Mercurial > trustbridge > nss-cmake-static
view nspr/pr/src/md/unix/uxproces.c @ 4:b513267f632f tip
Build DBM module
author | Andre Heinecke <andre.heinecke@intevation.de> |
---|---|
date | Tue, 05 Aug 2014 18:58:03 +0200 |
parents | 1e5118fa0cb1 |
children |
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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "primpl.h" #include <sys/types.h> #include <unistd.h> #include <fcntl.h> #include <signal.h> #include <sys/wait.h> #include <string.h> #if defined(AIX) #include <dlfcn.h> /* For dlopen, dlsym, dlclose */ #endif #if defined(DARWIN) #if defined(HAVE_CRT_EXTERNS_H) #include <crt_externs.h> #endif #else PR_IMPORT_DATA(char **) environ; #endif /* * HP-UX 9 doesn't have the SA_RESTART flag. */ #ifndef SA_RESTART #define SA_RESTART 0 #endif /* ********************************************************************** * * The Unix process routines * ********************************************************************** */ #define _PR_SIGNALED_EXITSTATUS 256 typedef enum pr_PidState { _PR_PID_DETACHED, _PR_PID_REAPED, _PR_PID_WAITING } pr_PidState; typedef struct pr_PidRecord { pid_t pid; int exitStatus; pr_PidState state; PRCondVar *reapedCV; struct pr_PidRecord *next; } pr_PidRecord; /* * Irix sprocs and LinuxThreads are actually a kind of processes * that can share the virtual address space and file descriptors. */ #if (defined(IRIX) && !defined(_PR_PTHREADS)) \ || ((defined(LINUX) || defined(__GNU__) || defined(__GLIBC__)) \ && defined(_PR_PTHREADS)) #define _PR_SHARE_CLONES #endif /* * The macro _PR_NATIVE_THREADS indicates that we are * using native threads only, so waitpid() blocks just the * calling thread, not the process. In this case, the waitpid * daemon thread can safely block in waitpid(). So we don't * need to catch SIGCHLD, and the pipe to unblock PR_Poll() is * also not necessary. */ #if defined(_PR_GLOBAL_THREADS_ONLY) \ || (defined(_PR_PTHREADS) \ && !defined(LINUX) && !defined(__GNU__) && !defined(__GLIBC__)) #define _PR_NATIVE_THREADS #endif /* * All the static variables used by the Unix process routines are * collected in this structure. */ static struct { PRCallOnceType once; PRThread *thread; PRLock *ml; #if defined(_PR_NATIVE_THREADS) PRInt32 numProcs; PRCondVar *cv; #else int pipefd[2]; #endif pr_PidRecord **pidTable; #ifdef _PR_SHARE_CLONES struct pr_CreateProcOp *opHead, *opTail; #endif #ifdef AIX pid_t (*forkptr)(void); /* Newer versions of AIX (starting in 4.3.2) * have f_fork, which is faster than the * regular fork in a multithreaded process * because it skips calling the fork handlers. * So we look up the f_fork symbol to see if * it's available and fall back on fork. */ #endif /* AIX */ } pr_wp; #ifdef _PR_SHARE_CLONES static int pr_waitpid_daemon_exit; void _MD_unix_terminate_waitpid_daemon(void) { if (pr_wp.thread) { pr_waitpid_daemon_exit = 1; write(pr_wp.pipefd[1], "", 1); PR_JoinThread(pr_wp.thread); } } #endif static PRStatus _MD_InitProcesses(void); #if !defined(_PR_NATIVE_THREADS) static void pr_InstallSigchldHandler(void); #endif static PRProcess * ForkAndExec( const char *path, char *const *argv, char *const *envp, const PRProcessAttr *attr) { PRProcess *process; int nEnv, idx; char *const *childEnvp; char **newEnvp = NULL; int flags; process = PR_NEW(PRProcess); if (!process) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return NULL; } childEnvp = envp; if (attr && attr->fdInheritBuffer) { PRBool found = PR_FALSE; if (NULL == childEnvp) { #ifdef DARWIN #ifdef HAVE_CRT_EXTERNS_H childEnvp = *(_NSGetEnviron()); #else /* _NSGetEnviron() is not available on iOS. */ PR_DELETE(process); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return NULL; #endif #else childEnvp = environ; #endif } for (nEnv = 0; childEnvp[nEnv]; nEnv++) { } newEnvp = (char **) PR_MALLOC((nEnv + 2) * sizeof(char *)); if (NULL == newEnvp) { PR_DELETE(process); PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return NULL; } for (idx = 0; idx < nEnv; idx++) { newEnvp[idx] = childEnvp[idx]; if (!found && !strncmp(newEnvp[idx], "NSPR_INHERIT_FDS=", 17)) { newEnvp[idx] = attr->fdInheritBuffer; found = PR_TRUE; } } if (!found) { newEnvp[idx++] = attr->fdInheritBuffer; } newEnvp[idx] = NULL; childEnvp = newEnvp; } #ifdef AIX process->md.pid = (*pr_wp.forkptr)(); #elif defined(NTO) || defined(SYMBIAN) /* * fork() & exec() does not work in a multithreaded process. * Use spawn() instead. */ { int fd_map[3] = { 0, 1, 2 }; if (attr) { if (attr->stdinFd && attr->stdinFd->secret->md.osfd != 0) { fd_map[0] = dup(attr->stdinFd->secret->md.osfd); flags = fcntl(fd_map[0], F_GETFL, 0); if (flags & O_NONBLOCK) fcntl(fd_map[0], F_SETFL, flags & ~O_NONBLOCK); } if (attr->stdoutFd && attr->stdoutFd->secret->md.osfd != 1) { fd_map[1] = dup(attr->stdoutFd->secret->md.osfd); flags = fcntl(fd_map[1], F_GETFL, 0); if (flags & O_NONBLOCK) fcntl(fd_map[1], F_SETFL, flags & ~O_NONBLOCK); } if (attr->stderrFd && attr->stderrFd->secret->md.osfd != 2) { fd_map[2] = dup(attr->stderrFd->secret->md.osfd); flags = fcntl(fd_map[2], F_GETFL, 0); if (flags & O_NONBLOCK) fcntl(fd_map[2], F_SETFL, flags & ~O_NONBLOCK); } PR_ASSERT(attr->currentDirectory == NULL); /* not implemented */ } #ifdef SYMBIAN /* In Symbian OS, we use posix_spawn instead of fork() and exec() */ posix_spawn(&(process->md.pid), path, NULL, NULL, argv, childEnvp); #else process->md.pid = spawn(path, 3, fd_map, NULL, argv, childEnvp); #endif if (fd_map[0] != 0) close(fd_map[0]); if (fd_map[1] != 1) close(fd_map[1]); if (fd_map[2] != 2) close(fd_map[2]); } #else process->md.pid = fork(); #endif if ((pid_t) -1 == process->md.pid) { PR_SetError(PR_INSUFFICIENT_RESOURCES_ERROR, errno); PR_DELETE(process); if (newEnvp) { PR_DELETE(newEnvp); } return NULL; } else if (0 == process->md.pid) { /* the child process */ /* * If the child process needs to exit, it must call _exit(). * Do not call exit(), because exit() will flush and close * the standard I/O file descriptors, and hence corrupt * the parent process's standard I/O data structures. */ #if !defined(NTO) && !defined(SYMBIAN) if (attr) { /* the osfd's to redirect stdin, stdout, and stderr to */ int in_osfd = -1, out_osfd = -1, err_osfd = -1; if (attr->stdinFd && attr->stdinFd->secret->md.osfd != 0) { in_osfd = attr->stdinFd->secret->md.osfd; if (dup2(in_osfd, 0) != 0) { _exit(1); /* failed */ } flags = fcntl(0, F_GETFL, 0); if (flags & O_NONBLOCK) { fcntl(0, F_SETFL, flags & ~O_NONBLOCK); } } if (attr->stdoutFd && attr->stdoutFd->secret->md.osfd != 1) { out_osfd = attr->stdoutFd->secret->md.osfd; if (dup2(out_osfd, 1) != 1) { _exit(1); /* failed */ } flags = fcntl(1, F_GETFL, 0); if (flags & O_NONBLOCK) { fcntl(1, F_SETFL, flags & ~O_NONBLOCK); } } if (attr->stderrFd && attr->stderrFd->secret->md.osfd != 2) { err_osfd = attr->stderrFd->secret->md.osfd; if (dup2(err_osfd, 2) != 2) { _exit(1); /* failed */ } flags = fcntl(2, F_GETFL, 0); if (flags & O_NONBLOCK) { fcntl(2, F_SETFL, flags & ~O_NONBLOCK); } } if (in_osfd != -1) { close(in_osfd); } if (out_osfd != -1 && out_osfd != in_osfd) { close(out_osfd); } if (err_osfd != -1 && err_osfd != in_osfd && err_osfd != out_osfd) { close(err_osfd); } if (attr->currentDirectory) { if (chdir(attr->currentDirectory) < 0) { _exit(1); /* failed */ } } } if (childEnvp) { (void)execve(path, argv, childEnvp); } else { /* Inherit the environment of the parent. */ (void)execv(path, argv); } /* Whoops! It returned. That's a bad sign. */ _exit(1); #endif /* !NTO */ } if (newEnvp) { PR_DELETE(newEnvp); } #if defined(_PR_NATIVE_THREADS) PR_Lock(pr_wp.ml); if (0 == pr_wp.numProcs++) { PR_NotifyCondVar(pr_wp.cv); } PR_Unlock(pr_wp.ml); #endif return process; } #ifdef _PR_SHARE_CLONES struct pr_CreateProcOp { const char *path; char *const *argv; char *const *envp; const PRProcessAttr *attr; PRProcess *process; PRErrorCode prerror; PRInt32 oserror; PRBool done; PRCondVar *doneCV; struct pr_CreateProcOp *next; }; PRProcess * _MD_CreateUnixProcess( const char *path, char *const *argv, char *const *envp, const PRProcessAttr *attr) { struct pr_CreateProcOp *op; PRProcess *proc; int rv; if (PR_CallOnce(&pr_wp.once, _MD_InitProcesses) == PR_FAILURE) { return NULL; } op = PR_NEW(struct pr_CreateProcOp); if (NULL == op) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return NULL; } op->path = path; op->argv = argv; op->envp = envp; op->attr = attr; op->done = PR_FALSE; op->doneCV = PR_NewCondVar(pr_wp.ml); if (NULL == op->doneCV) { PR_DELETE(op); return NULL; } PR_Lock(pr_wp.ml); /* add to the tail of op queue */ op->next = NULL; if (pr_wp.opTail) { pr_wp.opTail->next = op; pr_wp.opTail = op; } else { PR_ASSERT(NULL == pr_wp.opHead); pr_wp.opHead = pr_wp.opTail = op; } /* wake up the daemon thread */ do { rv = write(pr_wp.pipefd[1], "", 1); } while (-1 == rv && EINTR == errno); while (op->done == PR_FALSE) { PR_WaitCondVar(op->doneCV, PR_INTERVAL_NO_TIMEOUT); } PR_Unlock(pr_wp.ml); PR_DestroyCondVar(op->doneCV); proc = op->process; if (!proc) { PR_SetError(op->prerror, op->oserror); } PR_DELETE(op); return proc; } #else /* ! _PR_SHARE_CLONES */ PRProcess * _MD_CreateUnixProcess( const char *path, char *const *argv, char *const *envp, const PRProcessAttr *attr) { if (PR_CallOnce(&pr_wp.once, _MD_InitProcesses) == PR_FAILURE) { return NULL; } return