static inline int
perf_producer(void *arg)
{
+ int i;
struct prod_data *p = arg;
struct test_perf *t = p->t;
struct evt_options *opt = t->opt;
const uint32_t nb_flows = t->nb_flows;
uint32_t flow_counter = 0;
uint64_t count = 0;
- struct perf_elt *m;
+ struct perf_elt *m[BURST_SIZE + 1] = {NULL};
struct rte_event ev;
if (opt->verbose_level > 1)
ev.sub_event_type = 0; /* stage 0 */
while (count < nb_pkts && t->done == false) {
- if (rte_mempool_get(pool, (void **)&m) < 0)
+ if (rte_mempool_get_bulk(pool, (void **)m, BURST_SIZE) < 0)
continue;
-
- ev.flow_id = flow_counter++ % nb_flows;
- ev.event_ptr = m;
- m->timestamp = rte_get_timer_cycles();
- while (rte_event_enqueue_burst(dev_id, port, &ev, 1) != 1) {
- if (t->done)
- break;
- rte_pause();
- m->timestamp = rte_get_timer_cycles();
+ for (i = 0; i < BURST_SIZE; i++) {
+ ev.flow_id = flow_counter++ % nb_flows;
+ ev.event_ptr = m[i];
+ m[i]->timestamp = rte_get_timer_cycles();
+ while (rte_event_enqueue_burst(dev_id,
+ port, &ev, 1) != 1) {
+ if (t->done)
+ break;
+ rte_pause();
+ m[i]->timestamp = rte_get_timer_cycles();
+ }
}
- count++;
+ count += BURST_SIZE;
}
return 0;
static inline int
perf_event_timer_producer(void *arg)
{
+ int i;
struct prod_data *p = arg;
struct test_perf *t = p->t;
struct evt_options *opt = t->opt;
const uint32_t nb_flows = t->nb_flows;
const uint64_t nb_timers = opt->nb_timers;
struct rte_mempool *pool = t->pool;
- struct perf_elt *m;
+ struct perf_elt *m[BURST_SIZE + 1] = {NULL};
struct rte_event_timer_adapter **adptr = t->timer_adptr;
struct rte_event_timer tim;
uint64_t timeout_ticks = opt->expiry_nsec / opt->timer_tick_nsec;
printf("%s(): lcore %d\n", __func__, rte_lcore_id());
while (count < nb_timers && t->done == false) {
- if (rte_mempool_get(pool, (void **)&m) < 0)
+ if (rte_mempool_get_bulk(pool, (void **)m, BURST_SIZE) < 0)
continue;
-
- m->tim = tim;
- m->tim.ev.flow_id = flow_counter++ % nb_flows;
- m->tim.ev.event_ptr = m;
- m->timestamp = rte_get_timer_cycles();
- while (rte_event_timer_arm_burst(
- adptr[flow_counter % nb_timer_adptrs],
- (struct rte_event_timer **)&m, 1) != 1) {
- if (t->done)
- break;
- rte_pause();
- m->timestamp = rte_get_timer_cycles();
+ for (i = 0; i < BURST_SIZE; i++) {
+ rte_prefetch0(m[i + 1]);
+ m[i]->tim = tim;
+ m[i]->tim.ev.flow_id = flow_counter++ % nb_flows;
+ m[i]->tim.ev.event_ptr = m[i];
+ m[i]->timestamp = rte_get_timer_cycles();
+ while (rte_event_timer_arm_burst(
+ adptr[flow_counter % nb_timer_adptrs],
+ (struct rte_event_timer **)&m[i], 1) != 1) {
+ if (t->done)
+ break;
+ m[i]->timestamp = rte_get_timer_cycles();
+ }
+ arm_latency += rte_get_timer_cycles() - m[i]->timestamp;
}
- arm_latency += rte_get_timer_cycles() - m->timestamp;
- count++;
+ count += BURST_SIZE;
}
fflush(stdout);
rte_delay_ms(1000);
printf("%s(): lcore %d Average event timer arm latency = %.3f us\n",
- __func__, rte_lcore_id(), (float)(arm_latency / count) /
- (rte_get_timer_hz() / 1000000));
