// SPDX-License-Identifier: GPL-2.0-or-later /* Zebra's client header. * Copyright (C) 1999 Kunihiro Ishiguro */ #ifndef _ZEBRA_ZCLIENT_H #define _ZEBRA_ZCLIENT_H struct zclient; /* For struct zapi_route. */ #include "prefix.h" #include "ipaddr.h" /* For struct interface and struct connected. */ #include "if.h" /* For vrf_bitmap_t. */ #include "vrf.h" /* For union g_addr */ #include "nexthop.h" /* For resilience */ #include "nexthop_group.h" /* For union pw_protocol_fields */ #include "pw.h" #include "mlag.h" #include "srte.h" #include "srv6.h" #ifdef __cplusplus extern "C" { #endif /* Zebra types. Used in Zserv message header. */ typedef uint16_t zebra_size_t; /* Marker value used in new Zserv, in the byte location corresponding * the command value in the old zserv header. To allow old and new * Zserv headers to be distinguished from each other. */ #define ZEBRA_HEADER_MARKER 254 /* For input/output buffer to zebra. */ #define ZEBRA_MAX_PACKET_SIZ 16384U #define ZEBRA_SMALL_PACKET_SIZE 200U /* Zebra header size. */ #define ZEBRA_HEADER_SIZE 10 /* special socket path name to use TCP * @ is used as first character because that's abstract socket names on Linux */ #define ZAPI_TCP_PATHNAME "@tcp" /* IPset size name stands for the name of the ipset entry * that can be created by using some zapi interfaces */ #define ZEBRA_IPSET_NAME_SIZE 32 /* IPTable action is defined by two values: either * forward or drop */ #define ZEBRA_IPTABLES_FORWARD 0 #define ZEBRA_IPTABLES_DROP 1 /* Zebra FEC register command flags. */ #define ZEBRA_FEC_REGISTER_LABEL 0x1 #define ZEBRA_FEC_REGISTER_LABEL_INDEX 0x2 /* Client capabilities */ enum zserv_client_capabilities { ZEBRA_CLIENT_GR_CAPABILITIES = 1, ZEBRA_CLIENT_ROUTE_UPDATE_COMPLETE = 2, ZEBRA_CLIENT_ROUTE_UPDATE_PENDING = 3, ZEBRA_CLIENT_GR_DISABLE = 4, ZEBRA_CLIENT_RIB_STALE_TIME }; /* Macro to check if there GR enabled. */ #define ZEBRA_CLIENT_GR_ENABLED(X) (X == ZEBRA_CLIENT_GR_CAPABILITIES) #define ZEBRA_SR_POLICY_NAME_MAX_LENGTH 100 extern struct sockaddr_storage zclient_addr; extern socklen_t zclient_addr_len; /* Zebra message types. */ typedef enum { ZEBRA_INTERFACE_ADD, ZEBRA_INTERFACE_DELETE, ZEBRA_INTERFACE_ADDRESS_ADD, ZEBRA_INTERFACE_ADDRESS_DELETE, ZEBRA_INTERFACE_UP, ZEBRA_INTERFACE_DOWN, ZEBRA_INTERFACE_SET_MASTER, ZEBRA_INTERFACE_SET_PROTODOWN, ZEBRA_ROUTE_ADD, ZEBRA_ROUTE_DELETE, ZEBRA_ROUTE_NOTIFY_OWNER, ZEBRA_REDISTRIBUTE_ADD, ZEBRA_REDISTRIBUTE_DELETE, ZEBRA_REDISTRIBUTE_DEFAULT_ADD, ZEBRA_REDISTRIBUTE_DEFAULT_DELETE, ZEBRA_ROUTER_ID_ADD, ZEBRA_ROUTER_ID_DELETE, ZEBRA_ROUTER_ID_UPDATE, ZEBRA_HELLO, ZEBRA_CAPABILITIES, ZEBRA_NEXTHOP_REGISTER, ZEBRA_NEXTHOP_UNREGISTER, ZEBRA_NEXTHOP_UPDATE, ZEBRA_INTERFACE_NBR_ADDRESS_ADD, ZEBRA_INTERFACE_NBR_ADDRESS_DELETE, ZEBRA_INTERFACE_BFD_DEST_UPDATE, ZEBRA_BFD_DEST_REGISTER, ZEBRA_BFD_DEST_DEREGISTER, ZEBRA_BFD_DEST_UPDATE, ZEBRA_BFD_DEST_REPLAY, ZEBRA_REDISTRIBUTE_ROUTE_ADD, ZEBRA_REDISTRIBUTE_ROUTE_DEL, ZEBRA_VRF_UNREGISTER, ZEBRA_VRF_ADD, ZEBRA_VRF_DELETE, ZEBRA_VRF_LABEL, ZEBRA_INTERFACE_VRF_UPDATE, ZEBRA_BFD_CLIENT_REGISTER, ZEBRA_BFD_CLIENT_DEREGISTER, ZEBRA_INTERFACE_ENABLE_RADV, ZEBRA_INTERFACE_DISABLE_RADV, ZEBRA_NEXTHOP_LOOKUP_MRIB, ZEBRA_INTERFACE_LINK_PARAMS, ZEBRA_MPLS_LABELS_ADD, ZEBRA_MPLS_LABELS_DELETE, ZEBRA_MPLS_LABELS_REPLACE, ZEBRA_SR_POLICY_SET, ZEBRA_SR_POLICY_DELETE, ZEBRA_SR_POLICY_NOTIFY_STATUS, ZEBRA_IPMR_ROUTE_STATS, ZEBRA_LABEL_MANAGER_CONNECT, ZEBRA_LABEL_MANAGER_CONNECT_ASYNC, ZEBRA_GET_LABEL_CHUNK, ZEBRA_RELEASE_LABEL_CHUNK, ZEBRA_FEC_REGISTER, ZEBRA_FEC_UNREGISTER, ZEBRA_FEC_UPDATE, ZEBRA_ADVERTISE_DEFAULT_GW, ZEBRA_ADVERTISE_SVI_MACIP, ZEBRA_ADVERTISE_SUBNET, ZEBRA_ADVERTISE_ALL_VNI, ZEBRA_LOCAL_ES_ADD, ZEBRA_LOCAL_ES_DEL, ZEBRA_REMOTE_ES_VTEP_ADD, ZEBRA_REMOTE_ES_VTEP_DEL, ZEBRA_LOCAL_ES_EVI_ADD, ZEBRA_LOCAL_ES_EVI_DEL, ZEBRA_VNI_ADD, ZEBRA_VNI_DEL, ZEBRA_L3VNI_ADD, ZEBRA_L3VNI_DEL, ZEBRA_REMOTE_VTEP_ADD, ZEBRA_REMOTE_VTEP_DEL, ZEBRA_MACIP_ADD, ZEBRA_MACIP_DEL, ZEBRA_IP_PREFIX_ROUTE_ADD, ZEBRA_IP_PREFIX_ROUTE_DEL, ZEBRA_REMOTE_MACIP_ADD, ZEBRA_REMOTE_MACIP_DEL, ZEBRA_DUPLICATE_ADDR_DETECTION, ZEBRA_PW_ADD, ZEBRA_PW_DELETE, ZEBRA_PW_SET, ZEBRA_PW_UNSET, ZEBRA_PW_STATUS_UPDATE, ZEBRA_RULE_ADD, ZEBRA_RULE_DELETE, ZEBRA_RULE_NOTIFY_OWNER, ZEBRA_TABLE_MANAGER_CONNECT, ZEBRA_GET_TABLE_CHUNK, ZEBRA_RELEASE_TABLE_CHUNK, ZEBRA_IPSET_CREATE, ZEBRA_IPSET_DESTROY, ZEBRA_IPSET_ENTRY_ADD, ZEBRA_IPSET_ENTRY_DELETE, ZEBRA_IPSET_NOTIFY_OWNER, ZEBRA_IPSET_ENTRY_NOTIFY_OWNER, ZEBRA_IPTABLE_ADD, ZEBRA_IPTABLE_DELETE, ZEBRA_IPTABLE_NOTIFY_OWNER, ZEBRA_VXLAN_FLOOD_CONTROL, ZEBRA_VXLAN_SG_ADD, ZEBRA_VXLAN_SG_DEL, ZEBRA_VXLAN_SG_REPLAY, ZEBRA_MLAG_PROCESS_UP, ZEBRA_MLAG_PROCESS_DOWN, ZEBRA_MLAG_CLIENT_REGISTER, ZEBRA_MLAG_CLIENT_UNREGISTER, ZEBRA_MLAG_FORWARD_MSG, ZEBRA_NHG_ADD, ZEBRA_NHG_DEL, ZEBRA_NHG_NOTIFY_OWNER, ZEBRA_EVPN_REMOTE_NH_ADD, ZEBRA_EVPN_REMOTE_NH_DEL, ZEBRA_SRV6_LOCATOR_ADD, ZEBRA_SRV6_LOCATOR_DELETE, ZEBRA_SRV6_MANAGER_GET_LOCATOR_CHUNK, ZEBRA_SRV6_MANAGER_RELEASE_LOCATOR_CHUNK, ZEBRA_ERROR, ZEBRA_CLIENT_CAPABILITIES, ZEBRA_OPAQUE_MESSAGE, ZEBRA_OPAQUE_REGISTER, ZEBRA_OPAQUE_UNREGISTER, ZEBRA_NEIGH_DISCOVER, ZEBRA_ROUTE_NOTIFY_REQUEST, ZEBRA_CLIENT_CLOSE_NOTIFY, ZEBRA_NHRP_NEIGH_ADDED, ZEBRA_NHRP_NEIGH_REMOVED, ZEBRA_NHRP_NEIGH_GET, ZEBRA_NHRP_NEIGH_REGISTER, ZEBRA_NHRP_NEIGH_UNREGISTER, ZEBRA_NEIGH_IP_ADD, ZEBRA_NEIGH_IP_DEL, ZEBRA_CONFIGURE_ARP, ZEBRA_GRE_GET, ZEBRA_GRE_UPDATE, ZEBRA_GRE_SOURCE_SET, ZEBRA_TC_QDISC_INSTALL, ZEBRA_TC_QDISC_UNINSTALL, ZEBRA_TC_CLASS_ADD, ZEBRA_TC_CLASS_DELETE, ZEBRA_TC_FILTER_ADD, ZEBRA_TC_FILTER_DELETE, } zebra_message_types_t; enum zebra_error_types { ZEBRA_UNKNOWN_ERROR, /* Error of unknown type */ ZEBRA_NO_VRF, /* Vrf in header was not found */ ZEBRA_INVALID_MSG_TYPE, /* No handler found for msg type */ }; static inline const char *zebra_error_type2str(enum zebra_error_types type) { const char *ret = "UNKNOWN"; switch (type) { case ZEBRA_UNKNOWN_ERROR: ret = "ZEBRA_UNKNOWN_ERROR"; break; case ZEBRA_NO_VRF: ret = "ZEBRA_NO_VRF"; break; case ZEBRA_INVALID_MSG_TYPE: ret = "ZEBRA_INVALID_MSG_TYPE"; break; } return ret; } struct redist_proto { uint8_t enabled; struct list *instances; }; struct zclient_capabilities { uint32_t ecmp; bool mpls_enabled; enum mlag_role role; }; /* Graceful Restart Capabilities message */ struct zapi_cap { enum zserv_client_capabilities cap; uint32_t stale_removal_time; afi_t afi; safi_t safi; vrf_id_t vrf_id; }; /* clang-format off */ #define ZAPI_CALLBACK_ARGS \ int cmd, struct zclient *zclient, uint16_t length, vrf_id_t vrf_id /* function-type typedef (pointer not included) */ typedef int (zclient_handler)(ZAPI_CALLBACK_ARGS); /* clang-format on */ /* Structure for the zebra client. */ struct zclient { /* The thread master we schedule ourselves on */ struct event_loop *master; /* Privileges to change socket values */ struct zebra_privs_t *privs; /* Do we care about failure events for route install? */ bool receive_notify; /* Is this a synchronous client? */ bool synchronous; /* BFD enabled with bfd_protocol_integration_init() */ bool bfd_integration; /* Session id (optional) to support clients with multiple sessions */ uint32_t session_id; /* Socket to zebra daemon. */ int sock; /* Connection failure count. */ int fail; /* Input buffer for zebra message. */ struct stream *ibuf; /* Output buffer for zebra message. */ struct stream *obuf; /* Buffer of data waiting to be written to zebra. */ struct buffer *wb; /* Read and connect thread. */ struct event *t_read; struct event *t_connect; /* Thread to write buffered data to zebra. */ struct event *t_write; /* Redistribute information. */ uint8_t redist_default; /* clients protocol */ unsigned short instance; struct redist_proto mi_redist[AFI_MAX][ZEBRA_ROUTE_MAX]; vrf_bitmap_t redist[AFI_MAX][ZEBRA_ROUTE_MAX]; /* Redistribute default. */ vrf_bitmap_t default_information[AFI_MAX]; /* Pointer to the callback functions. */ void (*zebra_connected)(struct zclient *); void (*zebra_capabilities)(struct zclient_capabilities *cap); int (*handle_error)(enum zebra_error_types error); /* * When the zclient attempts to write the stream data to * it's named pipe to/from zebra, we may have a situation * where the other daemon has not fully drained the data * from the socket. In this case provide a mechanism * where we will *still* buffer the data to be sent * and also provide a callback mechanism to the appropriate * place where we can signal that we're ready to receive * more data. */ void (*zebra_buffer_write_ready)(void); zclient_handler *const *handlers; size_t n_handlers; }; /* lib handlers added in bfd.c */ extern int zclient_bfd_session_replay(ZAPI_CALLBACK_ARGS); extern int