numam-dpdk/app/test-pmd/csumonly.c
Maxime Coquelin 9b4ea7ae77 app/testpmd: revert MAC update in checksum forwarding
This patch reverts
commit 10f4620f02 ("app/testpmd: modify mac in csum forwarding"),
as the checksum forwarding is expected to only perform
checksum and not also overwrites the source and destination MAC addresses.

Doing so, we can test checksum offloading with real traffic
without breaking broadcast packets.

Fixes: 10f4620f02 ("app/testpmd: modify mac in csum forwarding")
Cc: stable@dpdk.org

Signed-off-by: Maxime Coquelin <maxime.coquelin@redhat.com>
Acked-by: Chenbo Xia <chenbo.xia@intel.com>
Acked-by: Aman Singh <aman.deep.singh@intel.com>
2022-06-17 14:41:04 +02:00

1221 lines
33 KiB
C

/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2010-2014 Intel Corporation.
* Copyright 2014 6WIND S.A.
*/
#include <stdarg.h>
#include <stdio.h>
#include <errno.h>
#include <stdint.h>
#include <unistd.h>
#include <inttypes.h>
#include <sys/queue.h>
#include <sys/stat.h>
#include <rte_common.h>
#include <rte_byteorder.h>
#include <rte_log.h>
#include <rte_debug.h>
#include <rte_cycles.h>
#include <rte_memory.h>
#include <rte_memcpy.h>
#include <rte_launch.h>
#include <rte_eal.h>
#include <rte_per_lcore.h>
#include <rte_lcore.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_ip.h>
#include <rte_tcp.h>
#include <rte_udp.h>
#include <rte_vxlan.h>
#include <rte_sctp.h>
#include <rte_gtp.h>
#include <rte_prefetch.h>
#include <rte_string_fns.h>
#include <rte_flow.h>
#ifdef RTE_LIB_GRO
#include <rte_gro.h>
#endif
#ifdef RTE_LIB_GSO
#include <rte_gso.h>
#endif
#include <rte_geneve.h>
#include "testpmd.h"
#define IP_DEFTTL 64 /* from RFC 1340. */
#define GRE_CHECKSUM_PRESENT 0x8000
#define GRE_KEY_PRESENT 0x2000
#define GRE_SEQUENCE_PRESENT 0x1000
#define GRE_EXT_LEN 4
#define GRE_SUPPORTED_FIELDS (GRE_CHECKSUM_PRESENT | GRE_KEY_PRESENT |\
GRE_SEQUENCE_PRESENT)
/* We cannot use rte_cpu_to_be_16() on a constant in a switch/case */
#if RTE_BYTE_ORDER == RTE_LITTLE_ENDIAN
#define _htons(x) ((uint16_t)((((x) & 0x00ffU) << 8) | (((x) & 0xff00U) >> 8)))
#else
#define _htons(x) (x)
#endif
uint16_t vxlan_gpe_udp_port = RTE_VXLAN_GPE_DEFAULT_PORT;
uint16_t geneve_udp_port = RTE_GENEVE_DEFAULT_PORT;
/* structure that caches offload info for the current packet */
struct testpmd_offload_info {
uint16_t ethertype;
#ifdef RTE_LIB_GSO
uint8_t gso_enable;
#endif
uint16_t l2_len;
uint16_t l3_len;
uint16_t l4_len;
uint8_t l4_proto;
uint8_t is_tunnel;
uint16_t outer_ethertype;
uint16_t outer_l2_len;
uint16_t outer_l3_len;
uint8_t outer_l4_proto;
uint16_t tso_segsz;
uint16_t tunnel_tso_segsz;
uint32_t pkt_len;
};
/* simplified GRE header */
struct simple_gre_hdr {
uint16_t flags;
uint16_t proto;
} __rte_packed;
static uint16_t
get_udptcp_checksum(struct rte_mbuf *m, void *l3_hdr, uint16_t l4_off,
uint16_t ethertype)
{
if (ethertype == _htons(RTE_ETHER_TYPE_IPV4))
return rte_ipv4_udptcp_cksum_mbuf(m, l3_hdr, l4_off);
else /* assume ethertype == RTE_ETHER_TYPE_IPV6 */
return rte_ipv6_udptcp_cksum_mbuf(m, l3_hdr, l4_off);
}
/* Parse an IPv4 header to fill l3_len, l4_len, and l4_proto */
static void
parse_ipv4(struct rte_ipv4_hdr *ipv4_hdr, struct testpmd_offload_info *info)
{
struct rte_tcp_hdr *tcp_hdr;
info->l3_len = rte_ipv4_hdr_len(ipv4_hdr);
info->l4_proto = ipv4_hdr->next_proto_id;
/* only fill l4_len for TCP, it's useful for TSO */
if (info->l4_proto == IPPROTO_TCP) {
tcp_hdr = (struct rte_tcp_hdr *)
((char *)ipv4_hdr + info->l3_len);
info->l4_len = (tcp_hdr->data_off & 0xf0) >> 2;
} else if (info->l4_proto == IPPROTO_UDP)
info->l4_len = sizeof(struct rte_udp_hdr);
else
info->l4_len = 0;
}
/* Parse an IPv6 header to fill l3_len, l4_len, and l4_proto */
static void
parse_ipv6(struct rte_ipv6_hdr *ipv6_hdr, struct testpmd_offload_info *info)
{
struct rte_tcp_hdr *tcp_hdr;
info->l3_len = sizeof(struct rte_ipv6_hdr);
info->l4_proto = ipv6_hdr->proto;
/* only fill l4_len for TCP, it's useful for TSO */
if (info->l4_proto == IPPROTO_TCP) {
tcp_hdr = (struct rte_tcp_hdr *)
((char *)ipv6_hdr + info->l3_len);
info->l4_len = (tcp_hdr->data_off & 0xf0) >> 2;
} else if (info->l4_proto == IPPROTO_UDP)
info->l4_len = sizeof(struct rte_udp_hdr);
else
info->l4_len = 0;
}
/*
* Parse an ethernet header to fill the ethertype, l2_len, l3_len and
* ipproto. This function is able to recognize IPv4/IPv6 with optional VLAN
* headers. The l4_len argument is only set in case of TCP (useful for TSO).
