[urcu.git] / src / workqueue.c

/*
 * workqueue.c
 *
 * Userspace RCU library - Userspace workqeues
 *
 * Copyright (c) 2010 Paul E. McKenney <paulmck@linux.vnet.ibm.com>
 * Copyright (c) 2017 Mathieu Desnoyers <mathieu.desnoyers@efficios.com>
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with this library; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
 */

#define _LGPL_SOURCE
#include <stdio.h>
#include <pthread.h>
#include <signal.h>
#include <stdlib.h>
#include <stdint.h>
#include <string.h>
#include <errno.h>
#include <poll.h>
#include <sys/time.h>
#include <unistd.h>
#include <sched.h>

#include "compat-getcpu.h"
#include <urcu/assert.h>
#include <urcu/wfcqueue.h>
#include <urcu/pointer.h>
#include <urcu/list.h>
#include <urcu/futex.h>
#include <urcu/tls-compat.h>
#include <urcu/ref.h>
#include "urcu-die.h"

#include "workqueue.h"

#define SET_AFFINITY_CHECK_PERIOD               (1U << 8)       /* 256 */
#define SET_AFFINITY_CHECK_PERIOD_MASK          (SET_AFFINITY_CHECK_PERIOD - 1)

/* Data structure that identifies a workqueue. */

struct urcu_workqueue {
        /*
         * We do not align head on a different cache-line than tail
         * mainly because workqueue threads use batching ("splice") to
         * get an entire list of callbacks, which effectively empties
         * the queue, and requires to touch the tail anyway.
         */
        struct cds_wfcq_tail cbs_tail;
        struct cds_wfcq_head cbs_head;
        unsigned long flags;
        int32_t futex;
        unsigned long qlen; /* maintained for debugging. */
        pthread_t tid;
        int cpu_affinity;
        unsigned long loop_count;
        void *priv;
        void (*grace_period_fct)(struct urcu_workqueue *workqueue, void *priv);
        void (*initialize_worker_fct)(struct urcu_workqueue *workqueue, void *priv);
        void (*finalize_worker_fct)(struct urcu_workqueue *workqueue, void *priv);
        void (*worker_before_pause_fct)(struct urcu_workqueue *workqueue, void *priv);
        void (*worker_after_resume_fct)(struct urcu_workqueue *workqueue, void *priv);
        void (*worker_before_wait_fct)(struct urcu_workqueue *workqueue, void *priv);
        void (*worker_after_wake_up_fct)(struct urcu_workqueue *workqueue, void *priv);
} __attribute__((aligned(CAA_CACHE_LINE_SIZE)));

struct urcu_workqueue_completion {
        int barrier_count;
        int32_t futex;
        struct urcu_ref ref;
};

struct urcu_workqueue_completion_work {
        struct urcu_work work;
        struct urcu_workqueue_completion *completion;
};

/*
 * Periodically retry setting CPU affinity if we migrate.
 * Losing affinity can be caused by CPU hotunplug/hotplug, or by
 * cpuset(7).
 */
#ifdef HAVE_SCHED_SETAFFINITY
static int set_thread_cpu_affinity(struct urcu_workqueue *workqueue)
{
        cpu_set_t mask;
        int ret;

        if (workqueue->cpu_affinity < 0)
                return 0;
        if (++workqueue->loop_count & SET_AFFINITY_CHECK_PERIOD_MASK)
                return 0;
        if (urcu_sched_getcpu() == workqueue->cpu_affinity)
                return 0;

        CPU_ZERO(&mask);
        CPU_SET(workqueue->cpu_affinity, &mask);
        ret = sched_setaffinity(0, sizeof(mask), &mask);

        /*
         * EINVAL is fine: can be caused by hotunplugged CPUs, or by
         * cpuset(7). This is why we should always retry if we detect
         * migration.
         */
        if (ret && errno == EINVAL) {
                ret = 0;
                errno = 0;
        }
        return ret;
}
#else
static int set_thread_cpu_affinity(struct urcu_workqueue *workqueue __attribute__((unused)))
{
        return 0;
}
#endif

static void futex_wait(int32_t *futex)
{
        int ret;

