numam-dpdk/app/test-pmd/config.c

3694 lines
96 KiB
C
Raw Normal View History

/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2010-2016 Intel Corporation.
* Copyright 2013-2014 6WIND S.A.
*/
#include <stdarg.h>
#include <errno.h>
#include <stdio.h>
#include <string.h>
#include <stdint.h>
#include <inttypes.h>
#include <sys/queue.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <rte_common.h>
#include <rte_byteorder.h>
#include <rte_debug.h>
#include <rte_log.h>
#include <rte_memory.h>
#include <rte_memcpy.h>
#include <rte_memzone.h>
#include <rte_launch.h>
#include <rte_eal.h>
#include <rte_per_lcore.h>
#include <rte_lcore.h>
#include <rte_atomic.h>
#include <rte_branch_prediction.h>
#include <rte_mempool.h>
#include <rte_mbuf.h>
#include <rte_interrupts.h>
#include <rte_pci.h>
#include <rte_ether.h>
#include <rte_ethdev.h>
#include <rte_string_fns.h>
#include <rte_cycles.h>
#include <rte_flow.h>
#include <rte_errno.h>
#ifdef RTE_LIBRTE_IXGBE_PMD
#include <rte_pmd_ixgbe.h>
#endif
#ifdef RTE_LIBRTE_I40E_PMD
#include <rte_pmd_i40e.h>
#endif
#ifdef RTE_LIBRTE_BNXT_PMD
#include <rte_pmd_bnxt.h>
#endif
#include <rte_gro.h>
#include <cmdline_parse_etheraddr.h>
#include "testpmd.h"
static char *flowtype_to_str(uint16_t flow_type);
static const struct {
enum tx_pkt_split split;
const char *name;
} tx_split_name[] = {
{
.split = TX_PKT_SPLIT_OFF,
.name = "off",
},
{
.split = TX_PKT_SPLIT_ON,
.name = "on",
},
{
.split = TX_PKT_SPLIT_RND,
.name = "rand",
},
};
const struct rss_type_info rss_type_table[] = {
{ "ipv4", ETH_RSS_IPV4 },
{ "ipv4-frag", ETH_RSS_FRAG_IPV4 },
{ "ipv4-tcp", ETH_RSS_NONFRAG_IPV4_TCP },
{ "ipv4-udp", ETH_RSS_NONFRAG_IPV4_UDP },
{ "ipv4-sctp", ETH_RSS_NONFRAG_IPV4_SCTP },
{ "ipv4-other", ETH_RSS_NONFRAG_IPV4_OTHER },
{ "ipv6", ETH_RSS_IPV6 },
{ "ipv6-frag", ETH_RSS_FRAG_IPV6 },
{ "ipv6-tcp", ETH_RSS_NONFRAG_IPV6_TCP },
{ "ipv6-udp", ETH_RSS_NONFRAG_IPV6_UDP },
{ "ipv6-sctp", ETH_RSS_NONFRAG_IPV6_SCTP },
{ "ipv6-other", ETH_RSS_NONFRAG_IPV6_OTHER },
{ "l2-payload", ETH_RSS_L2_PAYLOAD },
{ "ipv6-ex", ETH_RSS_IPV6_EX },
{ "ipv6-tcp-ex", ETH_RSS_IPV6_TCP_EX },
{ "ipv6-udp-ex", ETH_RSS_IPV6_UDP_EX },
{ "port", ETH_RSS_PORT },
{ "vxlan", ETH_RSS_VXLAN },
{ "geneve", ETH_RSS_GENEVE },
{ "nvgre", ETH_RSS_NVGRE },
{ "ip", ETH_RSS_IP },
{ "udp", ETH_RSS_UDP },
{ "tcp", ETH_RSS_TCP },
{ "sctp", ETH_RSS_SCTP },
{ "tunnel", ETH_RSS_TUNNEL },
{ NULL, 0 },
};
static void
print_ethaddr(const char *name, struct ether_addr *eth_addr)
{
char buf[ETHER_ADDR_FMT_SIZE];
ether_format_addr(buf, ETHER_ADDR_FMT_SIZE, eth_addr);
printf("%s%s", name, buf);
}
void
nic_stats_display(portid_t port_id)
{
static uint64_t prev_pkts_rx[RTE_MAX_ETHPORTS];
static uint64_t prev_pkts_tx[RTE_MAX_ETHPORTS];
static uint64_t prev_cycles[RTE_MAX_ETHPORTS];
uint64_t diff_pkts_rx, diff_pkts_tx, diff_cycles;
uint64_t mpps_rx, mpps_tx;
struct rte_eth_stats stats;
struct rte_port *port = &ports[port_id];
uint8_t i;
portid_t pid;
static const char *nic_stats_border = "########################";
if (port_id_is_invalid(port_id, ENABLED_WARN)) {
printf("Valid port range is [0");
RTE_ETH_FOREACH_DEV(pid)
printf(", %d", pid);
printf("]\n");
return;
}
rte_eth_stats_get(port_id, &stats);
printf("\n %s NIC statistics for port %-2d %s\n",
nic_stats_border, port_id, nic_stats_border);
if ((!port->rx_queue_stats_mapping_enabled) && (!port->tx_queue_stats_mapping_enabled)) {
printf(" RX-packets: %-10"PRIu64" RX-missed: %-10"PRIu64" RX-bytes: "
"%-"PRIu64"\n",
stats.ipackets, stats.imissed, stats.ibytes);
printf(" RX-errors: %-"PRIu64"\n", stats.ierrors);
printf(" RX-nombuf: %-10"PRIu64"\n",
stats.rx_nombuf);
printf(" TX-packets: %-10"PRIu64" TX-errors: %-10"PRIu64" TX-bytes: "
"%-"PRIu64"\n",
stats.opackets, stats.oerrors, stats.obytes);
}
else {
printf(" RX-packets: %10"PRIu64" RX-errors: %10"PRIu64
" RX-bytes: %10"PRIu64"\n",
stats.ipackets, stats.ierrors, stats.ibytes);
printf(" RX-errors: %10"PRIu64"\n", stats.ierrors);
printf(" RX-nombuf: %10"PRIu64"\n",
stats.rx_nombuf);
printf(" TX-packets: %10"PRIu64" TX-errors: %10"PRIu64
" TX-bytes: %10"PRIu64"\n",
stats.opackets, stats.oerrors, stats.obytes);
}
if (port->rx_queue_stats_mapping_enabled) {
printf("\n");
for (i = 0; i < RTE_ETHDEV_QUEUE_STAT_CNTRS; i++) {
printf(" Stats reg %2d RX-packets: %10"PRIu64
" RX-errors: %10"PRIu64
" RX-bytes: %10"PRIu64"\n",
i, stats.q_ipackets[i], stats.q_errors[i], stats.q_ibytes[i]);
}
}
if (port->tx_queue_stats_mapping_enabled) {
printf("\n");
for (i = 0; i < RTE_ETHDEV_QUEUE_STAT_CNTRS; i++) {
printf(" Stats reg %2d TX-packets: %10"PRIu64
" TX-bytes: %10"PRIu64"\n",
i, stats.q_opackets[i], stats.q_obytes[i]);
}
}
diff_cycles = prev_cycles[port_id];
prev_cycles[port_id] = rte_rdtsc();
if (diff_cycles > 0)
diff_cycles = prev_cycles[port_id] - diff_cycles;
diff_pkts_rx = (stats.ipackets > prev_pkts_rx[port_id]) ?
(stats.ipackets - prev_pkts_rx[port_id]) : 0;
diff_pkts_tx = (stats.opackets > prev_pkts_tx[port_id]) ?
(stats.opackets - prev_pkts_tx[port_id]) : 0;
prev_pkts_rx[port_id] = stats.ipackets;
prev_pkts_tx[port_id] = stats.opackets;
mpps_rx = diff_cycles > 0 ?
diff_pkts_rx * rte_get_tsc_hz() / diff_cycles : 0;
mpps_tx = diff_cycles > 0 ?
diff_pkts_tx * rte_get_tsc_hz() / diff_cycles : 0;
printf("\n Throughput (since last show)\n");
printf(" Rx-pps: %12"PRIu64"\n Tx-pps: %12"PRIu64"\n",
mpps_rx, mpps_tx);
printf(" %s############################%s\n",
nic_stats_border, nic_stats_border);
}
void
nic_stats_clear(portid_t port_id)
{
portid_t pid;
if (port_id_is_invalid(port_id, ENABLED_WARN)) {
printf("Valid port range is [0");
RTE_ETH_FOREACH_DEV(pid)
printf(", %d", pid);
printf("]\n");
return;
}
rte_eth_stats_reset(port_id);
printf("\n NIC statistics for port %d cleared\n", port_id);
}
void
nic_xstats_display(portid_t port_id)
{
struct rte_eth_xstat *xstats;
int cnt_xstats, idx_xstat;
struct rte_eth_xstat_name *xstats_names;
printf("###### NIC extended statistics for port %-2d\n", port_id);
if (!rte_eth_dev_is_valid_port(port_id)) {
printf("Error: Invalid port number %i\n", port_id);
return;
}
/* Get count */
cnt_xstats = rte_eth_xstats_get_names(port_id, NULL, 0);
if (cnt_xstats < 0) {
printf("Error: Cannot get count of xstats\n");
return;
}
/* Get id-name lookup table */
xstats_names = malloc(sizeof(struct rte_eth_xstat_name) * cnt_xstats);
if (xstats_names == NULL) {
printf("Cannot allocate memory for xstats lookup\n");
return;
}
if (cnt_xstats != rte_eth_xstats_get_names(
port_id, xstats_names, cnt_xstats)) {
printf("Error: Cannot get xstats lookup\n");
free(xstats_names);
return;
}
/* Get stats themselves */
xstats = malloc(sizeof(struct rte_eth_xstat) * cnt_xstats);
if (xstats == NULL) {
printf("Cannot allocate memory for xstats\n");
free(xstats_names);
return;
}
if (cnt_xstats != rte_eth_xstats_get(port_id, xstats, cnt_xstats)) {
printf("Error: Unable to get xstats\n");
free(xstats_names);
free(xstats);
return;
}
/* Display xstats */
for (idx_xstat = 0; idx_xstat < cnt_xstats; idx_xstat++) {
if (xstats_hide_zero && !xstats[idx_xstat].value)
continue;
printf("%s: %"PRIu64"\n",
xstats_names[idx_xstat].name,
xstats[idx_xstat].value);
}
free(xstats_names);
free(xstats);
}
void
nic_xstats_clear(portid_t port_id)
{
rte_eth_xstats_reset(port_id);
}
void
nic_stats_mapping_display(portid_t port_id)
{
struct rte_port *port = &ports[port_id];
uint16_t i;
portid_t pid;
static const char *nic_stats_mapping_border = "########################";
if (port_id_is_invalid(port_id, ENABLED_WARN)) {
printf("Valid port range is [0");
RTE_ETH_FOREACH_DEV(pid)
printf(", %d", pid);
printf("]\n");
return;
}
if ((!port->rx_queue_stats_mapping_enabled) && (!port->tx_queue_stats_mapping_enabled)) {
printf("Port id %d - either does not support queue statistic mapping or"
" no queue statistic mapping set\n", port_id);
return;
}
printf("\n %s NIC statistics mapping for port %-2d %s\n",
nic_stats_mapping_border, port_id, nic_stats_mapping_border);
if (port->rx_queue_stats_mapping_enabled) {
for (i = 0; i < nb_rx_queue_stats_mappings; i++) {
if (rx_queue_stats_mappings[i].port_id == port_id) {
printf(" RX-queue %2d mapped to Stats Reg %2d\n",
rx_queue_stats_mappings[i].queue_id,
rx_queue_stats_mappings[i].stats_counter_id);
}
}
printf("\n");
}
if (port->tx_queue_stats_mapping_enabled) {
for (i = 0; i < nb_tx_queue_stats_mappings; i++) {
if (tx_queue_stats_mappings[i].port_id == port_id) {
printf(" TX-queue %2d mapped to Stats Reg %2d\n",
tx_queue_stats_mappings[i].queue_id,
tx_queue_stats_mappings[i].stats_counter_id);
}
}
}
printf(" %s####################################%s\n",
nic_stats_mapping_border, nic_stats_mapping_border);
}
void
rx_queue_infos_display(portid_t port_id, uint16_t queue_id)
{
struct rte_eth_rxq_info qinfo;
int32_t rc;
static const char *info_border = "*********************";
rc = rte_eth_rx_queue_info_get(port_id, queue_id, &qinfo);
if (rc != 0) {
printf("Failed to retrieve information for port: %u, "
"RX queue: %hu\nerror desc: %s(%d)\n",
port_id, queue_id, strerror(-rc), rc);
return;
}
printf("\n%s Infos for port %-2u, RX queue %-2u %s",
info_border, port_id, queue_id, info_border);
printf("\nMempool: %s", (qinfo.mp == NULL) ? "NULL" : qinfo.mp->name);
printf("\nRX prefetch threshold: %hhu", qinfo.conf.rx_thresh.pthresh);
printf("\nRX host threshold: %hhu", qinfo.conf.rx_thresh.hthresh);
printf("\nRX writeback threshold: %hhu", qinfo.conf.rx_thresh.wthresh);
printf("\nRX free threshold: %hu", qinfo.conf.rx_free_thresh);
printf("\nRX drop packets: %s",
(qinfo.conf.rx_drop_en != 0) ? "on" : "off");
printf("\nRX deferred start: %s",
(qinfo.conf.rx_deferred_start != 0) ? "on" : "off");
printf("\nRX scattered packets: %s",
(qinfo.scattered_rx != 0) ? "on" : "off");
printf("\nNumber of RXDs: %hu", qinfo.nb_desc);
printf("\n");
}
void
tx_queue_infos_display(portid_t port_id, uint16_t queue_id)
{
struct rte_eth_txq_info qinfo;
int32_t rc;
static const char *info_border = "*********************";
rc = rte_eth_tx_queue_info_get(port_id, queue_id, &qinfo);
if (rc != 0) {
printf("Failed to retrieve information for port: %u, "
"TX queue: %hu\nerror desc: %s(%d)\n",
port_id, queue_id, strerror(-rc), rc);
return;
}
printf("\n%s Infos for port %-2u, TX queue %-2u %s",
info_border, port_id, queue_id, info_border);
printf("\nTX prefetch threshold: %hhu", qinfo.conf.tx_thresh.pthresh);
printf("\nTX host threshold: %hhu", qinfo.conf.tx_thresh.hthresh);
printf("\nTX writeback threshold: %hhu", qinfo.conf.tx_thresh.wthresh);
printf("\nTX RS threshold: %hu", qinfo.conf.tx_rs_thresh);
printf("\nTX free threshold: %hu", qinfo.conf.tx_free_thresh);
printf("\nTX deferred start: %s",
(qinfo.conf.tx_deferred_start != 0) ? "on" : "off");
printf("\nNumber of TXDs: %hu", qinfo.nb_desc);
printf("\n");
}
void
port_infos_display(portid_t port_id)
{
struct rte_port *port;
struct ether_addr mac_addr;
struct rte_eth_link link;
struct rte_eth_dev_info dev_info;
int vlan_offload;
struct rte_mempool * mp;
static const char *info_border = "*********************";
portid_t pid;
uint16_t mtu;
if (port_id_is_invalid(port_id, ENABLED_WARN)) {
printf("Valid port range is [0");
RTE_ETH_FOREACH_DEV(pid)
printf(", %d", pid);
printf("]\n");
return;
}
port = &ports[port_id];
rte_eth_link_get_nowait(port_id, &link);
memset(&dev_info, 0, sizeof(dev_info));
rte_eth_dev_info_get(port_id, &dev_info);
printf("\n%s Infos for port %-2d %s\n",
info_border, port_id, info_border);
rte_eth_macaddr_get(port_id, &mac_addr);
print_ethaddr("MAC address: ", &mac_addr);
printf("\nDriver name: %s", dev_info.driver_name);
printf("\nConnect to socket: %u", port->socket_id);
if (port_numa[port_id] != NUMA_NO_CONFIG) {
mp = mbuf_pool_find(port_numa[port_id]);
if (mp)
printf("\nmemory allocation on the socket: %d",
port_numa[port_id]);
} else
printf("\nmemory allocation on the socket: %u",port->socket_id);
printf("\nLink status: %s\n", (link.link_status) ? ("up") : ("down"));
printf("Link speed: %u Mbps\n", (unsigned) link.link_speed);
printf("Link duplex: %s\n", (link.link_duplex == ETH_LINK_FULL_DUPLEX) ?
