/* +----------------------------------------------------------------------+ | Copyright (c) The PHP Group | +----------------------------------------------------------------------+ | This source file is subject to version 3.01 of the PHP license, | | that is bundled with this package in the file LICENSE, and is | | available through the world-wide-web at the following url: | | http://www.php.net/license/3_01.txt | | If you did not receive a copy of the PHP license and are unable to | | obtain it through the world-wide-web, please send a note to | | license@php.net so we can mail you a copy immediately. | +----------------------------------------------------------------------+ | Author: Jason Greene | +----------------------------------------------------------------------+ */ #define PCNTL_DEBUG 0 #if PCNTL_DEBUG #define DEBUG_OUT printf("DEBUG: ");printf #define IF_DEBUG(z) z #else #define IF_DEBUG(z) #endif #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "php.h" #include "php_ini.h" #include "ext/standard/info.h" #include "php_pcntl.h" #include "pcntl_arginfo.h" #include "php_signal.h" #include "php_ticks.h" #if defined(HAVE_GETPRIORITY) || defined(HAVE_SETPRIORITY) || defined(HAVE_WAIT3) #include #include #include #endif #include #ifdef HAVE_UNSHARE #include #endif #ifndef NSIG # ifdef SIGRTMAX # define NSIG (SIGRTMAX + 1) # else # define NSIG 32 # endif #endif ZEND_DECLARE_MODULE_GLOBALS(pcntl) static PHP_GINIT_FUNCTION(pcntl); zend_module_entry pcntl_module_entry = { STANDARD_MODULE_HEADER, "pcntl", ext_functions, PHP_MINIT(pcntl), PHP_MSHUTDOWN(pcntl), PHP_RINIT(pcntl), PHP_RSHUTDOWN(pcntl), PHP_MINFO(pcntl), PHP_PCNTL_VERSION, PHP_MODULE_GLOBALS(pcntl), PHP_GINIT(pcntl), NULL, NULL, STANDARD_MODULE_PROPERTIES_EX }; #ifdef COMPILE_DL_PCNTL #ifdef ZTS ZEND_TSRMLS_CACHE_DEFINE() #endif ZEND_GET_MODULE(pcntl) #endif static void (*orig_interrupt_function)(zend_execute_data *execute_data); #ifdef HAVE_STRUCT_SIGINFO_T static void pcntl_signal_handler(int, siginfo_t*, void*); static void pcntl_siginfo_to_zval(int, siginfo_t*, zval*); #else static void pcntl_signal_handler(int); #endif static void pcntl_signal_dispatch(); static void pcntl_interrupt_function(zend_execute_data *execute_data); void php_register_signal_constants(INIT_FUNC_ARGS) { /* Wait Constants */ #ifdef WNOHANG REGISTER_LONG_CONSTANT("WNOHANG", (zend_long) WNOHANG, CONST_CS | CONST_PERSISTENT); #endif #ifdef WUNTRACED REGISTER_LONG_CONSTANT("WUNTRACED", (zend_long) WUNTRACED, CONST_CS | CONST_PERSISTENT); #endif #ifdef HAVE_WCONTINUED REGISTER_LONG_CONSTANT("WCONTINUED", (zend_long) WCONTINUED, CONST_CS | CONST_PERSISTENT); #endif /* Signal Constants */ REGISTER_LONG_CONSTANT("SIG_IGN", (zend_long) SIG_IGN, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIG_DFL", (zend_long) SIG_DFL, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIG_ERR", (zend_long) SIG_ERR, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGHUP", (zend_long) SIGHUP, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGINT", (zend_long) SIGINT, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGQUIT", (zend_long) SIGQUIT, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGILL", (zend_long) SIGILL, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGTRAP", (zend_long) SIGTRAP, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGABRT", (zend_long) SIGABRT, CONST_CS | CONST_PERSISTENT); #ifdef SIGIOT REGISTER_LONG_CONSTANT("SIGIOT", (zend_long) SIGIOT, CONST_CS | CONST_PERSISTENT); #endif REGISTER_LONG_CONSTANT("SIGBUS", (zend_long) SIGBUS, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGFPE", (zend_long) SIGFPE, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGKILL", (zend_long) SIGKILL, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGUSR1", (zend_long) SIGUSR1, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGSEGV", (zend_long) SIGSEGV, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGUSR2", (zend_long) SIGUSR2, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGPIPE", (zend_long) SIGPIPE, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGALRM", (zend_long) SIGALRM, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGTERM", (zend_long) SIGTERM, CONST_CS | CONST_PERSISTENT); #ifdef SIGSTKFLT REGISTER_LONG_CONSTANT("SIGSTKFLT",(zend_long) SIGSTKFLT, CONST_CS | CONST_PERSISTENT); #endif #ifdef SIGCLD REGISTER_LONG_CONSTANT("SIGCLD", (zend_long) SIGCLD, CONST_CS | CONST_PERSISTENT); #endif #ifdef SIGCHLD REGISTER_LONG_CONSTANT("SIGCHLD", (zend_long) SIGCHLD, CONST_CS | CONST_PERSISTENT); #endif REGISTER_LONG_CONSTANT("SIGCONT", (zend_long) SIGCONT, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGSTOP", (zend_long) SIGSTOP, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGTSTP", (zend_long) SIGTSTP, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGTTIN", (zend_long) SIGTTIN, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGTTOU", (zend_long) SIGTTOU, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGURG", (zend_long) SIGURG , CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGXCPU", (zend_long) SIGXCPU, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGXFSZ", (zend_long) SIGXFSZ, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGVTALRM",(zend_long) SIGVTALRM, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGPROF", (zend_long) SIGPROF, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGWINCH", (zend_long) SIGWINCH, CONST_CS | CONST_PERSISTENT); #ifdef SIGPOLL REGISTER_LONG_CONSTANT("SIGPOLL", (zend_long) SIGPOLL, CONST_CS | CONST_PERSISTENT); #endif REGISTER_LONG_CONSTANT("SIGIO", (zend_long) SIGIO, CONST_CS | CONST_PERSISTENT); #ifdef SIGPWR REGISTER_LONG_CONSTANT("SIGPWR", (zend_long) SIGPWR, CONST_CS | CONST_PERSISTENT); #endif #ifdef SIGSYS REGISTER_LONG_CONSTANT("SIGSYS", (zend_long) SIGSYS, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIGBABY", (zend_long) SIGSYS, CONST_CS | CONST_PERSISTENT); #endif #ifdef SIGRTMIN REGISTER_LONG_CONSTANT("SIGRTMIN", (zend_long) SIGRTMIN, CONST_CS | CONST_PERSISTENT); #endif #ifdef SIGRTMAX REGISTER_LONG_CONSTANT("SIGRTMAX", (zend_long) SIGRTMAX, CONST_CS | CONST_PERSISTENT); #endif #if defined(HAVE_GETPRIORITY) || defined(HAVE_SETPRIORITY) REGISTER_LONG_CONSTANT("PRIO_PGRP", PRIO_PGRP, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("PRIO_USER", PRIO_USER, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("PRIO_PROCESS", PRIO_PROCESS, CONST_CS | CONST_PERSISTENT); #endif /* {{{ "how" argument for sigprocmask */ #ifdef HAVE_SIGPROCMASK REGISTER_LONG_CONSTANT("SIG_BLOCK", SIG_BLOCK, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIG_UNBLOCK", SIG_UNBLOCK, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SIG_SETMASK", SIG_SETMASK, CONST_CS | CONST_PERSISTENT); #endif /* }}} */ /* {{{ si_code */ #if defined(HAVE_SIGWAITINFO) && defined(HAVE_SIGTIMEDWAIT) REGISTER_LONG_CONSTANT("SI_USER", SI_USER, CONST_CS | CONST_PERSISTENT); #ifdef SI_NOINFO REGISTER_LONG_CONSTANT("SI_NOINFO", SI_NOINFO, CONST_CS | CONST_PERSISTENT); #endif #ifdef SI_KERNEL REGISTER_LONG_CONSTANT("SI_KERNEL", SI_KERNEL, CONST_CS | CONST_PERSISTENT); #endif REGISTER_LONG_CONSTANT("SI_QUEUE", SI_QUEUE, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SI_TIMER", SI_TIMER, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SI_MESGQ", SI_MESGQ, CONST_CS | CONST_PERSISTENT); REGISTER_LONG_CONSTANT("SI_ASYNCIO", SI_ASYNCIO, CONST_CS | CONST_PERSISTENT); #ifdef SI_SIGIO REGISTER_LONG_CONSTANT("SI_SIGIO", SI_SIGIO, CONST_CS | CONST_PERSISTENT); #endif #ifdef SI_TKILL REGISTER_LONG_CONSTANT("SI_TKILL", SI_TKILL, CONST_CS | CONST_PERSISTENT); #endif /* si_code for SIGCHILD */ #ifdef CLD_EXITED REGISTER_LONG_CONSTANT("CLD_EXITED", CLD_EXITED, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLD_KILLED REGISTER_LONG_CONSTANT("CLD_KILLED", CLD_KILLED, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLD_DUMPED REGISTER_LONG_CONSTANT("CLD_DUMPED", CLD_DUMPED, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLD_TRAPPED REGISTER_LONG_CONSTANT("CLD_TRAPPED", CLD_TRAPPED, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLD_STOPPED REGISTER_LONG_CONSTANT("CLD_STOPPED", CLD_STOPPED, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLD_CONTINUED REGISTER_LONG_CONSTANT("CLD_CONTINUED", CLD_CONTINUED, CONST_CS | CONST_PERSISTENT); #endif /* si_code for SIGTRAP */ #ifdef TRAP_BRKPT REGISTER_LONG_CONSTANT("TRAP_BRKPT", TRAP_BRKPT, CONST_CS | CONST_PERSISTENT); #endif #ifdef TRAP_TRACE REGISTER_LONG_CONSTANT("TRAP_TRACE", TRAP_TRACE, CONST_CS | CONST_PERSISTENT); #endif /* si_code for SIGPOLL */ #ifdef POLL_IN REGISTER_LONG_CONSTANT("POLL_IN", POLL_IN, CONST_CS | CONST_PERSISTENT); #endif #ifdef POLL_OUT REGISTER_LONG_CONSTANT("POLL_OUT", POLL_OUT, CONST_CS | CONST_PERSISTENT); #endif #ifdef POLL_MSG REGISTER_LONG_CONSTANT("POLL_MSG", POLL_MSG, CONST_CS | CONST_PERSISTENT); #endif #ifdef POLL_ERR REGISTER_LONG_CONSTANT("POLL_ERR", POLL_ERR, CONST_CS | CONST_PERSISTENT); #endif #ifdef POLL_PRI REGISTER_LONG_CONSTANT("POLL_PRI", POLL_PRI, CONST_CS | CONST_PERSISTENT); #endif #ifdef POLL_HUP REGISTER_LONG_CONSTANT("POLL_HUP", POLL_HUP, CONST_CS | CONST_PERSISTENT); #endif #ifdef ILL_ILLOPC REGISTER_LONG_CONSTANT("ILL_ILLOPC", ILL_ILLOPC, CONST_CS | CONST_PERSISTENT); #endif #ifdef ILL_ILLOPN REGISTER_LONG_CONSTANT("ILL_ILLOPN", ILL_ILLOPN, CONST_CS | CONST_PERSISTENT); #endif #ifdef ILL_ILLADR REGISTER_LONG_CONSTANT("ILL_ILLADR", ILL_ILLADR, CONST_CS | CONST_PERSISTENT); #endif #ifdef ILL_ILLTRP REGISTER_LONG_CONSTANT("ILL_ILLTRP", ILL_ILLTRP, CONST_CS | CONST_PERSISTENT); #endif #ifdef ILL_PRVOPC REGISTER_LONG_CONSTANT("ILL_PRVOPC", ILL_PRVOPC, CONST_CS | CONST_PERSISTENT); #endif #ifdef ILL_PRVREG REGISTER_LONG_CONSTANT("ILL_PRVREG", ILL_PRVREG, CONST_CS | CONST_PERSISTENT); #endif #ifdef ILL_COPROC REGISTER_LONG_CONSTANT("ILL_COPROC", ILL_COPROC, CONST_CS | CONST_PERSISTENT); #endif #ifdef ILL_BADSTK REGISTER_LONG_CONSTANT("ILL_BADSTK", ILL_BADSTK, CONST_CS | CONST_PERSISTENT); #endif #ifdef FPE_INTDIV REGISTER_LONG_CONSTANT("FPE_INTDIV", FPE_INTDIV, CONST_CS | CONST_PERSISTENT); #endif #ifdef FPE_INTOVF REGISTER_LONG_CONSTANT("FPE_INTOVF", FPE_INTOVF, CONST_CS | CONST_PERSISTENT); #endif #ifdef FPE_FLTDIV REGISTER_LONG_CONSTANT("FPE_FLTDIV", FPE_FLTDIV, CONST_CS | CONST_PERSISTENT); #endif #ifdef FPE_FLTOVF REGISTER_LONG_CONSTANT("FPE_FLTOVF", FPE_FLTOVF, CONST_CS | CONST_PERSISTENT); #endif #ifdef FPE_FLTUND REGISTER_LONG_CONSTANT("FPE_FLTUND", FPE_FLTINV, CONST_CS | CONST_PERSISTENT); #endif #ifdef FPE_FLTRES REGISTER_LONG_CONSTANT("FPE_FLTRES", FPE_FLTRES, CONST_CS | CONST_PERSISTENT); #endif #ifdef FPE_FLTINV REGISTER_LONG_CONSTANT("FPE_FLTINV", FPE_FLTINV, CONST_CS | CONST_PERSISTENT); #endif #ifdef FPE_FLTSUB REGISTER_LONG_CONSTANT("FPE_FLTSUB", FPE_FLTSUB, CONST_CS | CONST_PERSISTENT); #endif #ifdef SEGV_MAPERR REGISTER_LONG_CONSTANT("SEGV_MAPERR", SEGV_MAPERR, CONST_CS | CONST_PERSISTENT); #endif #ifdef SEGV_ACCERR REGISTER_LONG_CONSTANT("SEGV_ACCERR", SEGV_ACCERR, CONST_CS | CONST_PERSISTENT); #endif #ifdef BUS_ADRALN REGISTER_LONG_CONSTANT("BUS_ADRALN", BUS_ADRALN, CONST_CS | CONST_PERSISTENT); #endif #ifdef BUS_ADRERR REGISTER_LONG_CONSTANT("BUS_ADRERR", BUS_ADRERR, CONST_CS | CONST_PERSISTENT); #endif #ifdef BUS_OBJERR REGISTER_LONG_CONSTANT("BUS_OBJERR", BUS_OBJERR, CONST_CS | CONST_PERSISTENT); #endif #endif /* defined(HAVE_SIGWAITINFO) && defined(HAVE_SIGTIMEDWAIT) */ /* }}} */ /* unshare(/clone) constants */ #ifdef HAVE_UNSHARE REGISTER_LONG_CONSTANT("CLONE_NEWNS", CLONE_NEWNS, CONST_CS | CONST_PERSISTENT); #ifdef CLONE_NEWIPC REGISTER_LONG_CONSTANT("CLONE_NEWIPC", CLONE_NEWIPC, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLONE_NEWUTS REGISTER_LONG_CONSTANT("CLONE_NEWUTS", CLONE_NEWUTS, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLONE_NEWNET REGISTER_LONG_CONSTANT("CLONE_NEWNET", CLONE_NEWNET, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLONE_NEWPID REGISTER_LONG_CONSTANT("CLONE_NEWPID", CLONE_NEWPID, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLONE_NEWUSER REGISTER_LONG_CONSTANT("CLONE_NEWUSER", CLONE_NEWUSER, CONST_CS | CONST_PERSISTENT); #endif #ifdef CLONE_NEWCGROUP REGISTER_LONG_CONSTANT("CLONE_NEWCGROUP", CLONE_NEWCGROUP, CONST_CS | CONST_PERSISTENT); #endif #endif } static void php_pcntl_register_errno_constants(INIT_FUNC_ARGS) { #ifdef EINTR REGISTER_PCNTL_ERRNO_CONSTANT(EINTR); #endif #ifdef ECHILD REGISTER_PCNTL_ERRNO_CONSTANT(ECHILD); #endif #ifdef EINVAL REGISTER_PCNTL_ERRNO_CONSTANT(EINVAL); #endif #ifdef EAGAIN REGISTER_PCNTL_ERRNO_CONSTANT(EAGAIN); #endif #ifdef ESRCH REGISTER_PCNTL_ERRNO_CONSTANT(ESRCH); #endif #ifdef EACCES REGISTER_PCNTL_ERRNO_CONSTANT(EACCES); #endif #ifdef EPERM REGISTER_PCNTL_ERRNO_CONSTANT(EPERM); #endif #ifdef ENOMEM REGISTER_PCNTL_ERRNO_CONSTANT(ENOMEM); #endif #ifdef E2BIG REGISTER_PCNTL_ERRNO_CONSTANT(E2BIG); #endif #ifdef EFAULT REGISTER_PCNTL_ERRNO_CONSTANT(EFAULT); #endif #ifdef EIO REGISTER_PCNTL_ERRNO_CONSTANT(EIO); #endif #ifdef EISDIR REGISTER_PCNTL_ERRNO_CONSTANT(EISDIR); #endif #ifdef ELIBBAD REGISTER_PCNTL_ERRNO_CONSTANT(ELIBBAD); #endif #ifdef ELOOP REGISTER_PCNTL_ERRNO_CONSTANT(ELOOP); #endif #ifdef EMFILE REGISTER_PCNTL_ERRNO_CONSTANT(EMFILE); #endif #ifdef ENAMETOOLONG REGISTER_PCNTL_ERRNO_CONSTANT(ENAMETOOLONG); #endif #ifdef ENFILE REGISTER_PCNTL_ERRNO_CONSTANT(ENFILE); #endif #ifdef ENOENT REGISTER_PCNTL_ERRNO_CONSTANT(ENOENT); #endif #ifdef ENOEXEC REGISTER_PCNTL_ERRNO_CONSTANT(ENOEXEC); #endif #ifdef ENOTDIR REGISTER_PCNTL_ERRNO_CONSTANT(ENOTDIR); #endif #ifdef ETXTBSY REGISTER_PCNTL_ERRNO_CONSTANT(ETXTBSY); #endif #ifdef ENOSPC REGISTER_PCNTL_ERRNO_CONSTANT(ENOSPC); #endif #ifdef EUSERS REGISTER_PCNTL_ERRNO_CONSTANT(EUSERS); #endif } static PHP_GINIT_FUNCTION(pcntl) { #if defined(COMPILE_DL_PCNTL) && defined(ZTS) ZEND_TSRMLS_CACHE_UPDATE(); #endif memset(pcntl_globals, 0, sizeof(*pcntl_globals)); } PHP_RINIT_FUNCTION(pcntl) { php_add_tick_function(pcntl_signal_dispatch, NULL); zend_hash_init(&PCNTL_G(php_signal_table), 16, NULL, ZVAL_PTR_DTOR, 0); PCNTL_G(head) = PCNTL_G(tail) = PCNTL_G(spares) = NULL; PCNTL_G(async_signals) = 0; PCNTL_G(last_error) = 0; return SUCCESS; } PHP_MINIT_FUNCTION(pcntl) { php_register_signal_constants(INIT_FUNC_ARGS_PASSTHRU); php_pcntl_register_errno_constants(INIT_FUNC_ARGS_PASSTHRU); orig_interrupt_function = zend_interrupt_function; zend_interrupt_function = pcntl_interrupt_function; return SUCCESS; } PHP_MSHUTDOWN_FUNCTION(pcntl) { return SUCCESS; } PHP_RSHUTDOWN_FUNCTION(pcntl) { struct php_pcntl_pending_signal *sig; /* FIXME: if a signal is delivered after this point, things will go pear shaped; * need to remove signal handlers */ zend_hash_destroy(&PCNTL_G(php_signal_table)); while (PCNTL_G(head)) { sig = PCNTL_G(head); PCNTL_G(head) = sig->next; efree(sig); } while (PCNTL_G(spares)) { sig = PCNTL_G(spares); PCNTL_G(spares) = sig->next; efree(sig); } return SUCCESS; } PHP_MINFO_FUNCTION(pcntl) { php_info_print_table_start(); php_info_print_table_header(2, "pcntl support", "enabled"); php_info_print_table_end(); } /* {{{ Forks the currently running process following the same behavior as the UNIX fork() system call*/ PHP_FUNCTION(pcntl_fork) { pid_t id; if (zend_parse_parameters_none() == FAILURE) { RETURN_THROWS(); } id = fork(); if (id == -1) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "Error %d", errno); } RETURN_LONG((zend_long) id); } /* }}} */ /* {{{ Set an alarm clock for delivery of a signal*/ PHP_FUNCTION(pcntl_alarm) { zend_long seconds; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &seconds) == FAILURE) { RETURN_THROWS(); } RETURN_LONG((zend_long) alarm(seconds)); } /* }}} */ #define PHP_RUSAGE_PARA(from, to, field) \ add_assoc_long(to, #field, from.field) #ifndef _OSD_POSIX #define PHP_RUSAGE_SPECIAL(from, to) \ PHP_RUSAGE_PARA(from, to, ru_oublock); \ PHP_RUSAGE_PARA(from, to, ru_inblock); \ PHP_RUSAGE_PARA(from, to, ru_msgsnd); \ PHP_RUSAGE_PARA(from, to, ru_msgrcv); \ PHP_RUSAGE_PARA(from, to, ru_maxrss); \ PHP_RUSAGE_PARA(from, to, ru_ixrss); \ PHP_RUSAGE_PARA(from, to, ru_idrss); \ PHP_RUSAGE_PARA(from, to, ru_minflt); \ PHP_RUSAGE_PARA(from, to, ru_majflt); \ PHP_RUSAGE_PARA(from, to, ru_nsignals); \ PHP_RUSAGE_PARA(from, to, ru_nvcsw); \ PHP_RUSAGE_PARA(from, to, ru_nivcsw); \ PHP_RUSAGE_PARA(from, to, ru_nswap); #else /*_OSD_POSIX*/ #define PHP_RUSAGE_SPECIAL(from, to) #endif #define PHP_RUSAGE_COMMON(from ,to) \ PHP_RUSAGE_PARA(from, to, ru_utime.tv_usec); \ PHP_RUSAGE_PARA(from, to, ru_utime.tv_sec); \ PHP_RUSAGE_PARA(from, to, ru_stime.tv_usec); \ PHP_RUSAGE_PARA(from, to, ru_stime.tv_sec); #define PHP_RUSAGE_TO_ARRAY(from, to) \ if (to) { \ PHP_RUSAGE_SPECIAL(from, to) \ PHP_RUSAGE_COMMON(from, to); \ } /* {{{ Waits on or returns the status of a forked child as defined by the waitpid() system call */ PHP_FUNCTION(pcntl_waitpid) { zend_long pid, options = 0; zval *z_status = NULL, *z_rusage = NULL; int status; pid_t child_id; #ifdef HAVE_WAIT4 struct rusage rusage; #endif if (zend_parse_parameters(ZEND_NUM_ARGS(), "lz|lz", &pid, &z_status, &options, &z_rusage) == FAILURE) { RETURN_THROWS(); } status = zval_get_long(z_status); #ifdef HAVE_WAIT4 if (z_rusage) { z_rusage = zend_try_array_init(z_rusage); if (!z_rusage) { RETURN_THROWS(); } memset(&rusage, 0, sizeof(struct rusage)); child_id = wait4((pid_t) pid, &status, options, &rusage); } else { child_id = waitpid((pid_t) pid, &status, options); } #else child_id = waitpid((pid_t) pid, &status, options); #endif if (child_id < 0) { PCNTL_G(last_error) = errno; } #ifdef HAVE_WAIT4 if (child_id > 0) { PHP_RUSAGE_TO_ARRAY(rusage, z_rusage); } #endif ZEND_TRY_ASSIGN_REF_LONG(z_status, status); RETURN_LONG((zend_long) child_id); } /* }}} */ /* {{{ Waits on or returns the status of a forked child as defined by the waitpid() system call */ PHP_FUNCTION(pcntl_wait) { zend_long options = 0; zval *z_status = NULL, *z_rusage = NULL; int status; pid_t child_id; #ifdef HAVE_WAIT3 struct rusage rusage; #endif if (zend_parse_parameters(ZEND_NUM_ARGS(), "z|lz", &z_status, &options, &z_rusage) == FAILURE) { RETURN_THROWS(); } status = zval_get_long(z_status); #ifdef HAVE_WAIT3 if (z_rusage) { z_rusage = zend_try_array_init(z_rusage); if (!z_rusage) { RETURN_THROWS(); } memset(&rusage, 0, sizeof(struct rusage)); child_id = wait3(&status, options, &rusage); } else if (options) { child_id = wait3(&status, options, NULL); } else { child_id = wait(&status); } #else child_id = wait(&status); #endif if (child_id < 0) { PCNTL_G(last_error) = errno; } #ifdef HAVE_WAIT3 if (child_id > 0) { PHP_RUSAGE_TO_ARRAY(rusage, z_rusage); } #endif ZEND_TRY_ASSIGN_REF_LONG(z_status, status); RETURN_LONG((zend_long) child_id); } /* }}} */ #undef PHP_RUSAGE_PARA #undef PHP_RUSAGE_SPECIAL #undef PHP_RUSAGE_COMMON #undef PHP_RUSAGE_TO_ARRAY /* {{{ Returns true if the child status code represents a successful exit */ PHP_FUNCTION(pcntl_wifexited) { zend_long status_word; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &status_word) == FAILURE) { RETURN_THROWS(); } #ifdef WIFEXITED int int_status_word = (int) status_word; if (WIFEXITED(int_status_word)) { RETURN_TRUE; } #endif