/*
* Copyright (C) 2007-2009 Sourcefire, Inc.
*
* Authors: Trog, Török Edvin
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
* MA 02110-1301, USA.
*/
#if HAVE_CONFIG_H
#include "clamav-config.h"
#endif
#include <stdio.h>
#include <pthread.h>
#include <time.h>
#include <errno.h>
#include <string.h>
#include "shared/output.h"
#include "thrmgr.h"
#include "others.h"
#include "mpool.h"
#include "server.h"
#ifdef HAVE_MALLINFO
#include <malloc.h>
#endif
/* BSD and HP-UX need a bigger stacksize than the system default */
#if defined (C_BSD) || defined (C_HPUX) || defined(C_AIX)
#define C_BIGSTACK 1
#endif
static work_queue_t *work_queue_new(void)
{
work_queue_t *work_q;
work_q = (work_queue_t *) malloc(sizeof(work_queue_t));
if (!work_q) {
return NULL;
}
work_q->head = work_q->tail = NULL;
work_q->item_count = 0;
work_q->popped = 0;
return work_q;
}
static int work_queue_add(work_queue_t *work_q, void *data)
{
work_item_t *work_item;
if (!work_q) {
return FALSE;
}
work_item = (work_item_t *) malloc(sizeof(work_item_t));
if (!work_item) {
return FALSE;
}
work_item->next = NULL;
work_item->data = data;
gettimeofday(&(work_item->time_queued), NULL);
if (work_q->head == NULL) {
work_q->head = work_q->tail = work_item;
work_q->item_count = 1;
} else {
work_q->tail->next = work_item;
work_q->tail = work_item;
work_q->item_count++;
}
return TRUE;
}
static void *work_queue_pop(work_queue_t *work_q)
{
work_item_t *work_item;
void *data;
if (!work_q || !work_q->head) {
return NULL;
}
work_item = work_q->head;
data = work_item->data;
work_q->head = work_item->next;
if (work_q->head == NULL) {
work_q->tail = NULL;
}
free(work_item);
work_q->item_count--;
return data;
}
static struct threadpool_list {
threadpool_t *pool;
struct threadpool_list *nxt;
} *pools = NULL;
static pthread_mutex_t pools_lock = PTHREAD_MUTEX_INITIALIZER;
static void add_topools(threadpool_t *t)
{
struct threadpool_list *new = malloc(sizeof(*new));
if(!new) {
logg("!Unable to add threadpool to list\n");
return;
}
new->pool = t;
pthread_mutex_lock(&pools_lock);
new->nxt = pools;
pools = new;
pthread_mutex_unlock(&pools_lock);
}
static void remove_frompools(threadpool_t *t)
{
struct threadpool_list *l, *prev;
struct task_desc *desc;
pthread_mutex_lock(&pools_lock);
prev = NULL;
l = pools;
while(l && l->pool != t) {
prev = l;
l = l->nxt;
}
if(!l)
return;
if(prev)
prev->nxt = l->nxt;
if(l == pools)
pools = l->nxt;
free(l);
desc = t->tasks;
while(desc) {
struct task_desc *q = desc;
desc = desc->nxt;
free(q);
}
t->tasks = NULL;
pthread_mutex_unlock(&pools_lock);
}
static void print_queue(int f, work_queue_t *queue, struct timeval *tv_now)
{
long umin=~0UL, umax=0, usum=0;
unsigned invalids = 0, cnt = 0;
work_item_t *q;
if(!queue->head)
return;
for(q=queue->head;q;q=q->next) {
long delta;
delta = tv_now->tv_usec - q->time_queued.tv_usec;
delta += (tv_now->tv_sec - q->time_queued.tv_sec)*1000000;
if(delta < 0) {
invalids++;
continue;
}
if(delta > umax)
umax = delta;
if(delta < umin)
umin = delta;
usum += delta;
++cnt;
}
mdprintf(f," min_wait: %.6f max_wait: %.6f avg_wait: %.6f",
umin/1e6, umax/1e6, usum /(1e6*cnt));
if(invalids)
mdprintf(f," (INVALID timestamps: %u)", invalids);
if(cnt + invalids != (unsigned)queue->item_count)
mdprintf(f," (ERROR: %u != %u)", cnt + invalids,