*/
static void
parse_ethernet(struct rte_ether_hdr *eth_hdr, struct testpmd_offload_info *info)
{
struct rte_ipv4_hdr *ipv4_hdr;
struct rte_ipv6_hdr *ipv6_hdr;
struct rte_vlan_hdr *vlan_hdr;
info->l2_len = sizeof(struct rte_ether_hdr);
info->ethertype = eth_hdr->ether_type;
while (info->ethertype == _htons(RTE_ETHER_TYPE_VLAN) ||
info->ethertype == _htons(RTE_ETHER_TYPE_QINQ)) {
vlan_hdr = (struct rte_vlan_hdr *)
((char *)eth_hdr + info->l2_len);
info->l2_len += sizeof(struct rte_vlan_hdr);
info->ethertype = vlan_hdr->eth_proto;
}
switch (info->ethertype) {
case _htons(RTE_ETHER_TYPE_IPV4):
ipv4_hdr = (struct rte_ipv4_hdr *)
((char *)eth_hdr + info->l2_len);
parse_ipv4(ipv4_hdr, info);
break;
case _htons(RTE_ETHER_TYPE_IPV6):
ipv6_hdr = (struct rte_ipv6_hdr *)
((char *)eth_hdr + info->l2_len);
parse_ipv6(ipv6_hdr, info);
break;
default:
info->l4_len = 0;
info->l3_len = 0;
info->l4_proto = 0;
break;
}
}
/* Fill in outer layers length */
static void
update_tunnel_outer(struct testpmd_offload_info *info)
{
info->is_tunnel = 1;
info->outer_ethertype = info->ethertype;
info->outer_l2_len = info->l2_len;
info->outer_l3_len = info->l3_len;
info->outer_l4_proto = info->l4_proto;
}
/*
* Parse a GTP protocol header.
* No optional fields and next extension header type.
*/
static void
parse_gtp(struct rte_udp_hdr *udp_hdr,
struct testpmd_offload_info *info)
{
struct rte_ipv4_hdr *ipv4_hdr;
struct rte_ipv6_hdr *ipv6_hdr;
struct rte_gtp_hdr *gtp_hdr;
uint8_t gtp_len = sizeof(*gtp_hdr);
uint8_t ip_ver;
/* Check udp destination port. */
if (udp_hdr->dst_port != _htons(RTE_GTPC_UDP_PORT) &&
udp_hdr->src_port != _htons(RTE_GTPC_UDP_PORT) &&
udp_hdr->dst_port != _htons(RTE_GTPU_UDP_PORT))
return;
update_tunnel_outer(info);
info->l2_len = 0;
gtp_hdr = (struct rte_gtp_hdr *)((char *)udp_hdr +
sizeof(struct rte_udp_hdr));
if (gtp_hdr->e || gtp_hdr->s || gtp_hdr->pn)
gtp_len += sizeof(struct rte_gtp_hdr_ext_word);
/*
* Check message type. If message type is 0xff, it is
* a GTP data packet. If not, it is a GTP control packet
*/
if (gtp_hdr->msg_type == 0xff) {
ip_ver = *(uint8_t *)((char *)gtp_hdr + gtp_len);
ip_ver = (ip_ver) & 0xf0;
if (ip_ver == RTE_GTP_TYPE_IPV4) {
ipv4_hdr = (struct rte_ipv4_hdr *)((char *)gtp_hdr +
gtp_len);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV4);
parse_ipv4(ipv4_hdr, info);
} else if (ip_ver == RTE_GTP_TYPE_IPV6) {
ipv6_hdr = (struct rte_ipv6_hdr *)((char *)gtp_hdr +
gtp_len);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV6);
parse_ipv6(ipv6_hdr, info);
}
} else {
info->ethertype = 0;
info->l4_len = 0;
info->l3_len = 0;
info->l4_proto = 0;
}
info->l2_len += RTE_ETHER_GTP_HLEN;
}
/* Parse a vxlan header */
static void
parse_vxlan(struct rte_udp_hdr *udp_hdr,
struct testpmd_offload_info *info)
{
struct rte_ether_hdr *eth_hdr;
/* check udp destination port, RTE_VXLAN_DEFAULT_PORT (4789) is the
* default vxlan port (rfc7348) or that the rx offload flag is set
* (i40e only currently)
*/
if (udp_hdr->dst_port != _htons(RTE_VXLAN_DEFAULT_PORT))
return;
update_tunnel_outer(info);
eth_hdr = (struct rte_ether_hdr *)((char *)udp_hdr +
sizeof(struct rte_udp_hdr) +
sizeof(struct rte_vxlan_hdr));
parse_ethernet(eth_hdr, info);
info->l2_len += RTE_ETHER_VXLAN_HLEN; /* add udp + vxlan */
}
/* Parse a vxlan-gpe header */
static void
parse_vxlan_gpe(struct rte_udp_hdr *udp_hdr,
struct testpmd_offload_info *info)
{
struct rte_ether_hdr *eth_hdr;
struct rte_ipv4_hdr *ipv4_hdr;
struct rte_ipv6_hdr *ipv6_hdr;
struct rte_vxlan_gpe_hdr *vxlan_gpe_hdr;
uint8_t vxlan_gpe_len = sizeof(*vxlan_gpe_hdr);
/* Check udp destination port. */
if (udp_hdr->dst_port != _htons(vxlan_gpe_udp_port))
return;
vxlan_gpe_hdr = (struct rte_vxlan_gpe_hdr *)((char *)udp_hdr +
sizeof(struct rte_udp_hdr));
if (!vxlan_gpe_hdr->proto || vxlan_gpe_hdr->proto ==
RTE_VXLAN_GPE_TYPE_IPV4) {
update_tunnel_outer(info);
ipv4_hdr = (struct rte_ipv4_hdr *)((char *)vxlan_gpe_hdr +
vxlan_gpe_len);
parse_ipv4(ipv4_hdr, info);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV4);
info->l2_len = 0;
} else if (vxlan_gpe_hdr->proto == RTE_VXLAN_GPE_TYPE_IPV6) {
