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bird/proto/snmp/bgp4_mib.c
2024-07-17 13:03:26 +02:00

1097 lines
31 KiB
C

/*
* BIRD -- Simple Network Management Protocol (SNMP)
* BGP4-MIB bgpPeerTable
*
* (c) 2022 Vojtech Vilimek <vojtech.vilimek@nic.cz>
* (c) 2022 CZ.NIC z.s.p.o
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
#include "snmp.h"
#include "snmp_utils.h"
#include "subagent.h"
#include "bgp4_mib.h"
#include "mib_tree.h"
/* hash table macros */
#define SNMP_HASH_KEY(n) n->peer_ip
#define SNMP_HASH_NEXT(n) n->next
#define SNMP_HASH_EQ(ip1, ip2) ip4_equal(ip1, ip2)
#define SNMP_HASH_FN(ip) ip4_hash(ip)
#define SNMP_HASH_LESS4(ip1, ip2) ip4_less(ip1, ip2)
#define SNMP_HASH_LESS6(ip1, ip2) ip6_less(ip1, ip2)
/* hash table only store ip4 addresses */
#define SNMP_HASH_LESS(ip1, ip2) SNMP_HASH_LESS4(ip1,ip2)
// delete me
#define SNMP_MANAGE_TBUF(...) (void)0
#define DECLARE_BGP4(addr, proto, conn, stats, config) \
ip4_addr addr; \
const struct bgp_proto UNUSED *proto; \
const struct bgp_conn UNUSED *conn; \
const struct bgp_stats UNUSED *stats; \
const struct bgp_config UNUSED *config
#define POPULATE_BGP4(addr, proto, conn, stats, config) populate_bgp4(c, &(addr), &(proto), &(conn), &(stats), &(config))
static inline void ip4_to_oid(struct oid *oid, ip4_addr addr);
static inline void
snmp_hash_add_peer(struct snmp_proto *p, struct snmp_bgp_peer *peer)
{
HASH_INSERT(p->bgp_hash, SNMP_HASH, peer);
}
static inline struct snmp_bgp_peer *
snmp_hash_find(struct snmp_proto *p, ip4_addr key)
{
return HASH_FIND(p->bgp_hash, SNMP_HASH, key);
}
static inline void
snmp_bgp_last_error(const struct bgp_proto *bgp, char err[2])
{
err[0] = bgp->last_error_code & 0x00FF0000 >> 16;
err[1] = bgp->last_error_code & 0x000000FF;
}
static void
snmp_bgp_reg_ok(struct snmp_proto *p, const struct agentx_response *res, struct snmp_registration *reg)
{
const struct oid * const oid = reg->oid;
(void)oid;
(void)p;
(void) res;
}
static void
snmp_bgp_reg_failed(struct snmp_proto *p, const struct agentx_response *res, struct snmp_registration *reg)
{
const struct oid * const oid = reg->oid;
(void) res;
(void)oid;
(void)p;
}
/*
* snmp_bgp_notify_common - common functionaly for BGP4-MIB notifications
* @p: SNMP protocol instance
* @type: type of notification send - either established or backward transition
* @ip4: IPv4 remote addr
* @last_error: 2 bytes of BGP last error
* @state_val: BGP peer state as defined in MIB
*/
static void
