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When my c++ app crashes I would like to generate a stacktrace.

I already asked this but I guess I needed to clarify my needs.

My app is being run by many different users and it also runs on Linux, Windows and Macintosh ( all versions are compiled using gcc ).

I would like my program to be able to generate a stack trace when it crashes and the next time the user run's it, it will ask them if it is ok to send the stack trace to me so I can track down the problem. I can handle the sending the info to me but I don't know how to generate the trace string. Any ideas?

share|improve this question
    
What OS, what shell? –  Paul Tomblin Sep 16 '08 at 20:44
    
backtrace and backtrace_symbols_fd are not async-signal-safe. you should not use these function in signal handler –  Parag Bafna Jun 14 '12 at 9:08
4  
backtrace_symbols calls malloc, and so must not be used in a signal handler. The other two functions (backtrace and backtrace_symbols_fd) do not have this problem, and are commonly used in signal handlers. –  cmccabe Aug 2 '12 at 20:01
    
@cmccabe that is incorrect backtrace_symbols_fd usually does not call malloc but may if something goes wrong in its catch_error block –  Sam Saffron Dec 17 '13 at 22:24
    
It "may" in the sense that there is no POSIX spec for backtrace_symbols_fd (or any backtrace); however, GNU/Linux's backtrace_symbols_fd is specified to never call malloc, as per linux.die.net/man/3/backtrace_symbols_fd . Therefore, it is safe to assume that it will never call malloc on Linux. –  codetaku Jul 17 at 14:42

26 Answers 26

up vote 226 down vote accepted

For Linux and I believe Mac OS X, if you're using gcc, or any compiler that uses glibc, you can use the backtrace() functions in execinfo.h to print a stacktrace and exit gracefully when you get a segmentation fault. Documentation can be found in the libc manual.

Here's an example program that installs a SIGSEGV handler and prints a stacktrace to stderr when it segfaults. The baz() function here causes the segfault that triggers the handler:

#include <stdio.h>
#include <execinfo.h>
#include <signal.h>
#include <stdlib.h>
#include <unistd.h>


void handler(int sig) {
  void *array[10];
  size_t size;

  // get void*'s for all entries on the stack
  size = backtrace(array, 10);

  // print out all the frames to stderr
  fprintf(stderr, "Error: signal %d:\n", sig);
  backtrace_symbols_fd(array, size, STDERR_FILENO);
  exit(1);
}

void baz() {
 int *foo = (int*)-1; // make a bad pointer
  printf("%d\n", *foo);       // causes segfault
}

void bar() { baz(); }
void foo() { bar(); }


int main(int argc, char **argv) {
  signal(SIGSEGV, handler);   // install our handler
  foo(); // this will call foo, bar, and baz.  baz segfaults.
}

Compiling with -g -rdynamic gets you symbol info in your output, which glibc can use to make a nice stacktrace:

$ gcc -g -rdynamic ./test.c -o test

Executing this gets you this output:

$ ./test
Error: signal 11:
./test(handler+0x19)[0x400911]
/lib64/tls/libc.so.6[0x3a9b92e380]
./test(baz+0x14)[0x400962]
./test(bar+0xe)[0x400983]
./test(foo+0xe)[0x400993]
./test(main+0x28)[0x4009bd]
/lib64/tls/libc.so.6(__libc_start_main+0xdb)[0x3a9b91c4bb]
./test[0x40086a]

This shows the load module, offset, and function that each frame in the stack came from. Here you can see the signal handler on top of the stack, and the libc functions before main in addition to main, foo, bar, and baz.