RETURN_FALSE; } /* }}} */ /* {{{ Returns true if the child status code represents a stopped process (WUNTRACED must have been used with waitpid) */ PHP_FUNCTION(pcntl_wifstopped) { zend_long status_word; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &status_word) == FAILURE) { RETURN_THROWS(); } #ifdef WIFSTOPPED int int_status_word = (int) status_word; if (WIFSTOPPED(int_status_word)) { RETURN_TRUE; } #endif RETURN_FALSE; } /* }}} */ /* {{{ Returns true if the child status code represents a process that was terminated due to a signal */ PHP_FUNCTION(pcntl_wifsignaled) { zend_long status_word; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &status_word) == FAILURE) { RETURN_THROWS(); } #ifdef WIFSIGNALED int int_status_word = (int) status_word; if (WIFSIGNALED(int_status_word)) { RETURN_TRUE; } #endif RETURN_FALSE; } /* }}} */ /* {{{ Returns true if the child status code represents a process that was resumed due to a SIGCONT signal */ PHP_FUNCTION(pcntl_wifcontinued) { zend_long status_word; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &status_word) == FAILURE) { RETURN_THROWS(); } #ifdef HAVE_WCONTINUED int int_status_word = (int) status_word; if (WIFCONTINUED(int_status_word)) { RETURN_TRUE; } #endif RETURN_FALSE; } /* }}} */ /* {{{ Returns the status code of a child's exit */ PHP_FUNCTION(pcntl_wexitstatus) { zend_long status_word; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &status_word) == FAILURE) { RETURN_THROWS(); } #ifdef WEXITSTATUS int int_status_word = (int) status_word; RETURN_LONG(WEXITSTATUS(int_status_word)); #else RETURN_FALSE; #endif } /* }}} */ /* {{{ Returns the number of the signal that terminated the process who's status code is passed */ PHP_FUNCTION(pcntl_wtermsig) { zend_long status_word; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &status_word) == FAILURE) { RETURN_THROWS(); } #ifdef WTERMSIG int int_status_word = (int) status_word; RETURN_LONG(WTERMSIG(int_status_word)); #else RETURN_FALSE; #endif } /* }}} */ /* {{{ Returns the number of the signal that caused the process to stop who's status code is passed */ PHP_FUNCTION(pcntl_wstopsig) { zend_long status_word; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &status_word) == FAILURE) { RETURN_THROWS(); } #ifdef WSTOPSIG int int_status_word = (int) status_word; RETURN_LONG(WSTOPSIG(int_status_word)); #else RETURN_FALSE; #endif } /* }}} */ /* {{{ Executes specified program in current process space as defined by exec(2) */ PHP_FUNCTION(pcntl_exec) { zval *args = NULL, *envs = NULL; zval *element; HashTable *args_hash, *envs_hash; int argc = 0, argi = 0; int envc = 0, envi = 0; char **argv = NULL, **envp = NULL; char **current_arg, **pair; int pair_length; zend_string *key; char *path; size_t path_len; zend_ulong key_num; if (zend_parse_parameters(ZEND_NUM_ARGS(), "p|aa", &path, &path_len, &args, &envs) == FAILURE) { RETURN_THROWS(); } if (ZEND_NUM_ARGS() > 1) { /* Build argument list */ SEPARATE_ARRAY(args); args_hash = Z_ARRVAL_P(args); argc = zend_hash_num_elements(args_hash); argv = safe_emalloc((argc + 2), sizeof(char *), 0); *argv = path; current_arg = argv+1; ZEND_HASH_FOREACH_VAL(args_hash, element) { if (argi >= argc) break; if (!try_convert_to_string(element)) { efree(argv); RETURN_THROWS(); } *current_arg = Z_STRVAL_P(element); argi++; current_arg++; } ZEND_HASH_FOREACH_END(); *current_arg = NULL; } else { argv = emalloc(2 * sizeof(char *)); argv[0] = path; argv[1] = NULL; } if ( ZEND_NUM_ARGS() == 3 ) { /* Build environment pair list */ SEPARATE_ARRAY(envs); envs_hash = Z_ARRVAL_P(envs); envc = zend_hash_num_elements(envs_hash); pair = envp = safe_emalloc((envc + 1), sizeof(char *), 0); ZEND_HASH_FOREACH_KEY_VAL(envs_hash, key_num, key, element) { if (envi >= envc) break; if (!key) { key = zend_long_to_str(key_num); } else { zend_string_addref(key); } if (!try_convert_to_string(element)) { zend_string_release(key); efree(argv); efree(envp); RETURN_THROWS(); } /* Length of element + equal sign + length of key + null */ pair_length = Z_STRLEN_P(element) + ZSTR_LEN(key) + 2; *pair = emalloc(pair_length); strlcpy(*pair, ZSTR_VAL(key), ZSTR_LEN(key) + 1); strlcat(*pair, "=", pair_length); strlcat(*pair, Z_STRVAL_P(element), pair_length); /* Cleanup */ zend_string_release_ex(key, 0); envi++; pair++; } ZEND_HASH_FOREACH_END(); *(pair) = NULL; if (execve(path, argv, envp) == -1) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "Error has occurred: (errno %d) %s", errno, strerror(errno)); } /* Cleanup */ for (pair = envp; *pair != NULL; pair++) efree(*pair); efree(envp); } else { if (execv(path, argv) == -1) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "Error has occurred: (errno %d) %s", errno, strerror(errno)); } } efree(argv); RETURN_FALSE; } /* }}} */ /* {{{ Assigns a system