API References

Dealing with many SNMP features may quickly overwhelm developers who aim at a quick and trivial task, PySNMP employs a layered architecture approach where the topmost programming API tries to be as simple as possible to allow immediate solutions for most common use cases.

It will let you perform SNMP GET/SET/WALK and TRAP/INFORM operations by pasting code snippets from PySNMP documentation and sample scripts right into your Python interactive session.

Most of SNMP operations involve packet exchange over network. PySNMP is shipped with asyncio binding that let you run PySNMP in parallel with other tasks your application may perform.

High-level v3arch sync

Most simple and straightforward way to use PySNMP is by employing its Synchronous, blocking API. It used to be the default API to offer on pysnmp.hlapi sub-package import. However, it is now deprecated and removed.

Warning

First deprecated in PySNMP 6.0, and completely removed in PySNMP 6.2.

High-level v3arch asyncio

The asyncio module first appeared in standard library since Python 3.3 (in provisional basis). Its main design feature is that it makes asynchronous code looking like synchronous one, especially after the introduction of async/await pattern. That greatly simplifies development and maintenance.

Command Generator

Notification Originator

Transport Configuration

The following shortcut classes convey configuration information to SNMP engine’s Local Configuration Datastore (RFC 2271#section-3.4.2) as well as to underlying socket API. Once committed to LCD, SNMP engine saves its configuration for the lifetime of SNMP engine object.

class pysnmp.hlapi.v3arch.asyncio.UdpTransportTarget(timeout: float = 1, retries: int = 5, tagList=b'')

Represent UDP/IPv6 transport endpoint.

This object can be used for adding new entries to Local Configuration Datastore (LCD) managed by SnmpEngine class instance.

See RFC 1906#section-3 for more information on the UDP transport mapping.

Parameters:
  • transportAddr (tuple) – Indicates remote address in Python socket module format which is a tuple of FQDN, port where FQDN is a string representing either hostname or IPv4 address in quad-dotted form, port is an integer.

  • timeout (int) – Response timeout in seconds.

  • retries (int) – Maximum number of request retries, 0 retries means just a single request.

  • tagList (str) – Arbitrary string that contains a list of tag values which are used to select target addresses for a particular operation (RFC 3413#section-4.1.4).

Examples

>>> from pysnmp.hlapi.v3arch.asyncio import UdpTransportTarget
>>> await UdpTransportTarget.create(('demo.pysnmp.com', 161))
UdpTransportTarget(('195.218.195.228', 161), timeout=1, retries=5, tagList='')
>>>
class pysnmp.hlapi.v3arch.asyncio.Udp6TransportTarget(timeout: float = 1, retries: int = 5, tagList=b'')

Creates UDP/IPv6 configuration entry and initialize socket API if needed.

This object can be used by AsyncCommandGenerator or AsyncNotificationOriginator and their derivatives for adding new entries to Local Configuration Datastore (LCD) managed by SnmpEngine class instance.

See RFC 1906#section-3, RFC 2851#section-4 for more information on the UDP and IPv6 transport mapping.

Parameters:
  • transportAddr (tuple) – Indicates remote address in Python socket module format which is a tuple of FQDN, port where FQDN is a string representing either hostname or IPv6 address in one of three conventional forms (RFC 1924#section-3), port is an integer.

  • timeout (int) – Response timeout in seconds.

  • retries (int) – Maximum number of request retries, 0 retries means just a single request.

  • tagList (str) – Arbitrary string that contains a list of tag values which are used to select target addresses for a particular operation (RFC 3413#section-4.1.4).

Examples

>>> from pysnmp.hlapi.v3arch.asyncio import Udp6TransportTarget
>>> await Udp6TransportTarget.create(('google.com', 161))
Udp6TransportTarget(('2a00:1450:4014:80a::100e', 161), timeout=1, retries=5, tagList='')
>>> await Udp6TransportTarget.create(('FEDC:BA98:7654:3210:FEDC:BA98:7654:3210', 161))
Udp6TransportTarget(('fedc:ba98:7654:3210:fedc:ba98:7654:3210', 161), timeout=1, retries=5, tagList='')
>>> await Udp6TransportTarget.create(('1080:0:0:0:8:800:200C:417A', 161))
Udp6TransportTarget(('1080::8:800:200c:417a', 161), timeout=1, retries=5, tagList='')
>>> await Udp6TransportTarget.create(('::0', 161))
Udp6TransportTarget(('::', 161), timeout=1, retries=5, tagList='')
>>> await Udp6TransportTarget.create(('::', 161))
Udp6TransportTarget(('::', 161), timeout=1, retries=5, tagList='')
>>>

High-level v3arch SNMP Engine

SNMP Engine is a central, stateful object used by all SNMP v3 subsystems. Calls to high-level Applications API also consume SNMP Engine object on input.

class pysnmp.hlapi.v3arch.asyncio.SnmpEngine(snmpEngineID=None)

Creates SNMP engine object.

SNMP engine object is central in SNMP v3 architecture. It is an umbrella object that coordinates interactions between all parts of SNMP v3 system. See RFC 3412#section-2.1 (where it is termed The Dispatcher).

With PySNMP design, SnmpEngine is the only stateful object, all SNMP v3 operations require an instance of SNMP engine. Users do not normally request services directly from SnmpEngine, but pass it around to other PySNMP interfaces.

It is possible to run multiple instances of SnmpEngine in the application. In a multithreaded environment, each thread that works with SNMP must have its own SnmpEngine instance.

Parameters:

snmpEngineID (OctetString) – Unique and unambiguous identifier of an SNMP engine. If not given, snmpEngineID is autogenerated and stored on the filesystem. See RFC 3411#section-3.1.1 for details.

Examples

>>> SnmpEngine()
SnmpEngine(snmpEngineID=OctetString(hexValue='0x80004fb80567726f6d6d69742'))
>>>

Create an SNMP engine object.

High-level v3arch auth

Calls to high-level Applications API consume Security Parameters configuration object on input. The shortcut classes described in this section convey configuration information to SNMP engine’s Local Configuration Datastore (RFC 2271#section-3.4.2). Once committed to LCD, SNMP engine saves its configuration for the lifetime of SNMP engine object.

Community-Based

Security Parameters object is Security Model specific. The CommunityData class is used for configuring Community-Based Security Model of SNMPv1/SNMPv2c.

class pysnmp.hlapi.v3arch.asyncio.CommunityData(communityIndex, communityName=None, mpModel=1, contextEngineId=None, contextName='', tag='')

Creates SNMP v1/v2c configuration entry.

This object can be used by AsyncCommandGenerator or AsyncNotificationOriginator and their derivatives for adding new entries to Local Configuration Datastore (LCD) managed by SnmpEngine class instance.

See RFC 2576#section-5.3 for more information on the SNMP-COMMUNITY-MIB::snmpCommunityTable.

Parameters:
  • communityIndex (str, OctetString) – Unique index value of a row in snmpCommunityTable. If it is the only positional parameter, it is treated as a communityName.

  • communityName (str, OctetString) – SNMP v1/v2c community string.

