static void chaos_run(unsigned int qtype)
{
odp_pool_t pool;
odp_pool_param_t params;
odp_queue_param_t qp;
odp_buffer_t buf;
chaos_buf *cbuf;
test_globals_t *globals;
thread_args_t *args;
odp_shm_t shm;
int i, rc;
odp_schedule_sync_t sync[] = {ODP_SCHED_SYNC_PARALLEL,
ODP_SCHED_SYNC_ATOMIC,
ODP_SCHED_SYNC_ORDERED};
const unsigned num_sync = (sizeof(sync) / sizeof(odp_schedule_sync_t));
const char *const qtypes[] = {"parallel", "atomic", "ordered"};
/* Set up the scheduling environment */
shm = odp_shm_lookup(GLOBALS_SHM_NAME);
CU_ASSERT_FATAL(shm != ODP_SHM_INVALID);
globals = odp_shm_addr(shm);
CU_ASSERT_PTR_NOT_NULL_FATAL(globals);
shm = odp_shm_lookup(SHM_THR_ARGS_NAME);
CU_ASSERT_FATAL(shm != ODP_SHM_INVALID);
args = odp_shm_addr(shm);
CU_ASSERT_PTR_NOT_NULL_FATAL(args);
args->globals = globals;
args->cu_thr.numthrds = globals->num_workers;
odp_queue_param_init(&qp);
odp_pool_param_init(¶ms);
params.buf.size = sizeof(chaos_buf);
params.buf.align = 0;
params.buf.num = CHAOS_NUM_EVENTS;
params.type = ODP_POOL_BUFFER;
pool = odp_pool_create("sched_chaos_pool", ¶ms);
CU_ASSERT_FATAL(pool != ODP_POOL_INVALID);
qp.type = ODP_QUEUE_TYPE_SCHED;
qp.sched.prio = ODP_SCHED_PRIO_DEFAULT;
qp.sched.group = ODP_SCHED_GROUP_ALL;
for (i = 0; i < CHAOS_NUM_QUEUES; i++) {
uint32_t ndx = (qtype == num_sync ? i % num_sync : qtype);
qp.sched.sync = sync[ndx];
snprintf(globals->chaos_q[i].name,
sizeof(globals->chaos_q[i].name),
"chaos queue %d - %s", i,
qtypes[ndx]);
globals->chaos_q[i].handle =
odp_queue_create(globals->chaos_q[i].name, &qp);
CU_ASSERT_FATAL(globals->chaos_q[i].handle !=
ODP_QUEUE_INVALID);
rc = odp_queue_context_set(globals->chaos_q[i].handle,
CHAOS_NDX_TO_PTR(i), 0);
CU_ASSERT_FATAL(rc == 0);
}
/* Now populate the queues with the initial seed elements */
for (i = 0; i < CHAOS_NUM_EVENTS; i++) {
buf = odp_buffer_alloc(pool);
CU_ASSERT_FATAL(buf != ODP_BUFFER_INVALID);
cbuf = odp_buffer_addr(buf);
cbuf->evno = i;
cbuf->seqno = 0;
rc = odp_queue_enq(
globals->chaos_q[i % CHAOS_NUM_QUEUES].handle,
odp_buffer_to_event(buf));
CU_ASSERT_FATAL(rc == 0);
}
/* Run the test */
odp_cunit_thread_create(chaos_thread, &args->cu_thr);
odp_cunit_thread_exit(&args->cu_thr);
if (CHAOS_DEBUG)
printf("Thread %d returning from chaos threads..cleaning up\n",
odp_thread_id());
drain_queues();
exit_schedule_loop();
for (i = 0; i < CHAOS_NUM_QUEUES; i++) {
if (CHAOS_DEBUG)
printf("Destroying queue %s\n",
globals->chaos_q[i].name);
rc = odp_queue_destroy(globals->chaos_q[i].handle);
CU_ASSERT(rc == 0);
}
rc = odp_pool_destroy(pool);
CU_ASSERT(rc == 0);
}
void scheduler_test_chaos(void)
{
odp_pool_t pool;
odp_pool_param_t params;
odp_queue_param_t qp;
odp_buffer_t buf;
chaos_buf *cbuf;
odp_event_t ev;
test_globals_t *globals;
thread_args_t *args;
odp_shm_t shm;
odp_queue_t from;
int i, rc;
uint64_t wait;
