#include "thread.h" <<<<<<< thread.c #ifndef DEBUG #define DEBUG #endif #ifdef DEBUG #define dprintf(args) printf args #else #define dprintf(args) #endif ======= #ifdef DEBUG #define dprintf(args) printf args #else #define dprintf(args) #endif >>>>>>> 2.3 #ifdef __sgi #include #include #include #include #include #include #define MAXPROC 100 /* max # of threads that can be started */ static usptr_t *shared_arena; static ulock_t count_lock; /* protection for some variables */ static ulock_t wait_lock; /* lock used to wait for other threads */ static int waiting_for_threads; /* protected by count_lock */ static int nthreads; /* protected by count_lock */ static int exit_status; static int do_exit; static int exiting; /* we're already exiting (for maybe_exit) */ static pid_t my_pid; /* PID of main thread */ static pid_t pidlist[MAXPROC]; /* PIDs of other threads */ static int maxpidindex; /* # of PIDs in pidlist */ #endif #ifdef sun #include #include #define STACKSIZE 1000 /* stacksize for a thread */ #define NSTACKS 2 /* # stacks to be put in cache initialy */ struct lock { int lock_locked; cv_t lock_condvar; mon_t lock_monitor; }; #endif #ifdef C_THREADS #include #endif #ifdef __STDC__ #define _P(args) args #define _P0() (void) #define _P1(v,t) (t) #define _P2(v1,t1,v2,t2) (t1,t2) #else #define _P(args) () #define _P0() () #define _P1(v,t) (v) t; #define _P2(v1,t1,v2,t2) (v1,v2) t1; t2; #endif static int initialized; <<<<<<< thread.c #ifdef __sgi /* * This routine is called as a signal handler when another thread * exits. When that happens, we must see whether we have to exit as * well (because of an exit_prog()) or whether we should continue on. */ static void exit_sig _P0() { dprintf(("exit_sig called\n")); if (exiting && getpid() == my_pid) { dprintf(("already exiting\n")); return; } if (do_exit) { dprintf(("exiting in exit_sig\n")); exit_thread(); } } /* * This routine is called when a process calls exit(). If that wasn't * done from the library, we do as if an exit_prog() was intended. */ static void maybe_exit _P0() { dprintf(("maybe_exit called\n")); if (exiting) { dprintf(("already exiting\n")); return; } exit_prog(0); } #endif /* * Initialization. */ void init_thread _P0() { #ifdef __sgi struct sigaction s; #endif dprintf(("init_thread called\n")); if (initialized) return; initialized = 1; #ifdef __sgi my_pid = getpid(); /* so that we know which is the main thread */ atexit(maybe_exit); s.sa_handler = exit_sig; sigemptyset(&s.sa_mask); sigaddset(&s.sa_mask, SIGUSR1); s.sa_flags = 0; sigaction(SIGUSR1, &s, 0); prctl(PR_SETEXITSIG, SIGUSR1); usconfig(CONF_ARENATYPE, US_SHAREDONLY); /*usconfig(CONF_LOCKTYPE, US_DEBUGPLUS);*/ shared_arena = usinit(tmpnam(0)); count_lock = usnewlock(shared_arena); (void) usinitlock(count_lock); wait_lock = usnewlock(shared_arena); #endif #ifdef sun lwp_setstkcache(STACKSIZE, NSTACKS); #endif #ifdef C_THREADS cthread_init(); #endif } /* * Thread support. */ ======= #ifdef __sgi /* * This routine is called as a signal handler when another thread * exits. When that happens, we must see whether we have to exit as * well (because of an exit_prog()) or whether we should continue on. */ static void exit_sig _P0() { dprintf(("exit_sig called\n")); if (exiting && getpid() == my_pid) { dprintf(("already exiting\n")); return; } if (do_exit) { dprintf(("exiting in exit_sig\n")); exit_thread(); } } /* * This routune is called when a process calls exit(). If that wasn't * done from the library, we do as if an exit_prog() was intended. */ static void maybe_exit _P0() { dprintf(("maybe_exit called\n")); if (exiting) { dprintf(("already exiting\n")); return; } exit_prog(0); } #endif /* * Initialization. */ void init_thread _P0() { #ifdef __sgi struct sigaction s; #endif dprintf(("init_thread called\n")); if (initialized) return; initialized = 1; #ifdef __sgi my_pid = getpid(); /* so that we know which is the main thread */ atexit(maybe_exit); s.sa_handler = exit_sig; sigemptyset(&s.sa_mask); sigaddset(&s.sa_mask, SIGUSR1); s.sa_flags = 0; sigaction(SIGUSR1, &s, 0); prctl(PR_SETEXITSIG, SIGUSR1); usconfig(CONF_ARENATYPE, US_SHAREDONLY); /*usconfig(CONF_LOCKTYPE, US_DEBUGPLUS);*/ shared_arena = usinit(tmpnam(0)); count_lock = usnewlock(shared_arena); (void) usinitlock(count_lock); wait_lock = usnewlock(shared_arena); #endif #ifdef sun lwp_setstkcache(STACKSIZE, NSTACKS); #endif #ifdef C_THREADS cthread_init(); #endif } /* * Thread support. */ >>>>>>> 2.3 int start_new_thread _P2(func, void (*func) _P((void *)), arg, void *arg) { #ifdef sun thread_t tid; #endif int success = 0; /* init not needed when SOLARIS and */ /* C_THREADS implemented properly */ dprintf(("start_new_thread called\n")); if (!initialized) init_thread(); #ifdef __sgi if (ussetlock(count_lock) == 0) return 0; if (maxpidindex >= MAXPROC) success = -1; else { success = sproc(func, PR_SALL, arg); if (success >= 0) { nthreads++; pidlist[maxpidindex++] = success; } } (void) usunsetlock(count_lock); #endif #ifdef SOLARIS (void) thread_create(0, 0, func, arg, THREAD_NEW_LWP); #endif #ifdef sun success = lwp_create(&tid, func, MINPRIO, 0, lwp_newstk(), 1, arg); #endif #ifdef C_THREADS (void) cthread_fork(func, arg); #endif return success < 0 ? 