Internet Engineering Task Force (IETF) K. Ogawa Request for Comments: 7121 NTT Corporation Updates: 5810 W. Wang Category: Standards Track Zhejiang Gongshang University ISSN: 2070-1721 E. Haleplidis University of Patras J. Hadi Salim Mojatatu Networks February 2014 High Availability within a Forwarding and Control Element Separation (ForCES) Network Element Abstract This document discusses Control Element (CE) High Availability (HA) within a Forwarding and Control Element Separation (ForCES) Network Element (NE). Additionally, this document updates RFC 5810 by providing new normative text for the Cold Standby High Availability mechanism. 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/rfc7121. Ogawa, et al. Standards Track [Page 1] RFC 7121 ForCES Intra-NE High Availability February 2014 Copyright Notice Copyright (c) 2014 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. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3 1.1. Quantifying Problem Scope . . . . . . . . . . . . . . . . 4 1.2. Definitions . . . . . . . . . . . . . . . . . . . . . . . 5 2. RFC 5810 CE HA Framework . . . . . . . . . . . . . . . . . . 7 2.1. RFC 5810 CE HA Support . . . . . . . . . . . . . . . . . 7 2.1.1. Cold Standby Interaction with the ForCES Protocol . . 8 2.1.2. Responsibilities for HA . . . . . . . . . . . . . . . 10 3. CE HA Hot Standby . . . . . . . . . . . . . . . . . . . . . . 11 3.1. Changes to the FEPO Model . . . . . . . . . . . . . . . . 11 3.2. FEPO Processing . . . . . . . . . . . . . . . . . . . . . 13 4. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 17 5. Security Considerations . . . . . . . . . . . . . . . . . . . 18 6. References . . . . . . . . . . . . . . . . . . . . . . . . . 19 6.1. Normative References . . . . . . . . . . . . . . . . . . 19 6.2. Informative References . . . . . . . . . . . . . . . . . 19 Appendix A. New FEPO Version . . . . . . . . . . . . . . . . . . 20 Ogawa, et al. Standards Track [Page 2] RFC 7121 ForCES Intra-NE High Availability February 2014 1. Introduction Figure 1 illustrates a ForCES Network Element (NE) controlled by a set of redundant Control Elements (CEs) with CE1 being active and CE2 and CEn being backups. ----------------------------------------- | ForCES Network Element | | +-----------+ | | | CEn | | | | (Backup) | | -------------- Fc | +------------+ +------------+ | | | CE Manager |--------+-| CE1 |------| CE2 |-+ | -------------- | | (Active) | Fr | (Backup) | | | | +-------+--+-+ +---+---+----+ | | Fl | | | Fp / | | | | | +---------+ / | | | | Fp| |/ |Fp | | | | | | | | | | Fp /+--+ | | | | | +-------+ | | | | | | | | | | -------------- Ff | --------+--+-- ----+---+----+ | | FE Manager |--------+-| FE1 | Fi | FE2 | | -------------- | | |------| | | | -------------- -------------- | | | | | | | | | | | ----+--+--+--+----------+--+--+--+------- | | | | | | | | | | | | | | | | Fi/f Fi/f Fp: CE-FE interface Fi: FE-FE interface Fr: CE-CE interface Fc: Interface between the CE manager and a CE Ff: Interface between the FE manager and an FE Fl: Interface between the CE manager and the FE manager Fi/f: FE external interface Figure 1: ForCES Architecture The ForCES architecture allows Forwarding Elements (FEs) to be aware of multiple CEs but enforces that only one CE be the master controller. This is known in the industry as 1+N redundancy. The master CE controls the FEs via the ForCES protocol operating on the Fp interface. If the master CE becomes faulty, i.e., crashes or loses connectivity, a backup CE takes over and NE operation Ogawa, et al. Standards Track [Page 3] RFC 7121 ForCES Intra-NE High Availability February 2014 continues. By definition, the current documented setup is known as cold standby. The set of CEs controlling an FE is static and is passed to the FE by the FE Manager (FEM) via the Ff interface and to each CE by the CE Manager (CEM) in the Fc interface during the pre- association phase. From an FE perspective, the operational parameters for a CE set are defined as components in the FEPO LFB in [RFC5810], Appendix B. In Section 2.1 of this document, we discuss further details of these parameters. It is assumed that the reader is aware of the ForCES architecture to make sense of the changes being described in this document. This document provides background information to set the context of the discussion in Section 3. At the time of writing, the Fr interface is out of scope for the ForCES architecture. However, it is expected that organizations implementing a set of CEs will need to have the CEs communicate to each other via the Fr interface in order to achieve the synchronization necessary for controlling the FEs. The problem scope addressed by this document falls into two areas: 1. To update the description of [RFC5810] with more clarity on how the current cold standby approach operates within the NE cluster. 