+ __func__, rte_lcore_id(),
+ count ? (float)(arm_latency / count) /
+ (rte_get_timer_hz() / 1000000) : 0);
return 0;
}
fflush(stdout);
rte_delay_ms(1000);
printf("%s(): lcore %d Average event timer arm latency = %.3f us\n",
- __func__, rte_lcore_id(), (float)(arm_latency / count) /
- (rte_get_timer_hz() / 1000000));
+ __func__, rte_lcore_id(),
+ count ? (float)(arm_latency / count) /
+ (rte_get_timer_hz() / 1000000) : 0);
return 0;
}
int port_idx = 0;
/* launch workers */
- RTE_LCORE_FOREACH_SLAVE(lcore_id) {
+ RTE_LCORE_FOREACH_WORKER(lcore_id) {
if (!(opt->wlcores[lcore_id]))
continue;
}
/* launch producers */
- RTE_LCORE_FOREACH_SLAVE(lcore_id) {
+ RTE_LCORE_FOREACH_WORKER(lcore_id) {
if (!(opt->plcores[lcore_id]))
continue;
if (!(adapter_info.caps &
RTE_EVENT_TIMER_ADAPTER_CAP_INTERNAL_PORT)) {
- uint32_t service_id;
+ uint32_t service_id = -1U;
rte_event_timer_adapter_service_id_get(wl,
&service_id);
{
unsigned int lcores;
- /* N producer + N worker + 1 master when producer cores are used
- * Else N worker + 1 master when Rx adapter is used
+ /* N producer + N worker + main when producer cores are used
+ * Else N worker + main when Rx adapter is used
*/
lcores = opt->prod_type == EVT_PROD_TYPE_SYNT ? 3 : 2;
}
/* Validate worker lcores */
- if (evt_lcores_has_overlap(opt->wlcores, rte_get_master_lcore())) {
- evt_err("worker lcores overlaps with master lcore");
+ if (evt_lcores_has_overlap(opt->wlcores, rte_get_main_lcore())) {
+ evt_err("worker lcores overlaps with main lcore");
return -1;
}
if (evt_lcores_has_overlap_multi(opt->wlcores, opt->plcores)) {
return -1;
}
- if (opt->prod_type == EVT_PROD_TYPE_SYNT) {
+ if (opt->prod_type == EVT_PROD_TYPE_SYNT ||
+ opt->prod_type == EVT_PROD_TYPE_EVENT_TIMER_ADPTR) {
/* Validate producer lcores */
if (evt_lcores_has_overlap(opt->plcores,
- rte_get_master_lcore())) {
- evt_err("producer lcores overlaps with master lcore");
+ rte_get_main_lcore())) {
+ evt_err("producer lcores overlaps with main lcore");
return -1;
}
if (evt_has_disabled_lcore(opt->plcores)) {
perf_ethdev_setup(struct evt_test *test, struct evt_options *opt)
{
uint16_t i;
+ int ret;
struct test_perf *t = evt_test_priv(test);
struct rte_eth_conf port_conf = {
.rxmode = {
.mq_mode = ETH_MQ_RX_RSS,
- .max_rx_pkt_len = ETHER_MAX_LEN,
+ .max_rx_pkt_len = RTE_ETHER_MAX_LEN,
.split_hdr_size = 0,
},
.rx_adv_conf = {
struct rte_eth_dev_info dev_info;
struct rte_eth_conf local_port_conf = port_conf;
- rte_eth_dev_info_get(i, &dev_info);
+ ret = rte_eth_dev_info_get(i, &dev_info);
+ if (ret != 0) {
+ evt_err("Error during getting device (port %u) info: %s\n",
+ i, strerror(-ret));
+ return ret;
+ }
local_port_conf.rx_adv_conf.rss_conf.rss_hf &=
dev_info.flow_type_rss_offloads;
return -EINVAL;
}
- rte_eth_promiscuous_enable(i);
+ ret = rte_eth_promiscuous_enable(i);
+ if (ret != 0) {
+ evt_err("Failed to enable promiscuous mode for eth port [%d]: %s",
+ i, rte_strerror(-ret));
+ return ret;
+ }
}
return 0;