("full-duplex") : ("half-duplex"));
if (!rte_eth_dev_get_mtu(port_id, &mtu))
printf("MTU: %u\n", mtu);
printf("Promiscuous mode: %s\n",
rte_eth_promiscuous_get(port_id) ? "enabled" : "disabled");
printf("Allmulticast mode: %s\n",
rte_eth_allmulticast_get(port_id) ? "enabled" : "disabled");
printf("Maximum number of MAC addresses: %u\n",
(unsigned int)(port->dev_info.max_mac_addrs));
printf("Maximum number of MAC addresses of hash filtering: %u\n",
(unsigned int)(port->dev_info.max_hash_mac_addrs));
vlan_offload = rte_eth_dev_get_vlan_offload(port_id);
if (vlan_offload >= 0){
printf("VLAN offload: \n");
if (vlan_offload & ETH_VLAN_STRIP_OFFLOAD)
printf(" strip on \n");
else
printf(" strip off \n");
if (vlan_offload & ETH_VLAN_FILTER_OFFLOAD)
printf(" filter on \n");
else
printf(" filter off \n");
if (vlan_offload & ETH_VLAN_EXTEND_OFFLOAD)
printf(" qinq(extend) on \n");
else
printf(" qinq(extend) off \n");
}
if (dev_info.hash_key_size > 0)
printf("Hash key size in bytes: %u\n", dev_info.hash_key_size);
if (dev_info.reta_size > 0)
printf("Redirection table size: %u\n", dev_info.reta_size);
if (!dev_info.flow_type_rss_offloads)
printf("No flow type is supported.\n");
else {
uint16_t i;
char *p;
printf("Supported flow types:\n");
for (i = RTE_ETH_FLOW_UNKNOWN + 1;
i < sizeof(dev_info.flow_type_rss_offloads) * CHAR_BIT; i++) {
if (!(dev_info.flow_type_rss_offloads & (1ULL << i)))
continue;
p = flowtype_to_str(i);
if (p)
printf(" %s\n", p);
else
printf(" user defined %d\n", i);
}
}
printf("Minimum size of RX buffer: %u\n", dev_info.min_rx_bufsize);
printf("Maximum configurable length of RX packet: %u\n",
dev_info.max_rx_pktlen);
if (dev_info.max_vfs)
printf("Maximum number of VFs: %u\n", dev_info.max_vfs);
if (dev_info.max_vmdq_pools)
printf("Maximum number of VMDq pools: %u\n",
dev_info.max_vmdq_pools);
printf("Current number of RX queues: %u\n", dev_info.nb_rx_queues);
printf("Max possible RX queues: %u\n", dev_info.max_rx_queues);
printf("Max possible number of RXDs per queue: %hu\n",
dev_info.rx_desc_lim.nb_max);
printf("Min possible number of RXDs per queue: %hu\n",
dev_info.rx_desc_lim.nb_min);
printf("RXDs number alignment: %hu\n", dev_info.rx_desc_lim.nb_align);
printf("Current number of TX queues: %u\n", dev_info.nb_tx_queues);
printf("Max possible TX queues: %u\n", dev_info.max_tx_queues);
printf("Max possible number of TXDs per queue: %hu\n",
dev_info.tx_desc_lim.nb_max);
printf("Min possible number of TXDs per queue: %hu\n",
dev_info.tx_desc_lim.nb_min);
printf("TXDs number alignment: %hu\n", dev_info.tx_desc_lim.nb_align);
}
void
port_offload_cap_display(portid_t port_id)
{
struct rte_eth_dev_info dev_info;
static const char *info_border = "************";
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
rte_eth_dev_info_get(port_id, &dev_info);
printf("\n%s Port %d supported offload features: %s\n",
info_border, port_id, info_border);
if (dev_info.rx_offload_capa & DEV_RX_OFFLOAD_VLAN_STRIP) {
printf("VLAN stripped: ");
if (ports[port_id].dev_conf.rxmode.offloads &
DEV_RX_OFFLOAD_VLAN_STRIP)
printf("on\n");
else
printf("off\n");
}
if (dev_info.rx_offload_capa & DEV_RX_OFFLOAD_QINQ_STRIP) {
printf("Double VLANs stripped: ");
if (ports[port_id].dev_conf.rxmode.offloads &
DEV_RX_OFFLOAD_VLAN_EXTEND)
printf("on\n");
else
printf("off\n");
}
if (dev_info.rx_offload_capa & DEV_RX_OFFLOAD_IPV4_CKSUM) {
printf("RX IPv4 checksum: ");
if (ports[port_id].dev_conf.rxmode.offloads &
DEV_RX_OFFLOAD_IPV4_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.rx_offload_capa & DEV_RX_OFFLOAD_UDP_CKSUM) {
printf("RX UDP checksum: ");
if (ports[port_id].dev_conf.rxmode.offloads &
DEV_RX_OFFLOAD_UDP_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.rx_offload_capa & DEV_RX_OFFLOAD_TCP_CKSUM) {
printf("RX TCP checksum: ");
if (ports[port_id].dev_conf.rxmode.offloads &
DEV_RX_OFFLOAD_TCP_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.rx_offload_capa & DEV_RX_OFFLOAD_OUTER_IPV4_CKSUM) {
printf("RX Outer IPv4 checksum: ");
if (ports[port_id].dev_conf.rxmode.offloads &
DEV_RX_OFFLOAD_OUTER_IPV4_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.rx_offload_capa & DEV_RX_OFFLOAD_TCP_LRO) {
printf("Large receive offload: ");
if (ports[port_id].dev_conf.rxmode.offloads &
DEV_RX_OFFLOAD_TCP_LRO)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_VLAN_INSERT) {
printf("VLAN insert: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_VLAN_INSERT)
printf("on\n");
else
printf("off\n");
}
if (dev_info.rx_offload_capa & DEV_RX_OFFLOAD_TIMESTAMP) {
printf("HW timestamp: ");
if (ports[port_id].dev_conf.rxmode.offloads &
DEV_RX_OFFLOAD_TIMESTAMP)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_QINQ_INSERT) {
printf("Double VLANs insert: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_QINQ_INSERT)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_IPV4_CKSUM) {
printf("TX IPv4 checksum: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_IPV4_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_UDP_CKSUM) {
printf("TX UDP checksum: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_UDP_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_TCP_CKSUM) {
printf("TX TCP checksum: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_TCP_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_SCTP_CKSUM) {
printf("TX SCTP checksum: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_SCTP_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_OUTER_IPV4_CKSUM) {
printf("TX Outer IPv4 checksum: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_OUTER_IPV4_CKSUM)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_TCP_TSO) {
printf("TX TCP segmentation: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_TCP_TSO)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_UDP_TSO) {
printf("TX UDP segmentation: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_UDP_TSO)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_VXLAN_TNL_TSO) {
printf("TSO for VXLAN tunnel packet: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_VXLAN_TNL_TSO)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_GRE_TNL_TSO) {
printf("TSO for GRE tunnel packet: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_GRE_TNL_TSO)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_IPIP_TNL_TSO) {
printf("TSO for IPIP tunnel packet: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_IPIP_TNL_TSO)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_GENEVE_TNL_TSO) {
printf("TSO for GENEVE tunnel packet: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_GENEVE_TNL_TSO)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_IP_TNL_TSO) {
printf("IP tunnel TSO: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_IP_TNL_TSO)
printf("on\n");
else
printf("off\n");
}
if (dev_info.tx_offload_capa & DEV_TX_OFFLOAD_UDP_TNL_TSO) {
printf("UDP tunnel TSO: ");
if (ports[port_id].dev_conf.txmode.offloads &
DEV_TX_OFFLOAD_UDP_TNL_TSO)
printf("on\n");
else
printf("off\n");
}
}
int
port_id_is_invalid(portid_t port_id, enum print_warning warning)
{
uint16_t pid;
if (port_id == (portid_t)RTE_PORT_ALL)
return 0;
RTE_ETH_FOREACH_DEV(pid)
if (port_id == pid)
return 0;
if (warning == ENABLED_WARN)
printf("Invalid port %d\n", port_id);
return 1;
}
static int
vlan_id_is_invalid(uint16_t vlan_id)
{
if (vlan_id < 4096)
return 0;
printf("Invalid vlan_id %d (must be < 4096)\n", vlan_id);
return 1;
}
static int
port_reg_off_is_invalid(portid_t port_id, uint32_t reg_off)
{
const struct rte_pci_device *pci_dev;
const struct rte_bus *bus;
uint64_t pci_len;
if (reg_off & 0x3) {
printf("Port register offset 0x%X not aligned on a 4-byte "
"boundary\n",
(unsigned)reg_off);
return 1;
}
if (!ports[port_id].dev_info.device) {
printf("Invalid device\n");
return 0;
}
bus = rte_bus_find_by_device(ports[port_id].dev_info.device);
if (bus && !strcmp(bus->name, "pci")) {
pci_dev = RTE_DEV_TO_PCI(ports[port_id].dev_info.device);
} else {
printf("Not a PCI device\n");
return 1;
}
pci_len = pci_dev->mem_resource[0].len;
if (reg_off >= pci_len) {
printf("Port %d: register offset %u (0x%X) out of port PCI "
"resource (length=%"PRIu64")\n",
port_id, (unsigned)reg_off, (unsigned)reg_off, pci_len);
return 1;
}
return 0;
}
static int
reg_bit_pos_is_invalid(uint8_t bit_pos)
{
if (bit_pos <= 31)
return 0;
printf("Invalid bit position %d (must be <= 31)\n", bit_pos);
return 1;
}
#define display_port_and_reg_off(port_id, reg_off) \
printf("port %d PCI register at offset 0x%X: ", (port_id), (reg_off))
static inline void
display_port_reg_value(portid_t port_id, uint32_t reg_off, uint32_t reg_v)
{
display_port_and_reg_off(port_id, (unsigned)reg_off);
printf("0x%08X (%u)\n", (unsigned)reg_v, (unsigned)reg_v);
}
void
port_reg_bit_display(portid_t port_id, uint32_t reg_off, uint8_t bit_x)
{
uint32_t reg_v;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (port_reg_off_is_invalid(port_id, reg_off))
return;
if (reg_bit_pos_is_invalid(bit_x))
return;
reg_v = port_id_pci_reg_read(port_id, reg_off);
display_port_and_reg_off(port_id, (unsigned)reg_off);
printf("bit %d=%d\n", bit_x, (int) ((reg_v & (1 << bit_x)) >> bit_x));
}
void
port_reg_bit_field_display(portid_t port_id, uint32_t reg_off,
uint8_t bit1_pos, uint8_t bit2_pos)
{
uint32_t reg_v;
uint8_t l_bit;
uint8_t h_bit;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (port_reg_off_is_invalid(port_id, reg_off))
return;
if (reg_bit_pos_is_invalid(bit1_pos))
return;
if (reg_bit_pos_is_invalid(bit2_pos))
return;
if (bit1_pos > bit2_pos)
l_bit = bit2_pos, h_bit = bit1_pos;
else
l_bit = bit1_pos, h_bit = bit2_pos;
reg_v = port_id_pci_reg_read(port_id, reg_off);
reg_v >>= l_bit;
if (h_bit < 31)
reg_v &= ((1 << (h_bit - l_bit + 1)) - 1);
display_port_and_reg_off(port_id, (unsigned)reg_off);
printf("bits[%d, %d]=0x%0*X (%u)\n", l_bit, h_bit,
((h_bit - l_bit) / 4) + 1, (unsigned)reg_v, (unsigned)reg_v);
}
void
port_reg_display(portid_t port_id, uint32_t reg_off)
{
uint32_t reg_v;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (port_reg_off_is_invalid(port_id, reg_off))
return;
reg_v = port_id_pci_reg_read(port_id, reg_off);
display_port_reg_value(port_id, reg_off, reg_v);
}
void
port_reg_bit_set(portid_t port_id, uint32_t reg_off, uint8_t bit_pos,
uint8_t bit_v)
{
uint32_t reg_v;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (port_reg_off_is_invalid(port_id, reg_off))
return;
if (reg_bit_pos_is_invalid(bit_pos))
return;
if (bit_v > 1) {
printf("Invalid bit value %d (must be 0 or 1)\n", (int) bit_v);
return;
}
reg_v = port_id_pci_reg_read(port_id, reg_off);
if (bit_v == 0)
reg_v &= ~(1 << bit_pos);
else
reg_v |= (1 << bit_pos);
port_id_pci_reg_write(port_id, reg_off, reg_v);
display_port_reg_value(port_id, reg_off, reg_v);
}
void
port_reg_bit_field_set(portid_t port_id, uint32_t reg_off,
uint8_t bit1_pos, uint8_t bit2_pos, uint32_t value)
{
uint32_t max_v;
uint32_t reg_v;
uint8_t l_bit;
uint8_t h_bit;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (port_reg_off_is_invalid(port_id, reg_off))
return;
if (reg_bit_pos_is_invalid(bit1_pos))
return;
if (reg_bit_pos_is_invalid(bit2_pos))
return;
if (bit1_pos > bit2_pos)
l_bit = bit2_pos, h_bit = bit1_pos;
else
l_bit = bit1_pos, h_bit = bit2_pos;
if ((h_bit - l_bit) < 31)
max_v = (1 << (h_bit - l_bit + 1)) - 1;
else
max_v = 0xFFFFFFFF;
if (value > max_v) {
printf("Invalid value %u (0x%x) must be < %u (0x%x)\n",
(unsigned)value, (unsigned)value,
(unsigned)max_v, (unsigned)max_v);
return;
}
reg_v = port_id_pci_reg_read(port_id, reg_off);
reg_v &= ~(max_v << l_bit); /* Keep unchanged bits */
reg_v |= (value << l_bit); /* Set changed bits */
port_id_pci_reg_write(port_id, reg_off, reg_v);
display_port_reg_value(port_id, reg_off, reg_v);
}
void
port_reg_set(portid_t port_id, uint32_t reg_off, uint32_t reg_v)
{
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (port_reg_off_is_invalid(port_id, reg_off))
return;
port_id_pci_reg_write(port_id, reg_off, reg_v);
display_port_reg_value(port_id, reg_off, reg_v);
}
void
port_mtu_set(portid_t port_id, uint16_t mtu)
{
int diag;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
diag = rte_eth_dev_set_mtu(port_id, mtu);
if (diag == 0)
return;
printf("Set MTU failed. diag=%d\n", diag);
}
/* Generic flow management functions. */
/** Generate flow_item[] entry. */
#define MK_FLOW_ITEM(t, s) \
[RTE_FLOW_ITEM_TYPE_ ## t] = { \
.name = # t, \
.size = s, \
}
/** Information about known flow pattern items. */
static const struct {
const char *name;
size_t size;
} flow_item[] = {
MK_FLOW_ITEM(END, 0),
MK_FLOW_ITEM(VOID, 0),
MK_FLOW_ITEM(INVERT, 0),
MK_FLOW_ITEM(ANY, sizeof(struct rte_flow_item_any)),
MK_FLOW_ITEM(PF, 0),
MK_FLOW_ITEM(VF, sizeof(struct rte_flow_item_vf)),
MK_FLOW_ITEM(PORT, sizeof(struct rte_flow_item_port)),
MK_FLOW_ITEM(RAW, sizeof(struct rte_flow_item_raw)), /* +pattern[] */
MK_FLOW_ITEM(ETH, sizeof(struct rte_flow_item_eth)),
MK_FLOW_ITEM(VLAN, sizeof(struct rte_flow_item_vlan)),
MK_FLOW_ITEM(IPV4, sizeof(struct rte_flow_item_ipv4)),
MK_FLOW_ITEM(IPV6, sizeof(struct rte_flow_item_ipv6)),
MK_FLOW_ITEM(ICMP, sizeof(struct rte_flow_item_icmp)),
MK_FLOW_ITEM(UDP, sizeof(struct rte_flow_item_udp)),
MK_FLOW_ITEM(TCP, sizeof(struct rte_flow_item_tcp)),
MK_FLOW_ITEM(SCTP, sizeof(struct rte_flow_item_sctp)),
MK_FLOW_ITEM(VXLAN, sizeof(struct rte_flow_item_vxlan)),
MK_FLOW_ITEM(E_TAG, sizeof(struct rte_flow_item_e_tag)),
MK_FLOW_ITEM(NVGRE, sizeof(struct rte_flow_item_nvgre)),