zclient_bfd_session_update(ZAPI_CALLBACK_ARGS); /* Zebra API message flag. */ #define ZAPI_MESSAGE_NEXTHOP 0x01 #define ZAPI_MESSAGE_DISTANCE 0x02 #define ZAPI_MESSAGE_METRIC 0x04 #define ZAPI_MESSAGE_TAG 0x08 #define ZAPI_MESSAGE_MTU 0x10 #define ZAPI_MESSAGE_SRCPFX 0x20 /* Backup nexthops are present */ #define ZAPI_MESSAGE_BACKUP_NEXTHOPS 0x40 #define ZAPI_MESSAGE_NHG 0x80 /* * This should only be used by a DAEMON that needs to communicate * the table being used is not in the VRF. You must pass the * default vrf, else this will be ignored. */ #define ZAPI_MESSAGE_TABLEID 0x0100 #define ZAPI_MESSAGE_SRTE 0x0200 #define ZAPI_MESSAGE_OPAQUE 0x0400 #define ZSERV_VERSION 6 /* Zserv protocol message header */ struct zmsghdr { uint16_t length; /* Always set to 255 in new zserv */ uint8_t marker; uint8_t version; vrf_id_t vrf_id; uint16_t command; } __attribute__((packed)); #define ZAPI_HEADER_CMD_LOCATION offsetof(struct zmsghdr, command) /* * ZAPI nexthop. Note that these are sorted when associated with ZAPI routes, * and that sorting must be aligned with the sorting of nexthops in * lib/nexthop.c. Any new fields must be accounted for in zapi_nexthop_cmp(). */ struct zapi_nexthop { enum nexthop_types_t type; vrf_id_t vrf_id; ifindex_t ifindex; uint8_t flags; union { union g_addr gate; enum blackhole_type bh_type; }; /* MPLS labels for BGP-LU or Segment Routing */ uint8_t label_num; enum lsp_types_t label_type; mpls_label_t labels[MPLS_MAX_LABELS]; struct ethaddr rmac; uint32_t weight; /* Backup nexthops, for IP-FRR, TI-LFA, etc */ uint8_t backup_num; uint8_t backup_idx[NEXTHOP_MAX_BACKUPS]; /* SR-TE color. */ uint32_t srte_color; /* SRv6 localsid info for Endpoint-behaviour */ uint32_t seg6local_action; struct seg6local_context seg6local_ctx; /* SRv6 Headend-behaviour */ struct in6_addr seg6_segs; }; /* * ZAPI nexthop flags values - we're encoding a single octet * initially, so ensure that the on-the-wire encoding continues * to match the number of valid flags. */ #define ZAPI_NEXTHOP_FLAG_ONLINK 0x01 #define ZAPI_NEXTHOP_FLAG_LABEL 0x02 #define ZAPI_NEXTHOP_FLAG_WEIGHT 0x04 #define ZAPI_NEXTHOP_FLAG_HAS_BACKUP 0x08 /* Nexthop has a backup */ #define ZAPI_NEXTHOP_FLAG_SEG6 0x10 #define ZAPI_NEXTHOP_FLAG_SEG6LOCAL 0x20 #define ZAPI_NEXTHOP_FLAG_EVPN 0x40 /* * ZAPI Nexthop Group. For use with protocol creation of nexthop groups. */ struct zapi_nhg { uint16_t proto; uint32_t id; struct nhg_resilience resilience; uint16_t nexthop_num; struct zapi_nexthop nexthops[MULTIPATH_NUM]; uint16_t backup_nexthop_num; struct zapi_nexthop backup_nexthops[MULTIPATH_NUM]; }; /* * Some of these data structures do not map easily to * a actual data structure size giving different compilers * and systems. For those data structures we need * to use the smallest available stream_getX/putX functions * to encode/decode. */ struct zapi_route { uint8_t type; unsigned short instance; /* If you add flags, update zclient_dump_route_flags */ uint32_t flags; /* * Cause Zebra to consider this routes nexthops recursively */ #define ZEBRA_FLAG_ALLOW_RECURSION 0x01 /* * This is a route that is read in on startup that was left around * from a previous run of FRR */ #define ZEBRA_FLAG_SELFROUTE 0x02 /* * This flag is used to tell Zebra that the BGP route being passed * down is a IBGP route */ #define ZEBRA_FLAG_IBGP 0x04 /* * This is a route that has been selected for FIB installation. * This flag is set in zebra and can be passed up to routing daemons */ #define ZEBRA_FLAG_SELECTED 0x08 /* * This is a route that we are telling Zebra that this route *must* * win and will be installed even over ZEBRA_FLAG_SELECTED */ #define ZEBRA_FLAG_FIB_OVERRIDE 0x10 /* * This flag tells Zebra that the route is a EVPN route and should * be treated specially */ #define ZEBRA_FLAG_EVPN_ROUTE 0x20 /* * This flag tells Zebra that it should treat the distance passed * down as an additional discriminator for route selection of the * route entry. This mainly is used for backup static routes. */ #define ZEBRA_FLAG_RR_USE_DISTANCE 0x40 /* * This flag tells everyone that the route was intentionally * not offloaded and the route will be sent to the cpu for * forwarding. This flag makes no sense unless you are in * an asic offload situation */ #define ZEBRA_FLAG_TRAPPED 0x80 /* * This flag tells everyone that the route has been * successfully