mib2.h revision 7c478bd95313f5f23a4c958a745db2134aa03244
/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License, Version 1.0 only
* (the "License"). You may not use this file except in compliance
* with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright 2005 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
/* Copyright (c) 1990 Mentat Inc. */
#ifndef _INET_MIB2_H
#define _INET_MIB2_H
#pragma ident "%Z%%M% %I% %E% SMI"
#include <netinet/in.h> /* For in6_addr_t */
#ifdef __cplusplus
extern "C" {
#endif
/*
* The IPv6 parts of this are derived from:
* RFC 2465
* RFC 2466
* RFC 2452
* RFC 2454
*/
/*
* SNMP set/get via M_PROTO T_OPTMGMT_REQ. Structure is that used
* for [gs]etsockopt() calls. get uses T_CURRENT, set uses T_NEOGTIATE
* MGMT_flags value. The following definition of opthdr is taken from
* socket.h:
*
* An option specification consists of an opthdr, followed by the value of
* the option. An options buffer contains one or more options. The len
* field of opthdr specifies the length of the option value in bytes. This
* length must be a multiple of sizeof(long) (use OPTLEN macro).
*
* struct opthdr {
* long level; protocol level affected
* long name; option to modify
* long len; length of option value
* };
*
* #define OPTLEN(x) ((((x) + sizeof(long) - 1) / sizeof(long)) * sizeof(long))
* #define OPTVAL(opt) ((char *)(opt + 1))
*
* For get requests (T_NEGOTIATE), any MIB2_xxx value can be used (only
* "get all" is supported, so all modules get a copy of the request to
* return everything it knows. Recommend: Use MIB2_IP
*
* IMPORTANT: some fields are grouped in a different structure than
* suggested by MIB-II, e.g., checksum error counts. The original MIB-2
* field name has been retained. Field names beginning with "mi" are not
* defined in the MIB but contain important & useful information maintained
* by the corresponding module.
*/
#ifndef IPPROTO_MAX
#define IPPROTO_MAX 256
#endif
#define MIB2_SYSTEM (IPPROTO_MAX+1)
#define MIB2_INTERFACES (IPPROTO_MAX+2)
#define MIB2_AT (IPPROTO_MAX+3)
#define MIB2_IP (IPPROTO_MAX+4)
#define MIB2_ICMP (IPPROTO_MAX+5)
#define MIB2_TCP (IPPROTO_MAX+6)
#define MIB2_UDP (IPPROTO_MAX+7)
#define MIB2_EGP (IPPROTO_MAX+8)
#define MIB2_CMOT (IPPROTO_MAX+9)
#define MIB2_TRANSMISSION (IPPROTO_MAX+10)
#define MIB2_SNMP (IPPROTO_MAX+11)
#define MIB2_IP6 (IPPROTO_MAX+12)
#define MIB2_ICMP6 (IPPROTO_MAX+13)
#define MIB2_TCP6 (IPPROTO_MAX+14)
#define MIB2_UDP6 (IPPROTO_MAX+15)
#define MIB2_SCTP (IPPROTO_MAX+16)
/*
* Define range of levels for use with MIB2_*
*/
#define MIB2_RANGE_START (IPPROTO_MAX+1)
#define MIB2_RANGE_END (IPPROTO_MAX+16)
#define EXPER 1024 /* experimental - not part of mib */
#define EXPER_IGMP (EXPER+1)
#define EXPER_DVMRP (EXPER+2)
#define EXPER_RAWIP (EXPER+3)
/*
* Define range of levels for experimental use
*/
#define EXPER_RANGE_START (EXPER+1)
#define EXPER_RANGE_END (EXPER+3)
#define BUMP_MIB(s, x) { \
extern void __dtrace_probe___mib_##x(int, void *); \
void *stataddr = &((s)->x); \
__dtrace_probe___mib_##x(1, stataddr); \
(s)->x++; \
}
#define UPDATE_MIB(s, x, y) { \
extern void __dtrace_probe___mib_##x(int, void *); \
void *stataddr = &((s)->x); \
__dtrace_probe___mib_##x(y, stataddr); \
(s)->x += (y); \
}
#define SET_MIB(x, y) x = y
#define BUMP_LOCAL(x) (x)++
#define UPDATE_LOCAL(x, y) (x) += (y)
#define OCTET_LENGTH 32 /* Must be at least LIFNAMSIZ */
typedef struct Octet_s {
int o_length;
char o_bytes[OCTET_LENGTH];
} Octet_t;
typedef uint32_t Counter;
typedef uint32_t Counter32;
typedef uint64_t Counter64;
typedef uint32_t Gauge;
typedef uint32_t IpAddress;
typedef struct in6_addr Ip6Address;
typedef Octet_t DeviceName;
typedef Octet_t PhysAddress;
typedef uint32_t DeviceIndex; /* Interface index */
/*
* IP group
*/
#define MIB2_IP_ADDR 20 /* ipAddrEntry */
#define MIB2_IP_ROUTE 21 /* ipRouteEntry */
#define MIB2_IP_MEDIA 22 /* ipNetToMediaEntry */
#define MIB2_IP6_ROUTE 23 /* ipv6RouteEntry */
#define MIB2_IP6_MEDIA 24 /* ipv6NetToMediaEntry */
#define MIB2_IP6_ADDR 25 /* ipv6AddrEntry */
#define EXPER_IP_GROUP_MEMBERSHIP 100
#define EXPER_IP6_GROUP_MEMBERSHIP 101
#define EXPER_IP_GROUP_SOURCES 102
#define EXPER_IP6_GROUP_SOURCES 103
/* Old names retained for compatibility */
#define MIB2_IP_20 MIB2_IP_ADDR
#define MIB2_IP_21 MIB2_IP_ROUTE
#define MIB2_IP_22 MIB2_IP_MEDIA
typedef struct mib2_ip {
/* forwarder? 1 gateway, 2 NOT gateway {ip 1} RW */
int ipForwarding;
/* default Time-to-Live for iph {ip 2} RW */
int ipDefaultTTL;
/* # of input datagrams {ip 3} */
Counter ipInReceives;
/* # of dg discards for iph error {ip 4} */
Counter ipInHdrErrors;
/* # of dg discards for bad addr {ip 5} */
Counter ipInAddrErrors;
/* # of dg being forwarded {ip 6} */
Counter ipForwDatagrams;
/* # of dg discards for unk protocol {ip 7} */
Counter ipInUnknownProtos;
/* # of dg discards of good dg's {ip 8} */
Counter ipInDiscards;
/* # of dg sent upstream {ip 9} */
Counter ipInDelivers;
/* # of outdgs recv'd from upstream {ip 10} */
Counter ipOutRequests;
/* # of good outdgs discarded {ip 11} */
Counter ipOutDiscards;
/* # of outdg discards: no route found {ip 12} */
Counter ipOutNoRoutes;
/* sec's recv'd frags held for reass. {ip 13} */
int ipReasmTimeout;
/* # of ip frags needing reassembly {ip 14} */
Counter ipReasmReqds;
/* # of dg's reassembled {ip 15} */
Counter ipReasmOKs;
/* # of reassembly failures (not dg cnt){ip 16} */
Counter ipReasmFails;
/* # of dg's fragged {ip 17} */
Counter ipFragOKs;
/* # of dg discards for no frag set {ip 18} */
Counter ipFragFails;
/* # of dg frags from fragmentation {ip 19} */
Counter ipFragCreates;
/* {ip 20} */
int ipAddrEntrySize;
/* {ip 21} */
int ipRouteEntrySize;
/* {ip 22} */
int ipNetToMediaEntrySize;
/* # of valid route entries discarded {ip 23} */
Counter ipRoutingDiscards;
/*
* following defined in MIB-II as part of TCP & UDP groups:
*/
/* total # of segments recv'd with error { tcp 14 } */
Counter tcpInErrs;
/* # of recv'd dg's not deliverable (no appl.) { udp 2 } */
Counter udpNoPorts;
/*
* In addition to MIB-II
*/
/* # of bad IP header checksums */
Counter ipInCksumErrs;
/* # of complete duplicates in reassembly */
Counter ipReasmDuplicates;
/* # of partial duplicates in reassembly */
Counter ipReasmPartDups;
/* # of packets not forwarded due to adminstrative reasons */
Counter ipForwProhibits;
/* # of UDP packets with bad UDP checksums */
Counter udpInCksumErrs;
/* # of UDP packets droped due to queue overflow */
Counter udpInOverflows;
/*
* # of RAW IP packets (all IP protocols except UDP, TCP
* and ICMP) droped due to queue overflow
*/
Counter rawipInOverflows;
/*
* Folowing are private IPSEC MIB.