(unsigned)queue->item_count);
}
int thrmgr_printstats(int f)
{
struct threadpool_list *l;
unsigned cnt, pool_cnt = 0;
size_t pool_used = 0, pool_total = 0, seen_cnt = 0, error_flag = 0;
float mem_heap = 0, mem_mmap = 0, mem_used = 0, mem_free = 0, mem_releasable = 0;
const struct cl_engine **seen = NULL;
int has_libc_memstats = 0;
pthread_mutex_lock(&pools_lock);
for(cnt=0,l=pools;l;l=l->nxt) cnt++;
mdprintf(f,"POOLS: %u\n\n", cnt);
for(l= pools;l && !error_flag;l = l->nxt) {
threadpool_t *pool = l->pool;
const char *state;
struct timeval tv_now;
struct task_desc *task;
cnt = 0;
if(!pool) {
mdprintf(f,"NULL\n\n");
continue;
}
/* now we can access desc->, knowing that they won't get freed
* because the other tasks can't quit while pool_mutex is taken
*/
switch(pool->state) {
case POOL_INVALID:
state = "INVALID";
break;
case POOL_VALID:
state = "VALID";
break;
case POOL_EXIT:
state = "EXIT";
break;
default:
state = "??";
break;
}
mdprintf(f, "STATE: %s %s\n", state, l->nxt ? "" : "PRIMARY");
mdprintf(f, "THREADS: live %u idle %u max %u idle-timeout %u\n"
,pool->thr_alive, pool->thr_idle, pool->thr_max,
pool->idle_timeout);
/* TODO: show both queues */
mdprintf(f,"QUEUE: %u items", pool->single_queue->item_count + pool->bulk_queue->item_count);
gettimeofday(&tv_now, NULL);
print_queue(f, pool->bulk_queue, &tv_now);
print_queue(f, pool->single_queue, &tv_now);
mdprintf(f, "\n");
for(task = pool->tasks; task; task = task->nxt) {
double delta;
size_t used, total;
delta = tv_now.tv_usec - task->tv.tv_usec;
delta += (tv_now.tv_sec - task->tv.tv_sec)*1000000.0;
mdprintf(f,"\t%s %f %s\n",
task->command ? task->command : "N/A",
delta/1e6,
task->filename ? task->filename:"");
if (task->engine) {
/* we usually have at most 2 engines so a linear
* search is good enough */
size_t i;
for (i=0;i<seen_cnt;i++) {
if (seen[i] == task->engine)
break;
}
/* we need to count the memusage from the same
* engine only once */
if (i == seen_cnt) {
const struct cl_engine **s;
/* new engine */
++seen_cnt;
s = realloc(seen, seen_cnt * sizeof(*seen));
if (!s) {
error_flag = 1;
break;
}
seen = s;
seen[seen_cnt - 1] = task->engine;
if (mpool_getstats(task->engine, &used, &total) != -1) {
pool_used += used;
pool_total += total;
pool_cnt++;
}
}
}
}
mdprintf(f,"\n");
}
free(seen);
#ifdef HAVE_MALLINFO
{
struct mallinfo inf = mallinfo();
mem_heap = inf.arena/(1024*1024.0);
mem_mmap = inf.hblkhd/(1024*1024.0);
mem_used = (inf.usmblks + inf.uordblks)/(1024*1024.0);
mem_free = (inf.fsmblks + inf.fordblks)/(1024*1024.0);
mem_releasable = inf.keepcost/(1024*1024.0);
has_libc_memstats=1;
}
#endif
if (error_flag) {
mdprintf(f, "ERROR: error encountered while formatting statistics\n");
} else {
if (has_libc_memstats)
mdprintf(f,"MEMSTATS: heap %.3fM mmap %.3fM used %.3fM free %.3fM releasable %.3fM pools %u pools_used %.3fM pools_total %.3fM\n",
mem_heap, mem_mmap, mem_used, mem_free, mem_releasable, pool_cnt,
pool_used/(1024*1024.0), pool_total/(1024*1024.0));
else
mdprintf(f,"MEMSTATS: heap N/A mmap N/A used N/A free N/A releasable N/A pools %u pools_used %.3fM pools_total %.3fM\n",
pool_cnt, pool_used/(1024*1024.0), pool_total/(1024*1024.0));
}
mdprintf(f,"END\n");
pthread_mutex_unlock(&pools_lock);
return 0;
}
