Internet Engineering Task Force (IETF) W. WangInternet-DraftRequest for Comments: 6984 Zhejiang Gongshang University Updates: 6053(if approved)K. OgawaIntended status:Category: Informational NTT CorporationExpires: December 04, 2013 E.H.ISSN: 2070-1721 E. Haleplidis University of Patras M. Gao Hangzhou BAUD Networks J. Hadi Salim Mojatatu NetworksJune 02,July 2013 Interoperability Report for Forwarding and Control Element Separation (ForCES)draft-ietf-forces-interop-09Abstract This document captures the results of the second Forwarding and Control Element Separation (ForCES) interoperability testwhichthat took place on February 24-25,20112011, in the Internet Technology Lab (ITL)ofat Zhejiang Gongshang University, China.RFC 6053 reported theThe results of the first ForCES interoperabilitytest,test were reported in RFC 6053, and this document updates RFC 6053 by providing further interoperability results. 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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. ForCES Protocol . . . . . . . . . . . . . . . . . . . . . 3 1.2. ForCES FE Model . . . . . . . . . . . . . . . . . . . . . 4 1.3. Transport Mapping Layer . . . . . . . . . . . . . . . . . 4 1.4. Definitions . . . . . . . . . . . . . . . . . . . . . . . 4 2. Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 2.1. Date, Location, and Participants . . . . . . . . . . . . . 4 2.2. Testbed Configuration . . . . . . . . . . . . . . . . . . 5 2.2.1.ParticipantsParticipants' Access . . . . . . . . . . . . . . . . . 5 2.2.2. Testbed Configuration . . . . . . . . . . . . . . . . 6 3. Scenarios . . . . . . . . . . . . . . . . . . . . . . . . . . 7 3.1. Scenario 1 - LFB Operation . . . . . . . . . . . . . . . . 7 3.2. Scenario 2 - TML with IPsec . . . . . . . . . . . . . . . 8 3.3. Scenario 3 - CE High Availability . . . . . . . . . . . . 9 3.4. Scenario 4 - PacketforwardingForwarding . . . . . . . . . . . . .11. 10 4. Test Results . . . . . . . . . . . . . . . . . . . . . . . .13. 14 4.1. Test of LFB OperationTest .. . . . . . . . . . . . . . . . . .1314 4.2. Test of TML with IPsecTest .. . . . . . . . . . . . . . . . . .1920 4.3. Test of CE High AvailabilityTest .. . . . . . . . . . . . . . .1920 4.4. Test of Packet ForwardingTest .. . . . . . . . . . . . . . . .2021 5. Discussions . . . . . . . . . . . . . . . . . . . . . . . . .2223 5.1. On Data Encapsulation Format . . . . . . . . . . . . . .22 6. Contributors . . . .. 23 6. Security Considerations . . . . . . . . . . . . . . . . . . .2526 7.Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 25 8. IANA Considerations . . . . . . . . . . . . . .References . . . . . . .26 9. Security Considerations. . . . . . . . . . . . . . . . . . . 2610.7.1. Normative References . . . . . . . . . . . . . . . . . . .. . . . . .2610.1. Normative7.2. Informative References . . . . . . . . . . . . . . . . . . 2610.2. Informative References . .Appendix A. Acknowledgements . . . . . . . . . . . . . . .26 Authors' Addresses. . . 28 Appendix B. Contributors . . . . . . . . . . . . . . . . . . . . 28 1. Introduction This document captures the results of the second interoperability test of the Forwarding and Control Element Separation (ForCES)whichthat took place on February 24-25,20112011, in the Internet Technology Lab (ITL)ofat Zhejiang Gongshang University, China. The test involved protocol elements described in severaldocumentsdocuments, namely: - ForCES Protocol [RFC5810] - ForCES Forwarding Element (FE) Model [RFC5812] - ForCES Transport Mapping Layer (TML) [RFC5811] The test also involved protocol elements described in the then- current versions of two Internet-Drafts. Although these documents have subsequently been revised and advanced, it is important to understand which versions of the work were used during this test. The then-current Internet-Drafts are: -ForCES"ForCES Logical Function Block (LFB)Library [I-D.ietf-forces-lfb-lib-03].Library" (December 2010) [LFB-LIB] -ForCES"ForCES Intra-NE HighAvailability [I-D.ietf-forces-ceha-00].Availability" (October 2010) [CEHA] Note: The'ForCESForCES Logical Function Block (LFB)Library'Library documenthas advanced and beenwas publishedby IETFasRFC 6956.[RFC6956]. Three independent ForCES implementations participated in the test. Scenarios of ForCES LFB Operation, TML with IPsec,CEControl Element HighAvailability,Availability (CEHA), and Packet Forwarding were constructed. Series of testing items for every scenario were carried out and interoperability results were achieved.PopularThe popular packet analyzersEthereal/Wireshark[Ethereal]Ethereal/Wireshark [Ethereal] andTcpdump[Tcpdump]Tcpdump [Tcpdump] were used to verify the wire results. This document is an update toRFC 6053,[RFC6053], which captured the results of the first ForCES interoperability test. The first test on ForCES was held in July 2008 at the University of Patras, Greece. That test focused on validating the basic semantics of the ForCES protocol and ForCESFEForwarding Element (FE) model. 1.1. ForCES Protocol The ForCES protocol works in a master-slave mode in whichForwarding Elements (FEs)FEs are slaves and Control Elements (CEs) are masters. The protocol includes commands for transport of Logical Function Block (LFB) configuration information, association setup, status,andevent notifications, etc. The reader is encouraged to read the ForCES protocol specification [RFC5810] for further information. 