*/
/* # of incoming packets that succeeded policy checks */
Counter ipsecInSucceeded;
/* # of incoming packets that failed policy checks */
Counter ipsecInFailed;
/* Compatible extensions added here */
int ipMemberEntrySize; /* Size of ip_member_t */
int ipGroupSourceEntrySize; /* Size of ip_grpsrc_t */
/* # of IPv6 packets received by IPv4 and dropped */
Counter ipInIPv6;
/* # of IPv6 packets transmitted by ip_wput */
Counter ipOutIPv6;
/* # of times ip_wput has switched to become ip_wput_v6 */
Counter ipOutSwitchIPv6;
} mib2_ip_t;
/*
* ipv6IfStatsEntry OBJECT-TYPE
* SYNTAX Ipv6IfStatsEntry
* MAX-ACCESS not-accessible
* STATUS current
* DESCRIPTION
* "An interface statistics entry containing objects
* at a particular IPv6 interface."
* AUGMENTS { ipv6IfEntry }
* ::= { ipv6IfStatsTable 1 }
*
* Per-interface IPv6 statistics table
*/
typedef struct mib2_ipv6IfStatsEntry {
/* Local ifindex to identify the interface */
DeviceIndex ipv6IfIndex;
/* forwarder? 1 gateway, 2 NOT gateway {ipv6MIBObjects 1} RW */
int ipv6Forwarding;
/* default Hoplimit for IPv6 {ipv6MIBObjects 2} RW */
int ipv6DefaultHopLimit;
int ipv6IfStatsEntrySize;
int ipv6AddrEntrySize;
int ipv6RouteEntrySize;
int ipv6NetToMediaEntrySize;
int ipv6MemberEntrySize; /* Size of ipv6_member_t */
int ipv6GroupSourceEntrySize; /* Size of ipv6_grpsrc_t */
/* # input datagrams (incl errors) { ipv6IfStatsEntry 1 } */
Counter ipv6InReceives;
/* # errors in IPv6 headers and options { ipv6IfStatsEntry 2 } */
Counter ipv6InHdrErrors;
/* # exceeds outgoing link MTU { ipv6IfStatsEntry 3 } */
Counter ipv6InTooBigErrors;
/* # discarded due to no route to dest { ipv6IfStatsEntry 4 } */
Counter ipv6InNoRoutes;
/* # invalid or unsupported addresses { ipv6IfStatsEntry 5 } */
Counter ipv6InAddrErrors;
/* # unknown next header { ipv6IfStatsEntry 6 } */
Counter ipv6InUnknownProtos;
/* # too short packets { ipv6IfStatsEntry 7 } */
Counter ipv6InTruncatedPkts;
/* # discarded e.g. due to no buffers { ipv6IfStatsEntry 8 } */
Counter ipv6InDiscards;
/* # delivered to upper layer protocols { ipv6IfStatsEntry 9 } */
Counter ipv6InDelivers;
/* # forwarded out interface { ipv6IfStatsEntry 10 } */
Counter ipv6OutForwDatagrams;
/* # originated out interface { ipv6IfStatsEntry 11 } */
Counter ipv6OutRequests;
/* # discarded e.g. due to no buffers { ipv6IfStatsEntry 12 } */
Counter ipv6OutDiscards;
/* # sucessfully fragmented packets { ipv6IfStatsEntry 13 } */
Counter ipv6OutFragOKs;
/* # fragmentation failed { ipv6IfStatsEntry 14 } */
Counter ipv6OutFragFails;
/* # fragments created { ipv6IfStatsEntry 15 } */
Counter ipv6OutFragCreates;
/* # fragments to reassemble { ipv6IfStatsEntry 16 } */
Counter ipv6ReasmReqds;
/* # packets after reassembly { ipv6IfStatsEntry 17 } */
Counter ipv6ReasmOKs;
/* # reassembly failed { ipv6IfStatsEntry 18 } */
Counter ipv6ReasmFails;
/* # received multicast packets { ipv6IfStatsEntry 19 } */
Counter ipv6InMcastPkts;
/* # transmitted multicast packets { ipv6IfStatsEntry 20 } */
Counter ipv6OutMcastPkts;
/*
* In addition to defined MIBs
*/
/* # discarded due to no route to dest */
Counter ipv6OutNoRoutes;
/* # of complete duplicates in reassembly */
Counter ipv6ReasmDuplicates;
/* # of partial duplicates in reassembly */
Counter ipv6ReasmPartDups;
/* # of packets not forwarded due to adminstrative reasons */
Counter ipv6ForwProhibits;
/* # of UDP packets with bad UDP checksums */
Counter udpInCksumErrs;
/* # of UDP packets droped due to queue overflow */
Counter udpInOverflows;
/*
* # of RAW IPv6 packets (all IPv6 protocols except UDP, TCP
* and ICMPv6) droped due to queue overflow
*/
Counter rawipInOverflows;
/* # of IPv4 packets received by IPv6 and dropped */
Counter ipv6InIPv4;
/* # of IPv4 packets transmitted by ip_wput_wput */
Counter ipv6OutIPv4;
/* # of times ip_wput_v6 has switched to become ip_wput */
Counter ipv6OutSwitchIPv4;
} mib2_ipv6IfStatsEntry_t;
/*
* The IP address table contains this entity's IP addressing information.
