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     IP Storage Working Group                                  Charles Monia
     INTERNET DRAFT                                           Rod Mullendore
     Expires July 2002                                            Josh Tseng
     <draft-ietf-ips-ifcp-08.txt>                             Nishan Systems
     
                                                           Franco Travostino
                                                             Nortel Networks
     
                                                              David Robinson
                                                            Sun Microsystems
     
                                                               Wayland Jeong
                                                             Troika Networks
     
                                                                   Rory Bolt
                                                                 Quantum/ATL
     
                                                             Paul Rutherford
                                                                        ADIC
     
                                                                Mark Edwards
                                                                   Eurologic
     
                                                                January 2002
     
     
        iFCP - A Protocol for Internet Fibre Channel Storage Networking
     
     Status of this Memo
     
         This document is an Internet-Draft and is in full conformance with
         all provisions of Section 10 of RFC 2026 [RFC2026].
     
         Internet-Drafts are working documents of the Internet Engineering
         Task Force (IETF), its areas, and its working groups. Note that
         other groups may also distribute working documents as Internet-
         Drafts. 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."
     
         The list of current Internet-Drafts can be accessed at
         http://www.ietf.org/ietf/1id-abstracts.txt
     
         The list of Internet-Draft Shadow Directories can be accessed at
         http://www.ietf.org/shadow.html.
     
     Comments
     
         Comments should be sent to the ips mailing list (ips@ece.cmu.edu)
         or to the author(s).
     
     
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     Status of this Memo...................................................1
     Comments..............................................................1
     1.      Abstract.....................................................4
     2.      About This Document..........................................4
     2.1     Conventions used in this document............................4
     2.2     Purpose of this document.....................................4
     3.      iFCP Introduction............................................4
     3.1     Definitions..................................................5
     4.      Fibre Channel Communication Concepts.........................7
     4.1     The Fibre Channel Network....................................7
     4.2     Fabric Topologies............................................8
     4.2.1    Switched Fibre Channel Fabrics..............................9
     4.2.2    Mixed Fibre Channel Fabric.................................10
     4.3     Fibre Channel Layers and Link Services......................11
     4.3.1    Fabric-Supplied Link Services..............................12
     4.4     Fibre Channel Nodes.........................................12
     4.5     Fibre Channel Device Discovery..............................13
     4.6     Fibre Channel Information Elements..........................13
     4.7     Fibre Channel Frame Format..................................14
     4.7.1    N_PORT Address Model.......................................14
     4.8     Fibre Channel Transport Services............................15
     4.9     Login Processes.............................................16
     5.      The iFCP Network Model......................................16
     5.1     Fibre Channel Fabric Topologies Supported by iFCP...........18
     5.2     iFCP Transport Services.....................................18
     5.2.1    Fibre Channel Transport Services Supported by iFCP.........18
     5.3     iFCP Device Discovery and Configuration Management..........19
     5.4     iFCP Fabric Properties......................................19
     5.4.1    Address Transparency.......................................20
     5.4.2    Configuration Scalability..................................20
     5.4.3    Fault Tolerance............................................20
     5.5     The iFCP N_PORT Address Model...............................21
     5.5.1    Operation in Address Transparent Mode......................22
     5.5.2    Operation in Address Translation Mode......................23
     5.5.3    Address Translation........................................24
     6.      iFCP Protocol...............................................27
     6.1     Overview....................................................27
     6.1.1    iFCP Transport Services....................................27
     6.1.2    iFCP Support for  Link Services............................28
     6.2     TCP Stream Transport of iFCP Frames.........................29
     6.2.1    iFCP Session Model.........................................29
     6.2.2    iFCP Session Management....................................29
     6.2.3    Terminating an N_PORT Login Session........................34
     6.3     IANA Considerations.........................................35
     6.4     Encapsulation of Fibre Channel Frames.......................35
     6.4.1    Encapsulation Header Format................................36
     6.4.2    SOF and EOF Delimiter Fields...............................39
     6.4.3    Frame Encapsulation........................................40
     6.4.4    Frame De-encapsulation.....................................40
     7.      TCP Session Control Messages................................41
     7.1     Connection Bind (CBIND).....................................43
     7.2     Unbind Connection (UNBIND)..................................46
     