        /* Read condition before read futex */
        cmm_smp_mb();
        while (uatomic_read(futex) == -1) {
                if (!futex_async(futex, FUTEX_WAIT, -1, NULL, NULL, 0)) {
                        /*
                         * Prior queued wakeups queued by unrelated code
                         * using the same address can cause futex wait to
                         * return 0 even through the futex value is still
                         * -1 (spurious wakeups). Check the value again
                         * in user-space to validate whether it really
                         * differs from -1.
                         */
                        continue;
                }
                switch (errno) {
                case EAGAIN:
                        /* Value already changed. */
                        return;
                case EINTR:
                        /* Retry if interrupted by signal. */
                        break;  /* Get out of switch. Check again. */
                default:
                        /* Unexpected error. */
                        urcu_die(errno);
                }
        }
}

static void futex_wake_up(int32_t *futex)
{
        /* Write to condition before reading/writing futex */
        cmm_smp_mb();
        if (caa_unlikely(uatomic_read(futex) == -1)) {
                uatomic_set(futex, 0);
                if (futex_async(futex, FUTEX_WAKE, 1,
                                NULL, NULL, 0) < 0)
                        urcu_die(errno);
        }
}

/* This is the code run by each worker thread. */

static void *workqueue_thread(void *arg)
{
        unsigned long cbcount;
        struct urcu_workqueue *workqueue = (struct urcu_workqueue *) arg;
        int rt = !!(uatomic_read(&workqueue->flags) & URCU_WORKQUEUE_RT);

        if (set_thread_cpu_affinity(workqueue))
                urcu_die(errno);

        if (workqueue->initialize_worker_fct)
                workqueue->initialize_worker_fct(workqueue, workqueue->priv);

        if (!rt) {
                uatomic_dec(&workqueue->futex);
                /* Decrement futex before reading workqueue */
                cmm_smp_mb();
        }
        for (;;) {
                struct cds_wfcq_head cbs_tmp_head;
                struct cds_wfcq_tail cbs_tmp_tail;
                struct cds_wfcq_node *cbs, *cbs_tmp_n;
                enum cds_wfcq_ret splice_ret;

                if (set_thread_cpu_affinity(workqueue))
                        urcu_die(errno);

                if (uatomic_read(&workqueue->flags) & URCU_WORKQUEUE_PAUSE) {
                        /*
                         * Pause requested. Become quiescent: remove
                         * ourself from all global lists, and don't
                         * process any callback. The callback lists may
                         * still be non-empty though.
                         */
                        if (workqueue->worker_before_pause_fct)
                                workqueue->worker_before_pause_fct(workqueue, workqueue->priv);
                        cmm_smp_mb__before_uatomic_or();
                        uatomic_or(&workqueue->flags, URCU_WORKQUEUE_PAUSED);
                        while ((uatomic_read(&workqueue->flags) & URCU_WORKQUEUE_PAUSE) != 0)
                                (void) poll(NULL, 0, 1);
                        uatomic_and(&workqueue->flags, ~URCU_WORKQUEUE_PAUSED);
                        cmm_smp_mb__after_uatomic_and();
                        if (workqueue->worker_after_resume_fct)
                                workqueue->worker_after_resume_fct(workqueue, workqueue->priv);
                }

                cds_wfcq_init(&cbs_tmp_head, &cbs_tmp_tail);
                splice_ret = __cds_wfcq_splice_blocking(&cbs_tmp_head,
                        &cbs_tmp_tail, &workqueue->cbs_head, &workqueue->cbs_tail);
                urcu_posix_assert(splice_ret != CDS_WFCQ_RET_WOULDBLOCK);
                urcu_posix_assert(splice_ret != CDS_WFCQ_RET_DEST_NON_EMPTY);
                if (splice_ret != CDS_WFCQ_RET_SRC_EMPTY) {
                        if (workqueue->grace_period_fct)
                                workqueue->grace_period_fct(workqueue, workqueue->priv);
                        cbcount = 0;
                        __cds_wfcq_for_each_blocking_safe(&cbs_tmp_head,
                                        &cbs_tmp_tail, cbs, cbs_tmp_n) {
                                struct urcu_work *uwp;