  • mpModel (int) – SNMP message processing model AKA SNMP version. Known SNMP versions are:

    • 0 - for SNMP v1

    • 1 - for SNMP v2c (default)

contextEngineId: str, OctetString

Indicates the location of the context in which management information is accessed when using the community string specified by the above communityName.

contextName: str, OctetString

The context in which management information is accessed when using the above communityName.

tag: str

Arbitrary string that specifies a set of transport endpoints from which a command responder application will accept management requests with given communityName or to which notification originator application will send notifications when targets are specified by a tag value(s).

The other way to look at the tag feature is that it can make specific communityName only valid for certain targets.

The other use-case is when multiple distinct SNMP peers share the same communityName – binding each instance of communityName to transport endpoint lets you distinguish SNMP peers from each other (e.g. resolving communityName into proper securityName).

For more technical information on SNMP configuration tags please refer to RFC 3413#section-4.1.1 and RFC 2576#section-5.3 (e.g. the snmpCommunityTransportTag object).

See also: UdpTransportTarget

Warning

If the same communityIndex value is supplied repeatedly with different communityName (or other parameters), the later call supersedes all previous calls.

Make sure not to configure duplicate communityName values unless they have distinct mpModel and/or tag fields. This will make communityName based database lookup ambiguous.

Examples

>>> from pysnmp.hlapi.v3arch.asyncio import CommunityData
>>> CommunityData('public')
CommunityData(communityIndex='s1410706889', communityName=<COMMUNITY>, mpModel=1, contextEngineId=None, contextName='', tag='')
>>> CommunityData('public', 'public')
CommunityData(communityIndex='public', communityName=<COMMUNITY>, mpModel=1, contextEngineId=None, contextName='', tag='')
>>>

Create a community data object.

User-Based

The UsmUserData class provides SNMPv3 User-Based Security Model configuration for SNMP v3 systems.

class pysnmp.hlapi.v3arch.asyncio.UsmUserData(userName, authKey=None, privKey=None, authProtocol=usmNoAuthProtocol, privProtocol=usmNoPrivProtocol, securityEngineId=None, authKeyType=usmKeyTypePassphrase, privKeyType=usmKeyTypePassphrase)

Creates SNMP v3 User Security Model (USM) configuration entry.

This object can be used by AsyncCommandGenerator or AsyncNotificationOriginator and their derivatives for adding new entries to Local Configuration Datastore (LCD) managed by SnmpEngine class instance.

See RFC 3414#section-5 for more information on the SNMP-USER-BASED-SM-MIB::usmUserTable.

Parameters:

userName (str, OctetString) – A human readable string representing the name of the SNMP USM user.

Other Parameters:
securityEngineId: OctetString

The snmpEngineID of the authoritative SNMP engine to which a dateRequest message is to be sent. Will be automatically discovered from peer if not given, unless localized keys are used. In the latter case securityEngineId must be specified.

See RFC 3414#section-2.5.1 for technical explanation.

securityName: str, OctetString

Together with the snmpEngineID it identifies a row in the SNMP-USER-BASED-SM-MIB::usmUserTable that is to be used for securing the message.

See RFC 3414#section-2.5.1 for technical explanation.

privProtocol: tuple, ObjectIdentifier

An indication of whether messages sent on behalf of this USM user be encrypted, and if so, the type of encryption protocol which is used.

Supported encryption protocol identifiers are:

authKeyType: int

Type of authKey material. See RFC 3414#section-2.6 for technical explanation.

Supported key types are:

privKeyType: int

Type of privKey material. See RFC 3414#section-2.6 for technical explanation.

Supported key types are:

Notes

If USM_KEY_TYPE_LOCALIZED is used when running a non-authoritative SNMP engine, USM key localization mechanism is not invoked. As a consequence, local SNMP engine configuration won’t get automatically populated with remote SNMP engine’s securityEngineId.

Therefore peer SNMP engine’s securityEngineId must be added to local configuration and associated with its localized keys.

Alternatively, the magic securityEngineId value of five zeros (0x0000000000) can be used to refer to the localized keys that should be used with any unknown remote SNMP engine. This feature is specific to pysnmp.

Examples

>>> from pysnmp.hlapi.v3arch.asyncio import UsmUserData
>>> UsmUserData('testuser', authKey='authenticationkey')
UsmUserData(userName='testuser', authKey=<AUTHKEY>, privKey=<PRIVKEY>, authProtocol=(1,3,6,1,6,3,10,1,1,2), privProtocol=(1,3,6,1,6,3,10,1,2,1))
>>> UsmUserData('testuser', authKey='authenticationkey', privKey='encryptionkey')
UsmUserData(userName='testuser', authKey=<AUTHKEY>, privKey=<PRIVKEY>, authProtocol=(1,3,6,1,6,3,10,1,1,2), privProtocol=(1,3,6,1,6,3,10,1,2,2))
>>>

Create a USM user data object.

Authentication protocol identifiers

pysnmp.hlapi.v3arch.asyncio.USM_AUTH_NONE = (1, 3, 6, 1, 6, 3, 10, 1, 1, 1)

No Authentication Protocol

pysnmp.hlapi.v3arch.asyncio.USM_AUTH_HMAC96_MD5 = (1, 3, 6, 1, 6, 3, 10, 1, 1, 2)

The HMAC-MD5-96 Digest Authentication Protocol (RFC 3414#section-6)

pysnmp.hlapi.v3arch.asyncio.USM_AUTH_HMAC96_SHA = (1, 3, 6, 1, 6, 3, 10, 1, 1, 3)

The HMAC-SHA-96 Digest Authentication Protocol AKA SHA-1 (RFC 3414#section-7)

pysnmp.hlapi.v3arch.asyncio.USM_AUTH_HMAC128_SHA224 = (1, 3, 6, 1, 6, 3, 10, 1, 1, 4)

The HMAC-SHA-2 Digest Authentication Protocols (RFC 7860)

pysnmp.hlapi.v3arch.asyncio.USM_AUTH_HMAC192_SHA256 = (1, 3, 6, 1, 6, 3, 10, 1, 1, 5)

The HMAC-SHA-2 Digest Authentication Protocols (RFC 7860)

pysnmp.hlapi.v3arch.asyncio.USM_AUTH_HMAC256_SHA384 = (1, 3, 6, 1, 6, 3, 10, 1, 1, 6)

The HMAC-SHA-2 Digest Authentication Protocols (RFC 7860)

pysnmp.hlapi.v3arch.asyncio.USM_AUTH_HMAC384_SHA512 = (1, 3, 6, 1, 6, 3, 10, 1, 1, 7)

The HMAC-SHA-2 Digest Authentication Protocols (RFC 7860)

Privacy (encryption) protocol identifiers

pysnmp.hlapi.v3arch.asyncio.USM_PRIV_NONE = (1, 3, 6, 1, 6, 3, 10, 1, 2, 1)

No Privacy Protocol

pysnmp.hlapi.v3arch.asyncio.USM_PRIV_CBC56_DES = (1, 3, 6, 1, 6, 3, 10, 1, 2, 2)

