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IETF RFC 7659



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Internet Engineering Task Force (IETF)                      S. Perreault
Request for Comments: 7659                           Jive Communications
Category: Standards Track                                      T. Tsou
ISSN: 2070-1721                                      Huawei Technologies
                                                            S. Sivakumar
                                                           Cisco Systems
                                                               T. Taylor
                                                    PT Taylor Consulting
                                                            October 2015


 Definitions of Managed Objects for Network Address Translators (NATs)

 Abstract

   This memo defines a portion of the Management Information Base (MIB)
   for devices implementing the Network Address Translator (NAT)
   function.  The new MIB module defined in this document, NATV2-MIB, is
   intended to replace module NAT-MIB (RFC 4008).  NATV2-MIB is not
   backwards compatible with NAT-MIB, for reasons given in the text of
   this document.  A companion document deprecates all objects in NAT-
   MIB.  NATV2-MIB can be used for the monitoring of NAT instances on a
   device capable of NAT function.  Compliance levels are defined for
   three application scenarios: basic NAT, pooled NAT, and
   carrier-grade NAT (CGN).

 Status of This Memo

   This is an Internet Standards Track document.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Further information on
   Internet Standards is available in Section 2 of RFC 5741.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   http://www.rfc-editor.org/info/RFC 7659.












Perreault, et al.            Standards Track                 PAGE 1 


RFC 7659 NAT MIB October 2015 Copyright Notice Copyright (c) 2015 IETF Trust and the persons identified as the document authors. All rights reserved. This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License. Table of Contents 1. The Internet-Standard Management Framework . . . . . . . . . 3 2. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3 3. Overview . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3.1. Content Provided by the NATV2-MIB Module . . . . . . . . 5 3.1.1. Configuration Data . . . . . . . . . . . . . . . . . 5 3.1.2. Notifications . . . . . . . . . . . . . . . . . . . . 6 3.1.3. State Information . . . . . . . . . . . . . . . . . . 9 3.1.4. Statistics . . . . . . . . . . . . . . . . . . . . . 9 3.2. Outline of MIB Module Organization . . . . . . . . . . . 12 3.3. Detailed MIB Module Walk-Through . . . . . . . . . . . . 13 3.3.1. Textual Conventions . . . . . . . . . . . . . . . . . 13 3.3.2. Notifications . . . . . . . . . . . . . . . . . . . . 14 3.3.3. The Subscriber Table: natv2SubscriberTable . . . . . 14 3.3.4. The Instance Table: natv2InstanceTable . . . . . . . 15 3.3.5. The Protocol Table: natv2ProtocolTable . . . . . . . 15 3.3.6. The Address Pool Table: natv2PoolTable . . . . . . . 16 3.3.7. The Address Pool Address Range Table: natv2PoolRangeTable . . . . . . . . . . . . . . . . . 17 3.3.8. The Address Map Table: natv2AddressMapTable . . . . . 17 3.3.9. The Port Map Table: natv2PortMapTable . . . . . . . . 17 3.4. Conformance: Three Application Scenarios . . . . . . . . 18 4. Definitions . . . . . . . . . . . . . . . . . . . . . . . . . 19 5. Operational and Management Considerations . . . . . . . . . . 74 5.1. Configuration Requirements . . . . . . . . . . . . . . . 74 5.2. Transition from and Coexistence with NAT-MIB (RFC 4008) . 76 6. Security Considerations . . . . . . . . . . . . . . . . . . . 78 7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 81 8. References . . . . . . . . . . . . . . . . . . . . . . . . . 81 8.1. Normative References . . . . . . . . . . . . . . . . . . 81 8.2. Informative References . . . . . . . . . . . . . . . . . 82 Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 84 Perreault, et al. Standards Track PAGE 2

RFC 7659 NAT MIB October 2015 1. The Internet-Standard Management Framework For a detailed overview of the documents that describe the current Internet-Standard Management Framework, please refer to section 7 of RFC 3410 [RFC 3410]. Managed objects are accessed via a virtual information store, termed the Management Information Base or MIB. MIB objects are generally accessed through the Simple Network Management Protocol (SNMP). Objects in the MIB are defined using the mechanisms defined in the Structure of Management Information (SMI). This memo specifies a MIB module that is compliant to the SMIv2, which is described in STD 58, RFC 2578 [RFC 2578], STD 58, RFC 2579 [RFC 2579] and STD 58, RFC 2580 [RFC 2580]. 2. Introduction This memo defines a portion of the Management Information Base (MIB) for devices implementing NAT functions. This MIB module, NATV2-MIB, may be used for the monitoring of such devices. NATV2-MIB supersedes NAT-MIB [RFC 4008], which did not fit well with existing NAT implementations, and hence was not itself much implemented. [RFC 7658] provides a detailed analysis of the deficiencies of NAT-MIB. Relative to [RFC 4008] and based on the analysis just mentioned, the present document introduces the following changes: o removed all writable configuration except that related to control of the generation of notifications and the setting of quotas on the use of NAT resources; o minimized the read-only exposure of configuration to what is needed to provide context for the state and statistical information presented by the MIB module; o removed the association between mapping and interfaces, retaining only the mapping aspect; o replaced references to NAT types with references to NAT behaviors as specified in [RFC 4787]; o replaced a module-specific enumeration of protocols with the standard protocol numbers provided by the IANA Protocol Numbers registry. Perreault, et al. Standards Track PAGE 3

RFC 7659 NAT MIB October 2015 This MIB module adds the following features not present in [RFC 4008]: o additional writable protective limits on NAT state data; o additional objects to report state, statistics, and notifications; o support for the carrier-grade NAT (CGN) application, including subscriber-awareness, support for an arbitrary number of address realms, and support for multiple NAT instances running on a single device; o expanded support for address pools; o revised indexing of port map entries to simplify traceback from externally observable packet parameters to the corresponding internal endpoint. These features are described in more detail below. The remainder of this document is organized as follows: o Section 3 provides a verbal description of the content and organization of the MIB module. o Section 4 provides the MIB module definition. o Section 5 discusses operational and management issues relating to the deployment of NATV2-MIB. One of these issues is NAT management when both NAT-MIB [RFC 4008] and NATV2-MIB are deployed. o Sections 6 and 7 provide a security discussion and a request to IANA for allocation of an object identifier for the module in the mib-2 tree, respectively. The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC 2119]. This document uses the following terminology: Upper-layer protocol: The protocol following the outer IP header of a packet. This follows the terminology of [RFC 2460], but as that document points out, "upper" is not necessarily a correct description of the protocol relationships (e.g., where IP is encapsulated in IP). The abbreviated term "protocol" will often be used where it is unambiguous. Perreault, et al. Standards Track PAGE 4

RFC 7659 NAT MIB October 2015 Trigger: With respect to notifications, the logical recognition of the event that the notification is intended to report. Report: The actual production of a notification message. Reporting can happen later than triggering, or may never happen for a given notification instance, because of the operation of notification rate controls. Address realm: A network domain in which the network addresses are uniquely assigned to entities such that datagrams can be routed to them. (Definition taken from [RFC 2663], Section 2.1.) The abbreviated term "realm" will often be used. 3. Overview This section provides a prose description of the contents and organization of the NATV2-MIB module. 3.1. Content Provided by the NATV2-MIB Module The content provided by the NATV2-MIB module can be classed under four headings: configuration data, notifications, state information, and statistics. 3.1.1. Configuration Data As mentioned above, the intent in designing the NATV2-MIB module was to minimize the amount of configuration data presented to that needed to give a context for interpreting the other types of information provided. Detailed descriptions of the configuration data are included with the descriptions of the individual tables. In general, that data is limited to what is needed for indexing and cross- referencing between tables. The two exceptions are the objects describing NAT instance behavior in the NAT instance table and the detailed enumeration of resources allocated to each address pool in the pool table and its extension. The NATV2-MIB module provides three sets of read-write objects, specifically related to other aspects of the module content. The first set controls the rate at which specific notifications are generated. The second set provides thresholds used to trigger the notifications. These objects are listed in Section 3.1.2. A third set of read-write objects sets limits on resource consumption per NAT instance and per subscriber. When these limits are reached, packets requiring further consumption of the given resource are Perreault, et al. Standards Track PAGE 5

RFC 7659 NAT MIB October 2015 dropped rather than translated. Statistics described in Section 3.1.4 record the numbers of packets dropped. Limits are provided for: o total number of address map entries over the NAT instance. Limit is set by object natv2InstanceLimitAddressMapEntries in table natv2InstanceTable. Dropped packets are counted in natv2InstanceAddressMapEntryLimitDrops in that table. o total number of port map entries over the NAT instance. Limit is set by object natv2InstanceLimitPortMapEntries in table natv2InstanceTable. Dropped packets are counted in natv2InstancePortMapEntryLimitDrops in that table. o total number of held fragments (applicable only when the NAT instance can receive fragments out of order; see [RFC 4787], Section 11). Limit is set by object natv2InstanceLimitPendingFragments in table natv2InstanceTable. Dropped packets are counted by natv2InstanceFragmentDrops in the same table. o total number of active subscribers (i.e., subscribers having at least one mapping table entry) over the NAT instance. Limit is set by object natv2InstanceLimitSubscriberActives in table natv2InstanceTable. Dropped packets are counted by natv2InstanceSubscriberActiveLimitDrops in the same table. o number of port map entries for an individual subscriber. Limit is set by object natv2SubscriberLimitPortMapEntries in table natv2SubscriberTable. Dropped packets are counted by natv2SubscriberPortMapFailureDrops in the same table. Note that, unlike in the instance table, the per-subscriber count is lumped in with the count of packets dropped because of failures to allocate a port map entry for other reasons to save on storage. 3.1.2. Notifications NATV2-MIB provides five notifications, intended to provide warning of the need to provision or reallocate NAT resources. As indicated in the previous section, each notification is associated with two read- write objects: a control on the rate at which that notification is generated and a threshold value used to trigger the notification in the first place. The default setting within the MIB module specification is that all notifications are disabled. The setting of threshold values is discussed in Section 5. Perreault, et al. Standards Track PAGE 6

RFC 7659 NAT MIB October 2015 The five notifications are as follows: o Two notifications relate to the management of address pools. One indicates that usage equals or exceeds an upper threshold and is therefore a warning that the pool may be over-utilized unless more addresses are assigned to it. The other notification indicates that usage equals or has fallen below a lower threshold, suggesting that some addresses allocated to that pool could be reallocated to other pools. Address pool usage is calculated as the percentage of the total number of ports allocated to the address pool that are already in use, for the most-mapped protocol at the time the notification is generated. The notifications identify that protocol and report the number of port map entries for that protocol in the given address pool at the moment the notification was triggered. o Two notifications relate to the number of address and port map entries, respectively, in total over the whole NAT instance. In both cases, the threshold that triggers the notification is an upper threshold. The notifications return the number of mapping entries of the given type, plus a cumulative counter of the number of entries created in that mapping table at the moment the notification was triggered. The intent is that the notifications provide a warning that the total number of address or port map entries is approaching the configured limit. o The final notification is generated on a per-subscriber basis when the number of port map entries for that subscriber crosses the associated threshold. The objects returned by this notification are similar to those returned for the instance-level mapping notifications. This notification is a warning that the number of port map entries for the subscriber is approaching the configured limit for that subscriber. Here is a detailed specification of the notifications. A given notification can be disabled by setting the threshold to -1 (default). Notification: natv2NotificationPoolUsageLow. Indicates that address pool usage for the most-mapped protocol equals or is less than the threshold value. Compared value: natv2PoolNotifiedPortMapEntries as a percentage of total available ports in the pool. Threshold: natv2PoolThresholdUsageLow in natv2PoolTable. Perreault, et al. Standards Track PAGE 7

RFC 7659 NAT MIB October 2015 Objects returned: natv2PoolNotifiedPortMapEntries and natv2PoolNotifiedPortMapProtocol in natv2PoolTable. Rate control: natv2PoolNotificationInterval in natv2PoolTable. Notification: natv2NotificationPoolUsageHigh. Indicates that address pool usage for the most-mapped protocol has risen to the threshold value or more. Compared value: natv2PoolNotifiedPortMapEntries as a percentage of total available ports in the pool. Threshold: natv2PoolThresholdUsageHigh in natv2PoolTable. Objects returned: natv2PoolNotifiedPortMapEntries and natv2PoolNotifiedPortMapProtocol in natv2PoolTable. Rate control: natv2PoolNotificationInterval in natv2PoolTable. Notification: natv2NotificationInstanceAddressMapEntriesHigh. Indicates that the total number of entries in the address map table over the whole NAT instance equals or exceeds the threshold value. Compared value: natv2InstanceAddressMapEntries in natv2InstanceTable. Threshold: natv2InstanceThresholdAddressMapEntriesHigh in natv2InstanceTable. Objects returned: natv2InstanceAddressMapEntries and natv2InstanceAddressMapCreations in natv2InstanceTable. Rate control: natv2InstanceNotificationInterval in natv2InstanceTable. Notification: natv2NotificationInstancePortMapEntriesHigh. Indicates that the total number of entries in the port map table over the whole NAT instance equals or exceeds the threshold value. Compared value: natv2InstancePortMapEntries in natv2InstanceTable. Threshold: natv2InstanceThresholdPortMapEntriesHigh in natv2InstanceTable. Objects returned: natv2InstancePortMapEntries and natv2InstancePortMapCreations in natv2InstanceTable. Perreault, et al. Standards Track PAGE 8

RFC 7659 NAT MIB October 2015 Rate control: natv2InstanceNotificationInterval in natv2InstanceTable. Notification: natv2NotificationSubscriberPortMapEntriesHigh. Indicates that the total number of entries in the port map table for the given subscriber equals or exceeds the threshold value configured for that subscriber. Compared value: natv2SubscriberPortMapEntries in natv2SubscriberTable. Threshold: natv2SubscriberThresholdPortMapEntriesHigh in natv2SubscriberTable. Objects returned: natv2SubscriberPortMapEntries and natv2SubscriberPortMapCreations in natv2SubscriberTable. Rate control: natv2SubscriberNotificationInterval in natv2SubscriberTable. 3.1.3. State Information State information provides a snapshot of the content and extent of the NAT mapping tables at a given moment of time. The address and port mapping tables are described in detail below. In addition to these tables, two state variables are provided: current number of entries in the address mapping table, and current number of entries in the port mapping table. With one exception, these are provided at four levels of granularity: per NAT instance, per protocol, per address pool, and per subscriber. Address map entries are not tracked per protocol, since address mapping is protocol independent. 3.1.4. Statistics NATV2-MIB provides a number of counters, intended to help with both the provisioning of the NAT and the debugging of problems. As with the state data, these counters are provided at the four levels of NAT instance, protocol, address pool, and subscriber when they make sense. Each counter is cumulative, beginning from a "last discontinuity time" recorded by an object that is usually in the table containing the counter. The basic set of counters, as reflected in the NAT instance table, is as follows: Translations: number of packets processed and translated (in this case, in total for the NAT instance). Perreault, et al. Standards Track PAGE 9

RFC 7659 NAT MIB October 2015 Address map entry creations: cumulative number of address map entries created, including static mappings. Port map entry creations: cumulative number of port map entries created, including static mappings. Address map limit drops: cumulative number of packets dropped rather than translated because the packet would have triggered the creation of a new address mapping, but the configured limit on number of address map entries has already been reached. Port map limit drops: cumulative number of packets dropped rather than translated because the packet would have triggered the creation of a new port mapping, but the configured limit on number of port map entries has already been reached. Active subscriber limit drops: cumulative number of packets dropped rather than translated because the packet would have triggered the creation of a new address and/or port mapping for a subscriber with no existing entries in either table, but the configured limit on number of active subscribers has already been reached. Address mapping failure drops: cumulative number of packets dropped because the packet would have triggered the creation of a new address mapping, but no address could be allocated in the external realm concerned because all addresses from the selected address pool (or the whole realm, if no address pool has been configured for that realm) have already been fully allocated. Port mapping failure drops: cumulative number of packets dropped because the packet would have triggered the creation of a new port mapping, but no port could be allocated for the protocol concerned. The precise conditions under which these packet drops occur depend on the pooling behavior [RFC 4787] configured or implemented in the NAT instance. See the DESCRIPTION clause for the natv2InstancePortMapFailureDrops object for a detailed description of the different cases. These cases were defined with care to ensure that address mapping failure could be distinguished from port mapping failure. Fragment drops: cumulative number of packets dropped because the packet contains a fragment, and the fragment behavior [RFC 4787] configured or implemented in the NAT instance indicates that the packet should be dropped. The main case is a NAT instance that meets REQ-14 of [RFC 4787], hence it can receive and process out- of-order fragments. In that case, dropping occurs only when the Perreault, et al. Standards Track PAGE 10

