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We have a bug in a production system, where a process segfaults while holding a shared memory mutex. We'd like it to release the lock when dying. We use sem_wait()/sem_post(), but doing my homework, I've found that this API does not allow for such a behavior:


The answer, the article says, is using the robust pthreads API. I've found the following article about this topic:


But, having implemented the following code, I'm having an unreliable behavior, that is, should I tell process 3, for instance, to segfault, the code works just fine. The other processes wake up, recognize that a process died while holding the mutex, and recover. However, should I tell process 0 to die, or should I remove the sleep call on line 63, the other processes do not wake up once the failling process kills itself. Am I doing something wrong?

#include <stdio.h>
#include <stdlib.h>
#include <features.h>
#define __USE_POSIX
#include <signal.h>
#include <sys/types.h>
#include <unistd.h>
#define __USE_MISC
#include <sys/mman.h>
#include <fcntl.h>
#include <errno.h>
#define __USE_GNU   /* Necessario para usar a API PTHREAD_MUTEX_ROBUST_NP */
#define __USE_UNIX98 /* Necessario para usar a funcao pthread_mutexattr_settype */
#include <pthread.h>
#include <sys/wait.h>
static void *shrd;

static int child_main(int slot, int segfault) {
    pthread_mutex_t   *lock = (pthread_mutex_t *) shrd;
    int                err;

    if ( 0 != (err=pthread_mutex_lock(lock)) ) {
        switch(err) {
        case EINVAL:
            printf("Lock invalido no filho [%d]\n", slot);
            goto excecao; 

        case EDEADLK:
            printf("O filho [%d] tentou travar um lock que jah possui.\n", slot);

        case EOWNERDEAD:
            printf("Filho [%d] foi informado que o processo que estava com o lock morreu.\n", slot);
            if ( 0 == pthread_mutex_consistent_np(lock) ) {
                printf("Filho [%d] retornou o lock para um estado consistente.\n", slot);
            } else {
                fprintf(stderr, "Nao foi possivel retornar o lock a um estado consistente.\n");
                goto desistir;

            if ( 0 != (err=pthread_mutex_lock(lock)) ) {
                fprintf(stderr, "Apos recuperar o estado do lock, nao foi possivel trava-lo: %d\n", err);
                goto desistir;

            printf("O filho [%d] foi informado de que o lock estah permanentemente em estado inconsistente.\n", slot);
            goto desistir;

            printf("Erro desconhecido ao tentar travar o lock no filho [%d]: [%d]\n", slot, err);
            goto excecao; 

    printf("Filho [%d] adquiriu o lock.\n", slot);

    if ( segfault == slot ) {
        printf("Matando o PID [%d] com SIGSEGV.\n", getpid());
        kill(getpid(), SIGSEGV); 
    } else {

    if ( 0 != (err = pthread_mutex_unlock(lock)) ) {
        switch (err) {
        case EPERM:
            printf("O filho [%d] tentou liberar o lock, mas nao o possui.\n", slot);

            fprintf(stderr, "Erro inesperado ao liberar o lock do filho [%d]: [%d]\n", slot, err);
    } else {
        printf("Filho [%d] retornou o lock.\n", slot);

    return 0;

    fprintf(stderr, "Programa terminado devido excecao.\n");
    return 1;

    fprintf(stderr, "A execucao do sistema nao deve prosseguir. Abortando todos os processos.\n");
    kill(0, SIGTERM);

    /* unreachable */
    return 1;

int main(int argc, const char * const argv[]) {
    pid_t               filhos[10];
    int                 status;
    pid_t               p;
    int                 segfault = -1;
    pthread_mutexattr_t attrs;

    if ( argc > 1 ) {
        segfault = atoi(argv[1]);
        if ( segfault < 0 || segfault > 9 )
            segfault = -1;

    if ( (shrd = mmap(NULL, sizeof(pthread_mutex_t), PROT_READ | PROT_WRITE, MAP_SHARED | MAP_ANONYMOUS, -1, 0)) == MAP_FAILED ) {
        perror("Erro ao criar shrd mem:\n");

    pthread_mutexattr_init         (&attrs);
    pthread_mutexattr_settype      (&attrs, PTHREAD_MUTEX_RECURSIVE_NP);
    pthread_mutexattr_setrobust_np (&attrs, PTHREAD_MUTEX_ROBUST_NP);
    pthread_mutexattr_setpshared   (&attrs, PTHREAD_PROCESS_SHARED);
        Devido a um BUG na glibc 2.5 (que eh a usada pelo CentOS 5,
        a unica forma de fazer os mutexes robustos funcionarem eh
        setando o protocolo para PTHREAD_PRIO_INHERIT:
    pthread_mutexattr_setprotocol  (&attrs, PTHREAD_PRIO_INHERIT);
    pthread_mutex_init             ((pthread_mutex_t*) shrd, &attrs);
    pthread_mutexattr_destroy      (&attrs);