The CBC-DES Symmetric Encryption Protocol (RFC 3414#section-8)

pysnmp.hlapi.v3arch.asyncio.USM_PRIV_CBC168_3DES = (1, 3, 6, 1, 6, 3, 10, 1, 2, 3)

The 3DES-EDE Symmetric Encryption Protocol (draft-reeder-snmpv3-usm-3desede-00)

pysnmp.hlapi.v3arch.asyncio.USM_PRIV_CFB128_AES = (1, 3, 6, 1, 6, 3, 10, 1, 2, 4)

The CFB128-AES-128 Symmetric Encryption Protocol (RFC 3826#section-3)

pysnmp.hlapi.v3arch.asyncio.USM_PRIV_CFB192_AES = (1, 3, 6, 1, 4, 1, 9, 12, 6, 1, 101)

The CFB128-AES-192 Symmetric Encryption Protocol (draft-blumenthal-aes-usm-04) with Reeder key localization. Also known as AES-192-Cisco

pysnmp.hlapi.v3arch.asyncio.USM_PRIV_CFB256_AES = (1, 3, 6, 1, 4, 1, 9, 12, 6, 1, 102)

The CFB128-AES-256 Symmetric Encryption Protocol (draft-blumenthal-aes-usm-04) with Reeder key localization. Also also known as AES-256-Cisco

pysnmp.hlapi.v3arch.asyncio.USM_PRIV_CFB192_AES_BLUMENTHAL = (1, 3, 6, 1, 4, 1, 9, 12, 6, 1, 1)

The CFB128-AES-192 Symmetric Encryption Protocol (draft-blumenthal-aes-usm-04)

pysnmp.hlapi.v3arch.asyncio.USM_PRIV_CFB256_AES_BLUMENTHAL = (1, 3, 6, 1, 4, 1, 9, 12, 6, 1, 2)

The CFB128-AES-256 Symmetric Encryption Protocol (draft-blumenthal-aes-usm-04)

Key material types

pysnmp.hlapi.v3arch.asyncio.USM_KEY_TYPE_PASSPHRASE = 0

USM key material type - plain-text pass phrase (RFC 3414#section-2.6)

pysnmp.hlapi.v3arch.asyncio.USM_KEY_TYPE_MASTER = 1

USM key material type - hashed pass-phrase AKA master key (RFC 3414#section-2.6)

pysnmp.hlapi.v3arch.asyncio.USM_KEY_TYPE_LOCALIZED = 2

USM key material type - hashed pass-phrase hashed with Context SNMP Engine ID (RFC 3414#section-2.6)

Note

SNMP authentication and encryption keys must be at least 8 and at most 32 octets long.

Transport configuration is I/O framework specific and is described in respective sections.

High-level v3arch SNMP Context

SNMP engine may serve several instances of the same MIB within possibly multiple SNMP entities. SNMP context is a tool for unambiguously identifying a collection of MIB variables behind the SNMP engine. See RFC 3411#section-3.3.1 for details.

Note

The SNMP context information is not tied to SNMPv3/USM user, but it is transferred in SNMPv3 message header.

Legacy SNMPv1/v2c protocols do not accommodate the SNMP context information at all.

To fit legacy SNMPv1/SNMPv2c systems into unified SNMPv3 architecture, the mapping procedure is introduced by RFC 2576#section-5.1 which essentially lets you first configure and then supply the missing items (e.g. contextName, contextEngineId and other) to the upper layers of SNMP stack based on SNMPv1/v2c communityName and transport endpoint.

The SNMP context information necessary for this mapping procedure to operate is supplied through the CommunityData object.

class pysnmp.hlapi.v3arch.asyncio.ContextData(contextEngineId=None, contextName=b'')

Creates UDP/IPv6 configuration entry and initialize socket API if needed.

This object can be used by AsyncCommandGenerator or AsyncNotificationOriginator and their derivatives for forming SNMP PDU and also adding new entries to Local Configuration Datastore (LCD) in order to support SNMPv1/v2c with SNMPv3 interoperability.

See RFC 3411#section-4.1 for SNMP Context details.

Parameters:
  • contextEngineId (str) – Uniquely identifies an SNMP entity that may realize an instance of a MIB with a particular contextName (RFC 3411#section-3.3.2). More frequently than not, ContextEngineID is the same as authoritative SnmpEngineID, however if SNMP Engine serves multiple SNMP Entities, their ContextEngineIDs would be distinct. Default is authoritative SNMP Engine ID.

  • contextName (str) – Used to name an instance of MIB (RFC 3411#section-3.3.3). Default is empty string.

Examples

>>> from pysnmp.hlapi.v3arch.asyncio import ContextData
>>> ContextData()
ContextData(contextEngineId=None, contextName='')
>>> ContextData(OctetString(hexValue='01020ABBA0'))
ContextData(contextEngineId=OctetString(hexValue='01020abba0'), contextName='')
>>> ContextData(contextName='mycontext')
ContextData(contextEngineId=None, contextName='mycontext')

Create a context data object.

High-level v1arch asyncio

The asyncio module is in Python standard library since ancient times. Main loop is built around select dispatcher, user code is invoked through callback callables.

Different from v3arch asyncio, v1arch asyncio API aims to avoid the complexity of the v3arch asyncio API, and to provide a simpler and more straightforward API for users who only need to perform SNMP v1 and v2c operations.

Command Generator

Notification Originator

Transport configuration

class pysnmp.hlapi.v1arch.asyncio.UdpTransportTarget(timeout: float = 1, retries: int = 5, tagList=b'')

Represent UDP/IPv4 transport endpoint.

This object can be used for passing UDP/IPv4 configuration information to the AsyncCommandGenerator and AsyncNotificationOriginator objects scheduled on I/O by SnmpDispatcher class instance.

See RFC 1906#section-3 for more information on the UDP transport mapping.

Parameters:
  • transportAddr (tuple) – Indicates remote address in Python socket module format which is a tuple of FQDN, port where FQDN is a string representing either hostname or IPv4 address in quad-dotted form, port is an integer.

  • timeout (int) – Response timeout in seconds.

  • retries (int) – Maximum number of request retries, 0 retries means just a single request.

  • tagList (str) – Arbitrary string that contains a list of tag values which are used to select target addresses for a particular operation (RFC 3413#section-4.1.4).

Examples

>>> from pysnmp.hlapi.v1arch.asyncio import UdpTransportTarget
>>> await UdpTransportTarget.create(('demo.pysnmp.com', 161))
UdpTransportTarget(('195.218.195.228', 161), timeout=1, retries=5)
>>>
class pysnmp.hlapi.v1arch.asyncio.Udp6TransportTarget(timeout: float = 1, retries: int = 5, tagList=b'')

Represent UDP/IPv6 transport endpoint.

This object can be used for passing UDP/IPv6 configuration information to the AsyncCommandGenerator and AsyncNotificationOriginator objects scheduled on I/O by SnmpDispatcher class instance.