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     7.3     LTEST -- Test Connection Liveness...........................48
     8.      Fibre Channel Link Services.................................49
     8.1     Special Link Service Messages...............................50
     8.2     Link Services Requiring Payload Address Translation.........52
     8.3     Fibre Channel Link Services Processed by iFCP...............54
     8.3.1    Special Extended Link Services.............................55
     8.3.2    Special FC-4 Link Services.................................68
     8.4     FLOGI Service Parameters Supported by an iFCP Gateway.......70
     9.      iFCP Error Detection........................................72
     9.1     Overview....................................................72
     9.2     Stale Frame Prevention......................................72
     9.2.1    Enforcing R_A_TOV Limits...................................73
     10.     Fabric Services Supported by an iFCP implementation.........75
     10.1    F_PORT Server...............................................75
     10.2    Fabric Controller...........................................75
     10.3    Directory/Name Server.......................................75
     10.4    Broadcast Server............................................76
     10.4.1     Establishing the Broadcast Configuration.................76
     10.4.2     Broadcast Session Management.............................77
     11.     iFCP Security...............................................78
     11.1    Overview....................................................78
     11.2    iFCP Security Operating Requirements........................78
     11.2.1     Context..................................................78
     11.2.2     Security Threats.........................................78
     11.2.3     Interoperability Requirements with Security Gateways.....79
     11.2.4     Statically and Dynamically Assigned IP Addresses.........79
     11.2.5     Authentication Requirements..............................79
     11.2.6     Confidentiality Requirements.............................80
     11.2.7     Rekeying Requirements....................................80
     11.2.8     Usage Requirements.......................................80
     11.2.9     iSNS Role................................................80
     11.3    iFCP Security Design........................................80
     11.3.1     Enabling Technologies....................................80
     11.3.2     Use of IKE and IPsec.....................................82
     11.3.3     Signatures and Certificate-based authentication..........84
     11.4    iSNS and iFCP Security......................................84
     11.5    Use of iSNS to Distribute Security Policy...................85
     11.6    Minimal Security Policy for an iFCP gateway.................86
     12.     Quality of Service Considerations...........................86
     12.1    Minimal requirements........................................86
     12.2    High-assurance..............................................86
     13.     Author's Addresses..........................................88
     14.     References..................................................90
     14.1    Normative...................................................90
     14.2    Non-Normative...............................................91
     A.      iFCP Support for Fibre Channel Link Services................93
     A.1     Basic Link Services.........................................93
     A.2     Link Services Processed Transparently.......................93
     A.3     iFCP-Processed Link Services................................94
     Full Copyright Statement.............................................97
     
     
     
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     1.       Abstract
     
         This document specifies an architecture and gateway-to-gateway
         protocol for the implementation of Fibre Channel fabric
         functionality on a network in which TCP/IP switching and routing
         elements replace Fibre Channel components. The protocol enables the
         attachment of Fibre Channel devices to an IP network by supporting
         the fabric services required by such devices.
     
     2.       About This Document
     
     2.1      Conventions used in this document
     
         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 RFC-2119
         [RFC2119].
     
         All frame formats are in big endian network byte order.
     
     2.2      Purpose of this document
     
         This is a standards-track document, which specifies a protocol for
         the implementation of Fibre Channel transport services on a TCP/IP
         network.  Some portions of this document contain material from
         standards controlled by NCITS T10 and T11. This material is
         included here for informational purposes only. The authoritative
         information is given in the appropriate NCITS standards document.
     
         The authoritative portions of this document specify the mapping of
         standards-compliant fibre Channelprotocol implementations to
         TCP/IP.  This mapping includes sections of this document which
         describe the "iFCP Protocol" (see section 6).
     