share|improve this answer
27  
There's also /lib/libSegFault.so which you can use with LD_PRELOAD. –  CesarB Oct 23 '08 at 15:05
4  
It looks like the first two entries in your backtrace output contain a return address inside the signal handler and probably one inside sigaction() in libc. While your backtrace appears to be correct, I have sometimes found that additional steps are necessary to ensure the actual location of the fault appears in the backtrace as it can be overwritten with sigaction() by the kernel. –  jschmier Mar 27 '10 at 19:11
1  
I can confirm that this (the original reply) works on OS X. –  Johannes Hoff Aug 31 '11 at 9:50
3  
What would happen if the crash comes from inside malloc? Wouldn't you then hold a lock and then get stuck as "backtrace" tries to allocate memory? –  Mattias Nilsson Apr 17 '12 at 6:39
1  
You could then try some other stackwalking API, e.g.: DynInst's StackwalkerAPI dyninst.org/stackwalkerapi or nongnu.org/libunwind. Generally if you expect to walk out of stack frames or interrupt frames inside malloc, you need to do special things to handle it. Many tools use their own arena allocator to avoid conflicting with the libc malloc in situations like this. –  tgamblin Apr 18 '12 at 0:19

Linux

While the use of the backtrace() functions in execinfo.h to print a stacktrace and exit gracefully when you get a segmentation fault has already been suggested, I see no mention of the intricacies necessary to ensure the resulting backtrace points to the actual location of the fault (at least for some architectures - x86 & ARM).

The first two entries in the stack frame chain when you get into the signal handler contain a return address inside the signal handler and one inside sigaction() in libc. The stack frame of the last function called before the signal (which is the location of the fault) is lost.

Code

#ifndef _GNU_SOURCE
#define _GNU_SOURCE
#endif
#ifndef __USE_GNU
#define __USE_GNU
#endif

#include <execinfo.h>
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <ucontext.h>
#include <unistd.h>

/* This structure mirrors the one found in /usr/include/asm/ucontext.h */
typedef struct _sig_ucontext {
 unsigned long     uc_flags;
 struct ucontext   *uc_link;
 stack_t           uc_stack;
 struct sigcontext uc_mcontext;
 sigset_t          uc_sigmask;
} sig_ucontext_t;

void crit_err_hdlr(int sig_num, siginfo_t * info, void * ucontext)
{
 void *             array[50];
 void *             caller_address;
 char **            messages;
 int                size, i;
 sig_ucontext_t *   uc;

 uc = (sig_ucontext_t *)ucontext;

 /* Get the address at the time the signal was raised */
#if defined(__i386__) // gcc specific
 caller_address = (void *) uc->uc_mcontext.eip; // EIP: x86 specific
#elif defined(__x86_64__) // gcc specific
 caller_address = (void *) uc->uc_mcontext.rip; // RIP: x86_64 specific
#else
#error Unsupported architecture. // TODO: Add support for other arch.
#endif

 fprintf(stderr, "signal %d (%s), address is %p from %p\n", 
  sig_num, strsignal(sig_num), info->si_addr, 
  (void *)caller_address);

 size = backtrace(array, 50);

 /* overwrite sigaction with caller's address */
 array[1] = caller_address;

 messages = backtrace_symbols(array, size);

 /* skip first stack frame (points here) */
 for (i = 1; i < size && messages != NULL; ++i)
 {
  fprintf(stderr, "[bt]: (%d) %s\n", i, messages[i]);
 }

 free(messages);

 exit(EXIT_FAILURE);
}

int crash()
{
 char * p = NULL;
 *p = 0;
 return 0;
}

int foo4()
{
 crash();
 return 0;
}

int foo3()
{
 foo4();
 return 0;
}

int foo2()
{
 foo3();
 return 0;
}

int foo1()
{
 foo2();
 return 0;
}

int main(int argc, char ** argv)
{
 struct sigaction sigact;

 sigact.sa_sigaction = crit_err_hdlr;
 sigact.sa_flags = SA_RESTART | SA_SIGINFO;

 if (sigaction(SIGSEGV, &sigact, (struct sigaction *)NULL) != 0)
 {
  fprintf(stderr, "error setting signal handler for %d (%s)\n",
    SIGSEGV, strsignal(SIGSEGV));

  exit(EXIT_FAILURE);
 }

 foo1();

 exit(EXIT_SUCCESS);
}

Output

signal 11 (Segmentation fault), address is (nil) from 0x8c50
[bt]: (1) ./test(crash+0x24) [0x8c50]
[bt]: (2) ./test(foo4+0x10) [0x8c70]
[bt]: (3) ./test(foo3+0x10) [0x8c8c]
[bt]: (4) ./test(foo2+0x10) [0x8ca8]
[bt]: (5) ./test(foo1+0x10) [0x8cc4]
[bt]: (6) ./test(main+0x74) [0x8d44]
[bt]: (7) /lib/libc.so.6(__libc_start_main+0xa8) [0x40032e44]

All the hazards of calling the backtrace() functions in a signal handler still exist and should not be overlooked, but I find the functionality I described here quite helpful in debugging crashes.