2. To describe how to evolve the [RFC5810] cold standby setup to a hot standby redundancy setup to improve the failover time and NE availability. 1.1. Quantifying Problem Scope NE recovery and availability is dependent on several time-sensitive metrics: 1. How fast the CE plane failure is detected by the FE. 2. How fast a backup CE becomes operational. 3. How fast the FEs associate with the new master CE. 4. How fast the FEs recover their state and become operational. Each FE state is the collective state of all its instantiated LFBs. The design intent of [RFC5810] as well as this document to meet the above goals is driven by desire for simplicity. Ogawa, et al. Standards Track [Page 4] RFC 7121 ForCES Intra-NE High Availability February 2014 To quantify the above criteria with the current prescribed ForCES CE setup in [RFC5810]: 1. How fast the FE side detects a CE failure is left undefined. To illustrate an extreme scenario, we could have a human operator acting as the monitoring entity to detect faulty CEs. How fast such detection happens could be in the range of seconds to days. A more active monitor on the Fp interface could improve this detection. Usually, the FE will detect a CE failure either by the TML if the Fp interface terminates or by the ForCES protocol by utilizing the ForCES Heartbeat mechanism. 2. How fast the backup CE becomes operational is also currently out of scope. In the current setup, a backup CE need not be operational at all (for example, to save power), and therefore it is feasible for a monitoring entity to boot up a backup CE after it detects the failure of the master CE. In Section 3 of this document, we suggest that at least one backup CE be online so as to improve this metric. 3. How fast an FE associates with a new master CE is also currently undefined. The cost of an FE connecting and associating adds to the recovery overhead. As mentioned above, we suggest having at least one backup CE online. In Section 3, we propose to remove the connection and association cost on failover by having each FE associate with all online backup CEs after associating to an active/master CE. Note that if an FE pre-associates with at least one backup CE, then the system will be technically operating in hot standby mode. 4. Finally, how fast an FE recovers its state depends on how much NE state exists. By the ForCES current definition, the new master CE assumes zero state on the FE and starts from scratch to update the FE. So, the larger the state, the longer the recovery. 1.2. Definitions The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119]. The following definitions are taken from [RFC3654], [RFC3746], and [RFC5810]. They are repeated here for convenience as needed, but the normative definitions are found in the referenced RFCs: Logical Functional Block (LFB): A template that represents fine- grained, logically separate aspects of FE processing. Ogawa, et al. Standards Track [Page 5] RFC 7121 ForCES Intra-NE High Availability February 2014 Forwarding Element (FE): A logical entity that implements the ForCES protocol. FEs use the underlying hardware to provide per-packet processing and handling as directed by a CE via the ForCES protocol. Control Element (CE): A logical entity that implements the ForCES protocol and uses it to instruct one or more FEs on how to process packets. CEs handle functionality such as the execution of control and signaling protocols. ForCES Network Element (NE): An entity composed of one or more CEs and one or more FEs. An NE usually hides its internal organization from external entities and represents a single point of management to entities outside the NE. FE Manager (FEM): A logical entity that operates in the pre- association phase and is responsible for determining to which CE(s) an FE should communicate. This process is called CE discovery and may involve the FE manager learning the capabilities of available CEs. CE Manager (CEM): A logical entity that operates in the pre- association phase and is responsible for determining to which FE(s) a CE should communicate. This process is called FE discovery and may involve the CE manager learning the capabilities of available FEs. ForCES Protocol: The protocol used for communication between CEs and FEs. This protocol does not apply to CE-to-CE communication, FE- to-FE communication, or to communication between FE and CE managers. The ForCES protocol is a master-slave protocol in which FEs are slaves and CEs are masters. This protocol includes both the management of the communication channel (e.g., connection establishment and heartbeats) and the control messages themselves. ForCES Protocol Layer (ForCES PL): A layer