update_tunnel_outer(info);
ipv6_hdr = (struct rte_ipv6_hdr *)((char *)vxlan_gpe_hdr +
vxlan_gpe_len);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV6);
parse_ipv6(ipv6_hdr, info);
info->l2_len = 0;
} else if (vxlan_gpe_hdr->proto == RTE_VXLAN_GPE_TYPE_ETH) {
update_tunnel_outer(info);
eth_hdr = (struct rte_ether_hdr *)((char *)vxlan_gpe_hdr +
vxlan_gpe_len);
parse_ethernet(eth_hdr, info);
} else
return;
info->l2_len += RTE_ETHER_VXLAN_GPE_HLEN;
}
/* Parse a geneve header */
static void
parse_geneve(struct rte_udp_hdr *udp_hdr,
struct testpmd_offload_info *info)
{
struct rte_ether_hdr *eth_hdr;
struct rte_ipv4_hdr *ipv4_hdr;
struct rte_ipv6_hdr *ipv6_hdr;
struct rte_geneve_hdr *geneve_hdr;
uint16_t geneve_len;
/* Check udp destination port. */
if (udp_hdr->dst_port != _htons(geneve_udp_port))
return;
geneve_hdr = (struct rte_geneve_hdr *)((char *)udp_hdr +
sizeof(struct rte_udp_hdr));
geneve_len = sizeof(struct rte_geneve_hdr) + geneve_hdr->opt_len * 4;
if (!geneve_hdr->proto || geneve_hdr->proto ==
_htons(RTE_ETHER_TYPE_IPV4)) {
update_tunnel_outer(info);
ipv4_hdr = (struct rte_ipv4_hdr *)((char *)geneve_hdr +
geneve_len);
parse_ipv4(ipv4_hdr, info);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV4);
info->l2_len = 0;
} else if (geneve_hdr->proto == _htons(RTE_ETHER_TYPE_IPV6)) {
update_tunnel_outer(info);
ipv6_hdr = (struct rte_ipv6_hdr *)((char *)geneve_hdr +
geneve_len);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV6);
parse_ipv6(ipv6_hdr, info);
info->l2_len = 0;
} else if (geneve_hdr->proto == _htons(RTE_GENEVE_TYPE_ETH)) {
update_tunnel_outer(info);
eth_hdr = (struct rte_ether_hdr *)((char *)geneve_hdr +
geneve_len);
parse_ethernet(eth_hdr, info);
} else
return;
info->l2_len +=
(sizeof(struct rte_udp_hdr) + sizeof(struct rte_geneve_hdr) +
((struct rte_geneve_hdr *)geneve_hdr)->opt_len * 4);
}
/* Parse a gre header */
static void
parse_gre(struct simple_gre_hdr *gre_hdr, struct testpmd_offload_info *info)
{
struct rte_ether_hdr *eth_hdr;
struct rte_ipv4_hdr *ipv4_hdr;
struct rte_ipv6_hdr *ipv6_hdr;
uint8_t gre_len = 0;
gre_len += sizeof(struct simple_gre_hdr);
if (gre_hdr->flags & _htons(GRE_KEY_PRESENT))
gre_len += GRE_EXT_LEN;
if (gre_hdr->flags & _htons(GRE_SEQUENCE_PRESENT))
gre_len += GRE_EXT_LEN;
if (gre_hdr->flags & _htons(GRE_CHECKSUM_PRESENT))
gre_len += GRE_EXT_LEN;
if (gre_hdr->proto == _htons(RTE_ETHER_TYPE_IPV4)) {
update_tunnel_outer(info);
ipv4_hdr = (struct rte_ipv4_hdr *)((char *)gre_hdr + gre_len);
parse_ipv4(ipv4_hdr, info);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV4);
info->l2_len = 0;
} else if (gre_hdr->proto == _htons(RTE_ETHER_TYPE_IPV6)) {
update_tunnel_outer(info);
ipv6_hdr = (struct rte_ipv6_hdr *)((char *)gre_hdr + gre_len);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV6);
parse_ipv6(ipv6_hdr, info);
info->l2_len = 0;
} else if (gre_hdr->proto == _htons(RTE_ETHER_TYPE_TEB)) {
update_tunnel_outer(info);
eth_hdr = (struct rte_ether_hdr *)((char *)gre_hdr + gre_len);
parse_ethernet(eth_hdr, info);
} else
return;
info->l2_len += gre_len;
}
/* Parse an encapsulated ip or ipv6 header */
static void
parse_encap_ip(void *encap_ip, struct testpmd_offload_info *info)
{
struct rte_ipv4_hdr *ipv4_hdr = encap_ip;
struct rte_ipv6_hdr *ipv6_hdr = encap_ip;
uint8_t ip_version;
ip_version = (ipv4_hdr->version_ihl & 0xf0) >> 4;
if (ip_version != 4 && ip_version != 6)
return;
info->is_tunnel = 1;
info->outer_ethertype = info->ethertype;
info->outer_l2_len = info->l2_len;
info->outer_l3_len = info->l3_len;
if (ip_version == 4) {
parse_ipv4(ipv4_hdr, info);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV4);
} else {
parse_ipv6(ipv6_hdr, info);
info->ethertype = _htons(RTE_ETHER_TYPE_IPV6);
}
info->l2_len = 0;
}
/* if possible, calculate the checksum of a packet in hw or sw,
* depending on the testpmd command line configuration */
static uint64_t
process_inner_cksums(void *l3_hdr, const struct testpmd_offload_info *info,
uint64_t tx_offloads, struct rte_mbuf *m)
{
struct rte_ipv4_hdr *ipv4_hdr = l3_hdr;
struct rte_udp_hdr *udp_hdr;
struct rte_tcp_hdr *tcp_hdr;
