Internet Engineering Task Force                                  W. Wang
Internet-Draft                             Zhejiang Gongshang University
Intended status: Informational                                  K. Ogawa
Expires: September 15, 2011 January 12, 2012                                NTT Corporation
                                                           E. Haleplidis
                                                    University of Patras
                                                                  M. Gao
                                                  Hangzhou BAUD Networks
                                                           J. Hadi Salim
                                                       Mojatatu Networks
                                                          March 14,
                                                           July 11, 2011

 Interoperability Report for Forwarding and Control Element Separation
                                (ForCES)
                      draft-ietf-forces-interop-01
                      draft-ietf-forces-interop-02

Abstract

   This document captures test results from the second Forwarding and
   control Element Separation (ForCES) interop testing interoperability test which took
   place on March February 24-25, 2011 at in the Internet Technology Lab (ITL) of
   Zhejiang Gongshang University in University, China.

Status of this Memo

   This Internet-Draft is submitted in full conformance with the
   provisions of BCP 78 and BCP 79.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF).  Note that other groups may also distribute
   working documents as Internet-Drafts.  The list of current Internet-
   Drafts is at http://datatracker.ietf.org/drafts/current/.

   Internet-Drafts are draft documents valid for a maximum of six months
   and may be updated, replaced, or obsoleted by other documents at any
   time.  It is inappropriate to use Internet-Drafts as reference
   material or to cite them other than as "work in progress."

   This Internet-Draft will expire on September 15, 2011. January 12, 2012.

Copyright Notice

   Copyright (c) 2011 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 . . . . . . . . . . . . . . . . . . . . . . . . .  4  3
     1.1.  ForCES Protocol  . . . . . . . . . . . . . . . . . . . . .  4  3
     1.2.  ForCES FE Model  . . . . . . . . . . . . . . . . . . . . . . .  4  3
     1.3.  Transport Mapping Layer  . . . . . . . . . . . . . . . . .  4
     1.4.  CE HA  . . . . . . . . . . . . . . . . . . . . . . . . . .  5  3
   2.  Terminology and Conventions  . . . . . . . . . . . . . . . . .  6  5
     2.1.  Requirements Language  . . . . . . . . . . . . . . . . . .  6  5
     2.2.  Definitions  . . . . . . . . . . . . . . . . . . . . . . .  6  5
   3.  Overview . . . . . . . . . . . . . . . . . . . . . . . . . . .  8  7
     3.1.  Date, Location, and Participants . . . . . . . . . . . . .  8  7
     3.2.  Testbed Configuration  . . . . . . . . . . . . . . . . . .  8  7
       3.2.1.  Participants Access  . . . . . . . . . . . . . . . . . . . . . . . .  8  7
       3.2.2.  Local  Testbed Configuration  . . . . . . . . . . . . . . . . .  9
       3.2.3.  Distributed Configuration  . . . . . . . . . . . . . . 10  8
   4.  Scenarios  . . . . . . . . . . . . . . . . . . . . . . . . . . 12 11
     4.1.  Scenario 1 - LFB Operation . . . . . . . . . . . . . . . . 12
       4.1.1.  Connection Diagram 11
     4.2.  Scenario 2 - TML with IPSec  . . . . . . . . . . . . . . . 11
     4.3.  Scenario 3 - CE High Availability  . . . 12
       4.1.2.  Design Considerations . . . . . . . . . 12
     4.4.  Scenario 4 - Packet forwarding . . . . . . . 12
       4.1.3.  Testing Proccess . . . . . . . 14
   5.  Test Results . . . . . . . . . . . . 12
     4.2.  Scenario 2 - TML with IPSec . . . . . . . . . . . . . 17
     5.1.  LFB Operation Test . . 12
       4.2.1.  Connection Diagram . . . . . . . . . . . . . . . . . . 13
       4.2.2.  Design Considerations 17
     5.2.  TML with IPSec Test  . . . . . . . . . . . . . . . . 13
       4.2.3.  Testing Proccess . . . 22
     5.3.  CE High Availability Test  . . . . . . . . . . . . . . . . 14
     4.3.  Scenario 3 - CE High Availability 23
     5.4.  Packet Forwarding Test . . . . . . . . . . . . 14
       4.3.1.  Connection Diagram . . . . . . 24
   6.  Discussions  . . . . . . . . . . . . 14
       4.3.2.  Design Considerations . . . . . . . . . . . . . 27
     6.1.  On Data Encapsulation Format . . . 14
       4.3.3.  Testing Proccess . . . . . . . . . . . . 27
   7.  Contributors . . . . . . . 15
     4.4.  Scenario 4 - Packet forwarding . . . . . . . . . . . . . . 16
       4.4.1.  Connection Diagram . . . . 30
   8.  Acknowledgements . . . . . . . . . . . . . . 16
       4.4.2.  Design Considerations . . . . . . . . . 31
   9.  IANA Considerations  . . . . . . . 17
       4.4.3.  Testing Proccess . . . . . . . . . . . . . . 32
   10. Security Considerations  . . . . . 17
   5.  Test Results . . . . . . . . . . . . . . 33
   11. References . . . . . . . . . . . 19
     5.1.  LFB Operation Test . . . . . . . . . . . . . . . 34
     11.1. Normative References . . . . . 19
     5.2.  TML with IPSec Test . . . . . . . . . . . . . . 34
     11.2. Informative References . . . . . 24
     5.3.  CE High Availability Test . . . . . . . . . . . . . 34
   Authors' Addresses . . . 25
     5.4.  Packet Forwarding Test . . . . . . . . . . . . . . . . . . 26
   6.  Discussions  . . . . . . . . . . . . . . . . . . . . . . . . . 29
     6.1.  On Data Encapsulation Format . . . . . . . . . . . . . . . 29
   7.  Contributors . . . . . . . . . . . . . . . . . . . . . . . . . 32
   8.  Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 33
   9.  IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 34
   10. Security Considerations  . . . . . . . . . . . . . . . . . . . 35
   11. References . . . . . . . . . . . . . . . . . . . . . . . . . . 36
     11.1. Normative References . . . . . . . . . . . . . . . . . . . 36
     11.2. Informative References . . . . . . . . . . . . . . . . . . 36
   Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 37

1.  Introduction

   This document captures the results of the second interoperability
   test of the Forwarding and control Element Separation (ForCES)
   Framework which took place March February 24-25, 2011 in the Internet
   Technology Lab (ITL) of Zhejiang Gongshang University in University, China.  The
   tests
   test involved several documents namely: ForCES protocol [RFC5810],
   ForCES FE model [RFC5812], ForCES TML [RFC5811], ForCES LFB Library
   [FORCES-LFBLIB]
   [I-D.ietf-forces-lfb-lib] and ForCES CE HA specification[FORCES-CEHA]. specification
   [I-D.ietf-forces-ceha] Three independent ForCES implementations
   participated in the test.

   Scenarios of ForCES LFB Operation, TML with IPSec, CE High
   Availability, and Packet Forwarding are constructed.  Series of
   testing items for every scenario are carried out and interoperability
   results are achieved.  Extended Wireshark and extended tcpdump are
   used to verify the results.

   The first interop interoperability test on ForCES was held in July 2008 at
   the University of Patras,
   Greece, Greece.  The test focussed on validating
   the basic semantics of the ForCES protocol and model[RFC6053]. ForCES FE model.  The
   test results were captured by RFC 6053[RFC6053].

1.1.  ForCES Protocol

   The ForCES protocol works in a master-slave mode in which FEs are
   slaves and CEs are masters.  The protocol includes commands for
   transport of Logical Function Block (LFB) configuration information,
   association setup, status, and event notifications, etc.  The reader
   is encouraged to read FE-protocol the ForCES protocol specification RFC 5810
   [RFC5810] for further information.