in the ForCES protocol architecture that defines the ForCES protocol messages, the protocol state transfer scheme, and the ForCES protocol architecture itself (including requirements of ForCES Transport Mapping Layer (TML) as shown below). Specifications of ForCES PL are defined in [RFC5810]. ForCES Protocol Transport Mapping Layer (ForCES TML): A layer in the ForCES protocol architecture that specifically addresses the protocol message transportation issues, such as how the protocol messages are mapped to different transport media (like Stream Ogawa, et al. Standards Track [Page 6] RFC 7121 ForCES Intra-NE High Availability February 2014 Control Transmission Protocol (SCTP), IP, TCP, UDP, ATM, Ethernet, etc.), and how to achieve and implement reliability, security, etc. 2. RFC 5810 CE HA Framework To achieve CE High Availability (HA), FEs and CEs MUST interoperate per the definition in [RFC5810], which is repeated for contextual reasons in Section 2.1. It should be noted that in this default setup, which MUST be implemented by CEs and FEs requiring HA, the Fr plane is out of scope (and if available, is proprietary to an implementation). 2.1. RFC 5810 CE HA Support As mentioned earlier, although there can be multiple redundant CEs, only one CE actively controls FEs in a ForCES NE. In practice, there may be only one backup CE. At any moment in time, only one master CE can control an FE. In addition, the FE connects and associates to only the master CE. The FE and the CE are aware of the primary and one or more secondary CEs. This information (primary and secondary CEs) is configured on the FE and the CE during pre-association by the FEM and the CEM, respectively. This section includes a new normative description that updates [RFC5810] for the Cold Standby High Availability mechanism. Figure 2 below illustrates the ForCES message sequences that the FE uses to recover the connection in the currently defined cold standby scheme. Ogawa, et al. Standards Track [Page 7] RFC 7121 ForCES Intra-NE High Availability February 2014 FE CE Primary CE Secondary | | | | Association Establishment | | | Capabilities Exchange | | 1 |<------------------------->| | | | | | State Update | | 2 |<------------------------->| | | | | | | | | FAILURE | | | | Association Establishment, Capabilities Exchange| 3 |<----------------------------------------------->| | | | Event Report (primary CE down) | 4 |------------------------------------------------>| | | | State Update | 5 |<----------------------------------------------->| Figure 2: CE Failover for Cold Standby 2.1.1. Cold Standby Interaction with the ForCES Protocol HA parameterization in an FE is driven by configuring the FE Protocol Object (FEPO) LFB. The FEPO Control Element ID (CEID) component identifies the current master CE, and the component table BackupCEs identifies the configured backup CEs. The FEPO FE Heartbeat Interval (FEHI), CE Heartbeat Dead Interval (CEHDI), and CE Heartbeat policy help in detecting connectivity problems between an FE and CE. The CE failover policy defines how the FE should react on a detected failure. The FEObject FEState component [RFC5812] defines the operational forwarding status and control. The CE can turn off the FE's forwarding operations by setting the FEState to AdminDisable and can turn it on by setting it to OperEnable. Note: Section 5.1 of [RFC5812] has been updated by an erratum ([Err3487]) that describes the FEState as read-only when it should be read-write. Figure 3 illustrates the defined state machine that facilitates the recovery of the connection state. The FE connects to the CE specified on the FEPO CEID component. If it fails to connect to the defined CE, it moves it to the bottom of table BackupCEs and sets its CEID component to be the first CE retrieved from table BackupCEs. The FE then attempts to associate Ogawa, et al. Standards Track [Page 8] RFC 7121 ForCES Intra-NE High Availability February 2014 with the CE designated as the new primary CE. The FE continues through this procedure until it successfully connects to one of the CEs or until the CE Failover Timeout Interval (CEFTI) expires. FE tries to associate +-->-----+ | | (CE changes master || | | CE issues Teardown || +---+--------v----+ Lost association) && | Pre-association | CE failover policy = 0 | (Association | +------------>-->-->| in +<----+ | | progress) | | | | | | | +--------+--------+ | | CE Association | | CEFTI | Response V | timer | +------------------+ | expires | |FE issues CEPrimaryDown ^ | V | +-+-----------+ +------+-----+ | | (CE changes master || | Not | | | CE issues Teardown || | Associated | | | Lost association) && | +->---+ | Associated | CE failover policy = 1 |(May | FE | | | | Continue | try v | |-------->------->------>| Forwarding)| assn| | | Start