20042013 Ericsson AB. All Rights Reserved. The contents of this file are subject to the Erlang Public License, Version 1.1, (the "License"); you may not use this file except in compliance with the License. You should have received a copy of the Erlang Public License along with this software. If not, it can be retrieved online at http://www.erlang.org/. Software distributed under the License is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License for the specific language governing rights and limitations under the License. snmpa snmpa.xml
snmpa Interface Functions to the SNMP toolkit agent

The module snmpa contains interface functions to the SNMP agent.

DATA TYPES

The oid() type is used to represent an ASN.1 OBJECT IDENTIFIER.

The record contains the following fields:

A user defined identity representing this notification send operation.

A module implementing the snmpa_notification_delivery_info_receiver behaviour. The info functions of this module will be called at various stages of delivery.

This is any extra info the user wants to have supplied when the functions in the callback module is called.

add_agent_caps(SysORID, SysORDescr) -> SysORIndex Add an AGENT-CAPABILITY definition to the agent SysORID = oid() SysORDescr = string() SysORIndex = integer()

This function can be used to add an AGENT-CAPABILITY statement to the sysORTable in the agent. The table is defined in the SNMPv2-MIB.

del_agent_caps(SysORIndex) -> void() Delete an AGENT-CAPABILITY definition from the agent SysORIndex = integer()

This function can be used to delete an AGENT-CAPABILITY statement to the sysORTable in the agent. This table is defined in the SNMPv2-MIB.

get_agent_caps() -> [[SysORIndex, SysORID, SysORDescr, SysORUpTime]] Return all AGENT-CAPABILITY definitions in the agent SysORIndex = integer() SysORId = oid() SysORDescr = string() SysORUpTime = integer()

Returns all AGENT-CAPABILITY statements in the sysORTable in the agent. This table is defined in the SNMPv2-MIB.

get(Agent, Vars) -> Values | {error, Reason} get(Agent, Vars, Context) -> Values | {error, Reason} Perform a get operation on the agent Agent = pid() | atom() Vars = [oid()] Context = string() Values = [term()] Reason = {atom(), oid()}

Performs a GET operation on the agent. All loaded MIB objects are visible in this operation. The agent calls the corresponding instrumentation functions just as if it was a GET request coming from a manager.

Note that the request specific parameters (such as current_request_id) are not accessible for the instrumentation functions if this function is used.

get_next(Agent, Vars) -> Values | {error, Reason} get_next(Agent, Vars, Context) -> Values | {error, Reason} Perform a get-next operation on the agent Agent = pid() | atom() Vars = [oid()] Context = string() Values = [{oid(), term()}] Reason = {atom(), oid()}

Performs a GET-NEXT operation on the agent. All loaded MIB objects are visible in this operation. The agent calls the corresponding instrumentation functions just as if it was a GET request coming from a manager.

Note that the request specific parameters (such as snmpa:current_request_id/0 are not accessible for the instrumentation functions if this function is used.

backup(BackupDir) -> ok | {error, Reason} backup(Agent, BackupDir) -> ok | {error, Reason} Backup agent data BackupDir = string() Agent = pid() | atom() Reason = backup_in_progress | term()

Backup persistent/permanent data handled by the agent (such as local-db, mib-data and vacm).

Data stored by mnesia is not handled.

BackupDir cannot be identical to DbDir.

Simultaneous backup calls are not allowed. That is, two different processes cannot simultaneously successfully call this function. One of them will be first, and succeed. The second will fail with the error reason backup_in_progress.

info() -> [{Key, Value}] info(Agent) -> [{Key, Value}] Return information about the agent Agent = pid() | atom()

Returns a list (a dictionary) containing information about the agent. Information includes loaded MIBs, registered sub-agents, some information about the memory allocation.