     3.       iFCP Introduction
     
         iFCP is a gateway-to-gateway protocol, which provides Fibre Channel
         fabric services to Fibre Channel devices over a TCP/IP network.
         iFCP uses TCP to provide congestion control, error detection and
         recovery. iFCP's primary objective is to allow interconnection and
         networking of existing Fibre Channel devices at wire speeds over an
         IP network.
     
         The protocol and method of frame address translation described in
         this document permit the attachment of Fibre Channel storage
         devices to an IP-based fabric by means of transparent gateways.
     
         The protocol achieves this transparency by allowing normal Fibre
         Channel frame traffic to pass through the gateway directly, with
     
     
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         provisions, where necessary, for intercepting and emulating the
         fabric services required by a Fibre Channel device.
     
     3.1      Definitions
     
         Terms needed to clarify the concepts presented in this document are
         presented here.
     
         Locally Attached Device - With respect to a gateway, a Fibre
                 Channel device accessed through the Fibre Channel fabric to
                 which the gateway is attached.
     
         Remotely Attached Device - With respect to a gateway, a Fibre
                 Channel device accessed from the gateway by means of the
                 iFCP protocol.
     
         Address-translation mode û A mode of gateway operation in which the
                 scope of N_PORT fabric addresses for locally attached
                 devices are local to the iFCP gateway.
     
         Address-transparent mode û A mode of gateway operation in which the
                 scope of N_PORT fabric addresses for all Fibre Channel
                 devices are unique to the logical fabric to which the
                 gateway belongs.
     
         Gateway Region û The portion of the iFCP storage network accessed
                 through an iFCP gateway. Fibre Channel devices in the
                 region consist of all Fibre Channel devices locally
                 attached to the gateway.
     
         Logical Fabric û The union of two or more gateway regions
                 configured to interoperate together in address-transparent
                 mode.
     
         Fibre Channel Device - An entity implementing the functionality
                 accessed through an FC-4 application protocol.
     
         Fibre Channel Node - A collection of one or more N_Ports controlled
                 by a level above the FC-2 layer. A node is attached to a
                 Fibre Channel fabric by means of the N_PORT interface
                 described in [FC-FS].
     
         Fibre Channel Network - A native Fibre Channel fabric and all
                 attached Fibre Channel nodes.
     
         Fabric - The components of a network that provide the transport
                 services defined in [FC-FS]. A fabric may be implemented in
                 the IP framework by means of the architecture and protocols
                 discussed in this document.
     
         Fabric Port -  The interface through which an N_PORT accesses a
                 Fibre Channel fabric.  The type of fabric port depends on
     
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                 the Fibre Channel fabric topology. In this specification,
                 all fabric port interfaces are considered to be
                 functionally equivalent.
     
         FC-2 - The Fibre Channel transport services layer described in [FC-
                 FS].
     
         FC-4 - The Fibre Channel application layer. This layer is
                 functionally equivalent to the TCP/IP application layer.
     
         iFCP Portal - An entity representing the point at which a logical
                 or physical iFCP device is attached to the IP network.  The
                 network address of the iFCP portal consists of the IP
                 address and TCP port number.
     
         N_PORT - An iFCP or Fibre Channel entity representing the interface
                 to Fibre Channel device functionality. This interface
                 implements the Fibre Channel N_PORT semantics specified in
                 [FC-FS].  Fibre Channel defines several variants of this
                 interface that are dependant on the Fibre Channel fabric
                 topology.  As used in this document, the term applies
                 equally to all variants.
     
         N_PORT fabric address - The address of an N_PORT within the Fibre
                 Channel fabric.
     
         N_PORT ID -- The address of a locally attached N_PORT within a
                 gateway region.  N_PORT I/Ds are assigned in accordance
                 with the Fibre Channel rules for address assignment
                 specified in [FC-FS].
     