CEFTI timer | |-<---+ | | | | +-------------+ +-------+----+ ^ | | Successful V | Association | | Setup | | (Cancel CEFTI timer) | +_________________________________________+ FE issues CEPrimaryDown event Figure 3: FE State Machine Considering HA There are several events that trigger mastership changes. The master CE may issue a mastership change (by changing the CEID component), it may tear down an existing association, or connectivity may be lost between the CE and FE. When communication fails between the FE and CE (which can be caused by either the CE or link failure but is not FE related), either the TML on the FE will trigger the FE PL regarding this failure or it Ogawa, et al. Standards Track [Page 9] RFC 7121 ForCES Intra-NE High Availability February 2014 will be detected using the Heartbeat messages between FEs and CEs. The communication failure, regardless of how it is detected, MUST be considered to be a loss of association between the CE and corresponding FE. If the FE's FEPO CE failover policy is configured to mode 0 (the default), it will immediately transition to the pre-association phase. This means that if association is later re-established with a CE, all FE states will need to be re-created. If the FE's FEPO CE failover policy is configured to mode 1, it indicates that the FE will run in HA restart recovery. In such a case, the FE transitions to the not associated state and the CEFTI timer [RFC5810] is started. The FE may continue to forward packets during this state, depending upon the value of the CEFailoverPolicy component of the FEPO LFB. The FE recycles through any configured backup CEs in a round-robin fashion. It first adds its primary CE to the bottom of table BackupCEs and sets its CEID component to be the first secondary retrieved from table BackupCEs. The FE then attempts to associate with the CE designated as the new primary CE. If it fails to re-associate with any CE and the CEFTI expires, the FE then transitions to the pre-association state and the FE will operationally bring down its forwarding path (and set the [RFC5812] FEObject FEState component to OperDisable). If the FE, while in the not associated state, manages to reconnect to a new primary CE before the CEFTI expires, it transitions to the associated state. Once re-associated, the CE may try to synchronize any state that the FE may have lost during disconnection. How the CE re-synchronizes such a state is out of scope for the current ForCES architecture but would typically constitute the issuing of new Config messages and queries. An explicit message (a Config message setting the primary CE component in the ForCES Protocol Object) from the primary CE can also be used to change the primary CE for an FE during normal protocol operation. In this case, the FE transitions to the not associated state and attempts to associate with the new CE. 2.1.2. Responsibilities for HA TML Level: 1. The TML controls logical connection availability and failover. 2. The TML also controls peer HA management. Ogawa, et al. Standards Track [Page 10] RFC 7121 ForCES Intra-NE High Availability February 2014 At this level, control of all lower layers, for example, the transport level (such as IP addresses, Media Access Control (MAC) addresses, etc.), and associated links going down are the role of the TML. PL Level: All other functionality, including configuring the HA behavior during setup, Control Element IDs (CE IDs) used to identify primary and secondary CEs, protocol messages used to report CE failure (event report), Heartbeat messages used to detect association failure, messages to change the primary CE (Config), and other HA-related operations described in Section 2.1, are the PL's responsibility. To put the two together, if a path to a primary CE is down, the TML would help recover from a failure by switching over to a backup path, if one is available. If the CE is totally unreachable, then the PL would be informed and it would take the appropriate actions described before. 3. CE HA Hot Standby In this section, we describe small extensions to the existing scheme to enable hot standby HA. To achieve hot standby HA, we aim to improve the specific goals defined in Section 1.1, namely: o How fast a backup CE becomes operational. o How fast the FEs associate with the new master CE. As described in Section 2.1, in the pre-association phase, the FEM configures the FE to make it aware of all the CEs in the NE. The FEM MUST configure the FE to make it aware of which CE is the master and MAY specify any backup CE(s). 