*
* ipAddrTable OBJECT-TYPE
* SYNTAX SEQUENCE OF IpAddrEntry
* ACCESS not-accessible
* STATUS mandatory
* DESCRIPTION
* "The table of addressing information relevant to
* this entity's IP addresses."
* ::= { ip 20 }
*/
typedef struct mib2_ipAddrEntry {
/* IP address of this entry {ipAddrEntry 1} */
IpAddress ipAdEntAddr;
/* Unique interface index {ipAddrEntry 2} */
DeviceName ipAdEntIfIndex;
/* Subnet mask for this IP addr {ipAddrEntry 3} */
IpAddress ipAdEntNetMask;
/* 2^lsb of IP broadcast addr {ipAddrEntry 4} */
int ipAdEntBcastAddr;
/* max size for dg reassembly {ipAddrEntry 5} */
int ipAdEntReasmMaxSize;
/* additional ipif_t fields */
struct ipAdEntInfo_s {
Gauge ae_mtu;
/* BSD if metric */
int ae_metric;
/* ipif broadcast addr. relation to above?? */
IpAddress ae_broadcast_addr;
/* point-point dest addr */
IpAddress ae_pp_dst_addr;
int ae_flags; /* IFF_* flags in if.h */
Counter ae_ibcnt; /* Inbound packets */
Counter ae_obcnt; /* Outbound packets */
Counter ae_focnt; /* Forwarded packets */
IpAddress ae_subnet; /* Subnet prefix */
int ae_subnet_len; /* Subnet prefix length */
IpAddress ae_src_addr; /* Source address */
} ipAdEntInfo;
} mib2_ipAddrEntry_t;
/*
* ipv6AddrTable OBJECT-TYPE
* SYNTAX SEQUENCE OF Ipv6AddrEntry
* MAX-ACCESS not-accessible
* STATUS current
* DESCRIPTION
* "The table of addressing information relevant to
* this node's interface addresses."
* ::= { ipv6MIBObjects 8 }
*/
typedef struct mib2_ipv6AddrEntry {
/* Unique interface index { Part of INDEX } */
DeviceName ipv6AddrIfIndex;
/* IPv6 address of this entry { ipv6AddrEntry 1 } */
Ip6Address ipv6AddrAddress;
/* Prefix length { ipv6AddrEntry 2 } */
uint_t ipv6AddrPfxLength;
/* Type: stateless(1), stateful(2), unknown(3) { ipv6AddrEntry 3 } */
uint_t ipv6AddrType;
/* Anycast: true(1), false(2) { ipv6AddrEntry 4 } */
uint_t ipv6AddrAnycastFlag;
/*
* Address status: preferred(1), deprecated(2), invalid(3),
* inaccessible(4), unknown(5) { ipv6AddrEntry 5 }
*/
uint_t ipv6AddrStatus;
struct ipv6AddrInfo_s {
Gauge ae_mtu;
/* BSD if metric */
int ae_metric;
/* point-point dest addr */
Ip6Address ae_pp_dst_addr;
int ae_flags; /* IFF_* flags in if.h */
Counter ae_ibcnt; /* Inbound packets */
Counter ae_obcnt; /* Outbound packets */
Counter ae_focnt; /* Forwarded packets */
Ip6Address ae_subnet; /* Subnet prefix */
int ae_subnet_len; /* Subnet prefix length */
Ip6Address ae_src_addr; /* Source address */
} ipv6AddrInfo;
} mib2_ipv6AddrEntry_t;
/*
* The IP routing table contains an entry for each route presently known to
* this entity. (for IPv4 routes)
*
* ipRouteTable OBJECT-TYPE
* SYNTAX SEQUENCE OF IpRouteEntry
* ACCESS not-accessible
* STATUS mandatory
* DESCRIPTION
* "This entity's IP Routing table."
* ::= { ip 21 }
*/
typedef struct mib2_ipRouteEntry {
/* dest ip addr for this route {ipRouteEntry 1 } RW */
IpAddress ipRouteDest;
/* unique interface index for this hop {ipRouteEntry 2 } RW */
DeviceName ipRouteIfIndex;
/* primary route metric {ipRouteEntry 3 } RW */
int ipRouteMetric1;
/* alternate route metric {ipRouteEntry 4 } RW */
int ipRouteMetric2;
/* alternate route metric {ipRouteEntry 5 } RW */
int ipRouteMetric3;
/* alternate route metric {ipRouteEntry 6 } RW */
int ipRouteMetric4;
/* ip addr of next hop on this route {ipRouteEntry 7 } RW */
IpAddress ipRouteNextHop;
/* other(1), inval(2), dir(3), indir(4) {ipRouteEntry 8 } RW */
int ipRouteType;
/* mechanism by which route was learned {ipRouteEntry 9 } */
int ipRouteProto;
/* sec's since last update of route {ipRouteEntry 10} RW */
int ipRouteAge;
/* {ipRouteEntry 11} RW */
IpAddress ipRouteMask;
/* alternate route metric {ipRouteEntry 12} RW */
int ipRouteMetric5;
/* additional info from ire's {ipRouteEntry 13 } */
struct ipRouteInfo_s {
Gauge re_max_frag;
Gauge re_rtt;
Counter re_ref;
int re_frag_flag;
IpAddress re_src_addr;
int re_ire_type;
Counter re_obpkt;
Counter re_ibpkt;
int re_flags;
DeviceName re_in_ill; /* Input interface */
IpAddress re_in_src_addr; /* Input source address */
} ipRouteInfo;
} mib2_ipRouteEntry_t;
/*
* The IPv6 routing table contains an entry for each route presently known to
* this entity.
*
* ipv6RouteTable OBJECT-TYPE
* SYNTAX SEQUENCE OF IpRouteEntry
* ACCESS not-accessible
* STATUS current
* DESCRIPTION
* "IPv6 Routing table. This table contains
* an entry for each valid IPv6 unicast route
* that can be used for packet forwarding
* determination."
