+ /* Validate/create attributes. */
+ [GROUP] = {
+ .name = "group",
+ .help = "specify a group",
+ .next = NEXT(next_vc_attr, NEXT_ENTRY(GROUP_ID)),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_attr, group)),
+ .call = parse_vc,
+ },
+ [PRIORITY] = {
+ .name = "priority",
+ .help = "specify a priority level",
+ .next = NEXT(next_vc_attr, NEXT_ENTRY(PRIORITY_LEVEL)),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_attr, priority)),
+ .call = parse_vc,
+ },
+ [INGRESS] = {
+ .name = "ingress",
+ .help = "affect rule to ingress",
+ .next = NEXT(next_vc_attr),
+ .call = parse_vc,
+ },
+ [EGRESS] = {
+ .name = "egress",
+ .help = "affect rule to egress",
+ .next = NEXT(next_vc_attr),
+ .call = parse_vc,
+ },
+ /* Validate/create pattern. */
+ [PATTERN] = {
+ .name = "pattern",
+ .help = "submit a list of pattern items",
+ .next = NEXT(next_item),
+ .call = parse_vc,
+ },
+ [ITEM_PARAM_IS] = {
+ .name = "is",
+ .help = "match value perfectly (with full bit-mask)",
+ .call = parse_vc_spec,
+ },
+ [ITEM_PARAM_SPEC] = {
+ .name = "spec",
+ .help = "match value according to configured bit-mask",
+ .call = parse_vc_spec,
+ },
+ [ITEM_PARAM_LAST] = {
+ .name = "last",
+ .help = "specify upper bound to establish a range",
+ .call = parse_vc_spec,
+ },
+ [ITEM_PARAM_MASK] = {
+ .name = "mask",
+ .help = "specify bit-mask with relevant bits set to one",
+ .call = parse_vc_spec,
+ },
+ [ITEM_PARAM_PREFIX] = {
+ .name = "prefix",
+ .help = "generate bit-mask from a prefix length",
+ .call = parse_vc_spec,
+ },
+ [ITEM_NEXT] = {
+ .name = "/",
+ .help = "specify next pattern item",
+ .next = NEXT(next_item),
+ },
+ [ITEM_END] = {
+ .name = "end",
+ .help = "end list of pattern items",
+ .priv = PRIV_ITEM(END, 0),
+ .next = NEXT(NEXT_ENTRY(ACTIONS)),
+ .call = parse_vc,
+ },
+ [ITEM_VOID] = {
+ .name = "void",
+ .help = "no-op pattern item",
+ .priv = PRIV_ITEM(VOID, 0),
+ .next = NEXT(NEXT_ENTRY(ITEM_NEXT)),
+ .call = parse_vc,
+ },
+ [ITEM_INVERT] = {
+ .name = "invert",
+ .help = "perform actions when pattern does not match",
+ .priv = PRIV_ITEM(INVERT, 0),
+ .next = NEXT(NEXT_ENTRY(ITEM_NEXT)),
+ .call = parse_vc,
+ },
+ [ITEM_ANY] = {
+ .name = "any",
+ .help = "match any protocol for the current layer",
+ .priv = PRIV_ITEM(ANY, sizeof(struct rte_flow_item_any)),
+ .next = NEXT(item_any),
+ .call = parse_vc,
+ },
+ [ITEM_ANY_NUM] = {
+ .name = "num",
+ .help = "number of layers covered",
+ .next = NEXT(item_any, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_item_any, num)),
+ },
+ [ITEM_PF] = {
+ .name = "pf",
+ .help = "match packets addressed to the physical function",
+ .priv = PRIV_ITEM(PF, 0),
+ .next = NEXT(NEXT_ENTRY(ITEM_NEXT)),
+ .call = parse_vc,
+ },
+ [ITEM_VF] = {
+ .name = "vf",
+ .help = "match packets addressed to a virtual function ID",
+ .priv = PRIV_ITEM(VF, sizeof(struct rte_flow_item_vf)),
+ .next = NEXT(item_vf),
+ .call = parse_vc,
+ },
+ [ITEM_VF_ID] = {
+ .name = "id",
+ .help = "destination VF ID",
+ .next = NEXT(item_vf, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_item_vf, id)),
+ },
+ [ITEM_PORT] = {
+ .name = "port",
+ .help = "device-specific physical port index to use",
+ .priv = PRIV_ITEM(PORT, sizeof(struct rte_flow_item_port)),
+ .next = NEXT(item_port),
+ .call = parse_vc,
+ },
+ [ITEM_PORT_INDEX] = {
+ .name = "index",
+ .help = "physical port index",
+ .next = NEXT(item_port, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_item_port, index)),
+ },
+ [ITEM_RAW] = {
+ .name = "raw",
+ .help = "match an arbitrary byte string",
+ .priv = PRIV_ITEM(RAW, ITEM_RAW_SIZE),
+ .next = NEXT(item_raw),
+ .call = parse_vc,
+ },
+ [ITEM_RAW_RELATIVE] = {
+ .name = "relative",
+ .help = "look for pattern after the previous item",
+ .next = NEXT(item_raw, NEXT_ENTRY(BOOLEAN), item_param),
+ .args = ARGS(ARGS_ENTRY_BF(struct rte_flow_item_raw,
+ relative, 1)),
+ },
+ [ITEM_RAW_SEARCH] = {
+ .name = "search",
+ .help = "search pattern from offset (see also limit)",
+ .next = NEXT(item_raw, NEXT_ENTRY(BOOLEAN), item_param),
+ .args = ARGS(ARGS_ENTRY_BF(struct rte_flow_item_raw,
+ search, 1)),
+ },
+ [ITEM_RAW_OFFSET] = {
+ .name = "offset",
+ .help = "absolute or relative offset for pattern",
+ .next = NEXT(item_raw, NEXT_ENTRY(INTEGER), item_param),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_item_raw, offset)),
+ },
+ [ITEM_RAW_LIMIT] = {
+ .name = "limit",
+ .help = "search area limit for start of pattern",