3.1. Changes to the FEPO Model In order for the above to be achievable, there is a need to make a few changes in the FEPO model. Appendix A contains the xml definition of the new version 1.1 of the FEPO LFB. Ogawa, et al. Standards Track [Page 11] RFC 7121 ForCES Intra-NE High Availability February 2014 Changes from version 1 of the FEPO are: 1. Added four new datatypes: 1. CEStatusType -- an unsigned char to specify the status of a connection with a CE. Special values are: + 0 (Disconnected) represents that no connection attempt has been made with the CE yet + 1 (Connected) represents that the FE connection with the CE at the TML has completed successfully + 2 (Associated) represents that the FE has successfully associated with the CE + 3 (IsMaster) represents that the FE has associated with the CE and is the master of the FE + 4 (LostConnection) represents that the FE was associated with the CE at one point but lost the connection + 5 (Unreachable) represents that the FE deems this CE unreachable, i.e., the FE has tried over a period to connect to it but has failed 2. HAModeValues -- an unsigned char to specify a selected HA mode. Special values are: + 0 (No HA Mode) represents that the FE is not running in HA mode + 1 (HA Mode - Cold Standby) represents that the FE is in HA mode cold standby + 2 (HA Mode - Hot Standby) represents that the FE is in HA mode hot standby 3. Statistics -- a complex structure representing the communication statistics between the FE and CE. The components are: + RecvPackets, representing the packet count received from the CE + RecvBytes, representing the byte count received from the CE Ogawa, et al. Standards Track [Page 12] RFC 7121 ForCES Intra-NE High Availability February 2014 + RecvErrPackets, representing the erroneous packets received from the CE. This component logs badly formatted packets as well as good packets sent to the FE by the CE to set components whilst that CE is not the master. Erroneous packets are dropped (i.e., not responded to). + RecvErrBytes, representing the RecvErrPackets byte count received from the CE + TxmitPackets, representing the packet count transmitted to the CE + TxmitErrPackets, representing the error packet count transmitted to the CE. Typically, these would be failures due to communication. + TxmitBytes, representing the byte count transmitted to the CE + TxmitErrBytes, representing the byte count of errors from transmit to the CE 4. AllCEType -- a complex structure constituting the CE IDs, statistics, and CEStatusType to reflect connection information for one CE. Used in the AllCE's component array. 2. Appended two new components: 1. Read-only AllCEs to hold the status for all CEs. AllCEs is an array of the AllCEType. 2. Read-write HAMode of type HAModeValues to carry the HA mode used by the FE. 3. Added one additional event, PrimaryCEChanged, reporting the new master CE ID when there is a mastership change. Since no component from FEPO v1 has been changed, FEPO v1.1 retains backwards compatibility with CEs that know only version 1.0. These CEs, however, cannot make use of the HA options that the new FEPO provides. 3.2. FEPO Processing The FE's FEPO LFB version 1.1 AllCEs table contains all the CE IDs with which the FE may connect and associate. The ordering of the CE IDs in this table defines the priority order in which an FE will connect to the CEs. This table is provisioned initially from the Ogawa, et al. Standards Track [Page 13] RFC 7121 ForCES Intra-NE High Availability February 2014 configuration plane (FEM). In the pre-association phase, the first CE (lowest table index) in the AllCEs table MUST be the first CE with which the FE will attempt to connect and associate. If the FE fails to connect and associate with the first listed CE, it will attempt to connect to the second CE and so forth, and it cycles back to the beginning of the list until there is a successful association. The FE MUST associate with at least one CE. Upon a successful association, a component of the FEPO LFB, specifically the CEID component, identifies the current associated master CE. While it would be much simpler to have the FE not respond to any messages from a CE other than the master, in practice it has been found to be useful to respond to queries and heartbeats from backup CEs. For this reason, we allow backup CEs to issue queries to the FE. Configuration messages (SET/DEL) from backup CEs MUST be dropped by the FE and logged as received errors. Asynchronous events that the master CE has subscribed to, as well as heartbeats, are sent to all associated CEs. Packet redirects continue to be sent only to the master CE. The Heartbeat Interval, the CE Heartbeat (CEHB) policy, and the FE Heartbeat (FEHB) policy are global for all CEs (and changed only by the master CE). Figure 4 illustrates the state machine that facilitates connection recovery with HA enabled. Ogawa, et al. Standards Track [Page 14] RFC 7121 ForCES Intra-NE High Availability