See RFC 1906#section-3, RFC 2851#section-4 for more information on the UDP and IPv6 transport mapping.

Parameters:
  • transportAddr (tuple) – Indicates remote address in Python socket module format which is a tuple of FQDN, port where FQDN is a string representing either hostname or IPv6 address in one of three conventional forms (RFC 1924#section-3), port is an integer.

  • timeout (int) – Response timeout in seconds.

  • retries (int) – Maximum number of request retries, 0 retries means just a single request.

  • tagList (str) – Arbitrary string that contains a list of tag values which are used to select target addresses for a particular operation (RFC 3413#section-4.1.4).

Examples

>>> from pysnmp.hlapi.v1arch.asyncio import Udp6TransportTarget
>>> await Udp6TransportTarget.create(('google.com', 161))
Udp6TransportTarget(('2a00:1450:4014:80a::100e', 161), timeout=1, retries=5, tagList='')
>>> await Udp6TransportTarget.create(('FEDC:BA98:7654:3210:FEDC:BA98:7654:3210', 161))
Udp6TransportTarget(('fedc:ba98:7654:3210:fedc:ba98:7654:3210', 161), timeout=1, retries=5, tagList='')
>>> await Udp6TransportTarget.create(('1080:0:0:0:8:800:200C:417A', 161))
Udp6TransportTarget(('1080::8:800:200c:417a', 161), timeout=1, retries=5, tagList='')
>>> await Udp6TransportTarget.create(('::0', 161))
Udp6TransportTarget(('::', 161), timeout=1, retries=5, tagList='')
>>> await Udp6TransportTarget.create(('::', 161))
Udp6TransportTarget(('::', 161), timeout=1, retries=5, tagList='')
>>>

High-level v1arch SNMP Dispatcher

SNMP Dispatcher is a stateful object representing asynchronous I/O event loop and also holding some caches. Calls to v1arch always require consume SNMP Dispatcher object on input.

class pysnmp.hlapi.v1arch.SnmpDispatcher

Creates SNMP message dispatcher object.

SnmpDispatcher object manages send and receives SNMP PDU messages through underlying transport dispatcher and dispatches them to the callers.

SnmpDispatcher is the only stateful object, all hlapi.v1arch SNMP operations require an instance of SnmpDispatcher. Users do not normally request services directly from SnmpDispather, but pass it around to other hlapi.v1arch interfaces.

It is possible to run multiple instances of SnmpDispatcher in the application. In a multithreaded environment, each thread that works with SNMP must have its own SnmpDispatcher instance.

High-level v1arch auth

Calls to v1arch API require SNMP authentication object on input.

Community-based

Security Parameters object is Security Model specific. The CommunityData class is used for configuring Community-Based Security Model of SNMPv1/SNMPv2c.

class pysnmp.hlapi.v1arch.CommunityData(communityName, mpModel=1)

Creates SNMP v1/v2c configuration entry.

This object can be used by AsyncCommandGenerator or AsyncNotificationOriginator and their derivatives for conveying SNMP v1/v2c configuration.

Parameters:
  • communityName (py:class:str) – SNMP v1/v2c community string.

  • mpModel (py:class:int) – SNMP version - 0 for SNMPv1 and 1 for SNMPv2c.

Examples

>>> from pysnmp.hlapi.v1arch import CommunityData
>>> CommunityData('public')
CommunityData(communityName=<COMMUNITY>, mpModel=1)

Create a community data instance.

MIB Services

MIB Variables

SNMP MIB variable is identified by an OBJECT IDENTIFIER (OID) and is accompanied by a value belonging to one of SNMP types (RFC 1902#section-2). This pair is collectively called a variable-binding in SNMP parlance.

The rfc1902 module implements RFC 1902#section-2 MACRO definitions.

class pysnmp.smi.rfc1902.ObjectIdentity(*args, **kwargs)

Create an object representing MIB variable ID.

At the protocol level, MIB variable is only identified by an OID. However, when interacting with humans, MIB variable can also be referred to by its MIB name. The ObjectIdentity class supports various forms of MIB variable identification, providing automatic conversion from one to others. At the same time ObjectIdentity objects behave like tuples of py:obj:int sub-OIDs.

See RFC 1902#section-2 for more information on OBJECT-IDENTITY SMI definitions.

Parameters:

args – initial MIB variable identity. Recognized variants:

  • single tuple or integers representing OID

  • single str representing OID in dot-separated integers form

  • single str representing MIB variable in dot-separated labels form

  • single str representing MIB name. First variable defined in MIB is assumed.

  • pair of str representing MIB name and variable name

  • pair of str representing MIB name and variable name followed by an arbitrary number of str and/or int values representing MIB variable instance identification.

Other Parameters:

kwargs – MIB resolution options(object):

  • whenever only MIB name is given, resolve into last variable defined in MIB if last=True. Otherwise resolves to first variable (default).

Notes

Actual conversion between MIB variable representation formats occurs upon resolve_with_mib() invocation.

Examples

>>> from pysnmp.smi.rfc1902 import ObjectIdentity
>>> ObjectIdentity((1, 3, 6, 1, 2, 1, 1, 1, 0))
ObjectIdentity((1, 3, 6, 1, 2, 1, 1, 1, 0))
>>> ObjectIdentity('1.3.6.1.2.1.1.1.0')
ObjectIdentity('1.3.6.1.2.1.1.1.0')
>>> ObjectIdentity('iso.org.dod.internet.mgmt.mib-2.system.sysDescr.0')
ObjectIdentity('iso.org.dod.internet.mgmt.mib-2.system.sysDescr.0')
>>> ObjectIdentity('SNMPv2-MIB', 'system')
ObjectIdentity('SNMPv2-MIB', 'system')
>>> ObjectIdentity('SNMPv2-MIB', 'sysDescr', 0)
ObjectIdentity('SNMPv2-MIB', 'sysDescr', 0)
>>> ObjectIdentity('IP-MIB', 'ipAdEntAddr', '127.0.0.1', 123)
ObjectIdentity('IP-MIB', 'ipAdEntAddr', '127.0.0.1', 123)

Create an ObjectIdentity instance.

get_mib_symbol()

Returns MIB variable symbolic identification.

Returns:

  • str – MIB module name

  • str – MIB variable symbolic name

  • ObjectName – class instance representing MIB variable instance index.

Raises:

SmiError – If MIB variable conversion has not been performed.

Examples

>>> objectIdentity = ObjectIdentity('1.3.6.1.2.1.1.1.0')
>>> objectIdentity.resolve_with_mib(mibViewController)
>>> objectIdentity.get_mib_symbol()
('SNMPv2-MIB', 'sysDescr', (0,))
>>>
get_oid()

Returns OID identifying MIB variable.

Returns:

ObjectName – full OID identifying MIB variable including possible index part.

Raises:

SmiError – If MIB variable conversion has not been performed.

Examples

>>> objectIdentity = ObjectIdentity('SNMPv2-MIB', 'sysDescr', 0)
>>> objectIdentity.resolve_with_mib(mibViewController)
>>> objectIdentity.get_oid()
ObjectName('1.3.6.1.2.1.1.1.0')
>>>
get_label() tuple[str, ...]