void thrmgr_destroy(threadpool_t *threadpool)
{
if (!threadpool) {
return;
}
if (pthread_mutex_lock(&threadpool->pool_mutex) != 0) {
logg("!Mutex lock failed\n");
exit(-1);
}
if(threadpool->state != POOL_VALID) {
if (pthread_mutex_unlock(&threadpool->pool_mutex) != 0) {
logg("!Mutex unlock failed\n");
exit(-1);
}
return;
}
threadpool->state = POOL_EXIT;
/* wait for threads to exit */
if (threadpool->thr_alive > 0) {
if (pthread_cond_broadcast(&(threadpool->pool_cond)) != 0) {
pthread_mutex_unlock(&threadpool->pool_mutex);
return;
}
}
while (threadpool->thr_alive > 0) {
if (pthread_cond_wait (&threadpool->pool_cond, &threadpool->pool_mutex) != 0) {
pthread_mutex_unlock(&threadpool->pool_mutex);
return;
}
}
remove_frompools(threadpool);
if (pthread_mutex_unlock(&threadpool->pool_mutex) != 0) {
logg("!Mutex unlock failed\n");
exit(-1);
}
pthread_mutex_destroy(&(threadpool->pool_mutex));
pthread_cond_destroy(&(threadpool->idle_cond));
pthread_cond_destroy(&(threadpool->queueable_cond));
pthread_cond_destroy(&(threadpool->pool_cond));
pthread_attr_destroy(&(threadpool->pool_attr));
free(threadpool->single_queue);
free(threadpool->bulk_queue);
free(threadpool);
return;
}
threadpool_t *thrmgr_new(int max_threads, int idle_timeout, int max_queue, void (*handler)(void *))
{
threadpool_t *threadpool;
#if defined(C_BIGSTACK)
size_t stacksize;
#endif
if (max_threads <= 0) {
return NULL;
}
threadpool = (threadpool_t *) malloc(sizeof(threadpool_t));
if (!threadpool) {
return NULL;
}
threadpool->single_queue = work_queue_new();
if (!threadpool->single_queue) {
free(threadpool);
return NULL;
}
threadpool->bulk_queue = work_queue_new();
if (!threadpool->bulk_queue) {
free(threadpool->single_queue);
free(threadpool);
return NULL;
}
threadpool->queue_max = max_queue;
threadpool->thr_max = max_threads;
threadpool->thr_alive = 0;
threadpool->thr_idle = 0;
threadpool->idle_timeout = idle_timeout;
threadpool->handler = handler;
threadpool->tasks = NULL;
if(pthread_mutex_init(&(threadpool->pool_mutex), NULL)) {
free(threadpool->single_queue);
free(threadpool->bulk_queue);
free(threadpool);
return NULL;
}
if (pthread_cond_init(&(threadpool->pool_cond), NULL) != 0) {
pthread_mutex_destroy(&(threadpool->pool_mutex));
free(threadpool->single_queue);
free(threadpool->bulk_queue);
free(threadpool);
return NULL;
}
if (pthread_cond_init(&(threadpool->queueable_cond), NULL) != 0) {
pthread_cond_destroy(&(threadpool->pool_cond));
pthread_mutex_destroy(&(threadpool->pool_mutex));
free(threadpool->single_queue);
free(threadpool->bulk_queue);
free(threadpool);
return NULL;
}
if (pthread_cond_init(&(threadpool->idle_cond),NULL) != 0) {
pthread_cond_destroy(&(threadpool->queueable_cond));
pthread_cond_destroy(&(threadpool->pool_cond));
pthread_mutex_destroy(&(threadpool->pool_mutex));
free(threadpool->single_queue);
free(threadpool->bulk_queue);
free(threadpool);
return NULL;
}
if (pthread_attr_init(&(threadpool->pool_attr)) != 0) {
pthread_cond_destroy(&(threadpool->queueable_cond));
pthread_cond_destroy(&(threadpool->idle_cond));
pthread_cond_destroy(&(threadpool->pool_cond));
pthread_mutex_destroy(&(threadpool->pool_mutex));
free(threadpool->single_queue);
free(threadpool->bulk_queue);
free(threadpool);
return NULL;
}