As of version 4.4 the format of the info has been changed. To convert the info to the old format, call the old_info_format function.

old_info_format(NewInfo) -> OldInfo Return information about the agent OldInfo = NewInfo = [{Key, Value}]

As of version 4.4 the format of the info has been changed. This function is used to convert to the old (pre-4.4) info format.

load_mib(Mib) -> ok | {error, Reason} load_mib(Agent, Mib) -> ok | {error, Reason} Load single MIB into the agent Agent = pid() | atom() MibName = string() Reason = already_loaded | term()

Load a single Mib into an agent. The MibName is the name of the Mib, including the path to where the compiled mib is found. For example:

Dir = code:priv_dir(my_app) ++ "/mibs/", snmpa:load_mib(snmp_master_agent, Dir ++ "MY-MIB").
load_mibs(Mibs) -> ok | {error, Reason} load_mibs(Mibs, Force) -> ok | {error, Reason} load_mibs(Agent, Mibs) -> ok | {error, Reason} load_mibs(Agent, Mibs, Force) -> ok | {error, Reason} Load MIBs into the agent Agent = pid() | atom() Mibs = [MibName] Force = boolean() MibName = string() Reason = {'load aborted at', MibName, InternalReason} InternalReason = already_loaded | term()

Load Mibs into an agent. If the agent cannot load all MIBs (the default value of the Force argument is false), it will indicate where loading was aborted. The MibName is the name of the Mib, including the path to where the compiled mib is found. For example,

Dir = code:priv_dir(my_app) ++ "/mibs/", snmpa:load_mibs(snmp_master_agent, [Dir ++ "MY-MIB"]).

If Force = true then the agent will continue attempting to load each mib even after failing to load a previous mib. Use with care.

unload_mib(Mib) -> ok | {error, Reason} unload_mib(Agent, Mib) -> ok | {error, Reason} Unload single MIB from the agent Agent = pid() | atom() MibName = string() Reason = not_loaded | term()

Unload a single Mib from an agent.

unload_mibs(Mibs) -> ok | {error, Reason} unload_mibs(Mibs, Force) -> ok | {error, Reason} unload_mibs(Agent, Mibs) -> ok | {error, Reason} unload_mibs(Agent, Mibs, Force) -> ok | {error, Reason} Unload MIBs from the agent Agent = pid() | atom() Mibs = [MibName] Force = boolean() MibName = string() Reason = {'unload aborted at', MibName, InternalReason} InternalReason = not_loaded | term()

Unload Mibs from an agent. If it cannot unload all MIBs (the default value of the Force argument is false), it will indicate where unloading was aborted.

If Force = true then the agent will continue attempting to unload each mib even after failing to unload a previous mib. Use with care.

which_mibs() -> Mibs which_mibs(Agent) -> Mibs Get a list of all the loaded mibs Agent = pid() | atom() Mibs = [{MibName, MibFile}] MibName = atom() MibFile = string()

Retrieve the list of all the mibs loaded into this agent. Default is the master agent.

whereis_mib(MibName) -> {ok, MibFile} | {error, Reason} whereis_mib(Agent, MibName) -> {ok, MibFile} | {error, Reason} Get the path to the mib file Agent = pid() | atom() MibName = atom() MibFile = string() Reason = term()

Get the full path to the (compiled) mib-file.

current_request_id() -> {value, RequestId} | false current_context() -> {value, Context} | false current_community() -> {value, Community} | false current_address() -> {value, Address} | false Get the request-id, context, community and address of the current request RequestId = integer() Context = string() Community = string() Address = term()

Get the request-id, context, community and address of the request currently being processed by the agent.

Note that these functions is intended to be called by the instrumentation functions and only if they are executed in the context of the agent process (e.g. it does not work if called from a spawned process).

enum_to_int(Name, Enum) -> {value, Int} | false enum_to_int(Db, Name, Enum) -> {value, Int} | false Convert an enum value to an integer Db = term() Name = atom() Enum = atom() Int = int()

Converts the symbolic value Enum to the corresponding integer of the enumerated object or type Name in a MIB. The MIB must be loaded.

false is returned if the object or type is not defined in any loaded MIB, or if it does not define the symbolic value as enumerated.

