#define JEMALLOC_BACKGROUND_THREAD_C_ #include "jemalloc/internal/jemalloc_preamble.h" #include "jemalloc/internal/jemalloc_internal_includes.h" #include "jemalloc/internal/assert.h" JEMALLOC_DIAGNOSTIC_DISABLE_SPURIOUS /******************************************************************************/ /* Data. */ /* This option should be opt-in only. */ #define BACKGROUND_THREAD_DEFAULT false /* Read-only after initialization. */ bool opt_background_thread = BACKGROUND_THREAD_DEFAULT; size_t opt_max_background_threads = MAX_BACKGROUND_THREAD_LIMIT + 1; /* Used for thread creation, termination and stats. */ malloc_mutex_t background_thread_lock; /* Indicates global state. Atomic because decay reads this w/o locking. */ atomic_b_t background_thread_enabled_state; size_t n_background_threads; size_t max_background_threads; /* Thread info per-index. */ background_thread_info_t *background_thread_info; /******************************************************************************/ #ifdef JEMALLOC_PTHREAD_CREATE_WRAPPER static int (*pthread_create_fptr)(pthread_t *__restrict, const pthread_attr_t *, void *(*)(void *), void *__restrict); static void pthread_create_wrapper_init(void) { #ifdef JEMALLOC_LAZY_LOCK if (!isthreaded) { isthreaded = true; } #endif } int pthread_create_wrapper(pthread_t *__restrict thread, const pthread_attr_t *attr, void *(*start_routine)(void *), void *__restrict arg) { pthread_create_wrapper_init(); return pthread_create_fptr(thread, attr, start_routine, arg); } #endif /* JEMALLOC_PTHREAD_CREATE_WRAPPER */ #ifndef JEMALLOC_BACKGROUND_THREAD #define NOT_REACHED { not_reached(); } bool background_thread_create(tsd_t *tsd, unsigned arena_ind) NOT_REACHED bool background_threads_enable(tsd_t *tsd) NOT_REACHED bool background_threads_disable(tsd_t *tsd) NOT_REACHED void background_thread_interval_check(tsdn_t *tsdn, arena_t *arena, arena_decay_t *decay, size_t npages_new) NOT_REACHED void background_thread_prefork0(tsdn_t *tsdn) NOT_REACHED void background_thread_prefork1(tsdn_t *tsdn) NOT_REACHED void background_thread_postfork_parent(tsdn_t *tsdn) NOT_REACHED void background_thread_postfork_child(tsdn_t *tsdn) NOT_REACHED bool background_thread_stats_read(tsdn_t *tsdn, background_thread_stats_t *stats) NOT_REACHED void background_thread_ctl_init(tsdn_t *tsdn) NOT_REACHED #undef NOT_REACHED #else static bool background_thread_enabled_at_fork; static void background_thread_info_init(tsdn_t *tsdn, background_thread_info_t *info) { background_thread_wakeup_time_set(tsdn, info, 0); info->npages_to_purge_new = 0; if (config_stats) { info->tot_n_runs = 0; nstime_init(&info->tot_sleep_time, 0); } } static inline bool set_current_thread_affinity(int cpu) { #if defined(JEMALLOC_HAVE_SCHED_SETAFFINITY) cpu_set_t cpuset; CPU_ZERO(&cpuset); CPU_SET(cpu, &cpuset); int ret = sched_setaffinity(0, sizeof(cpu_set_t), &cpuset); return (ret != 0); #else return false; #endif } /* Threshold for determining when to wake up the background thread. */ #define BACKGROUND_THREAD_NPAGES_THRESHOLD UINT64_C(1024) #define BILLION UINT64_C(1000000000) /* Minimal sleep interval 100 ms. */ #define BACKGROUND_THREAD_MIN_INTERVAL_NS (BILLION / 10) static inline size_t decay_npurge_after_interval(arena_decay_t *decay, size_t interval) { size_t i; uint64_t sum = 0; for (i = 0; i < interval; i++) { sum += decay->backlog[i] * h_steps[i]; } for (; i < SMOOTHSTEP_NSTEPS; i++) { sum += decay->backlog[i] * (h_steps[i] - h_steps[i - interval]); } return (size_t)(sum >> SMOOTHSTEP_BFP); } static uint64_t arena_decay_compute_purge_interval_impl(tsdn_t *tsdn, arena_decay_t *decay, extents_t *extents) { if (malloc_mutex_trylock(tsdn, &decay->mtx)) { /* Use minimal interval if decay is contended. */ return