         N_PORT Alias --  The N_PORT address assigned by a gateway to
                 represent a remote N_PORT accessed via the iFCP protocol.
                 When routing frame traffic in address translation mode, the
                 gateway automatically converts N_PORT aliases to N_PORT
                 network addresses and vice versa.
     
         N_PORT Network Address - The address of an N_PORT in the IP fabric.
                 This address consists of the IP address of the iFCP Portal
                 and the N_PORT ID of the locally attached Fibre Channel
                 device.
     
         F_PORT - The interface used by an N_PORT to access Fibre Channel
                 switched fabric functionality.
     
         iFCP - The protocol discussed in this document.
     
         Logical iFCP Device - The abstraction representing a single Fibre
                 Channel device as it appears on an iFCP network.
     
         iSNS - The server functionality and IP protocol which provides
                 storage name services in an iFCP network. Fibre Channel
     
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                 Name services are implemented  by an iSNS name server as
                 described in [ISNS].
     
         N_PORT Session - An association created when two N_PORTS have
                 executed a PLOGI operation.  It is comprised of the N_PORTs
                 and TCP connection that carries traffic between them.
     
         iFCP Frame - A Fibre Channel frame encapsulated in accordance with
                 the Common Encapsulation Specification [ENCAP] and this
                 specification.
     
         Port Login (PLOGI) - The Fibre Channel Extended Link Service (ELS)
                 that establishes an N_PORT login session through the
                 exchange of identification and operation parameters between
                 an originating N_PORT and a responding N_PORT.
     
         DOMAIN_ID û The value contained in the high-order byte of a 24-bit
                 N_PORT Fibre Channel address.
     
     4.       Fibre Channel Communication Concepts
     
         Fibre Channel is a frame-based, serial technology designed for
         peer-to-peer communication between devices at gigabit speeds and
         with low overhead and latency.
     
         This section contains a discussion of the Fibre Channel concepts
         that form the basis for the iFCP network architecture and protocol
         described in this document. Readers familiar with this material may
         skip to section 5.
     
         Material presented in this section is drawn from the following T11
         specifications:
     
         -- The Fibre Channel Framing and Signaling Interface, [FC-FS]
     
         -- Fibre Channel Switch Fabric -2, [FC-SW2]
     
         -- Fibre Channel Generic Services, [FC-GS3]
     
         -- Fibre Channel Fabric Loop Attachment, [FC-FLA]
     
         The reader will find an in-depth treatment of the technology in
         [KEMCMP] and [KEMALP].
     
     4.1      The Fibre Channel Network
     
         The fundamental entity in Fibre Channel is the Fibre Channel
         network. Unlike  a layered network architecture,  a Fibre Channel
         network is largely specified by functional elements and the
         interfaces between them. As shown in Figure 1, these consist, in
         part, of the following:
     
     
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        a) N_PORTs -- The end points for Fibre Channel traffic. In the FC
           standards, N_PORT interfaces have several variants, depending on
           the topology of the fabric to which they are attached.  As used
           in this specification, the term applies to any one of the
           variants.
     
        b) FC Devices û The Fibre Channel devices to which the N_PORTs
           provide access.
     
        c) Fabric Ports -û The interface within a fabric that provides Fibre
           Channel attachment for an N_PORT.  The types of fabric port
           depend on the fabric topology and are discussed in section 4.2.
     
        d) The fabric infrastructure for carrying frame traffic between
           N_PORTs.
     
        e) Within a switched or mixed fabric (see section 4.2), a set of
           auxiliary servers, including a name server for device discovery
           and network address resolution.  The types of service depend on
           the network topology.
     