Db is a reference to the symbolic store database (retrieved by a call to get_symbolic_store_db/0).

int_to_enum(Name, Int) -> {value, Enum} | false int_to_enum(Db, Name, Int) -> {value, Enum} | false Convert an integer to an enum value Db = term() Name = atom() Int = int() Enum = atom()

Converts the integer Int to the corresponding symbolic value of the enumerated object or type Name in a MIB. The MIB must be loaded.

false is returned if the object or type is not defined in any loaded MIB, or if it does not define the symbolic value as enumerated.

Db is a reference to the symbolic store database (retrieved by a call to get_symbolic_store_db/0).

name_to_oid(Name) -> {value, oid()} | false name_to_oid(Db, Name) -> {value, oid()} | false Convert a symbolic name to an OID Db = term() Name = atom()

Looks up the OBJECT IDENTIFIER of a MIB object, given the symbolic name. Note, the OBJECT IDENTIFIER is given for the object, not for an instance.

false is returned if the object is not defined in any loaded MIB.

Db is a reference to the symbolic store database (retrieved by a call to get_symbolic_store_db/0).

oid_to_name(OID) -> {value, Name} | false oid_to_name(Db, OID) -> {value, Name} | false Convert an OID to a symbolic name Db = term() OID = oid() Name = atom()

Looks up the symbolic name of a MIB object, given OBJECT IDENTIFIER.

false is returned if the object is not defined in any loaded MIB.

Db is a reference to the symbolic store database (retrieved by a call to get_symbolic_store_db/0).

which_aliasnames() -> Result Get all alias-names known to the agent Result = [atom()]

Retrieve all alias-names known to the agent.

which_tables() -> Result Get all tables known to the agent Result = [atom()]

Retrieve all tables known to the agent.

which_variables() -> Result Get all variables known to the agent Result = [atom()]

Retrieve all variables known to the agent.

which_notifications() -> Result Get all notifications known to the agent Result = [{Name, MibName, Info}] Name = atom() MibName = atom() Info = term()

Retrieve all notifications (and traps) known to the agent.

log_to_txt(LogDir) log_to_txt(LogDir, Mibs) log_to_txt(LogDir, Mibs, OutFile) -> ok | {error, Reason} log_to_txt(LogDir, Mibs, OutFile, LogName) -> ok | {error, Reason} log_to_txt(LogDir, Mibs, OutFile, LogName, LogFile) -> ok | {error, Reason} log_to_txt(LogDir, Mibs, OutFile, LogName, LogFile, Start) -> ok | {error, Reason} log_to_txt(LogDir, Mibs, OutFile, LogName, LogFile, Start, Stop) -> ok | {error, Reason} Convert an Audit Trail Log to text format LogDir = string() Mibs = [MibName] MibName = string() OutFile = string() LogName = string() LogFile = string() Start = Stop = null | datetime() | {local_time,datetime()} | {universal_time,datetime()} Reason = disk_log_open_error() | file_open_error() | term() disk_log_open_error() = {LogName, term()} file_open_error() = {OutFile, term()}

Converts an Audit Trail Log to a readable text file. OutFile defaults to "./snmpa_log.txt". LogName defaults to "snmpa_log". LogFile defaults to "snmpa.log". See snmp:log_to_txt for more info.

log_to_io(LogDir) -> ok | {error, Reason} log_to_io(LogDir, Mibs) -> ok | {error, Reason} log_to_io(LogDir, Mibs, LogName) -> ok | {error, Reason} log_to_io(LogDir, Mibs, LogName, LogFile) -> ok | {error, Reason} log_to_io(LogDir, Mibs, LogName, LogFile, Start) -> ok | {error, Reason} log_to_io(LogDir, Mibs, LogName, LogFile, Start, Stop) -> ok | {error, Reason} Convert an Audit Trail Log to text format LogDir = string() Mibs = [MibName] MibName = string() LogName = string() LogFile = string() Start = Stop = null | datetime() | {local_time,datetime()} | {universal_time,datetime()} Reason = disk_log_open_error() | file_open_error() | term() disk_log_open_error() = {LogName, term()} file_open_error() = {OutFile, term()}