BACKGROUND_THREAD_MIN_INTERVAL_NS; } uint64_t interval; ssize_t decay_time = atomic_load_zd(&decay->time_ms, ATOMIC_RELAXED); if (decay_time <= 0) { /* Purging is eagerly done or disabled currently. */ interval = BACKGROUND_THREAD_INDEFINITE_SLEEP; goto label_done; } uint64_t decay_interval_ns = nstime_ns(&decay->interval); assert(decay_interval_ns > 0); size_t npages = extents_npages_get(extents); if (npages == 0) { unsigned i; for (i = 0; i < SMOOTHSTEP_NSTEPS; i++) { if (decay->backlog[i] > 0) { break; } } if (i == SMOOTHSTEP_NSTEPS) { /* No dirty pages recorded. Sleep indefinitely. */ interval = BACKGROUND_THREAD_INDEFINITE_SLEEP; goto label_done; } } if (npages <= BACKGROUND_THREAD_NPAGES_THRESHOLD) { /* Use max interval. */ interval = decay_interval_ns * SMOOTHSTEP_NSTEPS; goto label_done; } size_t lb = BACKGROUND_THREAD_MIN_INTERVAL_NS / decay_interval_ns; size_t ub = SMOOTHSTEP_NSTEPS; /* Minimal 2 intervals to ensure reaching next epoch deadline. */ lb = (lb < 2) ? 2 : lb; if ((decay_interval_ns * ub <= BACKGROUND_THREAD_MIN_INTERVAL_NS) || (lb + 2 > ub)) { interval = BACKGROUND_THREAD_MIN_INTERVAL_NS; goto label_done; } assert(lb + 2 <= ub); size_t npurge_lb, npurge_ub; npurge_lb = decay_npurge_after_interval(decay, lb); if (npurge_lb > BACKGROUND_THREAD_NPAGES_THRESHOLD) { interval = decay_interval_ns * lb; goto label_done; } npurge_ub = decay_npurge_after_interval(decay, ub); if (npurge_ub < BACKGROUND_THREAD_NPAGES_THRESHOLD) { interval = decay_interval_ns * ub; goto label_done; } unsigned n_search = 0; size_t target, npurge; while ((npurge_lb + BACKGROUND_THREAD_NPAGES_THRESHOLD < npurge_ub) && (lb + 2 < ub)) { target = (lb + ub) / 2; npurge = decay_npurge_after_interval(decay, target); if (npurge > BACKGROUND_THREAD_NPAGES_THRESHOLD) { ub = target; npurge_ub = npurge; } else { lb = target; npurge_lb = npurge; } assert(n_search++ < lg_floor(SMOOTHSTEP_NSTEPS) + 1); } interval = decay_interval_ns * (ub + lb) / 2; label_done: interval = (interval < BACKGROUND_THREAD_MIN_INTERVAL_NS) ? BACKGROUND_THREAD_MIN_INTERVAL_NS : interval; malloc_mutex_unlock(tsdn, &decay->mtx); return interval; } /* Compute purge interval for background threads. */ static uint64_t arena_decay_compute_purge_interval(tsdn_t *tsdn, arena_t *arena) { uint64_t i1, i2; i1 = arena_decay_compute_purge_interval_impl(tsdn, &arena->decay_dirty, &arena->extents_dirty); if (i1 == BACKGROUND_THREAD_MIN_INTERVAL_NS) { return i1; } i2 = arena_decay_compute_purge_interval_impl(tsdn, &arena->decay_muzzy, &arena->extents_muzzy); return i1 < i2 ? i1 : i2; } static void background_thread_sleep(tsdn_t *tsdn, background_thread_info_t *info, uint64_t interval) { if (config_stats) { info->tot_n_runs++; } info->npages_to_purge_new = 0; struct timeval tv; /* Specific clock required by timedwait. */ gettimeofday(&tv, NULL); nstime_t before_sleep; nstime_init2(&before_sleep, tv.tv_sec, tv.tv_usec * 1000); int ret; if (interval == BACKGROUND_THREAD_INDEFINITE_SLEEP) { assert(background_thread_indefinite_sleep(info)); ret = pthread_cond_wait(&info->cond, &info->mtx.lock); assert(ret == 0); } else { assert(interval >= BACKGROUND_THREAD_MIN_INTERVAL_NS && interval <= BACKGROUND_THREAD_INDEFINITE_SLEEP); /* We need malloc clock (can be different from tv). */ nstime_t next_wakeup; nstime_init(&next_wakeup, 0); nstime_update(&next_wakeup); nstime_iadd(&next_wakeup, interval); assert(nstime_ns(&next_wakeup) < BACKGROUND_THREAD_INDEFINITE_SLEEP); background_thread_wakeup_time_set(tsdn, info, nstime_ns(&next_wakeup)); nstime_t ts_wakeup; nstime_copy(&ts_wakeup, &before_sleep); nstime_iadd(&ts_wakeup, interval); struct timespec ts; ts.tv_sec = (size_t)nstime_sec(&ts_wakeup); ts.tv_nsec = (size_t)nstime_nsec(&ts_wakeup); assert(!background_thread_indefinite_sleep(info)); ret = pthread_cond_timedwait(&info->cond, &info->mtx.lock, &ts); assert(ret == ETIMEDOUT || ret == 0); background_thread_wakeup_time_set(tsdn, info, BACKGROUND_THREAD_INDEFINITE_SLEEP); } if (config_stats) { gettimeofday(&tv, NULL); nstime_t after_sleep; nstime_init2(&after_sleep, tv.tv_sec, tv.tv_usec * 1000); if (nstime_compare(&after_sleep, &before_sleep) > 0) { nstime_subtract(&after_sleep, &before_sleep); nstime_add(&info->tot_sleep_time, &after_sleep); } } } static bool background_thread_pause_check(tsdn_t *tsdn, background_thread_info_t *info) { if (unlikely(info->state == background_thread_paused)) { malloc_mutex_unlock(tsdn, &info->mtx); /* Wait on global lock to update status. */ malloc_mutex_lock(tsdn, &background_thread_lock); malloc_mutex_unlock(tsdn, &background_thread_lock); malloc_mutex_lock(tsdn, &info->mtx); return true; } return false; } static inline void background_work_sleep_once(tsdn_t *tsdn, background_thread_info_t *info, unsigned ind) { uint64_t min_interval = BACKGROUND_THREAD_INDEFINITE_SLEEP; unsigned narenas = narenas_total_get(); for (unsigned i = ind; i < narenas; i += max_background_threads) { arena_t *arena = arena_get(tsdn, i, false); if (!arena) { continue; } arena_decay(tsdn, arena, true, false); if (min_interval == BACKGROUND_THREAD_MIN_INTERVAL_NS) { /* Min interval will be used. */ continue; } uint64_t interval = arena_decay_compute_purge_interval(tsdn, arena); assert(interval >= BACKGROUND_THREAD_MIN_INTERVAL_NS); if (min_interval > interval) { min_interval = interval; } } background_thread_sleep(tsdn, info, min_interval); } static bool background_threads_disable_single(tsd_t *tsd, background_thread_info_t *info) { if (info == &background_thread_info[0]) { malloc_mutex_assert_owner(tsd_tsdn(tsd), &background_thread_lock); } else { malloc_mutex_assert_not_owner(tsd_tsdn(tsd), &background_thread_lock); } pre_reentrancy(tsd, NULL); malloc_mutex_lock(tsd_tsdn(tsd), &info->mtx); bool has_thread; assert(info->state != background_thread_paused); if (info->state == background_thread_started) { has_thread = true; info->state = background_thread_stopped; pthread_cond_signal(&info->cond); } else { has_thread = false; } malloc_mutex_unlock(tsd_tsdn(tsd), &info->mtx); if (!has_thread) { post_reentrancy(tsd); return false; } void *ret; if (pthread_join(info->thread, &ret)) { post_reentrancy(tsd); return true; } assert(ret == NULL); n_background_threads--; post_reentrancy(tsd); return false; } static void *background_thread_entry(void *ind_arg); static int background_thread_create_signals_masked(pthread_t *thread, const pthread_attr_t *attr, void *(*start_routine)(void *), void *arg) { /* * Mask signals during thread creation so that the thread inherits * an empty signal set. */ sigset_t set; sigfillset(&set); sigset_t oldset; int mask_err = pthread_sigmask(SIG_SETMASK, &set, &oldset); if (mask_err != 0) { return mask_err; } int create_err = pthread_create_wrapper(thread, attr, start_routine, arg); /* * Restore the signal mask. Failure to restore the signal mask here * changes program behavior. */ int restore_err = pthread_sigmask(SIG_SETMASK, &oldset, NULL); if (restore_err != 0) { malloc_printf(": background thread creation " "failed (%d), and signal mask restoration failed " "(%d)\n", create_err, restore_err); if (opt_abort) { abort(); } } return create_err; } static bool check_background_thread_creation(tsd_t *tsd, unsigned *n_created, bool *created_threads) { bool ret = false; if (likely(*n_created == n_background_threads)) { return ret; } tsdn_t *tsdn = tsd_tsdn(tsd); malloc_mutex_unlock(tsdn, &background_thread_info[0].mtx); for (unsigned i = 1; i < max_background_threads; i++) { if (created_threads[i]) { continue; } background_thread_info_t *info = &background_thread_info[i]; malloc_mutex_lock(tsdn, &info->mtx); /* * In case of the background_thread_paused state because of * arena reset, delay the creation. */ bool create = (info->state == background_thread_started); malloc_mutex_unlock(tsdn, &info->mtx); if (!create) { continue; } pre_reentrancy(tsd, NULL); int err = background_thread_create_signals_masked(&info->thread, NULL, background_thread_entry, (void *)(uintptr_t)i); post_reentrancy(tsd); if (err == 0) { (*n_created)++; created_threads[i] = true; } else { malloc_printf(": background thread " "creation failed (%d)\n", err); if (opt_abort) { abort(); } } /* Return to restart the loop since we unlocked. */ ret = true; break; } malloc_mutex_lock(tsdn, &background_thread_info[0].mtx); return ret; } static void background_thread0_work(tsd_t *tsd) { /* Thread0 is also responsible for launching / terminating threads. */ VARIABLE_ARRAY(bool, created_threads, max_background_threads); unsigned i; for (i = 1; i < max_background_threads; i++) { created_threads[i] = false; } /* Start working, and create more threads when asked. */ unsigned n_created = 1; while (background_thread_info[0].state != background_thread_stopped) { if (background_thread_pause_check(tsd_tsdn(tsd), &background_thread_info[0])) { continue; } if (check_background_thread_creation(tsd, &n_created, (bool *)&created_threads)) { continue; } background_work_sleep_once(tsd_tsdn(tsd), &background_thread_info[0], 0); } /* * Shut down other threads at exit. Note that the ctl thread is holding * the global background_thread mutex (and is waiting) for us. */ assert(!background_thread_enabled()); for (i = 1; i < max_background_threads; i++) { background_thread_info_t *info = &background_thread_info[i]; assert(info->state != background_thread_paused); if (created_threads[i]) { background_threads_disable_single(tsd, info); } else { malloc_mutex_lock(tsd_tsdn(tsd), &info->mtx); if (info->state != background_thread_stopped) { /* The thread was not created. */ assert(info->state == background_thread_started); n_background_threads--; info->state = background_thread_stopped; } malloc_mutex_unlock(tsd_tsdn(tsd), &info->mtx); } } background_thread_info[0].state = background_thread_stopped; assert(n_background_threads == 1); } static void background_work(tsd_t *tsd, unsigned ind) { background_thread_info_t *info = &background_thread_info[ind]; malloc_mutex_lock(tsd_tsdn(tsd), &info->mtx); background_thread_wakeup_time_set(tsd_tsdn(tsd), info, BACKGROUND_THREAD_INDEFINITE_SLEEP); if (ind == 0) { background_thread0_work(tsd); } else { while (info->state != background_thread_stopped) { if (background_thread_pause_check(tsd_tsdn(tsd), info)) { continue; } background_work_sleep_once(tsd_tsdn(tsd), info, ind); } } assert(info->state == background_thread_stopped); background_thread_wakeup_time_set(tsd_tsdn(tsd), info, 0); malloc_mutex_unlock(tsd_tsdn(tsd), &info->mtx); } static void * background_thread_entry(void *ind_arg) { unsigned thread_ind = (unsigned)(uintptr_t)ind_arg; assert(thread_ind < max_background_threads); #ifdef JEMALLOC_HAVE_PTHREAD_SETNAME_NP pthread_setname_np(pthread_self(), "jemalloc_bg_thd"); #elif defined(__FreeBSD__) pthread_set_name_np(pthread_self(), "jemalloc_bg_thd"); #endif if (opt_percpu_arena != percpu_arena_disabled) { set_current_thread_affinity((int)thread_ind); } /* * Start periodic background work. We use internal tsd which avoids * side effects, for example triggering new arena creation (which in * turn triggers another background thread creation). */ background_work(tsd_internal_fetch(), thread_ind); assert(pthread_equal(pthread_self(), background_thread_info[thread_ind].thread)); return NULL; } static void background_thread_init(tsd_t *tsd, background_thread_info_t *info) { malloc_mutex_assert_owner(tsd_tsdn(tsd), &background_thread_lock); info->state = background_thread_started; background_thread_info_init(tsd_tsdn(tsd), info); n_background_threads++; } static bool background_thread_create_locked(tsd_t *tsd, unsigned arena_ind) { assert(have_background_thread); malloc_mutex_assert_owner(tsd_tsdn(tsd), &background_thread_lock); /* We create at most NCPUs threads. */ size_t thread_ind = arena_ind % max_background_threads; background_thread_info_t *info = &background_thread_info[thread_ind]; bool need_new_thread; malloc_mutex_lock(tsd_tsdn(tsd), &info->mtx); need_new_thread = background_thread_enabled() && (info->state == background_thread_stopped); if (need_new_thread) { background_thread_init(tsd, info); } malloc_mutex_unlock(tsd_tsdn(tsd), &info->mtx); if (!need_new_thread) { return false; } if (arena_ind != 0) { /* Threads are created asynchronously by Thread 0. */ background_thread_info_t *t0 = &background_thread_info[0]; malloc_mutex_lock(tsd_tsdn(tsd), &t0->mtx); assert(t0->state == background_thread_started); pthread_cond_signal(&t0->cond); malloc_mutex_unlock(tsd_tsdn(tsd), &t0->mtx); return false; } pre_reentrancy(tsd, NULL); /* * To avoid complications (besides reentrancy), create internal * background threads with the underlying pthread_create. */ int err = background_thread_create_signals_masked(&info->thread, NULL, background_thread_entry, (void *)thread_ind); post_reentrancy(tsd); if (err != 0) { malloc_printf(": arena 0 background thread creation " "failed (%d)\n", err); malloc_mutex_lock(tsd_tsdn(tsd), &info->mtx); info->state = background_thread_stopped; n_background_threads--; malloc_mutex_unlock(tsd_tsdn(tsd), &info->mtx); return true; } return false; } /* Create a new background thread if needed. */ bool background_thread_create(tsd_t *tsd, unsigned arena_ind) { assert(have_background_thread); bool ret; malloc_mutex_lock(tsd_tsdn(tsd), &background_thread_lock); ret = background_thread_create_locked(tsd, arena_ind); malloc_mutex_unlock(tsd_tsdn(tsd), &background_thread_lock); return ret; } bool background_threads_enable(tsd_t *tsd) { assert(n_background_threads == 0); assert(background_thread_enabled()); malloc_mutex_assert_owner(tsd_tsdn(tsd), &background_thread_lock); VARIABLE_ARRAY(bool, marked, max_background_threads); unsigned i, nmarked; for (i = 0; i < max_background_threads; i++) { marked[i] = false; } nmarked = 0; /* Thread 0 is required and created at the end. */ marked[0] = true; /* Mark the threads we need to create for thread 0. */ unsigned n = narenas_total_get(); for (i = 1; i < n; i++) { if (marked[i % max_background_threads] || arena_get(tsd_tsdn(tsd), i, false) == NULL) { continue; } background_thread_info_t *info = &background_thread_info[ i % max_background_threads]; malloc_mutex_lock(tsd_tsdn(tsd), &info->mtx); assert(info->state == background_thread_stopped); background_thread_init(tsd, info); malloc_mutex_unlock(tsd_tsdn(tsd), &info->mtx); marked[i % max_background_threads] = true; if (++nmarked == max_background_threads) { break; } } return background_thread_create_locked(tsd, 0); } bool background_threads_disable(tsd_t *tsd) { assert(!background_thread_enabled()); malloc_mutex_assert_owner(tsd_tsdn(tsd), &background_thread_lock); /* Thread 0 will be responsible for terminating other threads. */ if (background_threads_disable_single(tsd, &background_thread_info[0])) { return true; } assert(n_background_threads == 0); return false; } /* Check if we need to signal the background thread early. */ void background_thread_interval_check(tsdn_t *tsdn, arena_t *arena, arena_decay_t *decay, size_t npages_new) { background_thread_info_t *info = arena_background_thread_info_get( arena); if (malloc_mutex_trylock(tsdn, &info->mtx)) { /* * Background