It is important to note that the example I provided is developed/tested on Linux for x86. I have also successfully implemented this on ARM using uc_mcontext.arm_pc instead of uc_mcontext.eip.

Here's a link to the article where I learned the details for this implementation: http://www.linuxjournal.com/article/6391

share|improve this answer
9  
On systems using GNU ld, remember to compile with -rdynamic to instruct the linker to add all symbols, not only used ones, to the dynamic symbol table. This allows backtrace_symbols() to convert addresses to function names –  jschmier Mar 26 '10 at 20:00
    
The output in the example above was taken from an test program compiled using a gcc-3.4.5-glibc-2.3.6 cross-toolchain and executed on an ARMv6-based platform running Linux Kernel 2.6.22. –  jschmier May 24 '10 at 23:54
1  
Also, you need to add "-mapcs-frame" option to GCC''s command line to generate stack frames on ARM platform –  qehgt Feb 1 '12 at 15:53
1  
This may be too late but can we use addr2line command somehow to get the exact line where the crash occurred? –  enthusiasticgeek Oct 24 '12 at 18:26
2  
On more recent builds of glibc uc_mcontext does not contain a field named eip. There is now an array that needs to be indexed, uc_mcontext.gregs[REG_EIP] is the equivalent. –  mmlb Dec 14 '12 at 14:57

Even though a correct answer has been provided that describes how to use the GNU libc backtrace() function1 and I provided my own answer that describes how to ensure a backtrace from a signal handler points to the actual location of the fault2, I don't see any mention of demangling C++ symbols output from the backtrace.

When obtaining backtraces from a C++ program, the output can be run through c++filt1 to demangle the symbols or by using abi::__cxa_demangle1 directly.

  • 1 Linux & OS X Note that c++filt and __cxa_demangle are GCC specific
  • 2 Linux

The following C++ Linux example uses the same signal handler as my other answer and demonstrates how c++filt can be used to demangle the symbols.

Code:

class foo
{
public:
    foo() { foo1(); }

private:
    void foo1() { foo2(); }
    void foo2() { foo3(); }
    void foo3() { foo4(); }
    void foo4() { crash(); }
    void crash() { char * p = NULL; *p = 0; }
};

int main(int argc, char ** argv)
{
    // Setup signal handler for SIGSEGV
    ...

    foo * f = new foo();
    return 0;
}

Output (./test):

signal 11 (Segmentation fault), address is (nil) from 0x8048e07
[bt]: (1) ./test(crash__3foo+0x13) [0x8048e07]
[bt]: (2) ./test(foo4__3foo+0x12) [0x8048dee]
[bt]: (3) ./test(foo3__3foo+0x12) [0x8048dd6]
[bt]: (4) ./test(foo2__3foo+0x12) [0x8048dbe]
[bt]: (5) ./test(foo1__3foo+0x12) [0x8048da6]
[bt]: (6) ./test(__3foo+0x12) [0x8048d8e]
[bt]: (7) ./test(main+0xe0) [0x8048d18]
[bt]: (8) ./test(__libc_start_main+0x95) [0x42017589]
[bt]: (9) ./test(__register_frame_info+0x3d) [0x8048981]