+ .next = NEXT(item_raw, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_item_raw, limit)),
+ },
+ [ITEM_RAW_PATTERN] = {
+ .name = "pattern",
+ .help = "byte string to look for",
+ .next = NEXT(item_raw,
+ NEXT_ENTRY(STRING),
+ NEXT_ENTRY(ITEM_PARAM_IS,
+ ITEM_PARAM_SPEC,
+ ITEM_PARAM_MASK)),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_item_raw, length),
+ ARGS_ENTRY_USZ(struct rte_flow_item_raw,
+ pattern,
+ ITEM_RAW_PATTERN_SIZE)),
+ },
+ [ITEM_ETH] = {
+ .name = "eth",
+ .help = "match Ethernet header",
+ .priv = PRIV_ITEM(ETH, sizeof(struct rte_flow_item_eth)),
+ .next = NEXT(item_eth),
+ .call = parse_vc,
+ },
+ [ITEM_ETH_DST] = {
+ .name = "dst",
+ .help = "destination MAC",
+ .next = NEXT(item_eth, NEXT_ENTRY(MAC_ADDR), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_eth, dst)),
+ },
+ [ITEM_ETH_SRC] = {
+ .name = "src",
+ .help = "source MAC",
+ .next = NEXT(item_eth, NEXT_ENTRY(MAC_ADDR), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_eth, src)),
+ },
+ [ITEM_ETH_TYPE] = {
+ .name = "type",
+ .help = "EtherType",
+ .next = NEXT(item_eth, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_eth, type)),
+ },
+ [ITEM_VLAN] = {
+ .name = "vlan",
+ .help = "match 802.1Q/ad VLAN tag",
+ .priv = PRIV_ITEM(VLAN, sizeof(struct rte_flow_item_vlan)),
+ .next = NEXT(item_vlan),
+ .call = parse_vc,
+ },
+ [ITEM_VLAN_TPID] = {
+ .name = "tpid",
+ .help = "tag protocol identifier",
+ .next = NEXT(item_vlan, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_vlan, tpid)),
+ },
+ [ITEM_VLAN_TCI] = {
+ .name = "tci",
+ .help = "tag control information",
+ .next = NEXT(item_vlan, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_vlan, tci)),
+ },
+ [ITEM_VLAN_PCP] = {
+ .name = "pcp",
+ .help = "priority code point",
+ .next = NEXT(item_vlan, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_MASK_HTON(struct rte_flow_item_vlan,
+ tci, "\xe0\x00")),
+ },
+ [ITEM_VLAN_DEI] = {
+ .name = "dei",
+ .help = "drop eligible indicator",
+ .next = NEXT(item_vlan, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_MASK_HTON(struct rte_flow_item_vlan,
+ tci, "\x10\x00")),
+ },
+ [ITEM_VLAN_VID] = {
+ .name = "vid",
+ .help = "VLAN identifier",
+ .next = NEXT(item_vlan, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_MASK_HTON(struct rte_flow_item_vlan,
+ tci, "\x0f\xff")),
+ },
+ [ITEM_IPV4] = {
+ .name = "ipv4",
+ .help = "match IPv4 header",
+ .priv = PRIV_ITEM(IPV4, sizeof(struct rte_flow_item_ipv4)),
+ .next = NEXT(item_ipv4),
+ .call = parse_vc,
+ },
+ [ITEM_IPV4_TOS] = {
+ .name = "tos",
+ .help = "type of service",
+ .next = NEXT(item_ipv4, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv4,
+ hdr.type_of_service)),
+ },
+ [ITEM_IPV4_TTL] = {
+ .name = "ttl",
+ .help = "time to live",
+ .next = NEXT(item_ipv4, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv4,
+ hdr.time_to_live)),
+ },
+ [ITEM_IPV4_PROTO] = {
+ .name = "proto",
+ .help = "next protocol ID",
+ .next = NEXT(item_ipv4, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv4,
+ hdr.next_proto_id)),
+ },
+ [ITEM_IPV4_SRC] = {
+ .name = "src",
+ .help = "source address",
+ .next = NEXT(item_ipv4, NEXT_ENTRY(IPV4_ADDR), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv4,
+ hdr.src_addr)),
+ },
+ [ITEM_IPV4_DST] = {
+ .name = "dst",
+ .help = "destination address",
+ .next = NEXT(item_ipv4, NEXT_ENTRY(IPV4_ADDR), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv4,
+ hdr.dst_addr)),
+ },
+ [ITEM_IPV6] = {
+ .name = "ipv6",
+ .help = "match IPv6 header",
+ .priv = PRIV_ITEM(IPV6, sizeof(struct rte_flow_item_ipv6)),
+ .next = NEXT(item_ipv6),
+ .call = parse_vc,
+ },
+ [ITEM_IPV6_TC] = {
+ .name = "tc",
+ .help = "traffic class",
+ .next = NEXT(item_ipv6, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_MASK_HTON(struct rte_flow_item_ipv6,
+ hdr.vtc_flow,
+ "\x0f\xf0\x00\x00")),
+ },
+ [ITEM_IPV6_FLOW] = {
+ .name = "flow",
+ .help = "flow label",
+ .next = NEXT(item_ipv6, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_MASK_HTON(struct rte_flow_item_ipv6,
+ hdr.vtc_flow,
+ "\x00\x0f\xff\xff")),
+ },
+ [ITEM_IPV6_PROTO] = {
+ .name = "proto",
+ .help = "protocol (next header)",
+ .next = NEXT(item_ipv6, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv6,
+ hdr.proto)),
+ },
+ [ITEM_IPV6_HOP] = {
+ .name = "hop",
+ .help = "hop limit",
+ .next = NEXT(item_ipv6, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv6,
+ hdr.hop_limits)),
+ },
+ [ITEM_IPV6_SRC] = {
+ .name = "src",