ForkAndExec(path, argv, envp, attr); } /* _MD_CreateUnixProcess */ #endif /* _PR_SHARE_CLONES */ /* * The pid table is a hashtable. * * The number of buckets in the hashtable (NBUCKETS) must be a power of 2. */ #define NBUCKETS_LOG2 6 #define NBUCKETS (1 << NBUCKETS_LOG2) #define PID_HASH_MASK ((pid_t) (NBUCKETS - 1)) static pr_PidRecord * FindPidTable(pid_t pid) { pr_PidRecord *pRec; int keyHash = (int) (pid & PID_HASH_MASK); pRec = pr_wp.pidTable[keyHash]; while (pRec) { if (pRec->pid == pid) { break; } pRec = pRec->next; } return pRec; } static void InsertPidTable(pr_PidRecord *pRec) { int keyHash = (int) (pRec->pid & PID_HASH_MASK); pRec->next = pr_wp.pidTable[keyHash]; pr_wp.pidTable[keyHash] = pRec; } static void DeletePidTable(pr_PidRecord *pRec) { int keyHash = (int) (pRec->pid & PID_HASH_MASK); if (pr_wp.pidTable[keyHash] == pRec) { pr_wp.pidTable[keyHash] = pRec->next; } else { pr_PidRecord *pred, *cur; /* predecessor and current */ pred = pr_wp.pidTable[keyHash]; cur = pred->next; while (cur) { if (cur == pRec) { pred->next = cur->next; break; } pred = cur; cur = cur->next; } PR_ASSERT(cur != NULL); } } static int ExtractExitStatus(int rawExitStatus) { /* * We did not specify the WCONTINUED and WUNTRACED options * for waitpid, so these two events should not be reported. */ PR_ASSERT(!WIFSTOPPED(rawExitStatus)); #ifdef WIFCONTINUED PR_ASSERT(!WIFCONTINUED(rawExitStatus)); #endif if (WIFEXITED(rawExitStatus)) { return WEXITSTATUS(rawExitStatus); } else { PR_ASSERT(WIFSIGNALED(rawExitStatus)); return _PR_SIGNALED_EXITSTATUS; } } static void ProcessReapedChildInternal(pid_t pid, int status) { pr_PidRecord *pRec; pRec = FindPidTable(pid); if (NULL == pRec) { pRec = PR_NEW(pr_PidRecord); pRec->pid = pid; pRec->state = _PR_PID_REAPED; pRec->exitStatus = ExtractExitStatus(status); pRec->reapedCV = NULL; InsertPidTable(pRec); } else { PR_ASSERT(pRec->state != _PR_PID_REAPED); if (_PR_PID_DETACHED == pRec->state) { PR_ASSERT(NULL == pRec->reapedCV); DeletePidTable(pRec); PR_DELETE(pRec); } else { PR_ASSERT(_PR_PID_WAITING == pRec->state); PR_ASSERT(NULL != pRec->reapedCV); pRec->exitStatus = ExtractExitStatus(status); pRec->state = _PR_PID_REAPED; PR_NotifyCondVar(pRec->reapedCV); } } } #if defined(_PR_NATIVE_THREADS) /* * If all the threads are native threads, the daemon thread is * simpler. We don't need to catch the SIGCHLD signal. We can * just have the daemon thread block in waitpid(). */ static void WaitPidDaemonThread(void *unused) { pid_t pid; int status; while (1) { PR_Lock(pr_wp.ml); while (0 == pr_wp.numProcs) { PR_WaitCondVar(pr_wp.cv, PR_INTERVAL_NO_TIMEOUT); } PR_Unlock(pr_wp.ml); while (1) { do { pid = waitpid((pid_t) -1, &status, 0); } while ((pid_t) -1 == pid && EINTR == errno); /* * waitpid() cannot return 0 because we did not invoke it * with the WNOHANG option. */ PR_ASSERT(0 != pid); /* * The only possible error code is ECHILD. But if we do * our accounting correctly, we should only call waitpid() * when there is a child process to wait for. */ PR_ASSERT((pid_t) -1 != pid); if ((pid_t) -1 == pid) { break; } PR_Lock(pr_wp.ml); ProcessReapedChildInternal(pid, status); pr_wp.numProcs--; while (0 == pr_wp.numProcs) { PR_WaitCondVar(pr_wp.cv, PR_INTERVAL_NO_TIMEOUT); } PR_Unlock(pr_wp.ml); } } } #else /* _PR_NATIVE_THREADS */ static void WaitPidDaemonThread(void *unused) { PRPollDesc pd; PRFileDesc *fd; int rv; char buf[128]; pid_t pid; int status; #ifdef _PR_SHARE_CLONES struct pr_CreateProcOp *op; #endif #ifdef _PR_SHARE_CLONES pr_InstallSigchldHandler(); #endif fd = PR_ImportFile(pr_wp.pipefd[0]); PR_ASSERT(NULL != fd); pd.fd = fd; pd.in_flags = PR_POLL_READ; while (1) { rv = PR_Poll(&pd, 1, PR_INTERVAL_NO_TIMEOUT); PR_ASSERT(1 == rv); #ifdef _PR_SHARE_CLONES if (pr_waitpid_daemon_exit) { return; } PR_Lock(pr_wp.ml); #endif do { rv = read(pr_wp.pipefd[0], buf, sizeof(buf)); } while (sizeof(buf) == rv || (-1 == rv && EINTR == errno)); #ifdef _PR_SHARE_CLONES PR_Unlock(pr_wp.ml); while ((op = pr_wp.opHead) != NULL) { op->process = ForkAndExec(op->path, op->argv, op->envp, op->attr); if (NULL == op->process) { op->prerror = PR_GetError(); op->oserror = PR_GetOSError(); } PR_Lock(pr_wp.ml); pr_wp.opHead = op->next; if (NULL == pr_wp.opHead) { pr_wp.opTail = NULL; } op->done = PR_TRUE; PR_NotifyCondVar(op->doneCV); PR_Unlock(pr_wp.ml); } #endif while (1) { do { pid = waitpid((pid_t) -1, &status, WNOHANG); } while ((pid_t) -1 == pid && EINTR == errno); if (0 == pid) break; if ((pid_t) -1 == pid) { /* must be because we have no child processes */ PR_ASSERT(ECHILD == errno); break; } PR_Lock(pr_wp.ml); ProcessReapedChildInternal(pid, status); PR_Unlock(pr_wp.ml); } } } static void pr_SigchldHandler(int sig) { int errnoCopy; int rv; errnoCopy = errno; do { rv = write(pr_wp.pipefd[1], "", 1); } while (-1 == rv && EINTR == errno); #ifdef DEBUG if (-1 == rv && EAGAIN != errno && EWOULDBLOCK != errno) { char *msg = "cannot write to pipe\n"; write(2, msg, strlen(msg) + 1); _exit(1); } #endif errno = errnoCopy; } static void pr_InstallSigchldHandler() { #if defined(HPUX) && defined(_PR_DCETHREADS) #error "HP-UX DCE threads have their own SIGCHLD handler" #endif struct sigaction act, oact; int rv; act.sa_handler = pr_SigchldHandler; sigemptyset(&act.sa_mask); act.sa_flags = SA_NOCLDSTOP | SA_RESTART; rv = sigaction(SIGCHLD, &act, &oact); PR_ASSERT(0 == rv); /* Make sure we are not overriding someone else's SIGCHLD handler */ #ifndef _PR_SHARE_CLONES PR_ASSERT(oact.sa_handler == SIG_DFL); #endif } #endif /* !defined(_PR_NATIVE_THREADS) */ static PRStatus _MD_InitProcesses(void) { #if !defined(_PR_NATIVE_THREADS) int rv; int flags; #endif #ifdef AIX { void *handle = dlopen(NULL, RTLD_NOW | RTLD_GLOBAL); pr_wp.forkptr = (pid_t (*)(void)) dlsym(handle, "f_fork"); if (!pr_wp.forkptr) { pr_wp.forkptr = fork; } dlclose(handle); } #endif /* AIX */ pr_wp.ml = PR_NewLock(); PR_ASSERT(NULL != pr_wp.ml); #if defined(_PR_NATIVE_THREADS) pr_wp.numProcs = 0; pr_wp.cv = PR_NewCondVar(pr_wp.ml); PR_ASSERT(NULL != pr_wp.cv); #else rv = pipe(pr_wp.pipefd); PR_ASSERT(0 == rv); flags = fcntl(pr_wp.pipefd[0], F_GETFL, 0); fcntl(pr_wp.pipefd[0], F_SETFL, flags | O_NONBLOCK); flags = fcntl(pr_wp.pipefd[1], F_GETFL, 0); fcntl(pr_wp.pipefd[1], F_SETFL, flags | O_NONBLOCK); #ifndef _PR_SHARE_CLONES pr_InstallSigchldHandler(); #endif #endif /* !