RFC 7659 NAT MIB October 2015 configured limit on pending fragments provided by NATV2-MIB has already been reached. The other cases are detailed in the DESCRIPTION clause of the natv2InstanceFragmentBehavior object. Other resource drops: cumulative number of packets dropped because of unavailability of some other resource. The most likely case would be packets where the upper-layer protocol is not one supported by the NAT instance. Table 1 indicates the granularities at which these statistics are reported. +-----------------------+------------+----------+------+------------+ | Statistic | NAT | Protocol | Pool | Subscriber | | | Instance | | | | +-----------------------+------------+----------+------+------------+ | Translations | Yes | Yes | No | Yes | | | | | | | | Address map entry | Yes | No | Yes | Yes | | creations | | | | | | | | | | | | Port map entry | Yes | Yes | Yes | Yes | | creations | | | | | | | | | | | | Address map limit | Yes | No | No | No | | drops | | | | | | | | | | | | Port map limit drops | Yes | No | No | Yes | | | | | | | | Active subscriber | Yes | No | No | No | | limit drops | | | | | | | | | | | | Address mapping | Yes | No | Yes | Yes | | failure drops | | | | | | | | | | | | Port mapping failure | Yes | Yes | Yes | Yes | | drops | | | | | | | | | | | | Fragment drops | Yes | No | No | No | | | | | | | | Other resource drops | Yes | No | No | No | +-----------------------+------------+----------+------+------------+ Table 1: Statistics Provided By Level of Granularity Perreault, et al. Standards Track PAGE 11

RFC 7659 NAT MIB October 2015 3.2. Outline of MIB Module Organization Figure 1 shows how object identifiers are organized in the NATV2-MIB module. Under the general natv2MIB object identifier in the mib-2 tree, the objects are classed into four groups: natv2MIBNotifications(0): identifies the five notifications described in Section 3.1.2. natv2MIBDeviceObjects(1): identifies objects relating to the whole device, specifically, the subscriber table. natv2MIBInstanceObjects(2): identifies objects relating to individual NAT instances. These include the NAT instance table, the protocol table, the address pool table and its address range expansion, the address map table, and the port map table. natv2MIBConformance(3): identifies the group and compliance clauses, specified for the three application scenarios described in Section 3.4. Perreault, et al. Standards Track PAGE 12

RFC 7659 NAT MIB October 2015 natv2MIB | +-------------+-------------+-------------+ | | | | | | | 0 | | | natv2MIBNotifications | | | | | | | 1 | | | natv2MIBDeviceObjects | | Five | | notifications | 2 | | natv2MIBInstanceObjects | | | Subscriber | 3 table | natv2MIBConformance | | | | Six per-NAT- | instance tables | | +----------------------+------- | | | | 1 2 natv2MIBCompliances natv2MIBGroups | | | | Basic Basic pooled pooled carrier-grade NAT carrier-grade NAT Figure 1: Organization of Object Identifiers for NATV2-MIB 3.3. Detailed MIB Module Walk-Through This section reviews the contents of the NATV2-MIB module. The table descriptions include references to subsections of Section 3.1 where desirable to avoid repetition of that information. 3.3.1. Textual Conventions The module defines four key textual conventions: ProtocolNumber, Natv2SubscriberIndex, Natv2InstanceIndex, and Natv2PoolIndex. ProtocolNumber is based on the IANA registry of protocol numbers and hence is potentially reusable by other MIB modules. Perreault, et al. Standards Track PAGE 13

RFC 7659 NAT MIB October 2015 Objects of type Natv2SubscriberIndex identify individual subscribers served by the NAT device. The values of these identifiers are administered and, in intent, are permanently associated with their respective subscribers. Reuse of a value after a subscriber has been deleted is discouraged. The scope of the subscriber index was defined to be at the device rather than the NAT instance level to make it easier to shift subscribers between instances (e.g., for load balancing). Objects of type Natv2InstanceIndex identify specific NAT instances on the device. Again, these are administered values intended to be permanently associated with the NAT instances to which they have been assigned. Objects of type Natv2PoolIndex identify individual address pools in a given NAT instance. As with the subscriber and instance index objects, the pool identifiers are administered and intended to be permanently associated with their respective pools. 3.3.2. Notifications Notifications were described in Section 3.1.2. 3.3.3. The Subscriber Table: natv2SubscriberTable Table natv2SubscriberTable is indexed by the subscriber index. One conceptual row contains information relating to a specific subscriber: the subscriber's internal address or prefix for correlation with other management information; state and statistical information as described in Sections 3.1.3 and 3.1.4; the per- subscriber control objects described in Section 3.1.1; and natv2SubscriberDiscontinuityTime, which provides a timestamp of the latest time following, which the statistics have accumulated without discontinuity. Turning back to the address information for a moment: this information includes the identity of the address realm in which the address is routable. That enables support of an arbitrary number of address realms on the same NAT instance. Address realm identifiers are administered values in the form of a limited-length SnmpAdminString. In the absence of configuration to the contrary, the default realm for all internal addresses as recorded in mapping entries is "internal". The term "address realm" is defined in [RFC 2663], Section 2.1 and reused in subsequent NAT-related documents. Perreault, et al. Standards Track PAGE 14

RFC 7659 NAT MIB October 2015 In the special case of Dual-Stack Lite (DS-Lite) [RFC 6333], for unique matching of the subscriber data to other information in the MIB module, it is necessary that the address information should relate to the outer IPv6 header of packets going to or from the host, with the address realm being the one in which that IPv6 address is routable. The presentation of address information for other types of tunneled access to the NAT is out of scope. 3.3.4. The Instance Table: natv2InstanceTable Table natv2InstanceTable is indexed by an object of type Natv2InstanceIndex. A conceptual row of this table provides information relating to a particular NAT instance configured on the device. Configuration information provided by this table includes an instance name of type DisplayString that may have been configured for this instance and a set of objects indicating, respectively, the port mapping, filtering, pooling, and fragment behaviors configured or implemented in the instance. These behaviors are all defined in [RFC 4787]. Their values affect the interpretation of some of the statistics provided in the instance table. Read-write objects listed in Section 3.1.2 set the notification rate for instance-level notifications and set the thresholds that trigger them. Additional read-write objects described in Section 3.1.1 set limits on the number of address and port mapping entries, number of pending fragments, and number of active subscribers for the instance. The state and statistical information provided by this table consists of the per-instance items described in Sections 3.1.3 and 3.1.4, respectively. natv2InstanceDiscontinuityTime is a timestamp giving the time beyond which all of the statistical counters in natv2InstanceTable are guaranteed to have accumulated continuously. 3.3.5. The Protocol Table: natv2ProtocolTable The protocol table is indexed by the NAT instance number and an object of type ProtocolNumber as described in Section 3.3.1 (i.e., an IANA-registered protocol number). The set of protocols supported by the NAT instance is implementation dependent, but they MUST include ICMP(1), TCP(6), UDP(17), and ICMPv6(58). Depending on the application, it SHOULD include IPv4 encapsulation(4), IPv6 encapsulation(41), IPsec AH(51), and SCTP(132). Support of PIM(103) is highly desirable. Perreault, et al. Standards Track PAGE 15

RFC 7659 NAT MIB October 2015 This table includes no configuration information. The state and statistical information provided by this table consists of the per- protocol items described in Sections 3.1.3 and 3.1.4, respectively. natv2InstanceDiscontinuityTime in natv2InstanceTable is reused as the timestamp giving the time beyond which all of the statistical counters in natv2ProtocolTable are guaranteed to have accumulated continuously. The reasoning is that any event affecting the continuity of per-protocol statistics will affect the continuity of NAT instance statistics, and vice versa. 3.3.6. The Address Pool Table: natv2PoolTable The address pool table is indexed by the NAT instance identifier for the instance on which it is provisioned, plus a pool index of type Natv2PoolIndex. Configuration information provided includes the address realm for which the pool provides addresses, the type of address (IPv4 or IPv6) supported by the realm, plus the port range it makes available for allocation. The same set of port numbers (or, in the ICMP case, identifier values) is made available for every protocol supported by the NAT instance. The port range is specified in terms of minimum and maximum port number. The state and statistical information provided by this table consists of the per-pool items described in Sections 3.1.3 and 3.1.4 respectively, plus two additional state objects described below. natv2PoolTable provides the pool-specific object natv2PoolDiscontinuityTime to indicate the time since the statistical counters have accumulated continuously. Read-write objects to set high and low thresholds for pool usage notifications and for governing the notification rate were identified in Section 3.1.2. Implementation note: the thresholds are defined in terms of percentage of available port utilization. The number of available ports in a pool is equal to (max port - min port + 1) (from the natv2PoolTable configuration information) multiplied by the number of addresses provisioned in the pool (sum of number of addresses provided by each natv2PoolRangeTable conceptual row relating to that pool). At configuration time, the thresholds can be recalculated in terms of total number of port map entries corresponding to the configured percentage, so that runtime comparisons to the current number of port map entries require no further arithmetic operations. natv2PoolTable also provides two state objects that are returned with the notifications. natv2PoolNotifiedPortMapProtocol identifies the most-mapped protocol at the time the notification was triggered. Perreault, et al. Standards Track PAGE 16

RFC 7659 NAT MIB October 2015 natv2PoolNotifiedPortMapEntries provides the total number of port map entries for that protocol using addresses owned by this pool at that same time. 3.3.7. The Address Pool Address Range Table: natv2PoolRangeTable natv2PoolRangeTable provides configuration information only. It is an expansion of natv2PoolTable giving the address ranges with which a given address pool has been configured. As such, it is indexed by the combination of NAT instance index, address pool index, and a conceptual row index, where each conceptual row conveys a different address range. The address range is specified in terms of lowest address, highest address rather than the usual prefix notation to provide maximum flexibility. 3.3.8. The Address Map Table: natv2AddressMapTable The address map table provides a table of mappings from internal to external address at a given moment. It is indexed by the combination of NAT instance index, internal realm, internal address type (IPv4 or IPv6) in that realm, the internal address of the local host for which the map entry was created, and a conceptual row index to traverse all of the entries relating to the same internal address. In the special case of DS-Lite [RFC 6333], the internal address and realm used in the index are those of the IPv6 outer header. The IPv4 source address for the inner header, for which [RFC 6333] has reserved addresses in the 192.0.0.0/29 range, is captured in two additional objects in the corresponding conceptual row: natv2AddressMapInternalMappedAddressType and natv2AddressMapInternalMappedAddress. In cases other than DS-Lite access, these objects have no meaning. (Other tunneled access is out of scope.) The additional information provided by natv2AddressMapTable consists of the external realm, address type in that realm, and mapped external address. Depending on implementation support, the table also provides the index of the address pool from which the external address was drawn and the index of the subscriber to which the map entry belongs. 3.3.9. The Port Map Table: natv2PortMapTable The port map table provides a table of mappings by protocol from external port, address, and realm to internal port, address, and realm. As such, it is indexed by the combination of NAT instance index, protocol number, external realm identifier, address type in that realm, external address, and external port. The mapping from Perreault, et al. Standards Track PAGE 17

RFC 7659 NAT MIB October 2015 external realm, address, and port to internal realm, address, and port is unique, so no conceptual row index is needed. The indexing is designed to make it easy to trace individual sessions back to the host, based on the contents of packets observed in the external realm. Beyond the indexing, the information provided by the port map table consists of the internal realm, address type, address, and port number, and, depending on implementation support, the index of the subscriber to which the map entry belongs. As with the address map table, special provision is made for the case of DS-Lite [RFC 6333]. The realm and outgoing source address are those for the outer header, and the address type is IPv6. Additional objects natv2PortMapInternalMappedAddressType and natv2PortMapInternalMappedAddress capture the outgoing source address in the inner header, which will be in the well-known 192.0.0.0/29 range. 3.4. Conformance: Three Application Scenarios The conformance statements in NATV2-MIB provide for three application scenarios: basic NAT, NAT supporting address pools, and CGN. A basic NAT MAY limit the number of NAT instances it supports to one, but it MUST support indexing by NAT instance. Similarly, a basic NAT MAY limit the number of realms it supports to two. By definition, a basic NAT is not required to support the subscriber table, the address pool table, or the address pool address range table. Some individual objects in other tables are also not relevant to basic NAT. A NAT supporting address pools adds the address pool table and the address pool address range table to what it implements. Some individual objects in other tables also need to be implemented. A NAT supporting address pools MUST support more than two realms. Finally, a CGN MUST support the full contents of the MIB module. That includes the subscriber table, but it also includes the special provision for DS-Lite access in the address and port map tables. Perreault, et al. Standards Track PAGE 18

RFC 7659 NAT MIB October 2015 4. Definitions This MIB module IMPORTs objects from [RFC 2578], [RFC 2579], [RFC 2580], [RFC 3411], and [RFC 4001]. NATV2-MIB DEFINITIONS ::= BEGIN IMPORTS MODULE-IDENTITY, OBJECT-TYPE, Integer32, Unsigned32, Counter64, mib-2, NOTIFICATION-TYPE FROM SNMPv2-SMI -- RFC 2578 TEXTUAL-CONVENTION, DisplayString, TimeStamp FROM SNMPv2-TC -- RFC 2579 MODULE-COMPLIANCE, NOTIFICATION-GROUP, OBJECT-GROUP FROM SNMPv2-CONF -- RFC 2580 SnmpAdminString FROM SNMP-FRAMEWORK-MIB -- RFC 3411 InetAddressType, InetAddress, InetAddressPrefixLength, InetPortNumber FROM INET-ADDRESS-MIB; -- RFC 4001 natv2MIB MODULE-IDENTITY LAST-UPDATED "201510020000Z" -- 2 October 2015 ORGANIZATION "IETF Behavior Engineering for Hindrance Avoidance (BEHAVE) Working Group" CONTACT-INFO "Working Group Email: behave@ietf.org Simon Perreault Jive Communications Quebec, QC Canada Email: sperreault@jive.com Perreault, et al. Standards Track PAGE 19

RFC 7659 NAT MIB October 2015 Tina Tsou Huawei Technologies Bantian, Longgang Shenzhen 518129 China Email: tina.tsou.zouting@huawei.com Senthil Sivakumar Cisco Systems 7100-8 Kit Creek Road Research Triangle Park, North Carolina 27709 United States Phone: +1 919 392 5158 Email: ssenthil@cisco.com Tom Taylor PT Taylor Consulting Ottawa Canada Email: tom.taylor.stds@gmail.com" DESCRIPTION "This MIB module defines the generic managed objects for NAT. Copyright (c) 2015 IETF Trust and the persons identified as authors of the code. All rights reserved. Redistribution and use in source and binary forms, with or without modification, is permitted pursuant to, and subject to the license terms contained in, the Simplified BSD License set forth in Section 4.c of the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info). This version of this MIB module is part of RFC 7659; see the RFC itself for full legal notices." REVISION "201510020000Z" -- 2 October 2015 DESCRIPTION "Complete rewrite, published as RFC 7659. Replaces former version published as RFC 4008." ::= { mib-2 234 } -- Textual conventions Perreault, et al. Standards Track PAGE 20

RFC 7659 NAT MIB October 2015 ProtocolNumber ::= TEXTUAL-CONVENTION DISPLAY-HINT "d" STATUS current DESCRIPTION "A protocol number, from the IANA Protocol Numbers registry." REFERENCE "IANA Protocol Numbers, <http://www.iana.org/assignments/protocol-numbers>" SYNTAX Unsigned32 (0..255) Natv2SubscriberIndex ::= TEXTUAL-CONVENTION DISPLAY-HINT "d" STATUS current DESCRIPTION "A unique value, greater than zero, for each subscriber in the managed system. The value for each subscriber MUST remain constant at least from one update of the entity's natv2SubscriberDiscontinuityTime object until the next update of that object. If a subscriber is deleted, its assigned index value MUST NOT be assigned to another subscriber at least until reinitialization of the entity's management system." SYNTAX Unsigned32 (1..4294967295) Natv2SubscriberIndexOrZero ::= TEXTUAL-CONVENTION DISPLAY-HINT "d" STATUS current DESCRIPTION "This textual convention is an extension of the Natv2SubscriberIndex convention. The latter defines a greater than zero value used to identify a subscriber in the managed system. This extension permits the additional value of zero, which serves as a placeholder when no subscriber is associated with the object." SYNTAX Unsigned32 (0|1..4294967295) Natv2InstanceIndex ::= TEXTUAL-CONVENTION DISPLAY-HINT "d" STATUS current DESCRIPTION "A unique value, greater than zero, for each NAT instance in the managed system. It is RECOMMENDED that values are assigned contiguously starting from 1. The value for each NAT instance MUST remain constant at least from one update of the entity's natv2InstanceDiscontinuityTime object until the next update of that object. If a NAT instance is deleted, its assigned index value MUST NOT Perreault, et al. Standards Track PAGE 21

