struct lat_test lt[2];
struct lat_test *lat_test;
uint32_t generator_count;
+ uint16_t min_pkt_len;
struct early_loss_detect *eld;
struct rx_pkt_meta_data *rx_pkt_meta;
- uint64_t link_speed;
// Following fields are only used when starting or stopping, not in general runtime
uint64_t *prev_tx_packet_index;
FILE *fp_rx;
FILE *fp_tx;
struct prox_port_cfg *port;
+ uint64_t *bytes_to_tsc;
};
/* This function calculate the difference between rx and tx_time
* Both values are uint32_t (see handle_lat_bulk)
* rx time should be higher than tx_time...except every UINT32_MAX
- * cycles, when rx_time overflows.
- * As the return value is also uint32_t, returning (rx_time - tx_time)
+ * cycles, when rx_time overflows.
+ * As the return value is also uint32_t, returning (rx_time - tx_time)
* is also fine when it overflows.
*/
static uint32_t diff_time(uint32_t rx_time, uint32_t tx_time)
lat_info->tx_err = tx_err;
}
-static uint32_t task_lat_early_loss_detect(struct task_lat *task, struct unique_id *unique_id)
+static uint32_t task_lat_early_loss_detect(struct task_lat *task, uint32_t packet_id, uint8_t generator_id)
{
- struct early_loss_detect *eld;
- uint8_t generator_id;
- uint32_t packet_index;
-
- unique_id_get(unique_id, &generator_id, &packet_index);
-
- if (generator_id >= task->generator_count)
- return 0;
-
- eld = &task->eld[generator_id];
-
- return early_loss_detect_add(eld, packet_index);
+ struct early_loss_detect *eld = &task->eld[generator_id];
+ return early_loss_detect_add(eld, packet_id);
}
-static uint64_t tsc_extrapolate_backward(uint64_t link_speed, uint64_t tsc_from, uint64_t bytes, uint64_t tsc_minimum)
+static uint64_t tsc_extrapolate_backward(struct task_lat *task, uint64_t tsc_from, uint64_t bytes, uint64_t tsc_minimum)
{
- uint64_t tsc = tsc_from - (rte_get_tsc_hz()*bytes)/link_speed;
+#ifdef NO_EXTRAPOLATION
+ uint64_t tsc = tsc_from;
+#else
+ uint64_t tsc = tsc_from - task->bytes_to_tsc[bytes];
+#endif
if (likely(tsc > tsc_minimum))
return tsc;
else
static void task_lat_store_lat(struct task_lat *task, uint64_t rx_packet_index, uint64_t rx_time, uint64_t tx_time, uint64_t rx_error, uint64_t tx_error, uint32_t packet_id, uint8_t generator_id)
{
- if (tx_time == 0)
- return;
uint32_t lat_tsc = diff_time(rx_time, tx_time) << LATENCY_ACCURACY;
lat_test_add_latency(task->lat_test, lat_tsc, rx_error + tx_error);
static int handle_lat_bulk(struct task_base *tbase, struct rte_mbuf **mbufs, uint16_t n_pkts)
{
struct task_lat *task = (struct task_lat *)tbase;
- uint64_t rx_time_err;
-
- uint32_t pkt_rx_time, pkt_tx_time;
+ int rc;
if (n_pkts == 0) {
task->begin = tbase->aux->tsc_rx.before;
task_lat_update_lat_test(task);
- const uint64_t rx_tsc = tbase->aux->tsc_rx.after;
- uint32_t tx_time_err = 0;
+ // Remember those packets with bad length or bad signature
+ uint32_t non_dp_count = 0;
+ uint64_t pkt_bad_len_sig = 0;
+#define BIT64_SET(a64, bit) a64 |= (((uint64_t)1) << (bit & 63))