1.2. ForCES FE Model The ForCESForwarding Element (FE)FE model [RFC5812] presents a formal way to define FELogical Function Blocks (LFBs)LFBs using XML. LFB configuration components, capabilities, and associated events are defined when the LFB is formally created. The LFBs within the FE are accordingly controlled in a standardized way by the ForCES protocol. 1.3. Transport Mapping Layer The ForCES Transport Mapping Layer (TML) transports the ForCESProtocol Layer (PL)protocol layer messages. The TML is where the issues of how to achievetransport leveltransport-level reliability, congestion control, multicast, ordering,etcetc., are handled. It is expected that more than one TML will be standardized. RFC 5811 specifiesan SCTP-Based Transport Mapping Layer (TML) for ForCES protocol, whicha TML that is based on the Stream Control Transmission Protocol (SCTP) and is a mandated TML for ForCES. See RFC 5811 for more details. 1.4. Definitions This document follows the terminology defined byForCES relatedForCES-related documents, includingRFC3654, RFC3746, RFC5810, RFC5811, RFC5812, RFC5813,[RFC3654], [RFC3746], [RFC5810], [RFC5811], [RFC5812], [RFC5813], etc. 2. Overview 2.1. Date, Location, and Participants The second ForCES interoperability test meeting was held by the IETF ForCES Working Group on February 24-25, 2011, and was chaired by Jamal Hadi Salim. Three independent ForCES implementations participated in the test: o Zhejiang Gongshang University/Hangzhou BAUD Corporation of Information and Networks Technology (Hangzhou BAUD Networks), China. This implementation is referred to as "ZJSU" orin some cases"Z" inthethis document for the sake of brevity. o NTT Corporation, Japan. This implementation is referred to as "NTT" orin some cases"N" inthethis document for the sake of brevity. o The University of Patras, Greece. This implementation is referred to as "UoP" orin some cases"P" inthethis document for the sake of brevity. Two other organizations, Mojatatu Networks and Hangzhou BAUD Networks Corporation, which independently extended two differentwell knownwell-known public domain protocol analyzers, Ethereal/Wireshark [Ethereal] and Tcpdump [Tcpdump], also participated in theinteropinteroperability test. During theinteroperabilitytest, the two protocol analyzers were used to verify the validity (and in some cases, the semantics) of ForCES protocolmessages and in some cases semantics.messages. Some issues related to interoperability among implementations were discovered. Most of the issues were solved on site during the test. The most contentious issue found was on the format of encapsulation for the protocolTLV (ReferTLVs (refer to Section5.1 ).5.1). Some errata related to the ForCES document were found by the interoperability test. The erratahas been reported tofound in relatedIETF RFCs.RFCs have also been reported. At times, interoperability testing was exercised between two instead of all three representative implementationsdue to abecause the third onelackinglacked a specific feature; however, in ensuing discussions, all implementers mentioned they would be implementing any missing features in the future. 2.2. Testbed Configuration 2.2.1.ParticipantsParticipants' Access NTT and ZJSU were physicallyattended on sitepresent for the testing at the Internet Technology Lab (ITL)ofat Zhejiang Gongshang University in China. The implementation team from the University of Patrasimplementationjoined remotely from Greece. The chair, Jamal Hadi Salim, joined remotely from Canada by usingthe TeamviewerTeamViewer as the monitoringtool[Teamviewer].tool [TeamViewer]. The approachiswas as shown in Figure 1. In the figure, FE/CE refers to the FE or CE that the implementer may act as alternatively. +---------+ +----++----------++------------+ | FE/CE | | |+---|Monitoring|+---| Monitoring | | ZJSU |-----| | /\/\/\/\/\ ||(TeamViewer)|(TeamViewer)| +---------+ | | \Internet/ | | Mojatatu | |LAN |----/ \--|+----------++------------+ +---------+ | | \/\/\/\/\/ |+----------++------------+ | FE/CE |-----| | | | FE/CE | | NTT | | | +---| UoP | +---------+ +----++----------++------------+ Figure 1: Access for Participants As specified inRFC 5811,[RFC5811], all CEs and FEsshall implementimplemented IPsecsecurityin the TML. On theinternetInternet boundary, gateways used must allow for IPsec, the SCTPprotocolprotocol, and SCTP ports as defined in the ForCESSCTP-TML [RFC5811] .SCTP-based TML document [RFC5811]. 2.2.2. Testbed Configuration The CEs and FEs fromZJSUZJSU's andNTTNTT's implementations were physically located within the ITL Labofat Zhejiang Gongshang University and connected together using Ethernet switches. The configuration can be seen in Figure 2. In the figure,theSmartBits [SmartBits] is athird-partythird- party routing protocol testingmachine, whichmachine that acts as a router runningOSPFOpen Shortest Path First (OSPF) andRIPRIP, andexchangedexchanges routing protocol messages with ForCES routers in the network. Connection to the Internet was via anADSLAsymmetric Digital Subscriber Line (ADSL) channel. /\/\/\/\/\ \Internet/ / \ \/\/\/\/\/ | |(ADSL) |+------------------------------------------------------------------++-------------------------------------------------------------------+ | LAN (10.20.0.0/24) |+------------------------------------------------------------------++-------------------------------------------------------------------+ | | | | | | | | | | | | |.222 |.230 |.221 |.179 |.231 |.220 +-----+ +-----+ +-----+ +-----+ +-----+ +---------+ | CE | | CE | | | | | | | | Protocol| |ZJSU | | NTT | | FE1 |.1 .2| FE |.1 .2| FE2 | | Analyzer| +-----+ +-----+ |ZJSU |---------| NTT |---------|ZJSU | +---------+ +---------| |192.169. | | 192.168.