struct rte_sctp_hdr *sctp_hdr;
uint64_t ol_flags = 0;
uint32_t max_pkt_len, tso_segsz = 0;
uint16_t l4_off;
/* ensure packet is large enough to require tso */
if (!info->is_tunnel) {
max_pkt_len = info->l2_len + info->l3_len + info->l4_len +
info->tso_segsz;
if (info->tso_segsz != 0 && info->pkt_len > max_pkt_len)
tso_segsz = info->tso_segsz;
} else {
max_pkt_len = info->outer_l2_len + info->outer_l3_len +
info->l2_len + info->l3_len + info->l4_len +
info->tunnel_tso_segsz;
if (info->tunnel_tso_segsz != 0 && info->pkt_len > max_pkt_len)
tso_segsz = info->tunnel_tso_segsz;
}
if (info->ethertype == _htons(RTE_ETHER_TYPE_IPV4)) {
ipv4_hdr = l3_hdr;
ol_flags |= RTE_MBUF_F_TX_IPV4;
if (info->l4_proto == IPPROTO_TCP && tso_segsz) {
ol_flags |= RTE_MBUF_F_TX_IP_CKSUM;
} else {
if (tx_offloads & RTE_ETH_TX_OFFLOAD_IPV4_CKSUM) {
ol_flags |= RTE_MBUF_F_TX_IP_CKSUM;
} else {
ipv4_hdr->hdr_checksum = 0;
ipv4_hdr->hdr_checksum =
rte_ipv4_cksum(ipv4_hdr);
}
}
} else if (info->ethertype == _htons(RTE_ETHER_TYPE_IPV6))
ol_flags |= RTE_MBUF_F_TX_IPV6;
else
return 0; /* packet type not supported, nothing to do */
if (info->l4_proto == IPPROTO_UDP) {
udp_hdr = (struct rte_udp_hdr *)((char *)l3_hdr + info->l3_len);
/* do not recalculate udp cksum if it was 0 */
if (udp_hdr->dgram_cksum != 0) {
if (tx_offloads & RTE_ETH_TX_OFFLOAD_UDP_CKSUM) {
ol_flags |= RTE_MBUF_F_TX_UDP_CKSUM;
} else {
if (info->is_tunnel)
l4_off = info->outer_l2_len +
info->outer_l3_len +
info->l2_len + info->l3_len;
else
l4_off = info->l2_len + info->l3_len;
udp_hdr->dgram_cksum = 0;
udp_hdr->dgram_cksum =
get_udptcp_checksum(m, l3_hdr, l4_off,
info->ethertype);
}
}
#ifdef RTE_LIB_GSO
if (info->gso_enable)
ol_flags |= RTE_MBUF_F_TX_UDP_SEG;
#endif
} else if (info->l4_proto == IPPROTO_TCP) {
tcp_hdr = (struct rte_tcp_hdr *)((char *)l3_hdr + info->l3_len);
if (tso_segsz)
ol_flags |= RTE_MBUF_F_TX_TCP_SEG;
else if (tx_offloads & RTE_ETH_TX_OFFLOAD_TCP_CKSUM) {
ol_flags |= RTE_MBUF_F_TX_TCP_CKSUM;
} else {
if (info->is_tunnel)
l4_off = info->outer_l2_len + info->outer_l3_len +
info->l2_len + info->l3_len;
else
l4_off = info->l2_len + info->l3_len;
tcp_hdr->cksum = 0;
tcp_hdr->cksum =
get_udptcp_checksum(m, l3_hdr, l4_off,
info->ethertype);
}
#ifdef RTE_LIB_GSO
if (info->gso_enable)
ol_flags |= RTE_MBUF_F_TX_TCP_SEG;
#endif
} else if (info->l4_proto == IPPROTO_SCTP) {
sctp_hdr = (struct rte_sctp_hdr *)
((char *)l3_hdr + info->l3_len);
/* sctp payload must be a multiple of 4 to be
* offloaded */
if ((tx_offloads & RTE_ETH_TX_OFFLOAD_SCTP_CKSUM) &&
((ipv4_hdr->total_length & 0x3) == 0)) {
ol_flags |= RTE_MBUF_F_TX_SCTP_CKSUM;
} else {
sctp_hdr->cksum = 0;
/* XXX implement CRC32c, example available in
* RFC3309 */
}
}
return ol_flags;
}
/* Calculate the checksum of outer header */
static uint64_t
process_outer_cksums(void *outer_l3_hdr, struct testpmd_offload_info *info,
uint64_t tx_offloads, int tso_enabled, struct rte_mbuf *m)
{
struct rte_ipv4_hdr *ipv4_hdr = outer_l3_hdr;
struct rte_ipv6_hdr *ipv6_hdr = outer_l3_hdr;
struct rte_udp_hdr *udp_hdr;
uint64_t ol_flags = 0;
if (info->outer_ethertype == _htons(RTE_ETHER_TYPE_IPV4)) {
ipv4_hdr->hdr_checksum = 0;
ol_flags |= RTE_MBUF_F_TX_OUTER_IPV4;
if (tx_offloads & RTE_ETH_TX_OFFLOAD_OUTER_IPV4_CKSUM)
ol_flags |= RTE_MBUF_F_TX_OUTER_IP_CKSUM;
else
ipv4_hdr->hdr_checksum = rte_ipv4_cksum(ipv4_hdr);
} else
ol_flags |= RTE_MBUF_F_TX_OUTER_IPV6;
if (info->outer_l4_proto != IPPROTO_UDP)
return ol_flags;
udp_hdr = (struct rte_udp_hdr *)
((char *)outer_l3_hdr + info->outer_l3_len);
if (tso_enabled)
ol_flags |= RTE_MBUF_F_TX_TCP_SEG;
/* Skip SW outer UDP checksum generation if HW supports it */
if (tx_offloads & RTE_ETH_TX_OFFLOAD_OUTER_UDP_CKSUM) {
if (info->outer_ethertype == _htons(RTE_ETHER_TYPE_IPV4))
udp_hdr->dgram_cksum
= rte_ipv4_phdr_cksum(ipv4_hdr, ol_flags);
else
udp_hdr->dgram_cksum
= rte_ipv6_phdr_cksum(ipv6_hdr, ol_flags);
ol_flags |= RTE_MBUF_F_TX_OUTER_UDP_CKSUM;
return ol_flags;
}
/* outer UDP checksum is done in software. In the other side, for
* UDP tunneling, like VXLAN or Geneve, outer UDP checksum can be
* set to zero.