if (pthread_attr_setdetachstate(&(threadpool->pool_attr), PTHREAD_CREATE_DETACHED) != 0) {
pthread_cond_destroy(&(threadpool->queueable_cond));
pthread_attr_destroy(&(threadpool->pool_attr));
pthread_cond_destroy(&(threadpool->idle_cond));
pthread_cond_destroy(&(threadpool->pool_cond));
pthread_mutex_destroy(&(threadpool->pool_mutex));
free(threadpool->single_queue);
free(threadpool->bulk_queue);
free(threadpool);
return NULL;
}
#if defined(C_BIGSTACK)
pthread_attr_getstacksize(&(threadpool->pool_attr), &stacksize);
stacksize = stacksize + 64 * 1024;
if (stacksize < 1048576) stacksize = 1048576; /* at least 1MB please */
logg("Set stacksize to %lu\n", (unsigned long int) stacksize);
pthread_attr_setstacksize(&(threadpool->pool_attr), stacksize);
#endif
threadpool->state = POOL_VALID;
add_topools(threadpool);
return threadpool;
}
static pthread_key_t stats_tls_key;
static pthread_once_t stats_tls_key_once = PTHREAD_ONCE_INIT;
static void stats_tls_key_alloc(void)
{
pthread_key_create(&stats_tls_key, NULL);
}
static const char *IDLE_TASK = "IDLE";
/* no mutex is needed, we are using thread local variable */
void thrmgr_setactivetask(const char *filename, const char* cmd)
{
struct task_desc *desc;
pthread_once(&stats_tls_key_once, stats_tls_key_alloc);
desc = pthread_getspecific(stats_tls_key);
if(!desc)
return;
desc->filename = filename;
if(cmd) {
if(cmd == IDLE_TASK && desc->command == cmd)
return;
desc->command = cmd;
gettimeofday(&desc->tv, NULL);
}
}
void thrmgr_setactiveengine(const struct cl_engine *engine)
{
struct task_desc *desc;
pthread_once(&stats_tls_key_once, stats_tls_key_alloc);
desc = pthread_getspecific(stats_tls_key);
if(!desc)
return;
desc->engine = engine;
}
/* thread pool mutex must be held on entry */
static void stats_init(threadpool_t *pool)
{
struct task_desc *desc = calloc(1, sizeof(*desc));
if(!desc)
return;
pthread_once(&stats_tls_key_once, stats_tls_key_alloc);
pthread_setspecific(stats_tls_key, desc);
if(!pool->tasks)
pool->tasks = desc;
else {
desc->nxt = pool->tasks;
pool->tasks->prv = desc;
pool->tasks = desc;
}
}
/* thread pool mutex must be held on entry */
static void stats_destroy(threadpool_t *pool)
{
struct task_desc *desc = pthread_getspecific(stats_tls_key);
if(!desc)
return;
pthread_mutex_lock(&pools_lock);
if(desc->prv)
desc->prv->nxt = desc->nxt;
if(desc->nxt)
desc->nxt->prv = desc->prv;
if(pool->tasks == desc)
pool->tasks = desc->nxt;
free(desc);
pthread_setspecific(stats_tls_key, NULL);
pthread_mutex_unlock(&pools_lock);
}
static inline int thrmgr_contended(threadpool_t *pool)
{
return pool->bulk_queue->item_count + pool->single_queue->item_count
+ pool->thr_alive - pool->thr_idle >= pool->queue_max;
}
/* when both queues have tasks, it will pick 4 items from the single queue,
* and 1 from the bulk */
#define SINGLE_BULK_RATIO 4
#define SINGLE_BULK_SUM (SINGLE_BULK_RATIO + 1)
/* must be called with pool_mutex held */
static void *thrmgr_pop(threadpool_t *pool)
{
void *task;
work_queue_t *first, *second;
int ratio;
if (pool->single_queue->popped < SINGLE_BULK_RATIO) {
first = pool->single_queue;
second = pool->bulk_queue;
ratio = SINGLE_BULK_RATIO;
} else {
second = pool->single_queue;
first = pool->bulk_queue;
ratio = SINGLE_BULK_SUM - SINGLE_BULK_RATIO;
}
task = work_queue_pop(first);
if (task) {