odp_schedule_sync_t sync[] = {ODP_SCHED_SYNC_NONE,
ODP_SCHED_SYNC_ATOMIC/* , */
/* ODP_SCHED_SYNC_ORDERED */};
const int num_sync = (sizeof(sync) / sizeof(sync[0]));
const char *const qtypes[] = {"parallel", "atomic", "ordered"};
/* Set up the scheduling environment */
shm = odp_shm_lookup(GLOBALS_SHM_NAME);
CU_ASSERT_FATAL(shm != ODP_SHM_INVALID);
globals = odp_shm_addr(shm);
CU_ASSERT_PTR_NOT_NULL_FATAL(shm);
shm = odp_shm_lookup(SHM_THR_ARGS_NAME);
CU_ASSERT_FATAL(shm != ODP_SHM_INVALID);
args = odp_shm_addr(shm);
CU_ASSERT_PTR_NOT_NULL_FATAL(args);
args->globals = globals;
args->cu_thr.numthrds = globals->num_workers;
odp_queue_param_init(&qp);
odp_pool_param_init(¶ms);
params.buf.size = sizeof(chaos_buf);
params.buf.align = 0;
params.buf.num = CHAOS_NUM_EVENTS;
params.type = ODP_POOL_BUFFER;
pool = odp_pool_create("sched_chaos_pool", ¶ms);
CU_ASSERT_FATAL(pool != ODP_POOL_INVALID);
qp.sched.prio = ODP_SCHED_PRIO_DEFAULT;
for (i = 0; i < CHAOS_NUM_QUEUES; i++) {
qp.sched.sync = sync[i % num_sync];
snprintf(globals->chaos_q[i].name,
sizeof(globals->chaos_q[i].name),
"chaos queue %d - %s", i,
qtypes[i % num_sync]);
globals->chaos_q[i].handle =
odp_queue_create(globals->chaos_q[i].name,
ODP_QUEUE_TYPE_SCHED,
&qp);
CU_ASSERT_FATAL(globals->chaos_q[i].handle !=
ODP_QUEUE_INVALID);
rc = odp_queue_context_set(globals->chaos_q[i].handle,
CHAOS_NDX_TO_PTR(i));
CU_ASSERT_FATAL(rc == 0);
}
/* Now populate the queues with the initial seed elements */
odp_atomic_init_u32(&globals->chaos_pending_event_count, 0);
for (i = 0; i < CHAOS_NUM_EVENTS; i++) {
buf = odp_buffer_alloc(pool);
CU_ASSERT_FATAL(buf != ODP_BUFFER_INVALID);
cbuf = odp_buffer_addr(buf);
cbuf->evno = i;
cbuf->seqno = 0;
rc = odp_queue_enq(
globals->chaos_q[i % CHAOS_NUM_QUEUES].handle,
odp_buffer_to_event(buf));
CU_ASSERT_FATAL(rc == 0);
odp_atomic_inc_u32(&globals->chaos_pending_event_count);
}
/* Run the test */
odp_cunit_thread_create(chaos_thread, &args->cu_thr);
odp_cunit_thread_exit(&args->cu_thr);
if (CHAOS_DEBUG)
printf("Thread %d returning from chaos threads..cleaning up\n",
odp_thread_id());
/* Cleanup: Drain queues, free events */
wait = odp_schedule_wait_time(CHAOS_WAIT_FAIL);
while (odp_atomic_fetch_dec_u32(
&globals->chaos_pending_event_count) > 0) {
ev = odp_schedule(&from, wait);
CU_ASSERT_FATAL(ev != ODP_EVENT_INVALID);
cbuf = odp_buffer_addr(odp_buffer_from_event(ev));
if (CHAOS_DEBUG)
printf("Draining event %" PRIu64
" seq %" PRIu64 " from Q %s...\n",
cbuf->evno,
cbuf->seqno,
globals->
chaos_q
[CHAOS_PTR_TO_NDX(odp_queue_context(from))].
name);
odp_event_free(ev);
}
odp_schedule_release_ordered();
for (i = 0; i < CHAOS_NUM_QUEUES; i++) {
if (CHAOS_DEBUG)
printf("Destroying queue %s\n",
globals->chaos_q[i].name);
rc = odp_queue_destroy(globals->chaos_q[i].handle);
CU_ASSERT(rc == 0);
}
rc = odp_pool_destroy(pool);
CU_ASSERT(rc == 0);
}