Demangled Output (./test 2>&1 | c++filt):

signal 11 (Segmentation fault), address is (nil) from 0x8048e07
[bt]: (1) ./test(foo::crash(void)+0x13) [0x8048e07]
[bt]: (2) ./test(foo::foo4(void)+0x12) [0x8048dee]
[bt]: (3) ./test(foo::foo3(void)+0x12) [0x8048dd6]
[bt]: (4) ./test(foo::foo2(void)+0x12) [0x8048dbe]
[bt]: (5) ./test(foo::foo1(void)+0x12) [0x8048da6]
[bt]: (6) ./test(foo::foo(void)+0x12) [0x8048d8e]
[bt]: (7) ./test(main+0xe0) [0x8048d18]
[bt]: (8) ./test(__libc_start_main+0x95) [0x42017589]
[bt]: (9) ./test(__register_frame_info+0x3d) [0x8048981]

The following builds on the signal handler from my original answer and can replace the signal handler in the above example to demonstrate how abi::__cxa_demangle can be used to demangle the symbols. This signal handler produces the same demangled output as the above example.

Code:

void crit_err_hdlr(int sig_num, siginfo_t * info, void * ucontext)
{
    sig_ucontext_t * uc = (sig_ucontext_t *)ucontext;

    void * caller_address = (void *) uc->uc_mcontext.eip; // x86 specific

    std::cerr << "signal " << sig_num 
              << " (" << strsignal(sig_num) << "), address is " 
              << info->si_addr << " from " << caller_address 
              << std::endl << std::endl;

    void * array[50];
    int size = backtrace(array, 50);

    array[1] = caller_address;

    char ** messages = backtrace_symbols(array, size);    

    // skip first stack frame (points here)
    for (int i = 1; i < size && messages != NULL; ++i)
    {
        char *mangled_name = 0, *offset_begin = 0, *offset_end = 0;

        // find parantheses and +address offset surrounding mangled name
        for (char *p = messages[i]; *p; ++p)
        {
            if (*p == '(') 
            {
                mangled_name = p; 
            }
            else if (*p == '+') 
            {
                offset_begin = p;
            }
            else if (*p == ')')
            {
                offset_end = p;
                break;
            }
        }

        // if the line could be processed, attempt to demangle the symbol
        if (mangled_name && offset_begin && offset_end && 
            mangled_name < offset_begin)
        {
            *mangled_name++ = '\0';
            *offset_begin++ = '\0';
            *offset_end++ = '\0';

            int status;
            char * real_name = abi::__cxa_demangle(mangled_name, 0, 0, &status);

            // if demangling is successful, output the demangled function name
            if (status == 0)
            {    
                std::cerr << "[bt]: (" << i << ") " << messages[i] << " : " 
                          << real_name << "+" << offset_begin << offset_end 
                          << std::endl;

            }
            // otherwise, output the mangled function name
            else
            {
                std::cerr << "[bt]: (" << i << ") " << messages[i] << " : " 
                          << mangled_name << "+" << offset_begin << offset_end 
                          << std::endl;
            }
            free(real_name);
        }
        // otherwise, print the whole line
        else
        {
            std::cerr << "[bt]: (" << i << ") " << messages[i] << std::endl;
        }
    }
    std::cerr << std::endl;

    free(messages);

    exit(EXIT_FAILURE);
}
share|improve this answer
    
Thank you for this, jschmier. I created a little bash script to feed the output of this into the addr2line utility. See: stackoverflow.com/a/15801966/1797414 –  arr_sea Apr 5 '13 at 19:02
1  
Don't forget to #include <cxxabi.h> –  Bamaco Jul 7 at 19:52

It's even easier than "man backtrace", there's a little-documented library (GNU specific) distributed with glibc as libSegFault.so, which was I believe was written by Ulrich Drepper to support the program catchsegv (see "man catchsegv").

This gives us 3 possibilities. Instead of running "program -o hai":

  1. Run within catchsegv:

    $ catchsegv program -o hai
    
  2. Link with libSegFault at runtime:

    $ LD_PRELOAD=/lib/libSegFault.so program -o hai
    
  3. Link with libSegFault at compile time:

    $ gcc -g1 -lSegFault -o program program.cc
    $ program -o hai
    

In all 3 cases, you will get clearer backtraces with less optimization (gcc -O0 or -O1) and debugging symbols (gcc -g). Otherwise, you may just end up with a pile of memory addresses.