| |------+ | .2 +-----+ 20.0.24 +-----+ 30.0/24+-----+ .2 | | .12| |.12 | | | | | 192.168.50.0/24 | |192.168.60.0/24 | 192.168.10.0/24 192.168.40.0/24 | .1 | |.11 |.11 |.1 +--------+ +--------------------------------------+ +--------+ |Terminal| |SmartbitsSmartBits | |Terminal| +--------+ +--------------------------------------+ +--------+ Figure 2: Testbed Configuration Located in the ITL Lab, China The CE and FE from the UoP implementation were located within the University of Patras, Greece, and were connected together usingLANLAN, as shown in Figure 3. Connection to the Internet was via a VPN channel. /\/\/\/\/\ \Internet/ / \ \/\/\/\/\/ | |(VPN) | +------------------------------------+ | LAN | +------------------------------------+ | | | | | | +------+ +--------+ +------+ | FE | |Protocol| | CE | | UoP | |Analyzer| | UoP | +------+ +--------+ +------+ Figure 3: Testbed Configuration Located in the University ofPatras,GreecePatras, Greece The testbeds above were then able to satisfy the requirements of all interoperability test scenarios in this document. 3. Scenarios 3.1. Scenario 1 - LFB Operation This scenario was designed to test the interoperabilityonof LFB operations among the participants. The connection diagram for the participants isasshown in Figure 4. +------+ +------+ +------+ +------+ +------+ +------+ | CE | | CE | | CE | | CE | | CE | | CE | | ZJSU | | NTT | | ZJSU | | UoP | | NTT | | UoP | +------+ +------+ +------+ +------+ +------+ +------+ | | | | | | | | | | | | +------+ +------+ +------+ +------+ +------+ +------+ | FE | | FE | | FE | | FE | | FE | | FE | | NTT | | ZJSU | | UoP | | ZJSU | | UoP | | NTT | +------+ +------+ +------+ +------+ +------+ +------+ Figure 4: Scenario for LFB Operation In order to make interoperability more credible, the three implementers were required to carry out the testin a wayacting as a CE or FE alternatively. As a result, every LFB operation was combined with6six scenarios, as shown by Figure 4. The test scenario was designed with the followingpurposes:purposes. Firstly, the scenario was designed to verify all kinds of protocol messages with their complex data formats, which were defined inRFC 5810. Specially,[RFC5810]. Specifically, we tried to verify the data format of aPATH-DATAPATH-DATA-TLV with nestedPATH-DATAs,PATH-DATA-TLVs, and theoperation(SET,operation (SET, GET, and DEL) of an array or an array with a nested array. Secondly, the scenario was designed to verify the definition of ForCES LFB Library[I-D.ietf-forces-lfb-lib-03],[LFB-LIB], which defined a base set of ForCES LFB classes for typical router functions. Successfultesttests under this scenario would help the validity of the LFB definitions. 3.2. Scenario 2 - TML with IPsec This scenario was designed to implement a TML with IPsec, which was the requirement defined by RFC 5811. TML with IPsec was not implemented and tested in the first ForCES interoperabilitytesttest, as reportedbyin RFC 6053. For this reason, in this interoperability test, we specifically designed the test scenario to verify the TML over IPsec channel. In this scenario, tests on LFB operations for Scenario 1 were repeated with the difference that TML was secured via IPsec. This setup scenario allowed us to verify whether all interactions between the CE and FE could be made correctly under an IPsec TML environment. The connection diagram for this scenario is shownasin Figure 5. Because an unfortunate problem with the test system in the UoP prevented the deployment of IPsec over TML, this test only took place between the test systems in ZJSU and NTT. +------+ +------+ | CE | | CE | | ZJSU | | NTT | +------+ +------+ | | |TML over IPsec |TML over IPsec +------+ +------+ | FE | | FE | | NTT | | ZJSU | +------+ +------+ Figure 5: Scenario for LFB Operation with TML over IPsec In this scenario, ForCES TML was run over the IPsec channel. Implementers joined in this interoperabilityusedtest using the samethird- partythird-party software 'Racoon' [Racoon] to establish the IPsec channel. The Racoon in NetBSD is anIKE daemon performing the IPsecInternet Key Exchange (IKE) daemon that performs the key exchange with the peers. BothIKE v1IKEv1 andv2IKEv2 are supported by Racoon inlinuxLinux 2.6, andthe v2IKEv2 was adopted in the interop test.SADThe Security Association Database (SAD) andSPDSecurity Policy Database (SPD) were necessary for the test, setups of which were in the Racoon configuration file.ESPThe Encapsulating Security Payload (ESP) was specified in the SAD and SPD in the Racoon configuration file. ZJSU and NTTmadeconducted a successful test with the scenario, and thefollowingIPsec requirement items in [RFC5812] wererealized: o Internet Key Exchange (IKE) with certificates for endpoint authentication. o Transport Mode Encapsulating Security Payload (ESP), HMAC-SHA1-96 for message integrity protection.realized. 