*
* If a packet will be TSOed into small packets by NIC, we cannot
* set/calculate a non-zero checksum, because it will be a wrong
* value after the packet be split into several small packets.
*/
if (tso_enabled)
udp_hdr->dgram_cksum = 0;
/* do not recalculate udp cksum if it was 0 */
if (udp_hdr->dgram_cksum != 0) {
udp_hdr->dgram_cksum = 0;
udp_hdr->dgram_cksum = get_udptcp_checksum(m, outer_l3_hdr,
info->outer_l2_len + info->outer_l3_len,
info->outer_ethertype);
}
return ol_flags;
}
/*
* Helper function.
* Performs actual copying.
* Returns number of segments in the destination mbuf on success,
* or negative error code on failure.
*/
static int
mbuf_copy_split(const struct rte_mbuf *ms, struct rte_mbuf *md[],
uint16_t seglen[], uint8_t nb_seg)
{
uint32_t dlen, slen, tlen;
uint32_t i, len;
const struct rte_mbuf *m;
const uint8_t *src;
uint8_t *dst;
dlen = 0;
slen = 0;
tlen = 0;
dst = NULL;
src = NULL;
m = ms;
i = 0;
while (ms != NULL && i != nb_seg) {
if (slen == 0) {
slen = rte_pktmbuf_data_len(ms);
src = rte_pktmbuf_mtod(ms, const uint8_t *);
}
if (dlen == 0) {
dlen = RTE_MIN(seglen[i], slen);
md[i]->data_len = dlen;
md[i]->next = (i + 1 == nb_seg) ? NULL : md[i + 1];
dst = rte_pktmbuf_mtod(md[i], uint8_t *);
}
len = RTE_MIN(slen, dlen);
memcpy(dst, src, len);
tlen += len;
slen -= len;
dlen -= len;
src += len;
dst += len;
if (slen == 0)
ms = ms->next;
if (dlen == 0)
i++;
}
if (ms != NULL)
return -ENOBUFS;
else if (tlen != m->pkt_len)
return -EINVAL;
md[0]->nb_segs = nb_seg;
md[0]->pkt_len = tlen;
md[0]->vlan_tci = m->vlan_tci;
md[0]->vlan_tci_outer = m->vlan_tci_outer;
md[0]->ol_flags = m->ol_flags;
md[0]->tx_offload = m->tx_offload;
return nb_seg;
}
/*
* Allocate a new mbuf with up to tx_pkt_nb_segs segments.
* Copy packet contents and offload information into the new segmented mbuf.
*/
static struct rte_mbuf *
pkt_copy_split(const struct rte_mbuf *pkt)
{
int32_t n, rc;
uint32_t i, len, nb_seg;
struct rte_mempool *mp;
uint16_t seglen[RTE_MAX_SEGS_PER_PKT];
struct rte_mbuf *p, *md[RTE_MAX_SEGS_PER_PKT];
mp = current_fwd_lcore()->mbp;
if (tx_pkt_split == TX_PKT_SPLIT_RND)
nb_seg = rte_rand() % tx_pkt_nb_segs + 1;
else
nb_seg = tx_pkt_nb_segs;
memcpy(seglen, tx_pkt_seg_lengths, nb_seg * sizeof(seglen[0]));
/* calculate number of segments to use and their length. */
len = 0;
for (i = 0; i != nb_seg && len < pkt->pkt_len; i++) {
len += seglen[i];
md[i] = NULL;
}
n = pkt->pkt_len - len;
/* update size of the last segment to fit rest of the packet */
if (n >= 0) {
seglen[i - 1] += n;
len += n;
}
nb_seg = i;
while (i != 0) {
p = rte_pktmbuf_alloc(mp);
if (p == NULL) {
TESTPMD_LOG(ERR,
"failed to allocate %u-th of %u mbuf "
"from mempool: %s\n",
nb_seg - i, nb_seg, mp->name);
break;
}
md[--i] = p;
if (rte_pktmbuf_tailroom(md[i]) < seglen[i]) {
TESTPMD_LOG(ERR, "mempool %s, %u-th segment: "
"expected seglen: %u, "
"actual mbuf tailroom: %u\n",
mp->name, i, seglen[i],
rte_pktmbuf_tailroom(md[i]));
break;
}
}
/* all mbufs successfully allocated, do copy */
if (i == 0) {
rc = mbuf_copy_split(pkt, md, seglen, nb_seg);
if (rc < 0)
TESTPMD_LOG(ERR,
"mbuf_copy_split for %p(len=%u, nb_seg=%u) "
"into %u segments failed with error code: %d\n",
pkt, pkt->pkt_len, pkt->nb_segs, nb_seg, rc);
/* figure out how many mbufs to free. */
i = RTE_MAX(rc, 0);
}
/* free unused mbufs */
for (; i != nb_seg; i++) {
rte_pktmbuf_free_seg(md[i]);
md[i] = NULL;
}
return md[0];
}
#if defined(RTE_LIB_GRO) || defined(RTE_LIB_GSO)
/*
* Re-calculate IP checksum for merged/fragmented packets.