MK_FLOW_ITEM(MPLS, sizeof(struct rte_flow_item_mpls)),
MK_FLOW_ITEM(GRE, sizeof(struct rte_flow_item_gre)),
MK_FLOW_ITEM(FUZZY, sizeof(struct rte_flow_item_fuzzy)),
MK_FLOW_ITEM(GTP, sizeof(struct rte_flow_item_gtp)),
MK_FLOW_ITEM(GTPC, sizeof(struct rte_flow_item_gtp)),
MK_FLOW_ITEM(GTPU, sizeof(struct rte_flow_item_gtp)),
MK_FLOW_ITEM(GENEVE, sizeof(struct rte_flow_item_geneve)),
};
/** Pattern item specification types. */
enum item_spec_type {
ITEM_SPEC,
ITEM_LAST,
ITEM_MASK,
};
/** Compute storage space needed by item specification and copy it. */
static size_t
flow_item_spec_copy(void *buf, const struct rte_flow_item *item,
enum item_spec_type type)
{
size_t size = 0;
const void *item_spec =
type == ITEM_SPEC ? item->spec :
type == ITEM_LAST ? item->last :
type == ITEM_MASK ? item->mask :
NULL;
if (!item_spec)
goto empty;
switch (item->type) {
union {
const struct rte_flow_item_raw *raw;
} src;
union {
struct rte_flow_item_raw *raw;
} dst;
case RTE_FLOW_ITEM_TYPE_RAW:
src.raw = item_spec;
dst.raw = buf;
size = offsetof(struct rte_flow_item_raw, pattern) +
src.raw->length * sizeof(*src.raw->pattern);
if (dst.raw)
memcpy(dst.raw, src.raw, size);
break;
default:
size = flow_item[item->type].size;
if (buf)
memcpy(buf, item_spec, size);
break;
}
empty:
return RTE_ALIGN_CEIL(size, sizeof(double));
}
/** Generate flow_action[] entry. */
#define MK_FLOW_ACTION(t, s) \
[RTE_FLOW_ACTION_TYPE_ ## t] = { \
.name = # t, \
.size = s, \
}
/** Information about known flow actions. */
static const struct {
const char *name;
size_t size;
} flow_action[] = {
MK_FLOW_ACTION(END, 0),
MK_FLOW_ACTION(VOID, 0),
MK_FLOW_ACTION(PASSTHRU, 0),
MK_FLOW_ACTION(MARK, sizeof(struct rte_flow_action_mark)),
MK_FLOW_ACTION(FLAG, 0),
MK_FLOW_ACTION(QUEUE, sizeof(struct rte_flow_action_queue)),
MK_FLOW_ACTION(DROP, 0),
MK_FLOW_ACTION(COUNT, 0),
MK_FLOW_ACTION(DUP, sizeof(struct rte_flow_action_dup)),
MK_FLOW_ACTION(RSS, sizeof(struct rte_flow_action_rss)), /* +queue[] */
MK_FLOW_ACTION(PF, 0),
MK_FLOW_ACTION(VF, sizeof(struct rte_flow_action_vf)),
MK_FLOW_ACTION(METER, sizeof(struct rte_flow_action_meter)),
};
/** Compute storage space needed by action configuration and copy it. */
static size_t
flow_action_conf_copy(void *buf, const struct rte_flow_action *action)
{
size_t size = 0;
if (!action->conf)
goto empty;
switch (action->type) {
union {
const struct rte_flow_action_rss *rss;
} src;
union {
struct rte_flow_action_rss *rss;
} dst;
size_t off;
case RTE_FLOW_ACTION_TYPE_RSS:
src.rss = action->conf;
dst.rss = buf;
off = 0;
if (dst.rss)
*dst.rss = (struct rte_flow_action_rss){
.num = src.rss->num,
};
off += offsetof(struct rte_flow_action_rss, queue);
if (src.rss->num) {
size = sizeof(*src.rss->queue) * src.rss->num;
if (dst.rss)
memcpy(dst.rss->queue, src.rss->queue, size);
off += size;
}
off = RTE_ALIGN_CEIL(off, sizeof(double));
if (dst.rss) {
dst.rss->rss_conf = (void *)((uintptr_t)dst.rss + off);
*(struct rte_eth_rss_conf *)(uintptr_t)
dst.rss->rss_conf = (struct rte_eth_rss_conf){
.rss_key_len = src.rss->rss_conf->rss_key_len,
.rss_hf = src.rss->rss_conf->rss_hf,
};
}
off += sizeof(*src.rss->rss_conf);
if (src.rss->rss_conf->rss_key_len) {
off = RTE_ALIGN_CEIL(off, sizeof(double));
size = sizeof(*src.rss->rss_conf->rss_key) *
src.rss->rss_conf->rss_key_len;
if (dst.rss) {
((struct rte_eth_rss_conf *)(uintptr_t)
dst.rss->rss_conf)->rss_key =
(void *)((uintptr_t)dst.rss + off);
memcpy(dst.rss->rss_conf->rss_key,
src.rss->rss_conf->rss_key,
size);
}
off += size;
}
size = off;
break;
default:
size = flow_action[action->type].size;
if (buf)
memcpy(buf, action->conf, size);
break;
}
empty:
return RTE_ALIGN_CEIL(size, sizeof(double));
}
/** Generate a port_flow entry from attributes/pattern/actions. */
static struct port_flow *
port_flow_new(const struct rte_flow_attr *attr,
const struct rte_flow_item *pattern,
const struct rte_flow_action *actions)
{
const struct rte_flow_item *item;
const struct rte_flow_action *action;
struct port_flow *pf = NULL;
size_t tmp;
size_t off1 = 0;
size_t off2 = 0;
int err = ENOTSUP;
store:
item = pattern;
if (pf)
pf->pattern = (void *)&pf->data[off1];
do {
struct rte_flow_item *dst = NULL;
if ((unsigned int)item->type >= RTE_DIM(flow_item) ||
!flow_item[item->type].name)
goto notsup;
if (pf)
dst = memcpy(pf->data + off1, item, sizeof(*item));
off1 += sizeof(*item);
if (item->spec) {
if (pf)
dst->spec = pf->data + off2;
off2 += flow_item_spec_copy
(pf ? pf->data + off2 : NULL, item, ITEM_SPEC);
}
if (item->last) {
if (pf)
dst->last = pf->data + off2;
off2 += flow_item_spec_copy
(pf ? pf->data + off2 : NULL, item, ITEM_LAST);
}
if (item->mask) {
if (pf)
dst->mask = pf->data + off2;
off2 += flow_item_spec_copy
(pf ? pf->data + off2 : NULL, item, ITEM_MASK);
}
off2 = RTE_ALIGN_CEIL(off2, sizeof(double));
} while ((item++)->type != RTE_FLOW_ITEM_TYPE_END);
off1 = RTE_ALIGN_CEIL(off1, sizeof(double));
action = actions;
if (pf)
pf->actions = (void *)&pf->data[off1];
do {
struct rte_flow_action *dst = NULL;
if ((unsigned int)action->type >= RTE_DIM(flow_action) ||
!flow_action[action->type].name)
goto notsup;
if (pf)
dst = memcpy(pf->data + off1, action, sizeof(*action));
off1 += sizeof(*action);
if (action->conf) {
if (pf)
dst->conf = pf->data + off2;
off2 += flow_action_conf_copy
(pf ? pf->data + off2 : NULL, action);
}
off2 = RTE_ALIGN_CEIL(off2, sizeof(double));
} while ((action++)->type != RTE_FLOW_ACTION_TYPE_END);
if (pf != NULL)
return pf;
off1 = RTE_ALIGN_CEIL(off1, sizeof(double));
tmp = RTE_ALIGN_CEIL(offsetof(struct port_flow, data), sizeof(double));
pf = calloc(1, tmp + off1 + off2);
if (pf == NULL)
err = errno;
else {
*pf = (const struct port_flow){
.size = tmp + off1 + off2,
.attr = *attr,
};
tmp -= offsetof(struct port_flow, data);
off2 = tmp + off1;
off1 = tmp;
goto store;
}
notsup:
rte_errno = err;
return NULL;
}
/** Print a message out of a flow error. */
static int
port_flow_complain(struct rte_flow_error *error)
{
static const char *const errstrlist[] = {
[RTE_FLOW_ERROR_TYPE_NONE] = "no error",
[RTE_FLOW_ERROR_TYPE_UNSPECIFIED] = "cause unspecified",
[RTE_FLOW_ERROR_TYPE_HANDLE] = "flow rule (handle)",
[RTE_FLOW_ERROR_TYPE_ATTR_GROUP] = "group field",
[RTE_FLOW_ERROR_TYPE_ATTR_PRIORITY] = "priority field",
[RTE_FLOW_ERROR_TYPE_ATTR_INGRESS] = "ingress field",
[RTE_FLOW_ERROR_TYPE_ATTR_EGRESS] = "egress field",
[RTE_FLOW_ERROR_TYPE_ATTR] = "attributes structure",
[RTE_FLOW_ERROR_TYPE_ITEM_NUM] = "pattern length",
[RTE_FLOW_ERROR_TYPE_ITEM] = "specific pattern item",
[RTE_FLOW_ERROR_TYPE_ACTION_NUM] = "number of actions",
[RTE_FLOW_ERROR_TYPE_ACTION] = "specific action",
};
const char *errstr;
char buf[32];
int err = rte_errno;
if ((unsigned int)error->type >= RTE_DIM(errstrlist) ||
!errstrlist[error->type])
errstr = "unknown type";
else
errstr = errstrlist[error->type];
printf("Caught error type %d (%s): %s%s\n",
error->type, errstr,
error->cause ? (snprintf(buf, sizeof(buf), "cause: %p, ",
error->cause), buf) : "",
error->message ? error->message : "(no stated reason)");
return -err;
}
/** Validate flow rule. */
int
port_flow_validate(portid_t port_id,
const struct rte_flow_attr *attr,
const struct rte_flow_item *pattern,
const struct rte_flow_action *actions)
{
struct rte_flow_error error;
/* Poisoning to make sure PMDs update it in case of error. */
memset(&error, 0x11, sizeof(error));
if (rte_flow_validate(port_id, attr, pattern, actions, &error))
return port_flow_complain(&error);
printf("Flow rule validated\n");
return 0;
}
/** Create flow rule. */
int
port_flow_create(portid_t port_id,
const struct rte_flow_attr *attr,
const struct rte_flow_item *pattern,
const struct rte_flow_action *actions)
{
struct rte_flow *flow;
struct rte_port *port;
struct port_flow *pf;
uint32_t id;
struct rte_flow_error error;
/* Poisoning to make sure PMDs update it in case of error. */
memset(&error, 0x22, sizeof(error));
flow = rte_flow_create(port_id, attr, pattern, actions, &error);
if (!flow)
return port_flow_complain(&error);
port = &ports[port_id];
if (port->flow_list) {
if (port->flow_list->id == UINT32_MAX) {
printf("Highest rule ID is already assigned, delete"
" it first");
rte_flow_destroy(port_id, flow, NULL);
return -ENOMEM;
}
id = port->flow_list->id + 1;
} else
id = 0;
pf = port_flow_new(attr, pattern, actions);
if (!pf) {
int err = rte_errno;
printf("Cannot allocate flow: %s\n", rte_strerror(err));
rte_flow_destroy(port_id, flow, NULL);
return -err;
}
pf->next = port->flow_list;
pf->id = id;
pf->flow = flow;
port->flow_list = pf;
printf("Flow rule #%u created\n", pf->id);
return 0;
}
/** Destroy a number of flow rules. */
int
port_flow_destroy(portid_t port_id, uint32_t n, const uint32_t *rule)
{
struct rte_port *port;
struct port_flow **tmp;
uint32_t c = 0;
int ret = 0;
if (port_id_is_invalid(port_id, ENABLED_WARN) ||
port_id == (portid_t)RTE_PORT_ALL)
return -EINVAL;
port = &ports[port_id];
tmp = &port->flow_list;
while (*tmp) {
uint32_t i;
for (i = 0; i != n; ++i) {
struct rte_flow_error error;
struct port_flow *pf = *tmp;
if (rule[i] != pf->id)
continue;
/*
* Poisoning to make sure PMDs update it in case
* of error.
*/
memset(&error, 0x33, sizeof(error));
if (rte_flow_destroy(port_id, pf->flow, &error)) {
ret = port_flow_complain(&error);
continue;
}
printf("Flow rule #%u destroyed\n", pf->id);
*tmp = pf->next;
free(pf);
break;
}
if (i == n)
tmp = &(*tmp)->next;
++c;
}
return ret;
}
/** Remove all flow rules. */
int
port_flow_flush(portid_t port_id)
{
struct rte_flow_error error;
struct rte_port *port;
int ret = 0;
/* Poisoning to make sure PMDs update it in case of error. */
memset(&error, 0x44, sizeof(error));
if (rte_flow_flush(port_id, &error)) {
ret = port_flow_complain(&error);
if (port_id_is_invalid(port_id, DISABLED_WARN) ||
port_id == (portid_t)RTE_PORT_ALL)
return ret;
}
port = &ports[port_id];
while (port->flow_list) {
struct port_flow *pf = port->flow_list->next;
free(port->flow_list);
port->flow_list = pf;
}
return ret;
}
/** Query a flow rule. */
int
port_flow_query(portid_t port_id, uint32_t rule,
enum rte_flow_action_type action)
{
struct rte_flow_error error;
struct rte_port *port;
struct port_flow *pf;
const char *name;
union {
struct rte_flow_query_count count;
} query;
if (port_id_is_invalid(port_id, ENABLED_WARN) ||
port_id == (portid_t)RTE_PORT_ALL)
return -EINVAL;
port = &ports[port_id];
for (pf = port->flow_list; pf; pf = pf->next)
if (pf->id == rule)
break;
if (!pf) {
printf("Flow rule #%u not found\n", rule);
return -ENOENT;
}
if ((unsigned int)action >= RTE_DIM(flow_action) ||
!flow_action[action].name)
name = "unknown";
else
name = flow_action[action].name;
switch (action) {
case RTE_FLOW_ACTION_TYPE_COUNT:
break;
default:
printf("Cannot query action type %d (%s)\n", action, name);
return -ENOTSUP;
}
/* Poisoning to make sure PMDs update it in case of error. */
memset(&error, 0x55, sizeof(error));
memset(&query, 0, sizeof(query));
if (rte_flow_query(port_id, pf->flow, action, &query, &error))
return port_flow_complain(&error);
switch (action) {
case RTE_FLOW_ACTION_TYPE_COUNT:
printf("%s:\n"
" hits_set: %u\n"
" bytes_set: %u\n"
" hits: %" PRIu64 "\n"
" bytes: %" PRIu64 "\n",
name,
query.count.hits_set,
query.count.bytes_set,
query.count.hits,
query.count.bytes);
break;
default:
printf("Cannot display result for action type %d (%s)\n",
action, name);
break;
}
return 0;
}
/** List flow rules. */
void
port_flow_list(portid_t port_id, uint32_t n, const uint32_t group[n])
{
struct rte_port *port;
struct port_flow *pf;
struct port_flow *list = NULL;
uint32_t i;
if (port_id_is_invalid(port_id, ENABLED_WARN) ||
port_id == (portid_t)RTE_PORT_ALL)
return;
port = &ports[port_id];
if (!port->flow_list)
return;
/* Sort flows by group, priority and ID. */
for (pf = port->flow_list; pf != NULL; pf = pf->next) {
struct port_flow **tmp;
if (n) {
/* Filter out unwanted groups. */
for (i = 0; i != n; ++i)
if (pf->attr.group == group[i])
break;
if (i == n)
continue;
}
tmp = &list;
while (*tmp &&
(pf->attr.group > (*tmp)->attr.group ||
(pf->attr.group == (*tmp)->attr.group &&
pf->attr.priority > (*tmp)->attr.priority) ||
(pf->attr.group == (*tmp)->attr.group &&
pf->attr.priority == (*tmp)->attr.priority &&
pf->id > (*tmp)->id)))
tmp = &(*tmp)->tmp;
pf->tmp = *tmp;
*tmp = pf;
}
printf("ID\tGroup\tPrio\tAttr\tRule\n");
for (pf = list; pf != NULL; pf = pf->tmp) {
const struct rte_flow_item *item = pf->pattern;
const struct rte_flow_action *action = pf->actions;
printf("%" PRIu32 "\t%" PRIu32 "\t%" PRIu32 "\t%c%c\t",
pf->id,
pf->attr.group,
pf->attr.priority,
pf->attr.ingress ? 'i' : '-',
pf->attr.egress ? 'e' : '-');
while (item->type != RTE_FLOW_ITEM_TYPE_END) {
if (item->type != RTE_FLOW_ITEM_TYPE_VOID)
printf("%s ", flow_item[item->type].name);
++item;
}
printf("=>");
while (action->type != RTE_FLOW_ACTION_TYPE_END) {
if (action->type != RTE_FLOW_ACTION_TYPE_VOID)
printf(" %s", flow_action[action->type].name);
++action;
}
printf("\n");
}
}
/** Restrict ingress traffic to the defined flow rules. */
int
port_flow_isolate(portid_t port_id, int set)
{
struct rte_flow_error error;
/* Poisoning to make sure PMDs update it in case of error. */
memset(&error, 0x66, sizeof(error));
if (rte_flow_isolate(port_id, set, &error))
return port_flow_complain(&error);
printf("Ingress traffic on port %u is %s to the defined flow rules\n",
port_id,
set ? "now restricted" : "not restricted anymore");
return 0;
}
/*
* RX/TX ring descriptors display functions.