* ::= { ipv6MIBObjects 11 }
*/
typedef struct mib2_ipv6RouteEntry {
/* dest ip addr for this route { ipv6RouteEntry 1 } */
Ip6Address ipv6RouteDest;
/* prefix length { ipv6RouteEntry 2 } */
int ipv6RoutePfxLength;
/* unique route index { ipv6RouteEntry 3 } */
unsigned ipv6RouteIndex;
/* unique interface index for this hop { ipv6RouteEntry 4 } */
DeviceName ipv6RouteIfIndex;
/* IPv6 addr of next hop on this route { ipv6RouteEntry 5 } */
Ip6Address ipv6RouteNextHop;
/* other(1), discard(2), local(3), remote(4) */
/* { ipv6RouteEntry 6 } */
int ipv6RouteType;
/* mechanism by which route was learned { ipv6RouteEntry 7 } */
/*
* other(1), local(2), netmgmt(3), ndisc(4), rip(5), ospf(6),
* bgp(7), idrp(8), igrp(9)
*/
int ipv6RouteProtocol;
/* policy hook or traffic class { ipv6RouteEntry 8 } */
unsigned ipv6RoutePolicy;
/* sec's since last update of route { ipv6RouteEntry 9} */
int ipv6RouteAge;
/* Routing domain ID of the next hop { ipv6RouteEntry 10 } */
unsigned ipv6RouteNextHopRDI;
/* route metric { ipv6RouteEntry 11 } */
unsigned ipv6RouteMetric;
/* preference (impl specific) { ipv6RouteEntry 12 } */
unsigned ipv6RouteWeight;
/* additional info from ire's { } */
struct ipv6RouteInfo_s {
Gauge re_max_frag;
Gauge re_rtt;
Counter re_ref;
int re_frag_flag;
Ip6Address re_src_addr;
int re_ire_type;
Counter re_obpkt;
Counter re_ibpkt;
int re_flags;
} ipv6RouteInfo;
} mib2_ipv6RouteEntry_t;
/*
* The IP address translation table contain the IpAddress to
* `physical' address equivalences. Some interfaces do not
* use translation tables for determining address
* equivalences (e.g., DDN-X.25 has an algorithmic method);
* if all interfaces are of this type, then the Address
* Translation table is empty, i.e., has zero entries.
*
* ipNetToMediaTable OBJECT-TYPE
* SYNTAX SEQUENCE OF IpNetToMediaEntry
* ACCESS not-accessible
* STATUS mandatory
* DESCRIPTION
* "The IP Address Translation table used for mapping
* from IP addresses to physical addresses."
* ::= { ip 22 }
*/
typedef struct mib2_ipNetToMediaEntry {
/* Unique interface index { ipNetToMediaEntry 1 } RW */
DeviceName ipNetToMediaIfIndex;
/* Media dependent physical addr { ipNetToMediaEntry 2 } RW */
PhysAddress ipNetToMediaPhysAddress;
/* ip addr for this physical addr { ipNetToMediaEntry 3 } RW */
IpAddress ipNetToMediaNetAddress;
/* other(1), inval(2), dyn(3), stat(4) { ipNetToMediaEntry 4 } RW */
int ipNetToMediaType;
struct ipNetToMediaInfo_s {
PhysAddress ntm_mask; /* subnet mask for entry */
int ntm_flags; /* ACE_F_* flags in arp.h */
} ipNetToMediaInfo;
} mib2_ipNetToMediaEntry_t;
/*
* ipv6NetToMediaTable OBJECT-TYPE
* SYNTAX SEQUENCE OF Ipv6NetToMediaEntry
* MAX-ACCESS not-accessible
* STATUS current
* DESCRIPTION
* "The IPv6 Address Translation table used for
* mapping from IPv6 addresses to physical addresses.
*
* The IPv6 address translation table contain the
* Ipv6Address to `physical' address equivalencies.
* Some interfaces do not use translation tables
* for determining address equivalencies; if all
* interfaces are of this type, then the Address
* Translation table is empty, i.e., has zero
* entries."
* ::= { ipv6MIBObjects 12 }
*/
typedef struct mib2_ipv6NetToMediaEntry {
/* Unique interface index { Part of INDEX } */
DeviceIndex ipv6NetToMediaIfIndex;
/* ip addr for this physical addr { ipv6NetToMediaEntry 1 } */
Ip6Address ipv6NetToMediaNetAddress;
/* Media dependent physical addr { ipv6NetToMediaEntry 2 } */
PhysAddress ipv6NetToMediaPhysAddress;
/*
* Type of mapping
* other(1), dynamic(2), static(3), local(4)
* { ipv6NetToMediaEntry 3 }
*/
int ipv6NetToMediaType;
/*
* NUD state
* reachable(1), stale(2), delay(3), probe(4), invalid(5), unknown(6)
* Note: The kernel returns ND_* states.
* { ipv6NetToMediaEntry 4 }
*/
int ipv6NetToMediaState;
/* sysUpTime last time entry was updated { ipv6NetToMediaEntry 5 } */
int ipv6NetToMediaLastUpdated;
} mib2_ipv6NetToMediaEntry_t;
/*
* List of group members per interface
*/
typedef struct ip_member {
/* Interface index */
DeviceName ipGroupMemberIfIndex;
/* IP Multicast address */
IpAddress ipGroupMemberAddress;
/* Number of member sockets */
Counter ipGroupMemberRefCnt;
/* Filter mode: 1 => include, 2 => exclude */
int ipGroupMemberFilterMode;
} ip_member_t;
/*
* List of IPv6 group members per interface
*/
typedef struct ipv6_member {
/* Interface index */
DeviceIndex ipv6GroupMemberIfIndex;
/* IP Multicast address */
Ip6Address ipv6GroupMemberAddress;
/* Number of member sockets */
Counter ipv6GroupMemberRefCnt;
/* Filter mode: 1 => include, 2 => exclude */
int ipv6GroupMemberFilterMode;
} ipv6_member_t;
/*
* List of IPv4 source addresses being filtered per interface
*/
typedef struct ip_grpsrc {
/* Interface index */
DeviceName ipGroupSourceIfIndex;
/* IP Multicast address */
IpAddress ipGroupSourceGroup;
/* IP Source address */
IpAddress ipGroupSourceAddress;
} ip_grpsrc_t;
/*
* List of IPv6 source addresses being filtered per interface
*/
typedef struct ipv6_grpsrc {
/* Interface index */
DeviceIndex ipv6GroupSourceIfIndex;
/* IP Multicast address */
Ip6Address ipv6GroupSourceGroup;
/* IP Source address */
Ip6Address ipv6GroupSourceAddress;
} ipv6_grpsrc_t;
/*
* ICMP Group
*/
typedef struct mib2_icmp {
/* total # of recv'd ICMP msgs { icmp 1 } */
Counter icmpInMsgs;
/* recv'd ICMP msgs with errors { icmp 2 } */
Counter icmpInErrors;
/* recv'd "dest unreachable" msg's { icmp 3 } */
Counter icmpInDestUnreachs;
/* recv'd "time exceeded" msg's { icmp 4 } */