*/
static void
pkts_ip_csum_recalc(struct rte_mbuf **pkts_burst, const uint16_t nb_pkts, uint64_t tx_offloads)
{
int i;
struct rte_ipv4_hdr *ipv4_hdr;
for (i = 0; i < nb_pkts; i++) {
if ((pkts_burst[i]->ol_flags & RTE_MBUF_F_TX_IPV4) &&
(tx_offloads & RTE_ETH_TX_OFFLOAD_IPV4_CKSUM) == 0) {
ipv4_hdr = rte_pktmbuf_mtod_offset(pkts_burst[i],
struct rte_ipv4_hdr *,
pkts_burst[i]->l2_len);
ipv4_hdr->hdr_checksum = 0;
ipv4_hdr->hdr_checksum = rte_ipv4_cksum(ipv4_hdr);
}
}
}
#endif
/*
* Receive a burst of packets, and for each packet:
* - parse packet, and try to recognize a supported packet type (1)
* - if it's not a supported packet type, don't touch the packet, else:
* - reprocess the checksum of all supported layers. This is done in SW
* or HW, depending on testpmd command line configuration
* - if TSO is enabled in testpmd command line, also flag the mbuf for TCP
* segmentation offload (this implies HW TCP checksum)
* Then transmit packets on the output port.
*
* (1) Supported packets are:
* Ether / (vlan) / IP|IP6 / UDP|TCP|SCTP .
* Ether / (vlan) / outer IP|IP6 / outer UDP / VxLAN / Ether / IP|IP6 /
* UDP|TCP|SCTP
* Ether / (vlan) / outer IP|IP6 / outer UDP / VXLAN-GPE / Ether / IP|IP6 /
* UDP|TCP|SCTP
* Ether / (vlan) / outer IP|IP6 / outer UDP / VXLAN-GPE / IP|IP6 /
* UDP|TCP|SCTP
* Ether / (vlan) / outer IP / outer UDP / GTP / IP|IP6 / UDP|TCP|SCTP
* Ether / (vlan) / outer IP|IP6 / GRE / Ether / IP|IP6 / UDP|TCP|SCTP
* Ether / (vlan) / outer IP|IP6 / GRE / IP|IP6 / UDP|TCP|SCTP
* Ether / (vlan) / outer IP|IP6 / IP|IP6 / UDP|TCP|SCTP
*
* The testpmd command line for this forward engine sets the flags
* TESTPMD_TX_OFFLOAD_* in ports[tx_port].tx_ol_flags. They control
* whether a checksum must be calculated in software or in hardware. The
* IP, UDP, TCP and SCTP flags always concern the inner layer. The
* OUTER_IP is only useful for tunnel packets.
*/
static void
pkt_burst_checksum_forward(struct fwd_stream *fs)
{
struct rte_mbuf *pkts_burst[MAX_PKT_BURST];
#ifdef RTE_LIB_GSO
struct rte_mbuf *gso_segments[GSO_MAX_PKT_BURST];
struct rte_gso_ctx *gso_ctx;
#endif
struct rte_mbuf **tx_pkts_burst;
struct rte_port *txp;
struct rte_mbuf *m, *p;
struct rte_ether_hdr *eth_hdr;
void *l3_hdr = NULL, *outer_l3_hdr = NULL; /* can be IPv4 or IPv6 */
#ifdef RTE_LIB_GRO
void **gro_ctx;
uint16_t gro_pkts_num;
uint8_t gro_enable;
#endif
uint16_t nb_rx;
uint16_t nb_tx;
uint16_t nb_prep;
uint16_t i;
uint64_t rx_ol_flags, tx_ol_flags;
uint64_t tx_offloads;
uint32_t retry;
uint32_t rx_bad_ip_csum;
uint32_t rx_bad_l4_csum;
uint32_t rx_bad_outer_l4_csum;
uint32_t rx_bad_outer_ip_csum;
struct testpmd_offload_info info;
uint64_t start_tsc = 0;
get_start_cycles(&start_tsc);
/* receive a burst of packet */
nb_rx = rte_eth_rx_burst(fs->rx_port, fs->rx_queue, pkts_burst,
nb_pkt_per_burst);
inc_rx_burst_stats(fs, nb_rx);
if (unlikely(nb_rx == 0))
return;
fs->rx_packets += nb_rx;
rx_bad_ip_csum = 0;
rx_bad_l4_csum = 0;
rx_bad_outer_l4_csum = 0;
rx_bad_outer_ip_csum = 0;
#ifdef RTE_LIB_GRO
gro_enable = gro_ports[fs->rx_port].enable;
#endif
txp = &ports[fs->tx_port];
tx_offloads = txp->dev_conf.txmode.offloads;
memset(&info, 0, sizeof(info));
info.tso_segsz = txp->tso_segsz;
info.tunnel_tso_segsz = txp->tunnel_tso_segsz;
#ifdef RTE_LIB_GSO
if (gso_ports[fs->tx_port].enable)
info.gso_enable = 1;
#endif
for (i = 0; i < nb_rx; i++) {
if (likely(i < nb_rx - 1))
rte_prefetch0(rte_pktmbuf_mtod(pkts_burst[i + 1],
void *));
m = pkts_burst[i];
info.is_tunnel = 0;
info.pkt_len = rte_pktmbuf_pkt_len(m);
tx_ol_flags = m->ol_flags &
(RTE_MBUF_F_INDIRECT | RTE_MBUF_F_EXTERNAL);
rx_ol_flags = m->ol_flags;
/* Update the L3/L4 checksum error packet statistics */
if ((rx_ol_flags & RTE_MBUF_F_RX_IP_CKSUM_MASK) == RTE_MBUF_F_RX_IP_CKSUM_BAD)
rx_bad_ip_csum += 1;
if ((rx_ol_flags & RTE_MBUF_F_RX_L4_CKSUM_MASK) == RTE_MBUF_F_RX_L4_CKSUM_BAD)
rx_bad_l4_csum += 1;
if (rx_ol_flags & RTE_MBUF_F_RX_OUTER_L4_CKSUM_BAD)
rx_bad_outer_l4_csum += 1;
if (rx_ol_flags & RTE_MBUF_F_RX_OUTER_IP_CKSUM_BAD)