*/
int
rx_queue_id_is_invalid(queueid_t rxq_id)
{
if (rxq_id < nb_rxq)
return 0;
printf("Invalid RX queue %d (must be < nb_rxq=%d)\n", rxq_id, nb_rxq);
return 1;
}
int
tx_queue_id_is_invalid(queueid_t txq_id)
{
if (txq_id < nb_txq)
return 0;
printf("Invalid TX queue %d (must be < nb_rxq=%d)\n", txq_id, nb_txq);
return 1;
}
static int
rx_desc_id_is_invalid(uint16_t rxdesc_id)
{
if (rxdesc_id < nb_rxd)
return 0;
printf("Invalid RX descriptor %d (must be < nb_rxd=%d)\n",
rxdesc_id, nb_rxd);
return 1;
}
static int
tx_desc_id_is_invalid(uint16_t txdesc_id)
{
if (txdesc_id < nb_txd)
return 0;
printf("Invalid TX descriptor %d (must be < nb_txd=%d)\n",
txdesc_id, nb_txd);
return 1;
}
static const struct rte_memzone *
ring_dma_zone_lookup(const char *ring_name, portid_t port_id, uint16_t q_id)
{
char mz_name[RTE_MEMZONE_NAMESIZE];
const struct rte_memzone *mz;
snprintf(mz_name, sizeof(mz_name), "%s_%s_%d_%d",
ports[port_id].dev_info.driver_name, ring_name, port_id, q_id);
mz = rte_memzone_lookup(mz_name);
if (mz == NULL)
printf("%s ring memory zoneof (port %d, queue %d) not"
"found (zone name = %s\n",
ring_name, port_id, q_id, mz_name);
return mz;
}
union igb_ring_dword {
uint64_t dword;
struct {
#if RTE_BYTE_ORDER == RTE_BIG_ENDIAN
uint32_t lo;
uint32_t hi;
#else
uint32_t hi;
uint32_t lo;
#endif
} words;
};
struct igb_ring_desc_32_bytes {
union igb_ring_dword lo_dword;
union igb_ring_dword hi_dword;
union igb_ring_dword resv1;
union igb_ring_dword resv2;
};
struct igb_ring_desc_16_bytes {
union igb_ring_dword lo_dword;
union igb_ring_dword hi_dword;
};
static void
ring_rxd_display_dword(union igb_ring_dword dword)
{
printf(" 0x%08X - 0x%08X\n", (unsigned)dword.words.lo,
(unsigned)dword.words.hi);
}
static void
ring_rx_descriptor_display(const struct rte_memzone *ring_mz,
#ifndef RTE_LIBRTE_I40E_16BYTE_RX_DESC
portid_t port_id,
#else
__rte_unused portid_t port_id,
#endif
uint16_t desc_id)
{
struct igb_ring_desc_16_bytes *ring =
(struct igb_ring_desc_16_bytes *)ring_mz->addr;
#ifndef RTE_LIBRTE_I40E_16BYTE_RX_DESC
struct rte_eth_dev_info dev_info;
memset(&dev_info, 0, sizeof(dev_info));
rte_eth_dev_info_get(port_id, &dev_info);
if (strstr(dev_info.driver_name, "i40e") != NULL) {
/* 32 bytes RX descriptor, i40e only */
struct igb_ring_desc_32_bytes *ring =
(struct igb_ring_desc_32_bytes *)ring_mz->addr;
ring[desc_id].lo_dword.dword =
rte_le_to_cpu_64(ring[desc_id].lo_dword.dword);
ring_rxd_display_dword(ring[desc_id].lo_dword);
ring[desc_id].hi_dword.dword =
rte_le_to_cpu_64(ring[desc_id].hi_dword.dword);
ring_rxd_display_dword(ring[desc_id].hi_dword);
ring[desc_id].resv1.dword =
rte_le_to_cpu_64(ring[desc_id].resv1.dword);
ring_rxd_display_dword(ring[desc_id].resv1);
ring[desc_id].resv2.dword =
rte_le_to_cpu_64(ring[desc_id].resv2.dword);
ring_rxd_display_dword(ring[desc_id].resv2);
return;
}
#endif
/* 16 bytes RX descriptor */
ring[desc_id].lo_dword.dword =
rte_le_to_cpu_64(ring[desc_id].lo_dword.dword);
ring_rxd_display_dword(ring[desc_id].lo_dword);
ring[desc_id].hi_dword.dword =
rte_le_to_cpu_64(ring[desc_id].hi_dword.dword);
ring_rxd_display_dword(ring[desc_id].hi_dword);
}
static void
ring_tx_descriptor_display(const struct rte_memzone *ring_mz, uint16_t desc_id)
{
struct igb_ring_desc_16_bytes *ring;
struct igb_ring_desc_16_bytes txd;
ring = (struct igb_ring_desc_16_bytes *)ring_mz->addr;
txd.lo_dword.dword = rte_le_to_cpu_64(ring[desc_id].lo_dword.dword);
txd.hi_dword.dword = rte_le_to_cpu_64(ring[desc_id].hi_dword.dword);
printf(" 0x%08X - 0x%08X / 0x%08X - 0x%08X\n",
(unsigned)txd.lo_dword.words.lo,
(unsigned)txd.lo_dword.words.hi,
(unsigned)txd.hi_dword.words.lo,
(unsigned)txd.hi_dword.words.hi);
}
void
rx_ring_desc_display(portid_t port_id, queueid_t rxq_id, uint16_t rxd_id)
{
const struct rte_memzone *rx_mz;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (rx_queue_id_is_invalid(rxq_id))
return;
if (rx_desc_id_is_invalid(rxd_id))
return;
rx_mz = ring_dma_zone_lookup("rx_ring", port_id, rxq_id);
if (rx_mz == NULL)
return;
ring_rx_descriptor_display(rx_mz, port_id, rxd_id);
}
void
tx_ring_desc_display(portid_t port_id, queueid_t txq_id, uint16_t txd_id)
{
const struct rte_memzone *tx_mz;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (tx_queue_id_is_invalid(txq_id))
return;
if (tx_desc_id_is_invalid(txd_id))
return;
tx_mz = ring_dma_zone_lookup("tx_ring", port_id, txq_id);
if (tx_mz == NULL)
return;
ring_tx_descriptor_display(tx_mz, txd_id);
}
void
fwd_lcores_config_display(void)
{
lcoreid_t lc_id;
printf("List of forwarding lcores:");
for (lc_id = 0; lc_id < nb_cfg_lcores; lc_id++)
printf(" %2u", fwd_lcores_cpuids[lc_id]);
printf("\n");
}
void
rxtx_config_display(void)
{
portid_t pid;
queueid_t qid;
printf(" %s packet forwarding%s packets/burst=%d\n",
cur_fwd_eng->fwd_mode_name,
retry_enabled == 0 ? "" : " with retry",
nb_pkt_per_burst);
if (cur_fwd_eng == &tx_only_engine || cur_fwd_eng == &flow_gen_engine)
printf(" packet len=%u - nb packet segments=%d\n",
(unsigned)tx_pkt_length, (int) tx_pkt_nb_segs);
printf(" nb forwarding cores=%d - nb forwarding ports=%d\n",
nb_fwd_lcores, nb_fwd_ports);
RTE_ETH_FOREACH_DEV(pid) {
struct rte_eth_rxconf *rx_conf = &ports[pid].rx_conf[0];
struct rte_eth_txconf *tx_conf = &ports[pid].tx_conf[0];
uint16_t *nb_rx_desc = &ports[pid].nb_rx_desc[0];
uint16_t *nb_tx_desc = &ports[pid].nb_tx_desc[0];
/* per port config */
printf(" port %d: RX queue number: %d Tx queue number: %d\n",
(unsigned int)pid, nb_rxq, nb_txq);
printf(" Rx offloads=0x%"PRIx64" Tx offloads=0x%"PRIx64"\n",
ports[pid].dev_conf.rxmode.offloads,
ports[pid].dev_conf.txmode.offloads);
/* per rx queue config only for first queue to be less verbose */
for (qid = 0; qid < 1; qid++) {
printf(" RX queue: %d\n", qid);
printf(" RX desc=%d - RX free threshold=%d\n",
nb_rx_desc[qid], rx_conf[qid].rx_free_thresh);
printf(" RX threshold registers: pthresh=%d hthresh=%d "
" wthresh=%d\n",
rx_conf[qid].rx_thresh.pthresh,
rx_conf[qid].rx_thresh.hthresh,
rx_conf[qid].rx_thresh.wthresh);
printf(" RX Offloads=0x%"PRIx64"\n",
rx_conf[qid].offloads);
}
/* per tx queue config only for first queue to be less verbose */
for (qid = 0; qid < 1; qid++) {
printf(" TX queue: %d\n", qid);
printf(" TX desc=%d - TX free threshold=%d\n",
nb_tx_desc[qid], tx_conf[qid].tx_free_thresh);
printf(" TX threshold registers: pthresh=%d hthresh=%d "
" wthresh=%d\n",
tx_conf[qid].tx_thresh.pthresh,
tx_conf[qid].tx_thresh.hthresh,
tx_conf[qid].tx_thresh.wthresh);
printf(" TX offloads=0x%"PRIx64" - TX RS bit threshold=%d\n",
tx_conf[qid].offloads, tx_conf->tx_rs_thresh);
}
}
}
void
port_rss_reta_info(portid_t port_id,
struct rte_eth_rss_reta_entry64 *reta_conf,
uint16_t nb_entries)
{
uint16_t i, idx, shift;
int ret;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
ret = rte_eth_dev_rss_reta_query(port_id, reta_conf, nb_entries);
if (ret != 0) {
printf("Failed to get RSS RETA info, return code = %d\n", ret);
return;
}
for (i = 0; i < nb_entries; i++) {
idx = i / RTE_RETA_GROUP_SIZE;
shift = i % RTE_RETA_GROUP_SIZE;
if (!(reta_conf[idx].mask & (1ULL << shift)))
continue;
printf("RSS RETA configuration: hash index=%u, queue=%u\n",
i, reta_conf[idx].reta[shift]);
}
}
/*
* Displays the RSS hash functions of a port, and, optionaly, the RSS hash
* key of the port.
*/
void
port_rss_hash_conf_show(portid_t port_id, char rss_info[], int show_rss_key)
{
struct rte_eth_rss_conf rss_conf;
uint8_t rss_key[RSS_HASH_KEY_LENGTH];
uint64_t rss_hf;
uint8_t i;
int diag;
struct rte_eth_dev_info dev_info;
uint8_t hash_key_size;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
memset(&dev_info, 0, sizeof(dev_info));
rte_eth_dev_info_get(port_id, &dev_info);
if (dev_info.hash_key_size > 0 &&
dev_info.hash_key_size <= sizeof(rss_key))
hash_key_size = dev_info.hash_key_size;
else {
printf("dev_info did not provide a valid hash key size\n");
return;
}
rss_conf.rss_hf = 0;
for (i = 0; rss_type_table[i].str; i++) {
if (!strcmp(rss_info, rss_type_table[i].str))
rss_conf.rss_hf = rss_type_table[i].rss_type;
}
/* Get RSS hash key if asked to display it */
rss_conf.rss_key = (show_rss_key) ? rss_key : NULL;
rss_conf.rss_key_len = hash_key_size;
diag = rte_eth_dev_rss_hash_conf_get(port_id, &rss_conf);
if (diag != 0) {
switch (diag) {
case -ENODEV:
printf("port index %d invalid\n", port_id);
break;
case -ENOTSUP:
printf("operation not supported by device\n");
break;
default:
printf("operation failed - diag=%d\n", diag);
break;
}
return;
}
rss_hf = rss_conf.rss_hf;
if (rss_hf == 0) {
printf("RSS disabled\n");
return;
}
printf("RSS functions:\n ");
for (i = 0; rss_type_table[i].str; i++) {
if (rss_hf & rss_type_table[i].rss_type)
printf("%s ", rss_type_table[i].str);
}
printf("\n");
if (!show_rss_key)
return;
printf("RSS key:\n");
for (i = 0; i < hash_key_size; i++)
printf("%02X", rss_key[i]);
printf("\n");
}
void
port_rss_hash_key_update(portid_t port_id, char rss_type[], uint8_t *hash_key,
uint hash_key_len)
{
struct rte_eth_rss_conf rss_conf;
int diag;
unsigned int i;
rss_conf.rss_key = NULL;
rss_conf.rss_key_len = hash_key_len;
rss_conf.rss_hf = 0;
for (i = 0; rss_type_table[i].str; i++) {
if (!strcmp(rss_type_table[i].str, rss_type))
rss_conf.rss_hf = rss_type_table[i].rss_type;
}
diag = rte_eth_dev_rss_hash_conf_get(port_id, &rss_conf);
if (diag == 0) {
rss_conf.rss_key = hash_key;
diag = rte_eth_dev_rss_hash_update(port_id, &rss_conf);
}
if (diag == 0)
return;
switch (diag) {
case -ENODEV:
printf("port index %d invalid\n", port_id);
break;
case -ENOTSUP:
printf("operation not supported by device\n");
break;
default:
printf("operation failed - diag=%d\n", diag);
break;
}
}
/*
* Setup forwarding configuration for each logical core.
*/
static void
setup_fwd_config_of_each_lcore(struct fwd_config *cfg)
{
streamid_t nb_fs_per_lcore;
streamid_t nb_fs;
streamid_t sm_id;
lcoreid_t nb_extra;
lcoreid_t nb_fc;
lcoreid_t nb_lc;
lcoreid_t lc_id;
nb_fs = cfg->nb_fwd_streams;
nb_fc = cfg->nb_fwd_lcores;
if (nb_fs <= nb_fc) {
nb_fs_per_lcore = 1;
nb_extra = 0;
} else {
nb_fs_per_lcore = (streamid_t) (nb_fs / nb_fc);
nb_extra = (lcoreid_t) (nb_fs % nb_fc);
}
nb_lc = (lcoreid_t) (nb_fc - nb_extra);
sm_id = 0;
for (lc_id = 0; lc_id < nb_lc; lc_id++) {
fwd_lcores[lc_id]->stream_idx = sm_id;
fwd_lcores[lc_id]->stream_nb = nb_fs_per_lcore;
sm_id = (streamid_t) (sm_id + nb_fs_per_lcore);
}
/*
* Assign extra remaining streams, if any.