1.2.  ForCES FE Model

   The FE-MODEL [RFC5811] ForCES FE modelRFC 5812 [RFC5812] presents a formal way to define
   FE Logical Function Blocks (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 TML ForCES Transport Mapping Layer (TML) transports the PL ForCES
   Protocol Layer (PL) messages.  The TML is where the issues of how to
   achieve transport level reliability, congestion control, multicast,
   ordering, etc. etc are handled.  It is expected that more than one TML
   will be standardized.  The various possible TMLs could vary their
   implementations based on the capabilities of underlying media and
   transport.  However, since each TML is standardized, interoperability
   is guaranteed as long as both endpoints support the same TML.  All
   ForCES Protocol Layer implementations MUST be portable across all
   TMLs.  Although more than one TML may be standardized for the ForCES
   Protocol, for the purposes of the interoperability test, the mandated
   MUST IMPLEMENT SCTP TML [RFC5811] will be used.

1.4.  CE HA

2.  Terminology and Conventions

2.1.  Requirements Language

   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].

2.2.  Definitions

   This document follows the terminology defined by ForCES related
   documents, including RFC3654, RFC3746,
   RFC5810,RFC5811,RFC5812,RFC5812. RFC5810, RFC5811, RFC5812,
   RFC5813, etc.  Some definitions are repeated below for clarity.

      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.

      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/controlled by one or
      more CEs via the ForCES protocol.

      LFB (Logical Functional Block) - The basic building block that is
      operated on by the ForCES protocol.  The LFB is a well defined,
      logically separable functional block that resides in an FE and is
      controlled by the CE via the ForCES protocol.  The LFB may reside
      at the FE's datapath and process packets or may be purely an FE
      control or configuration entity that is operated on by the CE.
      Note that the LFB is a functionally accurate abstraction of the
      FE's processing capabilities, but not a hardware-accurate
      representation of the FE implementation.

      LFB Class and LFB Instance - LFBs are categorized by LFB Classes.
      An LFB Instance represents an LFB Class (or Type) existence.
      There may be multiple instances of the same LFB Class (or Type) in
      an FE.  An LFB Class is represented by an LFB Class ID, and an LFB
      Instance is represented by an LFB Instance ID.  As a result, an
      LFB Class ID associated with an LFB Instance ID uniquely specifies
      an LFB existence.

      LFB Metadata - Metadata is used to communicate per-packet state
      from one LFB to another, but is not sent across the network.  The
      FE model defines how such metadata is identified, produced, and
      consumed by the LFBs.  It defines the functionality but not how
      metadata is encoded within an implementation.

      LFB Components - Operational parameters of the LFBs that must be
      visible to the CEs are conceptualized in the FE model as the LFB
      components.  The LFB components include, for example, flags,
      single-parameter arguments, complex arguments, and tables that the
      CE can read and/or write via the ForCES protocol (see below). protocol.

      ForCES Protocol - While there may be multiple protocols used
      within the overall ForCES architecture, the term "ForCES protocol"
      and "protocol" refer to the "Fp" reference points in the ForCES
      framework in [RFC3746].  This protocol does not apply to CE-to-CE
      communication, FE-to-FE communication, or to communication between
      FE and CE managers.  Basically, the ForCES protocol works in a
      master-slave mode in which FEs are slaves and CEs are masters.

      ForCES Protocol Transport Mapping Layer (ForCES TML) - A layer in
      ForCES protocol architecture that uses the capabilities of
      existing transport protocols to specifically address protocol
      message transportation issues, such as how the protocol messages
      are mapped to different transport media (like TCP, IP, ATM,
      Ethernet, etc.), and how to achieve and implement reliability,
      multicast, ordering, etc.  The ForCES TML specifications are
      detailed in separate ForCES documents, one for each TML.

3.  Overview

3.1.  Date, Location, and Participants

   The second ForCES interoperability test meeting was held by IETF
   ForCES
   working group Working Group on March February 24-25, 2011, and was chaired by
   Jamal Hadi Salim, the current ForCES working group Working Group co-chair.  Three
   independent ForCES implementations participated in the test:

   * Zhejiang Gongshang University/Hangzhou BAUD Networks, Corparation of
   Inforamtion and Networks Technology (Hangzhou BAUD Networks), China.
   This implementation is referred to as "China" or in some cases "C" in
   the document for the sake of brevity.
   * NTT Corporation, Japan.  This implementation is referred to as
   "Japan" or in some cases "J" in the document for the sake of brevity.
   * The University of Patras, Greece.  This implementation is referred
   to as "Greece" or in some cases "G" in the document for the sake of
   brevity.

   Two other organizations, Mojatatu Networks and Hangzhou BAUD Networks
   Corporation, which independently extended two different well known
   public domain protocol analyzers, Ethereal/Wireshark [Ethereal] and
   Tcpdump [Tcpdump], also participated in the interop test.  During the
   interoperability test, the two protocol analyzers Wireshark and
   tcpdump were used to verify
   the validity of ForCES protocol messages and in some cases semantics.

   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 protocol TLV (Refer to Section 6). 6.1).

   Some errata related to ForCES document were found by the
   interoperability test.  The errata will be has been reported to related IETF
   RFCs.

   At times, interoperability testing was exercised between 2 instead of
   all three representative implementations due to the third one lacking
   a specific feature; however, in ensuing discussions, all implementors
   mentioned they will be implementing any missing features in the
   future.

3.2.  Testbed Configuration

3.2.1.  Participants Access

   Japan and China physically attended on site at the Internet
   Technology Lab (ITL) of Zhejiang Gongshang University in China.  The
   University of Patras implementation joined remotely from Greece.  The
   chair, Jamal Hadi Salim, joined remotely from Canada by using the
   teamviewer tool [ref XXX].
   Teamviewer as the monitoring tool.  The approach is as shown in figure
   Figure 1.  In the figure, FE/CE refers to FE or CE that the
   implementor may act alternatively.

        +---------+     +----+                    +----------+
        |  FE/CE  |     |    |                +---|TeamViewer|                +---|Monitoring|
        |  China  |-----|    |    /\/\/\/\/\  |   |  Canada  |   |(TeamViewer)
        +---------+     |    |    \Internet/  |   +----------+   |  Canada  |
                        |LAN |----/        \--|   +----------+
        +---------+     |    |    \/\/\/\/\/  |   +----------+
        |  FE/CE  |-----|    |                |   |  FE/CE   |
        |  Japan  |     |    |                +---|  Greece  |
        +---------+     +----+                    +----------+

                     Figure 1: The Approach Access for all Participants

   For interoperability test items, all

   All CEs and FEs SHALL implement
   IPSEC IPSec security in the TML.  For
   security, firewalls MUST be used that will allow only the specific
   IPs and the SCTP ports defined in the ForCES SCTP-TML [RFC5811].

3.2.2.  Local  Testbed Configuration

   Hardwares and softwares including CEs and FEs from China and Japan
   implementions that were located within the ITL Lab of Zhejiang
   Gongshang University, were connected together using ethernet Ethernet
   switches.  The configuration can be seen in figure Figure 2.  In the figure,
   the SmartBits is a third-party supplied routing protocol testing
   machine, which acts as a router running OSPF and RIP and exchanges
   routing protocol messages with ForCES routers in the network.  The
   Internet is connected via an ADSL channel.

