Wellfleet-MODULE-MIB device MIB details by Wellfleet
Wellfleet-MODULE-MIB file content
The SNMP protocol is used to for conveying information and commands between agents and managing entities. SNMP uses the User Datagram Protocol (UDP) as the transport protocol for passing data between managers and agents. The reasons for using UDP for SNMP are, firstly it has low overheads in comparison to TCP, which uses a 3-way hand shake for connection. Secondly, in congested networks, SNMP over TCP is a bad idea because TCP in order to maintain reliability will flood the network with retransmissions.
Management information (MIB) is represented as a collection of managed objects. These objects together form a virtual information base called MIB. An agent may implement many MIBs, but all agents must implement a particular MIB called MIB-II [16]. This standard defines variables for things such as interface statistics (interface speeds, MTU, octets sent, octets received, etc.) as well as various other things pertaining to the system itself (system location, system contact, etc.). The main goal of MIB-II is to provide general TCP/IP management information.
Use ActiveXperts Network Monitor 2024 to import vendor-specific MIB files, inclusing Wellfleet-MODULE-MIB.
Vendor: | Wellfleet |
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Mib: | Wellfleet-MODULE-MIB [download] [view objects] |
Tool: | ActiveXperts Network Monitor 2024 [download] (ships with advanced SNMP/MIB tools) |
Wellfleet-MODULE-MIB DEFINITIONS ::= BEGIN -- Created by mdl2asn version 3.1 -- Creation date: Wed Aug 30 16:45:27 EDT 1995 IMPORTS OBJECT-TYPE FROM RFC-1212 DisplayString FROM RFC1213-MIB wfHwModuleGroup FROM Wellfleet-COMMON-MIB; wfHwModuleTable OBJECT-TYPE SYNTAX SEQUENCE OF WfHwModuleEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Hardware Module Table Filled in by the Module Driver. Read by SNMP to build the driver load records " ::= { wfHwModuleGroup 1 } wfHwModuleEntry OBJECT-TYPE SYNTAX WfHwModuleEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Hardware specific information about a slot." INDEX { wfHwModuleSlot, wfHwModuleModule } ::= { wfHwModuleTable 1 } WfHwModuleEntry ::= SEQUENCE { wfHwModuleSlot INTEGER, wfHwModuleModule INTEGER, wfHwModuleModIdOpt INTEGER, wfHwModuleModRev OCTET STRING, wfHwModuleModSerialNumber OCTET STRING, wfHwModuleArtworkRev DisplayString, wfHwModuleMemorySize1 INTEGER, wfHwModuleMemorySize2 INTEGER, wfHwModuleDaughterBdIdOpt INTEGER, wfHwModuleLEDStatus1 INTEGER, wfHwModuleLEDState1 INTEGER, wfHwModuleLEDStatus2 INTEGER, wfHwModuleLEDState2 INTEGER, wfHwModuleLEDStatus3 INTEGER, wfHwModuleLEDState3 INTEGER } wfHwModuleSlot OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "A unique value for each slot. Its value ranges between 1 and 4." ::= { wfHwModuleEntry 1 } wfHwModuleModule OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "This value ranges between 1 and 4" ::= { wfHwModuleEntry 2 } wfHwModuleModIdOpt OBJECT-TYPE SYNTAX INTEGER { spex(512), spexhss(768), spexhsd(769), denm(1280), denmhwf(1281), iqe(1408), dsnmnn(1536), dsnmn1(1537), dsnmn2(1538), dsnm1n(1540), dsnm11(1541), dsnm12(1542), dsnm2n(1544), dsnm21(1545), dsnm22(1546), dsnmnnisdn(1584), dsnmn1isdn(1585), dsnmn2isdn(1586), dsnm1nisdn(1588), dsnm11isdn(1589), dsnm12isdn(1590), dsnm2nisdn(1592), dsnm21isdn(1593), dsnm22isdn(1594), qsyncnm(1664), mmfsdsas(1792), mmfsddas(1793), smfsdsas(1800), smfsddas(1801), mmscsas(1808), mmscdas(1809), smammbdas(1825), mmasmbdas(1833), mmfsdsashwf(1856), mmfsddashwf(1857), smfsdsashwf(1864), smfsddashwf(1865), mmscsashwf(1872), mmscdashwf(1873), smammbdashwf(1889), mmasmbdashwf(1897), dtnm(2048), cam(2049), iqtok(2176), se100nm(2304), asnqbri(2560), mce1nm(2816), dmct1nm(2944), hwcompnm32(3072), hwcompnm128(3073), ahwcompnm32(3328), ahwcompnm128(3329), ahwcompnm256(3330), shssinm(3584), arnmbstr(8704), arnmbsen(8720), arnmbsfetx(8728), arnmbsfefx(8729), arnssync(8736), arnv34(8752), arndcsu(8768), arnft1(8776), arnfe1(8780), arnisdns(8784), arnisdnu(8800), arnisdb(8808), arnstkrg(8816), arnsenet(8832), arntsync(8848), arnentsync(8864), arne7sync(8872), arn7sync(8873), arnpbe7sx10(8972), arntrtsync(8880), arnmbenx10(8896), arnmbtrx10(8912), arnpbenx10(8928), arnpbtrx10(8944), arnpbtenx10(8960), arnpbttrx10(8976), snm10t16(16384), snm100t2(16640), snmatmoc31mm(16896), snmatmoc31dmm(16897), snmatmoc31sm(16898), snmatmoc31dsm(16899), snmfddismm(17152), snmfddisms(17153), snmfddissm(17154), snmfddisss(17155), snm10f8(17408), snm100f2(17664), snm10t16p4(17920), snm100t2p4(18176), snm10t14100t1(18432), snm100t16(18688), snm10t14100f1(18944), atm5000ah(524288), atm5000bh(524544) } ACCESS