3.3. Scenario 3 - CE High Availability CE High Availability (CEHA) was tested based on the ForCES CEHA document[I-D.ietf-forces-ceha-00][CEHA]. The design of the setup and the scenario for the CEHA were simplified so as to focus mostly on the mechanics of the CEHA, which were: o Associating with more than one CE. o Switching to a backup CE on a master CE failure. The connection diagram for the scenario isasshown in Figure 6. master standby master standby +------+ +------+ +------+ +------+ | CE | | CE | | CE | | CE | | ZJSU | | UoP | | NTT | | UoP | +------+ +------+ +------+ +------+ | | | | +----------+ +-----------+ | | +------+ +------+ | FE | | FE | | UoP | | UoP | +------+ +------+ (a) (b) Figure 6: Scenario for CE High Availability In thisscenarioscenario, one FE was connected and associated to a master CE and a backup CE. In the pre-association phase, the FE would be configured to have ZJSU's or NTT's CE as the master CE and the UoP's CE as the standby CE. The CEFailoverPolicy component of the FE Protocol Object LFB that specified whether the FE was in High Availability mode (value 2 or 3) wouldeitherbe set either in thepre-associationpre- association phase by theFEMFE interface or in the post-association phase by the master CE. If the CEFailoverPolicy value was set to 2 or 3, the FE (in the post- association phase) would attempt to connect and associate with the standby CE. When the master CE was deemed disconnected, either by a TearDown, Loss ofHeartbeatsHeartbeats, or physically disconnected, the FE would assume that the standby CE was now the master CE. The FE would then send an Event Notification, Primary CE Down, to all associatedCEs, onlyCEs (only the standby CE in thiscase,case) with the value of the new masterCEID.Control Element ID (CEID). The standby CE would then respond by sending a configuration message to the CEID component of the FE Protocol Object with its own ID to confirm that the CE considered itselfasthe master as well. The steps of the CEHA test scenario were as follows: 1. In the pre-association phase,setup ofthe FE is set up with the master CE and the backupCECE. 2. The FEconnectingconnects andassociatingassociates with the master CE. 3. When CEFailoverPolicy is set to 2 or 3, the FEwill connectconnects andassociateassociates with the backup CE. 4. Once the master CE is considereddisconnecteddisconnected, then the FE chooses the firstAssociatedassociated backup CE. 5. It sends an Event Notificationspecifyingthat specifies the master CE is down andwho is nowidentifies the new master CE. 6. The new master CE sends a SET Configuration message to the FE; the FEsettingthen sets the CEID value towho is nowthe new master CE completing the switch. 3.4. Scenario 4 - PacketforwardingForwarding This test scenario was conducted to verify LFBs like RedirectIn, RedirectOut, IPv4NextHop,IPv4UcastLPMand IPv4UcastLPM, which were defined by the ForCES LFB library document[I-D.ietf-forces-lfb-lib-03],[LFB-LIB], and more importantly, to verify the combination of the LFBs to implement IP packet forwarding. The connection diagram for this scenario isasshown in Figure 7. +------+ | CE | | NTT | +------+ | ^ | | OSPF | +-------> +------+ +------+ +--------+ | FE | | OSPF | +--------+ |Terminal|------| ZJSU |-------|Router|------|Terminal| +--------+ +------+ +------+ +--------+ <--------------------------------------------> Packet Forwarding (a) +------+ | CE | | ZJSU | +------+ ^ | ^ OSPF | | | OSPF <-----+ | +-----> +-------+ +------+ +------+ +--------+ | OSPF | | FE | | OSPF | +--------+ |Terminal|----|Router |----| NTT |-----|Router|--|Terminal| +--------+ +-------+ +------+ +------+ +--------+ <--------------------------------------------> Packet Forwarding (b) +------+ +------+ | CE | | CE | | NTT | | ZJSU | +------+ +------+ | ^ ^ | | | OSPF | | | +----------+ | +------+ +------+ +--------+ | FE | | FE | +--------+ |Terminal|------| ZJSU |-------| NTT |------|Terminal| +--------+ +------+ +------+ +--------+ <--------------------------------------------> Packet Forwarding (c) Figure 7: Scenario for IP PacketforwardingForwarding In case (a),aNTT's CEby NTTwas connected toanZJSU's FEby ZJSUto form a ForCES router. ASmartbitsSmartBits [SmartBits] test machine equipped withitsrouting protocol softwarewerewas used to simulate an OSPF router andwerewas connected with the ForCES router to try to exchange OSPFhelloHello packets andLSALink State Advertisement (LSA) packets among them. Terminals were simulated bySmartbitsSmartBits to send and receive packets. As a result, the CE in the ForCES routerneedneeded to be configured to run and support the OSPF routing protocol. In case (b),aZJSU'S CEby ZJSUwas connected toanNTT'S FEby NTTto form a ForCES router. Two routers running OSPF were simulated and connected to the ForCES router to test if the ForCES router could support the OSPF protocol and support packet forwarding. In case (c), two ForCES routers wereconstructed. Oneconstructed; one was with NTT's CEby NTTandFE by ZJSUZJSU's FE, and the other wasopposite.with NTT's FE and ZJSU's CE. OSPF and packet forwarding were tested in the environment.TestingThe testing process for this scenario isasshown below: 1. Boot terminals and routers, and set the IP addresses of their interfaces. 2. Boot the CE and FE. 3. Establish an association between the CE and FE, and set the IP addresses ofFEsthe FE interfaces. 4. Start OSPF among the CE and routers, and setFIBthe Forwarding Information Base (FIB) on the FE. 5. Send packets between terminals. 