snmp_bgp_notify_common(struct snmp_proto *p, uint type, ip4_addr ip4, char last_error[], uint state_val)
{
uint sz = (uint) (snmp_varbind_size_from_len(9, AGENTX_IP_ADDRESS, 0)
+ snmp_varbind_size_from_len(9, AGENTX_OCTET_STRING, 2)
+ snmp_varbind_size_from_len(9, AGENTX_INTEGER, 0));
u32 trap_ids[] = { 1, 0, type };
STATIC_ASSERT(ARRAY_SIZE(trap_ids) == 3);
/* additional size for trap identification, here either
* bgpEstablishedNotification or bgpBackwardTransNotification (see below) */
void *data = tmp_alloc(snmp_oid_size_from_len(ARRAY_SIZE(trap_ids)) + sz);
struct oid *head = data;
{ /* trap id BGP4-MIB::bgpEstablishedNotification (.1.3.6.1.2.15.0.1)
* or BGP4-MIB::bgpBackwardTransNotification (.1.3.6.1.2.15.0.2) */
head->n_subid = ARRAY_SIZE(trap_ids);
head->prefix = SNMP_MGMT;
head->include = head->reserved = 0;
for (uint i = 0; i < head->n_subid; i++)
head->ids[i] = trap_ids[i];
}
data += sz;
struct agentx_varbind *addr_vb = data;
struct agentx_varbind *error_vb = \
data + snmp_varbind_size_from_len(9, AGENTX_IP_ADDRESS, 0);
struct agentx_varbind *state_vb = \
(void *) error_vb + snmp_varbind_size_from_len(9, AGENTX_OCTET_STRING, 2);
u32 oid_ids[] = {
SNMP_MIB_2, BGP4_MIB, BGP4_MIB_PEER_TABLE, BGP4_MIB_PEER_ENTRY
};
/*
* The n_subid is 9 in all cases because all are rows entries of
* BGP4-MIB::bgpPeerTable
* BGP4-MIB::bgpPeerRemoteAddr = .1.3.6.1.[2].1.15.3.1.7.a.b.c.d
* where .1.3.6.1 is internet prefix, .[2] is SNMP_MGMT,
* .1.15.3.1.7.a.b.c.d has 9 elements (a.b.c.d are IP addr bytes)
* Here subidentifier 7 is entry type bgpPeerRemoteAddr.
*/
#define PEER_TABLE_ENTRY 9
#define ENTRY_TYPE 4
{ /* BGP4-MIB::bgpPeerRemoteAddr */
struct oid *addr = &addr_vb->name;
*addr = (struct oid) {
.n_subid = PEER_TABLE_ENTRY, .prefix = SNMP_MGMT, .include = 0,
.reserved = 0,
};
for (uint i = 0; i < ARRAY_SIZE(oid_ids); i++)
addr->ids[i] = oid_ids[i];
addr->ids[ENTRY_TYPE] = BGP4_MIB_REMOTE_ADDR;
ip4_to_oid(addr, ip4);
}
/* We have enough space inside the TX-buffer prepared */
struct snmp_pdu dummy = { 0 };
dummy.sr_vb_start = addr_vb;
snmp_varbind_ip4(&dummy, ip4);
{ /* BGP4-MIB::bgpPeerLastError */
struct oid *error = &error_vb->name;
*error = (struct oid) {
.n_subid = PEER_TABLE_ENTRY, .prefix = SNMP_MGMT, .include = 0,
.reserved = 0,
};
for (uint i = 0; i < ARRAY_SIZE(oid_ids); i++)
error->ids[i] = oid_ids[i];
error->ids[ENTRY_TYPE] = BGP4_MIB_LAST_ERROR;
ip4_to_oid(error, ip4);
}
dummy.sr_vb_start = error_vb;
snmp_varbind_nstr(&dummy, last_error, 2);