thread may hold the mutex for a long period of * time. We'd like to avoid the variance on application * threads. So keep this non-blocking, and leave the work to a * future epoch. */ return; } if (info->state != background_thread_started) { goto label_done; } if (malloc_mutex_trylock(tsdn, &decay->mtx)) { goto label_done; } ssize_t decay_time = atomic_load_zd(&decay->time_ms, ATOMIC_RELAXED); if (decay_time <= 0) { /* Purging is eagerly done or disabled currently. */ goto label_done_unlock2; } uint64_t decay_interval_ns = nstime_ns(&decay->interval); assert(decay_interval_ns > 0); nstime_t diff; nstime_init(&diff, background_thread_wakeup_time_get(info)); if (nstime_compare(&diff, &decay->epoch) <= 0) { goto label_done_unlock2; } nstime_subtract(&diff, &decay->epoch); if (nstime_ns(&diff) < BACKGROUND_THREAD_MIN_INTERVAL_NS) { goto label_done_unlock2; } if (npages_new > 0) { size_t n_epoch = (size_t)(nstime_ns(&diff) / decay_interval_ns); /* * Compute how many new pages we would need to purge by the next * wakeup, which is used to determine if we should signal the * background thread. */ uint64_t npurge_new; if (n_epoch >= SMOOTHSTEP_NSTEPS) { npurge_new = npages_new; } else { uint64_t h_steps_max = h_steps[SMOOTHSTEP_NSTEPS - 1]; assert(h_steps_max >= h_steps[SMOOTHSTEP_NSTEPS - 1 - n_epoch]); npurge_new = npages_new * (h_steps_max - h_steps[SMOOTHSTEP_NSTEPS - 1 - n_epoch]); npurge_new >>= SMOOTHSTEP_BFP; } info->npages_to_purge_new += npurge_new; } bool should_signal; if (info->npages_to_purge_new > BACKGROUND_THREAD_NPAGES_THRESHOLD) { should_signal = true; } else if (unlikely(background_thread_indefinite_sleep(info)) && (extents_npages_get(&arena->extents_dirty) > 0 || extents_npages_get(&arena->extents_muzzy) > 0 || info->npages_to_purge_new > 0)) { should_signal = true; } else { should_signal = false; } if (should_signal) { info->npages_to_purge_new = 0; pthread_cond_signal(&info->cond); } label_done_unlock2: malloc_mutex_unlock(tsdn, &decay->mtx); label_done: malloc_mutex_unlock(tsdn, &info->mtx); } void background_thread_prefork0(tsdn_t *tsdn) { malloc_mutex_prefork(tsdn, &background_thread_lock); background_thread_enabled_at_fork = background_thread_enabled(); } void background_thread_prefork1(tsdn_t *tsdn) { for (unsigned i = 0; i < max_background_threads; i++) { malloc_mutex_prefork(tsdn, &background_thread_info[i].mtx); } } void background_thread_postfork_parent(tsdn_t *tsdn) { for (unsigned i = 0; i < max_background_threads; i++) { malloc_mutex_postfork_parent(tsdn, &background_thread_info[i].mtx); } malloc_mutex_postfork_parent(tsdn, &background_thread_lock); } void background_thread_postfork_child(tsdn_t *tsdn) { for (unsigned i = 0; i < max_background_threads; i++) { malloc_mutex_postfork_child(tsdn, &background_thread_info[i].mtx); } malloc_mutex_postfork_child(tsdn, &background_thread_lock); if (!background_thread_enabled_at_fork) { return; } /* Clear background_thread state (reset to disabled for child). */ malloc_mutex_lock(tsdn, &background_thread_lock); n_background_threads = 0; background_thread_enabled_set(tsdn, false); for (unsigned i = 0; i < max_background_threads; i++) { background_thread_info_t *info = &background_thread_info[i]; malloc_mutex_lock(tsdn, &info->mtx); info->state = background_thread_stopped; int ret = pthread_cond_init(&info->cond, NULL); assert(ret == 0); background_thread_info_init(tsdn, info); malloc_mutex_unlock(tsdn, &info->mtx); } malloc_mutex_unlock(tsdn, &background_thread_lock); } bool background_thread_stats_read(tsdn_t *tsdn, background_thread_stats_t *stats) { assert(config_stats); malloc_mutex_lock(tsdn, &background_thread_lock); if (!background_thread_enabled()) { malloc_mutex_unlock(tsdn, &background_thread_lock); return