rx_bad_outer_ip_csum += 1;
/* step 1: dissect packet, parsing optional vlan, ip4/ip6, vxlan
* and inner headers */
eth_hdr = rte_pktmbuf_mtod(m, struct rte_ether_hdr *);
parse_ethernet(eth_hdr, &info);
l3_hdr = (char *)eth_hdr + info.l2_len;
/* check if it's a supported tunnel */
if (txp->parse_tunnel) {
if (info.l4_proto == IPPROTO_UDP) {
struct rte_udp_hdr *udp_hdr;
udp_hdr = (struct rte_udp_hdr *)
((char *)l3_hdr + info.l3_len);
parse_gtp(udp_hdr, &info);
if (info.is_tunnel) {
tx_ol_flags |= RTE_MBUF_F_TX_TUNNEL_GTP;
goto tunnel_update;
}
parse_vxlan_gpe(udp_hdr, &info);
if (info.is_tunnel) {
tx_ol_flags |=
RTE_MBUF_F_TX_TUNNEL_VXLAN_GPE;
goto tunnel_update;
}
parse_vxlan(udp_hdr, &info);
if (info.is_tunnel) {
tx_ol_flags |=
RTE_MBUF_F_TX_TUNNEL_VXLAN;
goto tunnel_update;
}
parse_geneve(udp_hdr, &info);
if (info.is_tunnel) {
tx_ol_flags |=
RTE_MBUF_F_TX_TUNNEL_GENEVE;
goto tunnel_update;
}
/* Always keep last. */
if (unlikely(RTE_ETH_IS_TUNNEL_PKT(
m->packet_type) != 0)) {
TESTPMD_LOG(DEBUG, "Unknown tunnel packet. UDP dst port: %hu",
udp_hdr->dst_port);
}
} else if (info.l4_proto == IPPROTO_GRE) {
struct simple_gre_hdr *gre_hdr;
gre_hdr = (struct simple_gre_hdr *)
((char *)l3_hdr + info.l3_len);
parse_gre(gre_hdr, &info);
if (info.is_tunnel)
tx_ol_flags |= RTE_MBUF_F_TX_TUNNEL_GRE;
} else if (info.l4_proto == IPPROTO_IPIP) {
void *encap_ip_hdr;
encap_ip_hdr = (char *)l3_hdr + info.l3_len;
parse_encap_ip(encap_ip_hdr, &info);
if (info.is_tunnel)
tx_ol_flags |= RTE_MBUF_F_TX_TUNNEL_IPIP;
}
}
tunnel_update:
/* update l3_hdr and outer_l3_hdr if a tunnel was parsed */
if (info.is_tunnel) {
outer_l3_hdr = l3_hdr;
l3_hdr = (char *)l3_hdr + info.outer_l3_len + info.l2_len;
}
/* step 2: depending on user command line configuration,
* recompute checksum either in software or flag the
* mbuf to offload the calculation to the NIC. If TSO
* is configured, prepare the mbuf for TCP segmentation. */
/* process checksums of inner headers first */
tx_ol_flags |= process_inner_cksums(l3_hdr, &info,
tx_offloads, m);
/* Then process outer headers if any. Note that the software
* checksum will be wrong if one of the inner checksums is
* processed in hardware. */
if (info.is_tunnel == 1) {
tx_ol_flags |= process_outer_cksums(outer_l3_hdr, &info,
tx_offloads,
!!(tx_ol_flags & RTE_MBUF_F_TX_TCP_SEG),
m);
}
/* step 3: fill the mbuf meta data (flags and header lengths) */
m->tx_offload = 0;
if (info.is_tunnel == 1) {
if (info.tunnel_tso_segsz ||
(tx_offloads &
RTE_ETH_TX_OFFLOAD_OUTER_IPV4_CKSUM) ||
(tx_offloads &
RTE_ETH_TX_OFFLOAD_OUTER_UDP_CKSUM)) {
m->outer_l2_len = info.outer_l2_len;
m->outer_l3_len = info.outer_l3_len;
m->l2_len = info.l2_len;
m->l3_len = info.l3_len;
m->l4_len = info.l4_len;
m->tso_segsz = info.tunnel_tso_segsz;
}
else {
/* if there is a outer UDP cksum
processed in sw and the inner in hw,
the outer checksum will be wrong as
the payload will be modified by the
hardware */
m->l2_len = info.outer_l2_len +
info.outer_l3_len + info.l2_len;
m->l3_len = info.l3_len;
m->l4_len = info.l4_len;
}
} else {
/* this is only useful if an offload flag is
* set, but it does not hurt to fill it in any
* case */
m->l2_len = info.l2_len;
m->l3_len = info.l3_len;
m->l4_len = info.l4_len;
m->tso_segsz = info.tso_segsz;
}
m->ol_flags = tx_ol_flags;
/* Do split & copy for the packet. */
if (tx_pkt_split != TX_PKT_SPLIT_OFF) {
p = pkt_copy_split(m);
if (p != NULL) {
rte_pktmbuf_free(m);
m = p;
pkts_burst[i] = m;
}
}
/* if verbose mode is enabled, dump debug info */
if (verbose_level > 0) {
char buf[256];
printf("-----------------\n");
printf("port=%u, mbuf=%p, pkt_len=%u, nb_segs=%u:\n",
fs->rx_port, m, m->pkt_len, m->nb_segs);
/* dump rx parsed packet info */
rte_get_rx_ol_flag_list(rx_ol_flags, buf, sizeof(buf));
printf("rx: l2_len=%d ethertype=%x l3_len=%d "
"l4_proto=%d l4_len=%d flags=%s\n",
info.l2_len, rte_be_to_cpu_16(info.ethertype),
info.l3_len, info.l4_proto, info.l4_len, buf);
if (rx_ol_flags & RTE_MBUF_F_RX_LRO)
printf("rx: m->lro_segsz=%u\n", m->tso_segsz);