                           /\/\/\/\/\
                           \Internet/
                           /        \
                           \/\/\/\/\/
                               |
                               |124.90.146.218 (ADSL)
                               |
+------------------------------------------------------------------+
|                      LAN  (10.20.0.0/24)                         |
+------------------------------------------------------------------+
   |        |        |               |                |          |
   |        |        |               |                |          |
   |.222    |.230    |.221           |.179            |.231      |.220
+-----+  +-----+  +-----+         +-----+          +-----+  +---------+
| CE  |  | CE  |  |     |         |     |          |     |  | Protocol|
|China|  |Japan|  | FE1 |.1     .2| FE  |.1      .2| FE2 |  | Analyzer|
+-----+  +-----+  |China|---------|Japan|----------|China|  +---------+
        +---------|     |192.169. |     |     | 192.168. |     |-------+
        |      .2 +-----+    ^ 20.0.24 +-----+    ^  30.0/24 +-----+ .2    |
        |         .12|192.168.20.0/24  192.168.30.0/24         .12|                                 |.12      |
        |            |                                 |         |
  192.168.50.0/24    |                                 | 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|     |               Smartbits               | |Terminal|
   +--------+     +---------------------------------------+ +--------+

         Figure 2: Testbed Configuration Located in ITL Lab,China

3.2.3.  Distributed Configuration

   Hardware/Software

   Hardwares and Softwares (CE and FE) of Greece that were located
   within the University of Patras premises,were Patras, Greece, were connected together
   using LAN as shown in figure Figure 3.  The Internet is connected via a VPN
   channel.

                               /\/\/\/\/\
                               \Internet/
                               /        \
                               \/\/\/\/\/
                                   |
                                   |150.140.254.110(VPN)
                                   |
                +------------------------------------+
                |                LAN                 |
                +------------------------------------+
                     |           |             |
                     |           |             |
                 +------+    +--------+     +------+
                 |  FE  |    |Protocol|     |  CE  |
                 |Greece|    |Analyzer|     |Greece|
                 +------+    +--------+     +------+

       Figure 3: Testbed Configuration Located in the University of
                               Patras,Greece

   Above Testbed configuations can satisfy requirements of all the
   interoperability test scenarios that are mentioned in this document.

4.  Scenarios

4.1.  Scenario 1 - LFB Operation

4.1.1.  Connection Diagram

   This scenario is to test the interoperability on LFB operations among
   the participants.  The connection diagram for the participants is as
   shown in Figure 4.

    +------+    +------+    +------+    +------+    +------+    +------+
    |  CE  |    |  CE  |    |  CE  |    |  CE  |    |  CE  |    |  CE  |
    | China|    | Japan|    | China|    |Greece|    | Japan|    |Greece|
    +------+    +------+    +------+    +------+    +------+    +------+
       |           |           |           |           |           |
       |           |           |           |           |           |
    +------+    +------+    +------+    +------+    +------+    +------+
    |  FE  |    |  FE  |    |  FE  |    |  FE  |    |  FE  |    |  FE  |
    |Japan |    |China |    |Greece|    |China |    |Greece|    |Japan |
    +------+    +------+    +------+    +------+    +------+    +------+

                   Figure 4: Scenario for LFB Operation

4.1.2.  Design Considerations

   Firstly,

   In order to make interoperability more credible,the three
   implementors carried out the scenario of LFB Operation test in an alternative way acting as a
   CE or an FE.  As a result, every operation should be tested with 6
   combinations all three participants, as shown in Figure 4 4.

   The test scenario is designed with the following purposes:

   Firstly, the scenario is designed to verify all kinds of protocol
   messages with their complex data formats, which are defined in RFC
   5810.
   Different implementor may have different choices on implemeting RFC
   5810 using cases in the protocol messages.  However as long as it
   complies with the RFC 5810, the interoperating peer must have the
   ability to decode and handle it.  Specially, what we want try to verify the most is the data format of encasulation for a PATH-DATA
   with nested PATH-DATAs, and the operation(SET, GET,DEL) GET, DEL) of array, as well as an array
   or an array with a nested array.  (This case can be seen in ARP LFB's
   component of PortV4AddrInfoTable).

   Second,the scenario is designed to verify the definition of ForCES
   LFB Library[I-D.ietf-forces-lfb-lib]. Library[FORCES-LFBLIB], which defines a base set of ForCES LFB
   classes for typical router functions.  Successful test under this
   scenario also means all the implementors have followed validity of the LFB definitions.

4.2.  Scenario 2 - TML with IPSec

   This scenario is designed to implement a TML with IPSec, which is the instruction
   given
   requirement by RFC 5811.  TML with IPSec was not implemented in the
   first ForCES LFB Library document.

4.1.3.  Testing Proccess

   In order to make interoperability more credible,the three
   implementors carried out the test in an alternative way acting as a
   CE or an FE, as shown reported by RFC 6053.  For this
   reason, in figure 4, combined with 6 cases for the second interoperability test, we specificially
   designed the test scenario to verify the TML over IPSec channel.

   In this
   Scenario.

4.2. scenario, tests on LFB operations for Scenario 2 - TML 1 were just
   repeated only with the difference that the IPSec TML was adopted.  In
   this way, we try to verify whether all interactions between CE and FE
   can be made correctly under an IPSec TML enviroment.

   The connection diagram for this scenario is shown as Figure 5.
   Because of system difficulty to deploy IPSec
4.2.1.  Connection Diagram over TML in Greece, the
   text only took place between China and Japan.

                 +------+                 +------+
                 |  CE  |                 |  CE  |
                 | China|                 | Japan|
                 +------+                 +------+
                    |                        |
                    |TML over IPSec          |TML over IPSec
                 +------+                 +------+
                 |  FE  |                 |  FE  |
                 |Japan |                 |China |
                 +------+                 +------+
                               (a)

                 +------+                 +------+
                 |  CE  |                 |  CE  |
                 | China|                 |Greece|
                 +------+                 +------+
                    |                        |
                    |TML

         Figure 5: Scenario for LFB Operation with TML over IPSec          |TML over IPSec
                 +------+                 +------+
                 |  FE  |                 |  FE  |
                 |Greece|                 |China |
                 +------+                 +------+
                               (b)

                 +------+                 +------+
                 |  CE  |                 |  CE  |
                 | Japan|                 |Greece|
                 +------+                 +------+
                    |                        |
                    |TML over IPSec          |TML over IPSec
                 +------+                 +------+
                 |  FE  |                 |  FE  |
                 |Greece|                 |Japan |
                 +------+                 +------+
                               (c)

         Figure 5: Scenario for LFB Operation with TML over IPSec

4.2.2.  Design Considerations

   This scenario is designed to implement the requirement that stated in
   the section "7.  Security Considerations" in RFC 5811.  For this
   reason, we designed the scenario to make TML run over IPSec channel
   that was pre-established.  In this scenario, all operations for
   Scenario 1 were just repeated.  In this way, we try to verify whether
   all interactions between CE and FE can be done correctly under an
   IPSec enviroment.

4.2.3.  Testing Proccess

   In this scenario, ForCES TML was run

   In this scenario, ForCES TML was run over IPSec channel.  All the
   implementors
   Implementors joined in this interoperability have used the same third-
   party tool
   third-party software 'racoon' to establish have established the IPSec channel.  By this
   tool,

   China and Japan had have made a successful test, test with the scenario, and
   the following items have been realized:

   o  Internet Key Exchange (IKE) with certificates for endpoint
      authentication.

   o  Transport Mode Encapsulating Security Payload (ESP).  HMAC-SHA1-96
      [RFC2404] for message integrity protection.

4.3.  Scenario 3 - CE High Availability

4.3.1.  Connection Diagram

            master     standby            master     standby
            +------+    +------+          +------+    +------+
            |  CE  |    |  CE  |          |  CE  |    |  CE  |
            | China|    |Greece|          |Japan |    |Greece|
            +------+    +------+          +------+    +------+
               |          |                  |           |
               +----------+                  +-----------+
               |                             |
            +------+                      +------+
            |  FE  |                      |  FE  |
            |Greece|                      |Greece|
            +------+                      +------+
                   (a)                           (b)

                Figure 6: Scenario for CE High Availability

4.3.2.  Design Considerations

   CE High Availability (CEHA) was also tested in this interoperability
   test based on the ForCES CEHA document [I-D.draft-ietf-forces-ceha]. [ForCES-CEHA].