{ /* BGP4-MIB::bgpPeerState */
struct oid *state = &state_vb->name;
*state = (struct oid) {
.n_subid = PEER_TABLE_ENTRY, .prefix = SNMP_MGMT, .include = 0,
.reserved = 0,
};
for (uint i = 0; i < ARRAY_SIZE(oid_ids); i++)
state->ids[i] = oid_ids[i];
state->ids[ENTRY_TYPE] = BGP4_MIB_STATE;
ip4_to_oid(state, ip4);
}
dummy.sr_vb_start = state_vb;
snmp_varbind_int(&dummy, state_val);
/* We do not send the systemUpTime.0 */
snmp_notify_pdu(p, head, data, sz, 0);
#undef OID_N_SUBID
}
/*
* snmp_bgp_fsm_state - extract BGP FSM state for SNMP BGP4-MIB
* @bgp_proto: BGP instance
*
* Return FSM state in BGP4-MIB encoding
*/
static inline uint
snmp_bgp_fsm_state(const struct bgp_proto *bgp_proto)
{
const struct bgp_conn *bgp_conn = bgp_proto->conn;
const struct bgp_conn *bgp_in = &bgp_proto->incoming_conn;
const struct bgp_conn *bgp_out = &bgp_proto->outgoing_conn;
if (bgp_conn)
return bgp_conn->state + 1;
if (MAX(bgp_in->state, bgp_out->state) == BS_CLOSE &&
MIN(bgp_in->state, bgp_out->state) != BS_CLOSE)
return MIN(bgp_in->state, bgp_out->state) + 1;
if (MIN(bgp_in->state, bgp_out->state) == BS_CLOSE)
return BS_IDLE;
return MAX(bgp_in->state, bgp_out->state) + 1;
}
static void
snmp_bgp_notify_wrapper(struct snmp_proto *p, struct bgp_proto *bgp, uint type)
{
/* possibly incorrect cast */
ip4_addr ip4 = ipa_to_ip4(bgp->remote_ip);
char last_error[2];
snmp_bgp_last_error(bgp, last_error);
uint state_val = snmp_bgp_fsm_state(bgp);
snmp_bgp_notify_common(p, type, ip4, last_error, state_val);
}
void
snmp_bgp_notify_established(struct snmp_proto *p, struct bgp_proto *bgp)
{
snmp_bgp_notify_wrapper(p, bgp, BGP4_MIB_ESTABLISHED_NOTIFICATION);
}
void
snmp_bgp_notify_backward_trans(struct snmp_proto *p, struct bgp_proto *bgp)
{
snmp_bgp_notify_wrapper(p, bgp, BGP4_MIB_BACKWARD_TRANS_NOTIFICATION);
}
void
snmp_bgp4_register(struct snmp_proto *p)
{
u32 bgp_mib_prefix[] = { SNMP_MIB_2, BGP4_MIB };
{
/* Register the whole BGP4-MIB::bgp root tree node */
struct snmp_registration *reg;
reg = snmp_registration_create(p, BGP4_MIB);
struct oid *oid = mb_allocz(p->pool,
snmp_oid_size_from_len(ARRAY_SIZE(bgp_mib_prefix)));
STORE_U8(oid->n_subid, ARRAY_SIZE(bgp_mib_prefix));
STORE_U8(oid->prefix, SNMP_MGMT);
memcpy(oid->ids, bgp_mib_prefix, sizeof(bgp_mib_prefix));
reg->oid = oid;
reg->reg_hook_ok = snmp_bgp_reg_ok;
reg->reg_hook_fail = snmp_bgp_reg_failed;
/*
* We set both upper bound and index to zero, therefore only single OID
* is being registered.