RFC 7659 NAT MIB October 2015 be assigned to another NAT instance at least until reinitialization of the entity's management system." SYNTAX Unsigned32 (1..4294967295) Natv2PoolIndex ::= TEXTUAL-CONVENTION DISPLAY-HINT "d" STATUS current DESCRIPTION "A unique value over the containing NAT instance, greater than zero, for each address pool supported by that NAT instance. It is RECOMMENDED that values are assigned contiguously starting from 1. The value for each address pool MUST remain constant at least from one update of the entity's natv2PoolDiscontinuityTime object until the next update of that object. If an address pool is deleted, its assigned index value MUST NOT be assigned to another address pool for the same NAT instance at least until reinitialization of the entity's management system." SYNTAX Unsigned32 (1..4294967295) Natv2PoolIndexOrZero ::= TEXTUAL-CONVENTION DISPLAY-HINT "d" STATUS current DESCRIPTION "This textual convention is an extension of the Natv2PoolIndex convention. The latter defines a greater than zero value used to identify address pools in the managed system. This extension permits the additional value of zero, which serves as a placeholder when the implementation does not support address pools or no address pool is configured in a given external realm." SYNTAX Unsigned32 (0|1..4294967295) -- Notifications natv2MIBNotifications OBJECT IDENTIFIER ::= { natv2MIB 0 } natv2NotificationPoolUsageLow NOTIFICATION-TYPE OBJECTS { natv2PoolNotifiedPortMapEntries, natv2PoolNotifiedPortMapProtocol } STATUS current DESCRIPTION "This notification is triggered when an address pool's usage becomes less than or equal to the value of the natv2PoolThresholdUsageLow object for that pool, unless the notification has been disabled by setting the value of the threshold to -1. It is reported subject to the rate limitation specified by natv2PortMapNotificationInterval. Perreault, et al. Standards Track PAGE 22

RFC 7659 NAT MIB October 2015 Address pool usage is calculated as the percentage of the total number of ports allocated to the address pool that are already in use, for the most-mapped protocol at the time the notification is triggered. The two returned objects are members of natv2PoolTable indexed by the NAT instance and pool indices for which the event is being reported. They give the number of port map entries using external addresses configured on the pool for the most-mapped protocol and identify that protocol at the time the notification was triggered." REFERENCE "RFC 7659, Sections 3.1.2 and 3.3.6." ::= { natv2MIBNotifications 1 } natv2NotificationPoolUsageHigh NOTIFICATION-TYPE OBJECTS { natv2PoolNotifiedPortMapEntries, natv2PoolNotifiedPortMapProtocol } STATUS current DESCRIPTION "This notification is triggered when an address pool's usage becomes greater than or equal to the value of the natv2PoolThresholdUsageHigh object for that pool, unless the notification has been disabled by setting the value of the threshold to -1. It is reported subject to the rate limitation specified by natv2PortMapNotificationInterval. Address pool usage is calculated as the percentage of the total number of ports allocated to the address pool that are already in use, for the most-mapped protocol at the time the notification is triggered. The two returned objects are members of natv2PoolTable indexed by the NAT instance and pool indices for which the event is being reported. They give the number of port map entries using external addresses configured on the pool for the most-mapped protocol and identify that protocol at the time the notification was triggered." REFERENCE "RFC 7659, Sections 3.1.2 and 3.3.6." ::= { natv2MIBNotifications 2 } natv2NotificationInstanceAddressMapEntriesHigh NOTIFICATION-TYPE OBJECTS { natv2InstanceAddressMapEntries, natv2InstanceAddressMapCreations } STATUS current DESCRIPTION "This notification is triggered when the value of natv2InstanceAddressMapEntries equals or exceeds the value of the natv2InstanceThresholdAddressMapEntriesHigh object Perreault, et al. Standards Track PAGE 23

RFC 7659 NAT MIB October 2015 for the NAT instance, unless disabled by setting that threshold to -1. Reporting is subject to the rate limitation given by natv2InstanceNotificationInterval. natv2InstanceAddressMapEntries and natv2InstanceAddressMapCreations are members of table natv2InstanceTable indexed by the identifier of the NAT instance for which the event is being reported. The values reported are those observed at the moment the notification was triggered." REFERENCE "RFC 7659, Section 3.1.2." ::= { natv2MIBNotifications 3 } natv2NotificationInstancePortMapEntriesHigh NOTIFICATION-TYPE OBJECTS { natv2InstancePortMapEntries, natv2InstancePortMapCreations } STATUS current DESCRIPTION "This notification is triggered when the value of natv2InstancePortMapEntries becomes greater than or equal to the value of natv2InstanceThresholdPortMapEntriesHigh, unless disabled by setting that threshold to -1. Reporting is subject to the rate limitation given by natv2InstanceNotificationInterval. natv2InstancePortMapEntries and natv2InstancePortMapCreations are members of table natv2InstanceTable indexed by the identifier of the NAT instance for which the event is being reported. The values reported are those observed at the moment the notification was triggered." ::= { natv2MIBNotifications 4 } natv2NotificationSubscriberPortMappingEntriesHigh NOTIFICATION-TYPE OBJECTS { natv2SubscriberPortMapEntries, natv2SubscriberPortMapCreations } STATUS current DESCRIPTION "This notification is triggered when the value of natv2SubscriberPortMapEntries for an individual subscriber becomes greater than or equal to the value of the natv2SubscriberThresholdPortMapEntriesHigh object for that subscriber, unless disabled by setting that threshold to -1. Reporting is subject to the rate limitation given by natv2SubscriberNotificationInterval. Perreault, et al. Standards Track PAGE 24

RFC 7659 NAT MIB October 2015 natv2SubscriberPortMapEntries and natv2SubscriberPortMapCreations are members of table natv2SubscriberTable indexed by the subscriber for which the event is being reported. The values reported are those observed at the moment the notification was triggered." ::= { natv2MIBNotifications 5 } -- Device-level objects natv2MIBDeviceObjects OBJECT IDENTIFIER ::= { natv2MIB 1 } -- Subscriber table natv2SubscriberTable OBJECT-TYPE SYNTAX SEQUENCE OF Natv2SubscriberEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table of subscribers. As well as the subscriber index, it provides per-subscriber state and counter objects, a last discontinuity time object for the counters, and a writable threshold value and limit on port consumption." REFERENCE "RFC 7659, Section 3.3.3." ::= { natv2MIBDeviceObjects 1 } natv2SubscriberEntry OBJECT-TYPE SYNTAX Natv2SubscriberEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Each entry describes a single subscriber." INDEX { natv2SubscriberIndex } ::= { natv2SubscriberTable 1 } Natv2SubscriberEntry ::= SEQUENCE { natv2SubscriberIndex Natv2SubscriberIndex, natv2SubscriberInternalRealm SnmpAdminString, natv2SubscriberInternalPrefixType InetAddressType, natv2SubscriberInternalPrefix InetAddress, natv2SubscriberInternalPrefixLength InetAddressPrefixLength, -- State natv2SubscriberAddressMapEntries Unsigned32, natv2SubscriberPortMapEntries Unsigned32, Perreault, et al. Standards Track PAGE 25

RFC 7659 NAT MIB October 2015 -- Counters and last discontinuity time natv2SubscriberTranslations Counter64, natv2SubscriberAddressMapCreations Counter64, natv2SubscriberPortMapCreations Counter64, natv2SubscriberAddressMapFailureDrops Counter64, natv2SubscriberPortMapFailureDrops Counter64, natv2SubscriberDiscontinuityTime TimeStamp, -- Read-write controls natv2SubscriberLimitPortMapEntries Unsigned32, -- Disable notifications by setting threshold to -1 natv2SubscriberThresholdPortMapEntriesHigh Integer32, -- Disable limit by setting to 0 natv2SubscriberNotificationInterval Unsigned32 } natv2SubscriberIndex OBJECT-TYPE SYNTAX Natv2SubscriberIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "A unique value, greater than zero, for each subscriber in the managed system. The value for each subscriber MUST remain constant at least from one update of the entity's natv2SubscriberDiscontinuityTime object until the next update of that object. If a subscriber is deleted, its assigned index value MUST NOT be assigned to another subscriber at least until reinitialization of the entity's management system." ::= { natv2SubscriberEntry 1 } -- Configuration for this subscriber: realm, internal address(es) natv2SubscriberInternalRealm OBJECT-TYPE SYNTAX SnmpAdminString (SIZE(0..32)) MAX-ACCESS read-only STATUS current DESCRIPTION "The address realm to which this subscriber belongs. A realm defines an address space. All NATs support at least two realms. The default realm for subscribers is 'internal'. Administrators can set other values for individual subscribers when they are configured. The administrator MAY configure a new value of natv2SubscriberRealm at any time subsequent to initial configuration of the subscriber. If this happens, it MUST be treated as a point of discontinuity requiring an update of natv2SubscriberDiscontinuityTime. Perreault, et al. Standards Track PAGE 26

RFC 7659 NAT MIB October 2015 When the subscriber sends a packet to the NAT through a DS-Lite (RFC 6333) tunnel, this is the realm of the outer packet header source address. Other tunneled access is out of scope." REFERENCE "Address realm: RFC 2663. DS-Lite: RFC 6333." DEFVAL { "internal" } ::= { natv2SubscriberEntry 2 } natv2SubscriberInternalPrefixType OBJECT-TYPE SYNTAX InetAddressType MAX-ACCESS read-only STATUS current DESCRIPTION "Subscriber's internal prefix type. Any value other than ipv4(1) or ipv6(2) would be unexpected. In the case of DS-Lite access, this is the prefix type (IPv6(2)) used in the outer packet header." REFERENCE "DS-Lite: RFC 6333." ::= { natv2SubscriberEntry 3 } natv2SubscriberInternalPrefix OBJECT-TYPE SYNTAX InetAddress MAX-ACCESS read-only STATUS current DESCRIPTION "Prefix assigned to a subscriber's Customer Premises Equipment (CPE). The type of this prefix is given by natv2SubscriberInternalPrefixType. Source addresses of packets outgoing from the subscriber will be contained within this prefix. In the case of DS-Lite access, the source address taken from the prefix will be that of the outer header." REFERENCE "DS-Lite: RFC 6333." ::= { natv2SubscriberEntry 4 } natv2SubscriberInternalPrefixLength OBJECT-TYPE SYNTAX InetAddressPrefixLength MAX-ACCESS read-only STATUS current DESCRIPTION "Length of the prefix assigned to a subscriber's CPE, in bits. If a single address is assigned, this will be 32 for IPv4 and 128 for IPv6." ::= { natv2SubscriberEntry 5 } Perreault, et al. Standards Track PAGE 27

RFC 7659 NAT MIB October 2015 -- State objects natv2SubscriberAddressMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current number of address map entries for the subscriber, including static mappings. An address map entry maps from a given internal address and realm to an external address in a particular external realm. This definition includes 'hairpin' mappings, where the external realm is the same as the internal one. Address map entries are also tracked per instance and per address pool within the instance." REFERENCE "RFC 7659, Section 3.3.8." ::= { natv2SubscriberEntry 6 } natv2SubscriberPortMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current number of port map entries in the port map table for the subscriber, including static mappings. A port map entry maps from a given external realm, address, and port for a given protocol to an internal realm, address, and port. This definition includes 'hairpin' mappings, where the external realm is the same as the internal one. Port map entries are also tracked per instance and per protocol and address pool within the instance." REFERENCE "RFC 7659, Section 3.3.9." ::= { natv2SubscriberEntry 7 } -- Counters and last discontinuity time natv2SubscriberTranslations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of translated packets received from or sent to this subscriber. This value MUST be monotone increasing in the periods between updates of the entity's natv2SubscriberDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this Perreault, et al. Standards Track PAGE 28

RFC 7659 NAT MIB October 2015 counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2SubscriberDiscontinuityTime." ::= { natv2SubscriberEntry 8 } natv2SubscriberAddressMapCreations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of address map entries created for this subscriber, including static mappings. Address map entries are also tracked per instance and per protocol and address pool within the instance. This value MUST be monotone increasing in the periods between updates of the entity's natv2SubscriberDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2SubscriberDiscontinuityTime." ::= { natv2SubscriberEntry 9 } natv2SubscriberPortMapCreations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of port map entries created for this subscriber, including static mappings. Port map entries are also tracked per instance and per protocol and address pool within the instance. This value MUST be monotone increasing in the periods between updates of the entity's natv2SubscriberDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2SubscriberDiscontinuityTime." ::= { natv2SubscriberEntry 10 } natv2SubscriberAddressMapFailureDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current Perreault, et al. Standards Track PAGE 29

RFC 7659 NAT MIB October 2015 DESCRIPTION "The cumulative number of packets originated by this subscriber that were dropped because the packet would have triggered the creation of a new address map entry, but no address could be allocated in the selected external realm because all addresses from the selected address pool (or the whole realm, if no address pool has been configured for that realm) have already been fully allocated. This value MUST be monotone increasing in the periods between updates of the entity's natv2SubscriberDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2SubscriberDiscontinuityTime." ::= { natv2SubscriberEntry 11 } natv2SubscriberPortMapFailureDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped because the packet would have triggered the creation of a new port mapping, but no port could be allocated for the protocol concerned. The usual case for this will be for a NAT instance that supports address pooling and the 'Paired' pooling behavior recommended by RFC 4787, where the internal endpoint has used up all of the ports allocated to it for the address it was mapped to in the selected address pool in the external realm concerned and cannot be given more ports because - policy or implementation prevents it from having a second address in the same pool, and - policy or unavailability prevents it from acquiring more ports at its originally assigned address. If the NAT instance supports address pooling but its pooling behavior is 'Arbitrary' (meaning that the NAT instance can allocate a new port mapping for the given internal endpoint on any address in the selected address pool and is not bound to what it has already mapped for that endpoint), then this counter is incremented when all ports for the protocol concerned over the whole of the selected address pool are already in use. Perreault, et al. Standards Track PAGE 30

RFC 7659 NAT MIB October 2015 As a third case, if no address pools have been configured for the external realm concerned, then this counter is incremented because all ports for the protocol involved over the whole set of addresses available for that external realm are already in use. Finally, this counter is incremented if the packet would have triggered the creation of a new port mapping, but the current value of natv2SubscriberPortMapEntries equals or exceeds the value of natv2SubscriberLimitPortMapEntries for this subscriber (unless that limit is disabled). This value MUST be monotone increasing in the periods between updates of the entity's natv2SubscriberDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2SubscriberDiscontinuityTime." REFERENCE "Pooling behavior: RFC 4787, end of Section 4.1." ::= { natv2SubscriberEntry 12 } natv2SubscriberDiscontinuityTime OBJECT-TYPE SYNTAX TimeStamp MAX-ACCESS read-only STATUS current DESCRIPTION "Snapshot of the value of the sysUpTime object at the beginning of the latest period of continuity of the statistical counters associated with this subscriber." ::= { natv2SubscriberEntry 14 } -- Per-subscriber limit and threshold on port mappings -- Disabled if set to zero natv2SubscriberLimitPortMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-write STATUS current DESCRIPTION "Limit on total number of port mappings active for this subscriber (natv2SubscriberPortMapEntries). Once this limit is reached, packets that might have triggered new port mappings are dropped. The number of such packets dropped is counted in natv2InstancePortMapFailureDrops. Limit is disabled if set to zero." Perreault, et al. Standards Track PAGE 31