February 2014 FE tries to associate +-->-----+ | | (CE changes master || | | CE issues Teardown || +---+--------v----+ Lost association) && | Pre-association | CE failover policy = 0 | (Association | +------------>-->-->| in +<----+ | | progress) | | | | | | | +--------+--------+ | | CE Association | | CEFTI | Response V | timer | +------------------+ | expires | |FE issues CEPrimaryDown ^ | |FE issues PrimaryCEChanged ^ | V | +-+-----------+ +------+-----+ | | (CE changes master || | Not | | | CE issues Teardown || | Associated | | | Lost association) && | +->----------+ | Associated | CE failover policy = 1 |(May | find first | | | | Continue | associated v | |-------->------->------>| Forwarding)| CE or retry| | | Start CEFTI timer | | associating| | | | |-<----------+ | | | | +----+--------+ +-------+----+ | | ^ Found | associated CE | or newly | associated CE | V | (Cancel CEFTI timer) | +_________________________________________+ FE issues CEPrimaryDown event FE issues PrimaryCEChanged event Figure 4: FE State Machine Considering HA Once the FE has associated with a master CE, it moves to the post- association phase (associated state). It is assumed that the master CE will communicate with other CEs within the NE for the purpose of synchronization via the CE-CE interface. The CE-CE interface is out of scope for this document. An election result amongst CEs may result in the desire to change the mastership to a different associated CE; at which point, the current assumed master CE will instruct the FE to use a different master CE. Ogawa, et al. Standards Track [Page 15] RFC 7121 ForCES Intra-NE High Availability February 2014 FE CE#1 CE#2 ... CE#N | | | | | Association Establishment | | | | Capabilities Exchange | | | 1 |<------------------------->| | | | | | | | State Update | | | 2 |<------------------------->| | | | | | | | Association Establishment | | | Capabilities Exchange | | 3I|<-------------------------------------->| | ... ... ... ... |Association Establishment, Capabilities Exchange | 3N|<----------------------------------------------->| | | | | 4 |<------------------------->| | | . . . . 4x|<------------------------->| | | | FAILURE | | | | | | | Event Report (LastCEID changed) | | 5 |--------------------------------------->|------->| | Event Report (CE#2 is new master) | | 6 |--------------------------------------->|------->| | | | 7 |<-------------------------------------->| | . . . . 7x|<-------------------------------------->| | . . . . Figure 5: CE Failover for Hot Standby While in the post-association phase, if the CE failover policy is set to 1 and the HAMode is set to 2 (hot standby), then the FE, after successfully associating with the master CE, MUST attempt to connect and associate with all the CEs of which it is aware. Figure 5, steps #1 and #2 illustrates the FE associating with CE#1 as the master, and then proceeding to steps #3I to #3N, it shows the association with backup CEs CE#2 to CE#N. If the FE fails to connect or associate with some CEs, the FE MAY flag them as unreachable to avoid continuous attempts to connect. The FE MAY try to re-associate with unreachable CEs when possible. When the master CE, for any reason, is considered to be down, then the FE MUST try to find the first associated CE from the list of all CEs in a round-robin fashion. Ogawa, et al. Standards Track [Page 16] RFC 7121 ForCES Intra-NE High Availability February 2014 If the FE is unable to find an associated FE in its list of CEs, then it MUST attempt to connect and associate with the first from the list of all CEs and continue in a round-robin fashion until it connects and associates with a CE or the CEFTI timer expires. Once the FE selects an associated CE to use as the new master, the FE issues a PrimaryCEDown Event Notification to all associated CEs to notify them that the last primary CE went down (and what its identity was); a second event, PrimaryCEChanged, identifying the new master CE is sent as well to identify which CE the reporting FE considers to be the new master. In most HA architectures, there exists the possibility of split brain. However, in our setup, since the FE will never accept any configuration messages from any other than the master CE, we consider the FE to be fenced against data corruption from the other CEs that consider themselves as the master. The split-brain issue becomes mostly a CE-CE communication problem, which is considered to be out of scope. By virtue of having multiple CE connections, the FE switchover to a new master CE will be relatively much faster. The overall effect is improving the NE recovery time in case of communication failure or faults of the master CE. This satisfies the requirement we set to fulfill. 