/* -*-c-*- */ /********************************************************************** thread_pthread.c - $Author$ Copyright (C) 2004-2007 Koichi Sasada **********************************************************************/ #ifdef THREAD_SYSTEM_DEPENDENT_IMPLEMENTATION #include "internal/gc.h" #include "internal/sanitizers.h" #include "rjit.h" #ifdef HAVE_SYS_RESOURCE_H #include #endif #ifdef HAVE_THR_STKSEGMENT #include #endif #if defined(HAVE_FCNTL_H) #include #elif defined(HAVE_SYS_FCNTL_H) #include #endif #ifdef HAVE_SYS_PRCTL_H #include #endif #if defined(HAVE_SYS_TIME_H) #include #endif #if defined(__HAIKU__) #include #endif #ifdef __linux__ #include /* for SYS_gettid */ #endif #include #include #if defined __APPLE__ # include #endif #if defined(HAVE_SYS_EVENTFD_H) && defined(HAVE_EVENTFD) # define USE_EVENTFD (1) # include #else # define USE_EVENTFD (0) #endif #if defined(HAVE_PTHREAD_CONDATTR_SETCLOCK) && \ defined(CLOCK_REALTIME) && defined(CLOCK_MONOTONIC) && \ defined(HAVE_CLOCK_GETTIME) static pthread_condattr_t condattr_mono; static pthread_condattr_t *condattr_monotonic = &condattr_mono; #else static const void *const condattr_monotonic = NULL; #endif #include COROUTINE_H #ifndef HAVE_SYS_EVENT_H #define HAVE_SYS_EVENT_H 0 #endif #ifndef HAVE_SYS_EPOLL_H #define HAVE_SYS_EPOLL_H 0 #else // force setting for debug // #undef HAVE_SYS_EPOLL_H // #define HAVE_SYS_EPOLL_H 0 #endif #ifndef USE_MN_THREADS #if defined(__EMSCRIPTEN__) || defined(COROUTINE_PTHREAD_CONTEXT) // on __EMSCRIPTEN__ provides epoll* declarations, but no implementations. // on COROUTINE_PTHREAD_CONTEXT, it doesn't worth to use it. #define USE_MN_THREADS 0 #elif HAVE_SYS_EPOLL_H #include #define USE_MN_THREADS 1 #elif HAVE_SYS_EVENT_H #include #define USE_MN_THREADS 1 #else #define USE_MN_THREADS 0 #endif #endif // native thread wrappers #define NATIVE_MUTEX_LOCK_DEBUG 0 static void mutex_debug(const char *msg, void *lock) { if (NATIVE_MUTEX_LOCK_DEBUG) { int r; static pthread_mutex_t dbglock = PTHREAD_MUTEX_INITIALIZER; if ((r = pthread_mutex_lock(&dbglock)) != 0) {exit(EXIT_FAILURE);} fprintf(stdout, "%s: %p\n", msg, lock); if ((r = pthread_mutex_unlock(&dbglock)) != 0) {exit(EXIT_FAILURE);} } } void rb_native_mutex_lock(pthread_mutex_t *lock) { int r; mutex_debug("lock", lock); if ((r = pthread_mutex_lock(lock)) != 0) { rb_bug_errno("pthread_mutex_lock", r); } } void rb_native_mutex_unlock(pthread_mutex_t *lock) { int r; mutex_debug("unlock", lock); if ((r = pthread_mutex_unlock(lock)) != 0) { rb_bug_errno("pthread_mutex_unlock", r); } } int rb_native_mutex_trylock(pthread_mutex_t *lock) { int r; mutex_debug("trylock", lock); if ((r = pthread_mutex_trylock(lock)) != 0) { if (r == EBUSY) { return EBUSY; } else { rb_bug_errno("pthread_mutex_trylock", r); } } return 0; } void rb_native_mutex_initialize(pthread_mutex_t *lock) { int r = pthread_mutex_init(lock, 0); mutex_debug("init", lock); if (r != 0) { rb_bug_errno("pthread_mutex_init", r); } } void rb_native_mutex_destroy(pthread_mutex_t *lock) { int r = pthread_mutex_destroy(lock); mutex_debug("destroy", lock); if (r != 0) { rb_bug_errno("pthread_mutex_destroy", r); } } void rb_native_cond_initialize(rb_nativethread_cond_t *cond) { int r = pthread_cond_init(cond, condattr_monotonic); if (r != 0) { rb_bug_errno("pthread_cond_init", r); } } void rb_native_cond_destroy(rb_nativethread_cond_t *cond) { int r = pthread_cond_destroy(cond); if (r != 0) { rb_bug_errno("pthread_cond_destroy", r); } } /* * In OS X 10.7 (Lion), pthread_cond_signal and pthread_cond_broadcast return * EAGAIN after retrying 8192 times. You can see them in the following page: * * http://www.opensource.apple.com/source/Libc/Libc-763.11/pthreads/pthread_cond.c * * The following rb_native_cond_signal and rb_native_cond_broadcast functions * need to retrying until pthread functions don't return EAGAIN. */ void rb_native_cond_signal(rb_nativethread_cond_t *cond) { int r; do { r = pthread_cond_signal(cond); } while (r == EAGAIN); if (r != 0) { rb_bug_errno("pthread_cond_signal", r); } } void rb_native_cond_broadcast(rb_nativethread_cond_t *cond) { int r; do { r = pthread_cond_broadcast(cond); } while (r == EAGAIN); if (r != 0) { rb_bug_errno("rb_native_cond_broadcast", r); } } void rb_native_cond_wait(rb_nativethread_cond_t *cond, pthread_mutex_t *mutex) { int r = pthread_cond_wait(cond, mutex); if (r != 0) { rb_bug_errno("pthread_cond_wait", r); } } static int native_cond_timedwait(rb_nativethread_cond_t *cond, pthread_mutex_t *mutex, const rb_hrtime_t *abs) { int r; struct timespec ts; /* * An old Linux may return EINTR. Even though POSIX says * "These functions shall not return an error code of [EINTR]". * http://pubs.opengroup.org/onlinepubs/009695399/functions/pthread_cond_timedwait.html * Let's hide it from arch generic code. */ do { rb_hrtime2timespec(&ts, abs); r = pthread_cond_timedwait(cond, mutex, &ts); } while (r == EINTR); if (r != 0 && r != ETIMEDOUT) { rb_bug_errno("pthread_cond_timedwait", r); } return r; } static rb_hrtime_t native_cond_timeout(rb_nativethread_cond_t *cond, const rb_hrtime_t rel) { if (condattr_monotonic) { return rb_hrtime_add(rb_hrtime_now(), rel); } else { struct timespec ts; rb_timespec_now(&ts); return rb_hrtime_add(rb_timespec2hrtime(&ts), rel); } } void rb_native_cond_timedwait(rb_nativethread_cond_t *cond, pthread_mutex_t *mutex, unsigned long msec) { rb_hrtime_t hrmsec = native_cond_timeout(cond, RB_HRTIME_PER_MSEC * msec); native_cond_timedwait(cond, mutex, &hrmsec); } // thread scheduling static rb_internal_thread_event_hook_t *rb_internal_thread_event_hooks = NULL; static void rb_thread_execute_hooks(rb_event_flag_t event, rb_thread_t *th); #if 0 static const char * event_name(rb_event_flag_t event) { switch (event) { case RUBY_INTERNAL_THREAD_EVENT_STARTED: return "STARTED"; case RUBY_INTERNAL_THREAD_EVENT_READY: return "READY"; case RUBY_INTERNAL_THREAD_EVENT_RESUMED: return "RESUMED"; case RUBY_INTERNAL_THREAD_EVENT_SUSPENDED: return "SUSPENDED"; case RUBY_INTERNAL_THREAD_EVENT_EXITED: return "EXITED"; } return "no-event"; } #define RB_INTERNAL_THREAD_HOOK(event, th) \ if (UNLIKELY(rb_internal_thread_event_hooks)) { \ fprintf(stderr, "[thread=%"PRIxVALUE"] %s in %s (%s:%d)\n", th->self, event_name(event), __func__, __FILE__, __LINE__); \ rb_thread_execute_hooks(event, th); \ } #else #define RB_INTERNAL_THREAD_HOOK(event, th) if (UNLIKELY(rb_internal_thread_event_hooks)) { rb_thread_execute_hooks(event, th); } #endif static rb_serial_t current_fork_gen = 1; /* We can't use GET_VM()->fork_gen */ #if defined(SIGVTALRM) && !defined(__EMSCRIPTEN__) # define USE_UBF_LIST 1 #endif static void threadptr_trap_interrupt(rb_thread_t *); #ifdef HAVE_SCHED_YIELD #define native_thread_yield() (void)sched_yield() #else #define native_thread_yield() ((void)0) #endif /* 100ms. 10ms is too small for user level thread scheduling * on recent Linux (tested on 2.6.35) */ #define TIME_QUANTUM_MSEC (100) #define TIME_QUANTUM_USEC (TIME_QUANTUM_MSEC * 1000) #define TIME_QUANTUM_NSEC (TIME_QUANTUM_USEC * 1000) static void native_thread_dedicated_inc(rb_vm_t *vm, rb_ractor_t *cr, struct rb_native_thread *nt); static void native_thread_dedicated_dec(rb_vm_t *vm, rb_ractor_t *cr, struct rb_native_thread *nt); static void native_thread_assign(struct rb_native_thread *nt, rb_thread_t *th); static void ractor_sched_enq(rb_vm_t *vm, rb_ractor_t *r); static void timer_thread_wakeup(void); static void timer_thread_wakeup_locked(rb_vm_t *vm); static void timer_thread_wakeup_force(void); static void thread_sched_switch(rb_thread_t *cth, rb_thread_t *next_th); static void coroutine_transfer0(struct coroutine_context *transfer_from, struct coroutine_context *transfer_to, bool to_dead); #define thread_sched_dump(s) thread_sched_dump_(__FILE__, __LINE__, s) static bool th_has_dedicated_nt(const rb_thread_t *th) { // TODO: th->has_dedicated_nt return th->nt->dedicated > 0; } RBIMPL_ATTR_MAYBE_UNUSED() static void thread_sched_dump_(const char *file, int line, struct rb_thread_sched *sched) { fprintf(stderr, "@%s:%d running:%d\n", file, line, sched->running ? (int)sched->running->serial : -1); rb_thread_t *th; int i = 0; ccan_list_for_each(&sched->readyq, th, sched.node.readyq) { i++; if (i>10) rb_bug("too many"); fprintf(stderr, " ready:%d (%sNT:%d)\n", th->serial, th->nt ? (th->nt->dedicated ? "D" : "S") : "x", th->nt ? (int)th->nt->serial : -1); } } #define ractor_sched_dump(s) ractor_sched_dump_(__FILE__, __LINE__, s) RBIMPL_ATTR_MAYBE_UNUSED() static void ractor_sched_dump_(const char *file, int line, rb_vm_t *vm) { rb_ractor_t *r; fprintf(stderr, "ractor_sched_dump %s:%d\n", file, line); int i = 0; ccan_list_for_each(&vm->ractor.sched.grq, r, threads.sched.grq_node) { i++; if (i>10) rb_bug("!!"); fprintf(stderr, " %d ready:%d\n", i, rb_ractor_id(r)); } } #define thread_sched_lock(a, b) thread_sched_lock_(a, b, __FILE__, __LINE__) #define thread_sched_unlock(a, b) thread_sched_unlock_(a, b, __FILE__, __LINE__) static void thread_sched_lock_(struct rb_thread_sched *sched, rb_thread_t *th, const char *file, int line) { rb_native_mutex_lock(&sched->lock_); #if VM_CHECK_MODE RUBY_DEBUG_LOG2(file, line, "th:%u prev_owner:%u", rb_th_serial(th), rb_th_serial(sched->lock_owner)); VM_ASSERT(sched->lock_owner == NULL); sched->lock_owner = th; #else RUBY_DEBUG_LOG2(file, line, "th:%u", rb_th_serial(th)); #endif } static void thread_sched_unlock_(struct rb_thread_sched *sched, rb_thread_t *th, const char *file, int line) { RUBY_DEBUG_LOG2(file, line, "th:%u", rb_th_serial(th)); #if VM_CHECK_MODE VM_ASSERT(sched->lock_owner == th); sched->lock_owner = NULL; #endif rb_native_mutex_unlock(&sched->lock_); } static void thread_sched_set_lock_owner(struct rb_thread_sched *sched, rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u", rb_th_serial(th)); #if VM_CHECK_MODE > 0 sched->lock_owner = th; #endif } static void ASSERT_thread_sched_locked(struct rb_thread_sched *sched, rb_thread_t *th) { VM_ASSERT(rb_native_mutex_trylock(&sched->lock_) == EBUSY); #if VM_CHECK_MODE if (th) { VM_ASSERT(sched->lock_owner == th); } else { VM_ASSERT(sched->lock_owner != NULL); } #endif } #define ractor_sched_lock(a, b) ractor_sched_lock_(a, b, __FILE__, __LINE__) #define ractor_sched_unlock(a, b) ractor_sched_unlock_(a, b, __FILE__, __LINE__) RBIMPL_ATTR_MAYBE_UNUSED() static unsigned int rb_ractor_serial(const rb_ractor_t *r) { if (r) { return rb_ractor_id(r); } else { return 0; } } static void ractor_sched_set_locked(rb_vm_t *vm, rb_ractor_t *cr) { #if VM_CHECK_MODE > 0 VM_ASSERT(vm->ractor.sched.lock_owner == NULL); VM_ASSERT(vm->ractor.sched.locked == false); vm->ractor.sched.lock_owner = cr; vm->ractor.sched.locked = true; #endif } static void ractor_sched_set_unlocked(rb_vm_t *vm, rb_ractor_t *cr) { #if VM_CHECK_MODE > 0 VM_ASSERT(vm->ractor.sched.locked); VM_ASSERT(vm->ractor.sched.lock_owner == cr); vm->ractor.sched.locked = false; vm->ractor.sched.lock_owner = NULL; #endif } static void ractor_sched_lock_(rb_vm_t *vm, rb_ractor_t *cr, const char *file, int line) { rb_native_mutex_lock(&vm->ractor.sched.lock); #if VM_CHECK_MODE RUBY_DEBUG_LOG2(file, line, "cr:%u prev_owner:%u", rb_ractor_serial(cr), rb_ractor_serial(vm->ractor.sched.lock_owner)); #else RUBY_DEBUG_LOG2(file, line, "cr:%u", rb_ractor_serial(cr)); #endif ractor_sched_set_locked(vm, cr); } static void ractor_sched_unlock_(rb_vm_t *vm, rb_ractor_t *cr, const char *file, int line) { RUBY_DEBUG_LOG2(file, line, "cr:%u", rb_ractor_serial(cr)); ractor_sched_set_unlocked(vm, cr); rb_native_mutex_unlock(&vm->ractor.sched.lock); } static void ASSERT_ractor_sched_locked(rb_vm_t *vm, rb_ractor_t *cr) { VM_ASSERT(rb_native_mutex_trylock(&vm->ractor.sched.lock) == EBUSY); VM_ASSERT(vm->ractor.sched.locked); VM_ASSERT(cr == NULL || vm->ractor.sched.lock_owner == cr); } RBIMPL_ATTR_MAYBE_UNUSED() static bool ractor_sched_running_threads_contain_p(rb_vm_t *vm, rb_thread_t *th) { rb_thread_t *rth; ccan_list_for_each(&vm->ractor.sched.running_threads, rth, sched.node.running_threads) { if (rth == th) return true; } return false; } RBIMPL_ATTR_MAYBE_UNUSED() static unsigned int ractor_sched_running_threads_size(rb_vm_t *vm) { rb_thread_t *th; unsigned int i = 0; ccan_list_for_each(&vm->ractor.sched.running_threads, th, sched.node.running_threads) { i++; } return i; } RBIMPL_ATTR_MAYBE_UNUSED() static unsigned int ractor_sched_timeslice_threads_size(rb_vm_t *vm) { rb_thread_t *th; unsigned int i = 0; ccan_list_for_each(&vm->ractor.sched.timeslice_threads, th, sched.node.timeslice_threads) { i++; } return i; } RBIMPL_ATTR_MAYBE_UNUSED() static bool ractor_sched_timeslice_threads_contain_p(rb_vm_t *vm, rb_thread_t *th) { rb_thread_t *rth; ccan_list_for_each(&vm->ractor.sched.timeslice_threads, rth, sched.node.timeslice_threads) { if (rth == th) return true; } return false; } static void ractor_sched_barrier_join_signal_locked(rb_vm_t *vm); static void ractor_sched_barrier_join_wait_locked(rb_vm_t *vm, rb_thread_t *th); // setup timeslice signals by the timer thread. static void thread_sched_setup_running_threads(struct rb_thread_sched *sched, rb_ractor_t *cr, rb_vm_t *vm, rb_thread_t *add_th, rb_thread_t *del_th, rb_thread_t *add_timeslice_th) { #if USE_RUBY_DEBUG_LOG unsigned int prev_running_cnt = vm->ractor.sched.running_cnt; #endif rb_thread_t *del_timeslice_th; if (del_th && sched->is_running_timeslice) { del_timeslice_th = del_th; sched->is_running_timeslice = false; } else { del_timeslice_th = NULL; } RUBY_DEBUG_LOG("+:%u -:%u +ts:%u -ts:%u", rb_th_serial(add_th), rb_th_serial(del_th), rb_th_serial(add_timeslice_th), rb_th_serial(del_timeslice_th)); ractor_sched_lock(vm, cr); { // update running_threads if (del_th) { VM_ASSERT(ractor_sched_running_threads_contain_p(vm, del_th)); VM_ASSERT(del_timeslice_th != NULL || !ractor_sched_timeslice_threads_contain_p(vm, del_th)); ccan_list_del_init(&del_th->sched.node.running_threads); vm->ractor.sched.running_cnt--; if (UNLIKELY(vm->ractor.sched.barrier_waiting)) { ractor_sched_barrier_join_signal_locked(vm); } sched->is_running = false; } if (add_th) { while (UNLIKELY(vm->ractor.sched.barrier_waiting)) { RUBY_DEBUG_LOG("barrier-wait"); ractor_sched_barrier_join_signal_locked(vm); ractor_sched_barrier_join_wait_locked(vm, add_th); } VM_ASSERT(!ractor_sched_running_threads_contain_p(vm, add_th)); VM_ASSERT(!ractor_sched_timeslice_threads_contain_p(vm, add_th)); ccan_list_add(&vm->ractor.sched.running_threads, &add_th->sched.node.running_threads); vm->ractor.sched.running_cnt++; sched->is_running = true; VM_ASSERT(!vm->ractor.sched.barrier_waiting); } if (add_timeslice_th) { // update timeslice threads int was_empty = ccan_list_empty(&vm->ractor.sched.timeslice_threads); VM_ASSERT(!ractor_sched_timeslice_threads_contain_p(vm, add_timeslice_th)); ccan_list_add(&vm->ractor.sched.timeslice_threads, &add_timeslice_th->sched.node.timeslice_threads); sched->is_running_timeslice = true; if (was_empty) { timer_thread_wakeup_locked(vm); } } if (del_timeslice_th) { VM_ASSERT(ractor_sched_timeslice_threads_contain_p(vm, del_timeslice_th)); ccan_list_del_init(&del_timeslice_th->sched.node.timeslice_threads); } VM_ASSERT(ractor_sched_running_threads_size(vm) == vm->ractor.sched.running_cnt); VM_ASSERT(ractor_sched_timeslice_threads_size(vm) <= vm->ractor.sched.running_cnt); } ractor_sched_unlock(vm, cr); if (add_th && !del_th && UNLIKELY(vm->ractor.sync.lock_owner != NULL)) { // it can be after barrier synchronization by another ractor rb_thread_t *lock_owner = NULL; #if VM_CHECK_MODE lock_owner = sched->lock_owner; #endif thread_sched_unlock(sched, lock_owner); { RB_VM_LOCK_ENTER(); RB_VM_LOCK_LEAVE(); } thread_sched_lock(sched, lock_owner); } //RUBY_DEBUG_LOG("+:%u -:%u +ts:%u -ts:%u run:%u->%u", // rb_th_serial(add_th), rb_th_serial(del_th), // rb_th_serial(add_timeslice_th), rb_th_serial(del_timeslice_th), RUBY_DEBUG_LOG("run:%u->%u", prev_running_cnt, vm->ractor.sched.running_cnt); } static void thread_sched_add_running_thread(struct rb_thread_sched *sched, rb_thread_t *th) { ASSERT_thread_sched_locked(sched, th); VM_ASSERT(sched->running == th); rb_vm_t *vm = th->vm; thread_sched_setup_running_threads(sched, th->ractor, vm, th, NULL, ccan_list_empty(&sched->readyq) ? NULL : th); } static void thread_sched_del_running_thread(struct rb_thread_sched *sched, rb_thread_t *th) { ASSERT_thread_sched_locked(sched, th); rb_vm_t *vm = th->vm; thread_sched_setup_running_threads(sched, th->ractor, vm, NULL, th, NULL); } void rb_add_running_thread(rb_thread_t *th) { struct rb_thread_sched *sched = TH_SCHED(th); thread_sched_lock(sched, th); { thread_sched_add_running_thread(sched, th); } thread_sched_unlock(sched, th); } void rb_del_running_thread(rb_thread_t *th) { struct rb_thread_sched *sched = TH_SCHED(th); thread_sched_lock(sched, th); { thread_sched_del_running_thread(sched, th); } thread_sched_unlock(sched, th); } // setup current or next running thread // sched->running should be set only on this function. // // if th is NULL, there is no running threads. static void thread_sched_set_running(struct rb_thread_sched *sched, rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u->th:%u", rb_th_serial(sched->running), rb_th_serial(th)); VM_ASSERT(sched->running != th); sched->running = th; } RBIMPL_ATTR_MAYBE_UNUSED() static bool thread_sched_readyq_contain_p(struct rb_thread_sched *sched, rb_thread_t *th) { rb_thread_t *rth; ccan_list_for_each(&sched->readyq, rth, sched.node.readyq) { if (rth == th) return true; } return false; } // deque thread from the ready queue. // if the ready queue is empty, return NULL. // // return deque'ed running thread (or NULL). static rb_thread_t * thread_sched_deq(struct rb_thread_sched *sched) { ASSERT_thread_sched_locked(sched, NULL); rb_thread_t *next_th; VM_ASSERT(sched->running != NULL); if (ccan_list_empty(&sched->readyq)) { next_th = NULL; } else { next_th = ccan_list_pop(&sched->readyq, rb_thread_t, sched.node.readyq); VM_ASSERT(sched->readyq_cnt > 0); sched->readyq_cnt--; ccan_list_node_init(&next_th->sched.node.readyq); } RUBY_DEBUG_LOG("next_th:%u readyq_cnt:%d", rb_th_serial(next_th), sched->readyq_cnt); return next_th; } // enqueue ready thread to the ready queue. static void thread_sched_enq(struct rb_thread_sched *sched, rb_thread_t *ready_th) { ASSERT_thread_sched_locked(sched, NULL); RUBY_DEBUG_LOG("ready_th:%u readyq_cnt:%d", rb_th_serial(ready_th), sched->readyq_cnt); VM_ASSERT(sched->running != NULL); VM_ASSERT(!thread_sched_readyq_contain_p(sched, ready_th)); if (sched->is_running) { if (ccan_list_empty(&sched->readyq)) { // add sched->running to timeslice thread_sched_setup_running_threads(sched, ready_th->ractor, ready_th->vm, NULL, NULL, sched->running); } } else { VM_ASSERT(!ractor_sched_timeslice_threads_contain_p(ready_th->vm, sched->running)); } ccan_list_add_tail(&sched->readyq, &ready_th->sched.node.readyq); sched->readyq_cnt++; } // DNT: kick condvar // SNT: TODO static void thread_sched_wakeup_running_thread(struct rb_thread_sched *sched, rb_thread_t *next_th, bool will_switch) { ASSERT_thread_sched_locked(sched, NULL); VM_ASSERT(sched->running == next_th); if (next_th) { if (next_th->nt) { if (th_has_dedicated_nt(next_th)) { RUBY_DEBUG_LOG("pinning th:%u", next_th->serial); rb_native_cond_signal(&next_th->nt->cond.readyq); } else { // TODO RUBY_DEBUG_LOG("th:%u is already running.", next_th->serial); } } else { if (will_switch) { RUBY_DEBUG_LOG("th:%u (do nothing)", rb_th_serial(next_th)); } else { RUBY_DEBUG_LOG("th:%u (enq)", rb_th_serial(next_th)); ractor_sched_enq(next_th->vm, next_th->ractor); } } } else { RUBY_DEBUG_LOG("no waiting threads%s", ""); } } // waiting -> ready (locked) static void thread_sched_to_ready_common(struct rb_thread_sched *sched, rb_thread_t *th, bool wakeup, bool will_switch) { RUBY_DEBUG_LOG("th:%u running:%u redyq_cnt:%d", rb_th_serial(th), rb_th_serial(sched->running), sched->readyq_cnt); VM_ASSERT(sched->running != th); VM_ASSERT(!thread_sched_readyq_contain_p(sched, th)); RB_INTERNAL_THREAD_HOOK(RUBY_INTERNAL_THREAD_EVENT_READY, th); if (sched->running == NULL) { thread_sched_set_running(sched, th); if (wakeup) thread_sched_wakeup_running_thread(sched, th, will_switch); } else { thread_sched_enq(sched, th); } } // waiting -> ready // // `th` had became "waiting" state by `thread_sched_to_waiting` // and `thread_sched_to_ready` enqueue `th` to the thread ready queue. RBIMPL_ATTR_MAYBE_UNUSED() static void thread_sched_to_ready(struct rb_thread_sched *sched, rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u", rb_th_serial(th)); thread_sched_lock(sched, th); { thread_sched_to_ready_common(sched, th, true, false); } thread_sched_unlock(sched, th); } // wait until sched->running is `th`. static void thread_sched_wait_running_turn(struct rb_thread_sched *sched, rb_thread_t *th, bool can_direct_transfer) { RUBY_DEBUG_LOG("th:%u", rb_th_serial(th)); ASSERT_thread_sched_locked(sched, th); VM_ASSERT(th == GET_THREAD()); if (th != sched->running) { // already deleted from running threads // VM_ASSERT(!ractor_sched_running_threads_contain_p(th->vm, th)); // need locking // wait for execution right rb_thread_t *next_th; while((next_th = sched->running) != th) { if (th_has_dedicated_nt(th)) { RUBY_DEBUG_LOG("(nt) sleep th:%u running:%u", rb_th_serial(th), rb_th_serial(sched->running)); thread_sched_set_lock_owner(sched, NULL); { RUBY_DEBUG_LOG("nt:%d cond:%p", th->nt->serial, &th->nt->cond.readyq); rb_native_cond_wait(&th->nt->cond.readyq, &sched->lock_); } thread_sched_set_lock_owner(sched, th); RUBY_DEBUG_LOG("(nt) wakeup %s", sched->running == th ? "success" : "failed"); if (th == sched->running) { rb_ractor_thread_switch(th->ractor, th); } } else { // search another ready thread if (can_direct_transfer && (next_th = sched->running) != NULL && !next_th->nt // next_th is running or has dedicated nt ) { RUBY_DEBUG_LOG("th:%u->%u (direct)", rb_th_serial(th), rb_th_serial(next_th)); thread_sched_set_lock_owner(sched, NULL); { rb_ractor_set_current_ec(th->ractor, NULL); thread_sched_switch(th, next_th); } thread_sched_set_lock_owner(sched, th); } else { // search another ready ractor struct rb_native_thread *nt = th->nt; native_thread_assign(NULL, th); RUBY_DEBUG_LOG("th:%u->%u (ractor scheduling)", rb_th_serial(th), rb_th_serial(next_th)); thread_sched_set_lock_owner(sched, NULL); { rb_ractor_set_current_ec(th->ractor, NULL); coroutine_transfer0(th->sched.context, nt->nt_context, false); } thread_sched_set_lock_owner(sched, th); } VM_ASSERT(GET_EC() == th->ec); } } VM_ASSERT(th->nt != NULL); VM_ASSERT(GET_EC() == th->ec); VM_ASSERT(th->sched.waiting_reason.flags == thread_sched_waiting_none); // add th to running threads thread_sched_add_running_thread(sched, th); } // VM_ASSERT(ractor_sched_running_threads_contain_p(th->vm, th)); need locking RB_INTERNAL_THREAD_HOOK(RUBY_INTERNAL_THREAD_EVENT_RESUMED, th); } // waiting -> ready -> running (locked) static void thread_sched_to_running_common(struct rb_thread_sched *sched, rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u dedicated:%d", rb_th_serial(th), th_has_dedicated_nt(th)); VM_ASSERT(sched->running != th); VM_ASSERT(th_has_dedicated_nt(th)); VM_ASSERT(GET_THREAD() == th); native_thread_dedicated_dec(th->vm, th->ractor, th->nt); // waiting -> ready thread_sched_to_ready_common(sched, th, false, false); if (sched->running == th) { thread_sched_add_running_thread(sched, th); } // TODO: check SNT number thread_sched_wait_running_turn(sched, th, false); } // waiting -> ready -> running // // `th` had been waiting by `thread_sched_to_waiting()` // and run a dedicated task (like waitpid and so on). // After the dedicated task, this function is called // to join a normal thread-scheduling. static void thread_sched_to_running(struct rb_thread_sched *sched, rb_thread_t *th) { thread_sched_lock(sched, th); { thread_sched_to_running_common(sched, th); } thread_sched_unlock(sched, th); } // resume a next thread in the thread ready queue. // // deque next running thread from the ready thread queue and // resume this thread if available. // // If the next therad has a dedicated native thraed, simply signal to resume. // Otherwise, make the ractor ready and other nt will run the ractor and the thread. static void thread_sched_wakeup_next_thread(struct rb_thread_sched *sched, rb_thread_t *th, bool will_switch) { ASSERT_thread_sched_locked(sched, th); VM_ASSERT(sched->running == th); VM_ASSERT(sched->running->nt != NULL); rb_thread_t *next_th = thread_sched_deq(sched); RUBY_DEBUG_LOG("next_th:%u", rb_th_serial(next_th)); VM_ASSERT(th != next_th); thread_sched_set_running(sched, next_th); VM_ASSERT(next_th == sched->running); thread_sched_wakeup_running_thread(sched, next_th, will_switch); if (th != next_th) { thread_sched_del_running_thread(sched, th); } } // running -> waiting // // to_dead: false // th will run dedicated task. // run another ready thread. // to_dead: true // th will be dead. // run another ready thread. static void thread_sched_to_waiting_common0(struct rb_thread_sched *sched, rb_thread_t *th, bool to_dead) { RB_INTERNAL_THREAD_HOOK(RUBY_INTERNAL_THREAD_EVENT_SUSPENDED, th); if (!to_dead) native_thread_dedicated_inc(th->vm, th->ractor, th->nt); RUBY_DEBUG_LOG("%sth:%u", to_dead ? "to_dead " : "", rb_th_serial(th)); bool can_switch = to_dead ? !th_has_dedicated_nt(th) : false; thread_sched_wakeup_next_thread(sched, th, can_switch); } // running -> dead (locked) static void thread_sched_to_dead_common(struct rb_thread_sched *sched, rb_thread_t *th) { RUBY_DEBUG_LOG("dedicated:%d", th->nt->dedicated); thread_sched_to_waiting_common0(sched, th, true); RB_INTERNAL_THREAD_HOOK(RUBY_INTERNAL_THREAD_EVENT_EXITED, th); } // running -> dead static void thread_sched_to_dead(struct rb_thread_sched *sched, rb_thread_t *th) { thread_sched_lock(sched, th); { thread_sched_to_dead_common(sched, th); } thread_sched_unlock(sched, th); } // running -> waiting (locked) // // This thread will run dedicated task (th->nt->dedicated++). static void thread_sched_to_waiting_common(struct rb_thread_sched *sched, rb_thread_t *th) { RUBY_DEBUG_LOG("dedicated:%d", th->nt->dedicated); thread_sched_to_waiting_common0(sched, th, false); } // running -> waiting // // This thread will run a dedicated task. static void thread_sched_to_waiting(struct rb_thread_sched *sched, rb_thread_t *th) { thread_sched_lock(sched, th); { thread_sched_to_waiting_common(sched, th); } thread_sched_unlock(sched, th); } // mini utility func static void setup_ubf(rb_thread_t *th, rb_unblock_function_t *func, void *arg) { rb_native_mutex_lock(&th->interrupt_lock); { th->unblock.func = func; th->unblock.arg = arg; } rb_native_mutex_unlock(&th->interrupt_lock); } static void ubf_waiting(void *ptr) { rb_thread_t *th = (rb_thread_t *)ptr; struct rb_thread_sched *sched = TH_SCHED(th); // only once. it is safe because th->interrupt_lock is already acquired. th->unblock.func = NULL; th->unblock.arg = NULL; RUBY_DEBUG_LOG("th:%u", rb_th_serial(th)); thread_sched_lock(sched, th); { if (sched->running == th) { // not sleeping yet. } else { thread_sched_to_ready_common(sched, th, true, false); } } thread_sched_unlock(sched, th); } // running -> waiting // // This thread will sleep until other thread wakeup the thread. static void thread_sched_to_waiting_until_wakeup(struct rb_thread_sched *sched, rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u", rb_th_serial(th)); RB_VM_SAVE_MACHINE_CONTEXT(th); setup_ubf(th, ubf_waiting, (void *)th); RB_INTERNAL_THREAD_HOOK(RUBY_INTERNAL_THREAD_EVENT_SUSPENDED, th); thread_sched_lock(sched, th); { if (!RUBY_VM_INTERRUPTED(th->ec)) { bool can_direct_transfer = !th_has_dedicated_nt(th); thread_sched_wakeup_next_thread(sched, th, can_direct_transfer); thread_sched_wait_running_turn(sched, th, can_direct_transfer); } else { RUBY_DEBUG_LOG("th:%u interrupted", rb_th_serial(th)); } } thread_sched_unlock(sched, th); setup_ubf(th, NULL, NULL); } // run another thread in the ready queue. // continue to run if there are no ready threads. static void thread_sched_yield(struct rb_thread_sched *sched, rb_thread_t *th) { RUBY_DEBUG_LOG("th:%d sched->readyq_cnt:%d", (int)th->serial, sched->readyq_cnt); thread_sched_lock(sched, th); { if (!ccan_list_empty(&sched->readyq)) { RB_INTERNAL_THREAD_HOOK(RUBY_INTERNAL_THREAD_EVENT_SUSPENDED, th); thread_sched_wakeup_next_thread(sched, th, !th_has_dedicated_nt(th)); bool can_direct_transfer = !th_has_dedicated_nt(th); thread_sched_to_ready_common(sched, th, false, can_direct_transfer); thread_sched_wait_running_turn(sched, th, can_direct_transfer); } else { VM_ASSERT(sched->readyq_cnt == 0); } } thread_sched_unlock(sched, th); } void rb_thread_sched_init(struct rb_thread_sched *sched, bool atfork) { rb_native_mutex_initialize(&sched->lock_); #if VM_CHECK_MODE sched->lock_owner = NULL; #endif ccan_list_head_init(&sched->readyq); sched->readyq_cnt = 0; #if USE_MN_THREADS if (!atfork) sched->enable_mn_threads = true; // MN is enabled on Ractors #endif } static void coroutine_transfer0(struct coroutine_context *transfer_from, struct coroutine_context *transfer_to, bool to_dead) { #ifdef RUBY_ASAN_ENABLED void **fake_stack = to_dead ? NULL : &transfer_from->fake_stack; __sanitizer_start_switch_fiber(fake_stack, transfer_to->stack_base, transfer_to->stack_size); #endif RBIMPL_ATTR_MAYBE_UNUSED() struct coroutine_context *returning_from = coroutine_transfer(transfer_from, transfer_to); /* if to_dead was passed, the caller is promising that this coroutine is finished and it should * never be resumed! */ VM_ASSERT(!to_dead); #ifdef RUBY_ASAN_ENABLED __sanitizer_finish_switch_fiber(transfer_from->fake_stack, (const void**)&returning_from->stack_base, &returning_from->stack_size); #endif } static void thread_sched_switch0(struct coroutine_context *current_cont, rb_thread_t *next_th, struct rb_native_thread *nt, bool to_dead) { VM_ASSERT(!nt->dedicated); VM_ASSERT(next_th->nt == NULL); RUBY_DEBUG_LOG("next_th:%u", rb_th_serial(next_th)); ruby_thread_set_native(next_th); native_thread_assign(nt, next_th); coroutine_transfer0(current_cont, next_th->sched.context, to_dead); } static void thread_sched_switch(rb_thread_t *cth, rb_thread_t *next_th) { struct rb_native_thread *nt = cth->nt; native_thread_assign(NULL, cth); RUBY_DEBUG_LOG("th:%u->%u on nt:%d", rb_th_serial(cth), rb_th_serial(next_th), nt->serial); thread_sched_switch0(cth->sched.context, next_th, nt, cth->status == THREAD_KILLED); } #if VM_CHECK_MODE > 0 RBIMPL_ATTR_MAYBE_UNUSED() static unsigned int grq_size(rb_vm_t *vm, rb_ractor_t *cr) { ASSERT_ractor_sched_locked(vm, cr); rb_ractor_t *r, *prev_r = NULL; unsigned int i = 0; ccan_list_for_each(&vm->ractor.sched.grq, r, threads.sched.grq_node) { i++; VM_ASSERT(r != prev_r); prev_r = r; } return i; } #endif static void ractor_sched_enq(rb_vm_t *vm, rb_ractor_t *r) { struct rb_thread_sched *sched = &r->threads.sched; rb_ractor_t *cr = NULL; // timer thread can call this function VM_ASSERT(sched->running != NULL); VM_ASSERT(sched->running->nt == NULL); ractor_sched_lock(vm, cr); { #if VM_CHECK_MODE > 0 // check if grq contains r rb_ractor_t *tr; ccan_list_for_each(&vm->ractor.sched.grq, tr, threads.sched.grq_node) { VM_ASSERT(r != tr); } #endif ccan_list_add_tail(&vm->ractor.sched.grq, &sched->grq_node); vm->ractor.sched.grq_cnt++; VM_ASSERT(grq_size(vm, cr) == vm->ractor.sched.grq_cnt); RUBY_DEBUG_LOG("r:%u th:%u grq_cnt:%u", rb_ractor_id(r), rb_th_serial(sched->running), vm->ractor.sched.grq_cnt); rb_native_cond_signal(&vm->ractor.sched.cond); // ractor_sched_dump(vm); } ractor_sched_unlock(vm, cr); } #ifndef SNT_KEEP_SECONDS #define SNT_KEEP_SECONDS 0 #endif #ifndef MINIMUM_SNT // make at least MINIMUM_SNT snts for debug. #define MINIMUM_SNT 0 #endif static rb_ractor_t * ractor_sched_deq(rb_vm_t *vm, rb_ractor_t *cr) { rb_ractor_t *r; ractor_sched_lock(vm, cr); { RUBY_DEBUG_LOG("empty? %d", ccan_list_empty(&vm->ractor.sched.grq)); // ractor_sched_dump(vm); VM_ASSERT(rb_current_execution_context(false) == NULL); VM_ASSERT(grq_size(vm, cr) == vm->ractor.sched.grq_cnt); while ((r = ccan_list_pop(&vm->ractor.sched.grq, rb_ractor_t, threads.sched.grq_node)) == NULL) { RUBY_DEBUG_LOG("wait grq_cnt:%d", (int)vm->ractor.sched.grq_cnt); #if SNT_KEEP_SECONDS > 0 rb_hrtime_t abs = rb_hrtime_add(rb_hrtime_now(), RB_HRTIME_PER_SEC * SNT_KEEP_SECONDS); if (native_cond_timedwait(&vm->ractor.sched.cond, &vm->ractor.sched.lock, &abs) == ETIMEDOUT) { RUBY_DEBUG_LOG("timeout, grq_cnt:%d", (int)vm->ractor.sched.grq_cnt); VM_ASSERT(r == NULL); vm->ractor.sched.snt_cnt--; vm->ractor.sched.running_cnt--; break; } else { RUBY_DEBUG_LOG("wakeup grq_cnt:%d", (int)vm->ractor.sched.grq_cnt); } #else ractor_sched_set_unlocked(vm, cr); rb_native_cond_wait(&vm->ractor.sched.cond, &vm->ractor.sched.lock); ractor_sched_set_locked(vm, cr); RUBY_DEBUG_LOG("wakeup grq_cnt:%d", (int)vm->ractor.sched.grq_cnt); #endif } VM_ASSERT(rb_current_execution_context(false) == NULL); if (r) { VM_ASSERT(vm->ractor.sched.grq_cnt > 0); vm->ractor.sched.grq_cnt--; RUBY_DEBUG_LOG("r:%d grq_cnt:%u", (int)rb_ractor_id(r), vm->ractor.sched.grq_cnt); } else { VM_ASSERT(SNT_KEEP_SECONDS > 0); // timeout } } ractor_sched_unlock(vm, cr); return r; } void rb_ractor_lock_self(rb_ractor_t *r); void rb_ractor_unlock_self(rb_ractor_t *r); void rb_ractor_sched_sleep(rb_execution_context_t *ec, rb_ractor_t *cr, rb_unblock_function_t *ubf) { // ractor lock of cr is acquired // r is sleeping status rb_thread_t * volatile th = rb_ec_thread_ptr(ec); struct rb_thread_sched *sched = TH_SCHED(th); cr->sync.wait.waiting_thread = th; // TODO: multi-thread setup_ubf(th, ubf, (void *)cr); thread_sched_lock(sched, th); { rb_ractor_unlock_self(cr); { if (RUBY_VM_INTERRUPTED(th->ec)) { RUBY_DEBUG_LOG("interrupted"); } else if (cr->sync.wait.wakeup_status != wakeup_none) { RUBY_DEBUG_LOG("awaken:%d", (int)cr->sync.wait.wakeup_status); } else { // sleep RB_VM_SAVE_MACHINE_CONTEXT(th); th->status = THREAD_STOPPED_FOREVER; RB_INTERNAL_THREAD_HOOK(RUBY_INTERNAL_THREAD_EVENT_SUSPENDED, th); bool can_direct_transfer = !th_has_dedicated_nt(th); thread_sched_wakeup_next_thread(sched, th, can_direct_transfer); thread_sched_wait_running_turn(sched, th, can_direct_transfer); th->status = THREAD_RUNNABLE; // wakeup } } } thread_sched_unlock(sched, th); setup_ubf(th, NULL, NULL); rb_ractor_lock_self(cr); cr->sync.wait.waiting_thread = NULL; } void rb_ractor_sched_wakeup(rb_ractor_t *r) { rb_thread_t *r_th = r->sync.wait.waiting_thread; // ractor lock of r is acquired struct rb_thread_sched *sched = TH_SCHED(r_th); VM_ASSERT(r->sync.wait.wakeup_status != 0); thread_sched_lock(sched, r_th); { if (r_th->status == THREAD_STOPPED_FOREVER) { thread_sched_to_ready_common(sched, r_th, true, false); } } thread_sched_unlock(sched, r_th); } static bool ractor_sched_barrier_completed_p(rb_vm_t *vm) { RUBY_DEBUG_LOG("run:%u wait:%u", vm->ractor.sched.running_cnt, vm->ractor.sched.barrier_waiting_cnt); VM_ASSERT(vm->ractor.sched.running_cnt - 1 >= vm->ractor.sched.barrier_waiting_cnt); return (vm->ractor.sched.running_cnt - vm->ractor.sched.barrier_waiting_cnt) == 1; } void rb_ractor_sched_barrier_start(rb_vm_t *vm, rb_ractor_t *cr) { VM_ASSERT(cr == GET_RACTOR()); VM_ASSERT(vm->ractor.sync.lock_owner == cr); // VM is locked VM_ASSERT(!vm->ractor.sched.barrier_waiting); VM_ASSERT(vm->ractor.sched.barrier_waiting_cnt == 0); RUBY_DEBUG_LOG("start serial:%u", vm->ractor.sched.barrier_serial); unsigned int lock_rec; ractor_sched_lock(vm, cr); { vm->ractor.sched.barrier_waiting = true; // release VM lock lock_rec = vm->ractor.sync.lock_rec; vm->ractor.sync.lock_rec = 0; vm->ractor.sync.lock_owner = NULL; rb_native_mutex_unlock(&vm->ractor.sync.lock); { // interrupts all running threads rb_thread_t *ith; ccan_list_for_each(&vm->ractor.sched.running_threads, ith, sched.node.running_threads) { if (ith->ractor != cr) { RUBY_DEBUG_LOG("barrier int:%u", rb_th_serial(ith)); RUBY_VM_SET_VM_BARRIER_INTERRUPT(ith->ec); } } // wait for other ractors while (!ractor_sched_barrier_completed_p(vm)) { ractor_sched_set_unlocked(vm, cr); rb_native_cond_wait(&vm->ractor.sched.barrier_complete_cond, &vm->ractor.sched.lock); ractor_sched_set_locked(vm, cr); } } } ractor_sched_unlock(vm, cr); // acquire VM lock rb_native_mutex_lock(&vm->ractor.sync.lock); vm->ractor.sync.lock_rec = lock_rec; vm->ractor.sync.lock_owner = cr; RUBY_DEBUG_LOG("completed seirial:%u", vm->ractor.sched.barrier_serial); ractor_sched_lock(vm, cr); { vm->ractor.sched.barrier_waiting = false; vm->ractor.sched.barrier_serial++; vm->ractor.sched.barrier_waiting_cnt = 0; rb_native_cond_broadcast(&vm->ractor.sched.barrier_release_cond); } ractor_sched_unlock(vm, cr); } static void ractor_sched_barrier_join_signal_locked(rb_vm_t *vm) { if (ractor_sched_barrier_completed_p(vm)) { rb_native_cond_signal(&vm->ractor.sched.barrier_complete_cond); } } static void ractor_sched_barrier_join_wait_locked(rb_vm_t *vm, rb_thread_t *th) { VM_ASSERT(vm->ractor.sched.barrier_waiting); unsigned int barrier_serial = vm->ractor.sched.barrier_serial; while (vm->ractor.sched.barrier_serial == barrier_serial) { RUBY_DEBUG_LOG("sleep serial:%u", barrier_serial); RB_VM_SAVE_MACHINE_CONTEXT(th); rb_ractor_t *cr = th->ractor; ractor_sched_set_unlocked(vm, cr); rb_native_cond_wait(&vm->ractor.sched.barrier_release_cond, &vm->ractor.sched.lock); ractor_sched_set_locked(vm, cr); RUBY_DEBUG_LOG("wakeup serial:%u", barrier_serial); } } void rb_ractor_sched_barrier_join(rb_vm_t *vm, rb_ractor_t *cr) { VM_ASSERT(cr->threads.sched.running != NULL); // running ractor VM_ASSERT(cr == GET_RACTOR()); VM_ASSERT(vm->ractor.sync.lock_owner == NULL); // VM is locked, but owner == NULL VM_ASSERT(vm->ractor.sched.barrier_waiting); // VM needs barrier sync #if USE_RUBY_DEBUG_LOG || VM_CHECK_MODE > 0 unsigned int barrier_serial = vm->ractor.sched.barrier_serial; #endif RUBY_DEBUG_LOG("join"); rb_native_mutex_unlock(&vm->ractor.sync.lock); { VM_ASSERT(vm->ractor.sched.barrier_waiting); // VM needs barrier sync VM_ASSERT(vm->ractor.sched.barrier_serial == barrier_serial); ractor_sched_lock(vm, cr); { // running_cnt vm->ractor.sched.barrier_waiting_cnt++; RUBY_DEBUG_LOG("waiting_cnt:%u serial:%u", vm->ractor.sched.barrier_waiting_cnt, barrier_serial); ractor_sched_barrier_join_signal_locked(vm); ractor_sched_barrier_join_wait_locked(vm, cr->threads.sched.running); } ractor_sched_unlock(vm, cr); } rb_native_mutex_lock(&vm->ractor.sync.lock); // VM locked here } #if 0 // TODO static void clear_thread_cache_altstack(void); static void rb_thread_sched_destroy(struct rb_thread_sched *sched) { /* * only called once at VM shutdown (not atfork), another thread * may still grab vm->gvl.lock when calling gvl_release at * the end of thread_start_func_2 */ if (0) { rb_native_mutex_destroy(&sched->lock); } clear_thread_cache_altstack(); } #endif #ifdef RB_THREAD_T_HAS_NATIVE_ID static int get_native_thread_id(void) { #ifdef __linux__ return (int)syscall(SYS_gettid); #elif defined(__FreeBSD__) return pthread_getthreadid_np(); #endif } #endif #if defined(HAVE_WORKING_FORK) static void thread_sched_atfork(struct rb_thread_sched *sched) { current_fork_gen++; rb_thread_sched_init(sched, true); rb_thread_t *th = GET_THREAD(); rb_vm_t *vm = GET_VM(); if (th_has_dedicated_nt(th)) { vm->ractor.sched.snt_cnt = 0; } else { vm->ractor.sched.snt_cnt = 1; } vm->ractor.sched.running_cnt = 0; rb_native_mutex_initialize(&vm->ractor.sched.lock); // rb_native_cond_destroy(&vm->ractor.sched.cond); rb_native_cond_initialize(&vm->ractor.sched.cond); rb_native_cond_initialize(&vm->ractor.sched.barrier_complete_cond); rb_native_cond_initialize(&vm->ractor.sched.barrier_release_cond); ccan_list_head_init(&vm->ractor.sched.grq); ccan_list_head_init(&vm->ractor.sched.timeslice_threads); ccan_list_head_init(&vm->ractor.sched.running_threads); VM_ASSERT(sched->is_running); sched->is_running_timeslice = false; if (sched->running != th) { thread_sched_to_running(sched, th); } else { thread_sched_setup_running_threads(sched, th->ractor, vm, th, NULL, NULL); } #ifdef RB_THREAD_T_HAS_NATIVE_ID if (th->nt) { th->nt->tid = get_native_thread_id(); } #endif } #endif #ifdef RB_THREAD_LOCAL_SPECIFIER static RB_THREAD_LOCAL_SPECIFIER rb_thread_t *ruby_native_thread; #else static pthread_key_t ruby_native_thread_key; #endif static void null_func(int i) { /* null */ // This function can be called from signal handler // RUBY_DEBUG_LOG("i:%d", i); } rb_thread_t * ruby_thread_from_native(void) { #ifdef RB_THREAD_LOCAL_SPECIFIER return ruby_native_thread; #else return pthread_getspecific(ruby_native_thread_key); #endif } int ruby_thread_set_native(rb_thread_t *th) { if (th) { #ifdef USE_UBF_LIST ccan_list_node_init(&th->sched.node.ubf); #endif } // setup TLS if (th && th->ec) { rb_ractor_set_current_ec(th->ractor, th->ec); } #ifdef RB_THREAD_LOCAL_SPECIFIER ruby_native_thread = th; return 1; #else return pthread_setspecific(ruby_native_thread_key, th) == 0; #endif } static void native_thread_setup(struct rb_native_thread *nt); static void native_thread_setup_on_thread(struct rb_native_thread *nt); void Init_native_thread(rb_thread_t *main_th) { #if defined(HAVE_PTHREAD_CONDATTR_SETCLOCK) if (condattr_monotonic) { int r = pthread_condattr_init(condattr_monotonic); if (r == 0) { r = pthread_condattr_setclock(condattr_monotonic, CLOCK_MONOTONIC); } if (r) condattr_monotonic = NULL; } #endif #ifndef RB_THREAD_LOCAL_SPECIFIER if (pthread_key_create(&ruby_native_thread_key, 0) == EAGAIN) { rb_bug("pthread_key_create failed (ruby_native_thread_key)"); } if (pthread_key_create(&ruby_current_ec_key, 0) == EAGAIN) { rb_bug("pthread_key_create failed (ruby_current_ec_key)"); } #endif ruby_posix_signal(SIGVTALRM, null_func); // setup vm rb_vm_t *vm = main_th->vm; rb_native_mutex_initialize(&vm->ractor.sched.lock); rb_native_cond_initialize(&vm->ractor.sched.cond); rb_native_cond_initialize(&vm->ractor.sched.barrier_complete_cond); rb_native_cond_initialize(&vm->ractor.sched.barrier_release_cond); ccan_list_head_init(&vm->ractor.sched.grq); ccan_list_head_init(&vm->ractor.sched.timeslice_threads); ccan_list_head_init(&vm->ractor.sched.running_threads); // setup main thread main_th->nt->thread_id = pthread_self(); main_th->nt->serial = 1; #ifdef RUBY_NT_SERIAL ruby_nt_serial = 1; #endif ruby_thread_set_native(main_th); native_thread_setup(main_th->nt); native_thread_setup_on_thread(main_th->nt); TH_SCHED(main_th)->running = main_th; main_th->has_dedicated_nt = 1; thread_sched_setup_running_threads(TH_SCHED(main_th), main_th->ractor, vm, main_th, NULL, NULL); // setup main NT main_th->nt->dedicated = 1; main_th->nt->vm = vm; // setup mn vm->ractor.sched.dnt_cnt = 1; } extern int ruby_mn_threads_enabled; void ruby_mn_threads_params(void) { rb_vm_t *vm = GET_VM(); rb_ractor_t *main_ractor = GET_RACTOR(); const char *mn_threads_cstr = getenv("RUBY_MN_THREADS"); bool enable_mn_threads = false; if (USE_MN_THREADS && mn_threads_cstr && (enable_mn_threads = atoi(mn_threads_cstr) > 0)) { // enabled ruby_mn_threads_enabled = 1; } main_ractor->threads.sched.enable_mn_threads = enable_mn_threads; const char *max_cpu_cstr = getenv("RUBY_MAX_CPU"); const int default_max_cpu = 8; // TODO: CPU num? int max_cpu = default_max_cpu; if (USE_MN_THREADS && max_cpu_cstr) { int given_max_cpu = atoi(max_cpu_cstr); if (given_max_cpu > 0) { max_cpu = given_max_cpu; } } vm->ractor.sched.max_cpu = max_cpu; } static void native_thread_dedicated_inc(rb_vm_t *vm, rb_ractor_t *cr, struct rb_native_thread *nt) { RUBY_DEBUG_LOG("nt:%d %d->%d", nt->serial, nt->dedicated, nt->dedicated + 1); if (nt->dedicated == 0) { ractor_sched_lock(vm, cr); { vm->ractor.sched.snt_cnt--; vm->ractor.sched.dnt_cnt++; } ractor_sched_unlock(vm, cr); } nt->dedicated++; } static void native_thread_dedicated_dec(rb_vm_t *vm, rb_ractor_t *cr, struct rb_native_thread *nt) { RUBY_DEBUG_LOG("nt:%d %d->%d", nt->serial, nt->dedicated, nt->dedicated - 1); VM_ASSERT(nt->dedicated > 0); nt->dedicated--; if (nt->dedicated == 0) { ractor_sched_lock(vm, cr); { nt->vm->ractor.sched.snt_cnt++; nt->vm->ractor.sched.dnt_cnt--; } ractor_sched_unlock(vm, cr); } } static void native_thread_assign(struct rb_native_thread *nt, rb_thread_t *th) { #if USE_RUBY_DEBUG_LOG if (nt) { if (th->nt) { RUBY_DEBUG_LOG("th:%d nt:%d->%d", (int)th->serial, (int)th->nt->serial, (int)nt->serial); } else { RUBY_DEBUG_LOG("th:%d nt:NULL->%d", (int)th->serial, (int)nt->serial); } } else { if (th->nt) { RUBY_DEBUG_LOG("th:%d nt:%d->NULL", (int)th->serial, (int)th->nt->serial); } else { RUBY_DEBUG_LOG("th:%d nt:NULL->NULL", (int)th->serial); } } #endif th->nt = nt; } static void native_thread_destroy(struct rb_native_thread *nt) { if (nt) { rb_native_cond_destroy(&nt->cond.readyq); if (&nt->cond.readyq != &nt->cond.intr) { rb_native_cond_destroy(&nt->cond.intr); } RB_ALTSTACK_FREE(nt->altstack); ruby_xfree(nt->nt_context); ruby_xfree(nt); } } #if defined HAVE_PTHREAD_GETATTR_NP || defined HAVE_PTHREAD_ATTR_GET_NP #define STACKADDR_AVAILABLE 1 #elif defined HAVE_PTHREAD_GET_STACKADDR_NP && defined HAVE_PTHREAD_GET_STACKSIZE_NP #define STACKADDR_AVAILABLE 1 #undef MAINSTACKADDR_AVAILABLE #define MAINSTACKADDR_AVAILABLE 1 void *pthread_get_stackaddr_np(pthread_t); size_t pthread_get_stacksize_np(pthread_t); #elif defined HAVE_THR_STKSEGMENT || defined HAVE_PTHREAD_STACKSEG_NP #define STACKADDR_AVAILABLE 1 #elif defined HAVE_PTHREAD_GETTHRDS_NP #define STACKADDR_AVAILABLE 1 #elif defined __HAIKU__ #define STACKADDR_AVAILABLE 1 #endif #ifndef MAINSTACKADDR_AVAILABLE # ifdef STACKADDR_AVAILABLE # define MAINSTACKADDR_AVAILABLE 1 # else # define MAINSTACKADDR_AVAILABLE 0 # endif #endif #if MAINSTACKADDR_AVAILABLE && !defined(get_main_stack) # define get_main_stack(addr, size) get_stack(addr, size) #endif #ifdef STACKADDR_AVAILABLE /* * Get the initial address and size of current thread's stack */ static int get_stack(void **addr, size_t *size) { #define CHECK_ERR(expr) \ {int err = (expr); if (err) return err;} #ifdef HAVE_PTHREAD_GETATTR_NP /* Linux */ pthread_attr_t attr; size_t guard = 0; STACK_GROW_DIR_DETECTION; CHECK_ERR(pthread_getattr_np(pthread_self(), &attr)); # ifdef HAVE_PTHREAD_ATTR_GETSTACK CHECK_ERR(pthread_attr_getstack(&attr, addr, size)); STACK_DIR_UPPER((void)0, (void)(*addr = (char *)*addr + *size)); # else CHECK_ERR(pthread_attr_getstackaddr(&attr, addr)); CHECK_ERR(pthread_attr_getstacksize(&attr, size)); # endif # ifdef HAVE_PTHREAD_ATTR_GETGUARDSIZE CHECK_ERR(pthread_attr_getguardsize(&attr, &guard)); # else guard = getpagesize(); # endif *size -= guard; pthread_attr_destroy(&attr); #elif defined HAVE_PTHREAD_ATTR_GET_NP /* FreeBSD, DragonFly BSD, NetBSD */ pthread_attr_t attr; CHECK_ERR(pthread_attr_init(&attr)); CHECK_ERR(pthread_attr_get_np(pthread_self(), &attr)); # ifdef HAVE_PTHREAD_ATTR_GETSTACK CHECK_ERR(pthread_attr_getstack(&attr, addr, size)); # else CHECK_ERR(pthread_attr_getstackaddr(&attr, addr)); CHECK_ERR(pthread_attr_getstacksize(&attr, size)); # endif STACK_DIR_UPPER((void)0, (void)(*addr = (char *)*addr + *size)); pthread_attr_destroy(&attr); #elif (defined HAVE_PTHREAD_GET_STACKADDR_NP && defined HAVE_PTHREAD_GET_STACKSIZE_NP) /* MacOS X */ pthread_t th = pthread_self(); *addr = pthread_get_stackaddr_np(th); *size = pthread_get_stacksize_np(th); #elif defined HAVE_THR_STKSEGMENT || defined HAVE_PTHREAD_STACKSEG_NP stack_t stk; # if defined HAVE_THR_STKSEGMENT /* Solaris */ CHECK_ERR(thr_stksegment(&stk)); # else /* OpenBSD */ CHECK_ERR(pthread_stackseg_np(pthread_self(), &stk)); # endif *addr = stk.ss_sp; *size = stk.ss_size; #elif defined HAVE_PTHREAD_GETTHRDS_NP /* AIX */ pthread_t th = pthread_self(); struct __pthrdsinfo thinfo; char reg[256]; int regsiz=sizeof(reg); CHECK_ERR(pthread_getthrds_np(&th, PTHRDSINFO_QUERY_ALL, &thinfo, sizeof(thinfo), ®, ®siz)); *addr = thinfo.__pi_stackaddr; /* Must not use thinfo.__pi_stacksize for size. It is around 3KB smaller than the correct size calculated by thinfo.__pi_stackend - thinfo.__pi_stackaddr. */ *size = thinfo.__pi_stackend - thinfo.__pi_stackaddr; STACK_DIR_UPPER((void)0, (void)(*addr = (char *)*addr + *size)); #elif defined __HAIKU__ thread_info info; STACK_GROW_DIR_DETECTION; CHECK_ERR(get_thread_info(find_thread(NULL), &info)); *addr = info.stack_base; *size = (uintptr_t)info.stack_end - (uintptr_t)info.stack_base; STACK_DIR_UPPER((void)0, (void)(*addr = (char *)*addr + *size)); #else #error STACKADDR_AVAILABLE is defined but not implemented. #endif return 0; #undef CHECK_ERR } #endif static struct { rb_nativethread_id_t id; size_t stack_maxsize; VALUE *stack_start; } native_main_thread; #ifdef STACK_END_ADDRESS extern void *STACK_END_ADDRESS; #endif enum { RUBY_STACK_SPACE_LIMIT = 1024 * 1024, /* 1024KB */ RUBY_STACK_SPACE_RATIO = 5 }; static size_t space_size(size_t stack_size) { size_t space_size = stack_size / RUBY_STACK_SPACE_RATIO; if (space_size > RUBY_STACK_SPACE_LIMIT) { return RUBY_STACK_SPACE_LIMIT; } else { return space_size; } } #ifdef __linux__ static __attribute__((noinline)) void reserve_stack(volatile char *limit, size_t size) { # ifdef C_ALLOCA # error needs alloca() # endif struct rlimit rl; volatile char buf[0x100]; enum {stack_check_margin = 0x1000}; /* for -fstack-check */ STACK_GROW_DIR_DETECTION; if (!getrlimit(RLIMIT_STACK, &rl) && rl.rlim_cur == RLIM_INFINITY) return; if (size < stack_check_margin) return; size -= stack_check_margin; size -= sizeof(buf); /* margin */ if (IS_STACK_DIR_UPPER()) { const volatile char *end = buf + sizeof(buf); limit += size; if (limit > end) { /* |<-bottom (=limit(a)) top->| * | .. |<-buf 256B |<-end | stack check | * | 256B | =size= | margin (4KB)| * | =size= limit(b)->| 256B | | * | | alloca(sz) | | | * | .. |<-buf |<-limit(c) [sz-1]->0> | | */ size_t sz = limit - end; limit = alloca(sz); limit[sz-1] = 0; } } else { limit -= size; if (buf > limit) { /* |<-top (=limit(a)) bottom->| * | .. | 256B buf->| | stack check | * | 256B | =size= | margin (4KB)| * | =size= limit(b)->| 256B | | * | | alloca(sz) | | | * | .. | buf->| limit(c)-><0> | | */ size_t sz = buf - limit; limit = alloca(sz); limit[0] = 0; } } } #else # define reserve_stack(limit, size) ((void)(limit), (void)(size)) #endif static void native_thread_init_main_thread_stack(void *addr) { native_main_thread.id = pthread_self(); #ifdef RUBY_ASAN_ENABLED addr = asan_get_real_stack_addr((void *)addr); #endif #if MAINSTACKADDR_AVAILABLE if (native_main_thread.stack_maxsize) return; { void* stackaddr; size_t size; if (get_main_stack(&stackaddr, &size) == 0) { native_main_thread.stack_maxsize = size; native_main_thread.stack_start = stackaddr; reserve_stack(stackaddr, size); goto bound_check; } } #endif #ifdef STACK_END_ADDRESS native_main_thread.stack_start = STACK_END_ADDRESS; #else if (!native_main_thread.stack_start || STACK_UPPER((VALUE *)(void *)&addr, native_main_thread.stack_start > (VALUE *)addr, native_main_thread.stack_start < (VALUE *)addr)) { native_main_thread.stack_start = (VALUE *)addr; } #endif { #if defined(HAVE_GETRLIMIT) #if defined(PTHREAD_STACK_DEFAULT) # if PTHREAD_STACK_DEFAULT < RUBY_STACK_SPACE*5 # error "PTHREAD_STACK_DEFAULT is too small" # endif size_t size = PTHREAD_STACK_DEFAULT; #else size_t size = RUBY_VM_THREAD_VM_STACK_SIZE; #endif size_t space; int pagesize = getpagesize(); struct rlimit rlim; STACK_GROW_DIR_DETECTION; if (getrlimit(RLIMIT_STACK, &rlim) == 0) { size = (size_t)rlim.rlim_cur; } addr = native_main_thread.stack_start; if (IS_STACK_DIR_UPPER()) { space = ((size_t)((char *)addr + size) / pagesize) * pagesize - (size_t)addr; } else { space = (size_t)addr - ((size_t)((char *)addr - size) / pagesize + 1) * pagesize; } native_main_thread.stack_maxsize = space; #endif } #if MAINSTACKADDR_AVAILABLE bound_check: #endif /* If addr is out of range of main-thread stack range estimation, */ /* it should be on co-routine (alternative stack). [Feature #2294] */ { void *start, *end; STACK_GROW_DIR_DETECTION; if (IS_STACK_DIR_UPPER()) { start = native_main_thread.stack_start; end = (char *)native_main_thread.stack_start + native_main_thread.stack_maxsize; } else { start = (char *)native_main_thread.stack_start - native_main_thread.stack_maxsize; end = native_main_thread.stack_start; } if ((void *)addr < start || (void *)addr > end) { /* out of range */ native_main_thread.stack_start = (VALUE *)addr; native_main_thread.stack_maxsize = 0; /* unknown */ } } } #define CHECK_ERR(expr) \ {int err = (expr); if (err) {rb_bug_errno(#expr, err);}} static int native_thread_init_stack(rb_thread_t *th, void *local_in_parent_frame) { rb_nativethread_id_t curr = pthread_self(); #ifdef RUBY_ASAN_ENABLED local_in_parent_frame = asan_get_real_stack_addr(local_in_parent_frame); th->ec->machine.asan_fake_stack_handle = asan_get_thread_fake_stack_handle(); #endif if (!native_main_thread.id) { /* This thread is the first thread, must be the main thread - * configure the native_main_thread object */ native_thread_init_main_thread_stack(local_in_parent_frame); } if (pthread_equal(curr, native_main_thread.id)) { th->ec->machine.stack_start = native_main_thread.stack_start; th->ec->machine.stack_maxsize = native_main_thread.stack_maxsize; } else { #ifdef STACKADDR_AVAILABLE if (th_has_dedicated_nt(th)) { void *start; size_t size; if (get_stack(&start, &size) == 0) { uintptr_t diff = (uintptr_t)start - (uintptr_t)local_in_parent_frame; th->ec->machine.stack_start = local_in_parent_frame; th->ec->machine.stack_maxsize = size - diff; } } #else rb_raise(rb_eNotImpError, "ruby engine can initialize only in the main thread"); #endif } return 0; } struct nt_param { rb_vm_t *vm; struct rb_native_thread *nt; }; static void * nt_start(void *ptr); static int native_thread_create0(struct rb_native_thread *nt) { int err = 0; pthread_attr_t attr; const size_t stack_size = nt->vm->default_params.thread_machine_stack_size; const size_t space = space_size(stack_size); nt->machine_stack_maxsize = stack_size - space; #ifdef USE_SIGALTSTACK nt->altstack = rb_allocate_sigaltstack(); #endif CHECK_ERR(pthread_attr_init(&attr)); # ifdef PTHREAD_STACK_MIN RUBY_DEBUG_LOG("stack size: %lu", (unsigned long)stack_size); CHECK_ERR(pthread_attr_setstacksize(&attr, stack_size)); # endif # ifdef HAVE_PTHREAD_ATTR_SETINHERITSCHED CHECK_ERR(pthread_attr_setinheritsched(&attr, PTHREAD_INHERIT_SCHED)); # endif CHECK_ERR(pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED)); err = pthread_create(&nt->thread_id, &attr, nt_start, nt); RUBY_DEBUG_LOG("nt:%d err:%d", (int)nt->serial, err); CHECK_ERR(pthread_attr_destroy(&attr)); return err; } static void native_thread_setup(struct rb_native_thread *nt) { // init cond rb_native_cond_initialize(&nt->cond.readyq); if (&nt->cond.readyq != &nt->cond.intr) { rb_native_cond_initialize(&nt->cond.intr); } } static void native_thread_setup_on_thread(struct rb_native_thread *nt) { // init tid #ifdef RB_THREAD_T_HAS_NATIVE_ID nt->tid = get_native_thread_id(); #endif // init signal handler RB_ALTSTACK_INIT(nt->altstack, nt->altstack); } static struct rb_native_thread * native_thread_alloc(void) { struct rb_native_thread *nt = ZALLOC(struct rb_native_thread); native_thread_setup(nt); #if USE_MN_THREADS nt->nt_context = ruby_xmalloc(sizeof(struct coroutine_context)); #endif #if USE_RUBY_DEBUG_LOG static rb_atomic_t nt_serial = 2; nt->serial = RUBY_ATOMIC_FETCH_ADD(nt_serial, 1); #endif return nt; } static int native_thread_create_dedicated(rb_thread_t *th) { th->nt = native_thread_alloc(); th->nt->vm = th->vm; th->nt->running_thread = th; th->nt->dedicated = 1; // vm stack size_t vm_stack_word_size = th->vm->default_params.thread_vm_stack_size / sizeof(VALUE); void *vm_stack = ruby_xmalloc(vm_stack_word_size * sizeof(VALUE)); th->sched.malloc_stack = true; rb_ec_initialize_vm_stack(th->ec, vm_stack, vm_stack_word_size); th->sched.context_stack = vm_stack; // setup thread_sched_to_ready(TH_SCHED(th), th); return native_thread_create0(th->nt); } static void call_thread_start_func_2(rb_thread_t *th) { /* Capture the address of a local in this stack frame to mark the beginning of the machine stack for this thread. This is required even if we can tell the real stack beginning from the pthread API in native_thread_init_stack, because glibc stores some of its own data on the stack before calling into user code on a new thread, and replacing that data on fiber-switch would break it (see bug #13887) */ VALUE stack_start = 0; VALUE *stack_start_addr = asan_get_real_stack_addr(&stack_start); native_thread_init_stack(th, stack_start_addr); thread_start_func_2(th, th->ec->machine.stack_start); } static void * nt_start(void *ptr) { struct rb_native_thread *nt = (struct rb_native_thread *)ptr; rb_vm_t *vm = nt->vm; native_thread_setup_on_thread(nt); // init tid #ifdef RB_THREAD_T_HAS_NATIVE_ID nt->tid = get_native_thread_id(); #endif #if USE_RUBY_DEBUG_LOG && defined(RUBY_NT_SERIAL) ruby_nt_serial = nt->serial; #endif RUBY_DEBUG_LOG("nt:%u", nt->serial); if (!nt->dedicated) { coroutine_initialize_main(nt->nt_context); } while (1) { if (nt->dedicated) { // wait running turn rb_thread_t *th = nt->running_thread; struct rb_thread_sched *sched = TH_SCHED(th); RUBY_DEBUG_LOG("on dedicated th:%u", rb_th_serial(th)); ruby_thread_set_native(th); thread_sched_lock(sched, th); { if (sched->running == th) { thread_sched_add_running_thread(sched, th); } thread_sched_wait_running_turn(sched, th, false); } thread_sched_unlock(sched, th); // start threads call_thread_start_func_2(th); break; // TODO: allow to change to the SNT } else { RUBY_DEBUG_LOG("check next"); rb_ractor_t *r = ractor_sched_deq(vm, NULL); if (r) { struct rb_thread_sched *sched = &r->threads.sched; thread_sched_lock(sched, NULL); { rb_thread_t *next_th = sched->running; if (next_th && next_th->nt == NULL) { RUBY_DEBUG_LOG("nt:%d next_th:%d", (int)nt->serial, (int)next_th->serial); thread_sched_switch0(nt->nt_context, next_th, nt, false); } else { RUBY_DEBUG_LOG("no schedulable threads -- next_th:%p", next_th); } } thread_sched_unlock(sched, NULL); } else { // timeout -> deleted. break; } if (nt->dedicated) { // SNT becomes DNT while running break; } } } return NULL; } static int native_thread_create_shared(rb_thread_t *th); #if USE_MN_THREADS static void nt_free_stack(void *mstack); #endif void rb_threadptr_remove(rb_thread_t *th) { #if USE_MN_THREADS if (th->sched.malloc_stack) { // dedicated return; } else { rb_vm_t *vm = th->vm; th->sched.finished = false; RB_VM_LOCK_ENTER(); { ccan_list_add(&vm->ractor.sched.zombie_threads, &th->sched.node.zombie_threads); } RB_VM_LOCK_LEAVE(); } #endif } void rb_threadptr_sched_free(rb_thread_t *th) { #if USE_MN_THREADS if (th->sched.malloc_stack) { // has dedicated ruby_xfree(th->sched.context_stack); native_thread_destroy(th->nt); } else { nt_free_stack(th->sched.context_stack); // TODO: how to free nt and nt->altstack? } ruby_xfree(th->sched.context); th->sched.context = NULL; // VM_ASSERT(th->sched.context == NULL); #else ruby_xfree(th->sched.context_stack); native_thread_destroy(th->nt); #endif th->nt = NULL; } void rb_thread_sched_mark_zombies(rb_vm_t *vm) { if (!ccan_list_empty(&vm->ractor.sched.zombie_threads)) { rb_thread_t *zombie_th, *next_zombie_th; ccan_list_for_each_safe(&vm->ractor.sched.zombie_threads, zombie_th, next_zombie_th, sched.node.zombie_threads) { if (zombie_th->sched.finished) { ccan_list_del_init(&zombie_th->sched.node.zombie_threads); } else { rb_gc_mark(zombie_th->self); } } } } static int native_thread_create(rb_thread_t *th) { VM_ASSERT(th->nt == 0); RUBY_DEBUG_LOG("th:%d has_dnt:%d", th->serial, th->has_dedicated_nt); RB_INTERNAL_THREAD_HOOK(RUBY_INTERNAL_THREAD_EVENT_STARTED, th); if (!th->ractor->threads.sched.enable_mn_threads) { th->has_dedicated_nt = 1; } if (th->has_dedicated_nt) { return native_thread_create_dedicated(th); } else { return native_thread_create_shared(th); } } #if USE_NATIVE_THREAD_PRIORITY static void native_thread_apply_priority(rb_thread_t *th) { #if defined(_POSIX_PRIORITY_SCHEDULING) && (_POSIX_PRIORITY_SCHEDULING > 0) struct sched_param sp; int policy; int priority = 0 - th->priority; int max, min; pthread_getschedparam(th->nt->thread_id, &policy, &sp); max = sched_get_priority_max(policy); min = sched_get_priority_min(policy); if (min > priority) { priority = min; } else if (max < priority) { priority = max; } sp.sched_priority = priority; pthread_setschedparam(th->nt->thread_id, policy, &sp); #else /* not touched */ #endif } #endif /* USE_NATIVE_THREAD_PRIORITY */ static int native_fd_select(int n, rb_fdset_t *readfds, rb_fdset_t *writefds, rb_fdset_t *exceptfds, struct timeval *timeout, rb_thread_t *th) { return rb_fd_select(n, readfds, writefds, exceptfds, timeout); } static void ubf_pthread_cond_signal(void *ptr) { rb_thread_t *th = (rb_thread_t *)ptr; RUBY_DEBUG_LOG("th:%u on nt:%d", rb_th_serial(th), (int)th->nt->serial); rb_native_cond_signal(&th->nt->cond.intr); } static void native_cond_sleep(rb_thread_t *th, rb_hrtime_t *rel) { rb_nativethread_lock_t *lock = &th->interrupt_lock; rb_nativethread_cond_t *cond = &th->nt->cond.intr; /* Solaris cond_timedwait() return EINVAL if an argument is greater than * current_time + 100,000,000. So cut up to 100,000,000. This is * considered as a kind of spurious wakeup. The caller to native_sleep * should care about spurious wakeup. * * See also [Bug #1341] [ruby-core:29702] * http://download.oracle.com/docs/cd/E19683-01/816-0216/6m6ngupgv/index.html */ const rb_hrtime_t max = (rb_hrtime_t)100000000 * RB_HRTIME_PER_SEC; THREAD_BLOCKING_BEGIN(th); { rb_native_mutex_lock(lock); th->unblock.func = ubf_pthread_cond_signal; th->unblock.arg = th; if (RUBY_VM_INTERRUPTED(th->ec)) { /* interrupted. return immediate */ RUBY_DEBUG_LOG("interrupted before sleep th:%u", rb_th_serial(th)); } else { if (!rel) { rb_native_cond_wait(cond, lock); } else { rb_hrtime_t end; if (*rel > max) { *rel = max; } end = native_cond_timeout(cond, *rel); native_cond_timedwait(cond, lock, &end); } } th->unblock.func = 0; rb_native_mutex_unlock(lock); } THREAD_BLOCKING_END(th); RUBY_DEBUG_LOG("done th:%u", rb_th_serial(th)); } #ifdef USE_UBF_LIST static CCAN_LIST_HEAD(ubf_list_head); static rb_nativethread_lock_t ubf_list_lock = RB_NATIVETHREAD_LOCK_INIT; static void ubf_list_atfork(void) { ccan_list_head_init(&ubf_list_head); rb_native_mutex_initialize(&ubf_list_lock); } RBIMPL_ATTR_MAYBE_UNUSED() static bool ubf_list_contain_p(rb_thread_t *th) { rb_thread_t *list_th; ccan_list_for_each(&ubf_list_head, list_th, sched.node.ubf) { if (list_th == th) return true; } return false; } /* The thread 'th' is registered to be trying unblock. */ static void register_ubf_list(rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u", rb_th_serial(th)); struct ccan_list_node *node = &th->sched.node.ubf; VM_ASSERT(th->unblock.func != NULL); rb_native_mutex_lock(&ubf_list_lock); { // check not connected yet if (ccan_list_empty((struct ccan_list_head*)node)) { VM_ASSERT(!ubf_list_contain_p(th)); ccan_list_add(&ubf_list_head, node); } } rb_native_mutex_unlock(&ubf_list_lock); timer_thread_wakeup(); } /* The thread 'th' is unblocked. It no longer need to be registered. */ static void unregister_ubf_list(rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u", rb_th_serial(th)); struct ccan_list_node *node = &th->sched.node.ubf; /* we can't allow re-entry into ubf_list_head */ VM_ASSERT(th->unblock.func == NULL); if (!ccan_list_empty((struct ccan_list_head*)node)) { rb_native_mutex_lock(&ubf_list_lock); { VM_ASSERT(ubf_list_contain_p(th)); ccan_list_del_init(node); } rb_native_mutex_unlock(&ubf_list_lock); } } /* * send a signal to intent that a target thread return from blocking