if (++first->popped == ratio)
second->popped = 0;
} else {
task = work_queue_pop(second);
if (task) {
if (++second->popped == ratio)
first->popped = 0;
}
}
if (!thrmgr_contended(pool)) {
logg("$THRMGR: queue crossed low threshold -> signaling\n");
pthread_cond_signal(&pool->queueable_cond);
}
return task;
}
static void *thrmgr_worker(void *arg)
{
threadpool_t *threadpool = (threadpool_t *) arg;
void *job_data;
int retval, must_exit = FALSE, stats_inited = FALSE;
struct timespec timeout;
/* loop looking for work */
for (;;) {
if (pthread_mutex_lock(&(threadpool->pool_mutex)) != 0) {
logg("!Fatal: mutex lock failed\n");
exit(-2);
}
if(!stats_inited) {
stats_init(threadpool);
stats_inited = TRUE;
}
thrmgr_setactiveengine(NULL);
thrmgr_setactivetask(NULL, IDLE_TASK);
timeout.tv_sec = time(NULL) + threadpool->idle_timeout;
timeout.tv_nsec = 0;
threadpool->thr_idle++;
while (((job_data=thrmgr_pop(threadpool)) == NULL)
&& (threadpool->state != POOL_EXIT)) {
/* Sleep, awaiting wakeup */
pthread_cond_signal(&threadpool->idle_cond);
retval = pthread_cond_timedwait(&(threadpool->pool_cond),
&(threadpool->pool_mutex), &timeout);
if (retval == ETIMEDOUT) {
must_exit = TRUE;
break;
}
}
threadpool->thr_idle--;
if (threadpool->state == POOL_EXIT) {
must_exit = TRUE;
}
if (pthread_mutex_unlock(&(threadpool->pool_mutex)) != 0) {
logg("!Fatal: mutex unlock failed\n");
exit(-2);
}
if (job_data) {
threadpool->handler(job_data);
} else if (must_exit) {
break;
}
}
if (pthread_mutex_lock(&(threadpool->pool_mutex)) != 0) {
/* Fatal error */
logg("!Fatal: mutex lock failed\n");
exit(-2);
}
threadpool->thr_alive--;
if (threadpool->thr_alive == 0) {
/* signal that all threads are finished */
pthread_cond_broadcast(&threadpool->pool_cond);
}
stats_destroy(threadpool);
if (pthread_mutex_unlock(&(threadpool->pool_mutex)) != 0) {
/* Fatal error */
logg("!Fatal: mutex unlock failed\n");
exit(-2);
}
return NULL;
}
static int thrmgr_dispatch_internal(threadpool_t *threadpool, void *user_data, int bulk)
{
int ret = TRUE;
pthread_t thr_id;
if (!threadpool) {
return FALSE;
}
/* Lock the threadpool */
if (pthread_mutex_lock(&(threadpool->pool_mutex)) != 0) {
logg("!Mutex lock failed\n");
return FALSE;
}
do {
work_queue_t *queue;
int items;
if (threadpool->state != POOL_VALID) {
ret = FALSE;
break;
}
if (bulk)
queue = threadpool->bulk_queue;
else
queue = threadpool->single_queue;
while (thrmgr_contended(threadpool)) {
logg("$THRMGR: contended, sleeping\n");
pthread_cond_wait(&threadpool->queueable_cond, &threadpool->pool_mutex);
logg("$THRMGR: contended, woken\n");
}
if (!work_queue_add(queue, user_data)) {
ret = FALSE;
break;
}
items = threadpool->single_queue->item_count + threadpool->bulk_queue->item_count;
if ((threadpool->thr_idle < items) &&
(threadpool->thr_alive < threadpool->thr_max)) {
/* Start a new thread */
if (pthread_create(&thr_id, &(threadpool->pool_attr),
thrmgr_worker, threadpool) != 0) {
logg("!pthread_create failed\n");
} else {
threadpool->thr_alive++;
}
}
pthread_cond_signal(&(threadpool->pool_cond));
} while (0);
if (pthread_mutex_unlock(&(threadpool->pool_mutex)) != 0) {
logg("!Mutex unlock failed\n");
return FALSE;
}
return ret;
}
int thrmgr_dispatch(threadpool_t *threadpool, void *user_data)
{
return thrmgr_dispatch_internal(threadpool, user_data, 0);