offloaded to an asic for forwarding. * This flag makes no sense unless you are in an asic * offload situation. */ #define ZEBRA_FLAG_OFFLOADED 0x100 /* * This flag tells everyone that the route has * failed offloading. * This flag makes no sense unless you are in an asic * offload situation. */ #define ZEBRA_FLAG_OFFLOAD_FAILED 0x200 /* * This flag lets us know that we think the route entry * received has caused us to be out of sync with the * kernel (NLM_F_APPEND at the very least ) */ #define ZEBRA_FLAG_OUTOFSYNC 0x400 /* The older XXX_MESSAGE flags live here */ uint32_t message; /* * This is an enum but we are going to treat it as a uint8_t * for purpose of encoding/decoding */ safi_t safi; struct prefix prefix; struct prefix_ipv6 src_prefix; uint16_t nexthop_num; struct zapi_nexthop nexthops[MULTIPATH_NUM]; /* Support backup routes for IP FRR, TI-LFA, traffic engineering */ uint16_t backup_nexthop_num; struct zapi_nexthop backup_nexthops[MULTIPATH_NUM]; uint32_t nhgid; uint8_t distance; uint32_t metric; route_tag_t tag; uint32_t mtu; vrf_id_t vrf_id; uint32_t tableid; /* SR-TE color (used for nexthop updates only). */ uint32_t srte_color; #define ZAPI_MESSAGE_OPAQUE_LENGTH 1024 struct { uint16_t length; uint8_t data[ZAPI_MESSAGE_OPAQUE_LENGTH]; } opaque; }; extern char *zclient_dump_route_flags(uint32_t flags, char *buf, size_t len); struct zapi_labels { uint8_t message; #define ZAPI_LABELS_FTN 0x01 #define ZAPI_LABELS_HAS_BACKUPS 0x02 enum lsp_types_t type; mpls_label_t local_label; struct { struct prefix prefix; uint8_t type; unsigned short instance; } route; uint16_t nexthop_num; struct zapi_nexthop nexthops[MULTIPATH_NUM]; /* Backup nexthops, if present */ uint16_t backup_nexthop_num; struct zapi_nexthop backup_nexthops[MULTIPATH_NUM]; }; struct zapi_srte_tunnel { enum lsp_types_t type; mpls_label_t local_label; uint8_t label_num; mpls_label_t labels[MPLS_MAX_LABELS]; }; struct zapi_sr_policy { uint32_t color; struct ipaddr endpoint; char name[SRTE_POLICY_NAME_MAX_LENGTH]; struct zapi_srte_tunnel segment_list; int status; }; struct zapi_pw { char ifname[INTERFACE_NAMSIZ]; ifindex_t ifindex; int type; int af; union g_addr nexthop; uint32_t local_label; uint32_t remote_label; uint8_t flags; union pw_protocol_fields data; uint8_t protocol; }; struct zapi_pw_status { char ifname[INTERFACE_NAMSIZ]; ifindex_t ifindex; uint32_t status; }; /* IGP instance data associated to a RLFA. */ struct zapi_rlfa_igp { vrf_id_t vrf_id; int protocol; union { struct { char area_tag[32]; struct { int tree_id; int level; unsigned int run_id; } spf; } isis; }; }; /* IGP -> LDP RLFA (un)registration message. */ struct zapi_rlfa_request { /* IGP instance data. */ struct zapi_rlfa_igp igp; /* Destination prefix. */ struct prefix destination; /* PQ node address. */ struct in_addr pq_address; }; /* LDP -> IGP RLFA label update. */ struct zapi_rlfa_response { /* IGP instance data. */ struct zapi_rlfa_igp igp; /* Destination prefix. */ struct prefix destination; /* Resolved LDP labels. */ mpls_label_t pq_label; uint16_t nexthop_num; struct { int family; union g_addr gate; mpls_label_t label; } nexthops[MULTIPATH_NUM]; }; enum zapi_route_notify_owner { ZAPI_ROUTE_FAIL_INSTALL, ZAPI_ROUTE_BETTER_ADMIN_WON, ZAPI_ROUTE_INSTALLED, ZAPI_ROUTE_REMOVED, ZAPI_ROUTE_REMOVE_FAIL, }; enum zapi_nhg_notify_owner { ZAPI_NHG_FAIL_INSTALL, ZAPI_NHG_INSTALLED, ZAPI_NHG_REMOVED, ZAPI_NHG_REMOVE_FAIL, }; enum zapi_rule_notify_owner { ZAPI_RULE_FAIL_INSTALL, ZAPI_RULE_INSTALLED, ZAPI_RULE_REMOVED, ZAPI_RULE_FAIL_REMOVE, }; enum ipset_type { IPSET_NET_NET = 1, IPSET_NET_PORT_NET, IPSET_NET_PORT, IPSET_NET }; enum zapi_ipset_notify_owner { ZAPI_IPSET_FAIL_INSTALL = 0, ZAPI_IPSET_INSTALLED, ZAPI_IPSET_REMOVED, ZAPI_IPSET_FAIL_REMOVE, }; enum zapi_ipset_entry_notify_owner { ZAPI_IPSET_ENTRY_FAIL_INSTALL = 0, ZAPI_IPSET_ENTRY_INSTALLED, ZAPI_IPSET_ENTRY_REMOVED, ZAPI_IPSET_ENTRY_FAIL_REMOVE, }; enum zapi_iptable_notify_owner { ZAPI_IPTABLE_FAIL_INSTALL = 0, ZAPI_IPTABLE_INSTALLED, ZAPI_IPTABLE_REMOVED, ZAPI_IPTABLE_FAIL_REMOVE, }; enum zclient_send_status { ZCLIENT_SEND_FAILURE = -1, ZCLIENT_SEND_SUCCESS = 0, ZCLIENT_SEND_BUFFERED = 1 }; static inline const char * zapi_nhg_notify_owner2str(enum zapi_nhg_notify_owner note) { const char *ret = "UNKNOWN"; switch (note) { case ZAPI_NHG_FAIL_INSTALL: ret = "ZAPI_NHG_FAIL_INSTALL"; break; case ZAPI_NHG_INSTALLED: ret = "ZAPI_NHG_INSTALLED"; break; case ZAPI_NHG_REMOVE_FAIL: ret = "ZAPI_NHG_REMOVE_FAIL"; break; case ZAPI_NHG_REMOVED: ret = "ZAPI_NHG_REMOVED"; break; } return ret; } static inline const char * zapi_rule_notify_owner2str(enum zapi_rule_notify_owner note) { const char *ret = "UNKNOWN"; switch (note) { case ZAPI_RULE_FAIL_INSTALL: ret = "ZAPI_RULE_FAIL_INSTALL"; break; case ZAPI_RULE_INSTALLED: ret = "ZAPI_RULE_INSTALLED"; break; case ZAPI_RULE_FAIL_REMOVE: ret = "ZAPI_RULE_FAIL_REMOVE"; break; case ZAPI_RULE_REMOVED: ret = "ZAPI_RULE_REMOVED"; break; } return ret; } /* Zebra MAC types */ #define ZEBRA_MACIP_TYPE_STICKY 0x01 /* Sticky MAC*/ #define ZEBRA_MACIP_TYPE_GW 0x02 /* gateway (SVI) mac*/ #define ZEBRA_MACIP_TYPE_ROUTER_FLAG 0x04 /* Router Flag - proxy NA */ #define ZEBRA_MACIP_TYPE_OVERRIDE_FLAG 0x08 /* Override Flag */ #define ZEBRA_MACIP_TYPE_SVI_IP 0x10 /* SVI MAC-IP */ #define ZEBRA_MACIP_TYPE_PROXY_ADVERT 0x20 /* Not locally active */ #define ZEBRA_MACIP_TYPE_SYNC_PATH 0x40 /* sync path */ /* XXX - flags is an u8; that needs to be changed to u32 if you need * to allocate past 0x80. Additionally touch zclient_evpn_dump_macip_flags */ #define MACIP_BUF_SIZE 128 extern char *zclient_evpn_dump_macip_flags(uint8_t flags, char *buf, size_t len); /* Zebra ES VTEP flags (ZEBRA_REMOTE_ES_VTEP_ADD) */ /* ESR has been rxed from the VTEP. Only VTEPs that have advertised the * Type-4 route can participate in DF election. */ #define ZAPI_ES_VTEP_FLAG_ESR_RXED (1 << 0) enum zebra_neigh_state { ZEBRA_NEIGH_INACTIVE = 0, ZEBRA_NEIGH_ACTIVE = 1 }; struct zclient_options { bool receive_notify; bool synchronous; }; extern struct zclient_options zclient_options_default; /* link layer representation for GRE like interfaces * ip_in is the underlay IP, ip_out is the tunnel dest * index stands for the index of the interface * ndm state stands for the NDM value in netlink * (see linux/neighbour.h) */ #define ZEBRA_NEIGH_STATE_INCOMPLETE (0x01) #define ZEBRA_NEIGH_STATE_REACHABLE (0x02) #define ZEBRA_NEIGH_STATE_STALE (0x04) #define ZEBRA_NEIGH_STATE_DELAY (0x08) #define ZEBRA_NEIGH_STATE_PROBE (0x10) #define ZEBRA_NEIGH_STATE_FAILED (0x20) #define ZEBRA_NEIGH_STATE_NOARP (0x40) #define ZEBRA_NEIGH_STATE_PERMANENT (0x80) #define ZEBRA_NEIGH_STATE_NONE (0x00) struct zapi_neigh_ip { int cmd; struct ipaddr ip_in; struct ipaddr ip_out; ifindex_t index; uint32_t ndm_state; }; int zclient_neigh_ip_decode(struct stream *s, struct zapi_neigh_ip *api); int zclient_neigh_ip_encode(struct stream *s, uint16_t cmd, union sockunion *in, union sockunion *out, struct interface *ifp, int ndm_state); /* * We reserve the top 4 bits for l2-NHG, everything else * is for zebra/proto l3-NHG. * * Each client is going to get it's own nexthop group space * and we'll separate them, we'll figure out where to start based upon * the route_types.h */ #define ZEBRA_NHG_PROTO_UPPER \ ((uint32_t)250000000) /* Bottom 28 bits then rounded down */ #define ZEBRA_NHG_PROTO_SPACING (ZEBRA_NHG_PROTO_UPPER / ZEBRA_ROUTE_MAX) #define ZEBRA_NHG_PROTO_LOWER \ (ZEBRA_NHG_PROTO_SPACING * (ZEBRA_ROUTE_CONNECT + 1)) extern uint32_t zclient_get_nhg_start(uint32_t proto); extern struct zclient *zclient_new(struct event_loop *m, struct zclient_options *opt, zclient_handler *const *handlers, size_t n_handlers); extern void zclient_init(struct zclient *, int, unsigned short, struct zebra_privs_t *privs); extern int zclient_start(struct zclient *); extern void zclient_stop(struct zclient *); extern void zclient_reset(struct zclient *); extern void zclient_free(struct zclient *); extern int zclient_socket_connect(struct zclient *); extern unsigned short *redist_check_instance(struct redist_proto *, unsigned short); extern void redist_add_instance(struct redist_proto *, unsigned short); extern void redist_del_instance(struct redist_proto *, unsigned short); extern void redist_del_all_instances(struct redist_proto *red); /* * Send to zebra that the specified vrf is using label to resolve * itself for L3VPN's. Repeated calls of this function with * different labels will cause an effective update of the * label for lookup. If you pass in MPLS_LABEL_NONE * we will cause a delete action and remove this label pop * operation. * * The underlying AF_MPLS doesn't care about