*/
snmp_register(p, oid, 0, 0, SNMP_REGISTER_TREE, SNMP_DEFAULT_CONTEXT);
}
}
static int
snmp_bgp_valid_ip4(const struct oid *o)
{
return snmp_valid_ip4_index(o, 5);
}
static inline ip4_addr
ip4_from_oid(const struct oid *o)
{
return ip4_build(
o->n_subid > 5 ? (o->ids[5] & 0xff) : 0,
o->n_subid > 6 ? (o->ids[6] & 0xff) : 0,
o->n_subid > 7 ? (o->ids[7] & 0xff) : 0,
o->n_subid > 8 ? (o->ids[8] & 0xff) : 0
);
}
static inline void
ip4_to_oid(struct oid *o, ip4_addr addr)
{
u32 tmp = ip4_to_u32(addr);
ASSUME(o->n_subid >= 9);
STORE_U32(o->ids[5], (tmp & 0xFF000000) >> 24);
STORE_U32(o->ids[6], (tmp & 0x00FF0000) >> 16);
STORE_U32(o->ids[7], (tmp & 0x0000FF00) >> 8);
STORE_U32(o->ids[8], (tmp & 0x000000FF) >> 0);
}
static void UNUSED
print_bgp_record(const struct bgp_proto *bgp_proto)
{
struct bgp_conn *conn = bgp_proto->conn;
DBG(" name: %s", cf->name);
DBG(".");
DBG(" rem. identifier: %u", bgp_proto->remote_id);
DBG(" local ip: %I", config->local_ip);
DBG(" remote ip: %I", config->remote_ip);
DBG(" local port: %u", config->local_port);
DBG(" remote port: %u", config->remote_port);
if (conn) {
DBG(" state: %u", conn->state);
DBG(" remote as: %u", conn->remote_caps->as4_number);
}
DBG(" in updates: %u", bgp_proto->stats.rx_updates);
DBG(" out updates: %u", bgp_proto->stats.tx_updates);
DBG(" in total: %u", bgp_proto->stats.rx_messages);
DBG(" out total: %u", bgp_proto->stats.tx_messages);
DBG(" fsm transitions: %u",
bgp_proto->stats.fsm_established_transitions);
DBG(" fsm total time: -- (0)"); // not supported by bird
DBG(" retry interval: %u", config->connect_retry_time);
DBG(" hold configurated: %u", config->hold_time );
DBG(" keep alive config: %u", config->keepalive_time );
DBG(" min AS origin. int.: -- (0)"); // not supported by bird
DBG(" min route advertisement: %u", 0 );
DBG(" in update elapsed time: %u", 0 );
if (!conn)
DBG(" no connection established");
DBG(" outgoinin_conn state %u", bgp_proto->outgoing_conn.state + 1);
DBG(" incoming_conn state: %u", bgp_proto->incoming_conn.state + 1);
}
static inline enum snmp_search_res
populate_bgp4(struct snmp_pdu *c, ip4_addr *addr, const struct bgp_proto **proto, const struct bgp_conn
**conn, const struct bgp_stats **stats, const struct bgp_config **config)
{
const struct oid * const oid = &c->sr_vb_start->name;
if (snmp_bgp_valid_ip4(oid) && LOAD_U8(oid->n_subid) == 9)
*addr = ip4_from_oid(oid);
else
{
snmp_log("populate() invalid ip4");
return SNMP_SEARCH_NO_INSTANCE;
}
struct snmp_bgp_peer *pe = snmp_hash_find(c->p, *addr);
if (!pe)
{
snmp_log("populate() hash find failed");
return SNMP_SEARCH_NO_INSTANCE;
}
const struct bgp_proto *bgp_proto;
*proto = bgp_proto = pe->bgp_proto;
if (!ipa_is_ip4(bgp_proto->remote_ip))
{
log(L_ERR "%s: Found BGP protocol instance with IPv6 address", bgp_proto->p.name);
c->error = AGENTX_RES_GEN_ERROR;
return SNMP_SEARCH_NO_INSTANCE;
}
ip4_addr proto_ip = ipa_to_ip4(bgp_proto->remote_ip);
if (!ip4_equal(proto_ip, pe->peer_ip))
{
/* Here, we could be in problem as the bgp_proto IP address could be changed */
log(L_ERR "%s: Stored hash key IP address and peer remote address differ "
"(%I, %I).", bgp_proto->p.name, proto_ip, pe->peer_ip);
c->error = AGENTX_RES_GEN_ERROR;
return SNMP_SEARCH_NO_INSTANCE;
}
*conn = bgp_proto->conn;
*stats = &bgp_proto->stats;
*config = bgp_proto->cf;
snmp_log("populate() ok");
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_bgp_version(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill ver");
if (LOAD_U8(c->sr_vb_start->name.n_subid) != 3)
return SNMP_SEARCH_NO_INSTANCE;
c->size -= snmp_str_size_from_len(1);
snmp_varbind_nstr(c, BGP4_VERSIONS, 1);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_local_as(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill as");
if (LOAD_U8(c->sr_vb_start->name.n_subid) != 3)
return SNMP_SEARCH_NO_INSTANCE;
snmp_varbind_int(c, c->p->bgp_local_as);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_peer_id(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill peer id");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
uint fsm_state = snmp_bgp_fsm_state(bgp_proto);
if (fsm_state == BGP4_MIB_OPENCONFIRM || fsm_state == BGP4_MIB_ESTABLISHED)
// TODO last
snmp_varbind_ip4(c, ip4_from_u32(bgp_proto->remote_id));
