MIB implementation#
SNMP Command Responder is designed to interface with user data source and serve it on the network as SNMP agent(s).
The primary way of interfacing user data source with SNMP Command Responder involves two steps:
Using the pysmi project to compile ASN.1 MIB(s) into stubs of Python code
Interfacing the desired objects with the intended data sources by adding custom Pythob code into the hooks
Example workflow#
Let’s step through the MIB object implementaton workflow using the SNMPv2-MIB::sysName.0 managed object as an example.
Compile MIB into Python#
The MIB compiler and code generator shipped with the pysmi project is driven by the Jjinja2 templates to produce the desired code. User can use the default templates or extend them to adapt to their needs.
One of the templates pysmi ships can generate MIB instrumentation stubs for managed objects instances i.e. the leaf MIB objects representing the instances of MIB scalars of tabular objects.
We can just call the mibdump tool passing it the above mentioned template:
$ mibdump.py --no-dependencies \
--destination-directory /etc/snmpresponder/managed-objects \
--destination-format pysnmp \
--destination-template pysnmp/mib-instrumentation/managed-objects-instances.j2 \
SNMPv2-MIB
Warning
Once the compilation is done, make sure to rename produced MIB file into a name which is different from MIB module name (SNMPv2-MIB) which is reserved for MIB definitions, not MIB implementation. For example it could be __SNMPv2-MIB.py or SNMPv2-MIB::sysName.py.
Add glue code#
The produced Python stubs expose the extension points in the MIB managed objects read, write, create and destroy workflows. On top of that, each of these operations is performed on each SNMP request variable-binding in isolation from the other variable-bindings and in a transactional “all or nothing” manner.
For sake of simplicity, let’s focus solely on read operation performed in response to SNMP GET/GETNEXT and GETBULK commands.
class SysnameObjectInstance(MibScalarInstance):
"""Scalar Managed Object Instance with MIB instrumentation hooks.
User can override none, some or all of the method below interfacing
them to the data source they want to manage through SNMP.
Non-overridden methods could just be removed from this class.
See the SMI data model documentation at `https://www.pysnmp.com/pysnmp`.
"""
def readTest(self, varBind, **context):
# Put your code here
MibScalarInstance.readTest(self, varBind, **context)
def readGet(self, varBind, **context):
# Put your code here
MibScalarInstance.readGet(self, varBind, **context)
def readTestNext(self, varBind, **context):
# Put your code here
MibScalarInstance.readTestNext(self, varBind, **context)
def readGetNext(self, varBind, **context):
# Put your code here
MibScalarInstance.readGetNext(self, varBind, **context)
Note
In the above stubs, readTest and readGet methods are invoked on SNMP GET commands, while readTestNext and readGetNext are called on SNMP GETNEXT/GETBULK requests.
To obtain the value to serve the SNMPv2-MIB::sysName.0 MIB object we could simply call gethostbyname() from Python:
>>> import socket
>>>
>>> socket.gethostname()
'igarlic'
>>>
The MIB object API is asynchronous by design, the results should be delivered via a callback function.
class SysnameObjectInstance(MibScalarInstance):
def readTest(self, varBind, **context):
# Just confirm that this MIB object instance is available
cbFun = context['cbFun']
cbFun(varBind, **context)
def readGet(self, varBind, **context):
cbFun = context['cbFun']
name, value = varBind
# Initialize response value from *gethostname()* return
value = self.syntax.clone(socket.gethostname())
cbFun((name, value), **context)
def readTestNext(self, varBind, **context):
name, value = varBind
if name >= self.name:
# This object does not qualify as "next*, pass the call
MibScalarInstance.readTestNext(self, varBind, **context)
else:
# Confirm this object is available and report its OID
cbFun = context['cbFun']
cbFun((self.name, value), **context)
def readGetNext(self, varBind, **context):
name, value = varBind
if name >= self.name:
# This object does not qualify as "next*, pass the call
MibScalarInstance.readGetNext(self, varBind, **context)
else:
cbFun = context['cbFun']
# Initialize response value from *gethostname()* return
value = self.syntax.clone(socket.gethostname())
cbFun((self.name, value), **context)
Note
MIB objects being implemented must be able to run asynchronously, that is they should never block on long-pending operations.
Finally, instantiate and export the newly defined MIB object instance:
_sysName = SysnameObjectInstance(
sysName.name,
(0,),
sysName.syntax
)
# Export Managed Objects Instances to the MIB builder
mibBuilder.exportSymbols(
"__SNMPv2-MIB",
**{"sysName": _sysName}
)
Note
Unused Python stubs can be safely removed from the produced MIB code.
Bring MIB implementation on-line#
Once the MIB module is implemented and passes Python syntax check (just run it from command line):
$ python SNMPv2-MIB::sysName.py
SNMP MIB module (SNMPv2-MIB) expressed in pysnmp data model.
This Python module is designed to be imported and executed by the
pysnmp library.
See https://www.pysnmp.com/pysnmp for further information.
Notes
-----
ASN.1 source file:///usr/share/snmp/mibs/SNMPv2-MIB.txt
Produced by pysmi-0.4.0 at Sun Jan 13 09:39:06 2019
On host igarlic platform Darwin version 17.7.0 by user ietingof
Using Python version 3.6.0 (v3.6.0:41df79263a11, Dec 22 2016, 17:23:13)
Copy the SNMPv2-MIB::sysName.py over to the directory where SNMP Command Responder could find it while building the desired MIB tree.
If you place your MIB modules into /etc/snmpresponder/managed-objects, the example SNMP Command Responder MIB tree configuration entry could look like this:
snmpv2-mib-objects {
mib-text-search-path-list: http://mibs.pysnmp.com/asn1/
mib-code-modules-pattern-list: /etc/snmpresponder/managed-objects/.*py[co]?
mib-tree-id: managed-objects-1
}
Alternatively, you could put your SNMPv2-MIB::sysName.py implementation file into a Python package, then register the directory containing these MIB files via the entry point snmpresponder.mibs:
'entry_points': {
'snmpresponder.mibs': 'examples = mypackage'
},
With the above registration, SNMP command responder will import mypackage and consider importing modules matching mib-code-packages-pattern-list regexp:
snmpv2-mib-objects {
mib-text-search-path-list: http://mibs.pysnmp.com/asn1/
mib-code-packages-pattern-list: mypackage\..*
mib-tree-id: managed-objects-1
}
The main advantage of packaging MIB implementations is that the package becomes pip-installable and easily distributable. That might be especially convenient for generally useful MIB implementations such as HOST-RESOURCES-MIB.
Once you are done setting things up and restarting snmpresponderd, you should be able to read the hostname via SNMP:
$ snmpget -v2c -c public localhost SNMPv2-MIB::sysName.1
SNMPv2-MIB::sysName.0 = STRING: igarlic