Counter icmpInTimeExcds;
/* recv'd "parameter problem" msg's { icmp 5 } */
Counter icmpInParmProbs;
/* recv'd "source quench" msg's { icmp 6 } */
Counter icmpInSrcQuenchs;
/* recv'd "ICMP redirect" msg's { icmp 7 } */
Counter icmpInRedirects;
/* recv'd "echo request" msg's { icmp 8 } */
Counter icmpInEchos;
/* recv'd "echo reply" msg's { icmp 9 } */
Counter icmpInEchoReps;
/* recv'd "timestamp" msg's { icmp 10 } */
Counter icmpInTimestamps;
/* recv'd "timestamp reply" msg's { icmp 11 } */
Counter icmpInTimestampReps;
/* recv'd "address mask request" msg's { icmp 12 } */
Counter icmpInAddrMasks;
/* recv'd "address mask reply" msg's { icmp 13 } */
Counter icmpInAddrMaskReps;
/* total # of sent ICMP msg's { icmp 14 } */
Counter icmpOutMsgs;
/* # of msg's not sent for internal icmp errors { icmp 15 } */
Counter icmpOutErrors;
/* # of "dest unreachable" msg's sent { icmp 16 } */
Counter icmpOutDestUnreachs;
/* # of "time exceeded" msg's sent { icmp 17 } */
Counter icmpOutTimeExcds;
/* # of "parameter problme" msg's sent { icmp 18 } */
Counter icmpOutParmProbs;
/* # of "source quench" msg's sent { icmp 19 } */
Counter icmpOutSrcQuenchs;
/* # of "ICMP redirect" msg's sent { icmp 20 } */
Counter icmpOutRedirects;
/* # of "Echo request" msg's sent { icmp 21 } */
Counter icmpOutEchos;
/* # of "Echo reply" msg's sent { icmp 22 } */
Counter icmpOutEchoReps;
/* # of "timestamp request" msg's sent { icmp 23 } */
Counter icmpOutTimestamps;
/* # of "timestamp reply" msg's sent { icmp 24 } */
Counter icmpOutTimestampReps;
/* # of "address mask request" msg's sent { icmp 25 } */
Counter icmpOutAddrMasks;
/* # of "address mask reply" msg's sent { icmp 26 } */
Counter icmpOutAddrMaskReps;
/*
* In addition to MIB-II
*/
/* # of received packets with checksum errors */
Counter icmpInCksumErrs;
/* # of received packets with unknow codes */
Counter icmpInUnknowns;
/* # of received unreachables with "fragmentation needed" */
Counter icmpInFragNeeded;
/* # of sent unreachables with "fragmentation needed" */
Counter icmpOutFragNeeded;
/*
* # of msg's not sent since original packet was broadcast/multicast
* or an ICMP error packet
*/
Counter icmpOutDrops;
/* # of ICMP packets droped due to queue overflow */
Counter icmpInOverflows;
/* recv'd "ICMP redirect" msg's that are bad thus ignored */
Counter icmpInBadRedirects;
} mib2_icmp_t;
/*
* ipv6IfIcmpEntry OBJECT-TYPE
* SYNTAX Ipv6IfIcmpEntry
* MAX-ACCESS not-accessible
* STATUS current
* DESCRIPTION
* "An ICMPv6 statistics entry containing
* objects at a particular IPv6 interface.
*
* Note that a receiving interface is
* the interface to which a given ICMPv6 message
* is addressed which may not be necessarily
* the input interface for the message.
*
* Similarly, the sending interface is
* the interface that sources a given
* ICMP message which is usually but not
* necessarily the output interface for the message."
* AUGMENTS { ipv6IfEntry }
* ::= { ipv6IfIcmpTable 1 }
*
* Per-interface ICMPv6 statistics table
*/
typedef struct mib2_ipv6IfIcmpEntry {
/* Local ifindex to identify the interface */
DeviceIndex ipv6IfIcmpIfIndex;
int ipv6IfIcmpEntrySize; /* Size of ipv6IfIcmpEntry */
/* The total # ICMP msgs rcvd includes ipv6IfIcmpInErrors */
Counter32 ipv6IfIcmpInMsgs;
/* # ICMP with ICMP-specific errors (bad checkum, length, etc) */
Counter32 ipv6IfIcmpInErrors;
/* # ICMP Destination Unreachable */
Counter32 ipv6IfIcmpInDestUnreachs;
/* # ICMP destination unreachable/communication admin prohibited */
Counter32 ipv6IfIcmpInAdminProhibs;
Counter32 ipv6IfIcmpInTimeExcds;
Counter32 ipv6IfIcmpInParmProblems;
Counter32 ipv6IfIcmpInPktTooBigs;
Counter32 ipv6IfIcmpInEchos;
Counter32 ipv6IfIcmpInEchoReplies;
Counter32 ipv6IfIcmpInRouterSolicits;
Counter32 ipv6IfIcmpInRouterAdvertisements;
Counter32 ipv6IfIcmpInNeighborSolicits;
Counter32 ipv6IfIcmpInNeighborAdvertisements;
Counter32 ipv6IfIcmpInRedirects;
Counter32 ipv6IfIcmpInGroupMembQueries;
Counter32 ipv6IfIcmpInGroupMembResponses;
Counter32 ipv6IfIcmpInGroupMembReductions;
/* Total # ICMP messages attempted to send (includes OutErrors) */
Counter32 ipv6IfIcmpOutMsgs;
/* # ICMP messages not sent due to ICMP problems (e.g. no buffers) */
Counter32 ipv6IfIcmpOutErrors;
Counter32 ipv6IfIcmpOutDestUnreachs;
Counter32 ipv6IfIcmpOutAdminProhibs;
Counter32 ipv6IfIcmpOutTimeExcds;
Counter32 ipv6IfIcmpOutParmProblems;
Counter32 ipv6IfIcmpOutPktTooBigs;
Counter32 ipv6IfIcmpOutEchos;
Counter32 ipv6IfIcmpOutEchoReplies;
Counter32 ipv6IfIcmpOutRouterSolicits;
Counter32 ipv6IfIcmpOutRouterAdvertisements;
Counter32 ipv6IfIcmpOutNeighborSolicits;
Counter32 ipv6IfIcmpOutNeighborAdvertisements;
Counter32 ipv6IfIcmpOutRedirects;
Counter32 ipv6IfIcmpOutGroupMembQueries;
Counter32 ipv6IfIcmpOutGroupMembResponses;
Counter32 ipv6IfIcmpOutGroupMembReductions;
/* Additions beyond the MIB */
Counter32 ipv6IfIcmpInOverflows;
/* recv'd "ICMPv6 redirect" msg's that are bad thus ignored */
Counter32 ipv6IfIcmpBadHoplimit;
Counter32 ipv6IfIcmpInBadNeighborAdvertisements;
Counter32 ipv6IfIcmpInBadNeighborSolicitations;
Counter32 ipv6IfIcmpInBadRedirects;
Counter32 ipv6IfIcmpInGroupMembTotal;
Counter32 ipv6IfIcmpInGroupMembBadQueries;
Counter32 ipv6IfIcmpInGroupMembBadReports;
Counter32 ipv6IfIcmpInGroupMembOurReports;
} mib2_ipv6IfIcmpEntry_t;
/*
* the TCP group
*
* Note that instances of object types that represent
* information about a particular TCP connection are
* transient; they persist only as long as the connection
* in question.