       +--------+   +--------+          +--------+  +--------+
       |  FC    |   |  FC    |          |  FC    |  |  FC    |
       | Device |   | Device |<-------->| Device |  | Device |
       |........|   |........|          |........|  |........|
       | N_PORT |   | N_PORT |          | N_PORT |  | N_PORT |
       +---+----+   +----+---+          +----+---+  +----+---+
           |             |                   |           |
       +---+----+   +----+---+          +----+---+  +----+---+
       | Fabric |   | Fabric |          | Fabric |  | Fabric |
       | Port   |   | Port   |          | Port   |  | Port   |
       +========+===+========+==========+========+==+========+
       |                        Fabric                       |
       |                          &                          |
       |                     Fabric Services                 |
       +-----------------------------------------------------+
                         Figure 1 -- A Fibre Channel Network
     
         The following sections describe Fibre Channel fabric topologies and
         give an overview of the Fibre Channel communications model.
     
     4.2      Fabric Topologies
     
         The principal Fibre Channel fabric topologies consist of the
         following:
     
         a)  Arbitrated Loop -- A series of N_PORTs connected together in
             daisy-chain fashion.  Data transmission between N_PORTs
             requires arbitration for control of the loop in a manner
             similar to a token ring network.
     
     
     
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         b)  Switched Fabric --  A fabric consisting of switching elements,
             as described in section 4.2.1.
     
         c)  Mixed Fabric -- A fabric consisting of switches and "fabric-
             attached" loops.  A description can be found in [FC-FLA].
     
         Depending on the topology, the N_PORT and fabric port variants
         through which a Fibre Channel device is attached to the network may
         be one of the following:
     
              Fabric Topology  Fabric Port Type    N_PORT Variant
              ---------------  ----------------    --------------
     
              Loop             L_PORT              NL_PORT
     
              Switched         F_PORT              N_PORT
     
              Mixed            FL_PORT             NL_PORT
     
                               F_PORT              N_PORT
     
     
     
         The differences in each N_PORT variant and its corresponding fabric
         port are confined to the interactions between them.  To an external
         N_PORT, all fabric ports are transparent and all remote N_PORTs are
         functionally identical.
     
     4.2.1   Switched Fibre Channel Fabrics
     
         An example of a multi-switch Fibre Channel fabric is shown below.
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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                 +----------+          +----------+
                 |    FC    |          |  FC      |
                 |   Device |          | Device   |
                 |..........|          |..........|
                 |   N_PORT |<........>| N_PORT   |
                 +----+-----+          +-----+----+
                      |                      |
                 +----+-----+          +-----+----+
                 | F_PORT   |          | F_PORT   |
       ==========+==========+==========+==========+==============
                 |  FC      |          | FC       |
                 |  Switch  |          | Switch   |
                 +----------+          +----------+ Fibre Channel
                 |Inter-    |          |Inter-    |   Fabric
                 |Switch    |          |Switch    |
                 |Interface |          |Interface |
                 +-----+----+          +-----+----+
                       |                     |
                       |                     |
                 +-----+----+----------+-----+----+
                 |Inter-    |          |Inter-    |
                 |Switch    |          |Switch    |
                 |Interface |          |Interface |
                 +----------+          +----------+
                 |            FC Switch           |
                 |                                |
                 +--------------------------------+
                    Figure 3 -- Multi-Switch Fibre Channel Fabric
     
         The interface between switch elements is either proprietary or the
         standards-compliant E_PORT interface described by the FC-SW2
         specification, [FC-SW2].
     
     4.2.2   Mixed Fibre Channel Fabric
     
         A mixed fabric contains one or more arbitrated loops connected to a
         switched fabric as shown in Figure 4.
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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                 +----------+          +----------+   +---------+
                 |    FC    |          |  FC      |   |  FC     |
                 |   Device |          | Device   |   | Device  |
                 |..........|          |..........|   |.........|
                 |   N_PORT |<........>| NL_PORT  +---+ NL_PORT |
                 +----+-----+          +-----+----+   +----+----+
                      |                      |   FC Loop   |
                 +----+-----+          +-----+----+        |
                 | F_PORT   |          | FL_PORT  +--------+
                 |          |          |          |
       ==========+==========+==========+==========+==============
                 |  FC      |          | FC       |
                 |  Switch  |          | Switch   |
                 +----------+          +----------+
                 |Inter-    |          |Inter-    |
                 |Switch    |          |Switch    |
                 |Interface |          |Interface |
                 +-----+----+          +-----+----+
                       |                     |
                       |                     |
                 +-----+----+----------+-----+----+
                 |Inter-    |          |Inter-    |
                 |Switch    |          |Switch    |
                 |Interface |          |Interface |
                 +----------+          +----------+
                 |            FC Switch           |
                 |                                |
                 +--------------------------------+
                        Figure 4 -- Mixed Fibre Channel Fabric
     