Converts an Audit Trail Log to a readable format and prints it on stdio. LogName defaults to "snmpa_log". LogFile defaults to "snmpa.log". See snmp:log_to_io for more info.

change_log_size(NewSize) -> ok | {error, Reason} Change the size of the Audit Trail Log NewSize = {MaxBytes, MaxFiles} MaxBytes = integer() MaxFiles = integer() Reason = term()

Changes the log size of the Audit Trail Log. The application must be configured to use the audit trail log function. Please refer to disk_log(3) in Kernel Reference Manual for a description of how to change the log size.

The change is permanent, as long as the log is not deleted. That means, the log size is remembered across reboots.

set_log_type(NewType) -> {ok, OldType} | {error, Reason} set_log_type(Agent, NewType) -> {ok, OldType} | {error, Reason} Change the type of the Audit Trail Log NewType = OldType = atl_type() Agent = pid() | atom() Reason = term()

Changes the run-time Audit Trail log type.

Note that this has no effect on the application configuration as defined by configuration files, so a node restart will revert the config to whatever is in those files.

This function is primarily useful in testing/debugging scenarios.

mib_of(Oid) -> {ok, MibName} | {error, Reason} mib_of(Agent, Oid) -> {ok, MibName} | {error, Reason} Which mib an Oid belongs to Agent = pid() | atom() Oid = oid() MibName = atom() Reason = term()

Finds the mib corresponding to the Oid. If it is a variable, the Oid must be <Oid for var>.0 and if it is a table, Oid must be <table>.<entry>.<col>.<any>

me_of(Oid) -> {ok, Me} | {error, Reason} me_of(Agent, Oid) -> {ok, Me} | {error, Reason} Retrieve the mib-entry of an Oid Agent = pid() | atom() Oid = oid() Me = #me{} Reason = term()

Finds the mib entry corresponding to the Oid. If it is a variable, the Oid must be <Oid for var>.0 and if it is a table, Oid must be <table>.<entry>.<col>.<any>

invalidate_mibs_cache() -> void() invalidate_mibs_cache(Agent) -> void() Invalidate the mib server cache Agent = pid() | atom()

Invalidate the mib server cache.

The entire contents of the cache will be deleted.

enable_mibs_cache() -> void() enable_mibs_cache(Agent) -> void() Enable the mib server cache Agent = pid() | atom()

Enable the mib server cache.

disable_mibs_cache() -> void() disable_mibs_cache(Agent) -> void() Disable the mib server cache Agent = pid() | atom()

Disable the mib server cache.

which_mibs_cache_size() -> void() which_mibs_cache_size(Agent) -> void() The size of the mib server cache Agent = pid() | atom()

Retreive the size of the mib server cache.

gc_mibs_cache() -> {ok, NumElementsGCed} | {error, Reason} gc_mibs_cache(Agent) -> {ok, NumElementsGCed} | {error, Reason} gc_mibs_cache(Age) -> {ok, NumElementsGCed} | {error, Reason} gc_mibs_cache(Agent, Age) -> {ok, NumElementsGCed} | {error, Reason} gc_mibs_cache(Age, GcLimit) -> {ok, NumElementsGCed} | {error, Reason} gc_mibs_cache(Agent, Age, GcLimit) -> {ok, NumElementsGCed} | {error, Reason} Perform mib server cache gc Agent = pid() | atom() Age = integer() > 0 GcLimit = integer() > 0 | infinity NumElementsGCed = integer() >= 0 Reason = term()

Perform mib server cache gc.