RFC 7659 NAT MIB October 2015 DEFVAL { 0 } ::= { natv2SubscriberEntry 15 } natv2SubscriberThresholdPortMapEntriesHigh OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-write STATUS current DESCRIPTION "Notification threshold for total number of port mappings active for this subscriber. Whenever natv2SubscriberPortMapEntries is updated, if it equals or exceeds natv2SubscriberThresholdPortMapEntriesHigh, the notification natv2NotificationSubscriberPortMappingEntriesHigh is triggered, unless the notification is disabled by setting the threshold to -1. Reporting is subject to the minimum inter-notification interval given by natv2SubscriberNotificationInterval. If multiple notifications are triggered during one interval, the agent MUST report only the one containing the highest value of natv2SubscriberPortMapEntries and discard the others." DEFVAL { -1 } ::= { natv2SubscriberEntry 16 } natv2SubscriberNotificationInterval OBJECT-TYPE SYNTAX Unsigned32 (1..3600) UNITS "Seconds" MAX-ACCESS read-write STATUS current DESCRIPTION "Minimum number of seconds between successive reporting of notifications for this subscriber. Controls the reporting of natv2NotificationSubscriberPortMappingEntriesHigh." DEFVAL { 60 } ::= { natv2SubscriberEntry 17 } -- Per-NAT-instance objects natv2MIBInstanceObjects OBJECT IDENTIFIER ::= { natv2MIB 2 } -- Instance table Perreault, et al. Standards Track PAGE 32

RFC 7659 NAT MIB October 2015 natv2InstanceTable OBJECT-TYPE SYNTAX SEQUENCE OF Natv2InstanceEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table of NAT instances. As well as state and counter objects, it provides the instance index, instance name, and the last discontinuity time object that is applicable to the counters. It also contains writable thresholds for reporting of notifications and limits on usage of resources at the level of the NAT instance. It is assumed that NAT instances can be created and deleted dynamically, but this MIB module does not provide the means to do so. For restrictions on assignment and maintenance of the NAT index instance, see the description of natv2InstanceIndex in the table below. For the requirements on maintenance of the values of the counters in this table, see the description of natv2InstanceDiscontinuityTime in this table. Each NAT instance has its own resources and behavior. The resources include memory as reflected in space for map entries, processing power as reflected in the rate of map creation and deletion, and mappable addresses in each realm that can play the role of an external realm for at least some mappings for that instance. The NAT instance table includes limits and notification thresholds that relate to memory usage for mapping at the level of the whole instance. The limit on number of subscribers with active mappings is a limit to some extent on processor usage. The mappable 'external' addresses may or may not be organized into address pools. For a definition of address pools, see the description of natv2PoolTable. If the instance does support address pools, it also has a pooling behavior. Mapping, filtering, and pooling behavior are defined in the descriptions of the natv2InstancePortMappingBehavior, natv2InstanceFilteringBehavior, and natv2InstancePoolingBehavior objects in this table. The instance also has a fragmentation behavior, defined in the description of the natv2InstanceFragmentBehavior object." REFERENCE "RFC 7659, Section 3.3.4. NAT behaviors: RFC 4787 (primary, UDP); RFC 5382 (TCP); RFC 5508 (ICMP); and RFC 5597 (Datagram Congestion Control Protocol (DCCP))." ::= { natv2MIBInstanceObjects 1 } Perreault, et al. Standards Track PAGE 33

RFC 7659 NAT MIB October 2015 natv2InstanceEntry OBJECT-TYPE SYNTAX Natv2InstanceEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Objects related to a single NAT instance." INDEX { natv2InstanceIndex } ::= { natv2InstanceTable 1 } Natv2InstanceEntry ::= SEQUENCE { natv2InstanceIndex Natv2InstanceIndex, natv2InstanceAlias DisplayString, -- Configured behaviors natv2InstancePortMappingBehavior INTEGER, natv2InstanceFilteringBehavior INTEGER, natv2InstancePoolingBehavior INTEGER, natv2InstanceFragmentBehavior INTEGER, -- State natv2InstanceAddressMapEntries Unsigned32, natv2InstancePortMapEntries Unsigned32, -- Statistics and discontinuity time natv2InstanceTranslations Counter64, natv2InstanceAddressMapCreations Counter64, natv2InstancePortMapCreations Counter64, natv2InstanceAddressMapEntryLimitDrops Counter64, natv2InstancePortMapEntryLimitDrops Counter64, natv2InstanceSubscriberActiveLimitDrops Counter64, natv2InstanceAddressMapFailureDrops Counter64, natv2InstancePortMapFailureDrops Counter64, natv2InstanceFragmentDrops Counter64, natv2InstanceOtherResourceFailureDrops Counter64, natv2InstanceDiscontinuityTime TimeStamp, -- Notification thresholds, disabled if set to -1 natv2InstanceThresholdAddressMapEntriesHigh Integer32, natv2InstanceThresholdPortMapEntriesHigh Integer32, natv2InstanceNotificationInterval Unsigned32, -- Limits, disabled if set to 0 natv2InstanceLimitAddressMapEntries Unsigned32, natv2InstanceLimitPortMapEntries Unsigned32, natv2InstanceLimitPendingFragments Unsigned32, natv2InstanceLimitSubscriberActives Unsigned32 } natv2InstanceIndex OBJECT-TYPE SYNTAX Natv2InstanceIndex MAX-ACCESS not-accessible STATUS current Perreault, et al. Standards Track PAGE 34

RFC 7659 NAT MIB October 2015 DESCRIPTION "NAT instance index. It is up to the implementation to determine which values correspond to in-service NAT instances. This object is used as an index for all tables defined below." ::= { natv2InstanceEntry 1 } natv2InstanceAlias OBJECT-TYPE SYNTAX DisplayString (SIZE (0..64)) MAX-ACCESS read-only STATUS current DESCRIPTION "This object is an 'alias' name for the NAT instance as specified by a network manager and provides a non-volatile 'handle' for the instance. An example of the value that a network manager might store in this object for a NAT instance is the name/identifier of the interface that brings in internal traffic for this NAT instance or the name of the Virtual Routing and Forwarding (VRF) for internal traffic." ::= { natv2InstanceEntry 2 } -- Configured behaviors natv2InstancePortMappingBehavior OBJECT-TYPE SYNTAX INTEGER { endpointIndependent (0), addressDependent (1), addressAndPortDependent (2) } MAX-ACCESS read-only STATUS current DESCRIPTION "Port mapping behavior is the policy governing the selection of external address and port in a given realm for a given five-tuple of source address and port, destination address and port, and protocol. endpointIndependent(0), the behavior REQUIRED by RFC 4787, REQ-1, maps the source address and port to the same external address and port for all destination address and port combinations reached through the same external realm and using the given protocol. Perreault, et al. Standards Track PAGE 35

RFC 7659 NAT MIB October 2015 addressDependent(1) maps to the same external address and port for all destination ports at the same destination address reached through the same external realm and using the given protocol. addressAndPortDependent(2) maps to a separate external address and port combination for each different destination address and port combination reached through the same external realm." REFERENCE "RFC 4787, Section 4.1." ::= { natv2InstanceEntry 3 } natv2InstanceFilteringBehavior OBJECT-TYPE SYNTAX INTEGER { endpointIndependent (0), addressDependent (1), addressAndPortDependent (2) } MAX-ACCESS read-only STATUS current DESCRIPTION "Filtering behavior is the policy governing acceptance or the dropping of packets incoming from remote sources via a given external realm and destined to a specific three-tuple of external address, port, and protocol at the NAT instance that has been assigned in a port mapping. endpointIndependent(0) accepts for translation packets from all combinations of remote address and port destined to the mapped external address and port via the given external realm and using the given protocol. addressDependent(1) accepts for translation packets from all remote ports from the same remote source address destined to the mapped external address and port via the given external realm and using the given protocol. addressAndPortDependent(2) accepts for translation only those packets with the same remote source address, port, and protocol incoming from the same external realm as identified when the applicable port map entry was created. RFC 4787, REQ-8 recommends either endpointIndependent(0) or addressDependent(1) filtering behavior depending on whether application friendliness or security takes priority." REFERENCE "RFC 4787, Section 5." Perreault, et al. Standards Track PAGE 36

RFC 7659 NAT MIB October 2015 ::= { natv2InstanceEntry 4 } natv2InstancePoolingBehavior OBJECT-TYPE SYNTAX INTEGER { arbitrary (0), paired (1) } MAX-ACCESS read-only STATUS current DESCRIPTION "Pooling behavior is the policy used to select the address for a new port mapping within a given address pool to which the internal address has already been mapped. arbitrary(0) pooling behavior means that the NAT instance may create the new port mapping using any address in the pool that has a free port for the protocol concerned. paired(1) pooling behavior, the behavior RECOMMENDED by RFC 4787, REQ-2, means that once a given internal address has been mapped to a particular address in a particular pool, further mappings of the same internal address to that pool will reuse the previously assigned pool member address." REFERENCE "RFC 4787, near the end of Section 4.1" ::= { natv2InstanceEntry 5 } natv2InstanceFragmentBehavior OBJECT-TYPE SYNTAX INTEGER { fragmentNone (0), fragmentInOrder (1), fragmentOutOfOrder (2) } MAX-ACCESS read-only STATUS current DESCRIPTION "Fragment behavior is the NAT instance's capability to receive and translate fragments incoming from remote sources. fragmentNone(0) implies no capability to translate incoming fragments, so all received fragments are dropped. Each dropped fragment is counted in natv2InstanceFragmentDrops. fragmentInOrder(1) implies the ability to translate fragments only if they are received in order, so that in particular the header is in the first packet. If a fragment Perreault, et al. Standards Track PAGE 37

RFC 7659 NAT MIB October 2015 is received out of order, it is dropped and counted in natv2InstanceFragmentDrops. fragmentOutOfOrder(2), the capability REQUIRED by RFC 4787, REQ-14, implies the capability to translate fragments even when they arrive out of order, subject to a protective limit natv2InstanceLimitPendingFragments on total number of fragments awaiting the first fragment of the chain. If the implementation supports this capability, natv2InstanceFragmentDrops is incremented only when a new fragment arrives but is dropped because the limit on pending fragments has already been reached." REFERENCE "RFC 4787, Section 11." ::= { natv2InstanceEntry 6 } -- State natv2InstanceAddressMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current number of address map entries in total over the whole NAT instance, including static mappings. An address map entry maps from a given internal address and realm to an external address in a particular external realm. This definition includes 'hairpin' mappings, where the external realm is the same as the internal one. Address map entries are also tracked per subscriber and per address pool within the instance." REFERENCE "RFC 7659, Section 3.3.8. Hairpinning: RFC 4787, Section 6." ::= { natv2InstanceEntry 7 } natv2InstancePortMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current number of entries in the port map table in total over the whole NAT instance, including static mappings. A port map entry maps from a given external realm, address, and port for a given protocol to an internal realm, address, and port. This definition includes 'hairpin' mappings, where the external realm is the same as the internal one. Port map Perreault, et al. Standards Track PAGE 38

RFC 7659 NAT MIB October 2015 entries are also tracked per subscriber and per protocol and address pool within the instance." REFERENCE "RFC 7659, Section 3.3.9. Hairpinning: RFC 4787, Section 6." ::= { natv2InstanceEntry 8 } -- Statistics natv2InstanceTranslations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of translated packets passing through this NAT instance. This value MUST be monotone increasing in the periods between updates of natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2InstanceEntry 9 } natv2InstanceAddressMapCreations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of address map entries created by the NAT instance, including static mappings. Address map creations are also tracked per address pool within the instance and per subscriber. This value MUST be monotone increasing in the periods between updates of natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2InstanceEntry 10 } natv2InstancePortMapCreations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current Perreault, et al. Standards Track PAGE 39

RFC 7659 NAT MIB October 2015 DESCRIPTION "The cumulative number of port map entries created by the NAT instance, including static mappings. Port map creations are also tracked per protocol and address pool within the instance and per subscriber. This value MUST be monotone increasing in the periods between updates of natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2InstanceEntry 11 } natv2InstanceAddressMapEntryLimitDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped rather than translated because the packet would have triggered the creation of a new address map entry, but the limit on number of address map entries for the NAT instance given by natv2InstanceLimitAddressMapEntries has already been reached. This value MUST be monotone increasing in the periods between updates of the entity's natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2InstanceEntry 12 } natv2InstancePortMapEntryLimitDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped rather than translated because the packet would have triggered the creation of a new port map entry, but the limit on number of port map entries for the NAT instance given by natv2InstanceLimitPortMapEntries has already been reached. Perreault, et al. Standards Track PAGE 40

RFC 7659 NAT MIB October 2015 This value MUST be monotone increasing in the periods between updates of the entity's natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2InstanceEntry 13 } natv2InstanceSubscriberActiveLimitDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped rather than translated because the packet would have triggered the creation of a new mapping for a subscriber with no other active mappings, but the limit on number of active subscribers for the NAT instance given by natv2InstanceLimitSubscriberActives has already been reached. This value MUST be monotone increasing in the periods between updates of the entity's natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2InstanceEntry 14 } natv2InstanceAddressMapFailureDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped because the packet would have triggered the creation of a new address map entry, but no address could be allocated in the selected external realm because all addresses from the selected address pool (or the whole realm, if no address pool has been configured for that realm) have already been fully allocated. This value MUST be monotone increasing in the periods between updates of the entity's natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this Perreault, et al. Standards Track PAGE 41

RFC 7659 NAT MIB October 2015 counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2InstanceEntry 15 } natv2InstancePortMapFailureDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped because the packet would have triggered the creation of a new port map entry, but no port could be allocated for the protocol concerned. The usual case for this will be for a NAT instance that supports address pooling and the 'Paired' pooling behavior recommended by RFC 4787, where the internal endpoint has used up all of the ports allocated to it for the address it was mapped to in the selected address pool in the external realm concerned and cannot be given more ports because - policy or implementation prevents it from having a second address in the same pool, and - policy or unavailability prevents it from acquiring more ports at its originally assigned address. If the NAT instance supports address pooling but its pooling behavior is 'Arbitrary' (meaning that the NAT instance can allocate a new port mapping for the given internal endpoint on any address in the selected address pool and is not bound to what it has already mapped for that endpoint), then this counter is incremented when all ports for the protocol concerned over the whole of the selected address pool are already in use. Finally, if no address pools have been configured for the external realm concerned, then this counter is incremented because all ports for the protocol involved over the whole set of addresses available for that external realm are already in use. This value MUST be monotone increasing in the periods between updates of the entity's natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." Perreault, et al. Standards Track PAGE 42

RFC 7659 NAT MIB October 2015 REFERENCE "Pooling behavior: RFC 4787, end of Section 4.1." ::= { natv2InstanceEntry 16 } natv2InstanceFragmentDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of fragments received by the NAT instance but dropped rather than translated. When the NAT instance supports the 'Receive Fragment Out of Order' capability as required by RFC 4787, this occurs because the fragment was received out of order and would be added to the queue of fragments awaiting the initial fragment of the chain, but the queue has already reached the limit set by natv2InstanceLimitsPendingFragments. Counting in other cases is specified in the description of natv2InstanceFragmentBehavior. This value MUST be monotone increasing in the periods between updates of the entity's natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." REFERENCE "RFC 4787, Section 11." ::= { natv2InstanceEntry 17 } natv2InstanceOtherResourceFailureDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped because of unavailability of a resource other than an address or port that would have been required to process it. The most likely case is where the upper-layer protocol in the packet is not supported by the NAT instance. This value MUST be monotone increasing in the periods between updates of the entity's natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved Perreault, et al. Standards Track PAGE 43

RFC 7659 NAT MIB October 2015 before the new value of natv2InstanceDiscontinuityTime." ::= { natv2InstanceEntry 18 } natv2InstanceDiscontinuityTime OBJECT-TYPE SYNTAX TimeStamp MAX-ACCESS read-only STATUS current DESCRIPTION "Snapshot of the value of the sysUpTime object at the beginning of the latest period of continuity of the statistical counters associated with this NAT instance." ::= { natv2InstanceEntry 19 } -- Notification thresholds, disabled by setting to -1. natv2InstanceThresholdAddressMapEntriesHigh OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-write STATUS current DESCRIPTION "Notification threshold for total number of address map entries held by this NAT instance. Whenever natv2InstanceAddressMapEntries is updated, if it equals or exceeds natv2InstanceThresholdAddressMapEntriesHigh, then natv2NotificationInstanceAddressMapEntriesHigh may be triggered, unless the notification is disabled by setting the threshold to -1. Reporting is subject to the minimum inter-notification interval given by natv2InstanceNotificationInterval. If multiple notifications are triggered during one interval, the agent MUST report only the one containing the highest value of natv2InstanceAddressMapEntries and discard the others." DEFVAL { -1 } ::= { natv2InstanceEntry 20 } natv2InstanceThresholdPortMapEntriesHigh OBJECT-TYPE SYNTAX Integer32 MAX-ACCESS read-write STATUS current DESCRIPTION "Notification threshold for total number of port map entries held by this NAT instance. Whenever natv2InstancePortMapEntries is updated, if it equals or exceeds natv2InstanceThresholdPortMapEntriesHigh, then natv2NotificationInstancePortMapEntriesHigh may be triggered, unless the notification is disabled by setting the threshold to -1. Reporting is subject to the minimum Perreault, et al. Standards Track PAGE 44