4. IANA Considerations Following the policies outlined in "Guidelines for Writing an IANA Considerations Section in RFCs" [RFC5226], the "Logical Functional Block (LFB) Class Names and Class Identifiers" namespace has been updated. A new column, LFB version, has been added to the table after the LFB Class Name. The table now reads as follows: +----------------+------------+-----------+-------------+-----------+ | LFB Class | LFB Class | LFB | Description | Reference | | Identifier | Name | Version | | | +----------------+------------+-----------+-------------+-----------+ Logical Functional Block (LFB) Class Names and Class Identifiers The rules defined in [RFC5812] apply, with the addition that entries must provide the LFB version as a string. Ogawa, et al. Standards Track [Page 17] RFC 7121 ForCES Intra-NE High Availability February 2014 Upon publication of this document, all current entries are assigned a value of 1.0. New versions of already defined LFBs MUST NOT remove the previous version entries. It would make sense to have LFB versions appear in sequence in the registry. The table SHOULD be sorted, and the sorting should be done by Class ID first and then by version. This document introduces the FE Protocol Object version 1.1 as follows: +------------+----------+---------+---------------------+-----------+ | LFB Class | LFB | LFB | Description | Reference | | Identifier | Class | Version | | | | | Name | | | | +------------+----------+---------+---------------------+-----------+ | 2 | FE | 1.1 | Defines parameters | [RFC7121] | | | Protocol | | for the ForCES | | | | Object | | protocol operation | | +------------+----------+---------+---------------------+-----------+ Logical Functional Block (LFB) Class Names and Class Identifiers 5. Security Considerations Security considerations, as defined in Section 9 of [RFC5810], apply to securing each CE-FE communication. Multiple CEs associated with the same FE still require the same procedure to be followed on a per- association basis. It should be noted that since the FE is initiating the association with a CE, a CE cannot initiate association with the FE and such messages will be dropped. Thus, the FE is secured from rogue CEs that are attempting to associate with it. CE implementers should have in mind that once associated, the FE cannot distinguish whether the CE has been compromised or has been malfunctioning while not losing connectivity. Securing the CE is out of scope of this document. While the CE-CE plane is outside the current scope of ForCES, we recognize that it may be subjected to attacks that may affect the CE- FE communication. Ogawa, et al. Standards Track [Page 18] RFC 7121 ForCES Intra-NE High Availability February 2014 The following considerations should be made: 1. Secure communication channels should be used between CEs for coordination and keeping of state to at least avoid connection of malicious CEs. 2. The master CE should take into account DoS and Distributed Denial-of-Service (DDoS) attacks from malicious or malfunctioning CEs. 3. CEs should take into account the split-brain issue. There are currently two fail-safes in the FE: Firstly, the FE has the CEID component that denotes which CE is the master. Secondly, the FE does not allow BackupCEs to configure the FE. However, backup CEs that consider that the master CE has dropped should, as masters themselves, first do a sanity check and query the FE CEID component. 6. References 6.1. Normative References [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an IANA Considerations Section in RFCs", BCP 26, RFC 5226, May 2008. [RFC5810] Doria, A., Hadi Salim, J., Haas, R., Khosravi, H., Wang, W., Dong, L., Gopal, R., and J. Halpern, "Forwarding and Control Element Separation (ForCES) Protocol Specification", RFC 5810, March 2010. [RFC5812] Halpern, J. and J. Hadi Salim, "Forwarding and Control Element Separation (ForCES) Forwarding Element Model", RFC 5812, March 2010. 6.2. Informative References [Err3487] RFC Errata, Errata ID 3487, RFC 5812, . [RFC3654] Khosravi, H. and T. Anderson, "Requirements for Separation of IP Control and Forwarding", RFC 3654, November 2003. Ogawa, et al. Standards Track [Page 19] RFC 7121 ForCES Intra-NE High Availability February 2014 [RFC3746] Yang, L., Dantu, R., Anderson, T., and R. Gopal, "Forwarding and Control Element Separation (ForCES) Framework", RFC 3746, April 2004. Ogawa, et al. Standards Track [Page 20] RFC 7121 ForCES Intra-NE High Availability February 2014 Appendix A. New FEPO Version The xml has been validated against the schema defined in [RFC5812]. CEHBPolicyValues The possible values of the CE Heartbeat policy uchar CEHBPolicy0 The CE will send heartbeats to the FE every CEHDI timeout if no other messages have been sent since. CEHBPolicy1 The CE will not send