4. Test Results 4.1. Test of LFB OperationTestThe testresult is asresults are reportedbyin Figure 8.For the convenience sake, asAs mentioned earlier, for convenience, the following abbreviationsof 'Z'are used in thetable meanstable: "Z" for the implementation fromZJSU ,'N'ZJSU, "N" for the implementation from NTT, and'P'implementation"P" for the implementation from the UoP. +-----+----+-----+-----+--------------+-------------------+---------+ |Test#| CE |FE(s)|Oper | LFB | Component | Result | | | | | | | /Capability | | +-----+----+-----+-----+--------------+-------------------+---------+ | 1 | Z | N | GET | FEObject | LFBTopology | Success | | | N | Z | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 2 | Z | N | GET | FEObject | LFBSelector | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 3 | Z | N | GET | EtherPHYCop | PHYPortID | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 4 | Z | N | GET | EtherPHYCop | AdminStatus | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 5 | Z | N | GET | EtherPHYCop | OperStatus | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 6 | Z | N | GET | EtherPHYCop | AdminLinkSpeed | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 7 | Z | N | GET | EtherPHYCop | OperLinkSpeed | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 8 | Z | N | GET | EtherPHYCop | AdminDuplexSpeed | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 9 | Z | N | GET | EtherPHYCop | OperDuplexSpeed | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 10 | Z | N | GET | EtherPHYCop | CarrierStatus | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 11 | Z | N | GET | EtherMACIn | AdminStatus | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 12 | Z | N | GET | EtherMACIn | LocalMacAddresses | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 13 | Z | N | GET | EtherMACIn | L2Bridging | Success | | | N | Z | | | PathEnable | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 14 | Z | N | GET | EtherMACIn | PromiscuousMode | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 15 | Z | N | GET | EtherMACIn | TxFlowControl | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 16 | Z | N | GET | EtherMACIn | RxFlowControl | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 17 | Z | N | GET | EtherMACIn | MACInStats | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 18 | Z | N | GET | EtherMACOut | AdminStatus | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 19 | Z | N | GET | EtherMACOut | MTU | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 20 | Z | N | GET | EtherMACOut | TxFlowControl | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 21 | Z | N | GET | EtherMACOut | TxFlowControl | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 22 | Z | N | GET | EtherMACOut | MACOutStats | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 23 | Z | N | GET | ARP |PortV4AddrInfoTable| Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 24 | Z | N | SET | ARP |PortV4AddrInfoTable| Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 25 | Z | N | DEL | ARP |PortV4AddrInfoTable| Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 26 | Z | N | SET | EtherMACIn | LocalMACAddresses | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 27 | Z | N | SET | EtherMACIn | MTU | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 28 | Z | N | SET | IPv4NextHop | IPv4NextHopTable | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 29 | Z | N | SET | IPv4UcastLPM | IPv4PrefixTable | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 30 | Z | N | DEL | IPv4NextHop | IPv4NextHopTable | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 31 | Z | N | DEL | IPv4UcastLPM | IPv4PrefixTable | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 32 | Z | N | SET | EtherPHYCop | AdminStatus | Success | | | N | Z | | | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 33 | Z | N | SET | Ether | VlanInputTable | Success | | | N | Z | | Classifier | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 34 | Z | N | DEL | Ether | VlanInputTable | Success | | | N | Z | | Classifier | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 35 | Z | N | SET | Ether | VlanOutputTable | Success | | | N | Z | | Encapsulator | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | | | | | | | | | | 36 | Z | N | DEL | Ether | VlanOutputTable | Success | | | N | Z | | Encapsulator | | Success | | | Z | P | | | | Success | | | P | Z | | | | Success | | | N | P | | | | Success | | | P | N | | | | Success | +-----+----+-----+-----+--------------+-------------------+---------+ Figure 8:LFB OperationTest Results for LFB Operation Note ontesttests #1 and #2: On the wire format of encapsulation on array, only the case ofFULLDATA vs SPARSEDATAFULLDATA-TLV vs. SPARSEDATA-TLV was tested.ItWhen we use the ForCES protocol, it is very common for the CE toget information ofuse the FEobject LFBin FE so astoknow statusget information onall activeLFBs and their topology in the FE. Hence, the two tests were specificallydesigned.made. 4.2. Test of TML with IPsecTestIn this scenario, the ForCES TML was run over IPsec. Implementers joined this interoperability test and used the same third-party tool software 'Racoon' [Racoon] to establish the IPsec channel. Typical LFB operation tests as in Scenario 1 were repeated with theIPsec enabledIPsec-enabled TML. As mentioned, this scenario only took place between implementersoffrom ZJSU and NTT. The TML with IPsec test results are reportedbyin Figure 9. +-----+----+-----+-----+--------------+-------------------+---------+ |Test#| CE |FE(s)|Oper | LFB | Component/ | Result | | | | | | | Capability | | +-----+----+-----+-----+--------------+-------------------+---------+ | 1 | Z | N | GET | FEObject | LFBTopology | Success | | | N | Z | | | | Success | | | | | | | | | | 2 | Z | N | GET | FEObject | LFBSelectors | Success | | | N | Z | | | | Success | | | | | | | | | | 3 | Z | N | SET | Ether | VlanInputTable | Success | | | N | Z | | Classifier | | Success | | | | | | | | | | 4 | Z | N | DEL | Ether | VlanInputTable | Success | | | N | Z | | Classifier | | Success | +-----+----+-----+-----+--------------+-------------------+---------+ Figure 9: Test Results for TML with IPsecTest Results4.3. Test of CE High AvailabilityTestIn this scenario, one FE connected and associated with a master CE and a backup CE. When the master CE was deemed disconnected, the FEwould