else
snmp_varbind_ip4(c, IP4_NONE);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_peer_state(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill peer state");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
uint fsm_state = snmp_bgp_fsm_state(bgp_proto);
snmp_varbind_int(c, fsm_state);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_admin_status(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill adm status");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
if (bgp_proto->p.disabled)
snmp_varbind_int(c, AGENTX_ADMIN_STOP);
else
snmp_varbind_int(c, AGENTX_ADMIN_START);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_neg_version(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill neg ver");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
uint fsm_state = snmp_bgp_fsm_state(bgp_proto);
if (fsm_state == BGP4_MIB_ESTABLISHED || fsm_state == BGP4_MIB_ESTABLISHED)
snmp_varbind_int(c, BGP4_MIB_NEGOTIATED_VER_VALUE);
else
snmp_varbind_int(c, BGP4_MIB_NEGOTIATED_VER_NO_VALUE);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_local_addr(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("bgp4_mib fill local addr");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
snmp_log("fill local addr result %u", res);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_ip4(c, ipa_to_ip4(bgp_proto->local_ip));
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_local_port(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("bgp4_mib fill local port");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_int(c, bgp_conf->local_port);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_remote_addr(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("bgp4_mib fill remote addr");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_ip4(c, ipa_to_ip4(bgp_proto->remote_ip));
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_remote_port(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("bgp4_mib fill remote port");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_int(c, bgp_conf->remote_port);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_remote_as(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill rem as");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_int(c, bgp_proto->remote_as);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_in_updates(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill in updates");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_counter32(c, bgp_stats->rx_updates);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_out_updates(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill out updates");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_counter32(c, bgp_stats->tx_updates);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_in_total_msg(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill in total");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_counter32(c, bgp_stats->rx_messages);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_out_total_msg(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill out total");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_counter32(c, bgp_stats->tx_messages);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_last_err(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill last err");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
char last_error[2];
snmp_bgp_last_error(bgp_proto, last_error);
snmp_varbind_nstr(c, last_error, 2);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_established_trans(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill est trans");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_counter32(c,
bgp_stats->fsm_established_transitions);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_established_time(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill est time");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_gauge32(c,