read-only STATUS mandatory DESCRIPTION "Module IDs for the net modules modules" ::= { wfHwModuleEntry 3 } wfHwModuleModRev OBJECT-TYPE SYNTAX OCTET STRING ACCESS read-only STATUS mandatory DESCRIPTION "The revision level of the module. High byte is in upper 2 bytes." ::= { wfHwModuleEntry 4 } wfHwModuleModSerialNumber OBJECT-TYPE SYNTAX OCTET STRING ACCESS read-only STATUS mandatory DESCRIPTION "The serial number of the module." ::= { wfHwModuleEntry 5 } wfHwModuleArtworkRev OBJECT-TYPE SYNTAX DisplayString ACCESS read-only STATUS mandatory DESCRIPTION "The Artwork Revision number of the module" ::= { wfHwModuleEntry 6 } wfHwModuleMemorySize1 OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Size (in bytes) of memory #1." ::= { wfHwModuleEntry 7 } wfHwModuleMemorySize2 OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Size (in bytes) of memory #2." ::= { wfHwModuleEntry 8 } wfHwModuleDaughterBdIdOpt OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Daughterboard IDs that may be attached to net modules" ::= { wfHwModuleEntry 9 } wfHwModuleLEDStatus1 OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Bit mask representing the status of the LEDs on the module. Each LED is represented by 2 bits. LED #1 status is indicated by the 2 least significant bits. LED #16 status is indicated by the 2 most significant bits. How this bit mask is interpreted depends on the module ID. For example, some modules use this value to report what color the LED is currently set to ('00' off, '01' yellow, '10' green). This value can be used by a NMS that needs to know this information for whatever reason. Some modules may not support this value in which case it should be set to zero." ::= { wfHwModuleEntry 10 } wfHwModuleLEDState1 OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Bit mask representing the state of the LEDs on the module. Each LED is represented by 2 bits. LED #1 state is indicated by the 2 least significant bits. LED #16 state is indicated by the 2 most significant bits. How this bit mask is interpreted depends on the module ID. For example, some modules use this value to indicate a LED is flashing (value of '01') or a solid color (value of '00'). This value can be used by a NMS that needs to know this information for whatever reason. Some modules may not support this value in which case it should be set to zero." ::= { wfHwModuleEntry 11 } wfHwModuleLEDStatus2 OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Bit mask representing the status of the LEDs on the module. Each LED is represented by 2 bits. LED #17 status is indicated by the 2 least significant bits. LED #32 status is indicated by the 2 most significant bits. How this bit mask is interpreted depends on the module ID. For example, some modules use this value to report what color the LED is currently set to ('00' off, '01' yellow, '10' green). This value can be used by a NMS that needs to know this information for whatever reason. Some modules may not support this value in which case it should be set to zero." ::= { wfHwModuleEntry 12 } wfHwModuleLEDState2 OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Bit mask representing the state of the LEDs on the module. Each LED is represented by 2 bits. LED #17 state is indicated by the 2 least significant bits. LED #32 state is indicated by the 2 most significant bits. How this bit mask is interpreted depends on the module ID. For example, some modules use this value to indicate a LED is flashing (value of '01') or a solid color (value of '00'). This value can be used by a NMS that needs to know this information for whatever reason. Some modules may not support this value in which case it should be set to zero." ::= { wfHwModuleEntry 13 } wfHwModuleLEDStatus3 OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Bit mask representing the status of the LEDs on the module. Each LED is represented by 2 bits. LED #33 status is indicated by the 2 least significant bits. LED #48 status is indicated by the 2 most significant bits. How this bit mask is interpreted depends on the module ID. For example, some modules use this value to report what color the LED is currently set to ('00' off, '01' yellow, '10' green). This value can be used by a NMS that needs to know this information for whatever reason. Some modules may not support this value in which case it should be set to zero." ::= { wfHwModuleEntry 14 } wfHwModuleLEDState3 OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "Bit mask representing the state of the LEDs on the module. Each LED is represented by 2 bits. LED #33 state is indicated by the 2 least significant bits. LED #48 state is indicated by the 2 most significant bits. How this bit mask is interpreted depends on the module ID. For example, some modules use this value to indicate a LED is flashing (value of '01') or a solid color (value of '00'). This value can be used by a NMS that needs to know this information for whatever reason. Some modules may not support this value in which case it should be set to zero." ::= { wfHwModuleEntry 15 } wfModuleTable OBJECT-TYPE SYNTAX SEQUENCE OF WfModuleEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "This table is used by the module driver for Barracuda" ::= { wfHwModuleGroup 2 } wfModuleEntry OBJECT-TYPE SYNTAX WfModuleEntry ACCESS not-accessible STATUS mandatory DESCRIPTION "Hardware specific information about a slot." INDEX { wfModuleSlot } ::= { wfModuleTable 1 } WfModuleEntry ::= SEQUENCE { wfModuleDelete INTEGER, wfModuleSlot INTEGER, wfModuleTimerFrequency INTEGER, wfModuleBufferBalance INTEGER, wfModuleFddiWeight INTEGER, wfModuleTokenRingWeight INTEGER, wfModuleCsmacdWeight INTEGER, wfModuleSyncWeight INTEGER, wfModuleFreeBufferCredits INTEGER, wfModuleTotalBufferCredits INTEGER, wfModuleRestart INTEGER, wfModuleCsmacd100Weight INTEGER, wfModuleBisyncWeight INTEGER , wfModuleHssiWeight INTEGER } wfModuleDelete OBJECT-TYPE SYNTAX INTEGER { created(1), deleted(2) } ACCESS read-write STATUS mandatory DESCRIPTION "create/delete parameter" DEFVAL { created } ::= { wfModuleEntry 1 } wfModuleSlot OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "A unique value for each slot. Its value ranges between 1 and 14. There are products in this family that contain 1, 5, and 14 slots." ::= { wfModuleEntry 2 } wfModuleTimerFrequency OBJECT-TYPE SYNTAX INTEGER { timerdefault(1) } ACCESS read-write STATUS mandatory DESCRIPTION "This value determines the frequency for the buffer balance algorithm to run" DEFVAL { timerdefault } ::= { wfModuleEntry 3 } wfModuleBufferBalance OBJECT-TYPE SYNTAX INTEGER { txrx(1), none(2), rx(3), tx(4) } ACCESS read-write STATUS mandatory DESCRIPTION "Enable/Disable buffer balancing algorithm selectively" DEFVAL { txrx } ::= { wfModuleEntry 4 } wfModuleFddiWeight OBJECT-TYPE SYNTAX INTEGER(1..10) ACCESS read-write STATUS mandatory DESCRIPTION "This value determines the weight of the fddi line for the buffer balancing algorithm" DEFVAL { 6 } ::= { wfModuleEntry 5 } wfModuleTokenRingWeight OBJECT-TYPE SYNTAX INTEGER(1..10) ACCESS read-write STATUS mandatory DESCRIPTION "This value determines the weight of the token-ring for the buffer balancing algorithm" DEFVAL { 4 } ::= { wfModuleEntry 6 } wfModuleCsmacdWeight OBJECT-TYPE SYNTAX INTEGER(1..10) ACCESS read-write STATUS mandatory DESCRIPTION "This value determines the weight of the csmacd line for the buffer balancing algorithm" DEFVAL { 3 } ::= { wfModuleEntry 7 } wfModuleSyncWeight OBJECT-TYPE SYNTAX INTEGER(1..10) ACCESS read-write STATUS mandatory DESCRIPTION "This value determines the weight of the sync line for the buffer balancing algorithm" DEFVAL { 2 } ::= { wfModuleEntry 8 } wfModuleFreeBufferCredits OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "This attribute indicates the number of buffers available to line drivers but not used by them" ::= { wfModuleEntry 9 } wfModuleTotalBufferCredits OBJECT-TYPE SYNTAX INTEGER ACCESS read-only STATUS mandatory DESCRIPTION "This attribute indicates the total number of buffers available to line drivers" ::= { wfModuleEntry 10 } wfModuleRestart OBJECT-TYPE SYNTAX INTEGER ACCESS read-write STATUS mandatory DESCRIPTION "This attribute should be touched after the queue lengths are configured in the line-records" ::= { wfModuleEntry 11 } wfModuleCsmacd100Weight OBJECT-TYPE SYNTAX INTEGER(1..10) ACCESS read-write STATUS mandatory DESCRIPTION "This value determines the weight of the csmacd 100MB line for the buffer balancing algorithm" DEFVAL { 6 } ::= { wfModuleEntry 12 } wfModuleBisyncWeight OBJECT-TYPE SYNTAX INTEGER(1..10) ACCESS read-write STATUS mandatory DESCRIPTION "This value determines the weight of the bisync line for the buffer balancing algorithm" DEFVAL { 2 } ::= { wfModuleEntry 13 } wfModuleHssiWeight OBJECT-TYPE SYNTAX INTEGER(1..10) ACCESS read-write STATUS mandatory DESCRIPTION "This value determines the weight of the hssi line for the buffer balancing algorithm" DEFVAL { 2 } ::= { wfModuleEntry 14 } END -- Wellfleet-MODULE-MIB