I need to catch segmentation fault in third party library cleanup operations. This happens sometimes just before my program exits, and I cannot fix the real reason of this. In Windows programming I could do this with __try - __catch. Is there cross-platform or platform-specific way to do the same? I need this in Linux, gcc.

  • Segmentation fault is always caused by a bug that could be really difficult to catch. I just find one that appears randomly. Each file has 500 million data points. Roughly about every 10-15 files, this segmentation fault appears. I was using multi-threading, lock-free queue, etc. Quite complicated job management. In the end it is an object I created, the std::moved() into another data structure. Locally I was using this object after the move. For some reason, C++ is OK with this. But the segfault will show up for sure at some point. – Kemin Zhou Nov 22 '18 at 7:28

On Linux we can have these as exceptions, too.

Normally, when your program performs a segmentation fault, it is sent a SIGSEGV signal. You can set up your own handler for this signal and mitigate the consequences. Of course you should really be sure that you can recover from the situation. In your case, I think, you should debug your code instead.

Back to the topic. I recently encountered a library (short manual) that transforms such signals to exceptions, so you can write code like this:

    *(int*) 0 = 0;
catch (std::exception& e)
    std::cerr << "Exception caught : " << e.what() << std::endl;

Didn't check it, though. Works on my x86-64 Gentoo box. It has a platform-specific backend (borrowed from gcc's java implementation), so it can work on many platforms. It just supports x86 and x86-64 out of the box, but you can get backends from libjava, which resides in gcc sources.

  • 16
    +1 for be sure that you can recover before catching sig segfault – Henrik Mühe Feb 2 '14 at 10:29
  • 17
    Throwing from a signal handler is a very dangerous thing to do. Most compilers assume that only calls can generate exceptions, and set up unwind information accordingly. Languages that transform hardware exceptions into software exceptions, like Java and C#, are aware that anything can throw; this is not the case with C++. With GCC, you at least need -fnon-call-exceptions to ensure that it works–and there is a performance cost to that. There is also a danger that you'll be throwing from a function without exception support (like a C function) and leak/crash later. – zneak Jun 4 '15 at 3:19
  • 1
    I agree with zneak. Don't throw from a signal handler. – MM. Aug 12 '15 at 16:31
  • The library is now in github.com/Plaristote/segvcatch, but I couldn't find the manual or compile it. ./build_gcc_linux_release gives several errors. – alfC Dec 23 '16 at 0:07
  • Yay! Now I know I'm not the only Gentoo user in the world! – S.S. Anne Sep 2 '19 at 16:55

Here's an example of how to do it in C.

#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>

void segfault_sigaction(int signal, siginfo_t *si, void *arg)
    printf("Caught segfault at address %p\n", si->si_addr);

int main(void)
    int *foo = NULL;
    struct sigaction sa;

    memset(&sa, 0, sizeof(struct sigaction));
    sa.sa_sigaction = segfault_sigaction;
    sa.sa_flags   = SA_SIGINFO;

    sigaction(SIGSEGV, &sa, NULL);

    /* Cause a seg fault */
    *foo = 1;

    return 0;
  • 9
    sizeof(sigaction) ==> sizeof(struct sigaction), or else you get an ISO C++ error compiling the thing. – Dave Dopson Dec 20 '11 at 2:35
  • 7
    Doing IO in a signal handler is a recipe for disaster. – Tim Seguine Nov 6 '16 at 20:33
  • 6
    @TimSeguine: that's is not true. You just need to make sure you know what you are doing. signal(7) lists all async-signal-safe functions that can be used with relatively little care. In the example above it is also completely safe because nothing else in the program is touching stdout but the printf call in the handler. – stefanct Nov 17 '17 at 11:28
  • 3
    @stefanct This is a toy example. Virtually any non-toy program is going to hold the lock on stdout at some point. With this signal handler, the worst that can probably happen is a deadlock on segfault, but that can be bad enough if you currently have no mechanism to kill rogue processes in your use case. – Tim Seguine Nov 17 '17 at 11:50
  • 3
    according to 2.4.3 Signal Actions, calling printf from within a signal handler which is called as a result of an illegal indirection, whether the program is multithreaded or not is just plain undefined behavior period. – Julien Villemure-Fréchette Nov 22 '18 at 22:42