    for (size_t i=0; i<sizeof(filhos)/sizeof(pid_t); ++i) {
        if ( (filhos[i]=fork()) == 0 ) {
            return child_main((int) i, segfault);
        } else {
            if ( filhos[i] < 0 ) {
                fprintf(stderr, "Erro ao criar o filho [%zu]. Abortando.\n", i);

    for (size_t i=0; i<sizeof(filhos)/sizeof(pid_t); ++i) {
        do {
            p = waitpid(filhos[i], &status, 0);
        } while (p != -1);

    printf("Pai encerrou a sua execucao.\n");

    return 0;

BTW: I'm compiling on CentOS 5, 64 bits:

$ uname -rm
2.6.18-194.el5 x86_64

(Sorry, the sentences and comments on the code are in portuguese, my native language.)

share|improve this question

2 Answers 2

I've tried some other approaches, namely: 1. Using POSIX barriers 2. Having the parent holding the lock while forking() and releasing it after each child incremented a counter.

The first approach did not work at all, but I’m publishing the source code I used, as I might have made some mistake using the API:

On child_main:

pthread_barrier_t *barr = (pthread_barrier_t *) ((char *) shrd + sizeof(pthread_mutex_t));
int rc = pthread_barrier_wait(barr);
   printf("Nao foi possivel esperar na barreira.\n");

On main:

pthread_barrierattr_t   barr_attrs;
pthread_barrier_t      *barr;
initialize(pthread_barrierattr_init,       &barr_attrs);
initialize(pthread_barrierattr_setpshared, &barr_attrs, PTHREAD_PROCESS_SHARED);
barr = (pthread_barrier_t *) ((char *) shrd + sizeof(pthread_mutex_t));

if ( (init_result = pthread_barrier_init(barr, &barr_attrs, 10)) != 0 ) {
   printf("Nao foi possivel iniciar a barreira.\n");

Initialize is a macro, defined as:

 #define initialize(func, ...) \
 do { \
    init_result = func(__VA_ARGS__); \
    if ( 0 != init_result ) { \
      stored_errno = errno; \
      func_name = #func; \
      goto erro_criacao_semaforo; \
    } \
 } while(0);

The second approach seems to work:

On child_main:

int               *contador = (int *) ((char *) shrd + sizeof(pthread_mutex_t) + sizeof(int));
int *n = (int *)(lock+1);
if ( 0 != (err=pthread_mutex_lock(lock)) ) {

On main:

volatile int           *n; // Cada filho iniciado incrementa esta variavel. 
                           // Qdo ela chega em 10, liberamos o lock.
n          = (int *) ((char *) shrd + sizeof(pthread_mutex_t));
for (i=0; i<sizeof(filhos)/sizeof(pid_t); ++i) {
... // the fork goes here.

while (*n != 10); // Isto garante que todos os filhos cheguem ao lock.

But once I add a random sleep time, so they get unsynchronized, once again I’ve got a deadlock:

On child_main:

int                num_sorteado;
struct timespec    dessincronizador = { 1, 0 };

int *n = (int *)(lock+1);

num_sorteado = 1 + (int) (999999.0 * (rand() / (RAND_MAX + 1.0)));
dessincronizador.tv_nsec = num_sorteado;
nanosleep(&dessincronizador, NULL);

if ( 0 != (err=pthread_mutex_lock(lock)) ) {

Sadly, there seems to be no reliable way to learn that a process died while holding a lock, so the best way around to our issue is to capture the signal on the dying process and raise a kill(0, SIGTERM) to get the other processes to die too.

share|improve this answer
Is this an answer, or an attempt to expand on your question? –  Marcin Oct 15 '12 at 21:46

Your EOWNERDEAD block misses a break before ENOTRECOVERABLE block. Also, according to pthread_mutex_lock manpage, after the first call to pthread_mutex_lock(), the lock is held by caller even when EOWNERDEAD is returned. Thus, you should not call it again inside EOWNERDEAD's block.

share|improve this answer
Thanks for you reply Mr. @caruccio. Actually, the break before ENOTRECOVERABLE was there on the code. I might have removed it while removing splint marks before copying to the site. As you pointed out, removing the lock after pthread_mutex_consistent_np() seems to work on the same circumstances in which the original code did. I had it there because mutex_mutandis article said it was required. However, with or without the lock after returning the mutex to a consistent state, the fact is that without the sleep on line 63, or passing 0 as the parameter, the program hang after the segfault. –  Acacio Centeno Oct 21 '11 at 12:41

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