         As noted previously, the protocol for communications between peer
         N_PORTs is independent of the fabric topology, N_PORT variant and
         type of fabric port to which an N_PORT is attached.
     
     4.3      Fibre Channel Layers and Link Services
     
         Fibre channel consists of the following layers:
     
         FC-0 -- The interface to the physical media,
     
         FC-1 û- The encoding and decoding of data and out-of-band physical
         link control information for transmission over the physical media,
     
         FC-2 û- The transfer of frames, sequences and Exchanges comprising
         protocol information units.
     
         FC-3 û- Common Services,
     
         FC-4 û- Application protocols, such as FCP, the Fibre Channel SCSI
         protocol.
     
     
     
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         In addition to the layers defined above, Fibre Channel defines a
         set of auxiliary operations, some of which are implemented within
         the transport layer fabric, called link services. These are
         required to manage the Fibre Channel environment, establish
         communications with other devices, retrieve error information,
         perform error recovery and other similar services. Some link
         services are executed by the N_PORT. Others are implemented
         internally within the fabric.  These internal services are
         described in the next section.
     
     4.3.1   Fabric-Supplied Link Services
     
         Servers internal to a switched fabric handle certain classes of
         Link Service requests and service-specific commands.  The servers
         appear as N_PORTs located at the 'well-known' N_PORT fabric
         addresses specified in [FC-FS]. Service requests use the standard
         Fibre Channel mechanisms for N_PORT-to-N_PORT communications.
     
         All switched fabrics must provide the following services:
     
            Fabric F_PORT server û Services an N_PORT request to access the
            fabric for communications.
     
            Fabric Controller -- Provides state change information to inform
            other FC devices when an N_PORT exits or enters the fabric (see
            section 4.5).
     
            Directory/Name Server û Allows N_PORTs to register information
            in a database, retrieve information about other N_PORTs and
            discover other devices as described in section 4.5.
     
         A switched fabric may also implement the following optional
         services:
     
            Broadcast Address/Server û- Transmits single-frame, class 3
            sequences to all N_PORTs.
     
            Time Server û- Intended for the management of fabric-wide
            expiration timers or elapsed time values and is not intended for
            precise time synchronization.
     
            Management Server û Collects and reports management information,
            such as link usage, error statistics, link quality and similar
            items.
     
            Quality of Service Facilitator û Performs fabric-wide bandwidth
            and latency management.
     
     4.4      Fibre Channel Nodes
     
         A Fibre Channel node has one or more fabric-attached N_PORTs. The
         node and its N_PORTs have the following associated identifiers:
     
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        a) A world-wide unique identifier for the node,
     
        b) A world-wide unique identifier for each N_PORT associated with
           the nodee,
     
        c) For each N_PORT attached to a fabric, a 24-bit fabric-unique
           address having the properties defined in section 4.7.1.  The
           fabric address is the address to which frames are sent.
     
         Each world-wide unique identifier is a 64-bit binary quantity
         having the format defined in [FC-FS].
     
     4.5      Fibre Channel Device Discovery
     
         In a switched or mixed fabric, fibre channel devices and changes in
         the device configuration may be discovered by means of services
         provided by the Fibre Channel Name Server and Fabric Controller.
     
         The Name Server provides registration and query services that allow
         a Fibre Channel device to register its presence on the fabric and
         discover the existence of other devices.  For example, one type of
         query obtains the fabric address of an N_PORT from its 64-bit
         world-wide unique name. The full set of supported Fibre Channel
         Name Server queries is specified in [FC-GS3].
     