Manually performs a mib server cache gc. This can be done regardless of the value of the autogc option. The NumElementsGCed value indicates how many elements where actually removed from the cache.

enable_mibs_cache_autogc() -> void() enable_mibs_cache_autogc(Agent) -> void() Enable automatic gc of the mib server cache Agent = pid() | atom()

Enable automatic gc of the mib server cache.

disable_mibs_cache_autogc() -> void() disable_mibs_cache_autogc(Agent) -> void() Disable automatic gc of the mib server cache Agent = pid() | atom()

Disable automatic gc of the mib server cache.

update_mibs_cache_age(NewAge) -> ok | {error, Reason} update_mibs_cache_age(Agent, NewAge) -> ok | {error, Reason} Change the mib server cache age property Agent = pid() | atom() NewAge = integer() > 0 Reason = term()

Change the mib server cache age property.

update_mibs_cache_gclimit(NewGcLimit) -> ok | {error, Reason} update_mibs_cache_gclimit(Agent, NewGCLimit) -> ok | {error, Reason} Change the mib server cache gclimit property Agent = pid() | atom() NewGcLimit = integer() > 0 | infinity Reason = term()

Change the mib server cache gclimit property.

register_notification_filter(Id, Mod, Data) -> ok | {error, Reason} register_notification_filter(Agent, Id, Mod, Data) -> ok | {error, Reason} register_notification_filter(Id, Mod, Data, Where) -> ok | {error, Reason} register_notification_filter(Agent, Id, Mod, Data, Where) -> ok | {error, Reason} Register a notification filter Agent = pid() | atom() Id = filter_id() filter_id() = term() Mod = atom() Data = term() Where = filter_position() Reason = term() filter_position() = first | last | {insert_before, filter_id()} | {insert_after, filter_id()}

Registers a notification filter.

Mod is a module implementing the snmpa_notification_filter behaviour.

Data will be passed on to the filter when calling the functions of the behaviour.

unregister_notification_filter(Id) -> ok | {error, Reason} unregister_notification_filter(Agent, Id) -> ok | {error, Reason} Unregister a notification filter Agent = pid() | atom() Id = filter_id() filter_id() = term()

Unregister a notification filter.

which_notification_filter() -> Filters which_notification_filter(Agent) -> Filters Which notification filter Agent = pid() | atom() Filters = [filter_id()] filter_id() = term()

List all notification filters in an agent.

set_request_limit(NewLimit) -> {ok, OldLimit} | {error, Reason} set_request_limit(Agent, NewLimit) -> {ok, OldLimit} | {error, Reason} Change the request limit NewLimit = OldLimit = infinity | integer() >= 0 Agent = pid() | atom() Reason = term()

Changes the request limit.

Note that this has no effect on the application configuration as defined by configuration files, so a node restart will revert the config to whatever is in those files.

This function is primarily useful in load regulation scenarios.

register_subagent(Agent, SubTreeOid, Subagent) -> ok | {error, Reason} Register a sub-agent under a sub-tree Agent = pid() | atom() SubTreeOid = oid() SubAgent = pid()

Registers a sub-agent under a sub-tree of another agent.

It is easy to make mistakes when registering sub-agents and this activity should be done carefully. For example, a strange behaviour would result from the following configuration:

snmp_agent:register_subagent(MAPid,[1,2,3,4],SA1),
snmp_agent:register_subagent(SA1,[1,2,3], SA2).
        