RFC 7659 NAT MIB October 2015 inter-notification interval given by natv2InstanceNotificationInterval. If multiple notifications are triggered during one interval, the agent MUST report only the one containing the highest value of natv2InstancePortMapEntries and discard the others." DEFVAL { -1 } ::= { natv2InstanceEntry 21 } natv2InstanceNotificationInterval OBJECT-TYPE SYNTAX Unsigned32 (1..3600) UNITS "Seconds" MAX-ACCESS read-write STATUS current DESCRIPTION "Minimum number of seconds between successive notifications for this NAT instance. Controls the reporting of natv2NotificationInstanceAddressMapEntriesHigh and natv2NotificationInstancePortMapEntriesHigh." DEFVAL { 10 } ::= { natv2InstanceEntry 22 } -- Limits, disabled if set to 0 natv2InstanceLimitAddressMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-write STATUS current DESCRIPTION "Limit on total number of address map entries supported by the NAT instance. When natv2InstanceAddressMapEntries has reached this limit, subsequent packets that would normally trigger creation of a new address map entry will be dropped and counted in natv2InstanceAddressMapEntryLimitDrops. Warning of an approach to this limit can be achieved by setting natv2InstanceThresholdAddressMapEntriesHigh to a non-zero value, for example, 80% of the limit. The limit is disabled by setting its value to zero. For further information, please see the descriptions of natv2NotificationInstanceAddressMapEntriesHigh and natv2InstanceAddressMapEntries." DEFVAL { 0 } ::= { natv2InstanceEntry 23 } Perreault, et al. Standards Track PAGE 45

RFC 7659 NAT MIB October 2015 natv2InstanceLimitPortMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-write STATUS current DESCRIPTION "Limit on total number of port map entries supported by the NAT instance. When natv2InstancePortMapEntries has reached this limit, subsequent packets that would normally trigger creation of a new port map entry will be dropped and counted in natv2InstancePortMapEntryLimitDrops. Warning of an approach to this limit can be achieved by setting natv2InstanceThresholdPortMapEntriesHigh to a non-zero value, for example, 80% of the limit. The limit is disabled by setting its value to zero. For further information, please see the descriptions of natv2NotificationInstancePortMapEntriesHigh and natv2InstancePortMapEntries." DEFVAL { 0 } ::= { natv2InstanceEntry 24 } natv2InstanceLimitPendingFragments OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-write STATUS current DESCRIPTION "Limit on number of out-of-order fragments received by the NAT instance from remote sources and held until head of chain appears. While the number of held fragments is at this limit, subsequent packets that contain fragments not relating to those already held will be dropped and counted in natv2InstancePendingFragmentLimitDrops. The limit is disabled by setting the value to zero. Applicable only when the NAT instance supports 'Receive Fragments Out of Order' behavior; leave at default otherwise. See the description of natv2InstanceFragmentBehavior." REFERENCE "RFC 4787, Section 11." DEFVAL { 0 } ::= { natv2InstanceEntry 25 } natv2InstanceLimitSubscriberActives OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-write STATUS current Perreault, et al. Standards Track PAGE 46

RFC 7659 NAT MIB October 2015 DESCRIPTION "Limit on number of total number of active subscribers supported by the NAT instance. An active subscriber is defined as any subscriber with at least one map entry, including static mappings. While the number of active subscribers is at this limit, subsequent packets that would otherwise trigger first mappings for newly active subscribers will be dropped and counted in natv2InstanceSubscriberActiveLimitDrops. The limit is disabled by setting the value to zero." DEFVAL { 0 } ::= { natv2InstanceEntry 26 } -- Table of counters per upper-layer protocol identified by the -- packet header and supported by the NAT instance. natv2ProtocolTable OBJECT-TYPE SYNTAX SEQUENCE OF Natv2ProtocolEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table of protocols with per-protocol counters. Conceptual rows of the table are indexed by the combination of the NAT instance number and the IANA-assigned upper-layer protocol number as given by the ProtocolNumber Textual Convention (TC) and contained in the packet IP header. It is up to the agent implementation to determine and operate upon only those upper-layer protocol numbers supported by the NAT instance." REFERENCE "RFC 7659, Section 3.3.5." ::= { natv2MIBInstanceObjects 2 } natv2ProtocolEntry OBJECT-TYPE SYNTAX Natv2ProtocolEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Per-protocol counters." INDEX { natv2ProtocolInstanceIndex, natv2ProtocolNumber } ::= { natv2ProtocolTable 1 } Natv2ProtocolEntry ::= SEQUENCE { natv2ProtocolInstanceIndex Natv2InstanceIndex, natv2ProtocolNumber ProtocolNumber, Perreault, et al. Standards Track PAGE 47

RFC 7659 NAT MIB October 2015 -- State natv2ProtocolPortMapEntries Unsigned32, -- Statistics. Discontinuity object from instance table reused here. natv2ProtocolTranslations Counter64, natv2ProtocolPortMapCreations Counter64, natv2ProtocolPortMapFailureDrops Counter64 } natv2ProtocolInstanceIndex OBJECT-TYPE SYNTAX Natv2InstanceIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "NAT instance index. It is up to the implementation to determine and operate upon only those values that correspond to in-service NAT instances." ::= { natv2ProtocolEntry 1 } natv2ProtocolNumber OBJECT-TYPE SYNTAX ProtocolNumber MAX-ACCESS not-accessible STATUS current DESCRIPTION "Counters in this conceptual row apply to packets indicating the upper-layer protocol identified by the value of this object. It is up to the implementation to determine and operate upon only those values that correspond to protocols supported by the NAT instance." REFERENCE "RFC 7659, Section 3.3.5. IANA Protocol Numbers, <http://www.iana.org/assignments/protocol-numbers>" ::= { natv2ProtocolEntry 2 } -- State natv2ProtocolPortMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current number of entries in the port map table in total over the whole NAT instance for a given protocol, including static mappings. A port map entry maps from a given external realm, address, and port for a given protocol to an internal realm, address, and port. This definition includes 'hairpin' mappings, where the external realm is the same as the internal one. Port map entries are also tracked per subscriber, per instance, and per address pool within the Perreault, et al. Standards Track PAGE 48

RFC 7659 NAT MIB October 2015 instance." REFERENCE "RFC 7659, Sections 3.3.5 and 3.3.9. Hairpinning: RFC 4787, Section 6." ::= { natv2ProtocolEntry 3 } -- Statistics natv2ProtocolTranslations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets translated by the NAT instance in either direction for the given protocol. This value MUST be monotone increasing in the periods between updates of the NAT instance natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2ProtocolEntry 4 } natv2ProtocolPortMapCreations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of port map entries created by the NAT instance for the given protocol. This value MUST be monotone increasing in the periods between updates of the NAT instance natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." ::= { natv2ProtocolEntry 5 } natv2ProtocolPortMapFailureDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped because the packet would have triggered the creation of a new port map entry, Perreault, et al. Standards Track PAGE 49

RFC 7659 NAT MIB October 2015 but no port could be allocated for the protocol concerned. The usual case for this will be for a NAT instance that supports address pooling and the 'Paired' pooling behavior recommended by RFC 4787, where the internal endpoint has used up all of the ports allocated to it for the address it was mapped to in the selected address pool in the external realm concerned and cannot be given more ports because - policy or implementation prevents it from having a second address in the same pool, and - policy or unavailability prevents it from acquiring more ports at its originally assigned address. If the NAT instance supports address pooling but its pooling behavior is 'Arbitrary' (meaning that the NAT instance can allocate a new port mapping for the given internal endpoint on any address in the selected address pool and is not bound to what it has already mapped for that endpoint), then this counter is incremented when all ports for the protocol concerned over the whole of the selected address pool are already in use. Finally, if the NAT instance has no configured address pooling, then this counter is incremented because all ports for the protocol concerned over the whole of the NAT instance for the external realm concerned are already in use. This value MUST be monotone increasing in the periods between updates of the NAT instance natv2InstanceDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2InstanceDiscontinuityTime." REFERENCE "RFC 4787, end of Section 4.1." ::= { natv2ProtocolEntry 6 } -- pools natv2PoolTable OBJECT-TYPE SYNTAX SEQUENCE OF Natv2PoolEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table of address pools, applicable only if these are supported by the NAT instance. An address pool is a set of Perreault, et al. Standards Track PAGE 50

RFC 7659 NAT MIB October 2015 addresses and ports in a particular realm, available for assignment to the 'external' portion of a mapping. Where more than one pool has been configured for the realm, policy determines which subscribers and/or services are mapped to which pool. natv2PoolTable provides basic information, state, statistics, and two notification thresholds for each pool. natv2PoolRangeTable is an expansion table for natv2PoolTable that identifies particular address ranges allocated to the pool." REFERENCE "RFC 7659, Section 3.3.6." ::= { natv2MIBInstanceObjects 3 } natv2PoolEntry OBJECT-TYPE SYNTAX Natv2PoolEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Entry in the table of address pools." INDEX { natv2PoolInstanceIndex, natv2PoolIndex } ::= { natv2PoolTable 1 } Natv2PoolEntry ::= SEQUENCE { -- Index natv2PoolInstanceIndex Natv2InstanceIndex, natv2PoolIndex Natv2PoolIndex, -- Configuration natv2PoolRealm SnmpAdminString, natv2PoolAddressType InetAddressType, natv2PoolMinimumPort InetPortNumber, natv2PoolMaximumPort InetPortNumber, -- State natv2PoolAddressMapEntries Unsigned32, natv2PoolPortMapEntries Unsigned32, -- Statistics and discontinuity time natv2PoolAddressMapCreations Counter64, natv2PoolPortMapCreations Counter64, natv2PoolAddressMapFailureDrops Counter64, natv2PoolPortMapFailureDrops Counter64, natv2PoolDiscontinuityTime TimeStamp, -- Notification thresholds and objects returned by notifications natv2PoolThresholdUsageLow Integer32, natv2PoolThresholdUsageHigh Integer32, natv2PoolNotifiedPortMapEntries Unsigned32, natv2PoolNotifiedPortMapProtocol ProtocolNumber, natv2PoolNotificationInterval Unsigned32 } Perreault, et al. Standards Track PAGE 51

RFC 7659 NAT MIB October 2015 natv2PoolInstanceIndex OBJECT-TYPE SYNTAX Natv2InstanceIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "NAT instance index. It is up to the agent implementation to determine and operate upon only those values that correspond to in-service NAT instances." ::= { natv2PoolEntry 1 } natv2PoolIndex OBJECT-TYPE SYNTAX Natv2PoolIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "Index of an address pool that is unique for a given NAT instance. It is up to the agent implementation to determine and operate upon only those values that correspond to provisioned pools." ::= { natv2PoolEntry 2 } -- Configuration natv2PoolRealm OBJECT-TYPE SYNTAX SnmpAdminString (SIZE (0..32)) MAX-ACCESS read-only STATUS current DESCRIPTION "Address realm to which this pool's addresses belong." REFERENCE "Address realms are discussed in Section 3.3.3 of RFC 7659. The primary reference is RFC 2663, Section 2.1." ::= { natv2PoolEntry 3 } natv2PoolAddressType OBJECT-TYPE SYNTAX InetAddressType MAX-ACCESS read-only STATUS current DESCRIPTION "Address type supplied by this address pool. This will be the same for all pools in a given realm (by definition of an address realm). Values other than ipv4(1) or ipv6(2) would be unexpected." REFERENCE "InetAddressType in RFC 4001." ::= { natv2PoolEntry 4 } natv2PoolMinimumPort OBJECT-TYPE SYNTAX InetPortNumber Perreault, et al. Standards Track PAGE 52

RFC 7659 NAT MIB October 2015 MAX-ACCESS read-only STATUS current DESCRIPTION "Minimum port number of the range that can be allocated in this pool. Applies to all protocols supported by the NAT instance." REFERENCE "InetPortNumber in RFC 4001." ::= { natv2PoolEntry 5 } natv2PoolMaximumPort OBJECT-TYPE SYNTAX InetPortNumber MAX-ACCESS read-only STATUS current DESCRIPTION "Maximum port number of the range that can be allocated in this pool. Applies to all protocols supported by the NAT instance." REFERENCE "InetPortNumber in RFC 4001." ::= { natv2PoolEntry 6 } -- State natv2PoolAddressMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current number of address map entries using external addresses drawn from this pool, including static mappings. This definition includes 'hairpin' mappings, where the external realm is the same as the internal one. Address map entries are also tracked per subscriber and per instance." REFERENCE "RFC 7659, Section 3.3.8. Hairpinning: RFC 4787, Section 6." ::= { natv2PoolEntry 7 } natv2PoolPortMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS read-only STATUS current DESCRIPTION "The current number of entries in the port map table using external addresses and ports drawn from this pool, including static mappings. This definition includes 'hairpin' mappings, where the external realm is the same as the internal one. Port map entries are also tracked per Perreault, et al. Standards Track PAGE 53

RFC 7659 NAT MIB October 2015 subscriber, per instance, and per protocol within the instance." REFERENCE "RFC 7659, Section 3.3.9. Hairpinning: RFC 4787, Section 6." ::= { natv2PoolEntry 8 } -- Statistics and discontinuity time natv2PoolAddressMapCreations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of address map entries created in this pool, including static mappings. Address map entries are also tracked per instance and per subscriber. This value MUST be monotone increasing in the periods between updates of the entity's natv2PoolDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2PoolDiscontinuityTime." ::= { natv2PoolEntry 9 } natv2PoolPortMapCreations OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of port map entries created in this pool, including static mappings. Port map entries are also tracked per instance, per protocol, and per subscriber. This value MUST be monotone increasing in the periods between updates of the entity's natv2PoolDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2PoolDiscontinuityTime." ::= { natv2PoolEntry 10 } natv2PoolAddressMapFailureDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current Perreault, et al. Standards Track PAGE 54

RFC 7659 NAT MIB October 2015 DESCRIPTION "The cumulative number of packets originated by the subscriber that were dropped because the packet would have triggered the creation of a new address map entry, but no address could be allocated from this address pool because all addresses in the pool have already been fully allocated. Counters of this event are also provided per instance, per protocol, and per subscriber. This value MUST be monotone increasing in the periods between updates of the entity's natv2PoolDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2PoolDiscontinuityTime." ::= { natv2PoolEntry 11 } natv2PoolPortMapFailureDrops OBJECT-TYPE SYNTAX Counter64 MAX-ACCESS read-only STATUS current DESCRIPTION "The cumulative number of packets dropped because the packet would have triggered the creation of a new port map entry, but no port could be allocated for the protocol concerned. The usual case for this will be for a NAT instance that supports the 'Paired' pooling behavior recommended by RFC 4787, where the internal endpoint has used up all of the ports allocated to it for the address it was mapped to in this pool and cannot be given more ports because - policy or implementation prevents it from having a second address in the same pool, and - policy or unavailability prevents it from acquiring more ports at its originally assigned address. If the NAT instance pooling behavior is 'Arbitrary' (meaning that the NAT instance can allocate a new port mapping for the given internal endpoint on any address in the selected address pool and is not bound to what it has already mapped for that endpoint), then this counter is incremented when all ports for the protocol concerned over the whole of this address pool are already in use. This value MUST be monotone increasing in the periods between updates of the entity's natv2PoolDiscontinuityTime. If a manager detects a change in the latter since the last time it sampled this Perreault, et al. Standards Track PAGE 55