Returns symbolic path to this MIB variable.

Meaning a sequence of symbolic identifications for each of parent MIB objects in MIB tree.

Returns:

tuple – sequence of names of nodes in a MIB tree from the top of the tree towards this MIB variable.

Raises:

SmiError – If MIB variable conversion has not been performed.

Notes

Returned sequence may not contain full path to this MIB variable if some symbols are now known at the moment of MIB look up.

Examples

>>> objectIdentity = ObjectIdentity('SNMPv2-MIB', 'sysDescr', 0)
>>> objectIdentity.resolve_with_mib(mibViewController)
>>> objectIdentity.get_oid()
('iso', 'org', 'dod', 'internet', 'mgmt', 'mib-2', 'system', 'sysDescr')
>>>
get_mib_node() MibNode

Returns MIB node object representing this MIB variable.

Returns:

ObjectType – class instance representing MIB variable.

Raises:

SmiError – If MIB variable conversion has not been performed.

is_fully_resolved()

Returns True if MIB variable conversion has been performed.

Returns:

boolTrue if MIB variable conversion has been performed.

Examples

>>> objectIdentity = ObjectIdentity('SNMPv2-MIB', 'sysDescr', 0)
>>> objectIdentity.is_fully_resolved()
False
>>> objectIdentity.resolve_with_mib(mibViewController)
>>> objectIdentity.is_fully_resolved()
True
>>>
add_asn1_mib_source(*asn1Sources, **kwargs)

Adds path to a repository to search ASN.1 MIB files.

Parameters:

asn1Sources – one or more URL in form of str identifying local or remote ASN.1 MIB repositories. Path must include the @mib@ component which will be replaced with MIB module name at the time of search.

Returns:

ObjectIdentity – reference to itself

Notes

Please refer to HttpReader classes for in-depth information on ASN.1 MIB lookup.

Examples

>>> ObjectIdentity('SNMPv2-MIB', 'sysDescr').add_asn1_mib_source('https://mibs.pysnmp.com/asn1/@mib@')
ObjectIdentity('SNMPv2-MIB', 'sysDescr')
>>>
add_mib_source(*mibSources)

Adds path to repository to search PySNMP MIB files.

Parameters:

mibSources – one or more paths to search or Python package names to import and search for PySNMP MIB modules.

Returns:

ObjectIdentity – reference to itself

Notes

Normally, ASN.1-to-Python MIB modules conversion is performed automatically through PySNMP/PySMI interaction. ASN1 MIB modules could also be manually compiled into Python via the mibdump.py tool.

Examples

>>> ObjectIdentity('SNMPv2-MIB', 'sysDescr').add_mib_source('/opt/pysnmp/mibs', 'pysnmp_mibs')
ObjectIdentity('SNMPv2-MIB', 'sysDescr')
>>>
load_mibs(*modNames)

Schedules search and load of given MIB modules.

Parameters:

modNames – one or more MIB module names to load up and use for MIB variables resolution purposes.

Returns:

ObjectIdentity – reference to itself

Examples

>>> ObjectIdentity('SNMPv2-MIB', 'sysDescr').load_mibs('IF-MIB', 'TCP-MIB')
ObjectIdentity('SNMPv2-MIB', 'sysDescr')
>>>
resolve_with_mib(mibViewController: MibViewController, ignoreErrors=True)

Perform MIB variable ID conversion.

Parameters:

mibViewController (MibViewController) – class instance representing MIB browsing functionality.

Other Parameters:

ignoreErrors (bool) – If True (default), ignore MIB object name casting failures if possible.

Returns:

ObjectIdentity – reference to itself

Raises:

SmiError – In case of fatal MIB handling error

Notes

Calling this method might cause the following sequence of events (exact details depends on many factors):

  • ASN.1 MIB file downloaded and handed over to MibCompiler for conversion into Python MIB module (based on pysnmp classes)

  • Python MIB module is imported by SNMP engine, internal indices created

  • MibViewController looks up the rest of MIB identification information based on whatever information is already available, ObjectIdentity class instance gets updated and ready for further use.

Examples

>>> objectIdentity = ObjectIdentity('SNMPv2-MIB', 'sysDescr')
>>> objectIdentity.resolve_with_mib(mibViewController)
ObjectIdentity('SNMPv2-MIB', 'sysDescr')
>>>
prettyPrint()

Return a human-friendly representation of the object.

__repr__()

Return a string representation of the object.

__str__()

Return a string representation of the object.

__eq__(other)

Compare OID with another OID.

__ne__(other)

Compare OID with another OID.

__lt__(other)

Compare OID with another OID.

__le__(other)

Compare OID with another OID.

__gt__(other)

Compare OID with another OID.

__ge__(other)

Compare OID with another OID.

__nonzero__()

Return True if the OID is not empty.

__bool__()

Return True if the OID is not empty.

__getitem__(i)

Return the i-th element of the OID.

__len__()

Return the length of the OID.

__add__(other)

Add OID to the right of the other object.

__radd__(other)

Add OID to the left of the other object.

__hash__()

Return a hash value of the object.

__getattr__(attr)

Redirect some attributes.

class pysnmp.smi.rfc1902.ObjectType(objectIdentity, objectSyntax: ~pyasn1.type.base.SimpleAsn1Type = <Null value object, tagSet <TagSet object, tags 0:0:5>, subtypeSpec <ConstraintsIntersection object, consts <SingleValueConstraint object, consts b''>>, encoding iso-8859-1, payload []>)

Create an object representing MIB variable.

Instances of ObjectType class are containers incorporating ObjectIdentity class instance (identifying MIB variable) and optional value belonging to one of SNMP types (RFC 1902).

Typical MIB variable is defined like this (from SNMPv2-MIB.txt):

sysDescr OBJECT-TYPE
    SYNTAX      DisplayString (SIZE (0..255))
    MAX-ACCESS  read-only
    STATUS      current
    DESCRIPTION
            "A textual description of the entity.  This value should..."
    ::= { system 1 }

Corresponding ObjectType instantiation would look like this:

ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr'), 'Linux i386 box')

In order to behave like SNMP variable-binding (RFC 1157#section-4.1.1), ObjectType objects also support sequence protocol addressing objectIdentity as its 0-th element and objectSyntax as 1-st.

See RFC 1902#section-2 for more information on OBJECT-TYPE SMI definitions.

Parameters:
  • objectIdentity (ObjectIdentity) – Class instance representing MIB variable identification.

  • objectSyntax – Represents a value associated with this MIB variable. Values of built-in Python types will be automatically converted into SNMP object as specified in OBJECT-TYPE->SYNTAX field.

Notes

Actual conversion between MIB variable representation formats occurs upon resolve_with_mib() invocation.

Examples

>>> from pysnmp.smi.rfc1902 import *
>>> ObjectType(ObjectIdentity('1.3.6.1.2.1.1.1.0'))
ObjectType(ObjectIdentity('1.3.6.1.2.1.1.1.0'), Null(''))
>>> ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr', 0), 'Linux i386')
ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr', 0), 'Linux i386')

Create an ObjectType instance.