   The design of the setup and the scenario for the CEHA are as simple
   as possible to focus mostly on the mechanics of the CEHA, which are:

   o  Associating with more than one CEs.

   o  Switching to backup CE on master CE fail.

4.3.3.  Testing Proccess

   In this scenario one FE would be connected and associated with a
   master CE and a backup CE.  In the pre-association phase,

   The connection diagram for the FE
   would be configured to have China's or Japan's CE scenario is as shown in Figure 6.

            master CE and
   Greece's CE as     standby CE.  The CEFailoverPolicy component of            master     standby
            +------+    +------+          +------+    +------+
            |  CE  |    |  CE  |          |  CE  |    |  CE  |
            | China|    |Greece|          |Japan |    |Greece|
            +------+    +------+          +------+    +------+
               |          |                  |           |
               +----------+                  +-----------+
               |                             |
            +------+                      +------+
            |  FE  |                      |  FE  |
            |Greece|                      |Greece|
            +------+                      +------+
                   (a)                           (b)

                Figure 6: Scenario for CE High Availability

   In this scenario one FE would be connected and associated with a
   master CE and a backup CE.  In the pre-association phase, the FE
   would be configured to have China's or Japan's CE as master CE and
   Greece's CE as standby CE.  The CEFailoverPolicy component of the FE
   Protocol Object LFB that specifies whether the FE is in High
   Availability mode (value 2 or 3) would either be set in the pre-
   association phase or in post-association phase by the master CE.

   Once the FE is associated with the master CE it will move to the
   post-association phase.  Then when the CEFailoverPolicy value is set
   to 2 or 3, then it will then attempt to connect and associate with
   the standby CE.

   When the master CE is considered disconnected, either by TearDown,
   Loss of Heartbeats or Disconnected, FE would assume that the standby
   CE is now the master CE.  FE will then send an Event Notification,
   Primary CE Down,to all associated CEs, only the standby CE in this
   case with the value of the new master CEID.  The standby CE will then
   respond by setting with a configuration message the CEID of the FE
   Protocol Object with it's own ID, the same value, to confirm that the
   CE considers itself as the master as well.

   The steps of the CEHA scenario were the following:

   1.  In the pre-association phase, setup of FE with master CE and
       backup CE

   2.  FE connecting and associating with master CE.

   3.  When CEFailoverPolicy is set to 2 or 3, the FE will connect and
       associate with backup CE.

   4.  Once the master CE is considered disconnected then the FE chooses
       the first Associated backup CE.

   5.  It sends an Event Notification specifying that the master CE is
       down and who is now the master CE.

   6.  The new master CE sends a SET Configuration message to the FE
       setting the CEID value to who is now the new master CE completing
       the switch.

4.4.  Scenario 4 - Packet forwarding

4.4.1.  Connection Diagram

   This test scenario is to verify LFBs like RedirectIn, RedirectOut,
   IPv4NextHop, IPv4UcastLPM defined by the ForCES LFB library
   document[ForCES-LFBLIB], and more importantly, to verify the
   combination of the LFBs to implement IP packet forwarding.

   The connection diagram for this scenario is as Figure 7.

                              +------+
                              |  CE  |
                              | Japan|
                              +------+
                                 |  ^
                                 |  | OSPF
                                 |  +------->
                              +------+       +------+
              +--------+      |  FE  |       | OSPF |      +--------+
              |Terminal|------|China |-------|Router|------|Terminal|
              +--------+      +------+       +------+      +--------+

                <-------------------------------------------->
                            Packet Forwarding

                                   (a)

                                     +------+
                                     |  CE  |
                                     | China|
                                     +------+
                                      ^  |  ^
                                 OSPF |  |  | OSPF
                                <-----+  |  +----->
                            +-------+    +------+     +------+
          +--------+    | OSPF  |    |  FE  |     | OSPF |    +--------+
          |Terminal|----|Router |----|Japan |-----|Router|----|Terminal|
          +--------+    +-------+    +------+     +------+    +--------+
                  <-------------------------------------------->
                            Packet Forwarding

                                   (b)

                              +------+       +------+
                              |  CE  |       |  CE  |
                              | Japan|       | China|
                              +------+       +------+
                                 |  ^          ^ |
                                 |  |   OSPF   | |
                                 |  +----------+ |
                              +------+       +------+
              +--------+      |  FE  |       |  FE  |      +--------+
              |Terminal|------|China |-------|Japan |------|Terminal|
              +--------+      +------+       +------+      +--------+

                <-------------------------------------------->
                             Packet Forwarding

                                   (c)

                Figure 7: Scenario for IP Packet forwarding

4.4.2.  Design Considerations

   This Scenario is used to verify some LFBs such as RedirectIn,
   RedirectOut, IPv4NextHop, IPv4UcastLPM defined by ForCES LFB
   library[I-D.ietf-forces-lfb-lib].  Cases of (a) and (b) in Figure 7
   both need

   In case (a), a RedirectIn LFB to send CE generated OSPF packets by Japan is connected to an FE by
   packet redirect messages.  The OSPF packets China to form a
   ForCES router.  A Smartbits test machine with its routing protocol
   software are futher sent used to simulate an
   outside OSPF Router by the FE via forwarding LFBs like IPv4NextHop,
   IPv4UcastLPM.  A RedirectOut LFB in router and are connected with
   the FE sends ForCES router to try to exchange OSPF hello packets
   received from the outside OSPF Router and LSA
   packets among them.  Terminals are simulated by Smartbits to send and
   receive packets.  As a result, the CE by packet redirect
   messages also.  In this process, meta-data that are included in
   packet redirect messages as defined by the ForCES LFB library document
   should be coded and decoded by either CE or FE.

   If above test process can router need to be done, then this whole NE including FE
   configured to run and support OSPF routing protocol.

   In case (b), a CE actually work like by China is connected to an OSPF router which exchanges OSPF
   protocol information with other OSPF routers.  By FE by Japan to form a
   ForCES router.  Two routers running OSPF
   protocol, the CE can generate new routes are simulated and be loaded coneected
   to FE.  In the
   process, IPv4NextHop and Ipv4UcastLPM LFBs must be working ForCES router to test if the ForCES router can support OSPF
   protocol and support
   operations.

   By sending packet to the destination through the FE, forwarding.

   In case (c), two ForCES rotuers are constructed.  One is with CE by
   Japan and FE should
   forward packet according to the route generated by OSPF. so, China and the data
   path in FE can be tested other is opposite.  OSPF and LFBs such as EtherPHYCop, EtherMacIn,
   IPv4Classifier, IPv4Validator, EtherEncasulator, EtherMacOut also be
   verified.

4.4.3. packet
   forwarding are tested in the enviroment.

   Testing Proccess

   First,Boot proccess for this scenario is as below:

   1.  Boot terminals and routers, and set IP addresses of their
       interfaces.

   Second,

   2.  Boot CE and FE.

   Third,

   3.  Establish association between CE and FE, and set IP addresses of
       FE__s interfaces.

   Fifth,

   4.  Start OSPF among CE and routers, and set FIB on FE.

   Sixth,

   5.  Send packets between terminals.

5.  Test Results

5.1.  LFB Operation Test

   The test result is as reported by Figure 8.  For the convinience
   sake, as mentioned earlier, abbreviations of 'C' in the table means
   implementation from China,'J'Japan implementaion, and 'G' Greece
   implemenation.  Testing results of this scenario are listed in
   the following figure.