RFC 7659 NAT MIB October 2015 counter, it SHOULD NOT make use of the difference between the latest value of the counter and any value retrieved before the new value of natv2PoolDiscontinuityTime." REFERENCE "Pooling behavior: RFC 4787, end of Section 4.1." ::= { natv2PoolEntry 12 } natv2PoolDiscontinuityTime OBJECT-TYPE SYNTAX TimeStamp MAX-ACCESS read-only STATUS current DESCRIPTION "Snapshot of the value of the sysUpTime object at the beginning of the latest period of continuity of the statistical counters associated with this address pool. This MUST be initialized when the address pool is configured and MUST be updated whenever the port or address ranges allocated to the pool change." ::= { natv2PoolEntry 13 } -- Notification thresholds and objects returned by notifications natv2PoolThresholdUsageLow OBJECT-TYPE SYNTAX Integer32 (-1|0..100) UNITS "Percent" MAX-ACCESS read-write STATUS current DESCRIPTION "Threshold for reporting low utilization of the address pool. Utilization at a given instant is calculated as the percentage of ports allocated in port map entries for the most-used protocol at that instant. If utilization is less than or equal to natv2PoolThresholdUsageLow, an instance of natv2NotificationPoolUsageLow may be triggered, unless disabled by setting it to -1. Reporting is subject to the per-pool notification interval given by natv2PoolNotificationInterval. If multiple notifications are triggered during one interval, the agent MUST report only the one with the lowest value of natv2PoolNotifiedPortMapEntries and discard the others. Implementation note: the percentage specified by this object can be converted to a number of port map entries at configuration time (after port and address ranges have been configured or reconfigured) and compared to the current value of natv2PoolNotifiedPortMapEntries." REFERENCE "RFC 7659, Sections 3.1.2 and 3.3.6." Perreault, et al. Standards Track PAGE 56

RFC 7659 NAT MIB October 2015 DEFVAL { -1 } ::= { natv2PoolEntry 14 } natv2PoolThresholdUsageHigh OBJECT-TYPE SYNTAX Integer32 (-1|0..100) UNITS "Percent" MAX-ACCESS read-write STATUS current DESCRIPTION "Threshold for reporting high utilization of the address pool. Utilization at a given instant is calculated as the percentage of ports allocated in port map entries for the most-used protocol at that instant. If utilization is greater than or equal to natv2PoolThresholdUsageHigh, an instance of natv2NotificationPoolUsageHigh may be triggered, unless disabled by setting it to -1. Reporting is subject to the per-pool notification interval given by natv2PoolNotificationInterval. If multiple notifications are triggered during one interval, the agent MUST report only the one with the highest value of natv2PoolNotifiedPortMapEntries and discard the others. In the rare case where both upper and lower thresholds are crossed in the same interval, the agent MUST report only the upper-threshold notification. Implementation note: the percentage specified by this object can be converted to a number of port map entries at configuration time (after port and address ranges have been configured or reconfigured) and compared to the current value of natv2PoolNotifiedPortMapEntries." DEFVAL { -1 } ::= { natv2PoolEntry 15 } natv2PoolNotifiedPortMapEntries OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS accessible-for-notify STATUS current DESCRIPTION "Number of port map entries using addresses and ports from this address pool for the most-used protocol at a given instant. One of the objects returned by natv2NotificationPoolUsageLow and natv2NotificationPoolUsageHigh." ::= { natv2PoolEntry 16 } natv2PoolNotifiedPortMapProtocol OBJECT-TYPE SYNTAX ProtocolNumber Perreault, et al. Standards Track PAGE 57

RFC 7659 NAT MIB October 2015 MAX-ACCESS accessible-for-notify STATUS current DESCRIPTION "The most-used protocol (i.e., with the largest number of port map entries) mapped into this address pool at a given instant. One of the objects returned by natv2NotificationPoolUsageLow and natv2NotificationPoolUsageHigh." ::= { natv2PoolEntry 17 } natv2PoolNotificationInterval OBJECT-TYPE SYNTAX Unsigned32 (1..3600) UNITS "Seconds" MAX-ACCESS read-write STATUS current DESCRIPTION "Minimum number of seconds between successive notifications for this address pool. Controls the generation of natv2NotificationPoolUsageLow and natv2NotificationPoolUsageHigh." DEFVAL { 20 } ::= { natv2PoolEntry 18 } natv2PoolRangeTable OBJECT-TYPE SYNTAX SEQUENCE OF Natv2PoolRangeEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "This table contains address ranges used by pool entries. It is an expansion of natv2PoolTable." REFERENCE "RFC 7659, Section 3.3.7." ::= { natv2MIBInstanceObjects 4 } natv2PoolRangeEntry OBJECT-TYPE SYNTAX Natv2PoolRangeEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "NAT pool address range." INDEX { natv2PoolRangeInstanceIndex, natv2PoolRangePoolIndex, natv2PoolRangeRowIndex } Perreault, et al. Standards Track PAGE 58

RFC 7659 NAT MIB October 2015 ::= { natv2PoolRangeTable 1 } Natv2PoolRangeEntry ::= SEQUENCE { natv2PoolRangeInstanceIndex Natv2InstanceIndex, natv2PoolRangePoolIndex Natv2PoolIndex, natv2PoolRangeRowIndex Unsigned32, natv2PoolRangeBegin InetAddress, natv2PoolRangeEnd InetAddress } natv2PoolRangeInstanceIndex OBJECT-TYPE SYNTAX Natv2InstanceIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "Index of the NAT instance on which the address pool and this address range are configured. See Natv2InstanceIndex." ::= { natv2PoolRangeEntry 1 } natv2PoolRangePoolIndex OBJECT-TYPE SYNTAX Natv2PoolIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "Index of the address pool to which this address range belongs. See Natv2PoolIndex." ::= { natv2PoolRangeEntry 2 } natv2PoolRangeRowIndex OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS not-accessible STATUS current DESCRIPTION "Row index for successive range entries for the same address pool." ::= { natv2PoolRangeEntry 3 } natv2PoolRangeBegin OBJECT-TYPE SYNTAX InetAddress MAX-ACCESS read-only STATUS current DESCRIPTION "Lowest address included in this range. The type of address (IPv4 or IPv6) is given by natv2PoolAddressType in natv2PoolTable." ::= { natv2PoolRangeEntry 4 } Perreault, et al. Standards Track PAGE 59

RFC 7659 NAT MIB October 2015 natv2PoolRangeEnd OBJECT-TYPE SYNTAX InetAddress MAX-ACCESS read-only STATUS current DESCRIPTION "Highest address included in this range. The type of address (IPv4 or IPv6) is given by natv2PoolAddressType in natv2PoolTable." ::= { natv2PoolRangeEntry 5 } -- Indexed mapping tables -- Address Map Table. Mapped from the internal to external address. natv2AddressMapTable OBJECT-TYPE SYNTAX SEQUENCE OF Natv2AddressMapEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table of mappings from the internal to external address. By definition, this is a snapshot of NAT instance state at a given moment. Indexed by NAT instance, internal realm, and internal address in that realm. Provides the mapped external address and, depending on implementation support, identifies the address pool from which the external address and port were taken and the index of the subscriber to which the mapping has been allocated. In the case of DS-Lite (RFC 6333), the indexing realm and address are those of the IPv6 encapsulation rather than the IPv4 inner packet." REFERENCE "RFC 7659, Section 3.3.8. DS-Lite: RFC 6333" ::= { natv2MIBInstanceObjects 5 } natv2AddressMapEntry OBJECT-TYPE SYNTAX Natv2AddressMapEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Mapping from internal to external address." INDEX { natv2AddressMapInstanceIndex, natv2AddressMapInternalRealm, natv2AddressMapInternalAddressType, natv2AddressMapInternalAddress, natv2AddressMapRowIndex } ::= { natv2AddressMapTable 1 } Perreault, et al. Standards Track PAGE 60

RFC 7659 NAT MIB October 2015 Natv2AddressMapEntry ::= SEQUENCE { natv2AddressMapInstanceIndex Natv2InstanceIndex, natv2AddressMapInternalRealm SnmpAdminString, natv2AddressMapInternalAddressType InetAddressType, natv2AddressMapInternalAddress InetAddress, natv2AddressMapRowIndex Unsigned32, natv2AddressMapInternalMappedAddressType InetAddressType, natv2AddressMapInternalMappedAddress InetAddress, natv2AddressMapExternalRealm SnmpAdminString, natv2AddressMapExternalAddressType InetAddressType, natv2AddressMapExternalAddress InetAddress, natv2AddressMapExternalPoolIndex Natv2PoolIndexOrZero, natv2AddressMapSubscriberIndex Natv2SubscriberIndexOrZero } natv2AddressMapInstanceIndex OBJECT-TYPE SYNTAX Natv2InstanceIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "Index of the NAT instance that generated this address map." ::= { natv2AddressMapEntry 1 } natv2AddressMapInternalRealm OBJECT-TYPE SYNTAX SnmpAdminString (SIZE(0..32)) MAX-ACCESS not-accessible STATUS current DESCRIPTION "Realm to which the internal address belongs. In most cases, this is the realm defining the address space of the packet being translated. However, in the case of DS-Lite (RFC 6333), this realm defines the IPv6 outer header address space. It is the combination of that outer header and the inner IPv4 packet header that is remapped to the external address and realm. The corresponding IPv4 realm is restricted in scope to the tunnel, so there is no point in identifying it. The mapped IPv4 address will normally be the well-known value 192.0.0.2, or at least lie in the reserved 192.0.0.0/29 range. If natv2AddressMapSubscriberIndex in this table is a valid subscriber index (i.e., greater than zero), then the value of natv2AddressMapInternalRealm MUST be identical to the value of natv2SubscriberRealm associated with that index." REFERENCE "DS-Lite: RFC 6333, Sections 5.7 (for well-known addresses) and 6.6 (on the need to have the IPv6 tunnel address in Perreault, et al. Standards Track PAGE 61

RFC 7659 NAT MIB October 2015 the NAT mapping tables)." ::= { natv2AddressMapEntry 2 } natv2AddressMapInternalAddressType OBJECT-TYPE SYNTAX InetAddressType MAX-ACCESS not-accessible STATUS current DESCRIPTION "Address type in the header of packets on the interior side of this mapping. Any value other than ipv4(1) or ipv6(2) would be unexpected. In the DS-Lite case, the address type is ipv6(2)." REFERENCE "DS-Lite: RFC 6333, Sections 5.7 (for well-known addresses) and 6.6 (on the need to have the IPv6 tunnel source address in the NAT mapping tables)." ::= { natv2AddressMapEntry 3 } natv2AddressMapInternalAddress OBJECT-TYPE SYNTAX InetAddress (SIZE (0..16)) MAX-ACCESS not-accessible STATUS current DESCRIPTION "Source address of packets originating from the interior of the association provided by this mapping. The address type is given by natv2AddressMapInternalAddressType. In the case of DS-Lite (RFC 6333), this is the IPv6 tunnel source address. The mapping in this case is considered to be from the combination of the IPv6 tunnel source address natv2AddressMapInternalRealmAddress and the well-known IPv4 inner source address natv2AddressMapInternalMappedAddress to the external address." REFERENCE "DS-Lite: RFC 6333, Sections 5.7 (for well-known addresses) and 6.6 (on the need to have the IPv6 tunnel address in the NAT mapping tables)." ::= { natv2AddressMapEntry 4 } natv2AddressMapRowIndex OBJECT-TYPE SYNTAX Unsigned32 MAX-ACCESS not-accessible STATUS current DESCRIPTION "Index of a conceptual row corresponding to a mapping of the given internal realm and address to a single external realm and address. Multiple rows will be present because of a Perreault, et al. Standards Track PAGE 62

RFC 7659 NAT MIB October 2015 promiscuous external address selection policy, policies associating the same internal address with different address pools, or because the same internal realm-address combination is communicating with multiple external address realms." ::= { natv2AddressMapEntry 5 } natv2AddressMapInternalMappedAddressType OBJECT-TYPE SYNTAX InetAddressType MAX-ACCESS read-only STATUS current DESCRIPTION "Internal address type actually translated by this mapping. Any value other than ipv4(1) or ipv6(2) would be unexpected. In the general case, this is the same as given by natv2AddressMapInternalRealmAddressType. In the tunneled case, it is the address type used in the encapsulated packet header. In particular, in the DS-Lite case, the mapped address type is ipv4(1)." REFERENCE "DS-Lite: RFC 6333." ::= { natv2AddressMapEntry 6 } natv2AddressMapInternalMappedAddress OBJECT-TYPE SYNTAX InetAddress MAX-ACCESS read-only STATUS current DESCRIPTION "Internal address actually translated by this mapping. In the general case, this is the same as natv2AddressMapInternalRealmAddress. The address type is given by natv2AddressMapInternalMappedAddressType. In the case of DS-Lite (RFC 6333), this is the source address of the encapsulated IPv4 packet, normally lying in the well-known range 192.0.0.0/29. The mapping in this case is considered to be from the combination of the IPv6 tunnel source address natv2AddressMapInternalRealmAddress and the well-known IPv4 inner source address natv2AddressMapInternalMappedAddress to the external address." REFERENCE "DS-Lite: RFC 6333, Sections 5.7 (for well-known addresses) and 6.6 (on the need to have the IPv6 tunnel address in the NAT mapping tables)." ::= { natv2AddressMapEntry 7 } natv2AddressMapExternalRealm OBJECT-TYPE SYNTAX SnmpAdminString (SIZE(0..32)) MAX-ACCESS read-only Perreault, et al. Standards Track PAGE 63

RFC 7659 NAT MIB October 2015 STATUS current DESCRIPTION "External address realm to which this mapping maps the internal address. This can be the same as the internal realm in the case of a 'hairpin' connection, but otherwise will be different." ::= { natv2AddressMapEntry 8 } natv2AddressMapExternalAddressType OBJECT-TYPE SYNTAX InetAddressType MAX-ACCESS read-only STATUS current DESCRIPTION "Address type for the external realm. Any value other than ipv4(1) or ipv6(2) would be unexpected." ::= { natv2AddressMapEntry 9 } natv2AddressMapExternalAddress OBJECT-TYPE SYNTAX InetAddress MAX-ACCESS read-only STATUS current DESCRIPTION "External address to which the internal address is mapped. The address type is given by natv2AddressMapExternalAddressType. In the DS-Lite case, the mapping is from the combination of the internal IPv6 tunnel source address as presented in this table and the well-known IPv4 source address of the encapsulated IPv4 packet." REFERENCE "DS-Lite: RFC 6333, Sections 5.7 (for well-known addresses) and 6.6 (on the need to have the IPv6 tunnel address in the NAT mapping tables)." ::= { natv2AddressMapEntry 10 } natv2AddressMapExternalPoolIndex OBJECT-TYPE SYNTAX Natv2PoolIndexOrZero MAX-ACCESS read-only STATUS current DESCRIPTION "Index of the address pool in the external realm from which the mapped external address given in natv2AddressMapExternalAddress was taken. Zero if the implementation does not support address pools but has chosen to support this object or if no pool was configured for the given external realm." ::= { natv2AddressMapEntry 11 } Perreault, et al. Standards Track PAGE 64

RFC 7659 NAT MIB October 2015 natv2AddressMapSubscriberIndex OBJECT-TYPE SYNTAX Natv2SubscriberIndexOrZero MAX-ACCESS read-only STATUS current DESCRIPTION "Index of the subscriber to which this address mapping applies, or zero if no subscribers are configured on this NAT instance." ::= { natv2AddressMapEntry 12 } -- natv2PortMapTable natv2PortMapTable OBJECT-TYPE SYNTAX SEQUENCE OF Natv2PortMapEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "Table of port map entries indexed by the NAT instance, protocol, and external realm and address. A port map entry associates an internal upper-layer protocol endpoint with an endpoint for the same protocol in the given external realm. By definition, this is a snapshot of NAT instance state at a given moment. The table provides the basic mapping information. In the case of DS-Lite (RFC 6333), the table provides the internal IPv6 tunnel source address in natv2PortMapInternalRealmAddress and the IPv4 source address of the encapsulated packet that is actually translated in natv2PortMapInternalMappedAddress. In the general (non-DS- Lite) case, those two objects will have the same value." REFERENCE "RFC 7659, Section 3.3.9. DS-Lite: RFC 6333, Sections 5.7 (for well-known addresses) and 6.6 (on the need to have the IPv6 tunnel address in the NAT mapping tables)." ::= { natv2MIBInstanceObjects 6 } natv2PortMapEntry OBJECT-TYPE SYNTAX Natv2PortMapEntry MAX-ACCESS not-accessible STATUS current DESCRIPTION "A single NAT mapping." INDEX { natv2PortMapInstanceIndex, natv2PortMapProtocol, natv2PortMapExternalRealm, natv2PortMapExternalAddressType, Perreault, et al. Standards Track PAGE 65