attemptattempted to find another associated CE to become the master CE. The CEHAscenarioscenario, aswasdescribedbyin Scenario33, was completed successfully for both setups. Due to a bug in one of the FEs, an interesting issue was caught: it was observed that the buggy FE took up to a second to failover. It was eventually found that the issue was due to the FE's prioritization of the different CEs. All messages from the backup CE were being ignored unless the master CE was disconnected. While the bug was fixed and the CEHA scenario was completed successfully, the authors felt it was important to capture the implementation issue in this document. The recommended approach is the following: o The FE should receive and handle messages first from the master CE on all priority channels to maintain proper functionality and then receive and handle messages from the backup CEs. o Only when the FE is attempting to associate with the backupCEs, thenCEs should the FEshouldreceive and handle messages per priority channel from all CEs. When all backup CEs are associated with or deemed unreachable, then the FE should return to receiving and handling messages first from the master CE. 4.4. Test of Packet ForwardingTestAs described in the ForCES LFB library[I-D.ietf-forces-lfb-lib-03],[LFB-LIB], packet forwarding is implemented by a set of LFB classes that compose a processing path for packets. In this test scenario, as shown in Figure 7, a ForCES router running the OSPF protocol was constructed. In addition, a set of LFBs including RedirectIn, RedirectOut, IPv4UcastLPM, and IPv4NextHopLFBswere used. RedirectIn and RedirectOut LFBs redirected OSPFhelloHello and LSA packets from and to the CE. ASmartbitsSmartBits [SmartBits] test machine was used to simulate an OSPF router and exchange the OSPFhelloHello and LSA packets with the CE in the ForCES router. In Figure 7,casecases (a) andcase(b) both need a RedirectIn LFB to send OSPF packets generated by the CE to the FE by use of ForCES packet redirect messages. The OSPF packets were further sent to an outside OSPFRouterrouter by the FE via forwardingLFBsLFBs, including IPv4NextHop andIPv4UcastLPM LFBs.IPv4UcastLPM. A RedirectOut LFB in the FE was used to send OSPF packets received from outside the OSPFRouterrouter to the CE by ForCES packet redirect messages. By running OSPF, the CE in the ForCES router could generate new routes and load them to the routing table in the FE. The FE was then able to forward packets according to the routing table. The test results areasshown in Figure1010. +-----+----+-----+-------------------------+--------------+---------+ |Test#| CE |FE(s)| Item | LFBs Related | Result | +-----+----+-----+-------------------------+--------------+---------+ | 1 | N | Z | IPv4NextHopTable SET | IPv4NextHop | Success | | | | | | | | | 2 | N | Z | IPv4PrefixTable SET | IPv4UcastLPM | Success | | | | | | | | | 3 | N | Z |Redirect OSPF packet from| RedirectIn | Success | | | | | CE to SmartBits | | | | | | | | | | | 4 | N | Z |Redirect OSPF packet from| RedirectOut | Success | | | | | SmartBits to CE | | | | | | | | | | | 5 | N | Z | Metadata in | RedirectOut | Success | | | | | redirect message | RedirectIn | | | | | | | | | | 6 | N | Z | OSPF neighbor discovery | RedirectOut | Success | | | | | | RedirectIn | | | | | | | | | | 7 | N | Z | OSPF DD exchange | RedirectOut | Success | | | | | | RedirectIn | | | | | | | IPv4NextHop | | | | | | | | | | 8 | N | Z | OSPF LSA exchange | RedirectOut | Success | | | | | | RedirectIn | | | | | | | IPv4NextHop | | | | | | | IPv4UcastLPM| | | | | | | | | | 9 | N | Z | Data Forwarding | RedirectOut | Success | | | | | | RedirectIn | | | | | | | IPv4NextHop | | | | | | | IPv4UcastLPM| | | | | | | | | | 10 | Z | N | IPv4NextHopTable SET | IPv4NextHop | Success | | | | | | | | | 11 | Z | N | IPv4PrefixTable SET | IPv4UcastLPM| Success | | | | | | | | | 12 | Z | N |Redirect OSPF packet from| RedirectIn | Success | | | | | CE to other OSPF router | | | | | | | | | | | 13 | Z | N |Redirect OSPF packet from| RedirectOut | Success | | | | |other OSPF router to CE | | | | | | | | | | | 14 | Z | N | Metadata in | RedirectOut | Success | | | | | redirect message | RedirectIn | | | | | | | | | | 15 | Z | N |OSPF neighbor discovery | RedirectOut | Success | | | | | | RedirectIn | | | | | | | | | | 16 | Z | N | OSPF DD exchange | RedirectOut | Failure | | | | | | RedirectIn | | | | | | | IPv4NextHop | | | | | | | | | | 17 | Z | N | OSPF LSA exchange | RedirectOut | Failure | | | | | | RedirectIn | | | | | | | IPv4NextHop | | | | | | | IPv4UcastLPM| | +-----+----+-----+-------------------------+--------------+---------+ Figure 10:Packet ForwardingTest Results for Packet Forwarding Note ontest #1 and #2: The implementer found a multicast route pointing to localhost had to be manually set before a redirect channel could work normally. Note on test #3tests #3 to #9: During the test, OSPF packets received from the CE were found byEthereal /Wireshark withEthereal/Wireshark to have checksum errors in the FE. Because the test time was quite limited, the implementer of the CE did nottry tomakeeffortsan effort to find and solve the checksumerror,error; instead, the FE had tried to correct the checksum in ordernotto not let theSmartbitsSmartBits drop the packets. Note that such a solution does not affect the test results. Comment onTesttests #16 and #17: The two test items failed. Note thatTesttests #7 and #8 were identical tothe two tests,tests #16 and #17, only with CE and FE implementerswerebeing exchanged. Moreover,testtests #12 and #13 showed that the redirect channel worked well. Therefore, it can be reasonably inferred that the problem caused by the failure was from the implementations, rather than from the ForCES protocol itself orfromthe misunderstanding of implementations on the protocol specification. Although the failure made the OSPF interoperability test incomplete, it did not show an interoperability problem. More test work is needed to verify the OSPF interoperability. 