   +----+----+-----+----+-----------+-----------+--------+-------------+
   |Test|

   +-----+----+-----+-----+--------------+-------------------+---------+
   |Test#| CE |FE(s)|Oper| |FE(s)|Oper |      LFB   |Component/     |       Component   | Result  |   Comment
   |
   |#     |    |     |     |           |Capability              |     /Capability   |         |
   +----+----+-----+----+-----------+-----------+--------+-------------+
   +-----+----+-----+-----+--------------+-------------------+---------+
   |  1  | C  |  J  |     |              |           |Success |As for the                   | Success |
   |     | J  |  C  |     |              |           |Success | format of                   | Success |
   | C     | G  |  C  | GET |           |Success |encapsulation|
   |    | G   FEObject   |  C    LFBTopology    | GET| FEObject  |LFBTopology|Success |on array, Success |
   |     | J  |  G  |     |              |           |Success |only the case|                   | Success |
   |     | G  |  J  |     |              |           |Success |of FULLDATA-                   | Success |
   |     |    |     |     |              |                   |        |-in-FULLDATA         |
   |  2  | C  |  J  |     |              |           |Success |is supported                   | Success |
   |     | J  |  C  |     |              |           |Success |for everyone.|                   | Success |
   |     | C  |  G  |     |              |           |Success |Howerver more|                   | Success |
   |     | G  |  C  | GET| GET |   FEObject  |LFBSelector|Success |types such as|   |    LFBSelector    | Success |
   |     | J  |  G  |     |              |    s      |Success |SPARSEDATA                   | Success |
   |     | G  |  J  |     |              |           |Success |should be                   | Success |
   |     |    |     |     |              |                   |        |supported         |
   |  3  | C  |  J  |     |              |           |Success |in the                   | Success |
   |     | J  |  C  |     |              |           |Success |future.                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherPHYCop|PHYPortID  |Success GET |  EtherPHYCop |     PHYPortID     | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  4  | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherPHYCop|AdminStatus|Success GET |  EtherPHYCop |    AdminStatus    | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  5  | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherPHYCop|OperStatus |Success GET |  EtherPHYCop |     OperStatus    | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |As for the                   | Success |
   |     |    |     |     |              |                   |        |format of         |
   |  6  | C  |  J  |     |              |           |Success |PATH-DATA,                   | Success |
   |     | J  |  C  |     |              |           |Success |J use the                   | Success |
   |     | C  |  G  |     |              |           |Success |case of                   | Success |
   |     | G  |  C  | GET|EtherPHYCop|AdminLink  |Success |PATH-DATA in GET |  EtherPHYCop |  AdminLinkSpeed   | Success |
   |     | J  |  G  |     |              |  Speed    |Success |PATH-DATA,C                   | Success |
   |     | G  |  J  |     |              |           |Success |uses                   | Success |
   |     |    |     |     |              |                   |        |only one         |
   |  7  | C  |  J  |     |              |           |Success |PATH-DATA with                   | Success |
   |     | J  |  C  |     |              |           |Success |mutiple IDs.                   | Success |
   |     | C  |  G  |     |              |           |Success |G uses ...                   | Success |
   |     | G  |  C  | GET|EtherPHYCop| OperLink  |Success GET |  EtherPHYCop |   OperLinkSpeed   | Success |
   |     | J  |  G  |     |              |  Speed    |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  8  | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherPHYCop|AdminDuplex|Success GET |  EtherPHYCop |  AdminDuplexSpeed | Success |
   |     | J  |  G  |     |              |   Speed   |Success                   | Success |
   |     | G  |  J  |     |              |           |Success                   | Success |
   |     |    |     |     |              |                   |        |The side of         |
   |  9  | C  |  J  |     |              |           |Success |C thinks that|                   | Success | J
   |     | J  |  C  |     |              |           |Success |CE SHOULD get|                   | Success |
   |     | C  |  G  |     |              |           |Success |LFB instance                   | Success |
   |     | G  |  C  | GET|EtherPHYCop|OperDuplex |Success |data GET |  EtherPHYCop |  OperDuplexSpeed  | Success |
   |     | J  |  G  |     |              |   Speed   |Success |according to                   | Success |
   |     | G  |  J  |     |              |           |Success |LFBSelectors.|                   | Success |
   |     |    |     |     |              |                   |         |
   |  10 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherPHYCop|  Carrier  |Success GET |  EtherPHYCop |   CarrierStatus   | Success |
   |     | J  |  G  |     |              |  Status   |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  11 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET| EtherMACIn|AdminStatus|Success GET |  EtherMACIn  |    AdminStatus    | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  12 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACIn GET | LocalMac  |Success  EtherMACIn  | LocalMacAddresses | Success |
   |     | J  |  G  |     |              | Addresses |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  13 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACIn |L2Bridging |Success GET |  EtherMACIn  |    L2Bridging     | Success |
   |     | J  |  G  |     |           |PathEnable |Success              |   PathEnable      | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  14 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACIn |Promiscuous|Success GET |  EtherMACIn  |  PromiscuousMode  | Success |
   |     | J  |  G  |     |              |   Mode    |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  15 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACIn GET |  EtherMACIn  |   TxFlow  |Success   TxFlowControl   | Success |
   |     | J  |  G  |     |              |  Control  |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |        |
   |  16 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACIn GET |   RxFlow  |Success  EtherMACIn  |   RxFlowControl   | Success |
   |     | J  |  G  |     |              |   Control |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  17 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACIn |MACInStats |Success GET |  EtherMACIn  |     MACInStats    | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   | 18  | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACOut|AdminStatus|Success GET | EtherMACOut  |     AdminStatus   | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   | 19  | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACOut| GET |  EtherMACOut |          MTU    |Success      | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  20 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACOut|   TxFlow  |Success GET |  EtherMACOut |    TxFlowControl  | Success |
   |     | J  |  G  |     |              |  Control  |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  21 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACOut|   TxFlow  |Success GET |  EtherMACOut |    TxFlowControl  | Success |
   |     | J  |  G  |     |              |   Control |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  22 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|EtherMACOut|MACOutStats|Success GET |  EtherMACOut |     MACOutStats   | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  23 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | GET|    ARP    |PortV4Addr |Success GET |      ARP     |PortV4AddrInfoTable| Success |
   |     | J  |  G  |     |              | InfoTable |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  24 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | SET|    ARP    |PortV4Addr |Success SET |      ARP     |PortV4AddrInfoTable| Success |
   |     | J  |  G  |     |              | InfoTable |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  25 | C  |  J  |     |              |           |Success |C's misunder-|                   | Success |
   |     | J  |  C  |     |              |           |Success |standing of                   | Success |
   |     | C  |  G  |     |              |           |Success |the PATHDATA                   | Success |
   |     | G  |  C  | DEL|    ARP    |PortV4Addr |Success |in DEL |      ARP     |PortV4AddrInfoTable| Success |
   |     | J  |  G  |     |              | InfoTable |Success |Operation.                   | Success |
   |     | G  |  J  |     |              |           |Success |Later C fixed|                   | Success |
   |     |    |     |     |              |                   |        |the problem         |
   |  26 | C  |  J  |     |              |           |Success |and make it                   | Success |
   |     | J  |  C  |     |              |           |Success |successful                   | Success |
   |     | C  |  G  |     |              |           |Success |in testing                   | Success |
   |     | G  |  C  | SET|EtherMACIn SET |  EtherMACIn  |  LocalMAC |Success |with J. LocalMACAddresses | Success |
   |     | J  |  G  |     |              | Addresses |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  27 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | SET|EtherMACIn SET |  EtherMACIn  |          MTU    |Success      | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  28 | C  |  J  |     |              |           |Success |By setting                   | Success |
   |     | J  |  C  |     |              |           |Success |new reachable|                   | Success |
   |     | C  |  G  |     |              |           |Success |network,route|                   | Success |
   |     | G  |  C  | SET|IPv4NextHop|IPv4NextHop|Success |entry can be SET |  IPv4NextHop |  IPv4NextHopTable | Success |
   |     | J  |  G  |     |              |   Table   |Success |added into                   | Success |
   |     | G  |  J  |     |              |           |Success |system.                   | Success |
   |     |    |     |     |              |                   |         |
   |  29 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | SET| IPv4Ucast |IPv4Prefix |Success SET | IPv4UcastLPM |  IPv4PrefixTable  | Success |
   |     | J  |  G  |     |   LPM              |  Table    |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  30 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success |Corresponding|                   | Success |
   |     | C  |  G  |     |              |           |Success |nexthop entry|                   | Success |
   |     | G  |  C  | DEL|IPv4NextHop|IPv4NextHop|Success |MUST delete DEL |  IPv4NextHop |  IPv4NextHopTable | Success |
   |     | J  |  G  |     |              |   Table   |Success |before prefix|                   | Success |
   |     | G  |  J  |     |              |           |Success |entry.                   | Success |
   |     |    |     |     |              |                   |         |
   |  31 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | DEL| IPv4Ucast |IPv4Prefix |Success DEL | IPv4UcastLPM |  IPv4PrefixTable  | Success |
   |     | J  |  G  |     |   LPM              |   Table   |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  32 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | SET|EtherPHYCop|AdminStatus|Success SET |  EtherPHYCop |     AdminStatus   | Success |
   |     | J  |  G  |     |              |           |Success                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  33 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | SET| SET |     Ether    | VlanInput |Success   VlanInputTable  | Success |
   |     | J  |  G  |     | Classifier|   Table   |Success  Classifier  |                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  34 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | DEL| DEL |     Ether    | VlanInput |Success   VlanInputTable  | Success |
   |     | J  |  G  |     | Classifier|   Table   |Success  Classifier  |                   | Success |
   |     | G  |  J  |     |              |           |Success |                   | Success |
   |     |    |     |     |              |                   |         |
   |  35 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | SET| SET |    Ether   |VlanOutput |Success     |   VlanOutputTable | Success |
   |     | J  |  G  |    |Encapsulato|  Table    |Success     | Encapsulator |                   | Success |
   |     | G  |  J  |     |     r     |           |Success              |                   | Success |
   |     |    |     |     |              |                   |         |
   |  36 | C  |  J  |     |              |           |Success                   | Success |
   |     | J  |  C  |     |              |           |Success                   | Success |
   |     | C  |  G  |     |              |           |Success                   | Success |
   |     | G  |  C  | DEL| DEL |     Ether   |VlanOutput |Success    |  VlanOutputTable  | Success |
   |     | J  |  G  |    |Encapsulato|  Table    |Success     | Encapsulator |                   | Success |
   |     | G  |  J  |     |     r              |           |Success                   | Success |
   +----+----+-----+----+-----------+-----------+--------+-------------+
   +-----+----+-----+-----+--------------+-------------------+---------+

