// SPDX-License-Identifier: ISC /* * Copyright (c) 2018 Rafael Zalamena */ #include #if defined(HAVE_NETLINK) && defined(NETLINK_DEBUG) #include #include #include #include #include #include #include #include #include #include #include "zebra/rt_netlink.h" #include "zebra/kernel_netlink.h" #include "lib/vxlan.h" const char *nlmsg_type2str(uint16_t type) { switch (type) { /* Generic */ case NLMSG_NOOP: return "NOOP"; case NLMSG_ERROR: return "ERROR"; case NLMSG_DONE: return "DONE"; case NLMSG_OVERRUN: return "OVERRUN"; /* RTM */ case RTM_NEWLINK: return "NEWLINK"; case RTM_DELLINK: return "DELLINK"; case RTM_GETLINK: return "GETLINK"; case RTM_SETLINK: return "SETLINK"; case RTM_NEWADDR: return "NEWADDR"; case RTM_DELADDR: return "DELADDR"; case RTM_GETADDR: return "GETADDR"; case RTM_NEWROUTE: return "NEWROUTE"; case RTM_DELROUTE: return "DELROUTE"; case RTM_GETROUTE: return "GETROUTE"; case RTM_NEWNEIGH: return "NEWNEIGH"; case RTM_DELNEIGH: return "DELNEIGH"; case RTM_GETNEIGH: return "GETNEIGH"; case RTM_NEWRULE: return "NEWRULE"; case RTM_DELRULE: return "DELRULE"; case RTM_GETRULE: return "GETRULE"; case RTM_NEWNEXTHOP: return "NEWNEXTHOP"; case RTM_DELNEXTHOP: return "DELNEXTHOP"; case RTM_GETNEXTHOP: return "GETNEXTHOP"; case RTM_NEWTUNNEL: return "NEWTUNNEL"; case RTM_DELTUNNEL: return "DELTUNNEL"; case RTM_GETTUNNEL: return "GETTUNNEL"; case RTM_NEWNETCONF: return "RTM_NEWNETCONF"; case RTM_DELNETCONF: return "RTM_DELNETCONF"; default: return "UNKNOWN"; } } const char *af_type2str(int type) { switch (type) { case AF_UNSPEC: return "AF_UNSPEC"; case AF_UNIX: return "AF_UNIX"; case AF_INET: return "AF_INET"; case AF_INET6: return "AF_INET6"; case AF_BRIDGE: return "AF_BRIDGE"; case AF_NETLINK: return "AF_NETLINK"; #ifdef AF_MPLS case AF_MPLS: return "AF_MPLS"; #endif /* AF_MPLS */ case AF_BLUETOOTH: return "AF_BLUETOOTH"; case AF_VSOCK: return "AF_VSOCK"; case AF_KEY: return "AF_KEY"; case AF_PACKET: return "AF_PACKET"; default: return "UNKNOWN"; } } const char *ifi_type2str(int type) { switch (type) { case ARPHRD_ETHER: return "ETHER"; case ARPHRD_EETHER: return "EETHER"; case ARPHRD_NETROM: return "NETROM"; case ARPHRD_AX25: return "AX25"; case ARPHRD_PRONET: return "PRONET"; case ARPHRD_CHAOS: return "CHAOS"; case ARPHRD_IEEE802: return "IEEE802"; case ARPHRD_ARCNET: return "ARCNET"; case ARPHRD_APPLETLK: return "APPLETLK"; case ARPHRD_DLCI: return "DLCI"; case ARPHRD_ATM: return "ATM"; case ARPHRD_METRICOM: return "METRICOM"; case ARPHRD_IEEE1394: return "IEEE1394"; case ARPHRD_EUI64: return "EUI64"; case ARPHRD_INFINIBAND: return "INFINIBAND"; case ARPHRD_SLIP: return "SLIP"; case ARPHRD_CSLIP: return "CSLIP"; case ARPHRD_SLIP6: return "SLIP6"; case ARPHRD_CSLIP6: return "CSLIP6"; case ARPHRD_RSRVD: return "RSRVD"; case ARPHRD_ADAPT: return "ADAPT"; case ARPHRD_ROSE: return "ROSE"; case ARPHRD_X25: return "X25"; case ARPHRD_PPP: return "PPP"; case ARPHRD_HDLC: return "HDLC"; case ARPHRD_LAPB: return "LAPB"; case ARPHRD_DDCMP: return "DDCMP"; case ARPHRD_RAWHDLC: return "RAWHDLC"; case ARPHRD_TUNNEL: return "TUNNEL"; case ARPHRD_TUNNEL6: return "TUNNEL6"; case ARPHRD_FRAD: return "FRAD"; case ARPHRD_SKIP: return "SKIP"; case ARPHRD_LOOPBACK: return "LOOPBACK"; case ARPHRD_LOCALTLK: return "LOCALTLK"; case ARPHRD_FDDI: return "FDDI"; case ARPHRD_BIF: return "BIF"; case ARPHRD_SIT: return "SIT"; case ARPHRD_IPDDP: return "IPDDP"; case ARPHRD_IPGRE: return "IPGRE"; case ARPHRD_PIMREG: return "PIMREG"; case ARPHRD_HIPPI: return "HIPPI"; case ARPHRD_ASH: return "ASH"; case ARPHRD_ECONET: return "ECONET"; case ARPHRD_IRDA: return "IRDA"; case ARPHRD_FCPP: return "FCPP"; case ARPHRD_FCAL: return "FCAL"; case ARPHRD_FCPL: return "FCPL"; case ARPHRD_FCFABRIC: return "FCFABRIC"; case ARPHRD_IEEE802_TR: return "IEEE802_TR"; case ARPHRD_IEEE80211: return "IEEE80211"; case ARPHRD_IEEE80211_PRISM: return "IEEE80211_PRISM"; case ARPHRD_IEEE80211_RADIOTAP: return "IEEE80211_RADIOTAP"; case ARPHRD_IEEE802154: return "IEEE802154"; #ifdef ARPHRD_VSOCKMON case ARPHRD_VSOCKMON: return "VSOCKMON"; #endif /* ARPHRD_VSOCKMON */ case ARPHRD_VOID: return "VOID"; case ARPHRD_NONE: return "NONE"; default: return "UNKNOWN"; } } const char *ifla_pdr_type2str(int type) { switch (type) { case IFLA_PROTO_DOWN_REASON_UNSPEC: return "UNSPEC"; case IFLA_PROTO_DOWN_REASON_MASK: return "MASK"; case IFLA_PROTO_DOWN_REASON_VALUE: return "VALUE"; default: return "UNKNOWN"; } } const char *ifla_info_type2str(int type) { switch (type) { case IFLA_INFO_UNSPEC: return "UNSPEC"; case IFLA_INFO_KIND: return "KIND"; case IFLA_INFO_DATA: return "DATA"; case IFLA_INFO_XSTATS: return "XSTATS"; case IFLA_INFO_SLAVE_KIND: return "SLAVE_KIND"; case IFLA_INFO_SLAVE_DATA: return "SLAVE_DATA"; default: return "UNKNOWN"; } } const char *rta_type2str(int type) { switch (type) { case IFLA_UNSPEC: return "UNSPEC"; case IFLA_ADDRESS: return "ADDRESS"; case IFLA_BROADCAST: return "BROADCAST"; case IFLA_IFNAME: return "IFNAME"; case IFLA_MTU: return "MTU"; case IFLA_LINK: return "LINK"; case IFLA_QDISC: return "QDISC"; case IFLA_STATS: return "STATS"; case IFLA_COST: return "COST"; case IFLA_PRIORITY: return "PRIORITY"; case IFLA_MASTER: return "MASTER"; case IFLA_WIRELESS: return "WIRELESS"; case IFLA_PROTINFO: return "PROTINFO"; case IFLA_TXQLEN: return "TXQLEN"; case IFLA_MAP: return "MAP"; case IFLA_WEIGHT: return "WEIGHT"; case IFLA_OPERSTATE: return "OPERSTATE"; case IFLA_LINKMODE: return "LINKMODE"; case IFLA_LINKINFO: return "LINKINFO"; case IFLA_NET_NS_PID: return "NET_NS_PID"; case IFLA_IFALIAS: return "IFALIAS"; case IFLA_NUM_VF: return "NUM_VF"; case IFLA_VFINFO_LIST: return "VFINFO_LIST"; case IFLA_STATS64: return "STATS64"; case IFLA_VF_PORTS: return "VF_PORTS"; case IFLA_PORT_SELF: return "PORT_SELF"; case IFLA_AF_SPEC: return "AF_SPEC"; case IFLA_GROUP: return "GROUP"; case IFLA_NET_NS_FD: return "NET_NS_FD"; case IFLA_EXT_MASK: return "EXT_MASK"; case IFLA_PROMISCUITY: return "PROMISCUITY"; case IFLA_NUM_TX_QUEUES: return "NUM_TX_QUEUES"; case IFLA_NUM_RX_QUEUES: return "NUM_RX_QUEUES"; case IFLA_CARRIER: return "CARRIER"; case IFLA_PHYS_PORT_ID: return "PHYS_PORT_ID"; case IFLA_CARRIER_CHANGES: return "CARRIER_CHANGES"; case IFLA_PHYS_SWITCH_ID: return "PHYS_SWITCH_ID"; case IFLA_LINK_NETNSID: return "LINK_NETNSID"; case IFLA_PHYS_PORT_NAME: return "PHYS_PORT_NAME"; case IFLA_PROTO_DOWN: return "PROTO_DOWN"; #ifdef IFLA_GSO_MAX_SEGS case IFLA_GSO_MAX_SEGS: return "GSO_MAX_SEGS"; #endif /* IFLA_GSO_MAX_SEGS */ #ifdef IFLA_GSO_MAX_SIZE case IFLA_GSO_MAX_SIZE: return "GSO_MAX_SIZE"; #endif /* IFLA_GSO_MAX_SIZE */ #ifdef IFLA_PAD case IFLA_PAD: return "PAD"; #endif /* IFLA_PAD */ #ifdef IFLA_XDP case IFLA_XDP: return "XDP"; #endif /* IFLA_XDP */ #ifdef IFLA_EVENT case IFLA_EVENT: return "EVENT"; #endif /* IFLA_EVENT */ case IFLA_PROTO_DOWN_REASON: return "PROTO_DOWN_REASON"; default: return "UNKNOWN"; } } const char *rtm_type2str(int type) { switch (type) { case RTN_UNSPEC: return "UNSPEC"; case RTN_UNICAST: return "UNICAST"; case RTN_LOCAL: return "LOCAL"; case RTN_BROADCAST: return "BROADCAST"; case RTN_ANYCAST: return "ANYCAST"; case RTN_MULTICAST: return "MULTICAST"; case RTN_BLACKHOLE: return "BLACKHOLE"; case RTN_UNREACHABLE: return "UNREACHABLE"; case RTN_PROHIBIT: return "PROHIBIT"; case RTN_THROW: return "THROW"; case RTN_NAT: return "NAT"; case RTN_XRESOLVE: return "XRESOLVE"; default: return "UNKNOWN"; } } const char *rtm_protocol2str(int type) { switch (type) { case RTPROT_UNSPEC: return "UNSPEC"; case RTPROT_REDIRECT: return "REDIRECT"; case RTPROT_KERNEL: return "KERNEL"; case RTPROT_BOOT: return "BOOT"; case RTPROT_STATIC: return "STATIC"; case RTPROT_GATED: return "GATED"; case RTPROT_RA: return "RA"; case RTPROT_MRT: return "MRT"; case RTPROT_ZEBRA: return "ZEBRA"; case RTPROT_BGP: return "BGP"; case RTPROT_ISIS: return "ISIS"; case RTPROT_OSPF: return "OSPF"; case RTPROT_BIRD: return "BIRD"; case RTPROT_DNROUTED: return "DNROUTED"; case RTPROT_XORP: return "XORP"; case RTPROT_NTK: return "NTK"; case RTPROT_DHCP: return "DHCP"; case RTPROT_MROUTED: return "MROUTED"; case RTPROT_BABEL: return "BABEL"; default: return "UNKNOWN"; } } const char *rtm_scope2str(int type) { switch (type) { case RT_SCOPE_UNIVERSE: return "UNIVERSE"; case RT_SCOPE_SITE: return "SITE"; case RT_SCOPE_LINK: return "LINK"; case RT_SCOPE_HOST: return "HOST"; case RT_SCOPE_NOWHERE: return "NOWHERE"; default: return "UNKNOWN"; } } const char *rtm_rta2str(int type) { switch (type) { case RTA_UNSPEC: return "UNSPEC"; case RTA_DST: return "DST"; case RTA_SRC: return "SRC"; case RTA_IIF: return "IIF"; case RTA_OIF: return "OIF"; case RTA_GATEWAY: return "GATEWAY"; case RTA_PRIORITY: return "PRIORITY"; case RTA_PREF: return "PREF"; case RTA_PREFSRC: return "PREFSRC"; case RTA_MARK: return "MARK"; case RTA_METRICS: return "METRICS"; case RTA_MULTIPATH: return "MULTIPATH"; case RTA_PROTOINFO: return "PROTOINFO"; case RTA_FLOW: return "FLOW"; case