}
int thrmgr_group_dispatch(threadpool_t *threadpool, jobgroup_t *group, void *user_data)
{
int ret;
if (group) {
pthread_mutex_lock(&group->mutex);
group->jobs++;
logg("$THRMGR: active jobs for %p: %d\n", group, group->jobs);
pthread_mutex_unlock(&group->mutex);
}
if (!(ret = thrmgr_dispatch_internal(threadpool, user_data, 1)) && group) {
pthread_mutex_lock(&group->mutex);
group->jobs--;
logg("$THRMGR: active jobs for %p: %d\n", group, group->jobs);
pthread_mutex_unlock(&group->mutex);
}
return ret;
}
/* returns
* 0 - this was not the last thread in the group
* 1 - this was last thread in group, group freed
*/
int thrmgr_group_finished(jobgroup_t *group, enum thrmgr_exit exitc)
{
int ret = 0;
if (!group) {
/* there is no group, we are obviously the last one */
return 1;
}
pthread_mutex_lock(&group->mutex);
logg("$THRMGR: group_finished: %p, %d\n", group, group->jobs);
group->exit_total++;
switch (exitc) {
case EXIT_OK:
group->exit_ok++;
break;
case EXIT_ERROR:
group->exit_error++;
break;
}
if (group->jobs) {
if (!--group->jobs) {
ret = 1;
} else
logg("$THRMGR: active jobs for %p: %d\n", group, group->jobs);
if (group->jobs == 1)
pthread_cond_signal(&group->only);
}
pthread_mutex_unlock(&group->mutex);
if (ret) {
logg("$THRMGR: group_finished: freeing %p\n", group);
pthread_mutex_destroy(&group->mutex);
pthread_cond_destroy(&group->only);
free(group);
}
return ret;
}
void thrmgr_group_waitforall(jobgroup_t *group, unsigned *ok, unsigned *error, unsigned *total)
{
int needexit = 0, needfree = 0;
struct timespec timeout;
pthread_mutex_lock(&group->mutex);
while (group->jobs > 1) {
pthread_mutex_lock(&exit_mutex);
needexit = progexit;
pthread_mutex_unlock(&exit_mutex);
if (needexit)
break;
/* wake to check progexit */
timeout.tv_sec = time(NULL) + 5;
timeout.tv_nsec = 0;
pthread_cond_timedwait(&group->only, &group->mutex, &timeout);
}
*ok = group->exit_ok;
*error = group->exit_error + needexit;
*total = group->exit_total;
if(!--group->jobs)
needfree = 1;
else
logg("$THRMGR: active jobs for %p: %d\n", group, group->jobs);
pthread_mutex_unlock(&group->mutex);
if (needfree) {
logg("$THRMGR: group finished freeing %p\n", group);
free(group);
}
}
jobgroup_t *thrmgr_group_new(void)
{
jobgroup_t *group;
group = malloc(sizeof(*group));
if (!group)
return NULL;
group->jobs = 1;
group->exit_ok = group->exit_error = group->exit_total = group->force_exit = 0;
if (pthread_mutex_init(&group->mutex, NULL)) {
logg("^Failed to initialize group mutex");
free(group);
return NULL;
}
if (pthread_cond_init(&group->only, NULL)) {
logg("^Failed to initialize group cond");
pthread_mutex_destroy(&group->mutex);
free(group);
return NULL;
}
logg("$THRMGR: new group: %p\n", group);
return group;
}
int thrmgr_group_need_terminate(jobgroup_t *group)
{
int ret;
if (group) {
pthread_mutex_lock(&group->mutex);
ret = group->force_exit;
pthread_mutex_unlock(&group->mutex);
} else
ret = 0;
pthread_mutex_lock(&exit_mutex);
ret |= progexit;
pthread_mutex_unlock(&exit_mutex);
return ret;
}
void thrmgr_group_terminate(jobgroup_t *group)
{
if (group) {
/* we may not be the last active job, now
* the last active job will free resources */
pthread_mutex_lock(&group->mutex);
group->force_exit = 1;
pthread_mutex_unlock(&group->mutex);
}
}