5. Discussions 5.1. On Data Encapsulation FormatInOn the first day of the test, it was found that the LFBinter- operations aboutinteroperations pertaining to tables all failed. It was eventually found that the failurewasoccurred becausethatdifferent data encapsulation methods for ForCES protocol messages weretakenused by different implementations. The issue is described in detailas below:below. Assuming that an LFB has two components, one is a struct withID 1ID=1 and the other is an array withID 2, further withID=2; in addition, both have two components of u32bothinside, as shown below: struct1: type struct, ID=1 components are: a, type u32, ID=1 b, type u32, ID=2 table1: type array, ID=2 components for each row are (a struct of): x, type u32, ID=1 y, type u32, ID=2 1. OnresponseResponse ofPATH-DATA formatPATH-DATA-TLV Format When a CE sends a config/query ForCES protocol message to an FE from a different implementer, the CE probably receives a response from the FE with a differentPATH-DATAPATH-DATA-TLV encapsulation format. For example, if a CE sends a query message with a path of 1 to athird partythird-party FE to manipulatestruct 1struct1 as defined above,the FEit is probabletothat the FE will generate a response with two differentPATH-DATAPATH-DATA-TLV encapsulationformat:formats: one is the value withFULL/SPARSE-DATAFULLDATA-TLV/SPARSEDATA-TLV and the other is the value with many parallelPATH-DATA TLVPATH-DATA-TLVs and nestedPATH-DATA TLV,PATH-DATA-TLVs, as shown below: format 1: OPER = GET-RESPONSE-TLV PATH-DATA-TLV: IDs=1 FULLDATA-TLV containing valueof(a),valueof(b) format 2: OPER = GET-RESPONSE-TLV PATH-DATA-TLV: IDs=1 PATH-DATA-TLV: IDs=1 FULLDATA-TLV containing valueof(a) PATH-DATA-TLV: IDs=2 FULLDATA-TLV containing valueof(b) The interoperability testers witnessed that a ForCES element (CE or FE) sender is free to choose whatever data structure that IETF ForCES documents define and best suits the element, while a ForCES element (CE or FE) should be able to accept and process information (requests and responses) that use any legitimate structure defined by IETF ForCES documents. While in the case where a ForCES element is free to choose any legitimate data structure as a response, it is preferred that the ForCES element responds in the same format that the request was made, as it is mostprobablylikely the data structureisthat the request sender looksforwardto receive. 2. OnoperationOperation toarrayArray An array operation may also have several different data encapsulation formats. For instance, if a CE sends a config message totable 1table1 with a path of (2.1), which refers to the component withID=2, which is an array,ID=2 (an array), and the second ID is the row,sothen row1, it1 may be encapsulated with three formats as shown below: format 1: OPER = SET-TLV PATH-DATA-TLV: IDs=2.1 FULLDATA-TLV containing valueof(x),valueof(y) format 2: OPER = SET-TLV PATH-DATA-TLV: IDs=2.1 PATH-DATA-TLV: IDs=1 FULLDATA-TLV containing valueof(x) PATH-DATA-TLV IDs=2 FULLDATA-TLV containing valueof(y) Moreover, if the CE is targeting the whole array, forexampleexample, if the array is empty and the CE wants to add the first row to the table, it could also adopt another format: format 3: OPER = SET-TLV PATH-DATA-TLV: IDs=2 FULLDATA-TLV containing rowindex=1,valueof(x),valueof(y) The interoperability test experience has shown thatformatformats 1 andformat3, which take full advantage of the multiple data elements description in one TLV of FULLDATA-TLV,getare moreefficiency,efficient, although format 2 can alsogetachieve the same operating goal. 6.Contributors Contributors who have made major contributions to the interoperability test are as below: Hirofumi Yamazaki NTT Corporation Tokyo Japan Email: yamazaki.horofumi@lab.ntt.co.jp Rong Jin Zhejiang Gongshang University Hangzhou P.R.China Email: jinrong@zjsu.edu.cn Yuta Watanabe NTT Corporation Tokyo Japan Email: yuta.watanabe@ntt-at.co.jp Xiaochun Wu Zhejiang Gongshang University Hangzhou P.R.China Email: spring-403@zjsu.edu.cn 7. Acknowledgements The authors thank the following test participants: Chuanhuang Li, Hangzhou BAUD Networks Ligang Dong, Zhejiang Gongshang University Bin Zhuge, Zhejiang Gongshang University Jingjing Zhou, Zhejiang Gongshang University Liaoyuan Ke, Hangzhou BAUD Networks Kelei Jin, Hangzhou BAUD Networks The authors also thank very much to Adrian Farrel, Joel Halpern, Ben Campbell, Nevil Brownlee, and Sean Turner for their important help in the document publication process. 