__getitem__(i)

Return the i-th element of the ObjectType.

__str__()

Return a string representation of the object.

__repr__()

Return a string representation of the object.

is_fully_resolved()

Returns True if MIB variable conversion has been performed.

Returns:

boolTrue if MIB variable conversion has been performed.

add_asn1_mib_source(*asn1Sources, **kwargs)

Adds path to a repository to search ASN.1 MIB files.

Parameters:

asn1Sources – one or more URL in form of str identifying local or remote ASN.1 MIB repositories. Path must include the @mib@ component which will be replaced with MIB module name at the time of search.

Returns:

ObjectType – reference to itself

Notes

Please refer to FileReader and HttpReader classes for in-depth information on ASN.1 MIB lookup.

Examples

>>> ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr')).add_asn1_mib_source('https://mibs.pysnmp.com/asn1/@mib@')
ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr'))
>>>
add_mib_source(*mibSources)

Adds path to repository to search PySNMP MIB files.

Parameters:

mibSources – one or more paths to search or Python package names to import and search for PySNMP MIB modules.

Returns:

ObjectType – reference to itself

Notes

Normally, ASN.1-to-Python MIB modules conversion is performed automatically through PySNMP/PySMI interaction. ASN1 MIB modules could also be manually compiled into Python via the mibdump.py tool.

Examples

>>> ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr')).add_mib_source('/opt/pysnmp/mibs', 'pysnmp_mibs')
ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr'))
>>>
load_mibs(*modNames)

Schedules search and load of given MIB modules.

Parameters:

modNames – one or more MIB module names to load up and use for MIB variables resolution purposes.

Returns:

ObjectType – reference to itself

Examples

>>> ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr')).load_mibs('IF-MIB', 'TCP-MIB')
ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr'))
>>>
resolve_with_mib(mibViewController: MibViewController, ignoreErrors=True) ObjectType

Perform MIB variable ID and associated value conversion.

Parameters:

mibViewController (MibViewController) – class instance representing MIB browsing functionality.

Other Parameters:

ignoreErrors (bool) – If True (default), ignore MIB object name or value casting failures if possible.

Returns:

ObjectType – reference to itself

Raises:

SmiError – In case of fatal MIB handling error

Notes

Calling this method involves resolve_with_mib() method invocation.

Examples

>>> from pysmi.hlapi.v3arch.asyncio import varbinds
>>> mibViewController = varbinds.MibViewControllerManager.get_mib_view_controller(engine.cache)
>>> objectType = ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr'), 'Linux i386')
>>> objectType.resolve_with_mib(mibViewController)
ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr'), DisplayString('Linux i386'))
>>> str(objectType)
'SNMPv2-MIB::sysDescr."0" = Linux i386'
>>>
prettyPrint()

Return a human-friendly representation of the object.

__getattr__(attr)

Redirect some attrs access to the OID object to behave alike.

MIB Notification Types

SNMP Notifications are enumerated and imply including certain set of MIB variables. Notification Originator applications refer to MIBs for MIB notifications through NOTIFICATION-TYPE ASN.1 macro. It conveys a set of MIB variables to be gathered and reported in SNMP Notification. The rfc1902 module implements RFC 1902#section-2 macro definitions.

class pysnmp.smi.rfc1902.NotificationType(objectIdentity: ObjectIdentity, instanceIndex=(), objects={})

Create an object representing SNMP Notification.

Instances of NotificationType class are containers incorporating ObjectIdentity class instance (identifying particular notification) and a collection of MIB variables IDs that NotificationOriginator should gather and put into notification message.

Typical notification is defined like this (from IF-MIB.txt):

linkDown NOTIFICATION-TYPE
    OBJECTS { ifIndex, ifAdminStatus, ifOperStatus }
    STATUS  current
    DESCRIPTION
           "A linkDown trap signifies that the SNMP entity..."
    ::= { snmpTraps 3 }

Corresponding NotificationType instantiation would look like this:

NotificationType(ObjectIdentity('IF-MIB', 'linkDown'))

To retain similarity with SNMP variable-bindings, NotificationType objects behave like a sequence of ObjectType class instances.

See RFC 1902#section-2 for more information on NOTIFICATION-TYPE SMI definitions.

Parameters:
  • objectIdentity (ObjectIdentity) – Class instance representing MIB notification type identification.

  • instanceIndex (ObjectName) – Trailing part of MIB variables OID identification that represents concrete instance of a MIB variable. When notification is prepared, instanceIndex is appended to each MIB variable identification listed in NOTIFICATION-TYPE->OBJECTS clause.

  • objects (dict) – Dictionary-like object that may return values by OID key. The objects dictionary is consulted when notification is being prepared. OIDs are taken from MIB variables listed in NOTIFICATION-TYPE->OBJECTS with instanceIndex part appended.

Notes

Actual notification type and MIB variables look up occurs upon resolve_with_mib() invocation.

Examples

>>> from pysnmp.smi.rfc1902 import *
>>> NotificationType(ObjectIdentity('1.3.6.1.6.3.1.1.5.3'))
NotificationType(ObjectIdentity('1.3.6.1.6.3.1.1.5.3'), (), {})
>>> NotificationType(ObjectIdentity('IP-MIB', 'linkDown'), ObjectName('3.5'))
NotificationType(ObjectIdentity('1.3.6.1.6.3.1.1.5.3'), ObjectName('3.5'), {})

Create a NotificationType instance.

__getitem__(i)

Return the i-th element of the NotificationType.

__repr__()

Return a string representation of the object.

add_varbinds(*varBinds)

Appends variable-binding to notification.

Parameters:

varBinds (ObjectType) – One or more ObjectType class instances.

Returns:

NotificationType – reference to itself

Notes

This method can be used to add custom variable-bindings to notification message in addition to MIB variables specified in NOTIFICATION-TYPE->OBJECTS clause.

Examples

>>> nt = NotificationType(ObjectIdentity('IP-MIB', 'linkDown'))
>>> nt.add_varbinds(ObjectType(ObjectIdentity('SNMPv2-MIB', 'sysDescr', 0)))
NotificationType(ObjectIdentity('IP-MIB', 'linkDown'), (), {})
>>>
add_asn1_mib_source(*asn1Sources, **kwargs)

Adds path to a repository to search ASN.1 MIB files.

Parameters:

asn1Sources – one or more URL in form of str identifying local or remote ASN.1 MIB repositories. Path must include the @mib@ component which will be replaced with MIB module name at the time of search.

Returns:

NotificationType – reference to itself

Notes

Please refer to FileReader and HttpReader classes for in-depth information on ASN.1 MIB lookup.

Examples

>>> NotificationType(ObjectIdentity('IF-MIB', 'linkDown'), (), {}).add_asn1_mib_source('https://mibs.pysnmp.com/asn1/@mib@')
NotificationType(ObjectIdentity('IF-MIB', 'linkDown'), (), {})
>>>
add_mib_source(*mibSources)

Adds path to repository to search PySNMP MIB files.