+ .help = "source address",
+ .next = NEXT(item_ipv6, NEXT_ENTRY(IPV6_ADDR), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv6,
+ hdr.src_addr)),
+ },
+ [ITEM_IPV6_DST] = {
+ .name = "dst",
+ .help = "destination address",
+ .next = NEXT(item_ipv6, NEXT_ENTRY(IPV6_ADDR), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_ipv6,
+ hdr.dst_addr)),
+ },
+ [ITEM_ICMP] = {
+ .name = "icmp",
+ .help = "match ICMP header",
+ .priv = PRIV_ITEM(ICMP, sizeof(struct rte_flow_item_icmp)),
+ .next = NEXT(item_icmp),
+ .call = parse_vc,
+ },
+ [ITEM_ICMP_TYPE] = {
+ .name = "type",
+ .help = "ICMP packet type",
+ .next = NEXT(item_icmp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_icmp,
+ hdr.icmp_type)),
+ },
+ [ITEM_ICMP_CODE] = {
+ .name = "code",
+ .help = "ICMP packet code",
+ .next = NEXT(item_icmp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_icmp,
+ hdr.icmp_code)),
+ },
+ [ITEM_UDP] = {
+ .name = "udp",
+ .help = "match UDP header",
+ .priv = PRIV_ITEM(UDP, sizeof(struct rte_flow_item_udp)),
+ .next = NEXT(item_udp),
+ .call = parse_vc,
+ },
+ [ITEM_UDP_SRC] = {
+ .name = "src",
+ .help = "UDP source port",
+ .next = NEXT(item_udp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_udp,
+ hdr.src_port)),
+ },
+ [ITEM_UDP_DST] = {
+ .name = "dst",
+ .help = "UDP destination port",
+ .next = NEXT(item_udp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_udp,
+ hdr.dst_port)),
+ },
+ [ITEM_TCP] = {
+ .name = "tcp",
+ .help = "match TCP header",
+ .priv = PRIV_ITEM(TCP, sizeof(struct rte_flow_item_tcp)),
+ .next = NEXT(item_tcp),
+ .call = parse_vc,
+ },
+ [ITEM_TCP_SRC] = {
+ .name = "src",
+ .help = "TCP source port",
+ .next = NEXT(item_tcp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_tcp,
+ hdr.src_port)),
+ },
+ [ITEM_TCP_DST] = {
+ .name = "dst",
+ .help = "TCP destination port",
+ .next = NEXT(item_tcp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_tcp,
+ hdr.dst_port)),
+ },
+ [ITEM_TCP_FLAGS] = {
+ .name = "flags",
+ .help = "TCP flags",
+ .next = NEXT(item_tcp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_tcp,
+ hdr.tcp_flags)),
+ },
+ [ITEM_SCTP] = {
+ .name = "sctp",
+ .help = "match SCTP header",
+ .priv = PRIV_ITEM(SCTP, sizeof(struct rte_flow_item_sctp)),
+ .next = NEXT(item_sctp),
+ .call = parse_vc,
+ },
+ [ITEM_SCTP_SRC] = {
+ .name = "src",
+ .help = "SCTP source port",
+ .next = NEXT(item_sctp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_sctp,
+ hdr.src_port)),
+ },
+ [ITEM_SCTP_DST] = {
+ .name = "dst",
+ .help = "SCTP destination port",
+ .next = NEXT(item_sctp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_sctp,
+ hdr.dst_port)),
+ },
+ [ITEM_SCTP_TAG] = {
+ .name = "tag",
+ .help = "validation tag",
+ .next = NEXT(item_sctp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_sctp,
+ hdr.tag)),
+ },
+ [ITEM_SCTP_CKSUM] = {
+ .name = "cksum",
+ .help = "checksum",
+ .next = NEXT(item_sctp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_sctp,
+ hdr.cksum)),
+ },
+ [ITEM_VXLAN] = {
+ .name = "vxlan",
+ .help = "match VXLAN header",
+ .priv = PRIV_ITEM(VXLAN, sizeof(struct rte_flow_item_vxlan)),
+ .next = NEXT(item_vxlan),
+ .call = parse_vc,
+ },
+ [ITEM_VXLAN_VNI] = {
+ .name = "vni",
+ .help = "VXLAN identifier",
+ .next = NEXT(item_vxlan, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_vxlan, vni)),
+ },
+ [ITEM_E_TAG] = {
+ .name = "e_tag",
+ .help = "match E-Tag header",
+ .priv = PRIV_ITEM(E_TAG, sizeof(struct rte_flow_item_e_tag)),
+ .next = NEXT(item_e_tag),
+ .call = parse_vc,
+ },
+ [ITEM_E_TAG_GRP_ECID_B] = {
+ .name = "grp_ecid_b",
+ .help = "GRP and E-CID base",
+ .next = NEXT(item_e_tag, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_MASK_HTON(struct rte_flow_item_e_tag,
+ rsvd_grp_ecid_b,
+ "\x3f\xff")),
+ },
+ [ITEM_NVGRE] = {
+ .name = "nvgre",
+ .help = "match NVGRE header",
+ .priv = PRIV_ITEM(NVGRE, sizeof(struct rte_flow_item_nvgre)),
+ .next = NEXT(item_nvgre),
+ .call = parse_vc,
+ },
+ [ITEM_NVGRE_TNI] = {
+ .name = "tni",
+ .help = "virtual subnet ID",
+ .next = NEXT(item_nvgre, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_nvgre, tni)),
+ },
+ [ITEM_MPLS] = {
+ .name = "mpls",
+ .help = "match MPLS header",
+ .priv = PRIV_ITEM(MPLS, sizeof(struct rte_flow_item_mpls)),
+ .next = NEXT(item_mpls),
+ .call = parse_vc,
+ },
+ [ITEM_MPLS_LABEL] = {
+ .name = "label",
+ .help = "MPLS label",
+ .next = NEXT(item_mpls, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_MASK_HTON(struct rte_flow_item_mpls,