You can also catch more signals for stack traces with something like:

$ export SEGFAULT_SIGNALS="all"       # "all" signals
$ export SEGFAULT_SIGNALS="bus abrt"  # SIGBUS and SIGABRT

The output will look something like this (notice the backtrace at the bottom):

* Segmentation fault Register dump:

EAX: 0000000c EBX: 00000080 ECX: 00000000 EDX: 0000000c ESI: bfdbf080 EDI: 080497e0 EBP: bfdbee38 ESP: bfdbee20

EIP: 0805640f EFLAGS: 00010282

CS: 0073 DS: 007b ES: 007b FS: 0000 GS: 0033 SS: 007b

Trap: 0000000e Error: 00000004
OldMask: 00000000 ESP/signal: bfdbee20 CR2: 00000024

FPUCW: ffff037f FPUSW: ffff0000
TAG: ffffffff IPOFF: 00000000
CSSEL: 0000 DATAOFF: 00000000
DATASEL: 0000

ST(0) 0000 0000000000000000 ST(1) 0000 0000000000000000 ST(2) 0000 0000000000000000 ST(3) 0000 0000000000000000 ST(4) 0000 0000000000000000 ST(5) 0000 0000000000000000 ST(6) 0000 0000000000000000 ST(7) 0000 0000000000000000

Backtrace: /lib/libSegFault.so[0xb7f9e100] ??:0(??)[0xb7fa3400] /usr/include/c++/4.3/bits/stl_queue.h:226(_ZNSt5queueISsSt5dequeISsSaISsEEE4pushERKSs)[0x805647a] /home/dbingham/src/middle-earth-mud/alpha6/src/engine/player.cpp:73(_ZN6Player5inputESs)[0x805377c] /home/dbingham/src/middle-earth-mud/alpha6/src/engine/socket.cpp:159(_ZN6Socket4ReadEv)[0x8050698] /home/dbingham/src/middle-earth-mud/alpha6/src/engine/socket.cpp:413(_ZN12ServerSocket4ReadEv)[0x80507ad] /home/dbingham/src/middle-earth-mud/alpha6/src/engine/socket.cpp:300(ZN12ServerSocket4pollEv)[0x8050b44] /home/dbingham/src/middle-earth-mud/alpha6/src/engine/main.cpp:34(main)[0x8049a72] /lib/tls/i686/cmov/libc.so.6(_libc_start_main+0xe5)[0xb7d1b775] /build/buildd/glibc-2.9/csu/../sysdeps/i386/elf/start.S:122(_start)[0x8049801]

If you want to know the gory details, the best source is unfortunately the source: See http://sourceware.org/git/?p=glibc.git;a=blob;f=debug/segfault.c and its parent directory http://sourceware.org/git/?p=glibc.git;a=tree;f=debug

share|improve this answer
    
"Possibility 3. Link with libSegFault at compile time" does not work. –  Hans Kratz Jan 23 '13 at 18:05
2  
@crafter: What do you mean "does not work". What have you tried, on what language/compiler/toolchain/distribution/hardware ? Did it fail to compile ? To catch error ? To produce output at all ? To produce hard-to-use output ? Thank you for details it will help everyone. –  Stéphane Gourichon Mar 31 at 9:33
    
'best source is unfortunately the source' ... Hopefully, some day, the man page for catchsegv will actually mention SEGFAULT_SIGNALS. Until then, there's this answer to refer to. –  greggo Jul 3 at 16:06

Might be worth looking at Google Breakpad, a cross-platform crash dump generator and tools to process the dumps.

share|improve this answer

You did not specify your operating system, so this is difficult to answer. If you are using a system based on gnu libc, you might be able to use the libc function backtrace().