afi's * but we can make the zebra_vrf keep track of what * we have installed and play some special games * to get them both installed. */ extern enum zclient_send_status zclient_send_vrf_label(struct zclient *zclient, vrf_id_t vrf_id, afi_t afi, mpls_label_t label, enum lsp_types_t ltype); extern enum zclient_send_status zclient_send_localsid(struct zclient *zclient, const struct in6_addr *sid, ifindex_t oif, enum seg6local_action_t action, const struct seg6local_context *context); extern void zclient_send_reg_requests(struct zclient *, vrf_id_t); extern void zclient_send_dereg_requests(struct zclient *, vrf_id_t); extern enum zclient_send_status zclient_send_router_id_update(struct zclient *zclient, zebra_message_types_t type, afi_t afi, vrf_id_t vrf_id); extern enum zclient_send_status zclient_send_interface_radv_req(struct zclient *zclient, vrf_id_t vrf_id, struct interface *ifp, int enable, uint32_t ra_interval); extern enum zclient_send_status zclient_send_interface_protodown(struct zclient *zclient, vrf_id_t vrf_id, struct interface *ifp, bool down); /* Send redistribute command to zebra daemon. Do not update zclient state. */ extern enum zclient_send_status zebra_redistribute_send(int command, struct zclient *, afi_t, int type, unsigned short instance, vrf_id_t vrf_id); extern enum zclient_send_status zebra_redistribute_default_send(int command, struct zclient *zclient, afi_t afi, vrf_id_t vrf_id); /* Send route notify request to zebra */ extern int zebra_route_notify_send(int command, struct zclient *zclient, bool set); /* If state has changed, update state and call zebra_redistribute_send. */ extern void zclient_redistribute(int command, struct zclient *, afi_t, int type, unsigned short instance, vrf_id_t vrf_id); /* If state has changed, update state and send the command to zebra. */ extern void zclient_redistribute_default(int command, struct zclient *, afi_t, vrf_id_t vrf_id); /* * Send the message in zclient->obuf to the zebra daemon (or enqueue it). * Returns: * -1 on a I/O error * 0 data was successfully sent * 1 data was buffered for future usage */ extern enum zclient_send_status zclient_send_message(struct zclient *); /* create header for command, length to be filled in by user later */ extern void zclient_create_header(struct stream *, uint16_t, vrf_id_t); /* * Read sizeof(struct zmsghdr) bytes from the provided socket and parse the * received data into the specified fields. If this is successful, read the * rest of the packet into the provided stream. * * s * The stream to read into * * sock * The socket to read from * * size * Parsed message size will be placed in the pointed-at integer * * marker * Parsed marker will be placed in the pointed-at byte * * version * Parsed version will be placed in the pointed-at byte * * vrf_id * Parsed VRF ID will be placed in the pointed-at vrf_id_t * * cmd * Parsed command number will be placed in the pointed-at integer * * Returns: * -1 if: * - insufficient data for header was read * - a version mismatch was detected * - a marker mismatch was detected * - header size field specified more data than could be read */ extern int zclient_read_header(struct stream *s, int sock, uint16_t *size, uint8_t *marker, uint8_t *version, vrf_id_t *vrf_id, uint16_t *cmd); /* * Parse header from ZAPI message stream into struct zmsghdr. * This function assumes the stream getp points at the first byte of the header. * If the function is successful then the stream getp will point to the byte * immediately after the last byte of the header. * * zmsg * The stream containing the header * * hdr * The header struct to parse into. * * Returns: * true if parsing succeeded, false otherwise */ extern bool zapi_parse_header(struct stream *zmsg, struct zmsghdr *hdr); extern enum zclient_send_status zclient_interface_set_master(struct zclient *client, struct interface *master, struct interface *slave); extern struct interface *zebra_interface_state_read(struct stream *s, vrf_id_t); extern struct connected *zebra_interface_address_read(int, struct stream *, vrf_id_t); extern struct nbr_connected * zebra_interface_nbr_address_read(int, struct stream *, vrf_id_t); extern struct interface *zebra_interface_vrf_update_read(struct stream *s, vrf_id_t vrf_id, vrf_id_t *new_vrf_id); extern int zebra_router_id_update_read(struct stream *s, struct prefix *rid); extern struct interface *zebra_interface_link_params_read(struct stream *s, vrf_id_t vrf_id, bool *changed); extern size_t zebra_interface_link_params_write(struct stream *, struct interface *); extern enum zclient_send_status zclient_send_get_label_chunk(struct zclient *zclient, uint8_t keep, uint32_t chunk_size, uint32_t base); extern int lm_label_manager_connect(struct zclient *zclient, int async); extern int lm_get_label_chunk(struct zclient *zclient, uint8_t keep, uint32_t base, uint32_t chunk_size, uint32_t *start, uint32_t *end); extern int lm_release_label_chunk(struct zclient *zclient, uint32_t start, uint32_t end); extern int tm_table_manager_connect(struct zclient *zclient); extern int tm_get_table_chunk(struct zclient *zclient, uint32_t chunk_size, uint32_t *start, uint32_t *end); extern int tm_release_table_chunk(struct zclient *zclient, uint32_t start, uint32_t end); extern int srv6_manager_get_locator_chunk(struct zclient *zclient, const char *locator_name); extern int srv6_manager_release_locator_chunk(struct zclient *zclient, const char *locator_name); extern enum zclient_send_status zebra_send_sr_policy(struct zclient *zclient, int cmd, struct zapi_sr_policy *zp); extern int zapi_sr_policy_encode(struct stream *s, int cmd, struct zapi_sr_policy *zp); extern int zapi_sr_policy_decode(struct stream *s, struct zapi_sr_policy *zp); extern int zapi_sr_policy_notify_status_decode(struct stream *s, struct zapi_sr_policy *zp); extern enum zclient_send_status zebra_send_mpls_labels(struct zclient *zclient, int cmd, struct zapi_labels *zl); extern int zapi_labels_encode(struct stream *s, int cmd, struct zapi_labels *zl); extern int zapi_labels_decode(struct stream *s, struct zapi_labels *zl); extern int zapi_srv6_locator_encode(struct stream *s, const struct srv6_locator *l); extern int zapi_srv6_locator_decode(struct stream *s, struct srv6_locator *l); extern int zapi_srv6_locator_chunk_encode(struct stream *s, const struct srv6_locator_chunk *c); extern int zapi_srv6_locator_chunk_decode(struct stream *s, struct srv6_locator_chunk *c); extern enum zclient_send_status zebra_send_pw(struct zclient *zclient, int command, struct zapi_pw *pw); extern int zebra_read_pw_status_update(ZAPI_CALLBACK_ARGS, struct zapi_pw_status *pw); extern enum zclient_send_status zclient_route_send(uint8_t, struct zclient *, struct zapi_route *); extern enum zclient_send_status zclient_send_rnh(struct zclient *zclient, int command, const struct prefix *p, safi_t safi, bool connected, bool resolve_via_default, vrf_id_t vrf_id); int zapi_nexthop_encode(struct stream *s, const struct zapi_nexthop *api_nh, uint32_t api_flags, uint32_t api_message); extern int zapi_route_encode(uint8_t, struct stream *, struct zapi_route *); extern int zapi_route_decode(struct stream *s, struct zapi_route *api); extern int zapi_nexthop_decode(struct stream *s, struct zapi_nexthop *api_nh, uint32_t api_flags, uint32_t api_message); bool zapi_nhg_notify_decode(struct stream *s, uint32_t *id, enum zapi_nhg_notify_owner *note); bool zapi_route_notify_decode(struct stream *s, struct prefix *p, uint32_t *tableid, enum zapi_route_notify_owner *note, afi_t *afi, safi_t *safi); bool zapi_rule_notify_decode(struct stream *s, uint32_t *seqno, uint32_t *priority, uint32_t *unique, char *ifname, enum zapi_rule_notify_owner *note); bool zapi_ipset_notify_decode(struct stream *s, uint32_t *unique, enum zapi_ipset_notify_owner *note); /* Nexthop-group message apis */ extern enum zclient_send_status zclient_nhg_send(struct zclient *zclient, int cmd, struct zapi_nhg *api_nhg); #define ZEBRA_IPSET_NAME_SIZE 32 bool zapi_ipset_entry_notify_decode(struct stream *s, uint32_t *unique, char *ipset_name, enum zapi_ipset_entry_notify_owner *note); bool zapi_iptable_notify_decode(struct stream *s, uint32_t *unique, enum zapi_iptable_notify_owner *note); extern struct nexthop * nexthop_from_zapi_nexthop(const struct zapi_nexthop *znh); int zapi_nexthop_from_nexthop(struct zapi_nexthop *znh, const struct nexthop *nh); int zapi_backup_nexthop_from_nexthop(struct zapi_nexthop *znh, const struct nexthop *nh); /* * match -> is the prefix that the calling daemon asked to be matched * against. * nhr->prefix -> is the actual prefix that was matched against in the * rib itself. * * This distinction is made