*/
nb_fs_per_lcore = (streamid_t) (nb_fs_per_lcore + 1);
for (lc_id = 0; lc_id < nb_extra; lc_id++) {
fwd_lcores[nb_lc + lc_id]->stream_idx = sm_id;
fwd_lcores[nb_lc + lc_id]->stream_nb = nb_fs_per_lcore;
sm_id = (streamid_t) (sm_id + nb_fs_per_lcore);
}
}
static portid_t
fwd_topology_tx_port_get(portid_t rxp)
{
static int warning_once = 1;
RTE_ASSERT(rxp < cur_fwd_config.nb_fwd_ports);
switch (port_topology) {
default:
case PORT_TOPOLOGY_PAIRED:
if ((rxp & 0x1) == 0) {
if (rxp + 1 < cur_fwd_config.nb_fwd_ports)
return rxp + 1;
if (warning_once) {
printf("\nWarning! port-topology=paired"
" and odd forward ports number,"
" the last port will pair with"
" itself.\n\n");
warning_once = 0;
}
return rxp;
}
return rxp - 1;
case PORT_TOPOLOGY_CHAINED:
return (rxp + 1) % cur_fwd_config.nb_fwd_ports;
case PORT_TOPOLOGY_LOOP:
return rxp;
}
}
static void
simple_fwd_config_setup(void)
{
portid_t i;
cur_fwd_config.nb_fwd_ports = (portid_t) nb_fwd_ports;
cur_fwd_config.nb_fwd_streams =
(streamid_t) cur_fwd_config.nb_fwd_ports;
/* reinitialize forwarding streams */
init_fwd_streams();
/*
* In the simple forwarding test, the number of forwarding cores
* must be lower or equal to the number of forwarding ports.
*/
cur_fwd_config.nb_fwd_lcores = (lcoreid_t) nb_fwd_lcores;
if (cur_fwd_config.nb_fwd_lcores > cur_fwd_config.nb_fwd_ports)
cur_fwd_config.nb_fwd_lcores =
(lcoreid_t) cur_fwd_config.nb_fwd_ports;
setup_fwd_config_of_each_lcore(&cur_fwd_config);
for (i = 0; i < cur_fwd_config.nb_fwd_ports; i++) {
fwd_streams[i]->rx_port = fwd_ports_ids[i];
fwd_streams[i]->rx_queue = 0;
fwd_streams[i]->tx_port =
fwd_ports_ids[fwd_topology_tx_port_get(i)];
fwd_streams[i]->tx_queue = 0;
fwd_streams[i]->peer_addr = fwd_streams[i]->tx_port;
fwd_streams[i]->retry_enabled = retry_enabled;
}
}
/**
* For the RSS forwarding test all streams distributed over lcores. Each stream
* being composed of a RX queue to poll on a RX port for input messages,
* associated with a TX queue of a TX port where to send forwarded packets.
*/
static void
rss_fwd_config_setup(void)
{
portid_t rxp;
portid_t txp;
queueid_t rxq;
queueid_t nb_q;
streamid_t sm_id;
nb_q = nb_rxq;
if (nb_q > nb_txq)
nb_q = nb_txq;
cur_fwd_config.nb_fwd_lcores = (lcoreid_t) nb_fwd_lcores;
cur_fwd_config.nb_fwd_ports = nb_fwd_ports;
cur_fwd_config.nb_fwd_streams =
(streamid_t) (nb_q * cur_fwd_config.nb_fwd_ports);
if (cur_fwd_config.nb_fwd_streams < cur_fwd_config.nb_fwd_lcores)
cur_fwd_config.nb_fwd_lcores =
(lcoreid_t)cur_fwd_config.nb_fwd_streams;
/* reinitialize forwarding streams */
init_fwd_streams();
setup_fwd_config_of_each_lcore(&cur_fwd_config);
rxp = 0; rxq = 0;
for (sm_id = 0; sm_id < cur_fwd_config.nb_fwd_streams; sm_id++) {
struct fwd_stream *fs;
fs = fwd_streams[sm_id];
txp = fwd_topology_tx_port_get(rxp);
fs->rx_port = fwd_ports_ids[rxp];
fs->rx_queue = rxq;
fs->tx_port = fwd_ports_ids[txp];
fs->tx_queue = rxq;
fs->peer_addr = fs->tx_port;
fs->retry_enabled = retry_enabled;
rxq = (queueid_t) (rxq + 1);
if (rxq < nb_q)
continue;
/*
* rxq == nb_q
* Restart from RX queue 0 on next RX port
*/
rxq = 0;
rxp++;
}
}
/**
* For the DCB forwarding test, each core is assigned on each traffic class.
*
* Each core is assigned a multi-stream, each stream being composed of
* a RX queue to poll on a RX port for input messages, associated with
* a TX queue of a TX port where to send forwarded packets. All RX and
* TX queues are mapping to the same traffic class.
* If VMDQ and DCB co-exist, each traffic class on different POOLs share
* the same core
*/
static void
dcb_fwd_config_setup(void)
{
struct rte_eth_dcb_info rxp_dcb_info, txp_dcb_info;
portid_t txp, rxp = 0;
queueid_t txq, rxq = 0;
lcoreid_t lc_id;
uint16_t nb_rx_queue, nb_tx_queue;
uint16_t i, j, k, sm_id = 0;
uint8_t tc = 0;
cur_fwd_config.nb_fwd_lcores = (lcoreid_t) nb_fwd_lcores;
cur_fwd_config.nb_fwd_ports = nb_fwd_ports;
cur_fwd_config.nb_fwd_streams =
(streamid_t) (nb_rxq * cur_fwd_config.nb_fwd_ports);
/* reinitialize forwarding streams */
init_fwd_streams();
sm_id = 0;
txp = 1;
/* get the dcb info on the first RX and TX ports */
(void)rte_eth_dev_get_dcb_info(fwd_ports_ids[rxp], &rxp_dcb_info);
(void)rte_eth_dev_get_dcb_info(fwd_ports_ids[txp], &txp_dcb_info);
for (lc_id = 0; lc_id < cur_fwd_config.nb_fwd_lcores; lc_id++) {
fwd_lcores[lc_id]->stream_nb = 0;
fwd_lcores[lc_id]->stream_idx = sm_id;
for (i = 0; i < ETH_MAX_VMDQ_POOL; i++) {
/* if the nb_queue is zero, means this tc is
* not enabled on the POOL
*/
if (rxp_dcb_info.tc_queue.tc_rxq[i][tc].nb_queue == 0)
break;
k = fwd_lcores[lc_id]->stream_nb +
fwd_lcores[lc_id]->stream_idx;
rxq = rxp_dcb_info.tc_queue.tc_rxq[i][tc].base;
txq = txp_dcb_info.tc_queue.tc_txq[i][tc].base;
nb_rx_queue = txp_dcb_info.tc_queue.tc_rxq[i][tc].nb_queue;
nb_tx_queue = txp_dcb_info.tc_queue.tc_txq[i][tc].nb_queue;
for (j = 0; j < nb_rx_queue; j++) {
struct fwd_stream *fs;
fs = fwd_streams[k + j];
fs->rx_port = fwd_ports_ids[rxp];
fs->rx_queue = rxq + j;
fs->tx_port = fwd_ports_ids[txp];
fs->tx_queue = txq + j % nb_tx_queue;
fs->peer_addr = fs->tx_port;
fs->retry_enabled = retry_enabled;
}
fwd_lcores[lc_id]->stream_nb +=
rxp_dcb_info.tc_queue.tc_rxq[i][tc].nb_queue;
}
sm_id = (streamid_t) (sm_id + fwd_lcores[lc_id]->stream_nb);
tc++;
if (tc < rxp_dcb_info.nb_tcs)
continue;
/* Restart from TC 0 on next RX port */
tc = 0;
if (numa_support && (nb_fwd_ports <= (nb_ports >> 1)))
rxp = (portid_t)
(rxp + ((nb_ports >> 1) / nb_fwd_ports));
else
rxp++;
if (rxp >= nb_fwd_ports)
return;
/* get the dcb information on next RX and TX ports */
if ((rxp & 0x1) == 0)
txp = (portid_t) (rxp + 1);
else
txp = (portid_t) (rxp - 1);
rte_eth_dev_get_dcb_info(fwd_ports_ids[rxp], &rxp_dcb_info);
rte_eth_dev_get_dcb_info(fwd_ports_ids[txp], &txp_dcb_info);
}
}
app/testpmd: add engine that replies to ARP and ICMP echo requests Add a new specific packet processing engine in the "testpmd" application that only replies to ARP requests and to ICMP echo requests. For this purpose, a new "icmpecho" forwarding mode is provided that can be dynamically selected with the following testpmd command: set fwd icmpecho before starting the receipt of packets on the selected ports. Then, the "icmpecho" engine performs the following actions on all received packets: - replies to a received ARP request by sending back on the RX port a ARP reply with a "sender hardware address" field containing the MAC address of the RX port, - replies to a ICMP echo request by sending back on the RX port a ICMP echo reply, swapping the IP source and the IP destination address in the IP header, - otherwise, simply drops the received packet. When replying to a received packet that was encapsulated into a VLAN tunnel, the reply is sent back with the same VLAN identifier. By default, the testpmd configures VLAN header stripping RX option on each port. This option is not managed by the icmpecho engine which won't detect packets that were encapsulated into a VLAN. To address this issue, the VLAN header stripping option must be previously switched off with the following testpmd command: vlan set strip off When the "verbose" mode has been set with the testpmd command "set verbose 1", the "icmpecho" engine displays informations about each received packet. The "icmpecho" forwarding engine can also be used to simply check port connectivity at the hardware level (check that cables are well-plugged) and at the software level (receipt of VLAN packets, for instance). Signed-off-by: Ivan Boule <ivan.boule@6wind.com> Acked-by: Thomas Monjalon <thomas.monjalon@6wind.com>
2014-04-30 13:30:11 +00:00
static void
icmp_echo_config_setup(void)
{
portid_t rxp;
queueid_t rxq;
lcoreid_t lc_id;
uint16_t sm_id;
if ((nb_txq * nb_fwd_ports) < nb_fwd_lcores)
cur_fwd_config.nb_fwd_lcores = (lcoreid_t)
(nb_txq * nb_fwd_ports);
else
cur_fwd_config.nb_fwd_lcores = (lcoreid_t) nb_fwd_lcores;
cur_fwd_config.nb_fwd_ports = nb_fwd_ports;
cur_fwd_config.nb_fwd_streams =
(streamid_t) (nb_rxq * cur_fwd_config.nb_fwd_ports);
if (cur_fwd_config.nb_fwd_streams < cur_fwd_config.nb_fwd_lcores)
cur_fwd_config.nb_fwd_lcores =
(lcoreid_t)cur_fwd_config.nb_fwd_streams;
if (verbose_level > 0) {
printf("%s fwd_cores=%d fwd_ports=%d fwd_streams=%d\n",
__FUNCTION__,
cur_fwd_config.nb_fwd_lcores,
cur_fwd_config.nb_fwd_ports,
cur_fwd_config.nb_fwd_streams);
}
/* reinitialize forwarding streams */
init_fwd_streams();
setup_fwd_config_of_each_lcore(&cur_fwd_config);
rxp = 0; rxq = 0;
for (lc_id = 0; lc_id < cur_fwd_config.nb_fwd_lcores; lc_id++) {
if (verbose_level > 0)
printf(" core=%d: \n", lc_id);
for (sm_id = 0; sm_id < fwd_lcores[lc_id]->stream_nb; sm_id++) {
struct fwd_stream *fs;
fs = fwd_streams[fwd_lcores[lc_id]->stream_idx + sm_id];
fs->rx_port = fwd_ports_ids[rxp];
fs->rx_queue = rxq;
fs->tx_port = fs->rx_port;
fs->tx_queue = rxq;
app/testpmd: add engine that replies to ARP and ICMP echo requests Add a new specific packet processing engine in the "testpmd" application that only replies to ARP requests and to ICMP echo requests. For this purpose, a new "icmpecho" forwarding mode is provided that can be dynamically selected with the following testpmd command: set fwd icmpecho before starting the receipt of packets on the selected ports. Then, the "icmpecho" engine performs the following actions on all received packets: - replies to a received ARP request by sending back on the RX port a ARP reply with a "sender hardware address" field containing the MAC address of the RX port, - replies to a ICMP echo request by sending back on the RX port a ICMP echo reply, swapping the IP source and the IP destination address in the IP header, - otherwise, simply drops the received packet. When replying to a received packet that was encapsulated into a VLAN tunnel, the reply is sent back with the same VLAN identifier. By default, the testpmd configures VLAN header stripping RX option on each port. This option is not managed by the icmpecho engine which won't detect packets that were encapsulated into a VLAN. To address this issue, the VLAN header stripping option must be previously switched off with the following testpmd command: vlan set strip off When the "verbose" mode has been set with the testpmd command "set verbose 1", the "icmpecho" engine displays informations about each received packet. The "icmpecho" forwarding engine can also be used to simply check port connectivity at the hardware level (check that cables are well-plugged) and at the software level (receipt of VLAN packets, for instance). Signed-off-by: Ivan Boule <ivan.boule@6wind.com> Acked-by: Thomas Monjalon <thomas.monjalon@6wind.com>
2014-04-30 13:30:11 +00:00
fs->peer_addr = fs->tx_port;
fs->retry_enabled = retry_enabled;
app/testpmd: add engine that replies to ARP and ICMP echo requests Add a new specific packet processing engine in the "testpmd" application that only replies to ARP requests and to ICMP echo requests. For this purpose, a new "icmpecho" forwarding mode is provided that can be dynamically selected with the following testpmd command: set fwd icmpecho before starting the receipt of packets on the selected ports. Then, the "icmpecho" engine performs the following actions on all received packets: - replies to a received ARP request by sending back on the RX port a ARP reply with a "sender hardware address" field containing the MAC address of the RX port, - replies to a ICMP echo request by sending back on the RX port a ICMP echo reply, swapping the IP source and the IP destination address in the IP header, - otherwise, simply drops the received packet. When replying to a received packet that was encapsulated into a VLAN tunnel, the reply is sent back with the same VLAN identifier. By default, the testpmd configures VLAN header stripping RX option on each port. This option is not managed by the icmpecho engine which won't detect packets that were encapsulated into a VLAN. To address this issue, the VLAN header stripping option must be previously switched off with the following testpmd command: vlan set strip off When the "verbose" mode has been set with the testpmd command "set verbose 1", the "icmpecho" engine displays informations about each received packet. The "icmpecho" forwarding engine can also be used to simply check port connectivity at the hardware level (check that cables are well-plugged) and at the software level (receipt of VLAN packets, for instance). Signed-off-by: Ivan Boule <ivan.boule@6wind.com> Acked-by: Thomas Monjalon <thomas.monjalon@6wind.com>