RTA_CACHEINFO: return "CACHEINFO"; case RTA_TABLE: return "TABLE"; case RTA_MFC_STATS: return "MFC_STATS"; case RTA_NH_ID: return "NH_ID"; case RTA_EXPIRES: return "EXPIRES"; default: return "UNKNOWN"; } } const char *neigh_rta2str(int type) { switch (type) { case NDA_UNSPEC: return "UNSPEC"; case NDA_DST: return "DST"; case NDA_LLADDR: return "LLADDR"; case NDA_CACHEINFO: return "CACHEINFO"; case NDA_PROBES: return "PROBES"; case NDA_VLAN: return "VLAN"; case NDA_PORT: return "PORT"; case NDA_VNI: return "VNI"; case NDA_IFINDEX: return "IFINDEX"; case NDA_MASTER: return "MASTER"; case NDA_LINK_NETNSID: return "LINK_NETNSID"; default: return "UNKNOWN"; } } const char *ifa_rta2str(int type) { switch (type) { case IFA_UNSPEC: return "UNSPEC"; case IFA_ADDRESS: return "ADDRESS"; case IFA_LOCAL: return "LOCAL"; case IFA_LABEL: return "LABEL"; case IFA_BROADCAST: return "BROADCAST"; case IFA_ANYCAST: return "ANYCAST"; case IFA_CACHEINFO: return "CACHEINFO"; case IFA_MULTICAST: return "MULTICAST"; case IFA_FLAGS: return "FLAGS"; default: return "UNKNOWN"; } } const char *nhm_rta2str(int type) { switch (type) { case NHA_UNSPEC: return "UNSPEC"; case NHA_ID: return "ID"; case NHA_GROUP: return "GROUP"; case NHA_GROUP_TYPE: return "GROUP_TYPE"; case NHA_BLACKHOLE: return "BLACKHOLE"; case NHA_OIF: return "OIF"; case NHA_GATEWAY: return "GATEWAY"; case NHA_ENCAP_TYPE: return "ENCAP_TYPE"; case NHA_ENCAP: return "ENCAP"; case NHA_GROUPS: return "GROUPS"; case NHA_MASTER: return "MASTER"; default: return "UNKNOWN"; } } const char *frh_rta2str(int type) { switch (type) { case FRA_DST: return "DST"; case FRA_SRC: return "SRC"; case FRA_IIFNAME: return "IIFNAME"; case FRA_GOTO: return "GOTO"; case FRA_UNUSED2: return "UNUSED2"; case FRA_PRIORITY: return "PRIORITY"; case FRA_UNUSED3: return "UNUSED3"; case FRA_UNUSED4: return "UNUSED4"; case FRA_UNUSED5: return "UNUSED5"; case FRA_FWMARK: return "FWMARK"; case FRA_FLOW: return "FLOW"; case FRA_TUN_ID: return "TUN_ID"; case FRA_SUPPRESS_IFGROUP: return "SUPPRESS_IFGROUP"; case FRA_SUPPRESS_PREFIXLEN: return "SUPPRESS_PREFIXLEN"; case FRA_TABLE: return "TABLE"; case FRA_FWMASK: return "FWMASK"; case FRA_OIFNAME: return "OIFNAME"; case FRA_PAD: return "PAD"; case FRA_L3MDEV: return "L3MDEV"; case FRA_UID_RANGE: return "UID_RANGE"; case FRA_PROTOCOL: return "PROTOCOL"; case FRA_IP_PROTO: return "IP_PROTO"; case FRA_SPORT_RANGE: return "SPORT_RANGE"; case FRA_DPORT_RANGE: return "DPORT_RANGE"; default: return "UNKNOWN"; } } const char *frh_action2str(uint8_t action) { switch (action) { case FR_ACT_TO_TBL: return "TO_TBL"; case FR_ACT_GOTO: return "GOTO"; case FR_ACT_NOP: return "NOP"; case FR_ACT_RES3: return "RES3"; case FR_ACT_RES4: return "RES4"; case FR_ACT_BLACKHOLE: return "BLACKHOLE"; case FR_ACT_UNREACHABLE: return "UNREACHABLE"; case FR_ACT_PROHIBIT: return "PROHIBIT"; default: return "UNKNOWN"; } } static const char *ncm_rta2str(int type) { switch (type) { case NETCONFA_UNSPEC: return "UNSPEC"; case NETCONFA_IFINDEX: return "IFINDEX"; case NETCONFA_FORWARDING: return "FORWARDING"; case NETCONFA_RP_FILTER: return "RP_FILTER"; case NETCONFA_MC_FORWARDING: return "MCAST"; case NETCONFA_PROXY_NEIGH: return "PROXY_NEIGH"; case NETCONFA_IGNORE_ROUTES_WITH_LINKDOWN: return "IGNORE_LINKDOWN"; case NETCONFA_INPUT: return "MPLS"; case NETCONFA_BC_FORWARDING: return "BCAST"; default: return "UNKNOWN"; } } static void dump_on_off(uint32_t ival, const char *prefix) { zlog_debug("%s%s", prefix, (ival != 0) ? "on" : "off"); } static inline void flag_write(int flags, int flag, const char *flagstr, char *buf, size_t buflen) { if (CHECK_FLAG(flags, flag) == 0) return; if (buf[0]) strlcat(buf, ",", buflen); strlcat(buf, flagstr, buflen); } const char *nlmsg_flags2str(uint16_t flags, char *buf, size_t buflen) { const char *bufp = buf; *buf = 0; /* Specific flags. */ flag_write(flags, NLM_F_REQUEST, "REQUEST", buf, buflen); flag_write(flags, NLM_F_MULTI, "MULTI", buf, buflen); flag_write(flags, NLM_F_ACK, "ACK", buf, buflen); flag_write(flags, NLM_F_ECHO, "ECHO", buf, buflen); flag_write(flags, NLM_F_DUMP, "DUMP", buf, buflen); /* Netlink family type dependent. */ flag_write(flags, 0x0100, "(ROOT|REPLACE|CAPPED)", buf, buflen); flag_write(flags, 0x0200, "(MATCH|EXCLUDE|ACK_TLVS)", buf, buflen); flag_write(flags, 0x0400, "(ATOMIC|CREATE)", buf, buflen); flag_write(flags, 0x0800, "(DUMP|APPEND)", buf, buflen); return (bufp); } const char *if_flags2str(uint32_t flags, char *buf, size_t buflen) { const char *bufp = buf; *buf = 0; flag_write(flags, IFF_UP, "UP", buf, buflen); flag_write(flags, IFF_BROADCAST, "BROADCAST", buf, buflen); flag_write(flags, IFF_DEBUG, "DEBUG", buf, buflen); flag_write(flags, IFF_LOOPBACK, "LOOPBACK", buf, buflen); flag_write(flags, IFF_POINTOPOINT, "POINTOPOINT", buf, buflen); flag_write(flags, IFF_NOTRAILERS, "NOTRAILERS", buf, buflen); flag_write(flags, IFF_RUNNING, "RUNNING", buf, buflen); flag_write(flags, IFF_NOARP, "NOARP", buf, buflen); flag_write(flags, IFF_PROMISC, "PROMISC", buf, buflen); flag_write(flags, IFF_ALLMULTI, "ALLMULTI", buf, buflen); flag_write(flags, IFF_MASTER, "MASTER", buf, buflen); flag_write(flags, IFF_SLAVE, "SLAVE", buf, buflen); flag_write(flags, IFF_MULTICAST, "MULTICAST", buf, buflen); flag_write(flags, IFF_PORTSEL, "PORTSEL", buf, buflen); flag_write(flags, IFF_AUTOMEDIA, "AUTOMEDIA", buf, buflen); flag_write(flags, IFF_DYNAMIC, "DYNAMIC", buf, buflen); return (bufp); } const char *rtm_flags2str(uint32_t flags, char *buf, size_t buflen) { const char *bufp = buf; *buf = 0; flag_write(flags, RTM_F_NOTIFY, "NOTIFY", buf, buflen); flag_write(flags, RTM_F_CLONED, "CLONED", buf, buflen); flag_write(flags, RTM_F_EQUALIZE, "EQUALIZE", buf, buflen); return (bufp); } const char *neigh_state2str(uint32_t flags, char *buf, size_t buflen) { const char *bufp = buf; *buf = 0; flag_write(flags, NUD_INCOMPLETE, "INCOMPLETE", buf, buflen); flag_write(flags, NUD_REACHABLE, "REACHABLE", buf, buflen); flag_write(flags, NUD_STALE, "STALE", buf, buflen); flag_write(flags, NUD_DELAY, "DELAY", buf, buflen); flag_write(flags, NUD_PROBE, "PROBE", buf, buflen); flag_write(flags, NUD_FAILED, "FAILED", buf, buflen); flag_write(flags, NUD_NOARP, "NOARP", buf, buflen); flag_write(flags, NUD_PERMANENT, "PERMANENT", buf, buflen); return (bufp); } const char *neigh_flags2str(uint32_t flags, char *buf, size_t buflen) { const char *bufp = buf; *buf = 0; flag_write(flags, NTF_USE, "USE", buf, buflen); flag_write(flags, NTF_SELF, "SELF", buf, buflen); flag_write(flags, NTF_MASTER, "MASTER", buf, buflen); flag_write(flags, NTF_PROXY, "PROXY", buf, buflen); flag_write(flags, NTF_EXT_LEARNED, "EXT_LEARNED", buf, buflen); #ifdef NTF_OFFLOADED flag_write(flags, NTF_OFFLOADED, "OFFLOADED", buf, buflen); #endif /* NTF_OFFLOADED */ flag_write(flags, NTF_ROUTER, "ROUTER", buf, buflen); return (bufp); } const char *ifa_flags2str(uint32_t flags, char *buf, size_t buflen) { const char *bufp = buf; *buf = 0; flag_write(flags, IFA_F_SECONDARY, "SECONDARY", buf, buflen); flag_write(flags, IFA_F_NODAD, "NODAD", buf, buflen); flag_write(flags, IFA_F_OPTIMISTIC, "OPTIMISTIC", buf, buflen); flag_write(flags, IFA_F_DADFAILED, "DADFAILED", buf, buflen); flag_write(flags, IFA_F_HOMEADDRESS, "HOMEADDRESS", buf, buflen); flag_write(flags, IFA_F_DEPRECATED, "DEPRECATED", buf, buflen); flag_write(flags, IFA_F_TENTATIVE, "TENTATIVE", buf, buflen); flag_write(flags, IFA_F_PERMANENT, "PERMANENT", buf, buflen); flag_write(flags, IFA_F_MANAGETEMPADDR, "MANAGETEMPADDR", buf, buflen); flag_write(flags, IFA_F_NOPREFIXROUTE, "NOPREFIXROUTE", buf, buflen); flag_write(flags, IFA_F_MCAUTOJOIN, "MCAUTOJOIN", buf, buflen); flag_write(flags, IFA_F_STABLE_PRIVACY, "STABLE_PRIVACY", buf, buflen); return (bufp); } const char *nh_flags2str(uint32_t flags, char *buf, size_t buflen) { const char *bufp = buf; *buf = 0; flag_write(flags, RTNH_F_DEAD, "DEAD", buf, buflen); flag_write(flags, RTNH_F_PERVASIVE, "PERVASIVE", buf, buflen); flag_write(flags, RTNH_F_ONLINK, "ONLINK", buf, buflen); flag_write(flags, RTNH_F_OFFLOAD, "OFFLOAD", buf, buflen); flag_write(flags, RTNH_F_LINKDOWN, "LINKDOWN", buf, buflen); flag_write(flags, RTNH_F_UNRESOLVED, "UNRESOLVED", buf, buflen); return (bufp); } /* * Netlink abstractions. */ static void nllink_pdr_dump(struct rtattr *rta, size_t msglen) { size_t plen; uint32_t u32v; next_rta: /* Check the header for valid length and for outbound access. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); zlog_debug(" linkinfo [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta->rta_type, ifla_pdr_type2str(rta->rta_type)); switch (rta->rta_type) { case IFLA_PROTO_DOWN_REASON_MASK: case IFLA_PROTO_DOWN_REASON_VALUE: if (plen < sizeof(uint32_t)) { zlog_debug(" invalid length"); break; } u32v = *(uint32_t *)RTA_DATA(rta); zlog_debug(" %u", u32v); break; default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } static void nllink_linkinfo_dump(struct rtattr *rta, size_t msglen) { size_t plen; char dbuf[128]; next_rta: /* Check the header for valid length and for outbound access. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); zlog_debug(" linkinfo [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta->rta_type, ifla_info_type2str(rta->rta_type)); switch (rta->rta_type) { case IFLA_INFO_KIND: if (plen == 0) { zlog_debug(" invalid length"); break; } snprintf(dbuf, sizeof(dbuf), "%s", (char *)RTA_DATA(rta)); zlog_debug(" %s", dbuf); break; case IFLA_INFO_SLAVE_KIND: if (plen == 0) { zlog_debug(" invalid length"); break; } snprintf(dbuf, sizeof(dbuf), "%s", (char *)RTA_DATA(rta)); zlog_debug(" %s", dbuf); break; default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } static void nllink_dump(struct ifinfomsg *ifi, size_t msglen) { uint8_t *datap; struct rtattr *rta; size_t plen, it; uint32_t u32v; uint8_t u8v; char bytestr[16]; char dbuf[128]; unsigned short rta_type; /* Get the first attribute and go from there. */ rta = IFLA_RTA(ifi); next_rta: /* Check the header for valid length and for outbound access. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); rta_type = rta->rta_type & ~NLA_F_NESTED; zlog_debug(" rta [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta_type, rta_type2str(rta_type)); switch (rta_type) { case IFLA_IFNAME: case IFLA_IFALIAS: if (plen == 0) { zlog_debug(" invalid length"); break; } snprintf(dbuf, sizeof(dbuf), "%s", (char *)RTA_DATA(rta)); zlog_debug(" %s", dbuf); break; case IFLA_MTU: case IFLA_TXQLEN: case IFLA_NUM_TX_QUEUES: case IFLA_NUM_RX_QUEUES: case IFLA_GROUP: case IFLA_PROMISCUITY: #ifdef IFLA_GSO_MAX_SEGS case IFLA_GSO_MAX_SEGS: #endif /* IFLA_GSO_MAX_SEGS */ #ifdef IFLA_GSO_MAX_SIZE case IFLA_GSO_MAX_SIZE: #endif /* IFLA_GSO_MAX_SIZE */ case IFLA_CARRIER_CHANGES: case IFLA_MASTER: case IFLA_LINK: if (plen < sizeof(uint32_t)) { zlog_debug(" invalid length"); break; } u32v = *(uint32_t *)RTA_DATA(rta); zlog_debug(" %u", u32v); break; case IFLA_PROTO_DOWN: if (plen < sizeof(uint8_t)) { zlog_debug(" invalid length"); break; } u8v = *(uint8_t *)RTA_DATA(rta); zlog_debug(" %u", u8v); break; case IFLA_ADDRESS: datap = RTA_DATA(rta); dbuf[0] = 0; for (it = 0; it < plen; it++) { snprintf(bytestr, sizeof(bytestr), "%02X:", *datap); strlcat(dbuf, bytestr, sizeof(dbuf)); datap++; } /* Remove trailing ':'. */ if (dbuf[0]) dbuf[strlen(dbuf) - 1] = 0; zlog_debug(" %s", dbuf[0] ? dbuf : ""); break; case IFLA_LINKINFO: nllink_linkinfo_dump(RTA_DATA(rta), plen); break; case IFLA_PROTO_DOWN_REASON: nllink_pdr_dump(RTA_DATA(rta), plen); break; default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } static void nlroute_dump(struct rtmsg *rtm, size_t msglen) { struct rta_mfc_stats *mfc_stats; struct rtattr *rta; size_t plen; uint32_t u32v; uint64_t u64v; /* Get the first attribute and go from there. */ rta = RTM_RTA(rtm); next_rta: /* Check the header for valid length and for outbound access. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); zlog_debug(" rta [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta->rta_type & NLA_TYPE_MASK, rtm_rta2str(rta->rta_type & NLA_TYPE_MASK)); switch (rta->rta_type & NLA_TYPE_MASK) { case RTA_IIF: case RTA_OIF: case RTA_PRIORITY: case RTA_TABLE: case RTA_NH_ID: u32v = *(uint32_t *)RTA_DATA(rta); zlog_debug(" %u", u32v); break; case RTA_EXPIRES: u64v = *(uint64_t *)RTA_DATA(rta); zlog_debug(" %" PRIu64, u64v); break; case RTA_GATEWAY: case RTA_DST: case RTA_SRC: case RTA_PREFSRC: switch (plen) { case sizeof(struct in_addr): zlog_debug(" %pI4", (struct in_addr *)RTA_DATA(rta)); break; case sizeof(struct in6_addr): zlog_debug(" %pI6", (struct in6_addr *)RTA_DATA(rta)); break; default: break; } break; case RTA_MFC_STATS: mfc_stats = (struct rta_mfc_stats *)RTA_DATA(rta); zlog_debug(" pkts=%ju bytes=%ju wrong_if=%ju", (uintmax_t)mfc_stats->mfcs_packets, (uintmax_t)mfc_stats->mfcs_bytes, (uintmax_t)mfc_stats->mfcs_wrong_if); break; default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } static void nlneigh_dump(struct ndmsg *ndm, size_t msglen) { struct rtattr *rta; uint8_t *datap; size_t plen, it; uint16_t vid; char bytestr[16]; char dbuf[128]; unsigned short rta_type; #ifndef NDA_RTA #define NDA_RTA(ndm) \ /* struct ndmsg *ndm; */ \ ((struct rtattr *)(((uint8_t *)(ndm)) \ + NLMSG_ALIGN(sizeof(struct ndmsg)))) #endif /* NDA_RTA */ /* Get the first attribute and go from there. */ rta = NDA_RTA(ndm); next_rta: /* Check the header for valid length and for outbound access. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); rta_type = rta->rta_type & ~NLA_F_NESTED; zlog_debug(" rta [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta->rta_type, neigh_rta2str(rta_type)); switch (rta_type) { case NDA_LLADDR: datap = RTA_DATA(rta); dbuf[0] = 0; for (it = 0; it < plen; it++) { snprintf(bytestr, sizeof(bytestr), "%02X:", *datap); strlcat(dbuf, bytestr, sizeof(dbuf)); datap++; } /* Remove trailing ':'. */ if (dbuf[0]) dbuf[strlen(dbuf) - 1] = 0; zlog_debug(" %s", dbuf[0] ? dbuf : ""); break; case NDA_DST: switch (plen) { case sizeof(struct in_addr): zlog_debug(" %pI4", (struct in_addr *)RTA_DATA(rta)); break; case sizeof(struct in6_addr): zlog_debug(" %pI6", (struct in6_addr *)RTA_DATA(rta)); break; default: break; } break; case NDA_VLAN: vid = *(uint16_t *)RTA_DATA(rta); zlog_debug(" %d", vid); break; default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } static void nlifa_dump(struct ifaddrmsg *ifa, size_t msglen) { struct rtattr *rta; size_t plen; uint32_t u32v; /* Get the first attribute and go from there. */ rta = IFA_RTA(ifa); next_rta: /* Check the header for valid length and for outbound access. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); zlog_debug(" rta [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta->rta_type, ifa_rta2str(rta->rta_type)); switch (rta->rta_type) { case IFA_UNSPEC: u32v = *(uint32_t *)RTA_DATA(rta); zlog_debug(" %u", u32v); break; case IFA_LABEL: zlog_debug(" %s", (const char *)RTA_DATA(rta)); break; case IFA_ADDRESS: case IFA_LOCAL: case IFA_BROADCAST: switch (plen) { case 4: zlog_debug(" %pI4", (struct in_addr *)RTA_DATA(rta)); break; case 16: zlog_debug(" %pI6", (struct in6_addr *)RTA_DATA(rta)); break; default: break; } break; default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } static void nltnl_dump(struct tunnel_msg *tnlm, size_t msglen) { struct rtattr *attr; vni_t vni_start = 0, vni_end = 0; struct rtattr *ttb[VXLAN_VNIFILTER_ENTRY_MAX + 1]; uint8_t rta_type; attr = TUNNEL_RTA(tnlm); next_attr: /* Check the header for valid length and for outbound access. */ if (RTA_OK(attr, msglen) == 0) return; rta_type = attr->rta_type & NLA_TYPE_MASK; if (rta_type != VXLAN_VNIFILTER_ENTRY) { attr = RTA_NEXT(attr, msglen); goto next_attr; } memset(ttb, 0, sizeof(ttb)); netlink_parse_rtattr_flags(ttb, VXLAN_VNIFILTER_ENTRY_MAX, RTA_DATA(attr), RTA_PAYLOAD(attr), NLA_F_NESTED); if (ttb[VXLAN_VNIFILTER_ENTRY_START]) vni_start = *(uint32_t *)RTA_DATA(ttb[VXLAN_VNIFILTER_ENTRY_START]); if (ttb[VXLAN_VNIFILTER_ENTRY_END]) vni_end = *(uint32_t *)RTA_DATA(ttb[VXLAN_VNIFILTER_ENTRY_END]); zlog_debug(" vni_start %u, vni_end %u", vni_start, vni_end); attr = RTA_NEXT(attr, msglen); goto next_attr; } static const char *lwt_type2str(uint16_t type) { switch (type) { case LWTUNNEL_ENCAP_NONE: return "NONE"; case LWTUNNEL_ENCAP_MPLS: return "MPLS"; case LWTUNNEL_ENCAP_IP: return "IPv4"; case LWTUNNEL_ENCAP_ILA: return "ILA"; case LWTUNNEL_ENCAP_IP6: return "IPv6"; case LWTUNNEL_ENCAP_SEG6: return "SEG6"; case LWTUNNEL_ENCAP_BPF: return "BPF"; case LWTUNNEL_ENCAP_SEG6_LOCAL: return "SEG6_LOCAL"; default: return "UNKNOWN"; } } static const char *nhg_type2str(uint16_t type) { switch (type) { case NEXTHOP_GRP_TYPE_MPATH: return "MULTIPATH"; case NEXTHOP_GRP_TYPE_RES: return "RESILIENT MULTIPATH"; default: return "UNKNOWN"; } } static void nlnh_dump(struct nhmsg *nhm, size_t msglen) { struct rtattr *rta; int ifindex; size_t plen; uint16_t u16v; uint32_t u32v; unsigned long count, i; struct nexthop_grp *nhgrp; unsigned short rta_type; rta = RTM_NHA(nhm); next_rta: /* Check the header for valid length and for outbound access. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); rta_type = rta->rta_type & ~NLA_F_NESTED; zlog_debug(" rta [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta->rta_type, nhm_rta2str(rta_type)); switch (rta_type) { case NHA_ID: u32v = *(uint32_t *)RTA_DATA(rta); zlog_debug(" %u", u32v); break; case NHA_GROUP: nhgrp = (struct nexthop_grp *)RTA_DATA(rta); count = (RTA_PAYLOAD(rta) / sizeof(*nhgrp)); if (count == 0 || (count * sizeof(*nhgrp)) != RTA_PAYLOAD(rta)) { zlog_debug(" invalid nexthop group received"); return; } for (i = 0; i < count; i++) zlog_debug(" id %d weight %d", nhgrp[i].id, nhgrp[i].weight); break; case NHA_ENCAP_TYPE: u16v = *(uint16_t *)RTA_DATA(rta); zlog_debug(" %s", lwt_type2str(u16v)); break; case NHA_GROUP_TYPE: u16v = *(uint16_t *)RTA_DATA(rta); zlog_debug(" %s", nhg_type2str(u16v)); break; case