+#define BIT64_CLR(a64, bit) a64 &= ~(((uint64_t)1) << (bit & 63))
+#define BIT64_TEST(a64, bit) a64 & (((uint64_t)1) << (bit & 63))
/* Go once through all received packets and read them. If
packet has just been modified by another core, the cost of
for (uint16_t j = 0; j < n_pkts; ++j) {
struct rte_mbuf *mbuf = mbufs[j];
task->rx_pkt_meta[j].hdr = rte_pktmbuf_mtod(mbuf, uint8_t *);
+
+ // Remember those packets which are too short to hold the values that we expect
+ if (unlikely(rte_pktmbuf_pkt_len(mbuf) < task->min_pkt_len)) {
+ BIT64_SET(pkt_bad_len_sig, j);
+ non_dp_count++;
+ } else
+ BIT64_CLR(pkt_bad_len_sig, j);
}
- if (task->sig) {
+ if (task->sig_pos) {
for (uint16_t j = 0; j < n_pkts; ++j) {
- if (*(uint32_t *)(task->rx_pkt_meta[j].hdr + task->sig_pos) == task->sig)
+ if (unlikely(BIT64_TEST(pkt_bad_len_sig, j)))
+ continue;
+ // Remember those packets with bad signature
+ if (likely(*(uint32_t *)(task->rx_pkt_meta[j].hdr + task->sig_pos) == task->sig))
task->rx_pkt_meta[j].pkt_tx_time = *(uint32_t *)(task->rx_pkt_meta[j].hdr + task->lat_pos);
- else
- task->rx_pkt_meta[j].pkt_tx_time = 0;
+ else {
+ BIT64_SET(pkt_bad_len_sig, j);
+ non_dp_count++;
+ }
}
} else {
for (uint16_t j = 0; j < n_pkts; ++j) {
+ if (unlikely(BIT64_TEST(pkt_bad_len_sig, j)))
+ continue;
task->rx_pkt_meta[j].pkt_tx_time = *(uint32_t *)(task->rx_pkt_meta[j].hdr + task->lat_pos);
}
}
bytes_total_in_bulk += mbuf_wire_size(mbufs[flipped]);
}
- pkt_rx_time = tsc_extrapolate_backward(task->link_speed, rx_tsc, task->rx_pkt_meta[0].bytes_after_in_bulk, task->last_pkts_tsc) >> LATENCY_ACCURACY;
- if ((uint32_t)((task->begin >> LATENCY_ACCURACY)) > pkt_rx_time) {
+ const uint64_t rx_tsc = tbase->aux->tsc_rx.after;
+
+ uint64_t rx_time_err;
+ uint64_t pkt_rx_time64 = tsc_extrapolate_backward(task, rx_tsc, task->rx_pkt_meta[0].bytes_after_in_bulk, task->last_pkts_tsc) >> LATENCY_ACCURACY;
+ if (unlikely((task->begin >> LATENCY_ACCURACY) > pkt_rx_time64)) {
// Extrapolation went up to BEFORE begin => packets were stuck in the NIC but we were not seeing them
- rx_time_err = pkt_rx_time - (uint32_t)(task->last_pkts_tsc >> LATENCY_ACCURACY);
+ rx_time_err = pkt_rx_time64 - (task->last_pkts_tsc >> LATENCY_ACCURACY);
} else {
- rx_time_err = pkt_rx_time - (uint32_t)(task->begin >> LATENCY_ACCURACY);
+ rx_time_err = pkt_rx_time64 - (task->begin >> LATENCY_ACCURACY);
}
- struct unique_id *unique_id = NULL;
- struct delayed_latency_entry *delayed_latency_entry;
- uint32_t packet_id, generator_id;
-
+ TASK_STATS_ADD_RX_NON_DP(&tbase->aux->stats, non_dp_count);
for (uint16_t j = 0; j < n_pkts; ++j) {
+ // Used to display % of packets within accuracy limit vs. total number of packets (used_col)
+ task->lat_test->tot_all_pkts++;
+
+ // Skip those packets with bad length or bad signature
+ if (unlikely(BIT64_TEST(pkt_bad_len_sig, j)))
+ continue;
+
struct rx_pkt_meta_data *rx_pkt_meta = &task->rx_pkt_meta[j];
uint8_t *hdr = rx_pkt_meta->hdr;