8. IANA Considerations This memo includes no request to IANA. 9.Security Considerations Developers of ForCES FEs and CEs must take the security considerations of the ForCES Framework [RFC3746] andtheForCES Protocol Specification [RFC5810] into account. Also, as specified in the security considerationssectionoftheSCTP-Based TML for the ForCES Protocol [RFC5811], the transport-level security has to be ensured by IPsec. Test results of TML with IPsec supported have been shown in Section 4.2 in this document. The tests described in this document used only simple password security mode. Testing using more sophisticated security is for future study. Further testing using key agility is encouraged. The tests reported here used SCTP TML running over an IPsectunneltunnel, which was established by Racoon. Key negotiation formed part of this process, but we believe that the SCTP TML used does not include key agility or renegotiation.10.7. References10.1.7.1. Normative References [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. [RFC5811] Hadi Salim, J. and K. Ogawa, "SCTP-Based Transport Mapping Layer (TML) for the Forwarding and Control Element Separation (ForCES) Protocol", RFC 5811, March 2010. [RFC5812] Halpern, J. and J. Hadi Salim, "Forwarding and Control Element Separation (ForCES) Forwarding Element Model", RFC 5812, March 2010. [RFC5813] Haas, R., "Forwarding and Control Element Separation (ForCES) MIB", RFC 5813, March 2010.10.2.7.2. Informative References[Ethereal] , "Ethereal, also named Wireshark, is a protocol analyzer. The specific Ethereal that was used is an updated Ethereal, by Fenggen Jia, that can analyze and decode the ForCES protocol messages", http://www.ietf.org/mail- archive/web/forces/current/msg03687.html , . [I-D.ietf-forces-ceha-00][CEHA] Ogawa, K., Wang, W., Haleplidis, E., and J. Salim, "ForCES Intra-NE High Availability",draft-ietf-forces-ceha-00 (workWork inprogress) [RFC Editor Note: This reference is intended to indicate a specific versionProgress, October 2010. [Ethereal] Fenggen, J., "Subject: Release ofan Internet- Draft that was used during interop testing. Please Do NOT update this reference toamore recenttest version ofthe draft orForCES dissector based on Ethereal 0.99.0", message toan RFC. Please remove this note before publication] , October 2010. [I-D.ietf-forces-lfb-lib-03]the IETF forces mailing list, 11 June 2009, <http://www.ietf.org/mail-archive/web/forces/current/ msg03687.html>. [LFB-LIB] Wang, W., Haleplidis, E., Ogawa, K., Li, C., and J. Halpern, "ForCES Logical Function Block (LFB) Library",draft-ietf-forces-lfb-lib-03 (workWork inprogress) [RFC Editor Note: This reference is intended to indicate a specific version of an Internet-Draft that was used during interop testing. Please Do NOT update this reference to a more recent version of the draft or to an RFC. Please remove this note before publication] ,Progress, December 2010. [RFC3654] Khosravi, H. and T. Anderson, "Requirements for Separation of IP Control and Forwarding", RFC 3654, November 2003. [RFC3746] Yang, L., Dantu, R., Anderson, T., and R. Gopal, "Forwarding and Control Element Separation (ForCES) Framework", RFC 3746, April 2004. [RFC6053] Haleplidis, E., Ogawa, K., Wang, W., and J. Hadi Salim, "Implementation Report for Forwarding and Control Element Separation (ForCES)", RFC 6053, November 2010. [RFC6956] Wang, W., Haleplidis, E., Ogawa, K., Li, C., and J. Halpern, "Forwarding and Control Element Separation (ForCES) Logical Function Block (LFB) Library", RFC 6956, June 2013. [Racoon], "Racoon inThe NetBSDisFoundation, "How to build awell-known IKE daemon performing the IPsec Key Exchange (IKE)remote user access VPN withthe peers", http://www.netbsd.org/docs/network/ipsec/rasvpn.html , .Racoon", <http://www.netbsd.org/docs/network/ipsec/rasvpn.html>. [SmartBits] Spirent Inc., "The Highly-Scalable Router Performance Tester: TeraRouting Tester", 2005, <http://www.spirent.com/~/media/Datasheets/Broadband/ Obsolete_SMB-TM/TeraRouting%20Tester.pdf>. [Tcpdump], "Tcpdump is a Linux protocol analyzer. The specific tcpdump that was used is a modified tcpdump, by JamalHadi Salim,that can analyze and decodeJ., "Subject: tcpdump 4.1.1", message to theForCES protocol messages", http://www.ietf.org/mail-archive/web/forces/ current/msg03811.html , . [Teamviewer] ,IETF forces mailing list, 20 May 2010, <http://www.ietf.org/mail-archive/web/forces/current/ msg03811.html>. [TeamViewer] TeamViewer Inc., "TeamViewerconnects- the All-In-One Software for Remote Support and Online Meetings", <http://www.teamviewer.com/>. Appendix A. Acknowledgements The authors thank the following test participants: Chuanhuang Li, Hangzhou BAUD Networks Ligang Dong, Zhejiang Gongshang University Bin Zhuge, Zhejiang Gongshang University Jingjing Zhou, Zhejiang Gongshang University Liaoyuan Ke, Hangzhou BAUD Networks Kelei Jin, Hangzhou BAUD Networks The authors also thank very much Adrian Farrel, Joel Halpern, Ben Campbell, Nevil Brownlee, and Sean Turner for their important help in the document publication process. Appendix B. Contributors Contributors who have made major contributions toany PC or server aroundtheworld within a few seconds. ", http://www.teamviewer.com/ , .interoperability test are listed below. Hirofumi Yamazaki NTT Corporation Tokyo Japan EMail: yamazaki.horofumi@lab.ntt.co.jp Rong Jin Zhejiang Gongshang University Hangzhou P.R. China EMail: jinrong@zjsu.edu.cn Yuta Watanabe NTT Corporation Tokyo Japan EMail: yuta.watanabe@ntt-at.co.jp Xiaochun Wu Zhejiang Gongshang University Hangzhou P.R. China EMail: spring-403@zjsu.edu.cn Authors' Addresses Weiming Wang Zhejiang Gongshang University 18 Xuezheng Str., Xiasha University Town Hangzhou 310018P.R.ChinaP.R. China Phone: +86-571-28877721Email:EMail: wmwang@zjsu.edu.cn Kentaro Ogawa NTT Corporation Tokyo JapanEmail:EMail: ogawa.kentaro@lab.ntt.co.jp Evangelos Haleplidis University of Patras Department of Electrical & Computer Engineering Patras 26500 GreeceEmail:EMail: ehalep@ece.upatras.gr Ming Gao Hangzhou BAUD Networks 408 Wen-San Road Hangzhou 310012P.R.China Email: gmyyqno1@zjsu.edu.cnP.R. China EMail: gaoming@mail.zjgsu.edu.cn Jamal Hadi Salim Mojatatu Networks Ottawa CanadaEmail:EMail: hadi@mojatatu.com