Parameters:

mibSources – one or more paths to search or Python package names to import and search for PySNMP MIB modules.

Returns:

NotificationType – reference to itself

Notes

Normally, ASN.1-to-Python MIB modules conversion is performed automatically through PySNMP/PySMI interaction. ASN1 MIB modules could also be manually compiled into Python via the mibdump.py tool.

Examples

>>> NotificationType(ObjectIdentity('IF-MIB', 'linkDown'), (), {}).add_mib_source('/opt/pysnmp/mibs', 'pysnmp_mibs')
NotificationType(ObjectIdentity('IF-MIB', 'linkDown'), (), {})
>>>
load_mibs(*modNames)

Schedules search and load of given MIB modules.

Parameters:

modNames – one or more MIB module names to load up and use for MIB variables resolution purposes.

Returns:

NotificationType – reference to itself

Examples

>>> NotificationType(ObjectIdentity('IF-MIB', 'linkDown'), (), {}).load_mibs('IF-MIB', 'TCP-MIB')
NotificationType(ObjectIdentity('IF-MIB', 'linkDown'), (), {})
>>>
is_fully_resolved()

Return if the object is fully resolved.

resolve_with_mib(mibViewController: MibViewController, ignoreErrors=True) NotificationType

Perform MIB variable ID conversion and notification objects expansion.

Parameters:

mibViewController (MibViewController) – class instance representing MIB browsing functionality.

Other Parameters:

ignoreErrors (bool) – If True (default), ignore MIB object name or value casting failures if possible.

Returns:

NotificationType – reference to itself

Raises:

SmiError – In case of fatal MIB handling error

Notes

Calling this method might cause the following sequence of events (exact details depends on many factors):

  • pysnmp.smi.rfc1902.ObjectIdentity.resolve_with_mib() is called

  • MIB variables names are read from NOTIFICATION-TYPE->OBJECTS clause, ObjectType instances are created from MIB variable OID and indexInstance suffix.

  • objects dictionary is queried for each MIB variable OID, acquired values are added to corresponding MIB variable

Examples

>>> notificationType = NotificationType(ObjectIdentity('IF-MIB', 'linkDown'))
>>> notificationType.resolve_with_mib(mibViewController)
NotificationType(ObjectIdentity('IF-MIB', 'linkDown'), (), {})
>>>
prettyPrint()

Return a human-friendly representation of the object.

to_varbinds() tuple[ObjectType, ...]

Return a sequence of MIB variables.

__getattr__(attr: str)

Handle deprecated attributes.

SNMP Base Types

SNMP represents real-world objects it serves along with their states in form of values. Those values each belong to one of SNMP types (RFC 1902#section-2) which, in turn, are based on ASN.1 data description language. PySNMP types are derived from PyASN1 implementation.

Null Type

class pysnmp.proto.rfc1902.Null(initializer)

Creates an instance of SNMP Null class.

Null type represents the absence of value.

Parameters:

initializer (str) – Python string object. Must be an empty string.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> Null('')
Null('')
>>>

Note

The NULL type actually belongs to the base ASN.1 types. It is not defined in RFC 1902#section-2 as an SNMP type. The Null type is exposed through rfc1902 module just for convenience.

Integer32 Type

class pysnmp.proto.rfc1902.Integer32(initializer)

Creates an instance of SNMP Integer32 class.

Integer32 type represents integer-valued information between -2147483648 to 2147483647 inclusive (RFC 1902#section-7.1.1). This type is indistinguishable from the Integer type. The Integer32 type may be sub-typed to be more constrained than the base Integer32 type.

Parameters:

initializer (int) – Python integer in range between -2147483648 to 2147483647 inclusive or Integer32.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> Integer32(1234)
Integer32(1234)
>>> Integer32(1) > 2
True
>>> Integer32(1) + 1
Integer32(2)
>>> int(Integer32(321))
321
>>> SmallInteger = Integer32.with_range(1,3)
>>> SmallInteger(1)
Integer32(1)
>>> DiscreetInteger = Integer32.with_values(4, 8, 1)
>>> DiscreetInteger(4)
Integer32(4)
>>>
subtypeSpec = <ConstraintsIntersection object, consts <ValueRangeConstraint object, consts -2147483648, 2147483647>>

Set (on class, not on instance) or return a ConstraintsIntersection object imposing constraints on |ASN.1| type initialization values.

classmethod with_values(*values)

Creates a subclass with discreet values constraint.

classmethod with_range(minimum, maximum)

Creates a subclass with value range constraint.

Integer Type

class pysnmp.proto.rfc1902.Integer(initializer)

Creates an instance of SNMP INTEGER class.

The Integer type represents integer-valued information as named-number enumerations (RFC 1902#section-7.1.1). This type inherits and is indistinguishable from Integer32 class. The Integer type may be sub-typed to be more constrained than the base Integer type.

Parameters:

initializer (int) – Python integer in range between -2147483648 to 2147483647 inclusive or Integer class instance. In case of named-numbered enumerations, initialization is also possible by enumerated literal.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> Integer(1234)
Integer(1234)
>>> Integer(1) > 2
True
>>> Integer(1) + 1
Integer(2)
>>> int(Integer(321))
321
>>> SomeState = Integer.with_named_values(enable=1, disable=0)
>>> SomeState(1)
Integer('enable')
>>> int(SomeState('disable'))
0
>>>
classmethod with_named_values(**values)

Create a subclass with discreet named values constraint.

Reduce fully duplicate enumerations along the way.

OctetString Type

class pysnmp.proto.rfc1902.OctetString(strValue=None, hexValue=None)

Creates an instance of SNMP OCTET STRING class.

The OctetString type represents arbitrary binary or text data (RFC 1902#section-7.1.2). It may be sub-typed to be constrained in size.

Parameters:

strValue (str) – Python string or OctetString class instance.

Other Parameters:

hexValue (str) – Python string representing octets in a hexadecimal notation (e.g. DEADBEEF).

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> OctetString('some apples')
OctetString('some apples')
>>> OctetString('some apples') + ' and oranges'
OctetString('some apples and oranges')
>>> str(OctetString('some apples'))
'some apples'
>>> SomeString = OctetString.with_size(3, 12)
>>> str(SomeString(hexValue='deadbeef'))
'\xde\xad\xbe\xef'
>>>
subtypeSpec = <ConstraintsIntersection object, consts <ValueSizeConstraint object, consts 0, 65535>>

Set (on class, not on instance) or return a ConstraintsIntersection object imposing constraints on |ASN.1| type initialization values.

set_fixed_length(value)

Set fixed length.

is_fixed_length()

Return if fixed length.

get_fixed_length()

Return fixed length.

clone(*args, **kwargs)

Clone the data.

subtype(*args, **kwargs)

Subtype the data.

classmethod with_size(minimum, maximum)

Creates a subclass with value size constraint.

__getattr__(attr: str)

Handle deprecated attributes.