2014-04-30 13:30:11 +00:00
if (verbose_level > 0)
printf(" stream=%d port=%d rxq=%d txq=%d\n",
sm_id, fs->rx_port, fs->rx_queue,
fs->tx_queue);
rxq = (queueid_t) (rxq + 1);
if (rxq == nb_rxq) {
rxq = 0;
rxp = (portid_t) (rxp + 1);
}
}
}
}
void
fwd_config_setup(void)
{
cur_fwd_config.fwd_eng = cur_fwd_eng;
app/testpmd: add engine that replies to ARP and ICMP echo requests Add a new specific packet processing engine in the "testpmd" application that only replies to ARP requests and to ICMP echo requests. For this purpose, a new "icmpecho" forwarding mode is provided that can be dynamically selected with the following testpmd command: set fwd icmpecho before starting the receipt of packets on the selected ports. Then, the "icmpecho" engine performs the following actions on all received packets: - replies to a received ARP request by sending back on the RX port a ARP reply with a "sender hardware address" field containing the MAC address of the RX port, - replies to a ICMP echo request by sending back on the RX port a ICMP echo reply, swapping the IP source and the IP destination address in the IP header, - otherwise, simply drops the received packet. When replying to a received packet that was encapsulated into a VLAN tunnel, the reply is sent back with the same VLAN identifier. By default, the testpmd configures VLAN header stripping RX option on each port. This option is not managed by the icmpecho engine which won't detect packets that were encapsulated into a VLAN. To address this issue, the VLAN header stripping option must be previously switched off with the following testpmd command: vlan set strip off When the "verbose" mode has been set with the testpmd command "set verbose 1", the "icmpecho" engine displays informations about each received packet. The "icmpecho" forwarding engine can also be used to simply check port connectivity at the hardware level (check that cables are well-plugged) and at the software level (receipt of VLAN packets, for instance). Signed-off-by: Ivan Boule <ivan.boule@6wind.com> Acked-by: Thomas Monjalon <thomas.monjalon@6wind.com>
2014-04-30 13:30:11 +00:00
if (strcmp(cur_fwd_eng->fwd_mode_name, "icmpecho") == 0) {
icmp_echo_config_setup();
return;
}
if ((nb_rxq > 1) && (nb_txq > 1)){
if (dcb_config)
dcb_fwd_config_setup();
else
rss_fwd_config_setup();
}
else
simple_fwd_config_setup();
}
void
pkt_fwd_config_display(struct fwd_config *cfg)
{
struct fwd_stream *fs;
lcoreid_t lc_id;
streamid_t sm_id;
printf("%s packet forwarding%s - ports=%d - cores=%d - streams=%d - "
"NUMA support %s, MP over anonymous pages %s\n",
cfg->fwd_eng->fwd_mode_name,
retry_enabled == 0 ? "" : " with retry",
cfg->nb_fwd_ports, cfg->nb_fwd_lcores, cfg->nb_fwd_streams,
numa_support == 1 ? "enabled" : "disabled",
mp_anon != 0 ? "enabled" : "disabled");
if (retry_enabled)
printf("TX retry num: %u, delay between TX retries: %uus\n",
burst_tx_retry_num, burst_tx_delay_time);
for (lc_id = 0; lc_id < cfg->nb_fwd_lcores; lc_id++) {
printf("Logical Core %u (socket %u) forwards packets on "
"%d streams:",
fwd_lcores_cpuids[lc_id],
rte_lcore_to_socket_id(fwd_lcores_cpuids[lc_id]),
fwd_lcores[lc_id]->stream_nb);
for (sm_id = 0; sm_id < fwd_lcores[lc_id]->stream_nb; sm_id++) {
fs = fwd_streams[fwd_lcores[lc_id]->stream_idx + sm_id];
printf("\n RX P=%d/Q=%d (socket %u) -> TX "
"P=%d/Q=%d (socket %u) ",
fs->rx_port, fs->rx_queue,
ports[fs->rx_port].socket_id,
fs->tx_port, fs->tx_queue,
ports[fs->tx_port].socket_id);
print_ethaddr("peer=",
&peer_eth_addrs[fs->peer_addr]);
}
printf("\n");
}
printf("\n");
}
void
set_fwd_eth_peer(portid_t port_id, char *peer_addr)
{
uint8_t c, new_peer_addr[6];
if (!rte_eth_dev_is_valid_port(port_id)) {
printf("Error: Invalid port number %i\n", port_id);
return;
}
if (cmdline_parse_etheraddr(NULL, peer_addr, &new_peer_addr,
sizeof(new_peer_addr)) < 0) {
printf("Error: Invalid ethernet address: %s\n", peer_addr);
return;
}
for (c = 0; c < 6; c++)
peer_eth_addrs[port_id].addr_bytes[c] =
new_peer_addr[c];
}
int
set_fwd_lcores_list(unsigned int *lcorelist, unsigned int nb_lc)
{
unsigned int i;
unsigned int lcore_cpuid;
int record_now;
record_now = 0;
again:
for (i = 0; i < nb_lc; i++) {
lcore_cpuid = lcorelist[i];
if (! rte_lcore_is_enabled(lcore_cpuid)) {
printf("lcore %u not enabled\n", lcore_cpuid);
return -1;
}
if (lcore_cpuid == rte_get_master_lcore()) {
printf("lcore %u cannot be masked on for running "
"packet forwarding, which is the master lcore "
"and reserved for command line parsing only\n",
lcore_cpuid);
return -1;
}
if (record_now)
fwd_lcores_cpuids[i] = lcore_cpuid;
}
if (record_now == 0) {
record_now = 1;
goto again;
}
nb_cfg_lcores = (lcoreid_t) nb_lc;
if (nb_fwd_lcores != (lcoreid_t) nb_lc) {
printf("previous number of forwarding cores %u - changed to "
"number of configured cores %u\n",
(unsigned int) nb_fwd_lcores, nb_lc);
nb_fwd_lcores = (lcoreid_t) nb_lc;
}
return 0;
}
int
set_fwd_lcores_mask(uint64_t lcoremask)
{
unsigned int lcorelist[64];
unsigned int nb_lc;
unsigned int i;
if (lcoremask == 0) {
printf("Invalid NULL mask of cores\n");
return -1;
}
nb_lc = 0;
for (i = 0; i < 64; i++) {
if (! ((uint64_t)(1ULL << i) & lcoremask))
continue;
lcorelist[nb_lc++] = i;
}
return set_fwd_lcores_list(lcorelist, nb_lc);
}
void
set_fwd_lcores_number(uint16_t nb_lc)
{
if (nb_lc > nb_cfg_lcores) {
printf("nb fwd cores %u > %u (max. number of configured "
"lcores) - ignored\n",
(unsigned int) nb_lc, (unsigned int) nb_cfg_lcores);
return;
}
nb_fwd_lcores = (lcoreid_t) nb_lc;
printf("Number of forwarding cores set to %u\n",
(unsigned int) nb_fwd_lcores);
}
void
set_fwd_ports_list(unsigned int *portlist, unsigned int nb_pt)
{
unsigned int i;
portid_t port_id;
int record_now;
record_now = 0;
again:
for (i = 0; i < nb_pt; i++) {
port_id = (portid_t) portlist[i];
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (record_now)
fwd_ports_ids[i] = port_id;
}
if (record_now == 0) {
record_now = 1;
goto again;
}
nb_cfg_ports = (portid_t) nb_pt;
if (nb_fwd_ports != (portid_t) nb_pt) {
printf("previous number of forwarding ports %u - changed to "
"number of configured ports %u\n",
(unsigned int) nb_fwd_ports, nb_pt);
nb_fwd_ports = (portid_t) nb_pt;
}
}
void
set_fwd_ports_mask(uint64_t portmask)
{
unsigned int portlist[64];
unsigned int nb_pt;
unsigned int i;
if (portmask == 0) {
printf("Invalid NULL mask of ports\n");
return;
}
nb_pt = 0;
RTE_ETH_FOREACH_DEV(i) {
if (! ((uint64_t)(1ULL << i) & portmask))
continue;
portlist[nb_pt++] = i;
}
set_fwd_ports_list(portlist, nb_pt);
}
void
set_fwd_ports_number(uint16_t nb_pt)
{
if (nb_pt > nb_cfg_ports) {
printf("nb fwd ports %u > %u (number of configured "
"ports) - ignored\n",
(unsigned int) nb_pt, (unsigned int) nb_cfg_ports);
return;
}
nb_fwd_ports = (portid_t) nb_pt;
printf("Number of forwarding ports set to %u\n",
(unsigned int) nb_fwd_ports);
}
int
port_is_forwarding(portid_t port_id)
{
unsigned int i;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return -1;
for (i = 0; i < nb_fwd_ports; i++) {
if (fwd_ports_ids[i] == port_id)
return 1;
}
return 0;
}
void
set_nb_pkt_per_burst(uint16_t nb)
{
if (nb > MAX_PKT_BURST) {
printf("nb pkt per burst: %u > %u (maximum packet per burst) "
" ignored\n",
(unsigned int) nb, (unsigned int) MAX_PKT_BURST);
return;
}
nb_pkt_per_burst = nb;
printf("Number of packets per burst set to %u\n",
(unsigned int) nb_pkt_per_burst);
}
static const char *
tx_split_get_name(enum tx_pkt_split split)
{
uint32_t i;
for (i = 0; i != RTE_DIM(tx_split_name); i++) {
if (tx_split_name[i].split == split)
return tx_split_name[i].name;
}
return NULL;
}
void
set_tx_pkt_split(const char *name)
{
uint32_t i;
for (i = 0; i != RTE_DIM(tx_split_name); i++) {
if (strcmp(tx_split_name[i].name, name) == 0) {
tx_pkt_split = tx_split_name[i].split;
return;
}
}
printf("unknown value: \"%s\"\n", name);
}
void
show_tx_pkt_segments(void)
{
uint32_t i, n;
const char *split;
n = tx_pkt_nb_segs;
split = tx_split_get_name(tx_pkt_split);
printf("Number of segments: %u\n", n);
printf("Segment sizes: ");
for (i = 0; i != n - 1; i++)
printf("%hu,", tx_pkt_seg_lengths[i]);
printf("%hu\n", tx_pkt_seg_lengths[i]);
printf("Split packet: %s\n", split);
}
void
set_tx_pkt_segments(unsigned *seg_lengths, unsigned nb_segs)
{
uint16_t tx_pkt_len;
unsigned i;
if (nb_segs >= (unsigned) nb_txd) {
printf("nb segments per TX packets=%u >= nb_txd=%u - ignored\n",
nb_segs, (unsigned int) nb_txd);
return;
}
/*
* Check that each segment length is greater or equal than
* the mbuf data sise.
* Check also that the total packet length is greater or equal than the
* size of an empty UDP/IP packet (sizeof(struct ether_hdr) + 20 + 8).
*/
tx_pkt_len = 0;
for (i = 0; i < nb_segs; i++) {
if (seg_lengths[i] > (unsigned) mbuf_data_size) {
printf("length[%u]=%u > mbuf_data_size=%u - give up\n",
i, seg_lengths[i], (unsigned) mbuf_data_size);
return;
}
tx_pkt_len = (uint16_t)(tx_pkt_len + seg_lengths[i]);
}
if (tx_pkt_len < (sizeof(struct ether_hdr) + 20 + 8)) {
printf("total packet length=%u < %d - give up\n",
(unsigned) tx_pkt_len,
(int)(sizeof(struct ether_hdr) + 20 + 8));
return;
}
for (i = 0; i < nb_segs; i++)
tx_pkt_seg_lengths[i] = (uint16_t) seg_lengths[i];
tx_pkt_length = tx_pkt_len;
tx_pkt_nb_segs = (uint8_t) nb_segs;
}
void
setup_gro(const char *onoff, portid_t port_id)
{
if (!rte_eth_dev_is_valid_port(port_id)) {
printf("invalid port id %u\n", port_id);
return;
}
if (test_done == 0) {
printf("Before enable/disable GRO,"
" please stop forwarding first\n");
return;
}
if (strcmp(onoff, "on") == 0) {
if (gro_ports[port_id].enable != 0) {
printf("Port %u has enabled GRO. Please"
" disable GRO first\n", port_id);
return;
}
if (gro_flush_cycles == GRO_DEFAULT_FLUSH_CYCLES) {
gro_ports[port_id].param.gro_types = RTE_GRO_TCP_IPV4;
gro_ports[port_id].param.max_flow_num =
GRO_DEFAULT_FLOW_NUM;
gro_ports[port_id].param.max_item_per_flow =
GRO_DEFAULT_ITEM_NUM_PER_FLOW;
}
gro_ports[port_id].enable = 1;
} else {
if (gro_ports[port_id].enable == 0) {
printf("Port %u has disabled GRO\n", port_id);
return;
}
gro_ports[port_id].enable = 0;
}
}
void
setup_gro_flush_cycles(uint8_t cycles)
{
if (test_done == 0) {
printf("Before change flush interval for GRO,"
" please stop forwarding first.\n");
return;
}
if (cycles > GRO_MAX_FLUSH_CYCLES || cycles <
GRO_DEFAULT_FLUSH_CYCLES) {
printf("The flushing cycle be in the range"
" of 1 to %u. Revert to the default"
" value %u.\n",
GRO_MAX_FLUSH_CYCLES,
GRO_DEFAULT_FLUSH_CYCLES);
cycles = GRO_DEFAULT_FLUSH_CYCLES;
}
gro_flush_cycles = cycles;
}
void
show_gro(portid_t port_id)
{
struct rte_gro_param *param;
uint32_t max_pkts_num;
param = &gro_ports[port_id].param;
if (!rte_eth_dev_is_valid_port(port_id)) {
printf("Invalid port id %u.\n", port_id);
return;
}
if (gro_ports[port_id].enable) {
printf("GRO type: TCP/IPv4\n");
if (gro_flush_cycles == GRO_DEFAULT_FLUSH_CYCLES) {
max_pkts_num = param->max_flow_num *
param->max_item_per_flow;
} else
max_pkts_num = MAX_PKT_BURST * GRO_MAX_FLUSH_CYCLES;
printf("Max number of packets to perform GRO: %u\n",
max_pkts_num);
printf("Flushing cycles: %u\n", gro_flush_cycles);
} else
printf("Port %u doesn't enable GRO.\n", port_id);
}
void
setup_gso(const char *mode, portid_t port_id)
{
if (!rte_eth_dev_is_valid_port(port_id)) {
printf("invalid port id %u\n", port_id);
return;
}
if (strcmp(mode, "on") == 0) {
if (test_done == 0) {
printf("before enabling GSO,"
" please stop forwarding first\n");
return;
}
gso_ports[port_id].enable = 1;
} else if (strcmp(mode, "off") == 0) {
if (test_done == 0) {
printf("before disabling GSO,"
" please stop forwarding first\n");
return;
}
gso_ports[port_id].enable = 0;
}
}
char*
list_pkt_forwarding_modes(void)
{
static char fwd_modes[128] = "";
const char *separator = "|";
struct fwd_engine *fwd_eng;
unsigned i = 0;
if (strlen (fwd_modes) == 0) {
while ((fwd_eng = fwd_engines[i++]) != NULL) {
strncat(fwd_modes, fwd_eng->fwd_mode_name,
sizeof(fwd_modes) - strlen(fwd_modes) - 1);
strncat(fwd_modes, separator,
sizeof(fwd_modes) - strlen(fwd_modes) - 1);
}
fwd_modes[strlen(fwd_modes) - strlen(separator)] = '\0';
}
return fwd_modes;