                   Figure 8: LFB Operation Test Results

5.2.  TML with IPSec Test

   In this scenario, ForCES TML will run over IPSec channel.All the
   implementors who channel.
   Implementors joined this interoperability test use the same
   third-party third-
   party tool software 'racoon' to establish IPSec channel.To be
   mentioned is that we have not repeat all the operations listed channel.  Some
   typical LFB operation tests as in Scenario 1,only some typical operations 1 have been done.

   Although some problems still remains in the connection repeated with Greece,
   the TML with IPSec new security TML.

   A note on this test is considered as success.  The goal was is, because of the system difficulty to
   verify whether implement
   IPSec over TML, Greece did not join in the interaction test.  Therefore, this
   scenario only successfully took place between CE and FE can be done normally
   under such IPSec environment.  Since Japan's C and China's
   implementation worked J. However, it is assumed that Greece's would as well, as
   the problem was on the setup and configuration of
   still valid to make the interoperability test among two participants.

   The TML with IPSec
   connection and not on the ForCES protocol perse.

   During the test following results as shown in figure occured.

   +----+----+-----+----+-----------+-----------+--------+-------------+
   |Test| are reported by Figure 9.

   +-----+----+-----+-----+--------------+-------------------+---------+
   |Test#| CE |FE(s)|Oper| |FE(s)|Oper |       LFB   |Component/    |     Component/    | Result  |   Comment
   |
   |#     |    |     |     |           |Capability              |     Capability    |         |
   +----+----+-----+----+-----------+-----------+--------+-------------+
   +-----+----+-----+-----+--------------+-------------------+---------+
   |  1  | C  |  J  | GET |           |           |Success |For unkown   |
   |    | J  |  C  |    |           |           |Success |error in     |
   |    | C  |  G  |    |           |           |Failure |configuration|
   |    | G  |  C  | GET|   FEObject  |LFBTopology|Failure |with racoon,   |   LFBTopology     |    | J  |  G Success |
   |     |           |Failure |Greece still |
   | J  | G  C  |  J     |              |                   |           |Failure |need some Success |
   |     |    |     |     |              |                   |        |time to fix         |
   |  2  | C  |  J  | GET |           |           |Success |the issue.   |
   |    | J  |  C  |    |           |           |Success |So,this      |
   |    | C  |  G  |    |           |           |Failure |scenario only|
   |    | G  |  C  | GET|   FEObject  |LFBSelector|Failure |took place   |   |   LFBSelectors    | J Success |  G
   |     | J  |    s      |Failure |between  C and|
   |    | G  |  J  |     |              |           |Failure |J.                   | Success |
   |     |    |     |     |              |                   |         |
   |  3  | C  |  J  | SET |           |           |Success |             |
   |    | J  |  C  |    |           |           |Success |             |
   |    | C  |  G  |    |           |           |Failure |             |
   |    | G  |  C  | SET|   Ether      | VlanInput |Failure |             |
   |    | J  |  G  |    | Classifier|   Table   |Failure   VlanInputTable  | Success |
   |     | G  | J  |  C  |     |           |Failure Classifier   |                   | Success |
   |     |    |     |     |              |                   |         |
   |  4  | C  |  J  | DEL |           |           |Success |             |
   |    | J  |  C  |    |           |           |Success |             |
   |    | C  |  G  |    |           |           |Failure |             |
   |    | G  |  C  | DEL|   Ether      | VlanInput |Failure   VlanInputTable  | Success |
   |     | J  |  G  |    | Classifier|   Table   |Failure |             |
   |    | G  |  J  C  |     | Classifier   |           |Failure                   | Success |
   +----+----+-----+----+-----------+-----------+--------+-------------+
   +-----+----+-----+-----+--------------+-------------------+---------+

                   Figure 9: TML with IPSec Test Results

5.3.  CE High Availability Test

   In this scenario one FE will connect and associate with a master CE
   and a backup CE.  When the master CE is considered disconnected the
   FE would attempt to find another associated CE to become the master
   CE.

   The CEHA scenario as is described in Scenario 3 was completed
   successfully for both setups.

   Due to a bug in the FE, a possible issue was caught.  The bug in the
   FE introduced a delay in message handling of 1 second.  The master CE
   was sending Heartbeats at a rate of one in 500milliseconds (2 per
   second).  As heartbeats are of very low priority, the FE was working
   fine with associated only with the master CE.  However when the FE
   attempted to associate with the backup CE the following issue
   occured.

   The FE was checking first for messages from all priorities from the
   master CE and if the master CE hasn't sent any messages then it would
   check the backup CE.  So, when the FE was ordered to begin
   associating with the backup CE , it sent the Association setup
   message, the backup CE received it, responded back with an
   Association Setup result, but the FE never processed managed to
   process it.

   While the bug was fixed and the CEHA scenario was completed
   successfully, the issue still remains.  This is actually an
   implementation issue of how the FE prioritizes incoming messages from
   multiple CEs.  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 backup CEs,
      then the FE SHOULD receive 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.