SA2 will not get requests starting with object identifier [1,2,3] since SA1 does not.

unregister_subagent(Agent, SubagentOidOrPid) -> ok | {ok, SubAgentPid} | {error, Reason} Unregister a sub-agent Agent = pid() | atom() SubTreeOidorPid = oid() | pid()

Unregister a sub-agent. If the second argument is a pid, then that sub-agent will be unregistered from all trees in Agent.

send_notification2(Agent, Notification, SendOpts) -> void() Send notification Agent = pid() | atom() Notification = atom() SendOpts = [send_option()] send_option() = {receiver, receiver()} | {name, notify_name()} | {context, context_name()} | {varbinds, varbinds()} | {local_engine_id, string()} | {extra, extra_info()} receiver() = no_receiver | {tag(), tag_receiver()} | notification_delivery_info() tag() = term(() tag_receiver() = pid() | registered_name() | {Mod, Func, Args} registered_name() = atom() Mod = atom() Func = atom() Args = list() notify_name() = string() context_name() = string() varbinds() = [varbind()] varbind() = {variable(), value()} | {column(), row_index(), value()} | {oid(), value()} variable() = atom() value() = term() column() = atom() row_index() = [int()] extra_info() = term()

Send the notification Notification to the management targets defined for notify-name (name) in the snmpNotifyTable in SNMP-NOTIFICATION-MIB from the specified context.

If no name is specified (or if it is ""), the notification is sent to all management targets.

If no context is specified, the default context, "", is used.

The send option receiver specifies where information about delivery of Inform-Requests should be sent. The agent sends Inform-Requests and waits for acknowledgments from the management targets. The receiver can have three values:

no_receiver - No information is delivered.

notification_delivery_info() - The information is delivered via a function call according to this data. See the DATA TYPES section above for details.

{tag(), tag_receiver()} - The information is delivered either via messages or via a function call according to the value of tag_receiver().

Delivery is done differently depending on the value of tag_receiver():

pid() | registered_name() - The info will be delivered in the following messages:

{snmp_targets, tag(), Addresses}

This informs the user which target addresses the notification was sent to.

{snmp_notification, tag(), {got_response, Address}}

This informs the user that this target address acknowledged the notification.

{snmp_notification, tag(), {no_response, Address}}

This informs the user that this target address did not acknowledge the notification.

The notification is sent as an Inform-Request to each target address in Addresses and if there are no targets for which an Inform-Request is sent, Addresses is the empty list [].

The tag_receiver() will first be sent the snmp_targets message, and then for each address in Addresses list, one of the two snmp_notification messages.

{Mod, Func, Args} - The info will be delivered via the function call:

Mod:Func([Msg | Args])

where Msg has the same content and purpose as the messages descrived above.

The extra info is not normally interpreted by the agent, instead it is passed through to the net-if process. It is up to the implementor of that process to make use of this data.

The version of net-if provided by this application makes no use of this data, with one exception: Any tuple containing the atom snmpa_default_notification_extra_info may be used by the agent and is therefor reserved.

See the net-if incomming messages for sending a trap and notification for more info.

send_notification(Agent, Notification, Receiver) send_notification(Agent, Notification, Receiver, Varbinds) send_notification(Agent, Notification, Receiver, NotifyName, Varbinds) send_notification(Agent, Notification, Receiver, NotifyName, ContextName, Varbinds) -> void() send_notification(Agent, Notification, Receiver, NotifyName, ContextName, Varbinds, LocalEngineID) -> void() Send a notification Agent = pid() | atom() Notification = atom() Receiver = no_receiver | {Tag, Recv} | notification_delivery_info() Tag = term() Recv = receiver() receiver() = pid() | atom() | {Mod, Func, Args} Mod = atom() Func = atom() Args = list() NotifyName = string() ContextName = string() Varbinds = varbinds() varbinds() = [varbind()] varbind() = {Variable, Value} | {Column, RowIndex, Value} | {OID, Value} Variable = atom() Column = atom() OID = oid() Value = term() RowIndex = [int()] LocalEngineID = string()

Sends the notification Notification to the management targets defined for NotifyName in the snmpNotifyTable in SNMP-NOTIFICATION-MIB from the specified context.

If no NotifyName is specified (or if it is ""), the notification is sent to all management targets (Addresses below).

If no ContextName is specified, the default "" context is used.