}
char*
list_pkt_forwarding_retry_modes(void)
{
static char fwd_modes[128] = "";
const char *separator = "|";
struct fwd_engine *fwd_eng;
unsigned i = 0;
if (strlen(fwd_modes) == 0) {
while ((fwd_eng = fwd_engines[i++]) != NULL) {
if (fwd_eng == &rx_only_engine)
continue;
strncat(fwd_modes, fwd_eng->fwd_mode_name,
sizeof(fwd_modes) -
strlen(fwd_modes) - 1);
strncat(fwd_modes, separator,
sizeof(fwd_modes) -
strlen(fwd_modes) - 1);
}
fwd_modes[strlen(fwd_modes) - strlen(separator)] = '\0';
}
return fwd_modes;
}
void
set_pkt_forwarding_mode(const char *fwd_mode_name)
{
struct fwd_engine *fwd_eng;
unsigned i;
i = 0;
while ((fwd_eng = fwd_engines[i]) != NULL) {
if (! strcmp(fwd_eng->fwd_mode_name, fwd_mode_name)) {
printf("Set %s packet forwarding mode%s\n",
fwd_mode_name,
retry_enabled == 0 ? "" : " with retry");
cur_fwd_eng = fwd_eng;
return;
}
i++;
}
printf("Invalid %s packet forwarding mode\n", fwd_mode_name);
}
void
set_verbose_level(uint16_t vb_level)
{
printf("Change verbose level from %u to %u\n",
(unsigned int) verbose_level, (unsigned int) vb_level);
verbose_level = vb_level;
}
void
vlan_extend_set(portid_t port_id, int on)
{
int diag;
int vlan_offload;
uint64_t port_rx_offloads = ports[port_id].dev_conf.rxmode.offloads;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
vlan_offload = rte_eth_dev_get_vlan_offload(port_id);
if (on) {
vlan_offload |= ETH_VLAN_EXTEND_OFFLOAD;
port_rx_offloads |= DEV_RX_OFFLOAD_VLAN_EXTEND;
} else {
vlan_offload &= ~ETH_VLAN_EXTEND_OFFLOAD;
port_rx_offloads &= ~DEV_RX_OFFLOAD_VLAN_EXTEND;
}
diag = rte_eth_dev_set_vlan_offload(port_id, vlan_offload);
if (diag < 0)
printf("rx_vlan_extend_set(port_pi=%d, on=%d) failed "
"diag=%d\n", port_id, on, diag);
ports[port_id].dev_conf.rxmode.offloads = port_rx_offloads;
}
void
rx_vlan_strip_set(portid_t port_id, int on)
{
int diag;
int vlan_offload;
uint64_t port_rx_offloads = ports[port_id].dev_conf.rxmode.offloads;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
vlan_offload = rte_eth_dev_get_vlan_offload(port_id);
if (on) {
vlan_offload |= ETH_VLAN_STRIP_OFFLOAD;
port_rx_offloads |= DEV_RX_OFFLOAD_VLAN_STRIP;
} else {
vlan_offload &= ~ETH_VLAN_STRIP_OFFLOAD;
port_rx_offloads &= ~DEV_RX_OFFLOAD_VLAN_STRIP;
}
diag = rte_eth_dev_set_vlan_offload(port_id, vlan_offload);
if (diag < 0)
printf("rx_vlan_strip_set(port_pi=%d, on=%d) failed "
"diag=%d\n", port_id, on, diag);
ports[port_id].dev_conf.rxmode.offloads = port_rx_offloads;
}
void
rx_vlan_strip_set_on_queue(portid_t port_id, uint16_t queue_id, int on)
{
int diag;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
diag = rte_eth_dev_set_vlan_strip_on_queue(port_id, queue_id, on);
if (diag < 0)
printf("rx_vlan_strip_set_on_queue(port_pi=%d, queue_id=%d, on=%d) failed "
"diag=%d\n", port_id, queue_id, on, diag);
}
void
rx_vlan_filter_set(portid_t port_id, int on)
{
int diag;
int vlan_offload;
uint64_t port_rx_offloads = ports[port_id].dev_conf.rxmode.offloads;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
vlan_offload = rte_eth_dev_get_vlan_offload(port_id);
if (on) {
vlan_offload |= ETH_VLAN_FILTER_OFFLOAD;
port_rx_offloads |= DEV_RX_OFFLOAD_VLAN_FILTER;
} else {
vlan_offload &= ~ETH_VLAN_FILTER_OFFLOAD;
port_rx_offloads &= ~DEV_RX_OFFLOAD_VLAN_FILTER;
}
diag = rte_eth_dev_set_vlan_offload(port_id, vlan_offload);
if (diag < 0)
printf("rx_vlan_filter_set(port_pi=%d, on=%d) failed "
"diag=%d\n", port_id, on, diag);
ports[port_id].dev_conf.rxmode.offloads = port_rx_offloads;
}
int
rx_vft_set(portid_t port_id, uint16_t vlan_id, int on)
{
int diag;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return 1;
if (vlan_id_is_invalid(vlan_id))
return 1;
diag = rte_eth_dev_vlan_filter(port_id, vlan_id, on);
if (diag == 0)
return 0;
printf("rte_eth_dev_vlan_filter(port_pi=%d, vlan_id=%d, on=%d) failed "
"diag=%d\n",
port_id, vlan_id, on, diag);
return -1;
}
void
rx_vlan_all_filter_set(portid_t port_id, int on)
{
uint16_t vlan_id;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
for (vlan_id = 0; vlan_id < 4096; vlan_id++) {
if (rx_vft_set(port_id, vlan_id, on))
break;
}
}
void
vlan_tpid_set(portid_t port_id, enum rte_vlan_type vlan_type, uint16_t tp_id)
{
int diag;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
diag = rte_eth_dev_set_vlan_ether_type(port_id, vlan_type, tp_id);
if (diag == 0)
return;
printf("tx_vlan_tpid_set(port_pi=%d, vlan_type=%d, tpid=%d) failed "
"diag=%d\n",
port_id, vlan_type, tp_id, diag);
}
void
tx_vlan_set(portid_t port_id, uint16_t vlan_id)
{
int vlan_offload;
struct rte_eth_dev_info dev_info;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (vlan_id_is_invalid(vlan_id))
return;
vlan_offload = rte_eth_dev_get_vlan_offload(port_id);
if (vlan_offload & ETH_VLAN_EXTEND_OFFLOAD) {
printf("Error, as QinQ has been enabled.\n");
return;
}
rte_eth_dev_info_get(port_id, &dev_info);
if ((dev_info.tx_offload_capa & DEV_TX_OFFLOAD_VLAN_INSERT) == 0) {
printf("Error: vlan insert is not supported by port %d\n",
port_id);
return;
}
tx_vlan_reset(port_id);
ports[port_id].dev_conf.txmode.offloads |= DEV_TX_OFFLOAD_VLAN_INSERT;
ports[port_id].tx_vlan_id = vlan_id;
}
void
tx_qinq_set(portid_t port_id, uint16_t vlan_id, uint16_t vlan_id_outer)
{
int vlan_offload;
struct rte_eth_dev_info dev_info;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (vlan_id_is_invalid(vlan_id))
return;
if (vlan_id_is_invalid(vlan_id_outer))
return;
vlan_offload = rte_eth_dev_get_vlan_offload(port_id);
if (!(vlan_offload & ETH_VLAN_EXTEND_OFFLOAD)) {
printf("Error, as QinQ hasn't been enabled.\n");
return;
}
rte_eth_dev_info_get(port_id, &dev_info);
if ((dev_info.tx_offload_capa & DEV_TX_OFFLOAD_QINQ_INSERT) == 0) {
printf("Error: qinq insert not supported by port %d\n",
port_id);
return;
}
tx_vlan_reset(port_id);
ports[port_id].dev_conf.txmode.offloads |= DEV_TX_OFFLOAD_QINQ_INSERT;
ports[port_id].tx_vlan_id = vlan_id;
ports[port_id].tx_vlan_id_outer = vlan_id_outer;
}
void
tx_vlan_reset(portid_t port_id)
{
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
ports[port_id].dev_conf.txmode.offloads &=
~(DEV_TX_OFFLOAD_VLAN_INSERT |
DEV_TX_OFFLOAD_QINQ_INSERT);
ports[port_id].tx_vlan_id = 0;
ports[port_id].tx_vlan_id_outer = 0;
}
void
tx_vlan_pvid_set(portid_t port_id, uint16_t vlan_id, int on)
{
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
rte_eth_dev_set_vlan_pvid(port_id, vlan_id, on);
}
void
set_qmap(portid_t port_id, uint8_t is_rx, uint16_t queue_id, uint8_t map_value)
{
uint16_t i;
uint8_t existing_mapping_found = 0;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
if (is_rx ? (rx_queue_id_is_invalid(queue_id)) : (tx_queue_id_is_invalid(queue_id)))
return;
if (map_value >= RTE_ETHDEV_QUEUE_STAT_CNTRS) {
printf("map_value not in required range 0..%d\n",
RTE_ETHDEV_QUEUE_STAT_CNTRS - 1);
return;
}
if (!is_rx) { /*then tx*/
for (i = 0; i < nb_tx_queue_stats_mappings; i++) {
if ((tx_queue_stats_mappings[i].port_id == port_id) &&
(tx_queue_stats_mappings[i].queue_id == queue_id)) {
tx_queue_stats_mappings[i].stats_counter_id = map_value;
existing_mapping_found = 1;
break;
}
}
if (!existing_mapping_found) { /* A new additional mapping... */
tx_queue_stats_mappings[nb_tx_queue_stats_mappings].port_id = port_id;
tx_queue_stats_mappings[nb_tx_queue_stats_mappings].queue_id = queue_id;
tx_queue_stats_mappings[nb_tx_queue_stats_mappings].stats_counter_id = map_value;
nb_tx_queue_stats_mappings++;
}
}
else { /*rx*/
for (i = 0; i < nb_rx_queue_stats_mappings; i++) {
if ((rx_queue_stats_mappings[i].port_id == port_id) &&
(rx_queue_stats_mappings[i].queue_id == queue_id)) {
rx_queue_stats_mappings[i].stats_counter_id = map_value;
existing_mapping_found = 1;
break;
}
}
if (!existing_mapping_found) { /* A new additional mapping... */
rx_queue_stats_mappings[nb_rx_queue_stats_mappings].port_id = port_id;
rx_queue_stats_mappings[nb_rx_queue_stats_mappings].queue_id = queue_id;
rx_queue_stats_mappings[nb_rx_queue_stats_mappings].stats_counter_id = map_value;
nb_rx_queue_stats_mappings++;
}
}
}
void
set_xstats_hide_zero(uint8_t on_off)
{
xstats_hide_zero = on_off;
}
static inline void
print_fdir_mask(struct rte_eth_fdir_masks *mask)
{
printf("\n vlan_tci: 0x%04x", rte_be_to_cpu_16(mask->vlan_tci_mask));
if (fdir_conf.mode == RTE_FDIR_MODE_PERFECT_TUNNEL)
printf(", mac_addr: 0x%02x, tunnel_type: 0x%01x,"
" tunnel_id: 0x%08x",
mask->mac_addr_byte_mask, mask->tunnel_type_mask,
rte_be_to_cpu_32(mask->tunnel_id_mask));
else if (fdir_conf.mode != RTE_FDIR_MODE_PERFECT_MAC_VLAN) {
printf(", src_ipv4: 0x%08x, dst_ipv4: 0x%08x",
rte_be_to_cpu_32(mask->ipv4_mask.src_ip),
rte_be_to_cpu_32(mask->ipv4_mask.dst_ip));
printf("\n src_port: 0x%04x, dst_port: 0x%04x",
rte_be_to_cpu_16(mask->src_port_mask),
rte_be_to_cpu_16(mask->dst_port_mask));
printf("\n src_ipv6: 0x%08x,0x%08x,0x%08x,0x%08x",
rte_be_to_cpu_32(mask->ipv6_mask.src_ip[0]),
rte_be_to_cpu_32(mask->ipv6_mask.src_ip[1]),
rte_be_to_cpu_32(mask->ipv6_mask.src_ip[2]),
rte_be_to_cpu_32(mask->ipv6_mask.src_ip[3]));
printf("\n dst_ipv6: 0x%08x,0x%08x,0x%08x,0x%08x",
rte_be_to_cpu_32(mask->ipv6_mask.dst_ip[0]),
rte_be_to_cpu_32(mask->ipv6_mask.dst_ip[1]),
rte_be_to_cpu_32(mask->ipv6_mask.dst_ip[2]),
rte_be_to_cpu_32(mask->ipv6_mask.dst_ip[3]));
}
printf("\n");
}
static inline void
print_fdir_flex_payload(struct rte_eth_fdir_flex_conf *flex_conf, uint32_t num)
{
struct rte_eth_flex_payload_cfg *cfg;
uint32_t i, j;
for (i = 0; i < flex_conf->nb_payloads; i++) {
cfg = &flex_conf->flex_set[i];
if (cfg->type == RTE_ETH_RAW_PAYLOAD)
printf("\n RAW: ");
else if (cfg->type == RTE_ETH_L2_PAYLOAD)
printf("\n L2_PAYLOAD: ");
else if (cfg->type == RTE_ETH_L3_PAYLOAD)
printf("\n L3_PAYLOAD: ");
else if (cfg->type == RTE_ETH_L4_PAYLOAD)
printf("\n L4_PAYLOAD: ");
else
printf("\n UNKNOWN PAYLOAD(%u): ", cfg->type);
for (j = 0; j < num; j++)
printf(" %-5u", cfg->src_offset[j]);
}
printf("\n");
}
static char *
flowtype_to_str(uint16_t flow_type)
{
struct flow_type_info {
char str[32];
uint16_t ftype;
};
uint8_t i;
static struct flow_type_info flowtype_str_table[] = {
{"raw", RTE_ETH_FLOW_RAW},
{"ipv4", RTE_ETH_FLOW_IPV4},
{"ipv4-frag", RTE_ETH_FLOW_FRAG_IPV4},
{"ipv4-tcp", RTE_ETH_FLOW_NONFRAG_IPV4_TCP},
{"ipv4-udp", RTE_ETH_FLOW_NONFRAG_IPV4_UDP},
{"ipv4-sctp", RTE_ETH_FLOW_NONFRAG_IPV4_SCTP},
{"ipv4-other", RTE_ETH_FLOW_NONFRAG_IPV4_OTHER},
{"ipv6", RTE_ETH_FLOW_IPV6},
{"ipv6-frag", RTE_ETH_FLOW_FRAG_IPV6},
{"ipv6-tcp", RTE_ETH_FLOW_NONFRAG_IPV6_TCP},
{"ipv6-udp", RTE_ETH_FLOW_NONFRAG_IPV6_UDP},
{"ipv6-sctp", RTE_ETH_FLOW_NONFRAG_IPV6_SCTP},
{"ipv6-other", RTE_ETH_FLOW_NONFRAG_IPV6_OTHER},
{"l2_payload", RTE_ETH_FLOW_L2_PAYLOAD},
{"port", RTE_ETH_FLOW_PORT},
{"vxlan", RTE_ETH_FLOW_VXLAN},
{"geneve", RTE_ETH_FLOW_GENEVE},
{"nvgre", RTE_ETH_FLOW_NVGRE},
};
for (i = 0; i < RTE_DIM(flowtype_str_table); i++) {
if (flowtype_str_table[i].ftype == flow_type)
return flowtype_str_table[i].str;
}
return NULL;
}
static inline void
print_fdir_flex_mask(struct rte_eth_fdir_flex_conf *flex_conf, uint32_t num)
{
struct rte_eth_fdir_flex_mask *mask;
uint32_t i, j;
char *p;
for (i = 0; i < flex_conf->nb_flexmasks; i++) {
mask = &flex_conf->flex_mask[i];
p = flowtype_to_str(mask->flow_type);
printf("\n %s:\t", p ? p : "unknown");
for (j = 0; j < num; j++)
printf(" %02x", mask->mask[j]);
}
printf("\n");
}
static inline void
print_fdir_flow_type(uint32_t flow_types_mask)
{
int i;
char *p;
for (i = RTE_ETH_FLOW_UNKNOWN; i < RTE_ETH_FLOW_MAX; i++) {
if (!(flow_types_mask & (1 << i)))
continue;
p = flowtype_to_str(i);
if (p)
printf(" %s", p);
else
printf(" unknown");
}
printf("\n");
}
void
fdir_get_infos(portid_t port_id)
{
struct rte_eth_fdir_stats fdir_stat;
struct rte_eth_fdir_info fdir_info;
int ret;
static const char *fdir_stats_border = "########################";
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
ret = rte_eth_dev_filter_supported(port_id, RTE_ETH_FILTER_FDIR);
if (ret < 0) {
printf("\n FDIR is not supported on port %-2d\n",
port_id);
return;
}
memset(&fdir_info, 0, sizeof(fdir_info));
rte_eth_dev_filter_ctrl(port_id, RTE_ETH_FILTER_FDIR,
RTE_ETH_FILTER_INFO, &fdir_info);
memset(&fdir_stat, 0, sizeof(fdir_stat));
rte_eth_dev_filter_ctrl(port_id, RTE_ETH_FILTER_FDIR,
RTE_ETH_FILTER_STATS, &fdir_stat);
printf("\n %s FDIR infos for port %-2d %s\n",
fdir_stats_border, port_id, fdir_stats_border);