(current_time() - bgp_proto->last_established) TO_S);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_retry_interval(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill retry int");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_int(c, bgp_conf->connect_retry_time);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_hold_time(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill hold time");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_int(c, (bgp_conn) ? bgp_conn->hold_time : 0);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_keep_alive(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill keepalive");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
if (!bgp_conf->hold_time)
snmp_varbind_int(c, 0);
else
snmp_varbind_int(c,
(bgp_conn) ? bgp_conn->keepalive_time : 0);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_hold_time_conf(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill hold time c");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_int(c, bgp_conf->hold_time);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_keep_alive_conf(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill keepalive c");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
if (!bgp_conf->keepalive_time)
snmp_varbind_int(c, 0);
else
snmp_varbind_int(c,
(bgp_conn) ? bgp_conn->keepalive_time : 0);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_min_as_org_interval(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill min org int");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
/* value should be in 1..65535 but is not supported by bird */
snmp_varbind_int(c, 0);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_route_adv_interval(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill rt adv int");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
/* value should be in 1..65535 but is not supported by bird */
snmp_varbind_int(c, 0);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_in_update_elapsed_time(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fil in elapsed");
enum snmp_search_res res;
DECLARE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
res = POPULATE_BGP4(addr, bgp_proto, bgp_conn, bgp_stats, bgp_conf);
if (res != SNMP_SEARCH_OK)
return res;
snmp_varbind_gauge32(c,
(current_time() - bgp_proto->last_rx_update) TO_S
);
return SNMP_SEARCH_OK;
}
static enum snmp_search_res
fill_local_id(struct mib_walk_state *walk UNUSED, struct snmp_pdu *c)
{
snmp_log("fill local id");
if (LOAD_U8(c->sr_vb_start->name.n_subid) != 3)
return SNMP_SEARCH_NO_INSTANCE;
snmp_varbind_ip4(c, c->p->bgp_local_id);
return SNMP_SEARCH_OK;
}
/*
* bgp4_next_peer
*/
static int
bgp4_next_peer(struct mib_walk_state *state, struct snmp_pdu *c)
{
struct oid *oid = &c->sr_vb_start->name;
/* BGP4-MIB::bgpPeerIdentifier */
STATIC_OID(9) bgp4_peer_id = {
.n_subid = 9,
.prefix = SNMP_MGMT,
.include = 0,
.reserved = 0,
.ids = { SNMP_MIB_2, BGP4_MIB,
BGP4_MIB_PEER_TABLE, BGP4_MIB_PEER_ENTRY, BGP4_MIB_PEER_IDENTIFIER,
/* IP4_NONE */ 0, 0, 0, 0 }
};
ip4_addr ip4 = ip4_from_oid(oid);
const struct oid *peer_oid = (const struct oid *) &bgp4_peer_id;
int precise = 1;
if (LOAD_U8(oid->n_subid) > 9)
precise = 0;
if (LOAD_U8(oid->n_subid) != 9 || snmp_oid_compare(oid, peer_oid) < 0)
{
int old = snmp_oid_size(oid);
int new = snmp_oid_size(peer_oid);
if (new - old > 0 && (uint) new - old > c->size)
{
snmp_log("bgp4_next_peer small buffer");
snmp_manage_tbuf(c->p, c);
oid = &c->sr_vb_start->name; // TODO fix sr_vb_start in manage_tbuf
}
c->buffer += (new - old);
snmp_oid_copy(oid, peer_oid);
STORE_U8(oid->include, 1);
}
ASSUME(oid->n_subid == 9);
/* full path BGP4-MIB::bgpPeerEntry.x: .1.3.6.1.2.1.15.3.1.x
* index offset = ARRAY_SIZE(snmp_internet) + 1 <prefix> + 4 + 1 <identifier x> */
ASSUME(state->stack_pos > 10);
oid->ids[4] = state->stack[10]->empty.id;
net_addr net;
net_fill_ip4(&net, ip4, IP4_MAX_PREFIX_LENGTH);
struct f_trie_walk_state ws;
int match = trie_walk_init(&ws, c->p->bgp_trie, &net, 1);
if (match && LOAD_U8(oid->include) && precise)
{
STORE_U8(oid->include, 0);
ip4_to_oid(oid, ip4);
return 0;
}
/* We skip the first match as we should not include ip address in oid */
if (match)
(void) trie_walk_next(&ws, &net);
if (trie_walk_next(&ws, &net))
{
ASSUME(oid->n_subid == 9);
ip4_addr res = ipa_to_ip4(net_prefix(&net));
ip4_to_oid(oid, res);
return 0;
}
return 1;
}
/*
* snmp_bgp_start - prepare BGP4-MIB
* @p - SNMP protocol instance holding memory pool
*
* This function create all runtime bindings to BGP procotol structures.