+ label_tc_s,
+ "\xff\xff\xf0")),
+ },
+ [ITEM_GRE] = {
+ .name = "gre",
+ .help = "match GRE header",
+ .priv = PRIV_ITEM(GRE, sizeof(struct rte_flow_item_gre)),
+ .next = NEXT(item_gre),
+ .call = parse_vc,
+ },
+ [ITEM_GRE_PROTO] = {
+ .name = "protocol",
+ .help = "GRE protocol type",
+ .next = NEXT(item_gre, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_gre,
+ protocol)),
+ },
+ [ITEM_FUZZY] = {
+ .name = "fuzzy",
+ .help = "fuzzy pattern match, expect faster than default",
+ .priv = PRIV_ITEM(FUZZY,
+ sizeof(struct rte_flow_item_fuzzy)),
+ .next = NEXT(item_fuzzy),
+ .call = parse_vc,
+ },
+ [ITEM_FUZZY_THRESH] = {
+ .name = "thresh",
+ .help = "match accuracy threshold",
+ .next = NEXT(item_fuzzy, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_item_fuzzy,
+ thresh)),
+ },
+ [ITEM_GTP] = {
+ .name = "gtp",
+ .help = "match GTP header",
+ .priv = PRIV_ITEM(GTP, sizeof(struct rte_flow_item_gtp)),
+ .next = NEXT(item_gtp),
+ .call = parse_vc,
+ },
+ [ITEM_GTP_TEID] = {
+ .name = "teid",
+ .help = "tunnel endpoint identifier",
+ .next = NEXT(item_gtp, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_gtp, teid)),
+ },
+ [ITEM_GTPC] = {
+ .name = "gtpc",
+ .help = "match GTP header",
+ .priv = PRIV_ITEM(GTPC, sizeof(struct rte_flow_item_gtp)),
+ .next = NEXT(item_gtp),
+ .call = parse_vc,
+ },
+ [ITEM_GTPU] = {
+ .name = "gtpu",
+ .help = "match GTP header",
+ .priv = PRIV_ITEM(GTPU, sizeof(struct rte_flow_item_gtp)),
+ .next = NEXT(item_gtp),
+ .call = parse_vc,
+ },
+ [ITEM_GENEVE] = {
+ .name = "geneve",
+ .help = "match GENEVE header",
+ .priv = PRIV_ITEM(GENEVE, sizeof(struct rte_flow_item_geneve)),
+ .next = NEXT(item_geneve),
+ .call = parse_vc,
+ },
+ [ITEM_GENEVE_VNI] = {
+ .name = "vni",
+ .help = "virtual network identifier",
+ .next = NEXT(item_geneve, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_geneve, vni)),
+ },
+ [ITEM_GENEVE_PROTO] = {
+ .name = "protocol",
+ .help = "GENEVE protocol type",
+ .next = NEXT(item_geneve, NEXT_ENTRY(UNSIGNED), item_param),
+ .args = ARGS(ARGS_ENTRY_HTON(struct rte_flow_item_geneve,
+ protocol)),
+ },
+
+ /* Validate/create actions. */
+ [ACTIONS] = {
+ .name = "actions",
+ .help = "submit a list of associated actions",
+ .next = NEXT(next_action),
+ .call = parse_vc,
+ },
+ [ACTION_NEXT] = {
+ .name = "/",
+ .help = "specify next action",
+ .next = NEXT(next_action),
+ },
+ [ACTION_END] = {
+ .name = "end",
+ .help = "end list of actions",
+ .priv = PRIV_ACTION(END, 0),
+ .call = parse_vc,
+ },
+ [ACTION_VOID] = {
+ .name = "void",
+ .help = "no-op action",
+ .priv = PRIV_ACTION(VOID, 0),
+ .next = NEXT(NEXT_ENTRY(ACTION_NEXT)),
+ .call = parse_vc,
+ },
+ [ACTION_PASSTHRU] = {
+ .name = "passthru",
+ .help = "let subsequent rule process matched packets",
+ .priv = PRIV_ACTION(PASSTHRU, 0),
+ .next = NEXT(NEXT_ENTRY(ACTION_NEXT)),
+ .call = parse_vc,
+ },
+ [ACTION_MARK] = {
+ .name = "mark",
+ .help = "attach 32 bit value to packets",
+ .priv = PRIV_ACTION(MARK, sizeof(struct rte_flow_action_mark)),
+ .next = NEXT(action_mark),
+ .call = parse_vc,
+ },
+ [ACTION_MARK_ID] = {
+ .name = "id",
+ .help = "32 bit value to return with packets",
+ .next = NEXT(action_mark, NEXT_ENTRY(UNSIGNED)),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_action_mark, id)),
+ .call = parse_vc_conf,
+ },
+ [ACTION_FLAG] = {
+ .name = "flag",
+ .help = "flag packets",
+ .priv = PRIV_ACTION(FLAG, 0),
+ .next = NEXT(NEXT_ENTRY(ACTION_NEXT)),
+ .call = parse_vc,
+ },
+ [ACTION_QUEUE] = {
+ .name = "queue",
+ .help = "assign packets to a given queue index",
+ .priv = PRIV_ACTION(QUEUE,
+ sizeof(struct rte_flow_action_queue)),
+ .next = NEXT(action_queue),
+ .call = parse_vc,
+ },
+ [ACTION_QUEUE_INDEX] = {
+ .name = "index",
+ .help = "queue index to use",
+ .next = NEXT(action_queue, NEXT_ENTRY(UNSIGNED)),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_action_queue, index)),
+ .call = parse_vc_conf,
+ },
+ [ACTION_DROP] = {
+ .name = "drop",
+ .help = "drop packets (note: passthru has priority)",
+ .priv = PRIV_ACTION(DROP, 0),
+ .next = NEXT(NEXT_ENTRY(ACTION_NEXT)),
+ .call = parse_vc,
+ },
+ [ACTION_COUNT] = {
+ .name = "count",
+ .help = "enable counters for this rule",
+ .priv = PRIV_ACTION(COUNT, 0),
+ .next = NEXT(NEXT_ENTRY(ACTION_NEXT)),
+ .call = parse_vc,
+ },
+ [ACTION_DUP] = {
+ .name = "dup",
+ .help = "duplicate packets to a given queue index",