0 : 1; } static void do_exit_thread _P1(no_cleanup, int no_cleanup) { dprintf(("exit_thread called\n")); if (!initialized) if (no_cleanup) _exit(0); else exit(0); #ifdef __sgi (void) ussetlock(count_lock); nthreads--; if (getpid() == my_pid) { /* main thread; wait for other threads to exit */ exiting = 1; if (do_exit) { int i; /* notify other threads */ for (i = 0; i < maxpidindex; i++) (void) kill(pidlist[i], SIGUSR1); } waiting_for_threads = 1; ussetlock(wait_lock); for (;;) { if (nthreads < 0) { dprintf(("really exit (%d)\n", exit_status)); if (no_cleanup) _exit(exit_status); else exit(exit_status); } usunsetlock(count_lock); dprintf(("waiting for other threads (%d)\n", nthreads)); ussetlock(wait_lock); ussetlock(count_lock); } } /* not the main thread */ if (waiting_for_threads) { dprintf(("main thread is waiting\n")); usunsetlock(wait_lock); } (void) usunsetlock(count_lock); _exit(0); #endif #ifdef SOLARIS thread_exit(); #endif #ifdef sun lwp_destroy(SELF); #endif #ifdef C_THREADS cthread_exit(0); #endif } void exit_thread _P0() { do_exit_thread(0); } void _exit_thread _P0() { do_exit_thread(1); } static void do_exit_prog _P2(status, int status, no_cleanup, int no_cleanup) { dprintf(("exit_prog(%d) called\n", status)); if (!initialized) if (no_cleanup) _exit(status); else exit(status); #ifdef __sgi do_exit = 1; exit_status = status; do_exit_thread(no_cleanup); #endif #ifdef sun pod_exit(status); #endif } void exit_prog _P1(status, int status) { do_exit_prog(status, 0); } void _exit_prog _P1(status, int status) { do_exit_prog(status, 1); } /* * Lock support. */ type_lock allocate_lock _P0() { #ifdef __sgi ulock_t lock; #endif #ifdef sun struct lock *lock; extern char *malloc(); #endif dprintf(("allocate_lock called\n")); if (!initialized) init_thread(); #ifdef __sgi lock = usnewlock(shared_arena); (void) usinitlock(lock); #endif #ifdef sun lock = (struct lock *) malloc(sizeof(struct lock)); lock->lock_locked = 0; (void) mon_create(&lock->lock_monitor); (void) cv_create(&lock->lock_condvar, lock->lock_monitor); #endif dprintf(("allocate_lock() -> %lx\n", (long)lock)); return (type_lock) lock; } void free_lock _P1(lock, type_lock lock) { dprintf(("free_lock(%lx) called\n", (long)lock)); #ifdef __sgi usfreelock((ulock_t) lock, shared_arena); #endif #ifdef sun mon_destroy(((struct lock *) lock)->lock_monitor); free((char *) lock); #endif } int acquire_lock _P2(lock, type_lock lock, waitflag, int waitflag) { int success; dprintf(("acquire_lock(%lx, %d) called\n", (long)lock, waitflag)); #ifdef __sgi if (waitflag) success = ussetlock((ulock_t) lock); else success = uscsetlock((ulock_t) lock, 1); /* Try it once */ #endif #ifdef sun success = 0; (void) mon_enter(((struct lock *) lock)->lock_monitor); if (waitflag) while (((struct lock *) lock)->lock_locked) cv_wait(((struct lock *) lock)->lock_condvar); if (!((struct lock *) lock)->lock_locked) { success = 1; ((struct lock *) lock)->lock_locked = 1; } cv_broadcast(((struct lock *) lock)->lock_condvar); mon_exit(((struct lock *) lock)->lock_monitor); #endif dprintf(("acquire_lock(%lx, %d) -> %d\n", (long)lock, waitflag, success)); return success; } void release_lock _P1(lock, type_lock lock) { dprintf(("release_lock(%lx) called\n", (long)lock)); #ifdef __sgi (void) usunsetlock((ulock_t) lock); #endif #ifdef sun (void) mon_enter(((struct lock *) lock)->lock_monitor); ((struct lock *) lock)->lock_locked = 0; cv_broadcast(((struct lock *) lock)->lock_condvar); mon_exit(((struct lock *) lock)->lock_monitor); #endif } /* * Semaphore support. */ type_sema allocate_sema _P1(value, int value) { #ifdef __sgi usema_t *sema; #endif dprintf(("allocate_sema called\n")); #ifdef __sgi sema = usnewsema(shared_arena, value); dprintf(("allocate_sema() -> %lx\n", (long) sema)); return (type_sema) sema; #endif } void free_sema _P1(sema, type_sema sema) { dprintf(("free_sema(%lx) called\n", (long) sema)); #ifdef __sgi usfreesema((usema_t *) sema, shared_arena); #endif } void down_sema _P1(sema, type_sema sema) { dprintf(("down_sema(%lx) called\n", (long) sema)); #ifdef __sgi (void) uspsema((usema_t *) sema); #endif dprintf(("down_sema(%lx) return\n", (long) sema)); } void up_sema _P1(sema, type_sema sema) { dprintf(("up_sema(%lx)\n", (long) sema)); #ifdef __sgi (void) usvsema((usema_t *) sema); #endif }