GCC also has two builtins that can assist you, but which may or may not be implemented fully on your architecture, and those are __builtin_frame_address and __builtin_return_address. Both of which want an immediate integer level (by immediate, I mean it can't be a variable). If __builtin_frame_address for a given level is non-zero, it should be safe to grab the return address of the same level.

share|improve this answer

ulimit -c <value> sets the core file size limit on unix. By default, the core file size limit is 0. You can see your ulimit values with ulimit -a.

also, if you run your program from within gdb, it will halt your program on "segmentation violations" (SIGSEGV, generally when you accessed a piece of memory that you hadn't allocated) or you can set breakpoints.

ddd and nemiver are front-ends for gdb which make working with it much easier for the novice.

share|improve this answer
5  
Core dumps are infinitely more useful than stack traces because you can load the core dump in the debugger and see the state of the whole program and its data at the point of the crash. –  Adam Hawes Feb 4 '09 at 13:07
1  
The backtrace facility that others have suggested is probably better than nothing, but it is very basic -- it doesn't even give line numbers. Using core dumps, on the other hand, let's you retroactively view the entire state of your application at the time it crashed (including a detailed stack trace). There might be practical issues with trying to use this for field debugging, but it is definitely a more powerful tool for analyzing crashes and asserts during development (at least on Linux). –  nobar Oct 26 '10 at 13:36

Ive been looking at this problem for a while.

And buried deep in the Google Performance Tools README

http://code.google.com/p/google-perftools/source/browse/trunk/README

talks about libunwind

http://www.nongnu.org/libunwind/

Would love to hear opinions of this library.

The problem with -rdynamic is that it can increase the size of the binary relatively significantly in some cases

share|improve this answer
1  
On x86/64, I have not seen -rdynamic increase binary size much. Adding -g makes for a much bigger increase. –  Dan Mar 24 '10 at 6:46

Some versions of libc contain functions that deal with stack traces; you might be able to use them:

http://www.gnu.org/software/libc/manual/html_node/Backtraces.html

I remember using libunwind a long time ago to get stack traces, but it may not be supported on your platform.

share|improve this answer

It's important to note that once you generate a core file you'll need to use the gdb tool to look at it. For gdb to make sense of your core file, you must tell gcc to instrument the binary with debugging symbols: to do this, you compile with the -g flag:

$ g++ -g prog.cpp -o prog

Then, you can either set "ulimit -c unlimited" to let it dump a core, or just run your program inside gdb. I like the second approach more:

$ gdb ./prog
... gdb startup output ...
(gdb) run
... program runs and crashes ...
(gdb) where
... gdb outputs your stack trace ...

I hope this helps.

share|improve this answer
3  
You can also call gdb right from your crashing program. Setup handler for SIGSEGV, SEGILL, SIGBUS, SIGFPE that will call gdb. Details: stackoverflow.com/questions/3151779/… The advantage is that you get beautiful, annotated backtrace like in bt full, also you can get stack traces of all threads. –  Vi. Jun 30 '10 at 22:20

You can use DeathHandler - small C++ class which does everything for you, reliable.

share|improve this answer
    
The best shows line numbers (correct line numbers) –  Gelldur Jun 21 '13 at 7:29
    
unfortunately it uses execlp() to perform addr2line calls... would be nice to fully stay in the own program (which is possible by including the addr2line code in some form) –  example Aug 26 at 14:39

Thank you to enthusiasticgeek for drawing my attention to the addr2line utility.

I've written a quick and dirty script to process the output of the answer provided here: (much thanks to jschmier!) using the addr2line utility.

The script accepts a single argument: The name of the file containing the output from jschmier's utility.

The output should print something like the following for each level of the trace:

BACKTRACE:  testExe 0x8A5db6b
FILE:       pathToFile/testExe.C:110
FUNCTION:   testFunction(int) 
   107  
   108           
   109           int* i = 0x0;
  *110           *i = 5;
   111      
   112        }
   113        return i;

Code:

#!/bin/bash

LOGFILE=$1

NUM_SRC_CONTEXT_LINES=3

old_IFS=$IFS  # save the field separator           
IFS=$'\n'     # new field separator, the end of line           

for bt in `cat $LOGFILE | grep '\[bt\]'`; do
   IFS=$old_IFS     # restore default field separator 
   printf '\n'
   EXEC=`echo $bt | cut -d' ' -f3 | cut -d'(' -f1`  
   ADDR=`echo $bt | cut -d'[' -f3 | cut -d']' -f1`
   echo "BACKTRACE:  $EXEC $ADDR"
   A2L=`addr2line -a $ADDR -e $EXEC -pfC`
   #echo "A2L:        $A2L"