                                uwp = caa_container_of(cbs,
                                        struct urcu_work, next);
                                uwp->func(uwp);
                                cbcount++;
                        }
                        uatomic_sub(&workqueue->qlen, cbcount);
                }
                if (uatomic_read(&workqueue->flags) & URCU_WORKQUEUE_STOP)
                        break;
                if (workqueue->worker_before_wait_fct)
                        workqueue->worker_before_wait_fct(workqueue, workqueue->priv);
                if (!rt) {
                        if (cds_wfcq_empty(&workqueue->cbs_head,
                                        &workqueue->cbs_tail)) {
                                futex_wait(&workqueue->futex);
                                uatomic_dec(&workqueue->futex);
                                /*
                                 * Decrement futex before reading
                                 * urcu_work list.
                                 */
                                cmm_smp_mb();
                        }
                } else {
                        if (cds_wfcq_empty(&workqueue->cbs_head,
                                        &workqueue->cbs_tail)) {
                                (void) poll(NULL, 0, 10);
                        }
                }
                if (workqueue->worker_after_wake_up_fct)
                        workqueue->worker_after_wake_up_fct(workqueue, workqueue->priv);
        }
        if (!rt) {
                /*
                 * Read urcu_work list before write futex.
                 */
                cmm_smp_mb();
                uatomic_set(&workqueue->futex, 0);
        }
        if (workqueue->finalize_worker_fct)
                workqueue->finalize_worker_fct(workqueue, workqueue->priv);
        return NULL;
}

struct urcu_workqueue *urcu_workqueue_create(unsigned long flags,
                int cpu_affinity, void *priv,
                void (*grace_period_fct)(struct urcu_workqueue *workqueue, void *priv),
                void (*initialize_worker_fct)(struct urcu_workqueue *workqueue, void *priv),
                void (*finalize_worker_fct)(struct urcu_workqueue *workqueue, void *priv),
                void (*worker_before_wait_fct)(struct urcu_workqueue *workqueue, void *priv),
                void (*worker_after_wake_up_fct)(struct urcu_workqueue *workqueue, void *priv),
                void (*worker_before_pause_fct)(struct urcu_workqueue *workqueue, void *priv),
                void (*worker_after_resume_fct)(struct urcu_workqueue *workqueue, void *priv))
{
        struct urcu_workqueue *workqueue;
        int ret;

        workqueue = malloc(sizeof(*workqueue));
        if (workqueue == NULL)
                urcu_die(errno);
        memset(workqueue, '\0', sizeof(*workqueue));
        cds_wfcq_init(&workqueue->cbs_head, &workqueue->cbs_tail);
        workqueue->qlen = 0;
        workqueue->futex = 0;
        workqueue->flags = flags;
        workqueue->priv = priv;
        workqueue->grace_period_fct = grace_period_fct;
        workqueue->initialize_worker_fct = initialize_worker_fct;
        workqueue->finalize_worker_fct = finalize_worker_fct;
        workqueue->worker_before_wait_fct = worker_before_wait_fct;
        workqueue->worker_after_wake_up_fct = worker_after_wake_up_fct;
        workqueue->worker_before_pause_fct = worker_before_pause_fct;
        workqueue->worker_after_resume_fct = worker_after_resume_fct;
        workqueue->cpu_affinity = cpu_affinity;
        workqueue->loop_count = 0;
        cmm_smp_mb();  /* Structure initialized before pointer is planted. */
        ret = pthread_create(&workqueue->tid, NULL, workqueue_thread, workqueue);
        if (ret) {
                urcu_die(ret);
        }
        return workqueue;
}

static void wake_worker_thread(struct urcu_workqueue *workqueue)
{
        if (!(_CMM_LOAD_SHARED(workqueue->flags) & URCU_WORKQUEUE_RT))
                futex_wake_up(&workqueue->futex);
}

static int urcu_workqueue_destroy_worker(struct urcu_workqueue *workqueue)
{
        int ret;
        void *retval;

        uatomic_or(&workqueue->flags, URCU_WORKQUEUE_STOP);
        wake_worker_thread(workqueue);

        ret = pthread_join(workqueue->tid, &retval);
        if (ret) {
                urcu_die(ret);
        }
        if (retval != NULL) {
                urcu_die(EINVAL);
        }
        workqueue->flags &= ~URCU_WORKQUEUE_STOP;
        workqueue->tid = 0;
        return 0;
}

void urcu_workqueue_destroy(struct urcu_workqueue *workqueue)
{
        if (workqueue == NULL) {
                return;
        }
        if (urcu_workqueue_destroy_worker(workqueue)) {
                urcu_die(errno);
        }
        urcu_posix_assert(cds_wfcq_empty(&workqueue->cbs_head, &workqueue->cbs_tail));
        free(workqueue);
}