+ .priv = PRIV_ACTION(DUP, sizeof(struct rte_flow_action_dup)),
+ .next = NEXT(action_dup),
+ .call = parse_vc,
+ },
+ [ACTION_DUP_INDEX] = {
+ .name = "index",
+ .help = "queue index to duplicate packets to",
+ .next = NEXT(action_dup, NEXT_ENTRY(UNSIGNED)),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_action_dup, index)),
+ .call = parse_vc_conf,
+ },
+ [ACTION_RSS] = {
+ .name = "rss",
+ .help = "spread packets among several queues",
+ .priv = PRIV_ACTION(RSS, sizeof(union action_rss_data)),
+ .next = NEXT(action_rss),
+ .call = parse_vc_action_rss,
+ },
+ [ACTION_RSS_TYPES] = {
+ .name = "types",
+ .help = "RSS hash types",
+ .next = NEXT(action_rss, NEXT_ENTRY(ACTION_RSS_TYPE)),
+ },
+ [ACTION_RSS_TYPE] = {
+ .name = "{type}",
+ .help = "RSS hash type",
+ .call = parse_vc_action_rss_type,
+ .comp = comp_vc_action_rss_type,
+ },
+ [ACTION_RSS_KEY] = {
+ .name = "key",
+ .help = "RSS hash key",
+ .next = NEXT(action_rss, NEXT_ENTRY(STRING)),
+ .args = ARGS(ARGS_ENTRY_ARB
+ (((uintptr_t)&((union action_rss_data *)0)->
+ s.rss_conf.rss_key_len),
+ sizeof(((struct rte_eth_rss_conf *)0)->
+ rss_key_len)),
+ ARGS_ENTRY_ARB
+ (((uintptr_t)((union action_rss_data *)0)->
+ s.rss_key),
+ RSS_HASH_KEY_LENGTH)),
+ },
+ [ACTION_RSS_KEY_LEN] = {
+ .name = "key_len",
+ .help = "RSS hash key length in bytes",
+ .next = NEXT(action_rss, NEXT_ENTRY(UNSIGNED)),
+ .args = ARGS(ARGS_ENTRY_ARB_BOUNDED
+ (((uintptr_t)&((union action_rss_data *)0)->
+ s.rss_conf.rss_key_len),
+ sizeof(((struct rte_eth_rss_conf *)0)->
+ rss_key_len),
+ 0,
+ RSS_HASH_KEY_LENGTH)),
+ },
+ [ACTION_RSS_QUEUES] = {
+ .name = "queues",
+ .help = "queue indices to use",
+ .next = NEXT(action_rss, NEXT_ENTRY(ACTION_RSS_QUEUE)),
+ .call = parse_vc_conf,
+ },
+ [ACTION_RSS_QUEUE] = {
+ .name = "{queue}",
+ .help = "queue index",
+ .call = parse_vc_action_rss_queue,
+ .comp = comp_vc_action_rss_queue,
+ },
+ [ACTION_PF] = {
+ .name = "pf",
+ .help = "redirect packets to physical device function",
+ .priv = PRIV_ACTION(PF, 0),
+ .next = NEXT(NEXT_ENTRY(ACTION_NEXT)),
+ .call = parse_vc,
+ },
+ [ACTION_VF] = {
+ .name = "vf",
+ .help = "redirect packets to virtual device function",
+ .priv = PRIV_ACTION(VF, sizeof(struct rte_flow_action_vf)),
+ .next = NEXT(action_vf),
+ .call = parse_vc,
+ },
+ [ACTION_VF_ORIGINAL] = {
+ .name = "original",
+ .help = "use original VF ID if possible",
+ .next = NEXT(action_vf, NEXT_ENTRY(BOOLEAN)),
+ .args = ARGS(ARGS_ENTRY_BF(struct rte_flow_action_vf,
+ original, 1)),
+ .call = parse_vc_conf,
+ },
+ [ACTION_VF_ID] = {
+ .name = "id",
+ .help = "VF ID to redirect packets to",
+ .next = NEXT(action_vf, NEXT_ENTRY(UNSIGNED)),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_action_vf, id)),
+ .call = parse_vc_conf,
+ },
+ [ACTION_METER] = {
+ .name = "meter",
+ .help = "meter the directed packets at given id",
+ .priv = PRIV_ACTION(METER,
+ sizeof(struct rte_flow_action_meter)),
+ .next = NEXT(action_meter),
+ .call = parse_vc,
+ },
+ [ACTION_METER_ID] = {
+ .name = "mtr_id",
+ .help = "meter id to use",
+ .next = NEXT(action_meter, NEXT_ENTRY(UNSIGNED)),
+ .args = ARGS(ARGS_ENTRY(struct rte_flow_action_meter, mtr_id)),
+ .call = parse_vc_conf,
+ },
+};
+
+/** Remove and return last entry from argument stack. */
+static const struct arg *
+pop_args(struct context *ctx)
+{
+ return ctx->args_num ? ctx->args[--ctx->args_num] : NULL;
+}
+
+/** Add entry on top of the argument stack. */
+static int
+push_args(struct context *ctx, const struct arg *arg)
+{
+ if (ctx->args_num == CTX_STACK_SIZE)
+ return -1;
+ ctx->args[ctx->args_num++] = arg;
+ return 0;
+}
+
+/** Spread value into buffer according to bit-mask. */
+static size_t
+arg_entry_bf_fill(void *dst, uintmax_t val, const struct arg *arg)
+{
+ uint32_t i = arg->size;
+ uint32_t end = 0;
+ int sub = 1;
+ int add = 0;
+ size_t len = 0;
+
+ if (!arg->mask)
+ return 0;
+#if RTE_BYTE_ORDER == RTE_LITTLE_ENDIAN
+ if (!arg->hton) {
+ i = 0;
+ end = arg->size;
+ sub = 0;
+ add = 1;
+ }
+#endif
+ while (i != end) {
+ unsigned int shift = 0;
+ uint8_t *buf = (uint8_t *)dst + arg->offset + (i -= sub);
+
+ for (shift = 0; arg->mask[i] >> shift; ++shift) {
+ if (!(arg->mask[i] & (1 << shift)))
+ continue;
+ ++len;
+ if (!dst)
+ continue;
+ *buf &= ~(1 << shift);
+ *buf |= (val & 1) << shift;
+ val >>= 1;
+ }
+ i += add;
+ }
+ return len;
+}
+
+/** Compare a string with a partial one of a given length. */
+static int
