am looking at the right file :(.

Added: If there is a stack corruption bug, then the backtrace applied to the core dump is often garbage. In this case, running the program within gdb can give better results, as per the accepted answer (assuming the fault is easily reproducible). And also beware of multiple processes dumping core simultaneously; some OS's add the PID to the name of the core file.

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  • 7
    and don't forget ulimit -c unlimited to enable core dumps in the first place. Commented May 20, 2010 at 19:14
  • @James: Correct. Lucas already mentioned this. And for those of us who are still stuck in the csh, use 'limit'. And I've never been able to read the CYGWIN stackdumps (but I haven't tried for 2 or 3 years). Commented May 20, 2010 at 19:44
2

In case any of you (like me!) were looking for this same question but with gfortran, not gcc, the compiler is much more powerful these days and before resorting to the use of the debugger, you can also try out these compile options. For me, this identified exactly the line of code where the error occurred and which variable I was accessing out of bounds to cause the segmentation fault error.

-O0 -g -Wall -fcheck=all -fbacktrace
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  • 2
    gcc 10 report: -fcheck=all -fbacktrace are for Fortran not C
    – Valerio
    Commented Jan 30, 2023 at 18:15
  • yes, I should have specified that - I'll edit the answer Commented Jan 30, 2023 at 20:58
1

This is a crude way to find the exact line after which there was the segmentation fault.

  1. Define line logging function
#include \<iostream> 

void log(int line) {  
std::cout << line << std::endl;  
}
  1. find and replace all the semicolon after the log function with "; log(_LINE_);"

  2. Make sure that the semicolons replaced with functions in the for (;;) loops are removed

1

If you have a reproducible exception like segmentation fault, you can use a tool like a debugger to reproduce the error.

I used to find source code location for even non-reproducible error. It's based on the Microsoft compiler tool chain. But it's based on a idea.

  1. Save the MAP file for each binary (DLL,EXE) before you give it to the customer.
  2. If an exception occurs, lookup the address in the MAP file and determine the function whose start address is just below the exception address. As a result you know the function, where the exception occurred.
  3. Subtract the function start address from the exception address. The result is the offset in the function.
  4. Recompile the source file containing the function with assembly listing enabled. Extract the function's assembly listing.
  5. The assembly includes the offset of each instruction in the function. Lookup the source code line, that matches the offset in the function.
  6. Evaluate the assembler code for the specific source code line. The offset points exactly the assembler instruction that caused the thrown exception. Evaluate the code of this single source code line. With a bit of experience with the compiler output you can say what caused the exception.
  7. Be aware the reason for the exception might be at a totally different location. e.g. the code dereferenced a NULL pointer, but the actual reason, why the pointer is NULL can be somewhere else.

The steps 6. and 7. are beneficial since you asked only for the line of code. But I recommend that you should be aware of it.

I hope you get a similar environment with the GCC compiler for your platform. If you don't have a usable MAP file, use the tool chain tools to get the addresses of the the function. I am sure the ELF file format supports this.

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