*/
#define MIB2_TCP_CONN 13 /* tcpConnEntry */
#define MIB2_TCP6_CONN 14 /* tcp6ConnEntry */
/* Old name retained for compatibility */
#define MIB2_TCP_13 MIB2_TCP_CONN
typedef struct mib2_tcp {
/* algorithm used for transmit timeout value { tcp 1 } */
int tcpRtoAlgorithm;
/* minimum retransmit timeout (ms) { tcp 2 } */
int tcpRtoMin;
/* maximum retransmit timeout (ms) { tcp 3 } */
int tcpRtoMax;
/* maximum # of connections supported { tcp 4 } */
int tcpMaxConn;
/* # of direct transitions CLOSED -> SYN-SENT { tcp 5 } */
Counter tcpActiveOpens;
/* # of direct transitions LISTEN -> SYN-RCVD { tcp 6 } */
Counter tcpPassiveOpens;
/* # of direct SIN-SENT/RCVD -> CLOSED/LISTEN { tcp 7 } */
Counter tcpAttemptFails;
/* # of direct ESTABLISHED/CLOSE-WAIT -> CLOSED { tcp 8 } */
Counter tcpEstabResets;
/* # of connections ESTABLISHED or CLOSE-WAIT { tcp 9 } */
Gauge tcpCurrEstab;
/* total # of segments recv'd { tcp 10 } */
Counter tcpInSegs;
/* total # of segments sent { tcp 11 } */
Counter tcpOutSegs;
/* total # of segments retransmitted { tcp 12 } */
Counter tcpRetransSegs;
/* {tcp 13} */
int tcpConnTableSize; /* Size of tcpConnEntry_t */
/* in ip {tcp 14} */
/* # of segments sent with RST flag { tcp 15 } */
Counter tcpOutRsts;
/* In addition to MIB-II */
/* Sender */
/* total # of data segments sent */
Counter tcpOutDataSegs;
/* total # of bytes in data segments sent */
Counter tcpOutDataBytes;
/* total # of bytes in segments retransmitted */
Counter tcpRetransBytes;
/* total # of acks sent */
Counter tcpOutAck;
/* total # of delayed acks sent */
Counter tcpOutAckDelayed;
/* total # of segments sent with the urg flag on */
Counter tcpOutUrg;
/* total # of window updates sent */
Counter tcpOutWinUpdate;
/* total # of zero window probes sent */
Counter tcpOutWinProbe;
/* total # of control segments sent (syn, fin, rst) */
Counter tcpOutControl;
/* total # of segments sent due to "fast retransmit" */
Counter tcpOutFastRetrans;
/* Receiver */
/* total # of ack segments received */
Counter tcpInAckSegs;
/* total # of bytes acked */
Counter tcpInAckBytes;
/* total # of duplicate acks */
Counter tcpInDupAck;
/* total # of acks acking unsent data */
Counter tcpInAckUnsent;
/* total # of data segments received in order */
Counter tcpInDataInorderSegs;
/* total # of data bytes received in order */
Counter tcpInDataInorderBytes;
/* total # of data segments received out of order */
Counter tcpInDataUnorderSegs;
/* total # of data bytes received out of order */
Counter tcpInDataUnorderBytes;
/* total # of complete duplicate data segments received */
Counter tcpInDataDupSegs;
/* total # of bytes in the complete duplicate data segments received */
Counter tcpInDataDupBytes;
/* total # of partial duplicate data segments received */
Counter tcpInDataPartDupSegs;
/* total # of bytes in the partial duplicate data segments received */
Counter tcpInDataPartDupBytes;
/* total # of data segments received past the window */
Counter tcpInDataPastWinSegs;
/* total # of data bytes received part the window */
Counter tcpInDataPastWinBytes;
/* total # of zero window probes received */
Counter tcpInWinProbe;
/* total # of window updates received */
Counter tcpInWinUpdate;
/* total # of data segments received after the connection has closed */
Counter tcpInClosed;
/* Others */
/* total # of failed attempts to update the rtt estimate */
Counter tcpRttNoUpdate;
/* total # of successful attempts to update the rtt estimate */
Counter tcpRttUpdate;
/* total # of retransmit timeouts */
Counter tcpTimRetrans;
/* total # of retransmit timeouts dropping the connection */
Counter tcpTimRetransDrop;
/* total # of keepalive timeouts */
Counter tcpTimKeepalive;
/* total # of keepalive timeouts sending a probe */
Counter tcpTimKeepaliveProbe;
/* total # of keepalive timeouts dropping the connection */
Counter tcpTimKeepaliveDrop;
/* total # of connections refused due to backlog full on listen */
Counter tcpListenDrop;
/* total # of connections refused due to half-open queue (q0) full */
Counter tcpListenDropQ0;
/* total # of connections dropped from a full half-open queue (q0) */
Counter tcpHalfOpenDrop;
/* total # of retransmitted segments by SACK retransmission */
Counter tcpOutSackRetransSegs;
int tcp6ConnTableSize; /* Size of tcp6ConnEntry_t */
} mib2_tcp_t;
/*
* The TCP/IPv4 connection table {tcp 13} contains information about this
* entity's existing TCP connections over IPv4.
*/
/* For tcpConnState and tcp6ConnState */
#define MIB2_TCP_closed 1
#define MIB2_TCP_listen 2
#define MIB2_TCP_synSent 3
#define MIB2_TCP_synReceived 4
#define MIB2_TCP_established 5
#define MIB2_TCP_finWait1 6
#define MIB2_TCP_finWait2 7
#define MIB2_TCP_closeWait 8
#define MIB2_TCP_lastAck 9
#define MIB2_TCP_closing 10
#define MIB2_TCP_timeWait 11
#define MIB2_TCP_deleteTCB 12 /* only writeable value */
typedef struct mib2_tcpConnEntry {
/* state of tcp connection { tcpConnEntry 1} RW */
int tcpConnState;
/* local ip addr for this connection { tcpConnEntry 2 } */
IpAddress tcpConnLocalAddress;
/* local port for this connection { tcpConnEntry 3 } */
int tcpConnLocalPort; /* In host byte order */
/* remote ip addr for this connection { tcpConnEntry 4 } */
IpAddress tcpConnRemAddress;
/* remote port for this connection { tcpConnEntry 5 } */
int tcpConnRemPort; /* In host byte order */
struct tcpConnEntryInfo_s {
/* seq # of next segment to send */
Gauge ce_snxt;
/* seq # of of last segment unacknowledged */
Gauge ce_suna;
/* currect send window size */
Gauge ce_swnd;
/* seq # of next expected segment */
Gauge ce_rnxt;
/* seq # of last ack'd segment */
Gauge ce_rack;
/* currenct receive window size */
Gauge ce_rwnd;
/* current rto (retransmit timeout) */
Gauge ce_rto;
/* current max segment size */
Gauge ce_mss;
/* actual internal state */
int ce_state;
} tcpConnEntryInfo;
} mib2_tcpConnEntry_t;
/*
* The TCP/IPv6 connection table {tcp 14} contains information about this
* entity's existing TCP connections over IPv6.