NHA_BLACKHOLE: /* NOTHING */ break; case NHA_OIF: ifindex = *(int *)RTA_DATA(rta); zlog_debug(" %d", ifindex); break; case NHA_GATEWAY: switch (nhm->nh_family) { case AF_INET: zlog_debug(" %pI4", (struct in_addr *)RTA_DATA(rta)); break; case AF_INET6: zlog_debug(" %pI6", (struct in6_addr *)RTA_DATA(rta)); break; default: zlog_debug(" invalid family %d", nhm->nh_family); break; } break; case NHA_ENCAP: /* TODO: handle MPLS labels. */ zlog_debug(" unparsed MPLS labels"); break; case NHA_GROUPS: /* TODO: handle this message. */ zlog_debug(" unparsed GROUPS message"); break; default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } static void nlrule_dump(struct fib_rule_hdr *frh, size_t msglen) { struct rtattr *rta; size_t plen; uint8_t u8v; uint32_t u32v; int32_t s32v; uint64_t u64v; char dbuf[128]; struct fib_rule_uid_range *u_range; struct fib_rule_port_range *p_range; /* Get the first attribute and go from there. */ rta = RTM_RTA(frh); next_rta: /* Check the header for valid length and for outbound access. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); zlog_debug(" rta [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta->rta_type, frh_rta2str(rta->rta_type)); switch (rta->rta_type) { case FRA_DST: case FRA_SRC: switch (plen) { case sizeof(struct in_addr): zlog_debug(" %pI4", (struct in_addr *)RTA_DATA(rta)); break; case sizeof(struct in6_addr): zlog_debug(" %pI6", (struct in6_addr *)RTA_DATA(rta)); break; default: break; } break; case FRA_IIFNAME: case FRA_OIFNAME: snprintf(dbuf, sizeof(dbuf), "%s", (char *)RTA_DATA(rta)); zlog_debug(" %s", dbuf); break; case FRA_GOTO: case FRA_UNUSED2: case FRA_PRIORITY: case FRA_UNUSED3: case FRA_UNUSED4: case FRA_UNUSED5: case FRA_FWMARK: case FRA_FLOW: case FRA_TABLE: case FRA_FWMASK: u32v = *(uint32_t *)RTA_DATA(rta); zlog_debug(" %u", u32v); break; case FRA_SUPPRESS_IFGROUP: case FRA_SUPPRESS_PREFIXLEN: s32v = *(int32_t *)RTA_DATA(rta); zlog_debug(" %d", s32v); break; case FRA_TUN_ID: u64v = *(uint64_t *)RTA_DATA(rta); zlog_debug(" %" PRIu64, u64v); break; case FRA_L3MDEV: case FRA_PROTOCOL: case FRA_IP_PROTO: u8v = *(uint8_t *)RTA_DATA(rta); zlog_debug(" %u", u8v); break; case FRA_UID_RANGE: u_range = (struct fib_rule_uid_range *)RTA_DATA(rta); if (u_range->start == u_range->end) zlog_debug(" %u", u_range->start); else zlog_debug(" %u-%u", u_range->start, u_range->end); break; case FRA_SPORT_RANGE: case FRA_DPORT_RANGE: p_range = (struct fib_rule_port_range *)RTA_DATA(rta); if (p_range->start == p_range->end) zlog_debug(" %u", p_range->start); else zlog_debug(" %u-%u", p_range->start, p_range->end); break; case FRA_PAD: /* fallthrough */ default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } static const char *tcm_nltype2str(int nltype) { switch (nltype) { case RTM_NEWQDISC: case RTM_DELQDISC: return "qdisc"; case RTM_NEWTCLASS: case RTM_DELTCLASS: return "tclass"; case RTM_NEWTFILTER: case RTM_DELTFILTER: return "tfilter"; default: /* should never hit */ return "unknown"; } } static void nlncm_dump(const struct netconfmsg *ncm, size_t msglen) { const struct rtattr *rta; size_t plen; uint32_t ival; rta = (void *)((const char *)ncm + NLMSG_ALIGN(sizeof(struct netconfmsg))); next_rta: /* Check the attr header for valid length. */ if (RTA_OK(rta, msglen) == 0) return; plen = RTA_PAYLOAD(rta); zlog_debug(" rta [len=%d (payload=%zu) type=(%d) %s]", rta->rta_len, plen, rta->rta_type, ncm_rta2str(rta->rta_type)); switch (rta->rta_type) { case NETCONFA_IFINDEX: ival = *(uint32_t *)RTA_DATA(rta); zlog_debug(" %d", (int32_t)ival); break; /* Most attrs are just on/off. */ case NETCONFA_FORWARDING: case NETCONFA_RP_FILTER: case NETCONFA_MC_FORWARDING: case NETCONFA_PROXY_NEIGH: case NETCONFA_IGNORE_ROUTES_WITH_LINKDOWN: case NETCONFA_INPUT: case NETCONFA_BC_FORWARDING: ival = *(uint32_t *)RTA_DATA(rta); dump_on_off(ival, " "); break; default: /* NOTHING: unhandled. */ break; } /* Get next pointer and start iteration again. */ rta = RTA_NEXT(rta, msglen); goto next_rta; } void nl_dump(void *msg, size_t msglen) { struct nlmsghdr *nlmsg = msg; struct nlmsgerr *nlmsgerr; struct rtgenmsg *rtgen; struct ifaddrmsg *ifa; struct ndmsg *ndm; struct rtmsg *rtm; struct nhmsg *nhm; struct netconfmsg *ncm; struct ifinfomsg *ifi; struct tunnel_msg *tnlm; struct fib_rule_hdr *frh; struct tcmsg *tcm; char fbuf[128]; char ibuf[128]; next_header: zlog_debug( "nlmsghdr [len=%u type=(%d) %s flags=(0x%04x) {%s} seq=%u