+strcmp_partial(const char *full, const char *partial, size_t partial_len)
+{
+ int r = strncmp(full, partial, partial_len);
+
+ if (r)
+ return r;
+ if (strlen(full) <= partial_len)
+ return 0;
+ return full[partial_len];
+}
+
+/**
+ * Parse a prefix length and generate a bit-mask.
+ *
+ * Last argument (ctx->args) is retrieved to determine mask size, storage
+ * location and whether the result must use network byte ordering.
+ */
+static int
+parse_prefix(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ const struct arg *arg = pop_args(ctx);
+ static const uint8_t conv[] = "\x00\x80\xc0\xe0\xf0\xf8\xfc\xfe\xff";
+ char *end;
+ uintmax_t u;
+ unsigned int bytes;
+ unsigned int extra;
+
+ (void)token;
+ /* Argument is expected. */
+ if (!arg)
+ return -1;
+ errno = 0;
+ u = strtoumax(str, &end, 0);
+ if (errno || (size_t)(end - str) != len)
+ goto error;
+ if (arg->mask) {
+ uintmax_t v = 0;
+
+ extra = arg_entry_bf_fill(NULL, 0, arg);
+ if (u > extra)
+ goto error;
+ if (!ctx->object)
+ return len;
+ extra -= u;
+ while (u--)
+ (v <<= 1, v |= 1);
+ v <<= extra;
+ if (!arg_entry_bf_fill(ctx->object, v, arg) ||
+ !arg_entry_bf_fill(ctx->objmask, -1, arg))
+ goto error;
+ return len;
+ }
+ bytes = u / 8;
+ extra = u % 8;
+ size = arg->size;
+ if (bytes > size || bytes + !!extra > size)
+ goto error;
+ if (!ctx->object)
+ return len;
+ buf = (uint8_t *)ctx->object + arg->offset;
+#if RTE_BYTE_ORDER == RTE_LITTLE_ENDIAN
+ if (!arg->hton) {
+ memset((uint8_t *)buf + size - bytes, 0xff, bytes);
+ memset(buf, 0x00, size - bytes);
+ if (extra)
+ ((uint8_t *)buf)[size - bytes - 1] = conv[extra];
+ } else
+#endif
+ {
+ memset(buf, 0xff, bytes);
+ memset((uint8_t *)buf + bytes, 0x00, size - bytes);
+ if (extra)
+ ((uint8_t *)buf)[bytes] = conv[extra];
+ }
+ if (ctx->objmask)
+ memset((uint8_t *)ctx->objmask + arg->offset, 0xff, size);
+ return len;
+error:
+ push_args(ctx, arg);
+ return -1;
+}
+
+/** Default parsing function for token name matching. */
+static int
+parse_default(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ (void)ctx;
+ (void)buf;
+ (void)size;
+ if (strcmp_partial(token->name, str, len))
+ return -1;
+ return len;
+}
+
+/** Parse flow command, initialize output buffer for subsequent tokens. */
+static int
+parse_init(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ struct buffer *out = buf;
+
+ /* Token name must match. */
+ if (parse_default(ctx, token, str, len, NULL, 0) < 0)
+ return -1;
+ /* Nothing else to do if there is no buffer. */
+ if (!out)
+ return len;
+ /* Make sure buffer is large enough. */
+ if (size < sizeof(*out))
+ return -1;
+ /* Initialize buffer. */
+ memset(out, 0x00, sizeof(*out));
+ memset((uint8_t *)out + sizeof(*out), 0x22, size - sizeof(*out));
+ ctx->objdata = 0;
+ ctx->object = out;
+ ctx->objmask = NULL;
+ return len;
+}
+
+/** Parse tokens for validate/create commands. */
+static int
+parse_vc(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ struct buffer *out = buf;
+ uint8_t *data;
+ uint32_t data_size;
+
+ /* Token name must match. */
+ if (parse_default(ctx, token, str, len, NULL, 0) < 0)
+ return -1;
+ /* Nothing else to do if there is no buffer. */
+ if (!out)
+ return len;
+ if (!out->command) {
+ if (ctx->curr != VALIDATE && ctx->curr != CREATE)
+ return -1;
+ if (sizeof(*out) > size)
+ return -1;
+ out->command = ctx->curr;
+ ctx->objdata = 0;
+ ctx->object = out;
+ ctx->objmask = NULL;
+ out->args.vc.data = (uint8_t *)out + size;
+ return len;
+ }
+ ctx->objdata = 0;
+ ctx->object = &out->args.vc.attr;
+ ctx->objmask = NULL;
+ switch (ctx->curr) {
+ case GROUP:
+ case PRIORITY:
+ return len;
+ case INGRESS:
+ out->args.vc.attr.ingress = 1;
+ return len;
+ case EGRESS:
+ out->args.vc.attr.egress = 1;
+ return len;
+ case PATTERN:
+ out->args.vc.pattern =
+ (void *)RTE_ALIGN_CEIL((uintptr_t)(out + 1),
+ sizeof(double));
+ ctx->object = out->args.vc.pattern;
+ ctx->objmask = NULL;
+ return len;
+ case ACTIONS:
+ out->args.vc.actions =
+ (void *)RTE_ALIGN_CEIL((uintptr_t)
+ (out->args.vc.pattern +
+ out->args.vc.pattern_n),
+ sizeof(double));
+ ctx->object = out->args.vc.actions;
+ ctx->objmask = NULL;
+ return len;
+ default:
+ if (!token->priv)
+ return -1;
+ break;
+ }
+ if (!out->args.vc.actions) {
+ const struct parse_item_priv *priv = token->priv;
+ struct rte_flow_item *item =
+ out->args.vc.pattern + out->args.vc.pattern_n;
+
+ data_size = priv->size * 3; /* spec, last, mask */
+ data = (void *)RTE_ALIGN_FLOOR((uintptr_t)