The parameter Receiver specifies where information about delivery of Inform-Requests should be sent. The agent sends Inform-Requests and waits for acknowledgments from the managers. Receiver can have three values:

no_receiver - No information is delivered.

notification_delivery_info() - The information is delivered via a function call according to this data. See the DATA TYPES section above for details.

{Tag, Recv} - The information is delivered either via messages or via a function call according to the value of Recv.

If Receiver has the value {Tag, Recv}, the delivery is done according to Recv:

pid() | atom() - The info will be delivered in the following messages:

{snmp_targets, Tag, Addresses}

This inform the user which target addresses the notification was sent to.

{snmp_notification, Tag, {got_response, Address}}

This informs the user that this target address acknowledged the notification.

{snmp_notification, Tag, {no_response, Address}}

This informs the user that this target address did not acknowledge notification.

The notification is sent as an Inform-Request to each target address in Addresses and if there are no targets for which an Inform-Request is sent, Addresses is the empty list [].

The receiver will first be sent the snmp_targets message, and then for each address in Addresses list, one of the two snmp_notification messages.

{Mod, Func, Args} - The info will be delivered via the function call:

Mod:Func([Msg | Args])

where Msg has the same content and purpose as the messages descrived above.

Address is a management target address and Addresses is a list of management target addresses. They are defined as followes:

        Addresses  = [address()]
        Address    = address()
        address()  = v1_address() | v3_address()
        v1_address() = {TDomain, TAddress}
        v3_address() = {{TDomain, TAddress}, V3MsgData}
        TDomain    = tdoamin()
        TAddress   = taddress()
        tdomain()  = The oid of snmpUDPDomain 
                     This is the only supported transport domain.
        taddress() = [A1, A2, A3, A4, P1, P3]
                     The 4 first bytes makes up the IP-address and the last 2,
                     the UDP-port number.
        V3MsgData  = v3_msg_data()
        v3_msg_data() = term()

If Receiver is a notification_delivery_info() record, then the information about the notification delivery will be delivered to the receiver via the callback functions defined by the snmpa_notification_delivery_info_receiver behaviour according to the content of the notification_delivery_info() record.

The optional argument Varbinds defines values for the objects in the notification. If no value is given for an object, the Agent performs a get-operation to retrieve the value.

Varbinds is a list of Varbind, where each Varbind is one of:

{Variable, Value}, where Variable is the symbolic name of a scalar variable referred to in the notification specification. {Column, RowIndex, Value}, where Column is the symbolic name of a column variable. RowIndex is a list of indices for the specified element. If this is the case, the OBJECT IDENTIFIER sent in the notification is the RowIndex appended to the OBJECT IDENTIFIER for the table column. This is the OBJECT IDENTIFIER which specifies the element. {OID, Value}, where OID is the OBJECT IDENTIFIER for an instance of an object, scalar variable, or column variable.

For example, to specify that sysLocation should have the value "upstairs" in the notification, we could use one of:

{sysLocation, "upstairs"} or {[1,3,6,1,2,1,1,6,0], "upstairs"} or {?sysLocation_instance, "upstairs"} (provided that the generated .hrl file is included)

If a variable in the notification is a table element, the RowIndex for the element must be given in the Varbinds list. In this case, the OBJECT IDENTIFIER sent in the notification is the OBJECT IDENTIFIER that identifies this element. This OBJECT IDENTIFIER could be used in a get operation later.

This function is asynchronous, and does not return any information. If an error occurs, user_err/2 of the error report module is called and the notification is discarded.

Note that the use of the LocalEngineID argument is only intended for special cases, if the agent is to "emulate" multiple EngineIDs! By default, the agent uses the value of SnmpEngineID (see SNMP-FRAMEWORK-MIB).

ExtraInfo is not normally used in any way by the agent. It is intended to be passed along to the net-if process, which is a component that a user can implement themself. The users own net-if may then make use of ExtraInfo. The net-if provided with this application does not process ExtraInfo.