   FUNCTION=`echo $A2L | sed 's/\<at\>.*//' | cut -d' ' -f2-99`
   FILE_AND_LINE=`echo $A2L | sed 's/.* at //'`
   echo "FILE:       $FILE_AND_LINE"
   echo "FUNCTION:   $FUNCTION"

   # print offending source code
   SRCFILE=`echo $FILE_AND_LINE | cut -d':' -f1`
   LINENUM=`echo $FILE_AND_LINE | cut -d':' -f2`
   if ([ -f $SRCFILE ]); then
      cat -n $SRCFILE | grep -C $NUM_SRC_CONTEXT_LINES "^ *$LINENUM\>" | sed "s/ $LINENUM/*$LINENUM/"
   else
      echo "File not found: $SRCFILE"
   fi
   IFS=$'\n'     # new field separator, the end of line           
done

IFS=$old_IFS     # restore default field separator 
share|improve this answer
ulimit -c unlimited

is a system variable, wich will allow to create a core dump after your application crashes. In this case an unlimited amount. Look for a file called core in the very same directory. Make sure you compiled your code with debugging informations enabled!

regards

share|improve this answer
2  
The user is not asking for a core dump. He's asking for a stack trace. See delorie.com/gnu/docs/glibc/libc_665.html –  tgamblin Sep 16 '08 at 20:54
1  
a core dump will contain the call stack at the moment of the crash, won't it? –  Mo. Sep 16 '08 at 20:57
3  
You're assuming he's on Unix, and using Bash. –  Paul Tomblin Sep 16 '08 at 20:58
2  
If you are using tcsh, you have to do limit coredumpsize unlimited –  ShaChris23 Nov 10 '10 at 19:46

Look at:

man 3 backtrace

And:

#include <exeinfo.h>
int backtrace(void **buffer, int size);

These are GNU extensions.

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1  
There may be additional examples to help out on this page I created a while back: charette.no-ip.com:81/programming/2010-01-25_Backtrace –  Stéphane Oct 10 '10 at 7:05

I can help with the Linux version: the function backtrace, backtrace_symbols and backtrace_symbols_fd can be used. See the corresponding manual pages.

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win: How about StackWalk64 http://msdn.microsoft.com/en-us/library/ms680650.aspx

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See the Stack Trace facility in ACE (ADAPTIVE Communication Environment). It's already written to cover all major platforms (and more). The library is BSD-style licensed so you can even copy/paste the code if you don't want to use ACE.

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  • Compile your code using the -g flag to include debug symbols in the binary.
  • Set up your system so that it core files are produced when applications crash (e.g. ulimit -c unlimited).
  • When an application crashes, you can use the core file in a debugger (such as gdb, by running, for example, gdb ./core) to get a backtrace (gdb command: bt).

Note that C++ symbol names are sometimes pretty garbled and the backtrace will probably be somewhat incomprehensible.

More helpful backtraces will probably need evil trickery (one solution I've heard of requires that you add a special macro to the beginning of all methods that you write).

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3  
Missing the point of the question. –  Jonathan Leffler Oct 3 '08 at 17:37
    
Also, gdb ./core will make gdb think the core file is an executable, the correct syntax is –  user451498 Jul 23 '13 at 5:18
    
@LukeSanAntonio - gdb --core=./core :) –  kerim Aug 14 '13 at 19:52
    
@kerim Nice catch! I can't believe I forgot to write it in, thank you! =D - That's embarrassing... –  user451498 Aug 14 '13 at 22:09
    
There's also gdb <executable> <core-file> That's what I think I was going to say! –  user451498 Aug 14 '13 at 22:15

I would use the code that generates a stack trace for leaked memory in Visual Leak Detector. This only works on Win32, though.