true; } stats->num_threads = n_background_threads; uint64_t num_runs = 0; nstime_init(&stats->run_interval, 0); for (unsigned i = 0; i < max_background_threads; i++) { background_thread_info_t *info = &background_thread_info[i]; if (malloc_mutex_trylock(tsdn, &info->mtx)) { /* * Each background thread run may take a long time; * avoid waiting on the stats if the thread is active. */ continue; } if (info->state != background_thread_stopped) { num_runs += info->tot_n_runs; nstime_add(&stats->run_interval, &info->tot_sleep_time); } malloc_mutex_unlock(tsdn, &info->mtx); } stats->num_runs = num_runs; if (num_runs > 0) { nstime_idivide(&stats->run_interval, num_runs); } malloc_mutex_unlock(tsdn, &background_thread_lock); return false; } #undef BACKGROUND_THREAD_NPAGES_THRESHOLD #undef BILLION #undef BACKGROUND_THREAD_MIN_INTERVAL_NS #ifdef JEMALLOC_HAVE_DLSYM #include #endif static bool pthread_create_fptr_init(void) { if (pthread_create_fptr != NULL) { return false; } /* * Try the next symbol first, because 1) when use lazy_lock we have a * wrapper for pthread_create; and 2) application may define its own * wrapper as well (and can call malloc within the wrapper). */ #ifdef JEMALLOC_HAVE_DLSYM pthread_create_fptr = dlsym(RTLD_NEXT, "pthread_create"); #else pthread_create_fptr = NULL; #endif if (pthread_create_fptr == NULL) { if (config_lazy_lock) { malloc_write(": Error in dlsym(RTLD_NEXT, " "\"pthread_create\")\n"); abort(); } else { /* Fall back to the default symbol. */ pthread_create_fptr = pthread_create; } } return false; } /* * When lazy lock is enabled, we need to make sure setting isthreaded before * taking any background_thread locks. This is called early in ctl (instead of * wait for the pthread_create calls to trigger) because the mutex is required * before creating background threads. */ void background_thread_ctl_init(tsdn_t *tsdn) { malloc_mutex_assert_not_owner(tsdn, &background_thread_lock); #ifdef JEMALLOC_PTHREAD_CREATE_WRAPPER pthread_create_fptr_init(); pthread_create_wrapper_init(); #endif } #endif /* defined(JEMALLOC_BACKGROUND_THREAD) */ bool background_thread_boot0(void) { if (!have_background_thread && opt_background_thread) { malloc_printf(": option background_thread currently " "supports pthread only\n"); return true; } #ifdef JEMALLOC_PTHREAD_CREATE_WRAPPER if ((config_lazy_lock || opt_background_thread) && pthread_create_fptr_init()) { return true; } #endif return false; } bool background_thread_boot1(tsdn_t *tsdn) { #ifdef JEMALLOC_BACKGROUND_THREAD assert(have_background_thread); assert(narenas_total_get() > 0); if (opt_max_background_threads > MAX_BACKGROUND_THREAD_LIMIT) { opt_max_background_threads = DEFAULT_NUM_BACKGROUND_THREAD; } max_background_threads = opt_max_background_threads; background_thread_enabled_set(tsdn, opt_background_thread); if (malloc_mutex_init(&background_thread_lock, "background_thread_global", WITNESS_RANK_BACKGROUND_THREAD_GLOBAL, malloc_mutex_rank_exclusive)) { return true; } background_thread_info = (background_thread_info_t *)base_alloc(tsdn, b0get(), opt_max_background_threads * sizeof(background_thread_info_t), CACHELINE); if (background_thread_info == NULL) { return true; } for (unsigned i = 0; i < max_background_threads; i++) { background_thread_info_t *info = &background_thread_info[i]; /* Thread mutex is rank_inclusive because of thread0. */ if (malloc_mutex_init(&info->mtx, "background_thread", WITNESS_RANK_BACKGROUND_THREAD, malloc_mutex_address_ordered)) { return true; } if (pthread_cond_init(&info->cond, NULL)) { return true; } malloc_mutex_lock(tsdn, &info->mtx); info->state = background_thread_stopped; background_thread_info_init(tsdn, info); malloc_mutex_unlock(tsdn, &info->mtx); } #endif return false; }