if (info.is_tunnel == 1)
printf("rx: outer_l2_len=%d outer_ethertype=%x "
"outer_l3_len=%d\n", info.outer_l2_len,
rte_be_to_cpu_16(info.outer_ethertype),
info.outer_l3_len);
/* dump tx packet info */
if ((tx_offloads & (RTE_ETH_TX_OFFLOAD_IPV4_CKSUM |
RTE_ETH_TX_OFFLOAD_UDP_CKSUM |
RTE_ETH_TX_OFFLOAD_TCP_CKSUM |
RTE_ETH_TX_OFFLOAD_SCTP_CKSUM)) ||
info.tso_segsz != 0)
printf("tx: m->l2_len=%d m->l3_len=%d "
"m->l4_len=%d\n",
m->l2_len, m->l3_len, m->l4_len);
if (info.is_tunnel == 1) {
if ((tx_offloads &
RTE_ETH_TX_OFFLOAD_OUTER_IPV4_CKSUM) ||
(tx_offloads &
RTE_ETH_TX_OFFLOAD_OUTER_UDP_CKSUM) ||
(tx_ol_flags & RTE_MBUF_F_TX_OUTER_IPV6))
printf("tx: m->outer_l2_len=%d "
"m->outer_l3_len=%d\n",
m->outer_l2_len,
m->outer_l3_len);
if (info.tunnel_tso_segsz != 0 &&
(m->ol_flags & RTE_MBUF_F_TX_TCP_SEG))
printf("tx: m->tso_segsz=%d\n",
m->tso_segsz);
} else if (info.tso_segsz != 0 &&
(m->ol_flags & RTE_MBUF_F_TX_TCP_SEG))
printf("tx: m->tso_segsz=%d\n", m->tso_segsz);
rte_get_tx_ol_flag_list(m->ol_flags, buf, sizeof(buf));
printf("tx: flags=%s", buf);
printf("\n");
}
}
#ifdef RTE_LIB_GRO
if (unlikely(gro_enable)) {
if (gro_flush_cycles == GRO_DEFAULT_FLUSH_CYCLES) {
nb_rx = rte_gro_reassemble_burst(pkts_burst, nb_rx,
&(gro_ports[fs->rx_port].param));
} else {
gro_ctx = current_fwd_lcore()->gro_ctx;
nb_rx = rte_gro_reassemble(pkts_burst, nb_rx, gro_ctx);
if (++fs->gro_times >= gro_flush_cycles) {
gro_pkts_num = rte_gro_get_pkt_count(gro_ctx);
if (gro_pkts_num > MAX_PKT_BURST - nb_rx)
gro_pkts_num = MAX_PKT_BURST - nb_rx;
nb_rx += rte_gro_timeout_flush(gro_ctx, 0,
RTE_GRO_TCP_IPV4,
&pkts_burst[nb_rx],
gro_pkts_num);
fs->gro_times = 0;
}
}
pkts_ip_csum_recalc(pkts_burst, nb_rx, tx_offloads);
}
#endif
#ifdef RTE_LIB_GSO
if (gso_ports[fs->tx_port].enable != 0) {
uint16_t nb_segments = 0;
gso_ctx = &(current_fwd_lcore()->gso_ctx);
gso_ctx->gso_size = gso_max_segment_size;
for (i = 0; i < nb_rx; i++) {
int ret;
ret = rte_gso_segment(pkts_burst[i], gso_ctx,
&gso_segments[nb_segments],
GSO_MAX_PKT_BURST - nb_segments);
if (ret >= 1) {
/* pkts_burst[i] can be freed safely here. */
rte_pktmbuf_free(pkts_burst[i]);
nb_segments += ret;
} else if (ret == 0) {
/* 0 means it can be transmitted directly
* without gso.
*/
gso_segments[nb_segments] = pkts_burst[i];
nb_segments += 1;
} else {
TESTPMD_LOG(DEBUG, "Unable to segment packet");
rte_pktmbuf_free(pkts_burst[i]);
}
}
tx_pkts_burst = gso_segments;
nb_rx = nb_segments;
pkts_ip_csum_recalc(tx_pkts_burst, nb_rx, tx_offloads);
} else
#endif
tx_pkts_burst = pkts_burst;
nb_prep = rte_eth_tx_prepare(fs->tx_port, fs->tx_queue,
tx_pkts_burst, nb_rx);
if (nb_prep != nb_rx)
fprintf(stderr,
"Preparing packet burst to transmit failed: %s\n",
rte_strerror(rte_errno));
nb_tx = rte_eth_tx_burst(fs->tx_port, fs->tx_queue, tx_pkts_burst,
nb_prep);
/*
* Retry if necessary
*/
if (unlikely(nb_tx < nb_rx) && fs->retry_enabled) {
retry = 0;
while (nb_tx < nb_rx && retry++ < burst_tx_retry_num) {
rte_delay_us(burst_tx_delay_time);
nb_tx += rte_eth_tx_burst(fs->tx_port, fs->tx_queue,
&tx_pkts_burst[nb_tx], nb_rx - nb_tx);
}
}
fs->tx_packets += nb_tx;
fs->rx_bad_ip_csum += rx_bad_ip_csum;
fs->rx_bad_l4_csum += rx_bad_l4_csum;
fs->rx_bad_outer_l4_csum += rx_bad_outer_l4_csum;
fs->rx_bad_outer_ip_csum += rx_bad_outer_ip_csum;
inc_tx_burst_stats(fs, nb_tx);
if (unlikely(nb_tx < nb_rx)) {
fs->fwd_dropped += (nb_rx - nb_tx);
do {
rte_pktmbuf_free(tx_pkts_burst[nb_tx]);
} while (++nb_tx < nb_rx);
}
get_end_cycles(fs, start_tsc);
}
static void
stream_init_checksum_forward(struct fwd_stream *fs)
{
bool rx_stopped, tx_stopped;
rx_stopped = ports[fs->rx_port].rxq[fs->rx_queue].state ==
RTE_ETH_QUEUE_STATE_STOPPED;
tx_stopped = ports[fs->tx_port].txq[fs->tx_queue].state ==
RTE_ETH_QUEUE_STATE_STOPPED;
fs->disabled = rx_stopped || tx_stopped;
}
struct fwd_engine csum_fwd_engine = {
.fwd_mode_name = "csum",
.port_fwd_begin = NULL,
.port_fwd_end = NULL,
.stream_init = stream_init_checksum_forward,
.packet_fwd = pkt_burst_checksum_forward,
};