*/
typedef struct mib2_tcp6ConnEntry {
/* local ip addr for this connection { ipv6TcpConnEntry 1 } */
Ip6Address tcp6ConnLocalAddress;
/* local port for this connection { ipv6TcpConnEntry 2 } */
int tcp6ConnLocalPort;
/* remote ip addr for this connection { ipv6TcpConnEntry 3 } */
Ip6Address tcp6ConnRemAddress;
/* remote port for this connection { ipv6TcpConnEntry 4 } */
int tcp6ConnRemPort;
/* interface index or zero { ipv6TcpConnEntry 5 } */
DeviceIndex tcp6ConnIfIndex;
/* state of tcp6 connection { ipv6TcpConnEntry 6 } RW */
int tcp6ConnState;
struct tcp6ConnEntryInfo_s {
/* seq # of next segment to send */
Gauge ce_snxt;
/* seq # of of last segment unacknowledged */
Gauge ce_suna;
/* currect send window size */
Gauge ce_swnd;
/* seq # of next expected segment */
Gauge ce_rnxt;
/* seq # of last ack'd segment */
Gauge ce_rack;
/* currenct receive window size */
Gauge ce_rwnd;
/* current rto (retransmit timeout) */
Gauge ce_rto;
/* current max segment size */
Gauge ce_mss;
/* actual internal state */
int ce_state;
} tcp6ConnEntryInfo;
} mib2_tcp6ConnEntry_t;
/*
* the UDP group
*/
#define MIB2_UDP_ENTRY 5 /* udpEntry */
#define MIB2_UDP6_ENTRY 6 /* udp6Entry */
/* Old name retained for compatibility */
#define MIB2_UDP_5 MIB2_UDP_ENTRY
typedef struct mib2_udp {
/* total # of UDP datagrams sent upstream { udp 1 } */
Counter udpInDatagrams;
/* in ip { udp 2 } */
/* # of recv'd dg's not deliverable (other) { udp 3 } */
Counter udpInErrors;
/* total # of dg's sent { udp 4 } */
Counter udpOutDatagrams;
/* { udp 5 } */
int udpEntrySize; /* Size of udpEntry_t */
int udp6EntrySize; /* Size of udp6Entry_t */
Counter udpOutErrors;
} mib2_udp_t;
/*
* The UDP listener table contains information about this entity's UDP
* end-points on which a local application is currently accepting datagrams.
*/
/* For both IPv4 and IPv6 ue_state: */
#define MIB2_UDP_unbound 1
#define MIB2_UDP_idle 2
#define MIB2_UDP_connected 3
#define MIB2_UDP_unknown 4
typedef struct mib2_udpEntry {
/* local ip addr of listener { udpEntry 1 } */
IpAddress udpLocalAddress;
/* local port of listener { udpEntry 2 } */
int udpLocalPort; /* In host byte order */
struct udpEntryInfo_s {
int ue_state;
IpAddress ue_RemoteAddress;
int ue_RemotePort; /* In host byte order */
} udpEntryInfo;
} mib2_udpEntry_t;
/*
* The UDP (for IPv6) listener table contains information about this
* entity's UDP end-points on which a local application is
* currently accepting datagrams.
*/
typedef struct mib2_udp6Entry {
/* local ip addr of listener { ipv6UdpEntry 1 } */
Ip6Address udp6LocalAddress;
/* local port of listener { ipv6UdpEntry 2 } */
int udp6LocalPort; /* In host byte order */
/* interface index or zero { ipv6UdpEntry 3 } */
DeviceIndex udp6IfIndex;
struct udp6EntryInfo_s {
int ue_state;
Ip6Address ue_RemoteAddress;
int ue_RemotePort; /* In host byte order */
} udp6EntryInfo;
} mib2_udp6Entry_t;
/*
* the RAWIP group
*/
typedef struct mib2_rawip {
/* total # of RAWIP datagrams sent upstream */
Counter rawipInDatagrams;
/* # of RAWIP packets with bad IPV6_CHECKSUM checksums */
Counter rawipInCksumErrs;
/* # of recv'd dg's not deliverable (other) */
Counter rawipInErrors;
/* total # of dg's sent */
Counter rawipOutDatagrams;
/* total # of dg's not sent (e.g. no memory) */
Counter rawipOutErrors;
} mib2_rawip_t;
/* DVMRP group */
#define EXPER_DVMRP_VIF 1
#define EXPER_DVMRP_MRT 2
/*
* The SCTP group
*/
#define MIB2_SCTP_CONN 15
#define MIB2_SCTP_CONN_LOCAL 16
#define MIB2_SCTP_CONN_REMOTE 17
#define MIB2_SCTP_closed 1
#define MIB2_SCTP_cookieWait 2
#define MIB2_SCTP_cookieEchoed 3
#define MIB2_SCTP_established 4
#define MIB2_SCTP_shutdownPending 5
#define MIB2_SCTP_shutdownSent 6
#define MIB2_SCTP_shutdownReceived 7
#define MIB2_SCTP_shutdownAckSent 8
#define MIB2_SCTP_deleteTCB 9
#define MIB2_SCTP_listen 10 /* Not in the MIB */
#define MIB2_SCTP_ACTIVE 1
#define MIB2_SCTP_INACTIVE 2
#define MIB2_SCTP_ADDR_V4 1
#define MIB2_SCTP_ADDR_V6 2
#define MIB2_SCTP_RTOALGO_OTHER 1
#define MIB2_SCTP_RTOALGO_VANJ 2
typedef struct mib2_sctpConnEntry {
/* connection identifier { sctpAssocEntry 1 } */
uint32_t sctpAssocId;
/* remote hostname (not used) { sctpAssocEntry 2 } */
Octet_t sctpAssocRemHostName;
/* local port number { sctpAssocEntry 3 } */
uint32_t sctpAssocLocalPort;
/* remote port number { sctpAssocEntry 4 } */
uint32_t sctpAssocRemPort;
/* type of primary remote addr { sctpAssocEntry 5 } */
int sctpAssocRemPrimAddrType;
/* primary remote address { sctpAssocEntry 6 } */
Ip6Address sctpAssocRemPrimAddr;
/* local address */
Ip6Address sctpAssocLocPrimAddr;
/* current heartbeat interval { sctpAssocEntry 7 } */
uint32_t sctpAssocHeartBeatInterval;
/* state of this association { sctpAssocEntry 8 } */
int sctpAssocState;
/* # of inbound streams { sctpAssocEntry 9 } */
uint32_t sctpAssocInStreams;
/* # of outbound streams { sctpAssocEntry 10 } */
uint32_t sctpAssocOutStreams;
/* max # of data retans { sctpAssocEntry 11 } */
uint32_t sctpAssocMaxRetr;
/* sysId for assoc owner { sctpAssocEntry 12 } */