         The Fabric Controller complements the static discovery capabilities
         provided by the Name Server through a service that dynamically
         alerts a Fibre Channel device whenever an N_PORT is added or
         removed from the configuration. A Fibre Channel device receives
         these notifications by subscribing to the service as specified in
         [FC-FS].
     
     4.6      Fibre Channel Information Elements
     
         The fundamental element of information in Fibre Channel is the
         frame.  A frame consists of a fixed header and up to 2112 bytes of
         payload having the structure described in section 4.7. The maximum
         frame size that may be transmitted between a pair of Fibre Channel
         devices is negotiable up to the payload limit, based on the size of
         the frame buffers in each Fibre Channel device and the path MTU
         supported by the fabric.
     
         Operations involving the transfer of information between N_PORT
         pairs are performed through 'Exchanges'.  In an Exchange,
         information is transferred in one or more ordered series of frames
         referred to as Sequences.
     
         Within this framework, an upper layer protocol is defined in terms
         of transactions carried by Exchanges. Each transaction, in turn,
         consists of protocol information units, each of which is carried by
         an individual Sequence within an Exchange.
     
     
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     4.7      Fibre Channel Frame Format
     
         A Fibre Channel frame consists of a header, payload and 32-bit CRC
         bracketed by SOF and EOF delimiters. The header contains the
         control information necessary to route frames between N_PORTs and
         manage Exchanges and Sequences. The following diagram gives a
         highly simplified view of the frame.
     
                     +-----------------------------+
                     |   Start-of-frame Delimiter  |
                     +-----+-----------------------+<----+
                     |     | Destination N_PORT    |     |
                     |     | Fabric Address (D_ID) |     |
                     |     |  (24-bits)            |     |
                     +-----+-----------------------+   24-byte
                     |     | Source N_PORT         |   Frame
                     |     | Fabric Address (S_ID) |   Header
                     |     | (24 bits)             |     |
                     +-----+-----------------------+     |
                     |    Control information for  |     |
                     |    frame type, Exchange     |     |
                     |    management, IU           |     |
                     |    segmentation and         |     |
                     |    re-assembly              |     |
                     +-----------------------------+<----+
                     |                             |
                     |        Frame payload        |
                     |       (0 û 2112 bytes)      |
                     |                             |
                     |                             |
                     |                             |
                     +-----------------------------+
                     |            CRC              |
                     +-----------------------------+
                     |    End-of-Frame Delimiter   |
                     +-----------------------------+
                        Figure 6 -- Fibre Channel Frame Format
     
         The source and destination N_PORT fabric addresses embedded in the
         S_ID and D_ID fields represent the physical MAC addresses of
         originating and receiving N_PORTs.
     
     4.7.1   N_PORT Address Model
     
         N_PORT fabric addresses are 24-bit values having the following
         format defined by the Fibre Channel specification [FC-FS]:
     
     
     
     
     
     
     
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               Bit   23       16 15         8 7        0
                    +-----------+------------+----------+
                    | Domain ID | Area ID    |  Port ID |
                    +-----------+------------+----------+
                     Figure 7 -- Fibre Channel Address Format
     
         A Fibre Channel device acquires an address when it logs into the
         fabric. Such addresses are volatile and subject to change based on
         modifications in the fabric configuration.
     
         In a Fibre Channel fabric, each switch element has a unique Domain
         I/D assigned by the principal switch. The value of the Domain I/D
         ranges from 1 to 239 (0xEF). Each switch element, in turn,
         administers a block of addresses divided into area and port IDs. An
         N_PORT connected to a F_PORT receives a unique fabric address
         consisting of the switchÆs Domain I/D concatenated with switch-
         assigned area and port I/Ds.
     