* It is gruaranteed that the BGP protocols exist.
*/
void
snmp_bgp4_start(struct snmp_proto *p)
{
struct snmp_config *cf = SKIP_BACK(struct snmp_config, cf, p->p.cf);
/* Create binding to BGP protocols */
struct snmp_bond *b;
WALK_LIST(b, cf->bgp_entries)
{
const struct bgp_config *bgp_config = (struct bgp_config *) b->config;
const struct bgp_proto *bgp = SKIP_BACK(struct bgp_proto, p,
bgp_config->c.proto);
struct snmp_bgp_peer *peer = \
mb_alloc(p->pool, sizeof(struct snmp_bgp_peer));
peer->bgp_proto = bgp;
peer->peer_ip = ipa_to_ip4(bgp->remote_ip);
struct net_addr net;
net_fill_ip4(&net, ipa_to_ip4(bgp->remote_ip), IP4_MAX_PREFIX_LENGTH);
trie_add_prefix(p->bgp_trie, &net, IP4_MAX_PREFIX_LENGTH,
IP4_MAX_PREFIX_LENGTH);
snmp_hash_add_peer(p, peer);
}
const STATIC_OID(2) bgp4_mib_root = {
.n_subid = 2,
.prefix = SNMP_MGMT,
.include = 0,
.reserved = 0,
.ids = { SNMP_MIB_2, BGP4_MIB },
};
const STATIC_OID(4) bgp4_mib_peer_entry = {
.n_subid = 4,
.prefix = SNMP_MGMT,
.include = 0,
.reserved = 0,
.ids = { SNMP_MIB_2, BGP4_MIB, BGP4_MIB_PEER_TABLE, BGP4_MIB_PEER_ENTRY },
};
(void) mib_tree_hint(p->pool, p->mib_tree,
(const struct oid *) &bgp4_mib_root, BGP4_MIB_IDENTIFIER);
(void) mib_tree_hint(p->pool, p->mib_tree,
(const struct oid *) &bgp4_mib_peer_entry, BGP4_MIB_IN_UPDATE_ELAPSED_TIME);
mib_node_u *node;
struct mib_leaf *leaf;
STATIC_OID(3) bgp4_var = {
.n_subid = 3,
.prefix = SNMP_MGMT,
.include = 0,
.reserved = 0,
.ids = { SNMP_MIB_2, BGP4_MIB, BGP4_MIB_VERSION },
};
struct {
u32 id;
enum snmp_search_res (*filler)(struct mib_walk_state *state, struct snmp_pdu *c);
enum agentx_type type;
int size;
} leafs[] = {
{
.id = BGP4_MIB_VERSION,
.filler = fill_bgp_version,
.type = AGENTX_OCTET_STRING,
.size = snmp_str_size_from_len(sizeof(BGP4_VERSIONS)),
},
{
.id = BGP4_MIB_LOCAL_AS,
.filler = fill_local_as,
.type = AGENTX_INTEGER,
},
{
.id = BGP4_MIB_IDENTIFIER,
.filler = fill_local_id,
.type = AGENTX_IP_ADDRESS,
},
};
for (uint i = 0; i < ARRAY_SIZE(leafs); i++)
{
bgp4_var.ids[ARRAY_SIZE(bgp4_var.ids) - 1] = leafs[i].id;
node = mib_tree_add(p->pool, p->mib_tree, (const struct oid *) &bgp4_var, 1);
ASSUME(mib_node_is_leaf(node));
leaf = &node->leaf;
leaf->filler = leafs[i].filler;
leaf->call_next = NULL;
leaf->type = leafs[i].type;
leaf->size = leafs[i].size;
}
STATIC_OID(5) bgp4_entry_var = {
.n_subid = 5,
.prefix = SNMP_MGMT,
.include = 0,
.reserved = 0,
.ids = { SNMP_MIB_2, BGP4_MIB,
BGP4_MIB_PEER_TABLE, BGP4_MIB_PEER_ENTRY, BGP4_MIB_PEER_IDENTIFIER },
};
struct {
enum snmp_search_res (*filler)(struct mib_walk_state *state, struct snmp_pdu *c);
enum agentx_type type;
int size;
} entry_leafs[] = {
[BGP4_MIB_PEER_IDENTIFIER] = {
.filler = fill_peer_id,
.type = AGENTX_IP_ADDRESS,
},