+ (out->args.vc.data - data_size),
+ sizeof(double));
+ if ((uint8_t *)item + sizeof(*item) > data)
+ return -1;
+ *item = (struct rte_flow_item){
+ .type = priv->type,
+ };
+ ++out->args.vc.pattern_n;
+ ctx->object = item;
+ ctx->objmask = NULL;
+ } else {
+ const struct parse_action_priv *priv = token->priv;
+ struct rte_flow_action *action =
+ out->args.vc.actions + out->args.vc.actions_n;
+
+ data_size = priv->size; /* configuration */
+ data = (void *)RTE_ALIGN_FLOOR((uintptr_t)
+ (out->args.vc.data - data_size),
+ sizeof(double));
+ if ((uint8_t *)action + sizeof(*action) > data)
+ return -1;
+ *action = (struct rte_flow_action){
+ .type = priv->type,
+ .conf = data_size ? data : NULL,
+ };
+ ++out->args.vc.actions_n;
+ ctx->object = action;
+ ctx->objmask = NULL;
+ }
+ memset(data, 0, data_size);
+ out->args.vc.data = data;
+ ctx->objdata = data_size;
+ return len;
+}
+
+/** Parse pattern item parameter type. */
+static int
+parse_vc_spec(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ struct buffer *out = buf;
+ struct rte_flow_item *item;
+ uint32_t data_size;
+ int index;
+ int objmask = 0;
+
+ (void)size;
+ /* Token name must match. */
+ if (parse_default(ctx, token, str, len, NULL, 0) < 0)
+ return -1;
+ /* Parse parameter types. */
+ switch (ctx->curr) {
+ static const enum index prefix[] = NEXT_ENTRY(PREFIX);
+
+ case ITEM_PARAM_IS:
+ index = 0;
+ objmask = 1;
+ break;
+ case ITEM_PARAM_SPEC:
+ index = 0;
+ break;
+ case ITEM_PARAM_LAST:
+ index = 1;
+ break;
+ case ITEM_PARAM_PREFIX:
+ /* Modify next token to expect a prefix. */
+ if (ctx->next_num < 2)
+ return -1;
+ ctx->next[ctx->next_num - 2] = prefix;
+ /* Fall through. */
+ case ITEM_PARAM_MASK:
+ index = 2;
+ break;
+ default:
+ return -1;
+ }
+ /* Nothing else to do if there is no buffer. */
+ if (!out)
+ return len;
+ if (!out->args.vc.pattern_n)
+ return -1;
+ item = &out->args.vc.pattern[out->args.vc.pattern_n - 1];
+ data_size = ctx->objdata / 3; /* spec, last, mask */
+ /* Point to selected object. */
+ ctx->object = out->args.vc.data + (data_size * index);
+ if (objmask) {
+ ctx->objmask = out->args.vc.data + (data_size * 2); /* mask */
+ item->mask = ctx->objmask;
+ } else
+ ctx->objmask = NULL;
+ /* Update relevant item pointer. */
+ *((const void **[]){ &item->spec, &item->last, &item->mask })[index] =
+ ctx->object;
+ return len;
+}
+
+/** Parse action configuration field. */
+static int
+parse_vc_conf(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ struct buffer *out = buf;
+
+ (void)size;
+ /* Token name must match. */
+ if (parse_default(ctx, token, str, len, NULL, 0) < 0)
+ return -1;
+ /* Nothing else to do if there is no buffer. */
+ if (!out)
+ return len;
+ /* Point to selected object. */
+ ctx->object = out->args.vc.data;
+ ctx->objmask = NULL;
+ return len;
+}
+
+/** Parse RSS action. */
+static int
+parse_vc_action_rss(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ struct buffer *out = buf;
+ struct rte_flow_action *action;
+ union action_rss_data *action_rss_data;
+ unsigned int i;
+ int ret;
+
+ ret = parse_vc(ctx, token, str, len, buf, size);
+ if (ret < 0)
+ return ret;
+ /* Nothing else to do if there is no buffer. */
+ if (!out)
+ return ret;
+ if (!out->args.vc.actions_n)
+ return -1;
+ action = &out->args.vc.actions[out->args.vc.actions_n - 1];
+ /* Point to selected object. */
+ ctx->object = out->args.vc.data;
+ ctx->objmask = NULL;
+ /* Set up default configuration. */
+ action_rss_data = ctx->object;
+ *action_rss_data = (union action_rss_data){
+ .conf = (struct rte_flow_action_rss){
+ .rss_conf = &action_rss_data->s.rss_conf,
+ .num = RTE_MIN(nb_rxq, ACTION_RSS_QUEUE_NUM),
+ },
+ };
+ action_rss_data->s.rss_conf = (struct rte_eth_rss_conf){
+ .rss_key = action_rss_data->s.rss_key,
+ .rss_key_len = sizeof(action_rss_data->s.rss_key),
+ .rss_hf = rss_hf,
+ };
+ strncpy((void *)action_rss_data->s.rss_key,
+ "testpmd's default RSS hash key",
+ sizeof(action_rss_data->s.rss_key));
+ for (i = 0; i < action_rss_data->conf.num; ++i)
+ action_rss_data->conf.queue[i] = i;
+ if (!port_id_is_invalid(ctx->port, DISABLED_WARN) &&
+ ctx->port != (portid_t)RTE_PORT_ALL) {
+ struct rte_eth_dev_info info;
+
+ rte_eth_dev_info_get(ctx->port, &info);
+ action_rss_data->s.rss_conf.rss_key_len =
+ RTE_MIN(sizeof(action_rss_data->s.rss_key),
+ info.hash_key_size);
+ }
+ action->conf = &action_rss_data->conf;
+ return ret;
+}
+
+/**
+ * Parse type field for RSS action.