signal handler to a PHP function */ PHP_FUNCTION(pcntl_signal) { zval *handle; zend_long signo; bool restart_syscalls = 1; bool restart_syscalls_is_null = 1; char *error = NULL; if (zend_parse_parameters(ZEND_NUM_ARGS(), "lz|b!", &signo, &handle, &restart_syscalls, &restart_syscalls_is_null) == FAILURE) { RETURN_THROWS(); } if (signo < 1) { zend_argument_value_error(1, "must be greater than or equal to 1"); RETURN_THROWS(); } if (signo >= NSIG) { zend_argument_value_error(1, "must be less than %d", NSIG); RETURN_THROWS(); } if (!PCNTL_G(spares)) { /* since calling malloc() from within a signal handler is not portable, * pre-allocate a few records for recording signals */ int i; for (i = 0; i < NSIG; i++) { struct php_pcntl_pending_signal *psig; psig = emalloc(sizeof(*psig)); psig->next = PCNTL_G(spares); PCNTL_G(spares) = psig; } } /* If restart_syscalls was not explicitly specified and the signal is SIGALRM, then default * restart_syscalls to false. PHP used to enforce that restart_syscalls is false for SIGALRM, * so we keep this differing default to reduce the degree of BC breakage. */ if (restart_syscalls_is_null && signo == SIGALRM) { restart_syscalls = 0; } /* Special long value case for SIG_DFL and SIG_IGN */ if (Z_TYPE_P(handle) == IS_LONG) { if (Z_LVAL_P(handle) != (zend_long) SIG_DFL && Z_LVAL_P(handle) != (zend_long) SIG_IGN) { zend_argument_value_error(2, "must be either SIG_DFL or SIG_IGN when an integer value is given"); RETURN_THROWS(); } if (php_signal(signo, (Sigfunc *) Z_LVAL_P(handle), (int) restart_syscalls) == (void *)SIG_ERR) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "Error assigning signal"); RETURN_FALSE; } zend_hash_index_update(&PCNTL_G(php_signal_table), signo, handle); RETURN_TRUE; } if (!zend_is_callable_ex(handle, NULL, 0, NULL, NULL, &error)) { zend_string *func_name = zend_get_callable_name(handle); PCNTL_G(last_error) = EINVAL; zend_argument_type_error(2, "must be of type callable|int, %s given", zend_zval_type_name(handle)); zend_string_release_ex(func_name, 0); efree(error); RETURN_THROWS(); } ZEND_ASSERT(!error); /* Add the function name to our signal table */ handle = zend_hash_index_update(&PCNTL_G(php_signal_table), signo, handle); Z_TRY_ADDREF_P(handle); if (php_signal4(signo, pcntl_signal_handler, (int) restart_syscalls, 1) == (void *)SIG_ERR) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "Error assigning signal"); RETURN_FALSE; } RETURN_TRUE; } /* }}} */ /* {{{ Gets signal handler */ PHP_FUNCTION(pcntl_signal_get_handler) { zval *prev_handle; zend_long signo; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &signo) == FAILURE) { RETURN_THROWS(); } if (signo < 1 || signo > 32) { zend_argument_value_error(1, "must be between 1 and 32"); RETURN_THROWS(); } if ((prev_handle = zend_hash_index_find(&PCNTL_G(php_signal_table), signo)) != NULL) { RETURN_COPY(prev_handle); } else { RETURN_LONG((zend_long)SIG_DFL); } } /* {{{ Dispatch signals to signal handlers */ PHP_FUNCTION(pcntl_signal_dispatch) { if (zend_parse_parameters_none() == FAILURE) { RETURN_THROWS(); } pcntl_signal_dispatch(); RETURN_TRUE; } /* }}} */ #ifdef HAVE_SIGPROCMASK /* {{{ Examine and change blocked signals */ PHP_FUNCTION(pcntl_sigprocmask) { zend_long how, signo; zval *user_set, *user_oldset = NULL, *user_signo; sigset_t set, oldset; if (zend_parse_parameters(ZEND_NUM_ARGS(), "la|z", &how, &user_set, &user_oldset) == FAILURE) { RETURN_THROWS(); } if (sigemptyset(&set) != 0 || sigemptyset(&oldset) != 0) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "%s", strerror(errno)); RETURN_FALSE; } ZEND_HASH_FOREACH_VAL(Z_ARRVAL_P(user_set), user_signo) { signo = zval_get_long(user_signo); if (sigaddset(&set, signo) != 0) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "%s", strerror(errno)); RETURN_FALSE; } } ZEND_HASH_FOREACH_END(); if (sigprocmask(how, &set, &oldset) != 0) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "%s", strerror(errno)); RETURN_FALSE; } if (user_oldset != NULL) { user_oldset = zend_try_array_init(user_oldset); if (!user_oldset) { RETURN_THROWS(); } for (signo = 1; signo < NSIG; ++signo) { if (sigismember(&oldset, signo) != 1) { continue; } add_next_index_long(user_oldset, signo); } } RETURN_TRUE; } /* }}} */ #endif #ifdef HAVE_STRUCT_SIGINFO_T # if defined(HAVE_SIGWAITINFO) && defined(HAVE_SIGTIMEDWAIT) static void pcntl_sigwaitinfo(INTERNAL_FUNCTION_PARAMETERS, int timedwait) /* {{{ */ { zval *user_set, *user_signo, *user_siginfo = NULL; zend_long tv_sec = 0, tv_nsec = 0; sigset_t set; int signo; siginfo_t siginfo; struct timespec timeout; if (timedwait) { if (zend_parse_parameters(ZEND_NUM_ARGS(), "a|zll", &user_set, &user_siginfo, &tv_sec, &tv_nsec) == FAILURE) { RETURN_THROWS(); } } else { if (zend_parse_parameters(ZEND_NUM_ARGS(), "a|z", &user_set, &user_siginfo) == FAILURE) { RETURN_THROWS(); } } if (sigemptyset(&set) != 0) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "%s", strerror(errno)); RETURN_FALSE; } ZEND_HASH_FOREACH_VAL(Z_ARRVAL_P(user_set), user_signo) { signo = zval_get_long(user_signo); if (sigaddset(&set, signo) != 0) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "%s", strerror(errno)); RETURN_FALSE; } } ZEND_HASH_FOREACH_END(); if (timedwait) { timeout.tv_sec = (time_t) tv_sec; timeout.tv_nsec = tv_nsec; signo = sigtimedwait(&set, &siginfo, &timeout); } else { signo = sigwaitinfo(&set, &siginfo); } if (signo == -1 && errno != EAGAIN) { PCNTL_G(last_error) = errno; php_error_docref(NULL, E_WARNING, "%s", strerror(errno)); } /* * sigtimedwait and sigwaitinfo can return 0 on success on some * platforms, e.g. NetBSD */ if (!signo && siginfo.si_signo) { signo = siginfo.si_signo; } pcntl_siginfo_to_zval(signo, &siginfo, user_siginfo); RETURN_LONG(signo); } /* }}} */ /* {{{ Synchronously wait for queued signals */ PHP_FUNCTION(pcntl_sigwaitinfo) { pcntl_sigwaitinfo(INTERNAL_FUNCTION_PARAM_PASSTHRU, 0); } /* }}} */ /* {{{ Wait for queued signals */ PHP_FUNCTION(pcntl_sigtimedwait) { pcntl_sigwaitinfo(INTERNAL_FUNCTION_PARAM_PASSTHRU, 1); } /* }}} */ # endif static void pcntl_siginfo_to_zval(int signo, siginfo_t *siginfo, zval *user_siginfo) /* {{{ */ { if (signo > 0 && user_siginfo) { user_siginfo = zend_try_array_init(user_siginfo); if (!user_siginfo) { return; } add_assoc_long_ex(user_siginfo, "signo", sizeof("signo")-1, siginfo->si_signo); add_assoc_long_ex(user_siginfo, "errno", sizeof("errno")-1, siginfo->si_errno); add_assoc_long_ex(user_siginfo, "code", sizeof("code")-1, siginfo->si_code); switch(signo) { #ifdef SIGCHLD case SIGCHLD: add_assoc_long_ex(user_siginfo, "status", sizeof("status")-1, siginfo->si_status); # ifdef si_utime add_assoc_double_ex(user_siginfo, "utime", sizeof("utime")-1, siginfo->si_utime); # endif # ifdef si_stime add_assoc_double_ex(user_siginfo, "stime", sizeof("stime")-1, siginfo->si_stime); # endif add_assoc_long_ex(user_siginfo, "pid", sizeof("pid")-1, siginfo->si_pid); add_assoc_long_ex(user_siginfo, "uid", sizeof("uid")-1, siginfo->si_uid); break; case SIGUSR1: case SIGUSR2: add_assoc_long_ex(user_siginfo, "pid", sizeof("pid")-1, siginfo->si_pid); add_assoc_long_ex(user_siginfo, "uid", sizeof("uid")-1, siginfo->si_uid); break; #endif case SIGILL: case SIGFPE: case SIGSEGV: case SIGBUS: add_assoc_double_ex(user_siginfo, "addr", sizeof("addr")-1, (zend_long)siginfo->si_addr); break; #ifdef SIGPOLL case SIGPOLL: add_assoc_long_ex(user_siginfo, "band", sizeof("band")-1, siginfo->si_band); # ifdef si_fd add_assoc_long_ex(user_siginfo, "fd", sizeof("fd")-1, siginfo->si_fd); # endif break; #endif } #if defined(SIGRTMIN) && defined(SIGRTMAX) if (SIGRTMIN <= signo && signo <= SIGRTMAX) { add_assoc_long_ex(user_siginfo, "pid", sizeof("pid")-1, siginfo->si_pid); add_assoc_long_ex(user_siginfo, "uid", sizeof("uid")-1, siginfo->si_uid); } #endif } } /* }}} */ #endif #ifdef HAVE_GETPRIORITY /* {{{ Get the priority of any process */ PHP_FUNCTION(pcntl_getpriority) { zend_long who = PRIO_PROCESS; zend_long pid; bool pid_is_null = 1; int pri; if (zend_parse_parameters(ZEND_NUM_ARGS(), "|l!l", &pid, &pid_is_null, &who) == FAILURE) { RETURN_THROWS(); } /* needs to be cleared, since any returned value is valid */ errno = 0; pri = getpriority(who, pid_is_null ? getpid() : pid); if (errno) { PCNTL_G(last_error) = errno; switch (errno) { case ESRCH: php_error_docref(NULL, E_WARNING, "Error %d: No process was located using the given parameters", errno); break; case EINVAL: zend_argument_value_error(2, "must be one of PRIO_PGRP, PRIO_USER, or PRIO_PROCESS"); RETURN_THROWS(); default: php_error_docref(NULL, E_WARNING, "Unknown error %d has occurred", errno); break; } RETURN_FALSE; } RETURN_LONG(pri); } /* }}} */ #endif #ifdef HAVE_SETPRIORITY /* {{{ Change the priority of any process */ PHP_FUNCTION(pcntl_setpriority) { zend_long who = PRIO_PROCESS; zend_long pid; bool pid_is_null = 1; zend_long pri; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l|l!l", &pri, &pid, &pid_is_null, &who) == FAILURE) { RETURN_THROWS(); } if (setpriority(who, pid_is_null ? getpid() : pid, pri)) { PCNTL_G(last_error) = errno; switch (errno) { case ESRCH: php_error_docref(NULL, E_WARNING, "Error %d: No process was located using the given parameters", errno); break; case EINVAL: zend_argument_value_error(3, "must be one of PRIO_PGRP, PRIO_USER, or PRIO_PROCESS"); RETURN_THROWS(); case EPERM: php_error_docref(NULL, E_WARNING, "Error %d: A process was located, but neither its effective nor real user ID matched the effective user ID of the caller", errno); break; case EACCES: php_error_docref(NULL, E_WARNING, "Error %d: Only a super