void urcu_workqueue_queue_work(struct urcu_workqueue *workqueue,
                      struct urcu_work *work,
                      void (*func)(struct urcu_work *work))
{
        cds_wfcq_node_init(&work->next);
        work->func = func;
        cds_wfcq_enqueue(&workqueue->cbs_head, &workqueue->cbs_tail, &work->next);
        uatomic_inc(&workqueue->qlen);
        wake_worker_thread(workqueue);
}

static
void free_completion(struct urcu_ref *ref)
{
        struct urcu_workqueue_completion *completion;

        completion = caa_container_of(ref, struct urcu_workqueue_completion, ref);
        free(completion);
}

static
void _urcu_workqueue_wait_complete(struct urcu_work *work)
{
        struct urcu_workqueue_completion_work *completion_work;
        struct urcu_workqueue_completion *completion;

        completion_work = caa_container_of(work, struct urcu_workqueue_completion_work, work);
        completion = completion_work->completion;
        if (!uatomic_sub_return(&completion->barrier_count, 1))
                futex_wake_up(&completion->futex);
        urcu_ref_put(&completion->ref, free_completion);
        free(completion_work);
}

struct urcu_workqueue_completion *urcu_workqueue_create_completion(void)
{
        struct urcu_workqueue_completion *completion;

        completion = calloc(sizeof(*completion), 1);
        if (!completion)
                urcu_die(errno);
        urcu_ref_set(&completion->ref, 1);
        completion->barrier_count = 0;
        return completion;
}

void urcu_workqueue_destroy_completion(struct urcu_workqueue_completion *completion)
{
        urcu_ref_put(&completion->ref, free_completion);
}

void urcu_workqueue_wait_completion(struct urcu_workqueue_completion *completion)
{
        /* Wait for them */
        for (;;) {
                uatomic_dec(&completion->futex);
                /* Decrement futex before reading barrier_count */
                cmm_smp_mb();
                if (!uatomic_read(&completion->barrier_count))
                        break;
                futex_wait(&completion->futex);
        }
}

void urcu_workqueue_queue_completion(struct urcu_workqueue *workqueue,
                struct urcu_workqueue_completion *completion)
{
        struct urcu_workqueue_completion_work *work;

        work = calloc(sizeof(*work), 1);
        if (!work)
                urcu_die(errno);
        work->completion = completion;
        urcu_ref_get(&completion->ref);
        uatomic_inc(&completion->barrier_count);
        urcu_workqueue_queue_work(workqueue, &work->work, _urcu_workqueue_wait_complete);
}

/*
 * Wait for all in-flight work to complete execution.
 */
void urcu_workqueue_flush_queued_work(struct urcu_workqueue *workqueue)
{
        struct urcu_workqueue_completion *completion;

        completion = urcu_workqueue_create_completion();
        if (!completion)
                urcu_die(ENOMEM);
        urcu_workqueue_queue_completion(workqueue, completion);
        urcu_workqueue_wait_completion(completion);
        urcu_workqueue_destroy_completion(completion);
}

/* To be used in before fork handler. */
void urcu_workqueue_pause_worker(struct urcu_workqueue *workqueue)
{
        uatomic_or(&workqueue->flags, URCU_WORKQUEUE_PAUSE);
        cmm_smp_mb__after_uatomic_or();
        wake_worker_thread(workqueue);

        while ((uatomic_read(&workqueue->flags) & URCU_WORKQUEUE_PAUSED) == 0)
                (void) poll(NULL, 0, 1);
}

/* To be used in after fork parent handler. */
void urcu_workqueue_resume_worker(struct urcu_workqueue *workqueue)
{
        uatomic_and(&workqueue->flags, ~URCU_WORKQUEUE_PAUSE);
        while ((uatomic_read(&workqueue->flags) & URCU_WORKQUEUE_PAUSED) != 0)
                (void) poll(NULL, 0, 1);
}

void urcu_workqueue_create_worker(struct urcu_workqueue *workqueue)
{
        int ret;

        /* Clear workqueue state from parent. */
        workqueue->flags &= ~URCU_WORKQUEUE_PAUSED;
        workqueue->flags &= ~URCU_WORKQUEUE_PAUSE;
        workqueue->tid = 0;
        ret = pthread_create(&workqueue->tid, NULL, workqueue_thread, workqueue);
        if (ret) {
                urcu_die(ret);
        }
}