For portability, one should probably use std::signal from the standard C++ library, but there is a lot of restriction on what a signal handler can do. Unfortunately, it is not possible to catch a SIGSEGV from within a C++ program without introducing undefined behavior because the specification says:

  1. it is undefined behavior to call any library function from within the handler other than a very narrow subset of the standard library functions (abort, exit, some atomic functions, reinstall current signal handler, memcpy, memmove, type traits, `std::move, std::forward, and some more).
  2. it is undefined behavior if handler use a throw expression.
  3. it is undefined behavior if the handler returns when handling SIGFPE, SIGILL, SIGSEGV

This proves that it is impossible to catch SIGSEGV from within a program using strictly standard and portable C++. SIGSEGV is still caught by the operating system and is normally reported to the parent process when a wait family function is called.

You will probably run into the same kind of trouble using POSIX signal because there is a clause that says in 2.4.3 Signal Actions:

The behavior of a process is undefined after it returns normally from a signal-catching function for a SIGBUS, SIGFPE, SIGILL, or SIGSEGV signal that was not generated by kill(), sigqueue(), or raise().

A word about the longjumps. Assuming we are using POSIX signals, using longjump to simulate stack unwinding won't help:

Although longjmp() is an async-signal-safe function, if it is invoked from a signal handler which interrupted a non-async-signal-safe function or equivalent (such as the processing equivalent to exit() performed after a return from the initial call to main()), the behavior of any subsequent call to a non-async-signal-safe function or equivalent is undefined.

This means that the continuation invoked by the call to longjump cannot reliably call usually useful library function such as printf, malloc or exit or return from main without inducing undefined behavior. As such, the continuation can only do a restricted operations and may only exit through some abnormal termination mechanism.

To put things short, catching a SIGSEGV and resuming execution of the program in a portable is probably infeasible without introducing UB. Even if you are working on a Windows platform for which you have access to Structured exception handling, it is worth mentioning that MSDN suggest to never attempt to handle hardware exceptions: Hardware Exceptions

  • SIGSEGV is hardly a hardware exception, though. One could always use a parent-child architecture where the parent is able to detect the case of a child that got killed by the kernel and use IPC to share relevant program state in order to resume where we left of. I believe modern browsers can be seen this way, as they use IPC mechanisms to communicate with that one process per browser tab. Obviously the security boundary between processes is a bonus in the browser scenario. – 0xC0000022L Nov 6 '20 at 11:26

C++ solution found here (http://www.cplusplus.com/forum/unices/16430/)

#include <signal.h>
#include <stdio.h>
#include <unistd.h>
void ouch(int sig)
    printf("OUCH! - I got signal %d\n", sig);
int main()
    struct sigaction act;
    act.sa_handler = ouch;
    act.sa_flags = 0;
    sigaction(SIGINT, &act, 0);
    while(1) {
        printf("Hello World!\n");
  • 7
    I know this is just an example that you didn't write, but doing IO in a signal handler is a recipe for disaster. – Tim Seguine Nov 6 '16 at 20:32
  • 3
    @TimSeguine: repeating stuff that is at best very misleading is not a good idea (cf. stackoverflow.com/questions/2350489/…) – stefanct Nov 17 '17 at 11:29
  • 3
    @stefanct The precautions necessary in order to use printf safely in a signal handler are not trivial. There is nothing misleading about that. This is a toy example. And even in this toy example it is possible to deadlock if you time the SIGINT right. Deadlocks are dangerous precisely BECAUSE they are rare. If you think this advice was misleading, then stay away from my code, because I don't trust you within a mile of it. – Tim Seguine Nov 17 '17 at 11:54
  • Again, you were talking about I/O in general here. Instead of pointing out the problem with this actual example, which IS a bad one indeed. – stefanct Nov 24 '17 at 10:52
  • 1
    @stefanct If you want to nitpick and ignore the context of the statement, then that is your problem. Who said I was talking about I/O in general? You. I just have a major problem with people posting toy answers to difficult problems. Even in the case you use async safe functions, there is still a lot to think about and this answer makes it seem like it is trivial. – Tim Seguine Nov 26 '17 at 14:43

Sometimes we want to catch a SIGSEGV to find out if a pointer is valid, that is, if it references a valid memory address. (Or even check if some arbitrary value may be a pointer.)