syscall. * Maybe any signal is ok, but we chose SIGVTALRM. */ static void ubf_wakeup_thread(rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u thread_id:%p", rb_th_serial(th), (void *)th->nt->thread_id); pthread_kill(th->nt->thread_id, SIGVTALRM); } static void ubf_select(void *ptr) { rb_thread_t *th = (rb_thread_t *)ptr; RUBY_DEBUG_LOG("wakeup th:%u", rb_th_serial(th)); ubf_wakeup_thread(th); register_ubf_list(th); } static bool ubf_threads_empty(void) { return ccan_list_empty(&ubf_list_head) != 0; } static void ubf_wakeup_all_threads(void) { if (!ubf_threads_empty()) { rb_thread_t *th; rb_native_mutex_lock(&ubf_list_lock); { ccan_list_for_each(&ubf_list_head, th, sched.node.ubf) { ubf_wakeup_thread(th); } } rb_native_mutex_unlock(&ubf_list_lock); } } #else /* USE_UBF_LIST */ #define register_ubf_list(th) (void)(th) #define unregister_ubf_list(th) (void)(th) #define ubf_select 0 static void ubf_wakeup_all_threads(void) { return; } static bool ubf_threads_empty(void) { return true; } #define ubf_list_atfork() do {} while (0) #endif /* USE_UBF_LIST */ #define TT_DEBUG 0 #define WRITE_CONST(fd, str) (void)(write((fd),(str),sizeof(str)-1)<0) void rb_thread_wakeup_timer_thread(int sig) { // This function can be called from signal handlers so that // pthread_mutex_lock() should not be used. // wakeup timer thread timer_thread_wakeup_force(); // interrupt main thread if main thread is available if (system_working) { rb_vm_t *vm = GET_VM(); rb_thread_t *main_th = vm->ractor.main_thread; if (main_th) { volatile rb_execution_context_t *main_th_ec = ACCESS_ONCE(rb_execution_context_t *, main_th->ec); if (main_th_ec) { RUBY_VM_SET_TRAP_INTERRUPT(main_th_ec); if (vm->ubf_async_safe && main_th->unblock.func) { (main_th->unblock.func)(main_th->unblock.arg); } } } } } #define CLOSE_INVALIDATE_PAIR(expr) \ close_invalidate_pair(expr,"close_invalidate: "#expr) static void close_invalidate(int *fdp, const char *msg) { int fd = *fdp; *fdp = -1; if (close(fd) < 0) { async_bug_fd(msg, errno, fd); } } static void close_invalidate_pair(int fds[2], const char *msg) { if (USE_EVENTFD && fds[0] == fds[1]) { fds[1] = -1; // disable write port first close_invalidate(&fds[0], msg); } else { close_invalidate(&fds[1], msg); close_invalidate(&fds[0], msg); } } static void set_nonblock(int fd) { int oflags; int err; oflags = fcntl(fd, F_GETFL); if (oflags == -1) rb_sys_fail(0); oflags |= O_NONBLOCK; err = fcntl(fd, F_SETFL, oflags); if (err == -1) rb_sys_fail(0); } /* communication pipe with timer thread and signal handler */ static void setup_communication_pipe_internal(int pipes[2]) { int err; if (pipes[0] > 0 || pipes[1] > 0) { VM_ASSERT(pipes[0] > 0); VM_ASSERT(pipes[1] > 0); return; } /* * Don't bother with eventfd on ancient Linux 2.6.22..2.6.26 which were * missing EFD_* flags, they can fall back to pipe */ #if USE_EVENTFD && defined(EFD_NONBLOCK) && defined(EFD_CLOEXEC) pipes[0] = pipes[1] = eventfd(0, EFD_NONBLOCK|EFD_CLOEXEC); if (pipes[0] >= 0) { rb_update_max_fd(pipes[0]); return; } #endif err = rb_cloexec_pipe(pipes); if (err != 0) { rb_bug("can not create communication pipe"); } rb_update_max_fd(pipes[0]); rb_update_max_fd(pipes[1]); set_nonblock(pipes[0]); set_nonblock(pipes[1]); } #if !defined(SET_CURRENT_THREAD_NAME) && defined(__linux__) && defined(PR_SET_NAME) # define SET_CURRENT_THREAD_NAME(name) prctl(PR_SET_NAME, name) #endif enum { THREAD_NAME_MAX = #if defined(__linux__) 16 #elif defined(__APPLE__) /* Undocumented, and main thread seems unlimited */ 64 #else 16 #endif }; static VALUE threadptr_invoke_proc_location(rb_thread_t *th); static void native_set_thread_name(rb_thread_t *th) { #ifdef SET_CURRENT_THREAD_NAME VALUE loc; if (!NIL_P(loc = th->name)) { SET_CURRENT_THREAD_NAME(RSTRING_PTR(loc)); } else if ((loc = threadptr_invoke_proc_location(th)) != Qnil) { char *name, *p; char buf[THREAD_NAME_MAX]; size_t len; int n; name = RSTRING_PTR(RARRAY_AREF(loc, 0)); p = strrchr(name, '/'); /* show only the basename of the path. */ if (p && p[1]) name = p + 1; n = snprintf(buf, sizeof(buf), "%s:%d", name, NUM2INT(RARRAY_AREF(loc, 1))); RB_GC_GUARD(loc); len = (size_t)n; if (len >= sizeof(buf)) { buf[sizeof(buf)-2] = '*'; buf[sizeof(buf)-1] = '\0'; } SET_CURRENT_THREAD_NAME(buf); } #endif } static void native_set_another_thread_name(rb_nativethread_id_t thread_id, VALUE name) { #if defined SET_ANOTHER_THREAD_NAME || defined SET_CURRENT_THREAD_NAME char buf[THREAD_NAME_MAX]; const char *s = ""; # if !defined SET_ANOTHER_THREAD_NAME if (!pthread_equal(pthread_self(), thread_id)) return; # endif if (!NIL_P(name)) { long n; RSTRING_GETMEM(name, s, n); if (n >= (int)sizeof(buf)) { memcpy(buf, s, sizeof(buf)-1); buf[sizeof(buf)-1] = '\0'; s = buf; } } # if defined SET_ANOTHER_THREAD_NAME SET_ANOTHER_THREAD_NAME(thread_id, s); # elif defined SET_CURRENT_THREAD_NAME SET_CURRENT_THREAD_NAME(s); # endif #endif } #if defined(RB_THREAD_T_HAS_NATIVE_ID) || defined(__APPLE__) static VALUE native_thread_native_thread_id(rb_thread_t *target_th) { if (!target_th->nt) return Qnil; #ifdef RB_THREAD_T_HAS_NATIVE_ID int tid = target_th->nt->tid; if (tid == 0) return Qnil; return INT2FIX(tid); #elif defined(__APPLE__) uint64_t tid; /* The first condition is needed because MAC_OS_X_VERSION_10_6 is not defined on 10.5, and while __POWERPC__ takes care of ppc/ppc64, i386 will be broken without this. Note, 10.5 is supported with GCC upstream, so it has C++17 and everything needed to build modern Ruby. */ # if (!defined(MAC_OS_X_VERSION_10_6) || \ (MAC_OS_X_VERSION_MAX_ALLOWED < MAC_OS_X_VERSION_10_6) || \ defined(__POWERPC__) /* never defined for PowerPC platforms */) const bool no_pthread_threadid_np = true; # define NO_PTHREAD_MACH_THREAD_NP 1 # elif MAC_OS_X_VERSION_MIN_REQUIRED >= MAC_OS_X_VERSION_10_6 const bool no_pthread_threadid_np = false; # else # if !(defined(__has_attribute) && __has_attribute(availability)) /* __API_AVAILABLE macro does nothing on gcc */ __attribute__((weak)) int pthread_threadid_np(pthread_t, uint64_t*); # endif /* Check weakly linked symbol */ const bool no_pthread_threadid_np = !&pthread_threadid_np; # endif if (no_pthread_threadid_np) { return ULL2NUM(pthread_mach_thread_np(pthread_self())); } # ifndef NO_PTHREAD_MACH_THREAD_NP int e = pthread_threadid_np(target_th->nt->thread_id, &tid); if (e != 0) rb_syserr_fail(e, "pthread_threadid_np"); return ULL2NUM((unsigned long long)tid); # endif #endif } # define USE_NATIVE_THREAD_NATIVE_THREAD_ID 1 #else # define USE_NATIVE_THREAD_NATIVE_THREAD_ID 0 #endif static struct { rb_serial_t created_fork_gen; pthread_t pthread_id; int comm_fds[2]; // r, w #if (HAVE_SYS_EPOLL_H || HAVE_SYS_EVENT_H) && USE_MN_THREADS int event_fd; // kernel event queue fd (epoll/kqueue) #endif #if HAVE_SYS_EPOLL_H && USE_MN_THREADS #define EPOLL_EVENTS_MAX 0x10 struct epoll_event finished_events[EPOLL_EVENTS_MAX]; #elif HAVE_SYS_EVENT_H && USE_MN_THREADS #define KQUEUE_EVENTS_MAX 0x10 struct kevent finished_events[KQUEUE_EVENTS_MAX]; #endif // waiting threads list struct ccan_list_head waiting; // waiting threads in ractors pthread_mutex_t waiting_lock; } timer_th = { .created_fork_gen = 0, }; #define TIMER_THREAD_CREATED_P() (timer_th.created_fork_gen == current_fork_gen) static void timer_thread_check_timeslice(rb_vm_t *vm); static int timer_thread_set_timeout(rb_vm_t *vm); static void timer_thread_wakeup_thread(rb_thread_t *th); #include "thread_pthread_mn.c" static rb_thread_t * thread_sched_waiting_thread(struct rb_thread_sched_waiting *w) { if (w) { return (rb_thread_t *)((size_t)w - offsetof(rb_thread_t, sched.waiting_reason)); } else { return NULL; } } static int timer_thread_set_timeout(rb_vm_t *vm) { #if 0 return 10; // ms #else int timeout = -1; ractor_sched_lock(vm, NULL); { if ( !ccan_list_empty(&vm->ractor.sched.timeslice_threads) // (1-1) Provide time slice for active NTs || !ubf_threads_empty() // (1-3) Periodic UBF || vm->ractor.sched.grq_cnt > 0 // (1-4) Lazy GRQ deq start ) { RUBY_DEBUG_LOG("timeslice:%d ubf:%d grq:%d", !ccan_list_empty(&vm->ractor.sched.timeslice_threads), !ubf_threads_empty(), (vm->ractor.sched.grq_cnt > 0)); timeout = 10; // ms vm->ractor.sched.timeslice_wait_inf = false; } else { vm->ractor.sched.timeslice_wait_inf = true; } } ractor_sched_unlock(vm, NULL); if (vm->ractor.sched.timeslice_wait_inf) { rb_native_mutex_lock(&timer_th.waiting_lock); { struct rb_thread_sched_waiting *w = ccan_list_top(&timer_th.waiting, struct rb_thread_sched_waiting, node); rb_thread_t *th = thread_sched_waiting_thread(w); if (th && (th->sched.waiting_reason.flags & thread_sched_waiting_timeout)) { rb_hrtime_t now = rb_hrtime_now(); rb_hrtime_t hrrel = rb_hrtime_sub(th->sched.waiting_reason.data.timeout, now); RUBY_DEBUG_LOG("th:%u now:%lu rel:%lu", rb_th_serial(th), (unsigned long)now, (unsigned long)hrrel); // TODO: overflow? timeout = (int)((hrrel + RB_HRTIME_PER_MSEC - 1) / RB_HRTIME_PER_MSEC); // ms } } rb_native_mutex_unlock(&timer_th.waiting_lock); } RUBY_DEBUG_LOG("timeout:%d inf:%d", timeout, (int)vm->ractor.sched.timeslice_wait_inf); // fprintf(stderr, "timeout:%d\n", timeout); return timeout; #endif } static void timer_thread_check_signal(rb_vm_t *vm) { // ruby_sigchld_handler(vm); TODO int signum = rb_signal_buff_size(); if (UNLIKELY(signum > 0) && vm->ractor.main_thread) { RUBY_DEBUG_LOG("signum:%d", signum); threadptr_trap_interrupt(vm->ractor.main_thread); } } static bool timer_thread_check_exceed(rb_hrtime_t abs, rb_hrtime_t now) { if (abs < now) { return true; } else if (abs - now < RB_HRTIME_PER_MSEC) { return true; // too short time } else { return false; } } static rb_thread_t * timer_thread_deq_wakeup(rb_vm_t *vm, rb_hrtime_t now) { struct rb_thread_sched_waiting *w = ccan_list_top(&timer_th.waiting, struct rb_thread_sched_waiting, node); if (w != NULL && (w->flags & thread_sched_waiting_timeout) && timer_thread_check_exceed(w->data.timeout, now)) { RUBY_DEBUG_LOG("wakeup th:%u", rb_th_serial(thread_sched_waiting_thread(w))); // delete from waiting list ccan_list_del_init(&w->node); // setup result w->flags = thread_sched_waiting_none; w->data.result = 0; return thread_sched_waiting_thread(w); } return NULL; } static void timer_thread_wakeup_thread(rb_thread_t *th) { RUBY_DEBUG_LOG("th:%u", rb_th_serial(th)); struct rb_thread_sched *sched = TH_SCHED(th); thread_sched_lock(sched, th); { if (sched->running != th) { thread_sched_to_ready_common(sched, th, true, false); } else { // will be release the execution right } } thread_sched_unlock(sched, th); } static void timer_thread_check_timeout(rb_vm_t *vm) { rb_hrtime_t now = rb_hrtime_now(); rb_thread_t *th; rb_native_mutex_lock(&timer_th.waiting_lock); { while ((th = timer_thread_deq_wakeup(vm, now)) != NULL) { timer_thread_wakeup_thread(th); } } rb_native_mutex_unlock(&timer_th.waiting_lock); } static void timer_thread_check_timeslice(rb_vm_t *vm) { // TODO: check time rb_thread_t *th; ccan_list_for_each(&vm->ractor.sched.timeslice_threads, th, sched.node.timeslice_threads) { RUBY_DEBUG_LOG("timeslice th:%u", rb_th_serial(th)); RUBY_VM_SET_TIMER_INTERRUPT(th->ec); } } void rb_assert_sig(void) { sigset_t oldmask; pthread_sigmask(0, NULL, &oldmask); if (sigismember(&oldmask, SIGVTALRM)) { rb_bug("!!!"); } else { RUBY_DEBUG_LOG("ok"); } } static void * timer_thread_func(void *ptr) { rb_vm_t *vm = (rb_vm_t *)ptr; #if defined(RUBY_NT_SERIAL) ruby_nt_serial = (rb_atomic_t)-1; #endif RUBY_DEBUG_LOG("started%s", ""); while (system_working) { timer_thread_check_signal(vm); timer_thread_check_timeout(vm); ubf_wakeup_all_threads(); RUBY_DEBUG_LOG("system_working:%d", system_working); timer_thread_polling(vm); } RUBY_DEBUG_LOG("terminated"); return NULL; } /* only use signal-safe system calls here */ static void signal_communication_pipe(int fd) { #if USE_EVENTFD const uint64_t buff = 1; #else const char buff = '!'; #endif ssize_t result; /* already opened */ if (fd >= 0) { retry: if ((result = write(fd, &buff, sizeof(buff))) <= 0) { int e = errno; switch (e) { case EINTR: goto retry; case EAGAIN: #if defined(EWOULDBLOCK) && EWOULDBLOCK != EAGAIN case EWOULDBLOCK: #endif break; default: async_bug_fd("rb_thread_wakeup_timer_thread: write", e, fd); } } if (TT_DEBUG) WRITE_CONST(2, "rb_thread_wakeup_timer_thread: write\n"); } else { // ignore wakeup } } static void timer_thread_wakeup_force(void) { // should not use RUBY_DEBUG_LOG() because it can be called within signal handlers. signal_communication_pipe(timer_th.comm_fds[1]); } static void timer_thread_wakeup_locked(rb_vm_t *vm) { // should be locked before. ASSERT_ractor_sched_locked(vm, NULL); if (timer_th.created_fork_gen == current_fork_gen) { if (vm->ractor.sched.timeslice_wait_inf) { RUBY_DEBUG_LOG("wakeup with fd:%d", timer_th.comm_fds[1]); timer_thread_wakeup_force(); } else { RUBY_DEBUG_LOG("will be wakeup..."); } } } static void timer_thread_wakeup(void) { rb_vm_t *vm = GET_VM(); ractor_sched_lock(vm, NULL); { timer_thread_wakeup_locked(vm); } ractor_sched_unlock(vm, NULL); } static void rb_thread_create_timer_thread(void) { rb_serial_t created_fork_gen = timer_th.created_fork_gen; RUBY_DEBUG_LOG("fork_gen create:%d current:%d", (int)created_fork_gen, (int)current_fork_gen); timer_th.created_fork_gen = current_fork_gen; if (created_fork_gen != current_fork_gen) { if (created_fork_gen != 0) { RUBY_DEBUG_LOG("forked child process"); CLOSE_INVALIDATE_PAIR(timer_th.comm_fds); #if HAVE_SYS_EPOLL_H && USE_MN_THREADS close_invalidate(&timer_th.event_fd, "close event_fd"); #endif rb_native_mutex_destroy(&timer_th.waiting_lock); } ccan_list_head_init(&timer_th.waiting); rb_native_mutex_initialize(&timer_th.waiting_lock); // open communication channel setup_communication_pipe_internal(timer_th.comm_fds); // open event fd timer_thread_setup_mn(); } pthread_create(&timer_th.pthread_id, NULL, timer_thread_func, GET_VM()); } static int native_stop_timer_thread(void) { int stopped; stopped = --system_working <= 0; if (stopped) { RUBY_DEBUG_LOG("wakeup send %d", timer_th.comm_fds[1]); timer_thread_wakeup_force(); RUBY_DEBUG_LOG("wakeup sent"); pthread_join(timer_th.pthread_id, NULL); } if (TT_DEBUG) fprintf(stderr, "stop timer thread\n"); return stopped; } static void native_reset_timer_thread(void) { // } #ifdef HAVE_SIGALTSTACK int ruby_stack_overflowed_p(const rb_thread_t *th, const void *addr) { void *base; size_t size; const size_t water_mark = 1024 * 1024; STACK_GROW_DIR_DETECTION; #ifdef STACKADDR_AVAILABLE if (get_stack(&base, &size) == 0) { # ifdef __APPLE__ if (pthread_equal(th->nt->thread_id, native_main_thread.id)) { struct rlimit rlim; if (getrlimit(RLIMIT_STACK, &rlim) == 0 && rlim.rlim_cur > size) { size = (size_t)rlim.rlim_cur; } } # endif base = (char *)base + STACK_DIR_UPPER(+size, -size); } else #endif if (th) { size = th->ec->machine.stack_maxsize; base = (char *)th->ec->machine.stack_start - STACK_DIR_UPPER(0, size); } else { return 0; } size /= RUBY_STACK_SPACE_RATIO; if (size > water_mark) size = water_mark; if (IS_STACK_DIR_UPPER()) { if (size > ~(size_t)base+1) size = ~(size_t)base+1; if (addr > base && addr <= (void *)((char *)base + size)) return 1; } else { if (size > (size_t)base) size = (size_t)base; if (addr > (void *)((char *)base - size) && addr <= base) return 1; } return 0; } #endif int rb_reserved_fd_p(int fd) { /* no false-positive if out-of-FD at startup */ if (fd < 0) return 0; if (fd == timer_th.comm_fds[0] || fd == timer_th.comm_fds[1] #if (HAVE_SYS_EPOLL_H || HAVE_SYS_EVENT_H) && USE_MN_THREADS || fd == timer_th.event_fd #endif ) { goto check_fork_gen; } return 0; check_fork_gen: if (timer_th.created_fork_gen == current_fork_gen) { /* async-signal-safe */ return 1; } else { return 0; } } rb_nativethread_id_t rb_nativethread_self(void) { return pthread_self(); } #if defined(USE_POLL) && !defined(HAVE_PPOLL) /* TODO: don't ignore sigmask */ static int ruby_ppoll(struct pollfd *fds, nfds_t nfds, const struct timespec *ts, const sigset_t *sigmask) { int timeout_ms; if (ts) { int tmp, tmp2; if (ts->tv_sec > INT_MAX/1000) timeout_ms = INT_MAX; else { tmp = (int)(ts->tv_sec * 1000); /* round up 1ns to 1ms to avoid excessive wakeups for <1ms sleep */ tmp2 = (int)((ts->tv_nsec + 999999L) / (1000L * 1000L)); if (INT_MAX - tmp < tmp2) timeout_ms = INT_MAX; else timeout_ms = (int)(tmp + tmp2); } } else timeout_ms = -1; return poll(fds, nfds, timeout_ms); } # define ppoll(fds,nfds,ts,sigmask) ruby_ppoll((fds),(nfds),(ts),(sigmask)) #endif /* * Single CPU setups benefit from explicit sched_yield() before ppoll(), * since threads may be too starved to enter the GVL waitqueue for * us to detect contention. Instead, we want to kick other threads * so they can run and possibly prevent us from entering slow paths * in ppoll() or similar syscalls. * * Confirmed on FreeBSD 11.2 and Linux 4.19. * [ruby-core:90417] [Bug #15398] */ #define THREAD_BLOCKING_YIELD(th) do { \ const rb_thread_t *next_th; \ struct rb_thread_sched *sched = TH_SCHED(th); \ RB_VM_SAVE_MACHINE_CONTEXT(th); \ thread_sched_to_waiting(sched, (th)); \ next_th = sched->running; \ rb_native_mutex_unlock(&sched->lock_); \ native_thread_yield(); /* TODO: needed? */ \ if (!next_th && rb_ractor_living_thread_num(th->ractor) > 1) { \ native_thread_yield(); \ } static void native_sleep(rb_thread_t *th, rb_hrtime_t *rel) { struct rb_thread_sched *sched = TH_SCHED(th); RUBY_DEBUG_LOG("rel:%d", rel ? (int)*rel : 0); if (rel) { if (th_has_dedicated_nt(th)) { native_cond_sleep(th, rel); } else { thread_sched_wait_events(sched, th, -1, thread_sched_waiting_timeout, rel); } } else { thread_sched_to_waiting_until_wakeup(sched, th); } RUBY_DEBUG_LOG("wakeup"); } // fork read-write lock (only for pthread) static pthread_rwlock_t rb_thread_fork_rw_lock = PTHREAD_RWLOCK_INITIALIZER; void rb_thread_release_fork_lock(void) { int r; if ((r = pthread_rwlock_unlock(&rb_thread_fork_rw_lock))) { rb_bug_errno("pthread_rwlock_unlock", r); } } void rb_thread_reset_fork_lock(void) { int r; if ((r = pthread_rwlock_destroy(&rb_thread_fork_rw_lock))) { rb_bug_errno("pthread_rwlock_destroy", r); } if ((r = pthread_rwlock_init(&rb_thread_fork_rw_lock, NULL))) { rb_bug_errno("pthread_rwlock_init", r); } } void * rb_thread_prevent_fork(void *(*func)(void *), void *data) { int r; if ((r = pthread_rwlock_rdlock(&rb_thread_fork_rw_lock))) { rb_bug_errno("pthread_rwlock_rdlock", r); } void *result = func(data); rb_thread_release_fork_lock(); return result; } void rb_thread_acquire_fork_lock(void) { int r; if ((r = pthread_rwlock_wrlock(&rb_thread_fork_rw_lock))) { rb_bug_errno("pthread_rwlock_wrlock", r); } } // thread internal event hooks (only for pthread) struct rb_internal_thread_event_hook { rb_internal_thread_event_callback callback; rb_event_flag_t event; void *user_data; struct rb_internal_thread_event_hook *next; }; static pthread_rwlock_t rb_internal_thread_event_hooks_rw_lock = PTHREAD_RWLOCK_INITIALIZER; rb_internal_thread_event_hook_t * rb_internal_thread_add_event_hook(rb_internal_thread_event_callback callback, rb_event_flag_t internal_event, void *user_data) { rb_internal_thread_event_hook_t *hook = ALLOC_N(rb_internal_thread_event_hook_t, 1); hook->callback = callback; hook->user_data = user_data; hook->event = internal_event; int r; if ((r = pthread_rwlock_wrlock(&rb_internal_thread_event_hooks_rw_lock))) { rb_bug_errno("pthread_rwlock_wrlock", r); } hook->next = rb_internal_thread_event_hooks; ATOMIC_PTR_EXCHANGE(rb_internal_thread_event_hooks, hook); if ((r = pthread_rwlock_unlock(&rb_internal_thread_event_hooks_rw_lock))) { rb_bug_errno("pthread_rwlock_unlock", r); } return hook; } bool rb_internal_thread_remove_event_hook(rb_internal_thread_event_hook_t * hook) { int r; if ((r = pthread_rwlock_wrlock(&rb_internal_thread_event_hooks_rw_lock))) { rb_bug_errno("pthread_rwlock_wrlock", r); } bool success = FALSE; if (rb_internal_thread_event_hooks == hook) { ATOMIC_PTR_EXCHANGE(rb_internal_thread_event_hooks, hook->next); success = TRUE; } else { rb_internal_thread_event_hook_t *h = rb_internal_thread_event_hooks; do { if (h->next == hook) { h->next = hook->next; success = TRUE; break; } } while ((h = h->next)); } if ((r = pthread_rwlock_unlock(&rb_internal_thread_event_hooks_rw_lock))) { rb_bug_errno("pthread_rwlock_unlock", r); } if (success) { ruby_xfree(hook); } return success; } static void rb_thread_execute_hooks(rb_event_flag_t event, rb_thread_t *th) { int r; if ((r = pthread_rwlock_rdlock(&rb_internal_thread_event_hooks_rw_lock))) { rb_bug_errno("pthread_rwlock_rdlock", r); } if (rb_internal_thread_event_hooks) { rb_internal_thread_event_hook_t *h = rb_internal_thread_event_hooks; do { if (h->event & event) { rb_internal_thread_event_data_t event_data = { .thread = th->self, }; (*h->callback)(event, &event_data, h->user_data); } } while((h = h->next)); } if ((r = pthread_rwlock_unlock(&rb_internal_thread_event_hooks_rw_lock))) { rb_bug_errno("pthread_rwlock_unlock", r); } } // return true if the current thread acquires DNT. // return false if the current thread already acquires DNT. bool rb_thread_lock_native_thread(void) { rb_thread_t *th = GET_THREAD(); bool is_snt = th->nt->dedicated == 0; native_thread_dedicated_inc(th->vm, th->ractor, th->nt); return is_snt; } #endif /* THREAD_SYSTEM_DEPENDENT_IMPLEMENTATION */