_PR_NATIVE_THREADS */ pr_wp.thread = PR_CreateThread(PR_SYSTEM_THREAD, WaitPidDaemonThread, NULL, PR_PRIORITY_NORMAL, #ifdef _PR_SHARE_CLONES PR_GLOBAL_THREAD, #else PR_LOCAL_THREAD, #endif PR_JOINABLE_THREAD, 0); PR_ASSERT(NULL != pr_wp.thread); pr_wp.pidTable = (pr_PidRecord**)PR_CALLOC(NBUCKETS * sizeof(pr_PidRecord *)); PR_ASSERT(NULL != pr_wp.pidTable); return PR_SUCCESS; } PRStatus _MD_DetachUnixProcess(PRProcess *process) { PRStatus retVal = PR_SUCCESS; pr_PidRecord *pRec; PR_Lock(pr_wp.ml); pRec = FindPidTable(process->md.pid); if (NULL == pRec) { pRec = PR_NEW(pr_PidRecord); if (NULL == pRec) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); retVal = PR_FAILURE; goto done; } pRec->pid = process->md.pid; pRec->state = _PR_PID_DETACHED; pRec->reapedCV = NULL; InsertPidTable(pRec); } else { PR_ASSERT(_PR_PID_REAPED == pRec->state); if (_PR_PID_REAPED != pRec->state) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); retVal = PR_FAILURE; } else { DeletePidTable(pRec); PR_ASSERT(NULL == pRec->reapedCV); PR_DELETE(pRec); } } PR_DELETE(process); done: PR_Unlock(pr_wp.ml); return retVal; } PRStatus _MD_WaitUnixProcess( PRProcess *process, PRInt32 *exitCode) { pr_PidRecord *pRec; PRStatus retVal = PR_SUCCESS; PRBool interrupted = PR_FALSE; PR_Lock(pr_wp.ml); pRec = FindPidTable(process->md.pid); if (NULL == pRec) { pRec = PR_NEW(pr_PidRecord); if (NULL == pRec) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); retVal = PR_FAILURE; goto done; } pRec->pid = process->md.pid; pRec->state = _PR_PID_WAITING; pRec->reapedCV = PR_NewCondVar(pr_wp.ml); if (NULL == pRec->reapedCV) { PR_DELETE(pRec); retVal = PR_FAILURE; goto done; } InsertPidTable(pRec); while (!interrupted && _PR_PID_REAPED != pRec->state) { if (PR_WaitCondVar(pRec->reapedCV, PR_INTERVAL_NO_TIMEOUT) == PR_FAILURE && PR_GetError() == PR_PENDING_INTERRUPT_ERROR) { interrupted = PR_TRUE; } } if (_PR_PID_REAPED == pRec->state) { if (exitCode) { *exitCode = pRec->exitStatus; } } else { PR_ASSERT(interrupted); retVal = PR_FAILURE; } DeletePidTable(pRec); PR_DestroyCondVar(pRec->reapedCV); PR_DELETE(pRec); } else { PR_ASSERT(_PR_PID_REAPED == pRec->state); PR_ASSERT(NULL == pRec->reapedCV); DeletePidTable(pRec); if (exitCode) { *exitCode = pRec->exitStatus; } PR_DELETE(pRec); } PR_DELETE(process); done: PR_Unlock(pr_wp.ml); return retVal; } /* _MD_WaitUnixProcess */ PRStatus _MD_KillUnixProcess(PRProcess *process) { PRErrorCode prerror; PRInt32 oserror; #ifdef SYMBIAN /* In Symbian OS, we can not kill other process with Open C */ PR_SetError(PR_OPERATION_NOT_SUPPORTED_ERROR, oserror); return PR_FAILURE; #else if (kill(process->md.pid, SIGKILL) == 0) { return PR_SUCCESS; } oserror = errno; switch (oserror) { case EPERM: prerror = PR_NO_ACCESS_RIGHTS_ERROR; break; case ESRCH: prerror = PR_INVALID_ARGUMENT_ERROR; break; default: prerror = PR_UNKNOWN_ERROR; break; } PR_SetError(prerror, oserror); return PR_FAILURE; #endif } /* _MD_KillUnixProcess */