One option is to check it with isValidPtr() (worked on Android):

int isValidPtr(const void*p, int len) {
    if (!p) {
    return 0;
    int ret = 1;
    int nullfd = open("/dev/random", O_WRONLY);
    if (write(nullfd, p, len) < 0) {
    ret = 0;
    /* Not OK */
    return ret;
int isValidOrNullPtr(const void*p, int len) {
    return !p||isValidPtr(p, len);

Another option is to read the memory protection attributes, which is a bit more tricky (worked on Android):


#include <errno.h>
#include <malloc.h>
//#define PAGE_SIZE 4096
#include "dlog.h"
#include "stdlib.h"
#include "re_mprot.h"

struct buffer {
    int pos;
    int size;
    char* mem;

char* _buf_reset(struct buffer*b) {
    b->mem[b->pos] = 0;
    b->pos = 0;
    return b->mem;

struct buffer* _new_buffer(int length) {
    struct buffer* res = malloc(sizeof(struct buffer)+length+4);
    res->pos = 0;
    res->size = length;
    res->mem = (void*)(res+1);
    return res;

int _buf_putchar(struct buffer*b, int c) {
    b->mem[b->pos++] = c;
    return b->pos >= b->size;

void show_mappings(void)
    int a;
    FILE *f = fopen("/proc/self/maps", "r");
    struct buffer* b = _new_buffer(1024);
    while ((a = fgetc(f)) >= 0) {
    if (_buf_putchar(b,a) || a == '\n') {
        DLOG("/proc/self/maps: %s",_buf_reset(b));
    if (b->pos) {
    DLOG("/proc/self/maps: %s",_buf_reset(b));

unsigned int read_mprotection(void* addr) {
    int a;
    unsigned int res = MPROT_0;
    FILE *f = fopen("/proc/self/maps", "r");
    struct buffer* b = _new_buffer(1024);
    while ((a = fgetc(f)) >= 0) {
    if (_buf_putchar(b,a) || a == '\n') {
        char*end0 = (void*)0;
        unsigned long addr0 = strtoul(b->mem, &end0, 0x10);
        char*end1 = (void*)0;
        unsigned long addr1 = strtoul(end0+1, &end1, 0x10);
        if ((void*)addr0 < addr && addr < (void*)addr1) {
            res |= (end1+1)[0] == 'r' ? MPROT_R : 0;
            res |= (end1+1)[1] == 'w' ? MPROT_W : 0;
            res |= (end1+1)[2] == 'x' ? MPROT_X : 0;
            res |= (end1+1)[3] == 'p' ? MPROT_P
                 : (end1+1)[3] == 's' ? MPROT_S : 0;
    return res;

int has_mprotection(void* addr, unsigned int prot, unsigned int prot_mask) {
    unsigned prot1 = read_mprotection(addr);
    return (prot1 & prot_mask) == prot;

char* _mprot_tostring_(char*buf, unsigned int prot) {
    buf[0] = prot & MPROT_R ? 'r' : '-';
    buf[1] = prot & MPROT_W ? 'w' : '-';
    buf[2] = prot & MPROT_X ? 'x' : '-';
    buf[3] = prot & MPROT_S ? 's' : prot & MPROT_P ? 'p' :  '-';
    buf[4] = 0;
    return buf;


#include <alloca.h>
#include "re_bits.h"
#include <sys/mman.h>

void show_mappings(void);

enum {
    MPROT_0 = 0, // not found at all
    MPROT_R = PROT_READ,                                 // readable
    MPROT_W = PROT_WRITE,                                // writable
    MPROT_X = PROT_EXEC,                                 // executable
    MPROT_P = MPROT_S<<1,                                // private

// returns a non-zero value if the address is mapped (because either MPROT_P or MPROT_S will be set for valid addresses)
unsigned int read_mprotection(void* addr);

// check memory protection against the mask
// returns true if all bits corresponding to non-zero bits in the mask
// are the same in prot and read_mprotection(addr)
int has_mprotection(void* addr, unsigned int prot, unsigned int prot_mask);

// convert the protection mask into a string. Uses alloca(), no need to free() the memory!
#define mprot_tostring(x) ( _mprot_tostring_( (char*)alloca(8) , (x) ) )
char* _mprot_tostring_(char*buf, unsigned int prot);

PS DLOG() is printf() to the Android log. FIRST_UNUSED_BIT() is defined here.

PPS It may not be a good idea to call alloca() in a loop -- the memory may be not freed until the function returns.

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