because a LPM can be made if there is a * covering route. This way the upper level protocol can make a decision * point about whether or not it wants to use the match or not. */ extern bool zapi_nexthop_update_decode(struct stream *s, struct prefix *match, struct zapi_route *nhr); const char *zapi_nexthop2str(const struct zapi_nexthop *znh, char *buf, int bufsize); /* Decode the zebra error message */ extern bool zapi_error_decode(struct stream *s, enum zebra_error_types *error); /* Encode and decode restart capabilities */ extern enum zclient_send_status zclient_capabilities_send(uint32_t cmd, struct zclient *zclient, struct zapi_cap *api); extern int32_t zapi_capabilities_decode(struct stream *s, struct zapi_cap *api); static inline void zapi_route_set_blackhole(struct zapi_route *api, enum blackhole_type bh_type) { api->nexthop_num = 1; api->nexthops[0].type = NEXTHOP_TYPE_BLACKHOLE; api->nexthops[0].vrf_id = VRF_DEFAULT; api->nexthops[0].bh_type = bh_type; SET_FLAG(api->message, ZAPI_MESSAGE_NEXTHOP); }; extern enum zclient_send_status zclient_send_mlag_register(struct zclient *client, uint32_t bit_map); extern enum zclient_send_status zclient_send_mlag_deregister(struct zclient *client); extern enum zclient_send_status zclient_send_mlag_data(struct zclient *client, struct stream *client_s); /* * Send an OPAQUE message, contents opaque to zebra - but note that * the length of the payload is restricted by the zclient's * outgoing message buffer. * The message header is a message subtype; please use the registry * below to avoid sub-type collisions. Clients use the registration * apis to manage the specific opaque subtypes they want to receive. */ enum zclient_send_status zclient_send_opaque(struct zclient *zclient, uint32_t type, const uint8_t *data, size_t datasize); enum zclient_send_status zclient_send_opaque_unicast(struct zclient *zclient, uint32_t type, uint8_t proto, uint16_t instance, uint32_t session_id, const uint8_t *data, size_t datasize); /* Struct representing the decoded opaque header info */ struct zapi_opaque_msg { uint32_t type; /* Subtype */ uint16_t len; /* len after zapi header and this info */ uint16_t flags; /* Client-specific info - *if* UNICAST flag is set */ uint8_t proto; uint16_t instance; uint32_t session_id; }; #define ZAPI_OPAQUE_FLAG_UNICAST 0x01 /* Simple struct to convey registration/unreg requests */ struct zapi_opaque_reg_info { /* Message subtype */ uint32_t type; /* Client session tuple */ uint8_t proto; uint16_t instance; uint32_t session_id; }; /* Decode incoming opaque */ int zclient_opaque_decode(struct stream *msg, struct zapi_opaque_msg *info); enum zclient_send_status zclient_register_opaque(struct zclient *zclient, uint32_t type); enum zclient_send_status zclient_unregister_opaque(struct zclient *zclient, uint32_t type); int zapi_opaque_reg_decode(struct stream *msg, struct zapi_opaque_reg_info *info); /* * Registry of opaque message types. Please do not reuse an in-use * type code; some daemons are likely relying on it. */ enum zapi_opaque_registry { /* Request link-state database dump, at restart for example */ LINK_STATE_SYNC = 1, /* Update containing link-state db info */ LINK_STATE_UPDATE = 2, /* Request LDP-SYNC state from LDP */ LDP_IGP_SYNC_IF_STATE_REQUEST = 3, /* Update containing LDP IGP Sync State info */ LDP_IGP_SYNC_IF_STATE_UPDATE = 4, /* Announce that LDP is up */ LDP_IGP_SYNC_ANNOUNCE_UPDATE = 5, /* Register RLFA with LDP */ LDP_RLFA_REGISTER = 7, /* Unregister all RLFAs with LDP */ LDP_RLFA_UNREGISTER_ALL = 8, /* Announce LDP labels associated to a previously registered RLFA */ LDP_RLFA_LABELS = 9, }; /* Send the hello message. * Returns 0 for success or -1 on an I/O error. */ extern enum zclient_send_status zclient_send_hello(struct zclient *client); extern enum zclient_send_status zclient_send_neigh_discovery_req(struct zclient *zclient, const struct interface *ifp, const struct prefix *p); struct zapi_client_close_info { /* Client session tuple */ uint8_t proto; uint16_t instance; uint32_t session_id; }; /* Decode incoming client close notify */ extern int zapi_client_close_notify_decode(struct stream *s, struct zapi_client_close_info *info); extern int zclient_send_zebra_gre_request(struct zclient *client, struct interface *ifp); #ifdef __cplusplus } #endif #endif /* _ZEBRA_ZCLIENT_H */