RFC 7659 NAT MIB October 2015 natv2PortMapExternalAddress, natv2PortMapExternalPort } ::= { natv2PortMapTable 1 } Natv2PortMapEntry ::= SEQUENCE { natv2PortMapInstanceIndex Natv2InstanceIndex, natv2PortMapProtocol ProtocolNumber, natv2PortMapExternalRealm SnmpAdminString, natv2PortMapExternalAddressType InetAddressType, natv2PortMapExternalAddress InetAddress, natv2PortMapExternalPort InetPortNumber, natv2PortMapInternalRealm SnmpAdminString, natv2PortMapInternalAddressType InetAddressType, natv2PortMapInternalAddress InetAddress, natv2PortMapInternalMappedAddressType InetAddressType, natv2PortMapInternalMappedAddress InetAddress, natv2PortMapInternalPort InetPortNumber, natv2PortMapExternalPoolIndex Natv2PoolIndexOrZero, natv2PortMapSubscriberIndex Natv2SubscriberIndexOrZero } natv2PortMapInstanceIndex OBJECT-TYPE SYNTAX Natv2InstanceIndex MAX-ACCESS not-accessible STATUS current DESCRIPTION "Index of the NAT instance that created this port map entry." ::= { natv2PortMapEntry 1 } natv2PortMapProtocol OBJECT-TYPE SYNTAX ProtocolNumber MAX-ACCESS not-accessible STATUS current DESCRIPTION "The map entry's upper-layer protocol number." ::= { natv2PortMapEntry 2 } natv2PortMapExternalRealm OBJECT-TYPE SYNTAX SnmpAdminString (SIZE(0..32)) MAX-ACCESS not-accessible STATUS current DESCRIPTION "The realm to which natv2PortMapExternalAddress belongs." ::= { natv2PortMapEntry 3 } natv2PortMapExternalAddressType OBJECT-TYPE SYNTAX InetAddressType Perreault, et al. Standards Track PAGE 66

RFC 7659 NAT MIB October 2015 MAX-ACCESS not-accessible STATUS current DESCRIPTION "Address type for the external realm. A value other than ipv4(1) or ipv6(2) would be unexpected." ::= { natv2PortMapEntry 4 } natv2PortMapExternalAddress OBJECT-TYPE SYNTAX InetAddress (SIZE (0..16)) MAX-ACCESS not-accessible STATUS current DESCRIPTION "The mapping's assigned external address. (This address is taken from the address pool identified by natv2PortMapExternalPoolIndex, if the implementation supports address pools and pools are configured for the given external realm.) This is the source address for translated outgoing packets. The address type is given by natv2PortMapExternalAddressType." ::= { natv2PortMapEntry 5 } natv2PortMapExternalPort OBJECT-TYPE SYNTAX InetPortNumber MAX-ACCESS not-accessible STATUS current DESCRIPTION "The mapping's assigned external port number. This is the source port for translated outgoing packets. If the internal port number given by natv2PortMapInternalPort is zero, this value MUST also be zero. Otherwise, this MUST be a non-zero value." ::= { natv2PortMapEntry 6 } natv2PortMapInternalRealm OBJECT-TYPE SYNTAX SnmpAdminString (SIZE(0..32)) MAX-ACCESS read-only STATUS current DESCRIPTION "The realm to which natv2PortMapInternalRealmAddress belongs. In the general case, this realm contains the address that is being translated. In the DS-Lite (RFC 6333) case, this realm defines the IPv6 address space from which the tunnel source address is taken. The realm of the encapsulated IPv4 address is restricted in scope to the tunnel, so there is no point in identifying it separately." REFERENCE "DS-Lite: RFC 6333." Perreault, et al. Standards Track PAGE 67

RFC 7659 NAT MIB October 2015 ::= { natv2PortMapEntry 7 } natv2PortMapInternalAddressType OBJECT-TYPE SYNTAX InetAddressType MAX-ACCESS read-only STATUS current DESCRIPTION "Address type for addresses in the realm identified by natv2PortMapInternalRealm." ::= { natv2PortMapEntry 8 } natv2PortMapInternalAddress OBJECT-TYPE SYNTAX InetAddress MAX-ACCESS read-only STATUS current DESCRIPTION "Source address for packets received under this mapping on the internal side of the NAT instance. In the general case, this address is the same as the address given in natv2PortMapInternalMappedAddress. In the DS-Lite case, natv2PortMapInternalAddress is the IPv6 tunnel source address. The address type is given by natv2PortMapInternalAddressType." REFERENCE "DS-Lite: RFC 6333, Sections 5.7 (for well-known addresses) and 6.6 (on the need to have the IPv6 tunnel address in the NAT mapping tables)." ::= { natv2PortMapEntry 9 } natv2PortMapInternalMappedAddressType OBJECT-TYPE SYNTAX InetAddressType MAX-ACCESS read-only STATUS current DESCRIPTION "Internal address type actually translated by this mapping. Any value other than ipv4(1) or ipv6(2) would be unexpected. In the general case, this is the same as given by natv2AddressMapInternalAddressType. In the DS-Lite case, the address type is ipv4(1)." REFERENCE "DS-Lite: RFC 6333." ::= { natv2PortMapEntry 10 } natv2PortMapInternalMappedAddress OBJECT-TYPE SYNTAX InetAddress MAX-ACCESS read-only STATUS current DESCRIPTION Perreault, et al. Standards Track PAGE 68

RFC 7659 NAT MIB October 2015 "Internal address actually translated by this mapping. In the general case, this is the same as natv2PortMapInternalRealmAddress. The address type is given by natv2PortMapInternalMappedAddressType. In the case of DS-Lite (RFC 6333), this is the source address of the encapsulated IPv4 packet, normally selected from the well-known range 192.0.0.0/29. The mapping in this case is considered to be from the external address to the combination of the IPv6 tunnel source address natv2PortMapInternalRealmAddress and the well-known IPv4 inner source address natv2PortMapInternalMappedAddress." REFERENCE "DS-Lite: RFC 6333, Sections 5.7 (for well-known addresses) and 6.6 (on the need to have the IPv6 tunnel address in the NAT mapping tables)." ::= { natv2PortMapEntry 11 } natv2PortMapInternalPort OBJECT-TYPE SYNTAX InetPortNumber MAX-ACCESS read-only STATUS current DESCRIPTION "The mapping's internal port number. If this is zero, ports are not translated (i.e., the NAT instance is a pure NAT rather than a Network Address and Port Translator (NAPT))." ::= { natv2PortMapEntry 12 } natv2PortMapExternalPoolIndex OBJECT-TYPE SYNTAX Natv2PoolIndexOrZero MAX-ACCESS read-only STATUS current DESCRIPTION "Identifies the address pool from which the external address in this port map entry was taken. Zero if the implementation does not support address pools but has chosen to support this object or if no pools are configured for the given external realm." ::= { natv2PortMapEntry 13 } natv2PortMapSubscriberIndex OBJECT-TYPE SYNTAX Natv2SubscriberIndexOrZero MAX-ACCESS read-only STATUS current DESCRIPTION "Subscriber using this map entry. Zero if the implementation does not support subscribers but has chosen to support this object." Perreault, et al. Standards Track PAGE 69

RFC 7659 NAT MIB October 2015 ::= { natv2PortMapEntry 14 } -- Conformance section. Specifies three cumulatively more extensive -- applications: basic NAT, pooled NAT, and carrier-grade NAT. natv2MIBConformance OBJECT IDENTIFIER ::= { natv2MIB 3 } natv2MIBCompliances OBJECT IDENTIFIER ::= { natv2MIBConformance 1 } natv2MIBGroups OBJECT IDENTIFIER ::= { natv2MIBConformance 2 } natv2MIBBasicCompliance MODULE-COMPLIANCE STATUS current DESCRIPTION "Describes the requirements for conformance to the basic NAT application of NATV2-MIB." MODULE -- this module MANDATORY-GROUPS { natv2BasicNotificationGroup, natv2BasicInstanceLevelGroup } ::= { natv2MIBCompliances 1 } natv2MIBPooledNATCompliance MODULE-COMPLIANCE STATUS current DESCRIPTION "Describes the requirements for conformance to the pooled NAT application of NATV2-MIB." MODULE -- this module MANDATORY-GROUPS { natv2BasicNotificationGroup, natv2BasicInstanceLevelGroup, natv2PooledNotificationGroup, natv2PooledInstanceLevelGroup } ::= { natv2MIBCompliances 2 } natv2MIBCGNCompliance MODULE-COMPLIANCE STATUS current DESCRIPTION "Describes the requirements for conformance to the carrier-grade NAT application of NATV2-MIB." MODULE -- this module MANDATORY-GROUPS { natv2BasicNotificationGroup, natv2BasicInstanceLevelGroup, natv2PooledNotificationGroup, natv2PooledInstanceLevelGroup, natv2CGNNotificationGroup, natv2CGNDeviceLevelGroup, natv2CGNInstanceLevelGroup } Perreault, et al. Standards Track PAGE 70

RFC 7659 NAT MIB October 2015 ::= { natv2MIBCompliances 3 } -- Groups natv2BasicNotificationGroup NOTIFICATION-GROUP NOTIFICATIONS { natv2NotificationInstanceAddressMapEntriesHigh, natv2NotificationInstancePortMapEntriesHigh } STATUS current DESCRIPTION "Notifications that MUST be supported by all NAT applications." ::= { natv2MIBGroups 1 } natv2BasicInstanceLevelGroup OBJECT-GROUP OBJECTS { -- from natv2InstanceTable natv2InstanceAlias, natv2InstancePortMappingBehavior, natv2InstanceFilteringBehavior, natv2InstanceFragmentBehavior, natv2InstanceAddressMapEntries, natv2InstancePortMapEntries, natv2InstanceTranslations, natv2InstanceAddressMapCreations, natv2InstanceAddressMapEntryLimitDrops, natv2InstanceAddressMapFailureDrops, natv2InstancePortMapCreations, natv2InstancePortMapEntryLimitDrops, natv2InstancePortMapFailureDrops, natv2InstanceFragmentDrops, natv2InstanceOtherResourceFailureDrops, natv2InstanceDiscontinuityTime, natv2InstanceThresholdAddressMapEntriesHigh, natv2InstanceThresholdPortMapEntriesHigh, natv2InstanceNotificationInterval, natv2InstanceLimitAddressMapEntries, natv2InstanceLimitPortMapEntries, natv2InstanceLimitPendingFragments, -- from natv2ProtocolTable natv2ProtocolPortMapEntries, natv2ProtocolTranslations, natv2ProtocolPortMapCreations, natv2ProtocolPortMapFailureDrops, -- from natv2AddressMapTable natv2AddressMapExternalRealm, natv2AddressMapExternalAddressType, Perreault, et al. Standards Track PAGE 71

RFC 7659 NAT MIB October 2015 natv2AddressMapExternalAddress, -- from natv2PortMapTable natv2PortMapInternalRealm, natv2PortMapInternalAddressType, natv2PortMapInternalAddress, natv2PortMapInternalPort } STATUS current DESCRIPTION "Per-instance objects that MUST be supported by implementations of all NAT applications." ::= { natv2MIBGroups 2 } natv2PooledNotificationGroup NOTIFICATION-GROUP NOTIFICATIONS { natv2NotificationPoolUsageLow, natv2NotificationPoolUsageHigh } STATUS current DESCRIPTION "Notifications that MUST be supported by pooled and carrier-grade NAT applications." ::= { natv2MIBGroups 3 } natv2PooledInstanceLevelGroup OBJECT-GROUP OBJECTS { -- from natv2InstanceTable natv2InstancePoolingBehavior, -- from natv2PoolTable natv2PoolRealm, natv2PoolAddressType, natv2PoolMinimumPort, natv2PoolMaximumPort, natv2PoolAddressMapEntries, natv2PoolPortMapEntries, natv2PoolAddressMapCreations, natv2PoolPortMapCreations, natv2PoolAddressMapFailureDrops, natv2PoolPortMapFailureDrops, natv2PoolDiscontinuityTime, natv2PoolThresholdUsageLow, natv2PoolThresholdUsageHigh, natv2PoolNotifiedPortMapEntries, natv2PoolNotifiedPortMapProtocol, natv2PoolNotificationInterval, -- from natv2PoolRangeTable natv2PoolRangeBegin, natv2PoolRangeEnd, Perreault, et al. Standards Track PAGE 72

RFC 7659 NAT MIB October 2015 -- from natv2AddressMapTable natv2AddressMapExternalPoolIndex, -- from natv2PortMapTable natv2PortMapExternalPoolIndex } STATUS current DESCRIPTION "Per-instance objects that MUST be supported by implementations of the pooled and carrier-grade NAT applications." ::= { natv2MIBGroups 4 } natv2CGNNotificationGroup NOTIFICATION-GROUP NOTIFICATIONS { natv2NotificationSubscriberPortMappingEntriesHigh } STATUS current DESCRIPTION "Notification that MUST be supported by implementations of the carrier-grade NAT application." ::= { natv2MIBGroups 5 } natv2CGNDeviceLevelGroup OBJECT-GROUP OBJECTS { -- from table natv2SubscriberTable natv2SubscriberInternalRealm, natv2SubscriberInternalPrefixType, natv2SubscriberInternalPrefix, natv2SubscriberInternalPrefixLength, natv2SubscriberAddressMapEntries, natv2SubscriberPortMapEntries, natv2SubscriberTranslations, natv2SubscriberAddressMapCreations, natv2SubscriberPortMapCreations, natv2SubscriberAddressMapFailureDrops, natv2SubscriberPortMapFailureDrops, natv2SubscriberDiscontinuityTime, natv2SubscriberLimitPortMapEntries, natv2SubscriberThresholdPortMapEntriesHigh, natv2SubscriberNotificationInterval } STATUS current DESCRIPTION "Device-level objects that MUST be supported by the carrier-grade NAT application." ::= { natv2MIBGroups 6 } natv2CGNInstanceLevelGroup OBJECT-GROUP Perreault, et al. Standards Track PAGE 73

RFC 7659 NAT MIB October 2015 OBJECTS { -- from natv2InstanceTable natv2InstanceSubscriberActiveLimitDrops, natv2InstanceLimitSubscriberActives, -- from natv2AddressMapTable natv2AddressMapInternalMappedAddressType, natv2AddressMapInternalMappedAddress, natv2AddressMapSubscriberIndex, -- from natv2PortMapTable natv2PortMapInternalMappedAddressType, natv2PortMapInternalMappedAddress, natv2PortMapSubscriberIndex } STATUS current DESCRIPTION "Per-instance objects that MUST be supported by the carrier-grade NAT application." ::= { natv2MIBGroups 7 } END 5. Operational and Management Considerations This section covers two particular areas of operations and management: configuration requirements and transition from or coexistence with the MIB module in [RFC 4008]. 5.1. Configuration Requirements This MIB module assumes that the following information is configured on the NAT device by means outside the scope of the present document or is imposed by the implementation: o the set of address realms to which the device connects; o for the CGN application, per-subscriber information including subscriber index, address realm, assigned prefix or address, and (possibly) policies regarding address pool selection in the various possible address realms to which the subscriber may connect. In the particular case of DS-Lite [RFC 6333] access, as well as the assigned outer-layer (IPv6) prefix or address, the subscriber information will include an inner (IPv4) source address, usually 192.0.0.2; o the set of NAT instances running on the device, identified by NAT instance index and name; Perreault, et al. Standards Track PAGE 74

RFC 7659 NAT MIB October 2015 o the port mapping, filtering, pooling, and fragment behavior for each NAT instance; o the set of protocols supported by each NAT instance; o for the pooled NAT and CGN applications, address pool information for each NAT instance, including for each pool the pool index, address realm, address type, minimum and maximum port number, the address ranges assigned to that pool, and policies for access to that pool's resources; o static address and port map entries. As described in previous sections, this MIB module does provide read- write objects for control of notifications (see especially Section 3.1.2) and limiting of resource consumption (Section 3.1.1). This document is written in advance of any practical experience with the setting of these values and can thus provide only general principles for how to set them. By default, the MIB module definition disables notifications until they are explicitly enabled by the operator, using the associated threshold value to do so. To make use of the notifications, the operator may wish to take the following considerations into account. Except for the low address pool utilization notification, the notifications imply that some sort of administrative action is required to mitigate an impending shortage of a particular resource. The choice of value for the triggering threshold needs to take two factors into account: the volatility of usage of the given resource, and the amount of time the operator needs to mitigate the potential overload situation. That time could vary from almost immediate to several weeks required to order and install new hardware or software. To give a numeric example, if average utilization is going up 1% per week but can vary 10% around that average in any given hour, and it takes two weeks to carry through mitigating measures, the threshold should be set to 88% of the corresponding limit (two weeks' growth plus 10% volatility margin). If mitigating measures can be carried out immediately, this can rise to 90%. For this particular example, that change is insignificant, but in other cases the difference may be large enough to matter in terms of reduced load on the management plane. The notification rate-limit settings really depend on the operator's processes but are a tradeoff between reliably reporting the notified condition and not having it overload the management plane. Reliability rises in importance with the importance of the resource Perreault, et al. Standards Track PAGE 75