5.4.  Packet Forwarding Test

   The Scenario of

   As described in the ForCES LFB library [I-D.ietf-forces-lfb-lib],
   packet forwading forwarding is the most complex one because it
   need the Scenario 1 must be completed.In implemented by a set of LFB classes that compose
   a processing path for packets.  In this scenario testing,the
   pattern test scenario, as shown in
   Figure 7, a ForCES router running OSPF protocol should be construted.
   Moreover, a set of J-CE C-FE was carried out.  Smartbits's 2 testing ports
   connect LFBs including RedirectIn, RedirectOut,
   IPv4UcastLPM, and IPv4NextHop LFBs should be constructed and be
   joined in a processing data path.  RedirectIn and RedirectOut LFBs
   redirect OSPF hello and LSA packets from and to CE.  Smartbits test
   machine is used to FE's 2 data-forwarding ports,meanwhile smartbits simulate
   ospf an OSPF router and try to exchange the
   OSPF hello packet and LSA packet with CE,because CE also has an OSPF process in it so that the whole
   NE including FE ForCES router.

   Cases (a) and (b) in Figure 7 both need a RedirectIn LFB to send OSPF
   packets generated by CE looks like to FE by use of ForCES packet redirect
   messages.  The OSPF packets are futher sent to an outside OSPF router.

   In this scenario,RedirectIn,RedirectOut,IPv4NextHop,IPv4UcastLPM LFB
   should join Router
   by the data path.First, it must be sured that FE via forwarding LFBs including IPv4NextHop and IPv4UcastLPM can work normally so that route entry can be added
   to FE.Second,RedirectIn and
   LFBs.  A RedirectOut LFB MUST work,only that can in FE redirect out is used to send OSPF hello and LSA packets to CE received
   from
   smartBits,FE outside OSPF Router to CE by ForCES packet redirect in messages.

   By running OSPF hello protocol, CE in the ForCES router then can generate
   new routes and LSA load them to routing table in FE.  FE is then able to
   forward packets according to smartBits
   received from CE's OSPF process.

   During the test, routing table.

   The test is reported with the results as shown in the following figure are
   recorded.

   +----+----+-----+----------------+-----------+--------+-------------+
   |Test| Figure 10

   +-----+----+-----+-------------------------+--------------+---------+
   |Test#| CE |FE(s)|           Item          |     LFB LFBs Related | Result  |   Comment   |
   |#   |    |     |                |           |        |             |
   +----+----+-----+----------------+-----------+--------+-------------+
   +-----+----+-----+-------------------------+--------------+---------+
   |  1  | J  |  C  |IPv4NextHopTable|IPv4NextHop|Success |  Muticast   |
   |    |    |  |  IPv4NextHopTable SET   | IPv4NextHop  |        |  route is   | Success |
   |     |    |     |                         |              |  added by         |
   |  2  | J  |  C  |IPv4PrefixTable | IPv4Ucast |Success |manual,this  |
   |    |    |  |   IPv4PrefixTable SET   |     LPM   |        |problem still|
   |    | IPv4UcastLPM | Success |
   |     |        |need to be    |     |                         |              |     |Redirect  ospf  |           |        |fixed in the         |
   |  3  | J  |  C  |packet from CE  |RedirectIn |Success |   future.   |
   |    |    |     |to SmartBits    |           |        |             |
   |    |    |     |                |           |        |    As for   |
   |    |    |  |Redirect ospf packet from|  RedirectIn  | Success |
   |   redirect  |
   | 4  | J  |  C  |packet from     |RedirectOut|Success |   message,  |     |    |     |     |SmartBits to     CE |           |        |ospf hello to SmartBits     |              |         |
   |     |    |     |        |packet in 2-                         |              |         |
   |     |Metadata in     |RedirectOut|        |direction can|
   | 5  4  | J  |  C  |redirect message|RedirectIn |Success |be wathed by |
   |    |    |     |                |           |        | wireshark.  |
   |    |    |     |                |           |        |however  |Redirect ospf |
   |    |    |     |OSPF neiborhood |RedirectOut|        | packet    |
   | 6  | J  |  C  |   discovery    |RedirectIn |Success |received from|  RedirectOut | Success |
   |     |    |     |        |CE have an   |
   |    |    |     |                |RedirectOut|        |error with   |
   |    |    |     |    OSPF DD     |RedirectIn |        |checksum,so  |
   | 7  | J  |  C  |    exchange    |IPv4NextHop|Success |smartBits    |
   |    |    |     |                | IPv4Ucast |        |will drop it |
   |    |    |     |                |   LPM     |        |with no      |
   |    |    |     |                |           |        |neighborhood |
   |    |    |     |                |           |        |discovered.  |
   | 8  | J  |  C  |    OSPF LSA    |RedirectOut|        |             |
   |    |    |     |    exchange    |RedirectIn |Success |             |
   |    |    |     |                |IPv4NextHop|        |             |
   |    |    |     |                | IPv4Ucast |        |             |
   |    |    |     |                |   LPM     |        |             |
   |    |    |     |                |           |        |             |
   |    |    |     |                |RedirectOut|        |             |
   | 9  | J  |  C  |Data Forwarding |RedirectIn |        |             |     SmartBits to CE     |              |         |
   |                |IPv4NextHop|Success     |    |     |                         |              |         |
   | IPv4Ucast  5  | J  |  C  |       Metadata in       |  RedirectOut | Success |
   |     |    LPM    |     |     redirect message    |  RedirectIn  |         |
   |     |    |     |                         |              |         | 10
   | C  6  | J  |IPv4NextHopTable|IPv4NextHop|Success  |  C  |OSPF neiborhood discovery|  RedirectOut | Success |
   |     |    |      SET     |                         |  RedirectIn  |         |
   |     |    |     |                         |              |         |
   |  7  | 11 J  |  C  |  J  |IPv4PrefixTable | IPv4Ucast |Success     OSPF DD exchange    |  RedirectOut | Success |
   |     |    |      SET     |     LPM                         |  RedirectIn  |         |
   |     |    |     |                         |  IPv4NextHop |         |
   |     |    |     |     |Redirect  ospf                         |              |         |
   |  8  | 12 J  |  C  |  J  |packet from CE  |RedirectIn |Success |    OSPF LSA exchange    |  RedirectOut | Success |
   |     |to other OSPF     |    |     |                         |  RedirectIn  |         |
   |     |    router    |     |                         |  IPv4NextHop |         |
   |     |    |     |                         |  IPv4UcastLPM|         |
   |     |    |     |     |Redirect ospf                         |              |         |
   |  9  | 12 J  |  C  |  J  |packet from     |RedirectOut|Success     Data Forwarding     |  RedirectOut |         |
   |     |     |other OSPF    |     |                         |  RedirectIn  | Success |
   |     |    |     |router to CE     |                         |  IPv4NextHop |         |
   |     |    |     |                         |  IPv4UcastLPM|         |
   |     |    |     |                         |     |Metadata in     |RedirectOut|              |         |
   | 13  10 | C  |  J  |redirect message|RedirectIn |Success  |  IPv4NextHopTable SET   |  IPv4NextHop | Success |
   |     |    |     |                         |              |         |
   |  11 | C  |  J  |   IPv4PrefixTable SET   |  IPv4UcastLPM| Success |
   |     |    |     |                         |     |OSPF neiborhood |RedirectOut|              |         |
   | 14  12 | C  |  J  |Redirect ospf packet from|  RedirectIn  |   discovery    |RedirectIn |Success |             |
   |    |    |     |                |           | Success |
   |     |    |     | CE to other OSPF router |                |RedirectOut|              |         |
   |     |    |     |    OSPF DD     |RedirectIn                         |              |         |
   | 15  13 | C  |  J  |Redirect ospf packet from|  RedirectOut |    exchange    |IPv4NextHop|Failure |FE connected |
   |    | Success |
   |     | IPv4Ucast    |        |by 2     |other OSPF router to CE  |              |         |
   |     |    |   LPM     |        |router,only  |
   |     |                         |              |         |
   |        |1 OSPF can be|  14 | C  |  J  |       Metadata in       |  RedirectOut | Success |        |discovered by|
   |     |    |     |     redirect message    |  RedirectIn  |        |CE,so DD         |
   |     |    |     |                         |              |        |exchanging         |
   | 16  15 | C  |  J  |OSPF neiborhood discovery|  RedirectOut |    OSPF LSA    |RedirectOut|        |stopped. Success |
   |     |    |     |    exchange    |RedirectIn |Failure                         |  RedirectIn  |         |
   |     |    |                |IPv4NextHop|     |                         |              |         |
   |     |    | IPv4Ucast     |                         |  RedirectOut |         |
   |  16 | C  |  J  |   LPM    OSPF DD exchange     |  RedirectIn  | Failure |
   |     |    |     |                         |  IPv4NextHop |         |
   |     |    |     |                         |                |RedirectOut|              |         |
   |  17 | J  | C  |Data Forwarding |RedirectIn  |  J  |    OSPF LSA exchange    |  RedirectOut |         |
   |     |                |IPv4NextHop|TBD    |     |                         |  RedirectIn  | Failure |
   |     | IPv4Ucast    |     |                         |  IPv4NextHop |         |
   |     |    |    LPM     |                         |  IPv4UcastLPM|         |
   +----+----+-----+----------------+-----------+--------+-------------+
   +-----+----+-----+-------------------------+--------------+---------+
                 Figure 10: Packet Forwarding Test Results

