/***********************************************************************/ /* */ /* Objective Caml */ /* */ /* Xavier Leroy and Damien Doligez, INRIA Rocquencourt */ /* */ /* Copyright 1996 Institut National de Recherche en Informatique et */ /* en Automatique. All rights reserved. This file is distributed */ /* under the terms of the GNU Library General Public License, with */ /* the special exception on linking described in file ../LICENSE. */ /* */ /***********************************************************************/ /* $Id$ */ #include #include "alloc.h" #include "callback.h" #include "config.h" #include "fail.h" #include "memory.h" #include "misc.h" #include "mlvalues.h" #include "roots.h" #include "signals.h" #include "signals_machdep.h" #include "sys.h" #ifndef NSIG #define NSIG 64 #endif #ifdef _WIN32 typedef void (*sighandler)(int sig); extern sighandler caml_win32_signal(int sig, sighandler action); #define signal(sig,act) caml_win32_signal(sig,act) #endif CAMLexport long volatile caml_pending_signals[NSIG]; CAMLexport int volatile caml_something_to_do = 0; int volatile caml_force_major_slice = 0; value caml_signal_handlers = 0; CAMLexport void (* volatile caml_async_action_hook)(void) = NULL; void caml_process_event(void) { int signal_number; long signal_state; void (*async_action)(void); if (caml_force_major_slice) caml_minor_collection (); /* FIXME should be [caml_check_urgent_gc] */ for (signal_number = 0; signal_number < NSIG; signal_number++) { Read_and_clear(signal_state, caml_pending_signals[signal_number]); if (signal_state) caml_execute_signal(signal_number, 0); } Read_and_clear(async_action, caml_async_action_hook); if (async_action != NULL) (*async_action)(); } static long volatile caml_async_signal_mode = 0; static void caml_enter_blocking_section_default(void) { Assert (caml_async_signal_mode == 0); caml_async_signal_mode = 1; } static void caml_leave_blocking_section_default(void) { Assert (caml_async_signal_mode == 1); caml_async_signal_mode = 0; } static int caml_try_leave_blocking_section_default(void) { long res; Read_and_clear(res, caml_async_signal_mode); return res; } CAMLexport void (*caml_enter_blocking_section_hook)(void) = caml_enter_blocking_section_default; CAMLexport void (*caml_leave_blocking_section_hook)(void) = caml_leave_blocking_section_default; CAMLexport int (*caml_try_leave_blocking_section_hook)(void) = caml_try_leave_blocking_section_default; CAMLexport int caml_rev_convert_signal_number(int signo); void caml_execute_signal(int signal_number, int in_signal_handler) { value res; #ifdef POSIX_SIGNALS sigset_t sigs; /* Block the signal before executing the handler, and record in sigs the original signal mask */ sigemptyset(&sigs); sigaddset(&sigs, signal_number); sigprocmask(SIG_BLOCK, &sigs, &sigs); #endif res = caml_callback_exn( Field(caml_signal_handlers, signal_number), Val_int(caml_rev_convert_signal_number(signal_number))); #ifdef POSIX_SIGNALS if (! in_signal_handler) { /* Restore the original signal mask */ sigprocmask(SIG_SETMASK, &sigs, NULL); } else if (Is_exception_result(res)) { /* Restore the original signal mask and unblock the signal itself */ sigdelset(&sigs, signal_number); sigprocmask(SIG_SETMASK, &sigs, NULL); } #endif if (Is_exception_result(res)) caml_raise(Extract_exception(res)); } static void handle_signal(int signal_number) { #if !defined(POSIX_SIGNALS) && !defined(BSD_SIGNALS) signal(signal_number, handle_signal); #endif if (signal_number < 0 || signal_number >= NSIG) return; if (caml_try_leave_blocking_section_hook()) { caml_execute_signal(signal_number, 1); caml_enter_blocking_section_hook(); }else{ caml_pending_signals[signal_number] = 1; caml_something_to_do = 1; } } void caml_urge_major_slice (void) { caml_force_major_slice = 1; caml_something_to_do = 1; } CAMLexport void caml_enter_blocking_section(void) { int signal_number; long signal_state, pending; while (1){ /* Process all pending signals now */ for (signal_number = 0; signal_number < NSIG; signal_number++) { Read_and_clear(signal_state, caml_pending_signals[signal_number]); if (signal_state) caml_execute_signal(signal_number, 0); } caml_enter_blocking_section_hook (); /* Check again for pending signals. */ pending = 0; for (signal_number = 0; signal_number < NSIG; signal_number++) pending |= caml_pending_signals[signal_number]; /* If none, done; otherwise, try again */ if (!pending) break; caml_leave_blocking_section_hook (); } } CAMLexport void caml_leave_blocking_section(void) { #ifdef _WIN32 int signal_number; long signal_state; /* Under Win32, asynchronous signals such as ctrl-C are not processed immediately (see ctrl_handler in win32.c), but simply set [caml_pending_signal] and let the system call run to completion. Hence, test [caml_pending_signal] here and act upon it, before we get a chance to process the result of the system call. */ for (signal_number = 0; signal_number < NSIG; signal_number++) { Read_and_clear(signal_state, caml_pending_signals[signal_number]); if (signal_state) caml_execute_signal(signal_number, 0); } #endif caml_leave_blocking_section_hook (); } #ifndef SIGABRT #define SIGABRT -1 #endif #ifndef SIGALRM #define SIGALRM -1 #endif #ifndef SIGFPE #define SIGFPE -1 #endif #ifndef SIGHUP #define SIGHUP -1 #endif #ifndef SIGILL #define SIGILL -1 #endif #ifndef SIGINT #define SIGINT -1 #endif #ifndef SIGKILL #define SIGKILL -1 #endif #ifndef SIGPIPE #define SIGPIPE -1 #endif #ifndef SIGQUIT #define SIGQUIT -1 #endif #ifndef SIGSEGV #define SIGSEGV -1 #endif #ifndef SIGTERM #define SIGTERM -1 #endif #ifndef SIGUSR1 #define SIGUSR1 -1 #endif #ifndef SIGUSR2 #define SIGUSR2 -1 #endif #ifndef SIGCHLD #define SIGCHLD -1 #endif #ifndef SIGCONT #define SIGCONT -1 #endif #ifndef SIGSTOP #define SIGSTOP -1 #endif #ifndef SIGTSTP #define SIGTSTP -1 #endif #ifndef SIGTTIN #define SIGTTIN -1 #endif #ifndef SIGTTOU #define SIGTTOU -1 #endif #ifndef SIGVTALRM #define SIGVTALRM -1 #endif #ifndef SIGPROF #define SIGPROF -1 #endif static int posix_signals[] = { SIGABRT, SIGALRM, SIGFPE, SIGHUP, SIGILL, SIGINT, SIGKILL, SIGPIPE, SIGQUIT, SIGSEGV, SIGTERM, SIGUSR1, SIGUSR2, SIGCHLD, SIGCONT, SIGSTOP, SIGTSTP, SIGTTIN, SIGTTOU, SIGVTALRM, SIGPROF }; CAMLexport int caml_convert_signal_number(int signo) { if (signo < 0 && signo >= -(sizeof(posix_signals) / sizeof(int))) return posix_signals[-signo-1]; else return signo; } CAMLexport int caml_rev_convert_signal_number(int signo) { int i; for (i = 0; i < sizeof(posix_signals) / sizeof(int); i++) if (signo == posix_signals[i]) return -i - 1; return signo; } CAMLprim value caml_install_signal_handler(value signal_number, value action) { CAMLparam2 (signal_number, action); int sig; void (*act)(int signo), (*oldact)(int signo); #ifdef POSIX_SIGNALS struct sigaction sigact, oldsigact; #endif CAMLlocal1 (res); sig = caml_convert_signal_number(Int_val(signal_number)); if (sig < 0 || sig >= NSIG) caml_invalid_argument("Sys.signal: unavailable signal"); switch(action) { case Val_int(0): /* Signal_default */ act = SIG_DFL; break; case Val_int(1): /* Signal_ignore */ act = SIG_IGN; break; default: /* Signal_handle */ act = handle_signal; break; } #ifdef POSIX_SIGNALS sigact.sa_handler = act; sigemptyset(&sigact.sa_mask); sigact.sa_flags = 0; if (sigaction(sig, &sigact, &oldsigact) == -1) caml_sys_error(NO_ARG); oldact = oldsigact.sa_handler; #else oldact = signal(sig, act); if (oldact == SIG_ERR) caml_sys_error(NO_ARG); #endif if (oldact == handle_signal) { res = caml_alloc_small (1, 0); /* Signal_handle */ Field(res, 0) = Field(caml_signal_handlers, sig); } else if (oldact == SIG_IGN) res = Val_int(1); /* Signal_ignore */ else res = Val_int(0); /* Signal_default */ if (Is_block(action)) { if (caml_signal_handlers == 0) { caml_signal_handlers = caml_alloc(NSIG, 0); caml_register_global_root(&caml_signal_handlers); } caml_modify(&Field(caml_signal_handlers, sig), Field(action, 0)); } CAMLreturn (res); }