printf(" MODE: ");
if (fdir_info.mode == RTE_FDIR_MODE_PERFECT)
printf(" PERFECT\n");
else if (fdir_info.mode == RTE_FDIR_MODE_PERFECT_MAC_VLAN)
printf(" PERFECT-MAC-VLAN\n");
else if (fdir_info.mode == RTE_FDIR_MODE_PERFECT_TUNNEL)
printf(" PERFECT-TUNNEL\n");
else if (fdir_info.mode == RTE_FDIR_MODE_SIGNATURE)
printf(" SIGNATURE\n");
else
printf(" DISABLE\n");
if (fdir_info.mode != RTE_FDIR_MODE_PERFECT_MAC_VLAN
&& fdir_info.mode != RTE_FDIR_MODE_PERFECT_TUNNEL) {
printf(" SUPPORTED FLOW TYPE: ");
print_fdir_flow_type(fdir_info.flow_types_mask[0]);
}
printf(" FLEX PAYLOAD INFO:\n");
printf(" max_len: %-10"PRIu32" payload_limit: %-10"PRIu32"\n"
" payload_unit: %-10"PRIu32" payload_seg: %-10"PRIu32"\n"
" bitmask_unit: %-10"PRIu32" bitmask_num: %-10"PRIu32"\n",
fdir_info.max_flexpayload, fdir_info.flex_payload_limit,
fdir_info.flex_payload_unit,
fdir_info.max_flex_payload_segment_num,
fdir_info.flex_bitmask_unit, fdir_info.max_flex_bitmask_num);
printf(" MASK: ");
print_fdir_mask(&fdir_info.mask);
if (fdir_info.flex_conf.nb_payloads > 0) {
printf(" FLEX PAYLOAD SRC OFFSET:");
print_fdir_flex_payload(&fdir_info.flex_conf, fdir_info.max_flexpayload);
}
if (fdir_info.flex_conf.nb_flexmasks > 0) {
printf(" FLEX MASK CFG:");
print_fdir_flex_mask(&fdir_info.flex_conf, fdir_info.max_flexpayload);
}
printf(" guarant_count: %-10"PRIu32" best_count: %"PRIu32"\n",
fdir_stat.guarant_cnt, fdir_stat.best_cnt);
printf(" guarant_space: %-10"PRIu32" best_space: %"PRIu32"\n",
fdir_info.guarant_spc, fdir_info.best_spc);
printf(" collision: %-10"PRIu32" free: %"PRIu32"\n"
" maxhash: %-10"PRIu32" maxlen: %"PRIu32"\n"
" add: %-10"PRIu64" remove: %"PRIu64"\n"
" f_add: %-10"PRIu64" f_remove: %"PRIu64"\n",
fdir_stat.collision, fdir_stat.free,
fdir_stat.maxhash, fdir_stat.maxlen,
fdir_stat.add, fdir_stat.remove,
fdir_stat.f_add, fdir_stat.f_remove);
printf(" %s############################%s\n",
fdir_stats_border, fdir_stats_border);
}
void
fdir_set_flex_mask(portid_t port_id, struct rte_eth_fdir_flex_mask *cfg)
{
struct rte_port *port;
struct rte_eth_fdir_flex_conf *flex_conf;
int i, idx = 0;
port = &ports[port_id];
flex_conf = &port->dev_conf.fdir_conf.flex_conf;
for (i = 0; i < RTE_ETH_FLOW_MAX; i++) {
if (cfg->flow_type == flex_conf->flex_mask[i].flow_type) {
idx = i;
break;
}
}
if (i >= RTE_ETH_FLOW_MAX) {
if (flex_conf->nb_flexmasks < RTE_DIM(flex_conf->flex_mask)) {
idx = flex_conf->nb_flexmasks;
flex_conf->nb_flexmasks++;
} else {
printf("The flex mask table is full. Can not set flex"
" mask for flow_type(%u).", cfg->flow_type);
return;
}
}
rte_memcpy(&flex_conf->flex_mask[idx],
cfg,
sizeof(struct rte_eth_fdir_flex_mask));
}
void
fdir_set_flex_payload(portid_t port_id, struct rte_eth_flex_payload_cfg *cfg)
{
struct rte_port *port;
struct rte_eth_fdir_flex_conf *flex_conf;
int i, idx = 0;
port = &ports[port_id];
flex_conf = &port->dev_conf.fdir_conf.flex_conf;
for (i = 0; i < RTE_ETH_PAYLOAD_MAX; i++) {
if (cfg->type == flex_conf->flex_set[i].type) {
idx = i;
break;
}
}
if (i >= RTE_ETH_PAYLOAD_MAX) {
if (flex_conf->nb_payloads < RTE_DIM(flex_conf->flex_set)) {
idx = flex_conf->nb_payloads;
flex_conf->nb_payloads++;
} else {
printf("The flex payload table is full. Can not set"
" flex payload for type(%u).", cfg->type);
return;
}
}
rte_memcpy(&flex_conf->flex_set[idx],
cfg,
sizeof(struct rte_eth_flex_payload_cfg));
}
void
set_vf_traffic(portid_t port_id, uint8_t is_rx, uint16_t vf, uint8_t on)
{
#ifdef RTE_LIBRTE_IXGBE_PMD
int diag;
if (is_rx)
diag = rte_pmd_ixgbe_set_vf_rx(port_id, vf, on);
else
diag = rte_pmd_ixgbe_set_vf_tx(port_id, vf, on);
if (diag == 0)
return;
printf("rte_pmd_ixgbe_set_vf_%s for port_id=%d failed diag=%d\n",
is_rx ? "rx" : "tx", port_id, diag);
return;
#endif
printf("VF %s setting not supported for port %d\n",
is_rx ? "Rx" : "Tx", port_id);
RTE_SET_USED(vf);
RTE_SET_USED(on);
}
int
set_queue_rate_limit(portid_t port_id, uint16_t queue_idx, uint16_t rate)
{
int diag;
struct rte_eth_link link;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return 1;
rte_eth_link_get_nowait(port_id, &link);
if (rate > link.link_speed) {
printf("Invalid rate value:%u bigger than link speed: %u\n",
rate, link.link_speed);
return 1;
}
diag = rte_eth_set_queue_rate_limit(port_id, queue_idx, rate);
if (diag == 0)
return diag;
printf("rte_eth_set_queue_rate_limit for port_id=%d failed diag=%d\n",
port_id, diag);
return diag;
}
int
set_vf_rate_limit(portid_t port_id, uint16_t vf, uint16_t rate, uint64_t q_msk)
{
int diag = -ENOTSUP;
RTE_SET_USED(vf);
RTE_SET_USED(rate);
RTE_SET_USED(q_msk);
#ifdef RTE_LIBRTE_IXGBE_PMD
if (diag == -ENOTSUP)
diag = rte_pmd_ixgbe_set_vf_rate_limit(port_id, vf, rate,
q_msk);
#endif
#ifdef RTE_LIBRTE_BNXT_PMD
if (diag == -ENOTSUP)
diag = rte_pmd_bnxt_set_vf_rate_limit(port_id, vf, rate, q_msk);
#endif
if (diag == 0)
return diag;
printf("set_vf_rate_limit for port_id=%d failed diag=%d\n",
port_id, diag);
return diag;
}
/*
* Functions to manage the set of filtered Multicast MAC addresses.
*
* A pool of filtered multicast MAC addresses is associated with each port.
* The pool is allocated in chunks of MCAST_POOL_INC multicast addresses.
* The address of the pool and the number of valid multicast MAC addresses
* recorded in the pool are stored in the fields "mc_addr_pool" and
* "mc_addr_nb" of the "rte_port" data structure.
*
* The function "rte_eth_dev_set_mc_addr_list" of the PMDs API imposes
* to be supplied a contiguous array of multicast MAC addresses.
* To comply with this constraint, the set of multicast addresses recorded
* into the pool are systematically compacted at the beginning of the pool.
* Hence, when a multicast address is removed from the pool, all following
* addresses, if any, are copied back to keep the set contiguous.
*/
#define MCAST_POOL_INC 32
static int
mcast_addr_pool_extend(struct rte_port *port)
{
struct ether_addr *mc_pool;
size_t mc_pool_size;
/*
* If a free entry is available at the end of the pool, just
* increment the number of recorded multicast addresses.
*/
if ((port->mc_addr_nb % MCAST_POOL_INC) != 0) {
port->mc_addr_nb++;
return 0;
}
/*
* [re]allocate a pool with MCAST_POOL_INC more entries.
* The previous test guarantees that port->mc_addr_nb is a multiple
* of MCAST_POOL_INC.
*/
mc_pool_size = sizeof(struct ether_addr) * (port->mc_addr_nb +
MCAST_POOL_INC);
mc_pool = (struct ether_addr *) realloc(port->mc_addr_pool,
mc_pool_size);
if (mc_pool == NULL) {
printf("allocation of pool of %u multicast addresses failed\n",
port->mc_addr_nb + MCAST_POOL_INC);
return -ENOMEM;
}
port->mc_addr_pool = mc_pool;
port->mc_addr_nb++;
return 0;
}
static void
mcast_addr_pool_remove(struct rte_port *port, uint32_t addr_idx)
{
port->mc_addr_nb--;
if (addr_idx == port->mc_addr_nb) {
/* No need to recompact the set of multicast addressses. */
if (port->mc_addr_nb == 0) {
/* free the pool of multicast addresses. */
free(port->mc_addr_pool);
port->mc_addr_pool = NULL;
}
return;
}
memmove(&port->mc_addr_pool[addr_idx],
&port->mc_addr_pool[addr_idx + 1],
sizeof(struct ether_addr) * (port->mc_addr_nb - addr_idx));
}
static void
eth_port_multicast_addr_list_set(portid_t port_id)
{
struct rte_port *port;
int diag;
port = &ports[port_id];
diag = rte_eth_dev_set_mc_addr_list(port_id, port->mc_addr_pool,
port->mc_addr_nb);
if (diag == 0)
return;
printf("rte_eth_dev_set_mc_addr_list(port=%d, nb=%u) failed. diag=%d\n",
port->mc_addr_nb, port_id, -diag);
}
void
mcast_addr_add(portid_t port_id, struct ether_addr *mc_addr)
{
struct rte_port *port;
uint32_t i;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
port = &ports[port_id];
/*
* Check that the added multicast MAC address is not already recorded
* in the pool of multicast addresses.
*/
for (i = 0; i < port->mc_addr_nb; i++) {
if (is_same_ether_addr(mc_addr, &port->mc_addr_pool[i])) {
printf("multicast address already filtered by port\n");
return;
}
}
if (mcast_addr_pool_extend(port) != 0)
return;
ether_addr_copy(mc_addr, &port->mc_addr_pool[i]);
eth_port_multicast_addr_list_set(port_id);
}
void
mcast_addr_remove(portid_t port_id, struct ether_addr *mc_addr)
{
struct rte_port *port;
uint32_t i;
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
port = &ports[port_id];
/*
* Search the pool of multicast MAC addresses for the removed address.
*/
for (i = 0; i < port->mc_addr_nb; i++) {
if (is_same_ether_addr(mc_addr, &port->mc_addr_pool[i]))
break;
}
if (i == port->mc_addr_nb) {
printf("multicast address not filtered by port %d\n", port_id);
return;
}
mcast_addr_pool_remove(port, i);
eth_port_multicast_addr_list_set(port_id);
}
void
port_dcb_info_display(portid_t port_id)
{
struct rte_eth_dcb_info dcb_info;
uint16_t i;
int ret;
static const char *border = "================";
if (port_id_is_invalid(port_id, ENABLED_WARN))
return;
ret = rte_eth_dev_get_dcb_info(port_id, &dcb_info);
if (ret) {
printf("\n Failed to get dcb infos on port %-2d\n",
port_id);
return;
}
printf("\n %s DCB infos for port %-2d %s\n", border, port_id, border);
printf(" TC NUMBER: %d\n", dcb_info.nb_tcs);
printf("\n TC : ");
for (i = 0; i < dcb_info.nb_tcs; i++)
printf("\t%4d", i);
printf("\n Priority : ");
for (i = 0; i < dcb_info.nb_tcs; i++)
printf("\t%4d", dcb_info.prio_tc[i]);
printf("\n BW percent :");
for (i = 0; i < dcb_info.nb_tcs; i++)
printf("\t%4d%%", dcb_info.tc_bws[i]);
printf("\n RXQ base : ");
for (i = 0; i < dcb_info.nb_tcs; i++)
printf("\t%4d", dcb_info.tc_queue.tc_rxq[0][i].base);
printf("\n RXQ number :");
for (i = 0; i < dcb_info.nb_tcs; i++)
printf("\t%4d", dcb_info.tc_queue.tc_rxq[0][i].nb_queue);
printf("\n TXQ base : ");
for (i = 0; i < dcb_info.nb_tcs; i++)
printf("\t%4d", dcb_info.tc_queue.tc_txq[0][i].base);
printf("\n TXQ number :");
for (i = 0; i < dcb_info.nb_tcs; i++)
printf("\t%4d", dcb_info.tc_queue.tc_txq[0][i].nb_queue);
printf("\n");
}
uint8_t *
open_file(const char *file_path, uint32_t *size)
{
int fd = open(file_path, O_RDONLY);
off_t pkg_size;
uint8_t *buf = NULL;
int ret = 0;
struct stat st_buf;
if (size)
*size = 0;
if (fd == -1) {
printf("%s: Failed to open %s\n", __func__, file_path);
return buf;
}
if ((fstat(fd, &st_buf) != 0) || (!S_ISREG(st_buf.st_mode))) {
close(fd);
printf("%s: File operations failed\n", __func__);
return buf;
}
pkg_size = st_buf.st_size;
if (pkg_size < 0) {
close(fd);
printf("%s: File operations failed\n", __func__);
return buf;
}
buf = (uint8_t *)malloc(pkg_size);
if (!buf) {
close(fd);
printf("%s: Failed to malloc memory\n", __func__);
return buf;
}
ret = read(fd, buf, pkg_size);
if (ret < 0) {
close(fd);
printf("%s: File read operation failed\n", __func__);
close_file(buf);
return NULL;
}
if (size)
*size = pkg_size;
close(fd);
return buf;
}
int
save_file(const char *file_path, uint8_t *buf, uint32_t size)
{
FILE *fh = fopen(file_path, "wb");
if (fh == NULL) {
printf("%s: Failed to open %s\n", __func__, file_path);
return -1;
}
if (fwrite(buf, 1, size, fh) != size) {
fclose(fh);
printf("%s: File write operation failed\n", __func__);
return -1;
}
fclose(fh);
return 0;
}
int
close_file(uint8_t *buf)
{
if (buf) {
free((void *)buf);
return 0;
}
return -1;
}
void
port_queue_region_info_display(portid_t port_id, void *buf)
{
#ifdef RTE_LIBRTE_I40E_PMD
uint16_t i, j;
struct rte_pmd_i40e_queue_regions *info =
(struct rte_pmd_i40e_queue_regions *)buf;
static const char *queue_region_info_stats_border = "-------";
if (!info->queue_region_number)
printf("there is no region has been set before");
printf("\n %s All queue region info for port=%2d %s",
queue_region_info_stats_border, port_id,
queue_region_info_stats_border);
printf("\n queue_region_number: %-14u \n",
info->queue_region_number);
for (i = 0; i < info->queue_region_number; i++) {
printf("\n region_id: %-14u queue_number: %-14u "
"queue_start_index: %-14u \n",
info->region[i].region_id,
info->region[i].queue_num,
info->region[i].queue_start_index);
printf(" user_priority_num is %-14u :",
info->region[i].user_priority_num);
for (j = 0; j < info->region[i].user_priority_num; j++)
printf(" %-14u ", info->region[i].user_priority[j]);
printf("\n flowtype_num is %-14u :",
info->region[i].flowtype_num);
for (j = 0; j < info->region[i].flowtype_num; j++)
printf(" %-14u ", info->region[i].hw_flowtype[j]);
}
#else
RTE_SET_USED(port_id);
RTE_SET_USED(buf);
#endif
printf("\n\n");
}