+ *
+ * Valid tokens are type field names and the "end" token.
+ */
+static int
+parse_vc_action_rss_type(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ static const enum index next[] = NEXT_ENTRY(ACTION_RSS_TYPE);
+ union action_rss_data *action_rss_data;
+ unsigned int i;
+
+ (void)token;
+ (void)buf;
+ (void)size;
+ if (ctx->curr != ACTION_RSS_TYPE)
+ return -1;
+ if (!(ctx->objdata >> 16) && ctx->object) {
+ action_rss_data = ctx->object;
+ action_rss_data->s.rss_conf.rss_hf = 0;
+ }
+ if (!strcmp_partial("end", str, len)) {
+ ctx->objdata &= 0xffff;
+ return len;
+ }
+ for (i = 0; rss_type_table[i].str; ++i)
+ if (!strcmp_partial(rss_type_table[i].str, str, len))
+ break;
+ if (!rss_type_table[i].str)
+ return -1;
+ ctx->objdata = 1 << 16 | (ctx->objdata & 0xffff);
+ /* Repeat token. */
+ if (ctx->next_num == RTE_DIM(ctx->next))
+ return -1;
+ ctx->next[ctx->next_num++] = next;
+ if (!ctx->object)
+ return len;
+ action_rss_data = ctx->object;
+ action_rss_data->s.rss_conf.rss_hf |= rss_type_table[i].rss_type;
+ return len;
+}
+
+/**
+ * Parse queue field for RSS action.
+ *
+ * Valid tokens are queue indices and the "end" token.
+ */
+static int
+parse_vc_action_rss_queue(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ static const enum index next[] = NEXT_ENTRY(ACTION_RSS_QUEUE);
+ union action_rss_data *action_rss_data;
+ int ret;
+ int i;
+
+ (void)token;
+ (void)buf;
+ (void)size;
+ if (ctx->curr != ACTION_RSS_QUEUE)
+ return -1;
+ i = ctx->objdata >> 16;
+ if (!strcmp_partial("end", str, len)) {
+ ctx->objdata &= 0xffff;
+ return len;
+ }
+ if (i >= ACTION_RSS_QUEUE_NUM)
+ return -1;
+ if (push_args(ctx,
+ ARGS_ENTRY_ARB(offsetof(struct rte_flow_action_rss,
+ queue) +
+ i * sizeof(action_rss_data->s.queue[i]),
+ sizeof(action_rss_data->s.queue[i]))))
+ return -1;
+ ret = parse_int(ctx, token, str, len, NULL, 0);
+ if (ret < 0) {
+ pop_args(ctx);
+ return -1;
+ }
+ ++i;
+ ctx->objdata = i << 16 | (ctx->objdata & 0xffff);
+ /* Repeat token. */
+ if (ctx->next_num == RTE_DIM(ctx->next))
+ return -1;
+ ctx->next[ctx->next_num++] = next;
+ if (!ctx->object)
+ return len;
+ action_rss_data = ctx->object;
+ action_rss_data->conf.num = i;
+ return len;
+}
+
+/** Parse tokens for destroy command. */
+static int
+parse_destroy(struct context *ctx, const struct token *token,
+ const char *str, unsigned int len,
+ void *buf, unsigned int size)
+{
+ struct buffer *out = buf;
+
+ /* Token name must match. */
+ if (parse_default(ctx, token, str, len, NULL, 0) < 0)
+ return -1;
+ /* Nothing else to do if there is no buffer. */
+ if (!out)
+ return len;
+ if (!out->command) {
+ if (ctx->curr != DESTROY)
+ return -1;
+ if (sizeof(*out) > size)
+ return -1;
+ out->command = ctx->curr;
+ ctx->objdata = 0;
+ ctx->object = out;
+ ctx->objmask = NULL;
+ out->args.destroy.rule =
+ (void *)RTE_ALIGN_CEIL((uintptr_t)(out + 1),
+ sizeof(double));
+ return len;
+ }
+ if (((uint8_t *)(out->args.destroy.rule + out->args.destroy.rule_n) +
+ sizeof(*out->args.destroy.rule)) > (uint8_t *)out + size)