[BGP4_MIB_STATE] = {
.filler = fill_peer_state,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_ADMIN_STATUS] = {
.filler = fill_admin_status,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_NEGOTIATED_VERSION] = {
.filler = fill_neg_version,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_LOCAL_ADDR] = {
.filler = fill_local_addr,
.type = AGENTX_IP_ADDRESS,
},
[BGP4_MIB_LOCAL_PORT] = {
.filler = fill_local_port,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_REMOTE_ADDR] = {
.filler = fill_remote_addr,
.type = AGENTX_IP_ADDRESS,
},
[BGP4_MIB_REMOTE_PORT] = {
.filler = fill_remote_port,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_REMOTE_AS] = {
.filler = fill_remote_as,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_RX_UPDATES] = {
.filler = fill_in_updates,
.type = AGENTX_COUNTER_32,
},
[BGP4_MIB_TX_UPDATES] = {
.filler = fill_out_updates,
.type = AGENTX_COUNTER_32,
},
[BGP4_MIB_RX_MESSAGES] = {
.filler = fill_in_total_msg,
.type = AGENTX_COUNTER_32,
},
[BGP4_MIB_TX_MESSAGES] = {
.filler = fill_out_total_msg,
.type = AGENTX_COUNTER_32,
},
[BGP4_MIB_LAST_ERROR] = {
.filler = fill_last_err,
.type = AGENTX_OCTET_STRING,
.size = snmp_str_size_from_len(2),
},
[BGP4_MIB_FSM_TRANSITIONS] = {
.filler = fill_established_trans,
.type = AGENTX_COUNTER_32,
},
[BGP4_MIB_FSM_ESTABLISHED_TIME] = {
.filler = fill_established_time,
.type = AGENTX_GAUGE_32,
},
[BGP4_MIB_RETRY_INTERVAL] = {
.filler = fill_retry_interval,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_HOLD_TIME] = {
.filler = fill_hold_time,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_KEEPALIVE] = {
.filler = fill_keep_alive,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_HOLD_TIME_CONFIGURED] = {
.filler = fill_hold_time_conf,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_KEEPALIVE_CONFIGURED] = {
.filler = fill_keep_alive_conf,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_ORIGINATION_INTERVAL] = {
.filler = fill_min_as_org_interval,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_MIN_ROUTE_ADVERTISEMENT] = {
.filler = fill_route_adv_interval,
.type = AGENTX_INTEGER,
},
[BGP4_MIB_IN_UPDATE_ELAPSED_TIME] = {
.filler = fill_in_update_elapsed_time,
.type = AGENTX_GAUGE_32,
},
}; /* struct _anon entry_leafs[] */
for (enum bgp4_mib_peer_entry_row e = BGP4_MIB_PEER_IDENTIFIER;
e <= BGP4_MIB_IN_UPDATE_ELAPSED_TIME; e++)
{
bgp4_entry_var.ids[ARRAY_SIZE(bgp4_entry_var.ids) - 1] = (u32) e;
node = mib_tree_add(p->pool, p->mib_tree, (const struct oid *) &bgp4_entry_var, 1);
ASSUME(mib_node_is_leaf(node));
leaf = &node->leaf;
leaf->filler = entry_leafs[e].filler;
leaf->call_next = bgp4_next_peer;
leaf->type = entry_leafs[e].type;
leaf->size = entry_leafs[e].size;
}
}