- pkt_rx_time = tsc_extrapolate_backward(task->link_speed, rx_tsc, rx_pkt_meta->bytes_after_in_bulk, task->last_pkts_tsc) >> LATENCY_ACCURACY;
- pkt_tx_time = rx_pkt_meta->pkt_tx_time;
+ uint32_t pkt_rx_time = tsc_extrapolate_backward(task, rx_tsc, rx_pkt_meta->bytes_after_in_bulk, task->last_pkts_tsc) >> LATENCY_ACCURACY;
+ uint32_t pkt_tx_time = rx_pkt_meta->pkt_tx_time;
+ uint8_t generator_id;
+ uint32_t packet_id;
if (task->unique_id_pos) {
- unique_id = (struct unique_id *)(hdr + task->unique_id_pos);
+ struct unique_id *unique_id = (struct unique_id *)(hdr + task->unique_id_pos);
+ unique_id_get(unique_id, &generator_id, &packet_id);
+
+ if (unlikely(generator_id >= task->generator_count)) {
+ /* No need to remember unexpected packet at this stage
+ BIT64_SET(pkt_bad_len_sig, j);
+ */
+ // Skip unexpected packet
+ continue;
+ }
- uint32_t n_loss = task_lat_early_loss_detect(task, unique_id);
- packet_id = unique_id->packet_id;
- generator_id = unique_id->generator_id;
- lat_test_add_lost(task->lat_test, n_loss);
+ lat_test_add_lost(task->lat_test, task_lat_early_loss_detect(task, packet_id, generator_id));
} else {
- packet_id = task->rx_packet_index;
generator_id = 0;
+ packet_id = task->rx_packet_index;
}
- task->lat_test->tot_all_pkts++;
/* If accuracy is enabled, latency is reported with a
delay of ACCURACY_BUFFER_SIZE packets since the generator puts the
ensures that all reported latencies have both rx
and tx error. */
if (task->accur_pos) {
- tx_time_err = *(uint32_t *)(hdr + task->accur_pos);
+ uint32_t tx_time_err = *(uint32_t *)(hdr + task->accur_pos);
- delayed_latency_entry = delayed_latency_get(task->delayed_latency_entries, generator_id, packet_id - ACCURACY_BUFFER_SIZE);
+ struct delayed_latency_entry *delayed_latency_entry = delayed_latency_get(task->delayed_latency_entries, generator_id, packet_id - ACCURACY_BUFFER_SIZE);
if (delayed_latency_entry) {
task_lat_store_lat(task,
} else {
task_lat_store_lat(task, task->rx_packet_index, pkt_rx_time, pkt_tx_time, 0, 0, packet_id, generator_id);
}
+
+ // Bad/unexpected packets do not need to be indexed
task->rx_packet_index++;
}
- int ret;
- ret = task->base.tx_pkt(&task->base, mbufs, n_pkts, NULL);
- task->begin = tbase->aux->tsc_rx.before;
+
+ if (n_pkts < MAX_PKT_BURST)
+ task->begin = tbase->aux->tsc_rx.before;
task->last_pkts_tsc = tbase->aux->tsc_rx.after;
- return ret;
+
+ rc = task->base.tx_pkt(&task->base, mbufs, n_pkts, NULL);
+ // non_dp_count should not be drop-handled, as there are all by definition considered as not handled
+ // RX = DISCARDED + HANDLED + NON_DP + (TX - TX_NON_DP) + TX_FAIL
+ TASK_STATS_ADD_DROP_HANDLED(&tbase->aux->stats, -non_dp_count);
+ return rc;
}
static void init_task_lat_latency_buffer(struct task_lat *task, uint32_t core_id)
{
struct task_lat *task = (struct task_lat *)tbase;
- if (task->port && task->port->link_speed) {
- // task->port->link->speed reports the link speed in Mbps e.g. 40k for a 40 Gbps NIC
- // task->link_speed reported link speed in Bytes per sec.