There is one exception. Any tuple containing the atom snmpa_default_notification_extra_info will, in this context, be considered belonging to this application, and may be processed by the agent.

discovery(TargetName, Notification) -> {ok, ManagerEngineID} | {error, Reason} discovery(TargetName, Notification, Varbinds) -> {ok, ManagerEngineID} | {error, Reason} discovery(TargetName, Notification, DiscoHandler) -> {ok, ManagerEngineID} | {error, Reason} discovery(TargetName, Notification, ContextName, Varbinds) -> {ok, ManagerEngineID} | {error, Reason} discovery(TargetName, Notification, Varbinds, DiscoHandler) -> {ok, ManagerEngineID} | {error, Reason} discovery(TargetName, Notification, ContextName, Varbinds, DiscoHandler) -> {ok, ManagerEngineID} | {error, Reason} discovery(TargetName, Notification, ContextName, Varbinds, DiscoHandler, ExtraInfo) -> {ok, ManagerEngineID} | {error, Reason} Initiate the discovery process with a manager TargetName = string() Notification = atom() ContextName = string() (defaults to "") Varbinds = varbinds() varbinds() = [varbind()] DiscoHandler = snmpa_discovery_handler() ExtraInfo = term() snmpa_discovery_handler() = Module implementing the snmpa_discovery_handler behaviour ManagerEngineID = string() varbind() = {Variable, Value} | {Column, RowIndex, Value} | {OID, Value} Variable = atom() Column = atom() OID = oid() Value = term() RowIndex = [int()] Reason = term()

Initiate the discovery process with the manager identified by TargetName using the notification Notification.

This function is synchronous, which means that it will return when the discovery process has been completed or failed.

The DiscoHandler module is used during the discovery process. See discovery handler for more info.

The ExtraInfo argument is passed on to the callback functions of the DiscoHandler.

If we are not at security-level noAuthNoPriv, this could be complicated, since the agent will then continue with stage 2, before which the usm-related updates must be done.

The default discovery handler will require additional actions by the caller and the discovery will not work if the security-level is higher then noAuthNoPriv.

convert_config(OldConfig) -> AgentConfig Convert old snmp config to new agent config OldConfig = list() AgentConfig = list()

This off-line utility function can be used to convert the old snmp application config (pre snmp-4.0) to the new snmp agent config (as of snmp-4.0).

For information about the old config (OldConfig) see the OTP R9C documentation.

For information about the current agent config (AgentConfig), see either the SNMP application part of the reference manual or the Configuring the application chapter of the SNMP user's guide.

restart_worker() -> void() restart_worker(Agent) -> void() Restart the worker process of a multi-threaded agent Agent = pid() | atom()

Restart the worker process of a multi-threaded agent.

This is a utility function, that can be useful when e.g. debugging instrumentation functions.

restart_set_worker() -> void() restart_set_worker(Agent) -> void() Restart the set worker process of a multi-threaded agent Agent = pid() | atom()

Restart the set worker process of a multi-threaded agent.

This is a utility function, that can be useful when e.g. debugging instrumentation functions.

print_mib_info() -> void() Print mib info

Prints the content of all the (snmp) tables and variables for all mibs handled by the snmp agent.

print_mib_tables() -> void() Print mib tables

Prints the content of all the (snmp) tables for all mibs handled by the snmp agent.

print_mib_variables() -> void() Print mib variables

Prints the content of all the (snmp) variables for all mibs handled by the snmp agent.

verbosity(Ref,Verbosity) -> void() Assign a new verbosity for the process Ref = pid() | sub_agents | master_agent | net_if | mib_server | symbolic_store | note_store | local_db Verbosity = verbosity() | {subagents, verbosity()} verbosity() = silence | info | log | debug | trace

Sets verbosity for the designated process. For the lowest verbosity silence, nothing is printed. The higher the verbosity, the more is printed.

See Also

calendar(3), erlc(1)