pid=%u]", nlmsg->nlmsg_len, nlmsg->nlmsg_type, nlmsg_type2str(nlmsg->nlmsg_type), nlmsg->nlmsg_flags, nlmsg_flags2str(nlmsg->nlmsg_flags, fbuf, sizeof(fbuf)), nlmsg->nlmsg_seq, nlmsg->nlmsg_pid); switch (nlmsg->nlmsg_type) { /* Generic. */ case NLMSG_NOOP: break; case NLMSG_ERROR: nlmsgerr = NLMSG_DATA(nlmsg); zlog_debug(" nlmsgerr [error=(%d) %s]", nlmsgerr->error, strerror(-nlmsgerr->error)); break; case NLMSG_DONE: return; case NLMSG_OVERRUN: break; /* RTM. */ case RTM_NEWLINK: case RTM_DELLINK: case RTM_SETLINK: ifi = NLMSG_DATA(nlmsg); zlog_debug( " ifinfomsg [family=%d type=(%d) %s index=%d flags=0x%04x {%s}]", ifi->ifi_family, ifi->ifi_type, ifi_type2str(ifi->ifi_type), ifi->ifi_index, ifi->ifi_flags, if_flags2str(ifi->ifi_flags, ibuf, sizeof(ibuf))); nllink_dump(ifi, nlmsg->nlmsg_len - NLMSG_LENGTH(sizeof(*ifi))); break; case RTM_GETLINK: rtgen = NLMSG_DATA(nlmsg); zlog_debug(" rtgen [family=(%d) %s]", rtgen->rtgen_family, af_type2str(rtgen->rtgen_family)); break; case RTM_NEWROUTE: case RTM_DELROUTE: case RTM_GETROUTE: rtm = NLMSG_DATA(nlmsg); zlog_debug( " rtmsg [family=(%d) %s dstlen=%d srclen=%d tos=%d table=%d protocol=(%d) %s scope=(%d) %s type=(%d) %s flags=0x%04x {%s}]", rtm->rtm_family, af_type2str(rtm->rtm_family), rtm->rtm_dst_len, rtm->rtm_src_len, rtm->rtm_tos, rtm->rtm_table, rtm->rtm_protocol, rtm_protocol2str(rtm->rtm_protocol), rtm->rtm_scope, rtm_scope2str(rtm->rtm_scope), rtm->rtm_type, rtm_type2str(rtm->rtm_type), rtm->rtm_flags, rtm_flags2str(rtm->rtm_flags, fbuf, sizeof(fbuf))); nlroute_dump(rtm, nlmsg->nlmsg_len - NLMSG_LENGTH(sizeof(*rtm))); break; case RTM_NEWNEIGH: case RTM_DELNEIGH: ndm = NLMSG_DATA(nlmsg); zlog_debug( " ndm [family=%d (%s) ifindex=%d state=0x%04x {%s} flags=0x%04x {%s} type=%d (%s)]", ndm->ndm_family, af_type2str(ndm->ndm_family), ndm->ndm_ifindex, ndm->ndm_state, neigh_state2str(ndm->ndm_state, ibuf, sizeof(ibuf)), ndm->ndm_flags, neigh_flags2str(ndm->ndm_flags, fbuf, sizeof(fbuf)), ndm->ndm_type, rtm_type2str(ndm->ndm_type)); nlneigh_dump(ndm, nlmsg->nlmsg_len - NLMSG_LENGTH(sizeof(*ndm))); break; case RTM_NEWRULE: case RTM_DELRULE: frh = NLMSG_DATA(nlmsg); zlog_debug( " frh [family=%d (%s) dst_len=%d src_len=%d tos=%d table=%d res1=%d res2=%d action=%d (%s) flags=0x%x]", frh->family, af_type2str(frh->family), frh->dst_len, frh->src_len, frh->tos, frh->table, frh->res1, frh->res2, frh->action, frh_action2str(frh->action), frh->flags); nlrule_dump(frh, nlmsg->nlmsg_len - NLMSG_LENGTH(sizeof(*frh))); break; case RTM_NEWADDR: case RTM_DELADDR: ifa = NLMSG_DATA(nlmsg); zlog_debug( " ifa [family=(%d) %s prefixlen=%d flags=0x%04x {%s} scope=%d index=%u]", ifa->ifa_family, af_type2str(ifa->ifa_family), ifa->ifa_prefixlen, ifa->ifa_flags, if_flags2str(ifa->ifa_flags, fbuf, sizeof(fbuf)), ifa->ifa_scope, ifa->ifa_index); nlifa_dump(ifa, nlmsg->nlmsg_len - NLMSG_LENGTH(sizeof(*ifa))); break; case RTM_NEWNEXTHOP: case RTM_DELNEXTHOP: case RTM_GETNEXTHOP: nhm = NLMSG_DATA(nlmsg); zlog_debug( " nhm [family=(%d) %s scope=(%d) %s protocol=(%d) %s flags=0x%08x {%s}]", nhm->nh_family, af_type2str(nhm->nh_family), nhm->nh_scope, rtm_scope2str(nhm->nh_scope), nhm->nh_protocol, rtm_protocol2str(nhm->nh_protocol), nhm->nh_flags, nh_flags2str(nhm->nh_flags, fbuf, sizeof(fbuf))); nlnh_dump(nhm, nlmsg->nlmsg_len - NLMSG_LENGTH(sizeof(*nhm))); break; case RTM_NEWTUNNEL: case RTM_DELTUNNEL: case RTM_GETTUNNEL: tnlm = NLMSG_DATA(nlmsg); zlog_debug(" tnlm [family=(%d) %s ifindex=%d ", tnlm->family, af_type2str(tnlm->family), tnlm->ifindex); nltnl_dump(tnlm, nlmsg->nlmsg_len - NLMSG_LENGTH(sizeof(struct tunnel_msg))); break; case RTM_NEWNETCONF: case RTM_DELNETCONF: ncm = NLMSG_DATA(nlmsg); zlog_debug(" ncm [family=%s (%d)]", af_type2str(ncm->ncm_family), ncm->ncm_family); nlncm_dump(ncm, nlmsg->nlmsg_len - NLMSG_LENGTH(sizeof(*ncm))); break; case RTM_NEWQDISC: case RTM_DELQDISC: case RTM_NEWTCLASS: case RTM_DELTCLASS: case RTM_NEWTFILTER: case RTM_DELTFILTER: tcm = NLMSG_DATA(nlmsg); zlog_debug( " tcm [type=%s family=%s (%d) ifindex=%d handle=%04x:%04x]", tcm_nltype2str(nlmsg->nlmsg_type), af_type2str(tcm->tcm_family), tcm->tcm_family, tcm->tcm_ifindex, tcm->tcm_handle >> 16, tcm->tcm_handle & 0xffff); break; default: break; } /* * Try to get the next header. There should only be more * messages if this header was flagged as MULTI, otherwise just * end it here. */ nlmsg = NLMSG_NEXT(nlmsg, msglen); if (NLMSG_OK(nlmsg, msglen) == 0) return; goto next_header; } #endif /* NETLINK_DEBUG */