user may attempt to increase the process priority", errno); break; default: php_error_docref(NULL, E_WARNING, "Unknown error %d has occurred", errno); break; } RETURN_FALSE; } RETURN_TRUE; } /* }}} */ #endif /* {{{ Retrieve the error number set by the last pcntl function which failed. */ PHP_FUNCTION(pcntl_get_last_error) { if (zend_parse_parameters_none() == FAILURE) { RETURN_THROWS(); } RETURN_LONG(PCNTL_G(last_error)); } /* }}} */ /* {{{ Retrieve the system error message associated with the given errno. */ PHP_FUNCTION(pcntl_strerror) { zend_long error; if (zend_parse_parameters(ZEND_NUM_ARGS(), "l", &error) == FAILURE) { RETURN_THROWS(); } RETURN_STRING(strerror(error)); } /* }}} */ /* Our custom signal handler that calls the appropriate php_function */ #ifdef HAVE_STRUCT_SIGINFO_T static void pcntl_signal_handler(int signo, siginfo_t *siginfo, void *context) #else static void pcntl_signal_handler(int signo) #endif { struct php_pcntl_pending_signal *psig; psig = PCNTL_G(spares); if (!psig) { /* oops, too many signals for us to track, so we'll forget about this one */ return; } PCNTL_G(spares) = psig->next; psig->signo = signo; psig->next = NULL; #ifdef HAVE_STRUCT_SIGINFO_T psig->siginfo = *siginfo; #endif /* the head check is important, as the tick handler cannot atomically clear both * the head and tail */ if (PCNTL_G(head) && PCNTL_G(tail)) { PCNTL_G(tail)->next = psig; } else { PCNTL_G(head) = psig; } PCNTL_G(tail) = psig; PCNTL_G(pending_signals) = 1; if (PCNTL_G(async_signals)) { EG(vm_interrupt) = 1; } } void pcntl_signal_dispatch() { zval params[2], *handle, retval; struct php_pcntl_pending_signal *queue, *next; sigset_t mask; sigset_t old_mask; if(!PCNTL_G(pending_signals)) { return; } /* Mask all signals */ sigfillset(&mask); sigprocmask(SIG_BLOCK, &mask, &old_mask); /* Bail if the queue is empty or if we are already playing the queue */ if (!PCNTL_G(head) || PCNTL_G(processing_signal_queue)) { sigprocmask(SIG_SETMASK, &old_mask, NULL); return; } /* Prevent reentrant handler calls */ PCNTL_G(processing_signal_queue) = 1; queue = PCNTL_G(head); PCNTL_G(head) = NULL; /* simple stores are atomic */ /* Allocate */ while (queue) { if ((handle = zend_hash_index_find(&PCNTL_G(php_signal_table), queue->signo)) != NULL) { if (Z_TYPE_P(handle) != IS_LONG) { ZVAL_NULL(&retval); ZVAL_LONG(¶ms[0], queue->signo); #ifdef HAVE_STRUCT_SIGINFO_T array_init(¶ms[1]); pcntl_siginfo_to_zval(queue->signo, &queue->siginfo, ¶ms[1]); #else ZVAL_NULL(¶ms[1]); #endif /* Call php signal handler - Note that we do not report errors, and we ignore the return value */ /* FIXME: this is probably broken when multiple signals are handled in this while loop (retval) */ call_user_function(NULL, NULL, handle, &retval, 2, params); zval_ptr_dtor(&retval); #ifdef HAVE_STRUCT_SIGINFO_T zval_ptr_dtor(¶ms[1]); #endif } } next = queue->next; queue->next = PCNTL_G(spares); PCNTL_G(spares) = queue; queue = next; } PCNTL_G(pending_signals) = 0; /* Re-enable queue */ PCNTL_G(processing_signal_queue) = 0; /* return signal mask to previous state */ sigprocmask(SIG_SETMASK, &old_mask, NULL); } /* {{{ Enable/disable asynchronous signal handling and return the old setting. */ PHP_FUNCTION(pcntl_async_signals) { bool on, on_is_null = 1; if (zend_parse_parameters(ZEND_NUM_ARGS(), "|b!", &on, &on_is_null) == FAILURE) { RETURN_THROWS(); } if (on_is_null) { RETURN_BOOL(PCNTL_G(async_signals)); } RETVAL_BOOL(PCNTL_G(async_signals)); PCNTL_G(async_signals) = on; } /* }}} */ #ifdef HAVE_UNSHARE /* {{{ disassociate parts of the process execution context */ PHP_FUNCTION(pcntl_unshare) { zend_long flags; ZEND_PARSE_PARAMETERS_START(1, 1) Z_PARAM_LONG(flags) ZEND_PARSE_PARAMETERS_END(); if (unshare(flags) == -1) { PCNTL_G(last_error) = errno; switch (errno) { #ifdef EINVAL case EINVAL: zend_argument_value_error(1, "must be a combination of CLONE_* flags"); RETURN_THROWS(); break; #endif #ifdef ENOMEM case ENOMEM: php_error_docref(NULL, E_WARNING, "Error %d: Insufficient memory for unshare", errno); break; #endif #ifdef EPERM case EPERM: php_error_docref(NULL, E_WARNING, "Error %d: No privilege to use these flags", errno); break; #endif #ifdef ENOSPC case ENOSPC: php_error_docref(NULL, E_WARNING, "Error %d: Reached the maximum nesting limit for one of the specified namespaces", errno); break; #endif #ifdef EUSERS case EUSERS: php_error_docref(NULL, E_WARNING, "Error %d: Reached the maximum nesting limit for the user namespace", errno); break; #endif default: php_error_docref(NULL, E_WARNING, "Unknown error %d has occurred", errno); break; } RETURN_FALSE; } RETURN_TRUE; } /* }}} */ #endif static void pcntl_interrupt_function(zend_execute_data *execute_data) { pcntl_signal_dispatch(); if (orig_interrupt_function) { orig_interrupt_function(execute_data); } }