heartbeats to the FE FEHBPolicyValues The possible values of the FE Heartbeat policy uchar FEHBPolicy0 The FE will not generate any heartbeats to the CE Ogawa, et al. Standards Track [Page 21] RFC 7121 ForCES Intra-NE High Availability February 2014 FEHBPolicy1 The FE generates heartbeats to the CE every FEHI if no other messages have been sent to the CE. FERestartPolicyValues The possible values of the FE restart policy uchar FERestartPolicy0 The FE restarts its state from scratch HAModeValues The possible values of HA modes uchar NoHA The FE is not running in HA mode ColdStandby The FE is running in HA mode cold standby Ogawa, et al. Standards Track [Page 22] RFC 7121 ForCES Intra-NE High Availability February 2014 HotStandby The FE is running in HA mode hot standby CEFailoverPolicyValues The possible values of the CE failover policy uchar CEFailoverPolicy0 The FE should stop functioning immediately and transition to the FE OperDisable state CEFailoverPolicy1 The FE should continue forwarding even without an associated CE for CEFTI. The FE goes to FE OperDisable when the CEFTI expires and there is no association. Requires graceful restart support. FEHACapab The supported HA features uchar GracefullRestart The FE supports graceful restart Ogawa, et al. Standards Track [Page 23] RFC 7121 ForCES Intra-NE High Availability February 2014 HA The FE supports HA CEStatusType Status values. Status for each CE uchar Disconnected No connection attempt with the CE yet Connected The FE connection with the CE at the TML has been completed Associated The FE has associated with the CE IsMaster The CE is the master (and associated) LostConnection The FE was associated with the CE but lost the connection Unreachable The CE is deemed as unreachable by the FE Ogawa, et al. Standards Track [Page 24] RFC 7121 ForCES Intra-NE High Availability February 2014 StatisticsType Statistics Definition RecvPackets Packets received uint64 RecvErrPackets Packets received from the CE with errors uint64 RecvBytes Bytes received from the CE uint64 RecvErrBytes Bytes received from the CE in Error uint64 TxmitPackets Packets transmitted to the CE uint64 TxmitErrPackets Packets transmitted to the CE that incurred errors uint64 TxmitBytes Bytes transmitted to the CE uint64 TxmitErrBytes Ogawa, et al. Standards Track [Page 25] RFC 7121 ForCES Intra-NE High Availability February 2014 Bytes transmitted to the CE that incurred errors uint64 AllCEType Table type for the AllCE component CEID ID of the CE uint32 Statistics Statistics per the CE StatisticsType CEStatus Status of the CE CEStatusType FEPO The FE Protocol Object, with new CEHA 1.1 CurrentRunningVersion Currently running the ForCES version uchar FEID Unicast FEID uint32 Ogawa, et al. Standards Track [Page 26] RFC 7121 ForCES Intra-NE High Availability February 2014 MulticastFEIDs The table of all multicast IDs uint32 CEHBPolicy The CE Heartbeat policy CEHBPolicyValues CEHDI The CE Heartbeat Dead Interval in milliseconds uint32 FEHBPolicy The FE Heartbeat policy FEHBPolicyValues FEHI The FE Heartbeat Interval in milliseconds uint32 CEID The primary CE this FE is associated with uint32 BackupCEs Ogawa, et al. Standards Track [Page 27] RFC 7121 ForCES Intra-NE High Availability February 2014 The table of all backup CEs other than the primary uint32 CEFailoverPolicy The CE failover policy CEFailoverPolicyValues CEFTI The CE Failover Timeout Interval in milliseconds uint32 FERestartPolicy The FE restart policy FERestartPolicyValues LastCEID The primary CE this FE was last associated with uint32 HAMode The HA mode used HAModeValues AllCEs The table of all CEs Ogawa, et al. Standards Track [Page 28] RFC 7121 ForCES Intra-NE High Availability February 2014 AllCEType SupportableVersions The table of ForCES versions that FE supports uchar HACapabilities The table of HA capabilities the FE supports FEHACapab PrimaryCEDown The primary CE has changed LastCEID LastCEID PrimaryCEChanged A new primary CE has been selected CEID Ogawa, et al. Standards Track [Page 29] RFC 7121 ForCES Intra-NE High Availability February 2014 CEID Ogawa, et al. Standards Track [Page 30] RFC 7121 ForCES Intra-NE High Availability February 2014 Authors' Addresses Kentaro Ogawa NTT Corporation 3-9-11 Midori-cho Musashino-shi, Tokyo 180-8585 Japan EMail: k.ogawa@ntt.com Weiming Wang Zhejiang Gongshang University 18 Xuezheng Str., Xiasha University Town Hangzhou 310018 P.R. China Phone: +86 571 28877751 EMail: wmwang@zjsu.edu.cn Evangelos Haleplidis University of Patras Department of Electrical and Computer Engineering Patras 26500 Greece EMail: ehalep@ece.upatras.gr Jamal Hadi Salim Mojatatu Networks Suite 400, 303 Moodie Dr. Ottawa, Ontario K2H 9R4 Canada EMail: hadi@mojatatu.com Ogawa, et al. Standards Track [Page 31]