   Comment on Test #16 and #17:

   The two test items failed.  Note that Test #7 and #8 are exactly the
   same as these tests, only with CE and FE implementors are exchanged,
   and Test #12 and #13 show the redirect channel works well.  As a
   result, it can be infered that the problem caused the test failure
   was almost certainly from the implementation of the related LFBs
   rather than from the ForCES protocol design problem, therefore the
   failure does not lead to the interoperability problem on ForCES.

6.  Discussions

6.1.  On Data Encapsulation Format

   In the first day of the test, it was found that the LFB inter-
   operations about tables all failed.  The reason is found to be the
   different ForCES protocol data encapsulation method among different
   implementations.  The encapsulation issues are detailed as below:

   Assuming that an LFB has two components, one a struct with ID 1 and
   an array with ID 2 with two components of u32 both per row.

   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.  On response of PATH-DATA format

   When a CE sends a config/query ForCES protocol message to an FE from
   a different implementor, the CE probably receives response from the
   FE with different PATH-DATA encaplation format.  For example, if a CE
   sends a query message with a path of 1 to a third party FE to
   manipulate struct 1 as defined above, the FE is probable to generate
   response with two different PATH-DATA encaplation format: one is the
   value with FULL/SPARSE-DATA and the other is the value with many
   parallel PATH-DATA TLV and nested PATH-DATA TLV, as below:

   format 1:
       OPER = GET-RESPONSE-TLV
           PATH-DATA-TLV:
               IDs=1
               FULLDATA-TLV containing valueof(a),valueof(b)
   format 2:
       OPER = GET-RESPONSS-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 test shows that an ForCES element (CE or FE)
   sender is free to choose whatever data structure that IETF ForCES
   documents define and best suits the element, while an ForCES element
   (CE or FE) is preferable to accept and process information (requests
   and responses) that use any legitimate structure defined by IETF
   ForCES documents.  While in the case an ForCES element is free to
   choose any legitimate data structure as a response, it is preferred
   the ForCES element responds in the same format that the request was
   made, as it is most probably the data structure is the request sender
   looks forward to receive.

   2.  On operation to array

   An array operation may also have several different data encaplation
   formats.  For instance, if a CE sends a config message to table 1
   with a path of (2.1), which refers to component with ID=2, which is
   an array, and the second ID is the row, so row 1, it may be
   encapsulated with three formats as below:

   format 1:
       OPER = SET-TLV
           PATH-DATA-TLV:
               IDs=2.1
               FULLDATA-TLV conaining 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 CE is targeting the whole array, for example if the
   array is empty and 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 shows that format 1 and format
   3, which take full advantage of multiple data elements description in
   one TLV of FULLDATA-TLV, get more efficiency, although format 2 can
   also get the same operating goal.

7.  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@zjgsu.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@zjgsu.edu.cn

8.  Acknowledgements

   The authors would also like thank the following test participants:

      Chuanhuang Li, Hangzhou BAUD Networks
      Ligang Dong, Zhejiang Gongshang University
      Jingjing Zhou, Zhejiang Gongshang Unviersity
      Liaoyuan Ke, Hangzhou BAUD Networks
      Kelei Jin,Hangzhou BAUD Networks

9.  IANA Considerations

   This memo includes no request to IANA.

10.  Security Considerations

   TBD IANA.

10.  Security Considerations

   Developers of ForCES FEs and CEs must take the security
   considerations of the ForCES Framework [RFC3746] and the ForCES
   Protocol [RFC5810] into account.  Also, as specified in the security
   considerations section of the SCTP-Based TML for the ForCES Protocol
   [RFC5811] the transport-level security, has to be ensured by IPsec.

11.  References

11.1.  Normative References

   [I-D.ietf-forces-ceha]
              Ogawa, K., Wang, W., Haleplidis, E., and J. Salim, "ForCES
              Intra-NE High Availability", draft-ietf-forces-ceha-01
              (work in progress), February 2011.

   [I-D.ietf-forces-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 (work in 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.

   [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.

11.2.  Informative References

   [Ethereal]
              "Ethereal 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]
              Ogawa, K., Wang, W., Haleplidis, E., and J. Salim, "ForCES
              Intra-NE High Availability", draft-ietf-forces-ceha-01
              (work in progress), February 2011.

   [I-D.ietf-forces-lfb-lib]
              Wang, W., Haleplidis, E., Ogawa, K., Li, C., and J.
              Halpern, "ForCES Logical Function Block (LFB) Library",
              draft-ietf-forces-lfb-lib-05 (work in progress),
              July 2011.

   [RFC2629]  Rose, M., "Writing I-Ds and RFCs using XML", RFC 2629,
              June 1999.

   [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.

11.2.  Informative References

   [RFC2629]  Rose, M., "Writing I-Ds

   [Tcpdump]  "Tcpdump is a Linux protocol analyzer. The specific
              tcpdump that was used is a modified tcpdump, by Jamal Hadi
              Salim, that can analyze and RFCs using XML", RFC 2629,
              June 1999. decode the ForCES protocol
              messages", http://www.ietf.org/mail-archive/web/forces/
              current/msg03811.html .

Authors' Addresses

   Weiming Wang
   Zhejiang Gongshang University
   18 Xuezheng Str., Xiasha University Town
   Hangzhou,   310018
   P.R.China

   Phone: +86-571-28877721
   Email: wmwang@zjgsu.edu.cn

   Kentaro Ogawa
   NTT Corporation
   Tokyo,
   Japan

   Email: ogawa.kentaro@lab.ntt.co.jp

   Evangelos Haleplidis
   University of Patras
   Patras,
   Greece

   Email: ehalep@ece.upatras.gr

   Ming Gao
   Hangzhou BAUD Networks
   408 Wen-San Road
   Hangzhou,   310012
   P.R.China

   Phone: +86-571-28877751
   Email: gmyyqno1@pop.zjgsu.edu.cn

   Jamal Hadi Salim
   Mojatatu Networks
   Ottawa
   Canada

   Email: hadi@mojatatu.com