RFC 7659 NAT MIB October 2015 involved. Thus, the default notification intervals defined in this MIB module range from 10 seconds (high reliability) for the address and port map entry thresholds up to 60 seconds (lower reliability) for the per-subscriber port entry thresholds. Experience may suggest better values. The limits on number of instance-level address map and port map entries and held fragments relate directly to memory allocations for these tables. The relationship between number of map entries or number of held fragments and memory required will be implementation- specific. Hence it is up to the implementor to provide specific advice on the setting of these limits. The limit on simultaneous number of active subscribers is indirectly related to memory consumption for map entries, but also to processor usage by the NAT instance. The best strategy for setting this limit would seem to be to leave it disabled during an initial period while observing device processor utilization, then to implement a trial setting while observing the number of blocked packets affected by the new limit. The setting may vary by NAT instance if a suitable estimator of likely load (e.g., total number of hosts served by that instance) is available. 5.2. Transition from and Coexistence with NAT-MIB (RFC 4008) A manager may have to deal with a mixture of devices supporting the NAT-MIB module [RFC 4008] and the NATV2-MIB module defined in the present document. It is even possible that both modules are supported on the same device. The following discussion brings out the limits of comparability between the two MIB modules. A first point to note is that NAT-MIB is primarily focused on configuration, while NATV2-MIB is primarily focused on measurements. To summarize the model used by [RFC 4008]: o The basic unit of NAT configuration is the interface. o An interface connects to a single realm, either "private" or "public". In principle that means there could be multiple instances of one type of realm or the other, but the number is physically limited by the number of interfaces on the NAT device. o Before the NAT can operate on a given interface, an "address map" has to be configured on it. The address map in [RFC 4008] is equivalent to the pool tables in the present document. Since just one "address map" is configured per interface, this is the equivalent of a single address pool per interface. Perreault, et al. Standards Track PAGE 76

RFC 7659 NAT MIB October 2015 o The address binding and port binding tables are roughly equivalent to the address map and port map tables in the present document in their content, but they can be either unidirectional or bidirectional. The model in [RFC 4008] shows the address binding and port binding as alternative precursors to session establishment, depending on whether the device does address translation only or address and port translation. In contrast, NATV2-MIB assumes a model where bidirectional port mappings are based on bidirectional address mappings that have conceptually been established beforehand. o The equivalent to an [RFC 4008] session in NATV2-MIB would be a pair of port map entries. The added complexity in [RFC 4008] is due to the modeling of NAT service types as defined in [RFC 3489] (the symmetric NAT in particular) instead of the more granular set of behaviors described in [RFC 4787]. (Note: [RFC 3489] has been obsoleted by [RFC 5389].) With regard to that last point, the mapping between [RFC 3489] service types and [RFC 4787] NAT behaviors is as follows: o A full cone NAT exhibits endpoint-independent port mapping behavior and endpoint-independent filtering behavior. o A restricted cone NAT exhibits endpoint-independent port mapping behavior, but address-dependent filtering behavior. o A port restricted cone NAT exhibits endpoint-independent port mapping behavior, but address-and-port-dependent filtering behavior. o A symmetric NAT exhibits address-and-port-dependent port mapping and filtering behaviors. Note that these NAT types are a subset of the types that could be configured according to the [RFC 4787] behavioral classification used in NATV2-MIB, but they include the two possibilities (full and restricted cone NAT) that satisfy requirements REQ-1 and REQ-8 of [RFC 4787]. Note further that other behaviors defined in [RFC 4787] are not considered in [RFC 4008]. Having established a context for discussion, we are now in a position to compare the outputs provided to management from the [RFC 4008] and NATV2-MIB modules. This comparison relates to the ability to compare results if testing with both MIBs implemented on the same device during a transition period. Perreault, et al. Standards Track PAGE 77

RFC 7659 NAT MIB October 2015 [RFC 4008] provides three counters: incoming translations, outgoing translations, and discarded packets, at the granularities of interface, address map, and protocol, and incoming and outgoing translations at the levels of individual address bind, address port bind, and session entries. Implementation at the protocol and address map levels is optional. NATV2-MIB provides a single total (both directions) translations counter at the instance, protocol within instance, and subscriber levels. Given the differences in granularity, it appears that the only comparable measurement of translations between the two MIB modules would be through aggregation of the [RFC 4008] interface counters to give a total number of translations for the NAT instance. NATV2-MIB has broken out the single discard counter into a number of different counters reflecting the cause of the discard in more detail, to help in troubleshooting. Again, with the differing levels of granularity, the only comparable statistic would be through aggregation to a single value of total discards per NAT instance. Moving on to state variables, [RFC 4008] offers counts of number of "address map" (i.e., address pool) entries used (excluding static entries) at the address map level and number of entries in the address bind and address and port bind tables, respectively. Finally, [RFC 4008] provides a count of the number of sessions currently using each entry in the address and port bind table. None of these counts are directly comparable with the state values offered by NATV2-MIB, because of the exclusion of static entries at the address map level, and because of the differing models of the translation tables between [RFC 4008] and the NATV2-MIB. 6. Security Considerations There are a number of management objects defined in this MIB module with a MAX-ACCESS clause of read-write. Such objects may be considered sensitive or vulnerable in some network environments. The support for SET operations in a non-secure environment without proper protection opens devices to attack. These are the tables and objects and their sensitivity/vulnerability: Limits: An attacker setting a very low or very high limit can easily cause a denial-of-service situation. * natv2InstanceLimitAddressMapEntries; * natv2InstanceLimitPortMapEntries; * natv2InstanceLimitPendingFragments; Perreault, et al. Standards Track PAGE 78

RFC 7659 NAT MIB October 2015 * natv2InstanceLimitSubscriberActives; * natv2SubscriberLimitPortMapEntries. Notification thresholds: An attacker setting an arbitrarily low threshold can cause many useless notifications to be generated (subject to the notification interval). Setting an arbitrarily high threshold can effectively disable notifications, which could be used to hide another attack. * natv2InstanceThresholdAddressMapEntriesHigh; * natv2InstanceThresholdPortMapEntriesHigh; * natv2PoolThresholdUsageLow; * natv2PoolThresholdUsageHigh; * natv2SubscriberThresholdPortMapEntriesHigh. Notification intervals: An attacker setting a low notification interval in combination with a low threshold value can cause many useless notifications to be generated. * natv2InstanceNotificationInterval; * natv2PoolNotificationInterval; * natv2SubscriberNotificationInterval. Some of the readable objects in this MIB module (i.e., objects with a MAX-ACCESS other than not-accessible) may be considered sensitive or vulnerable in some network environments. It is thus important to control even GET and/or NOTIFY access to these objects and possibly to even encrypt the values of these objects when sending them over the network via SNMP. These are the tables and objects and their sensitivity/vulnerability: Objects that reveal host identities: Various objects can reveal the identity of private hosts that are engaged in a session with external end nodes. A curious outsider could monitor these to assess the number of private hosts being supported by the NAT device. Further, a disgruntled former employee of an enterprise could use the information to break into specific private hosts by intercepting the existing sessions or originating new sessions into the host. If nothing else, unauthorized monitoring of these objects will violate individual subscribers' privacy. Perreault, et al. Standards Track PAGE 79

RFC 7659 NAT MIB October 2015 * entries in the natv2SubscriberTable; * entries in the natv2AddressMapTable; * entries in the natv2PortMapTable. Other objects that reveal NAT state: Other managed objects in this MIB may contain information that may be sensitive from a business perspective, in that they may represent NAT capabilities, business policies, and state information. * natv2SubscriberLimitPortMapEntries; * natv2InstancePortMappingBehavior; * natv2InstanceFilteringBehavior; * natv2InstancePoolingBehavior; * natv2InstanceFragmentBehavior; * natv2InstanceAddressMapEntries; * natv2InstancePortMapEntries. There are no objects that are sensitive in their own right, such as passwords or monetary amounts. SNMP versions prior to SNMPv3 did not include adequate security. Even if the network itself is secure (for example by using IPsec), there is no control as to who on the secure network is allowed to access and GET/SET (read/change/create/delete) the objects in this MIB module. Implementations SHOULD provide the security features described by the SNMPv3 framework (see [RFC 3410]), and implementations claiming compliance to the SNMPv3 standard MUST include full support for authentication and privacy via the User-based Security Model (USM) [RFC 3414] with the AES cipher algorithm [RFC 3826]. Implementations MAY also provide support for the Transport Security Model (TSM) [RFC 5591] in combination with a secure transport such as SSH [RFC 5592] or TLS/DTLS [RFC 6353]. Further, deployment of SNMP versions prior to SNMPv3 is NOT RECOMMENDED. Instead, it is RECOMMENDED to deploy SNMPv3 and to enable cryptographic security. It is then a customer/operator responsibility to ensure that the SNMP entity giving access to an instance of this MIB module is properly configured to give access to Perreault, et al. Standards Track PAGE 80

RFC 7659 NAT MIB October 2015 the objects only to those principals (users) that have legitimate rights to indeed GET or SET (change/create/delete) them. 7. IANA Considerations IANA has assigned an object identifier to the natv2MIB module, with prefix iso.org.dod.internet.mgmt.mib-2 in the SMI Numbers registry [SMI-NUMBERS]. 8. References 8.1. Normative References [RFC 2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC 2119, March 1997, <http://www.rfc-editor.org/info/RFC 2119>. [RFC 2578] McCloghrie, K., Ed., Perkins, D., Ed., and J. Schoenwaelder, Ed., "Structure of Management Information Version 2 (SMIv2)", STD 58, RFC 2578, DOI 10.17487/RFC 2578, April 1999, <http://www.rfc-editor.org/info/RFC 2578>. [RFC 2579] McCloghrie, K., Ed., Perkins, D., Ed., and J. Schoenwaelder, Ed., "Textual Conventions for SMIv2", STD 58, RFC 2579, DOI 10.17487/RFC 2579, April 1999, <http://www.rfc-editor.org/info/RFC 2579>. [RFC 2580] McCloghrie, K., Ed., Perkins, D., Ed., and J. Schoenwaelder, Ed., "Conformance Statements for SMIv2", STD 58, RFC 2580, DOI 10.17487/RFC 2580, April 1999, <http://www.rfc-editor.org/info/RFC 2580>. [RFC 3411] Harrington, D., Presuhn, R., and B. Wijnen, "An Architecture for Describing Simple Network Management Protocol (SNMP) Management Frameworks", STD 62, RFC 3411, DOI 10.17487/RFC 3411, December 2002, <http://www.rfc-editor.org/info/RFC 3411>. [RFC 3414] Blumenthal, U. and B. Wijnen, "User-based Security Model (USM) for version 3 of the Simple Network Management Protocol (SNMPv3)", STD 62, RFC 3414, DOI 10.17487/RFC 3414, December 2002, <http://www.rfc-editor.org/info/RFC 3414>. Perreault, et al. Standards Track PAGE 81

RFC 7659 NAT MIB October 2015 [RFC 3826] Blumenthal, U., Maino, F., and K. McCloghrie, "The Advanced Encryption Standard (AES) Cipher Algorithm in the SNMP User-based Security Model", RFC 3826, DOI 10.17487/RFC 3826, June 2004, <http://www.rfc-editor.org/info/RFC 3826>. [RFC 4001] Daniele, M., Haberman, B., Routhier, S., and J. Schoenwaelder, "Textual Conventions for Internet Network Addresses", RFC 4001, DOI 10.17487/RFC 4001, February 2005, <http://www.rfc-editor.org/info/RFC 4001>. [RFC 4787] Audet, F., Ed. and C. Jennings, "Network Address Translation (NAT) Behavioral Requirements for Unicast UDP", BCP 127, RFC 4787, DOI 10.17487/RFC 4787, January 2007, <http://www.rfc-editor.org/info/RFC 4787>. [RFC 5591] Harrington, D. and W. Hardaker, "Transport Security Model for the Simple Network Management Protocol (SNMP)", STD 78, RFC 5591, DOI 10.17487/RFC 5591, June 2009, <http://www.rfc-editor.org/info/RFC 5591>. [RFC 5592] Harrington, D., Salowey, J., and W. Hardaker, "Secure Shell Transport Model for the Simple Network Management Protocol (SNMP)", RFC 5592, DOI 10.17487/RFC 5592, June 2009, <http://www.rfc-editor.org/info/RFC 5592>. [RFC 6353] Hardaker, W., "Transport Layer Security (TLS) Transport Model for the Simple Network Management Protocol (SNMP)", STD 78, RFC 6353, DOI 10.17487/RFC 6353, July 2011, <http://www.rfc-editor.org/info/RFC 6353>. 8.2. Informative References [RFC 2460] Deering, S. and R. Hinden, "Internet Protocol, Version 6 (IPv6) Specification", RFC 2460, DOI 10.17487/RFC 2460, December 1998, <http://www.rfc-editor.org/info/RFC 2460>. [RFC 2663] Srisuresh, P. and M. Holdrege, "IP Network Address Translator (NAT) Terminology and Considerations", RFC 2663, DOI 10.17487/RFC 2663, August 1999, <http://www.rfc-editor.org/info/RFC 2663>. [RFC 3410] Case, J., Mundy, R., Partain, D., and B. Stewart, "Introduction and Applicability Statements for Internet- Standard Management Framework", RFC 3410, DOI 10.17487/RFC 3410, December 2002, <http://www.rfc-editor.org/info/RFC 3410>. Perreault, et al. Standards Track PAGE 82

RFC 7659 NAT MIB October 2015 [RFC 3489] Rosenberg, J., Weinberger, J., Huitema, C., and R. Mahy, "STUN - Simple Traversal of User Datagram Protocol (UDP) Through Network Address Translators (NATs)", RFC 3489, DOI 10.17487/RFC 3489, March 2003, <http://www.rfc-editor.org/info/RFC 3489>. [RFC 4008] Rohit, R., Srisuresh, P., Raghunarayan, R., Pai, N., and C. Wang, "Definitions of Managed Objects for Network Address Translators (NAT)", RFC 4008, DOI 10.17487/RFC 4008, March 2005, <http://www.rfc-editor.org/info/RFC 4008>. [RFC 5389] Rosenberg, J., Mahy, R., Matthews, P., and D. Wing, "Session Traversal Utilities for NAT (STUN)", RFC 5389, DOI 10.17487/RFC 5389, October 2008, <http://www.rfc-editor.org/info/RFC 5389>. [RFC 6333] Durand, A., Droms, R., Woodyatt, J., and Y. Lee, "Dual- Stack Lite Broadband Deployments Following IPv4 Exhaustion", RFC 6333, DOI 10.17487/RFC 6333, August 2011, <http://www.rfc-editor.org/info/RFC 6333>. [RFC 7658] Perreault, S., Tsou, T., Sivakumar, S., and T. Taylor, "Deprecation of MIB Module NAT-MIB: Managed Objects for Network Address Translators (NATs)", RFC 7658, DOI 10.17487/RFC 7658, October 2015, <http://www.rfc-editor.org/info/RFC 7658>. [SMI-NUMBERS] IANA, "Structure of Management Information (SMI) Numbers (MIB Module Registrations)", <http://www.iana.org/assignments/smi-number>. Perreault, et al. Standards Track PAGE 83

RFC 7659 NAT MIB October 2015 Authors' Addresses Simon Perreault Jive Communications Quebec, QC Canada Email: sperreault@jive.com Tina Tsou Huawei Technologies Bantian, Longgang District Shenzhen 518129 China Email: tina.tsou.zouting@huawei.com Senthil Sivakumar Cisco Systems 7100-8 Kit Creek Road Research Triangle Park, North Carolina 27709 United States Phone: +1 919 392 5158 Email: ssenthil@cisco.com Tom Taylor PT Taylor Consulting Ottawa Canada Email: tom.taylor.stds@gmail.com Perreault, et al. Standards Track PAGE 84

RFC TOTAL SIZE: 183157 bytes PUBLICATION DATE: Tuesday, October 27th, 2015 LEGAL RIGHTS: The IETF Trust (see BCP 78)


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