IpAddress Type

class pysnmp.proto.rfc1902.IpAddress(strValue=None, hexValue=None)

Creates an instance of SNMP IpAddress class.

The IpAddress class represents a 32-bit internet address as an OCTET STRING of length 4, in network byte-order (RFC 1902#section-7.1.5).

Parameters:

strValue (str) – The same as OctetString, additionally IPv4 address in dotted notation (‘127.0.0.1’).

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> IpAddress('127.0.0.1')
IpAddress(hexValue='7f000001')
>>> str(IpAddress(hexValue='7f000001'))
'\x7f\x00\x00\x01'
>>> IpAddress('\x7f\x00\x00\x01')
IpAddress(hexValue='7f000001')
>>>

ObjectIdentifier Type

class pysnmp.proto.rfc1902.ObjectIdentifier(initializer)

Creates an instance of SNMP OBJECT IDENTIFIER class.

The ObjectIdentifier type represents administratively assigned names (RFC 1902#section-7.1.3). Supports sequence protocol where elements are integer sub-identifiers.

Parameters:

initializer (tuple, str) – Python tuple of up to 128 integers in range between 0 to 4294967295 inclusive or Python string containing OID in “dotted” form or ObjectIdentifier.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> ObjectIdentifier((1, 3, 6))
ObjectIdentifier('1.3.6')
>>> ObjectIdentifier('1.3.6')
ObjectIdentifier('1.3.6')
>>> tuple(ObjectIdentifier('1.3.6'))
(1, 3, 6)
>>> str(ObjectIdentifier('1.3.6'))
'1.3.6'
>>>

Counter32 Type

class pysnmp.proto.rfc1902.Counter32(initializer)

Creates an instance of SNMP Counter32 class.

Counter32 type represents a non-negative integer which monotonically increases until it reaches a maximum value of 4294967295, when it wraps around and starts increasing again from zero (RFC 1902#section-7.1.6).

Parameters:

initializer (int) – Python integer in range between 0 to 4294967295 inclusive or any Integer-based class.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> Counter32(1234)
Counter32(1234)
>>> Counter32(1) + 1
Counter32(2)
>>> int(Counter32(321))
321
>>>

Gauge32 Type

class pysnmp.proto.rfc1902.Gauge32(initializer)

Creates an instance of SNMP Gauge32 class.

Gauge32 type represents a non-negative integer, which may increase or decrease, but shall never exceed a maximum value. The maximum value can not be greater than 4294967295 (RFC 1902#section-7.1.7).

Parameters:

initializer (int) – Python integer in range between 0 to 4294967295 inclusive or any Integer-based class.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> Gauge32(1234)
Gauge32(1234)
>>> Gauge32(1) + 1
Gauge32(2)
>>> int(Gauge32(321))
321
>>>

Unsigned32 Type

class pysnmp.proto.rfc1902.Unsigned32(initializer)

Creates an instance of SNMP Unsigned32 class.

Unsigned32 type represents integer-valued information between 0 and 4294967295 (RFC 1902#section-7.1.11).

Parameters:

initializer (int) – Python integer in range between 0 to 4294967295 inclusive or any Integer-based class.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> Unsigned32(1234)
Unsigned32(1234)
>>> Unsigned32(1) + 1
Unsigned32(2)
>>> int(Unsigned32(321))
321
>>>

TimeTicks Type

class pysnmp.proto.rfc1902.TimeTicks(initializer)

Creates an instance of SNMP TimeTicks class.

TimeTicks type represents a non-negative integer which represents the time, modulo 4294967296, in hundredths of a second between two epochs (RFC 1902#section-7.1.8).

Parameters:

initializer (int) – Python integer in range between 0 to 4294967295 inclusive or any Integer-based class.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> TimeTicks(1234)
TimeTicks(1234)
>>> TimeTicks(1) + 1
TimeTicks(2)
>>> int(TimeTicks(321))
321
>>>

Opaque Type

class pysnmp.proto.rfc1902.Opaque(initializer)

Creates an instance of SNMP Opaque class.

The Opaque type supports the capability to pass arbitrary ASN.1 syntax. A value is encoded using the ASN.1 BER into a string of octets. This, in turn, is encoded as an OCTET STRING, in effect “double-wrapping” the original ASN.1 value (RFC 1902#section-7.1.9).

Parameters:

strValue (str) – Python string or OctetString-based class instance.

Other Parameters:

hexValue (str) – Python string representing octets in a hexadecimal notation (e.g. DEADBEEF).

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> Opaque('some apples')
Opaque('some apples')
>>> Opaque('some apples') + ' and oranges'
Opaque('some apples and oranges')
>>> str(Opaque('some apples'))
'some apples'
>>> str(Opaque(hexValue='deadbeef'))
'\xde\xad\xbe\xef'
>>>

Counter64 Type

class pysnmp.proto.rfc1902.Counter64(initializer)

Creates an instance of SNMP Counter64 class.

Counter64 type represents a non-negative integer which monotonically increases until it reaches a maximum value of 18446744073709551615, when it wraps around and starts increasing again from zero (RFC 1902#section-7.1.10).

Parameters:

initializer (int) – Python integer in range between 0 to 4294967295 inclusive or any Integer-based class.

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> Counter64(1234)
Counter64(1234)
>>> Counter64(1) + 1
Counter64(2)
>>> int(Counter64(321))
321
>>>

Bits Type

class pysnmp.proto.rfc1902.Bits(initializer)

Creates an instance of SNMP BITS class.

The Bits type represents an enumeration of named bits. This collection is assigned non-negative, contiguous values, starting at zero. Only those named-bits so enumerated may be present in a value (RFC 1902#section-7.1.4).

The bits are named and identified by their position in the octet string. Position zero is the high order (or left-most) bit in the first octet of the string. Position 7 is the low order (or right-most) bit of the first octet of the string. Position 8 is the high order bit in the second octet of the string, and so on (BITS Pseudotype).

Parameters:

strValue (str, tuple) – Sequence of bit names or a Python string (as a raw data) or OctetString class instance.

Other Parameters:

hexValue (str) – Python string representing octets in a hexadecimal notation (e.g. DEADBEEF).

Raises:

PyAsn1Error : – On constraint violation or bad initializer.

Examples

>>> from pysnmp.proto.rfc1902 import *
>>> SomeBits = Bits.with_named_bits(apple=0, orange=1, peach=2)
>>> SomeBits(('apple', 'orange')).prettyPrint()
'apple, orange'
>>> SomeBits(('apple', 'orange'))
Bits(hexValue='c0')
>>> SomeBits('\x80')
Bits(hexValue='80')
>>> SomeBits(hexValue='80')
Bits(hexValue='80')
>>> SomeBits(hexValue='80').prettyPrint()
'apple'
>>>

Create a new instance of the class.

static __new__(cls, *args, **kwargs)

Create a new instance of the class.

prettyIn(bits)

Return raw bitstring.

prettyOut(value)

Return named bits.

classmethod with_named_bits(**values)

Creates a subclass with discreet named bits constraint.

Reduce fully duplicate enumerations along the way.