- task->link_speed = task->port->link_speed * 125000L;
- plog_info("\tReceiving at %lu Mbps\n", 8 * task->link_speed / 1000000);
- }
}
static void init_task_lat(struct task_base *tbase, struct task_args *targ)
task->unique_id_pos = targ->packet_id_pos;
task->latency_buffer_size = targ->latency_buffer_size;
+ PROX_PANIC(task->lat_pos == 0, "Missing 'lat pos' parameter in config file\n");
+ uint16_t min_pkt_len = task->lat_pos + sizeof(uint32_t);
+ if (task->unique_id_pos && (
+ min_pkt_len < task->unique_id_pos + sizeof(struct unique_id)))
+ min_pkt_len = task->unique_id_pos + sizeof(struct unique_id);
+ if (task->accur_pos && (
+ min_pkt_len < task->accur_pos + sizeof(uint32_t)))
+ min_pkt_len = task->accur_pos + sizeof(uint32_t);
+ if (task->sig_pos && (
+ min_pkt_len < task->sig_pos + sizeof(uint32_t)))
+ min_pkt_len = task->sig_pos + sizeof(uint32_t);
+ task->min_pkt_len = min_pkt_len;
+
task_init_generator_count(task);
if (task->latency_buffer_size) {
task->lat_test = &task->lt[task->using_lt];
task_lat_set_accuracy_limit(task, targ->accuracy_limit_nsec);
- task->rx_pkt_meta = prox_zmalloc(MAX_RX_PKT_ALL * sizeof(*task->rx_pkt_meta), socket_id);
+ task->rx_pkt_meta = prox_zmalloc(MAX_PKT_BURST * sizeof(*task->rx_pkt_meta), socket_id);
PROX_PANIC(task->rx_pkt_meta == NULL, "unable to allocate memory to store RX packet meta data");
- task->link_speed = UINT64_MAX;
+ uint32_t max_frame_size = MAX_PKT_SIZE;
+ uint64_t bytes_per_hz = UINT64_MAX;
if (targ->nb_rxports) {
- // task->port structure is only used while starting handle_lat to get the link_speed.
- // link_speed can not be quiried at init as the port has not been initialized yet.
struct prox_port_cfg *port = &prox_port_cfg[targ->rx_port_queue[0].port];
- task->port = port;
+ max_frame_size = port->mtu + ETHER_HDR_LEN + ETHER_CRC_LEN + 2 * PROX_VLAN_TAG_SIZE;
+
+ // port->max_link_speed reports the maximum, non negotiated ink speed in Mbps e.g. 40k for a 40 Gbps NIC.
+ // It can be UINT32_MAX (virtual devices or not supported by DPDK < 16.04)
+ if (port->max_link_speed != UINT32_MAX) {
+ bytes_per_hz = port->max_link_speed * 125000L;
+ plog_info("\tPort %u: max link speed is %ld Mbps\n",
+ (uint8_t)(port - prox_port_cfg), 8 * bytes_per_hz / 1000000);
+ }
+ }
+ task->bytes_to_tsc = prox_zmalloc(max_frame_size * sizeof(task->bytes_to_tsc[0]) * MAX_PKT_BURST, rte_lcore_to_socket_id(targ->lconf->id));
+ PROX_PANIC(task->bytes_to_tsc == NULL,
+ "Failed to allocate %u bytes (in huge pages) for bytes_to_tsc\n", max_frame_size);
+
+ for (unsigned int i = 0; i < max_frame_size * MAX_PKT_BURST ; i++) {
+ if (bytes_per_hz == UINT64_MAX)
+ task->bytes_to_tsc[i] = 0;
+ else
+ task->bytes_to_tsc[i] = (rte_get_tsc_hz() * i) / bytes_per_hz;
}
}
.handle = handle_lat_bulk,
.start = lat_start,
.stop = lat_stop,
- .flag_features = TASK_FEATURE_TSC_RX | TASK_FEATURE_RX_ALL | TASK_FEATURE_ZERO_RX | TASK_FEATURE_NEVER_DISCARDS,
+ .flag_features = TASK_FEATURE_TSC_RX | TASK_FEATURE_ZERO_RX | TASK_FEATURE_NEVER_DISCARDS,
.size = sizeof(struct task_lat)
};