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*nix: you can intercept SIGSEGV (usualy this signal is raised before crashing) and keep the info into a file. (besides the core file which you can use to debug using gdb for example).

win: Check this from msdn.

You can also look at the google's chrome code to see how it handles crashes. It has a nice exception handling mechanism.

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If your program crashes, it's the operating system itself that generates crash dump information. If you're using a *nix OS, you simply need to not prevent it from doing so (check out the ulimit command's 'coredump' options).

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In addition to above answers, here how you make Debian Linux OS generate core dump

  1. Create a “coredumps” folder in the user's home folder
  2. Go to /etc/security/limits.conf. Below the ' ' line, type “ soft core unlimited”, and “root soft core unlimited” if enabling core dumps for root, to allow unlimited space for core dumps.
  3. NOTE: “* soft core unlimited” does not cover root, which is why root has to be specified in its own line.
  4. To check these values, log out, log back in, and type “ulimit -a”. “Core file size” should be set to unlimited.
  5. Check the .bashrc files (user, and root if applicable) to make sure that ulimit is not set there. Otherwise, the value above will be overwritten on startup.
  6. Open /etc/sysctl.conf. Enter the following at the bottom: “kernel.core_pattern = /home//coredumps/%e_%t.dump”. (%e will be the process name, and %t will be the system time)
  7. Exit and type “sysctl -p” to load the new configuration Check /proc/sys/kernel/core_pattern and verify that this matches what you just typed in.
  8. Core dumping can be tested by running a process on the command line (“ &”), and then killing it with “kill -11 ”. If core dumping is successful, you will see “(core dumped)” after the segmentation fault indication.
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On Linux/unix/MacOSX use core files (you can enable them with ulimit or compatible system call). On Windows use Microsoft error reporting (you can become a partner and get access to your application crash data).

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I forgot about the GNOME tech of "apport", but I don't know much about using it. It is used to generate stacktraces and other diagnostics for processing and can automatically file bugs. It's certainly worth checking in to.

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I have seen a lot of answers here performing a signal handler and then exiting. That's the way to go, but remember a very important fact: If you want to get the core dump for the generated error, you can't call exit(status). Call abort() instead!

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I found that @tgamblin solution is not complete. It cannot handle with stackoverflow. I think because by default signal handler is called with the same stack and SIGSEGV is thrown twice. To protect you need register an independent stack for the signal handler.

You can check this with code below. By default the handler fails. With defined macro STACK_OVERFLOW it's all right.

#include <iostream>
#include <execinfo.h>
#include <signal.h>
#include <stdlib.h>
#include <unistd.h>
#include <string>
#include <cassert>

using namespace std;

//#define STACK_OVERFLOW

#ifdef STACK_OVERFLOW
static char stack_body[64*1024];
static stack_t sigseg_stack;
#endif

static struct sigaction sigseg_handler;

void handler(int sig) {
  cerr << "sig seg fault handler" << endl;
  const int asize = 10;
  void *array[asize];
  size_t size;

  // get void*'s for all entries on the stack
  size = backtrace(array, asize);

  // print out all the frames to stderr
  cerr << "stack trace: " << endl;
  backtrace_symbols_fd(array, size, STDERR_FILENO);
  cerr << "resend SIGSEGV to get core dump" << endl;
  signal(sig, SIG_DFL);
  kill(getpid(), sig);
}

void foo() {
  foo();
}

int main(int argc, char **argv) {
#ifdef STACK_OVERFLOW
  sigseg_stack.ss_sp = stack_body;
  sigseg_stack.ss_flags = SS_ONSTACK;
  sigseg_stack.ss_size = sizeof(stack_body);
  assert(!sigaltstack(&sigseg_stack, nullptr));
  sigseg_handler.sa_flags = SA_ONSTACK;
#else
  sigseg_handler.sa_flags = SA_RESTART;  
#endif
  sigseg_handler.sa_handler = &handler;
  assert(!sigaction(SIGSEGV, &sigseg_handler, nullptr));
  cout << "sig action set" << endl;
  foo();
  return 0;
} 
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