uint32_t sctpAssocPrimProcess;
/* # of rxmit timeouts during hanshake */
Counter32 sctpAssocT1expired; /* { sctpAssocEntry 13 } */
/* # of rxmit timeouts during shutdown */
Counter32 sctpAssocT2expired; /* { sctpAssocEntry 14 } */
/* # of rxmit timeouts during data transfer */
Counter32 sctpAssocRtxChunks; /* { sctpAssocEntry 15 } */
/* assoc start-up time { sctpAssocEntry 16 } */
uint32_t sctpAssocStartTime;
struct sctpConnEntryInfo_s {
/* amount of data in send Q */
Gauge ce_sendq;
/* amount of data in recv Q */
Gauge ce_recvq;
/* currect send window size */
Gauge ce_swnd;
/* currenct receive window size */
Gauge ce_rwnd;
/* current max segment size */
Gauge ce_mss;
} sctpConnEntryInfo;
} mib2_sctpConnEntry_t;
typedef struct mib2_sctpConnLocalAddrEntry {
/* connection identifier */
uint32_t sctpAssocId;
/* type of local addr { sctpAssocLocalEntry 1 } */
int sctpAssocLocalAddrType;
/* local address { sctpAssocLocalEntry 2 } */
Ip6Address sctpAssocLocalAddr;
} mib2_sctpConnLocalEntry_t;
typedef struct mib2_sctpConnRemoteAddrEntry {
/* connection identier */
uint32_t sctpAssocId;
/* remote addr type { sctpAssocRemEntry 1 } */
int sctpAssocRemAddrType;
/* remote address { sctpAssocRemEntry 2 } */
Ip6Address sctpAssocRemAddr;
/* is the address active { sctpAssocRemEntry 3 } */
int sctpAssocRemAddrActive;
/* whether hearbeat is active { sctpAssocRemEntry 4 } */
int sctpAssocRemAddrHBActive;
/* current RTO { sctpAssocRemEntry 5 } */
uint32_t sctpAssocRemAddrRTO;
/* max # of rexmits before becoming inactive */
uint32_t sctpAssocRemAddrMaxPathRtx; /* {sctpAssocRemEntry 6} */
/* # of rexmits to this dest { sctpAssocRemEntry 7 } */
uint32_t sctpAssocRemAddrRtx;
} mib2_sctpConnRemoteEntry_t;
/* Pack data in mib2_sctp to make struct size the same for 32- and 64-bits */
#if _LONG_LONG_ALIGNMENT == 8 && _LONG_LONG_ALIGNMENT_32 == 4
#pragma pack(4)
#endif
typedef struct mib2_sctp {
/* algorithm used to determine rto { sctpParams 1 } */
int sctpRtoAlgorithm;
/* min RTO in msecs { sctpParams 2 } */
uint32_t sctpRtoMin;
/* max RTO in msecs { sctpParams 3 } */
uint32_t sctpRtoMax;
/* initial RTO in msecs { sctpParams 4 } */
uint32_t sctpRtoInitial;
/* max # of assocs { sctpParams 5 } */
int32_t sctpMaxAssocs;
/* cookie lifetime in msecs { sctpParams 6 } */
uint32_t sctpValCookieLife;
/* max # of retrans in startup { sctpParams 7 } */
uint32_t sctpMaxInitRetr;
/* # of conns ESTABLISHED, SHUTDOWN-RECEIVED or SHUTDOWN-PENDING */
Counter32 sctpCurrEstab; /* { sctpStats 1 } */
/* # of active opens { sctpStats 2 } */
Counter32 sctpActiveEstab;
/* # of passive opens { sctpStats 3 } */
Counter32 sctpPassiveEstab;
/* # of aborted conns { sctpStats 4 } */
Counter32 sctpAborted;
/* # of graceful shutdowns { sctpStats 5 } */
Counter32 sctpShutdowns;
/* # of OOB packets { sctpStats 6 } */
Counter32 sctpOutOfBlue;
/* # of packets discarded due to cksum { sctpStats 7 } */
Counter32 sctpChecksumError;
/* # of control chunks sent { sctpStats 8 } */
Counter64 sctpOutCtrlChunks;
/* # of ordered data chunks sent { sctpStats 9 } */
Counter64 sctpOutOrderChunks;
/* # of unordered data chunks sent { sctpStats 10 } */
Counter64 sctpOutUnorderChunks;
/* # of retransmitted data chunks */
Counter64 sctpRetransChunks;
/* # of SACK chunks sent */
Counter sctpOutAck;
/* # of delayed ACK timeouts */
Counter sctpOutAckDelayed;
/* # of SACK chunks sent to update window */
Counter sctpOutWinUpdate;
/* # of fast retransmits */
Counter sctpOutFastRetrans;
/* # of window probes sent */
Counter sctpOutWinProbe;
/* # of control chunks received { sctpStats 11 } */
Counter64 sctpInCtrlChunks;
/* # of ordered data chunks rcvd { sctpStats 12 } */
Counter64 sctpInOrderChunks;
/* # of unord data chunks rcvd { sctpStats 13 } */
Counter64 sctpInUnorderChunks;
/* # of received SACK chunks */
Counter sctpInAck;
/* # of received SACK chunks with duplicate TSN */
Counter sctpInDupAck;
/* # of SACK chunks acking unsent data */
Counter sctpInAckUnsent;
/* # of Fragmented User Messages { sctpStats 14 } */
Counter64 sctpFragUsrMsgs;
/* # of Reassembled User Messages { sctpStats 15 } */
Counter64 sctpReasmUsrMsgs;
/* # of Sent SCTP Packets { sctpStats 16 } */
Counter64 sctpOutSCTPPkts;
/* # of Received SCTP Packets { sctpStats 17 } */
Counter64 sctpInSCTPPkts;
/* # of invalid cookies received */
Counter sctpInInvalidCookie;
/* total # of retransmit timeouts */
Counter sctpTimRetrans;
/* total # of retransmit timeouts dropping the connection */
Counter sctpTimRetransDrop;
/* total # of heartbeat probes */
Counter sctpTimHeartBeatProbe;
/* total # of heartbeat timeouts dropping the connection */
Counter sctpTimHeartBeatDrop;
/* total # of conns refused due to backlog full on listen */
Counter sctpListenDrop;
/* total # of pkts received after the association has closed */
Counter sctpInClosed;
int sctpEntrySize;
int sctpLocalEntrySize;
int sctpRemoteEntrySize;
} mib2_sctp_t;
#if _LONG_LONG_ALIGNMENT == 8 && _LONG_LONG_ALIGNMENT_32 == 4
#pragma pack()
#endif
#ifdef __cplusplus
}
#endif
#endif /* _INET_MIB2_H */