         A loop-attached NL_PORT (see Figure 4) obtains the Port ID
         component of its address during the loop initialization process
         described in [FC-AL2]. The area and domain I/Ds are supplied by the
         fabric when the FLOGI is executed.
     
     4.8      Fibre Channel Transport Services
     
         N_PORTs communicate by means of the following classes of service
         specified in the Fibre Channel standard ([FC-FS]):
     
         Class 1 û A dedicated physical circuit connecting two N_PORTs.
     
         Class 2 û A frame-multiplexed connection with end-to-end flow
         control and delivery confirmation.
     
         Class 3 û A frame-multiplexed connection with no provisions for
         end-to-end flow control or delivery confirmation.
     
         Class 4 - A connection-oriented service, based on a virtual circuit
         model, providing confirmed delivery with bandwidth and latency
         guarantees.
     
         Class 6 - A reliable multicast service derived from class 1.
     
         Class 2 and class 3 are the predominant services supported by
         deployed Fibre Channel storage and clustering systems.
     
         Class 3 service is similar to UDP or IP datagram service. Fibre
         channel storage devices using this class of service rely on the ULP
         implementation to detect and recover from transient device and
         transport errors.
     
         For class 2 and class 3 service, the Fibre Channel fabric is not
         required to provide in-order delivery of frames unless explicitly
     
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         requested by the frame originator (and supported by the fabric). If
         ordered delivery is not in effect, it is the responsibility of the
         frame recipient to reconstruct the order in which frames were sent
         based on information in the frame header.
     
     4.9      Login Processes
     
         The Login processes are the means whereby an N_PORT establishes the
         operating environment necessary to communicate with the fabric,
         other N_PORTs and ULP implementations accessed via the N_PORT.
         Three login operations are supported:
     
         a)  Fabric Login (FLOGI) -- An operation whereby the N_PORT
             registers its presence on the fabric, obtains fabric
             parameters, such as classes of service supported, and receives
             its N_PORT address,
     
         b)  Port Login (PLOGI) -- An operation by which an N_PORT
             establishes communication with another N_PORT.
     
         c)  Process Login (PRLOGI) -- An operation which establishes the
             process-to-process communications associated with a specific
             FC-4 ULP -- such as FCP-2, the Fibre Channel SCSI mapping.
     
         Since N_PORT addresses are volatile, an N_PORT originating a login
         (PLOGI) operation executes a Name Server query to discover the
         Fibre Channel address of the remote device.  A common query type
         involves use of the world-wide unique name of an N_PORT to obtain
         the 24-bit N_PORT Fibre Channel address to which the PLOGI request
         is sent.
     
     5.       The iFCP Network Model
     
         The iFCP protocol enables the implementation of Fibre Channel mixed
         or switched fabric functionality on an IP network in which IP
         components and technology replace the Fibre Channel switching and
         routing infrastructure described in section 4.2.
     
         The example of Figure 8  shows a Fibre Channel fabric with attached
         devices. These access the fabric through an N_PORT interface
         connected to a Fabric Port whose behavior is specified in [FC-FS].
         In this case, the N_PORT and Fabric Port represent any of the
         variants described in section 4.2.
     
         Within the Fibre Channel device domain, fabric-addressable entities
         consist of other N_PORTs and devices internal to the fabric that
         perform the fabric services defined in [FC-GS3].
     
     
     
     
     
     
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                     Fibre Channel Network
                 +--------+        +--------+
                 |  FC    |        |  FC    |
                 | Device |        | Device |
                 |........|        |........| Fibre Channel
                 | N_PORT |<......>| N_PORT | Device Domain
                 +---+----+        +----+---+       ^
                     |                  |           |
                 +---+----+        +----+---+       |
                 | Fabric |        | Fabric |       |
                 | Port   |        | Port   |       |
       ==========+========+========+========+==============
                 |         Fabric &         |       |
                 |     Fabric Services      |       v
                 |                          | Fibre Channel
                 +--------------------------+ Fabric Domain
                          Figure 8 -- A Fibre Channel Fabric
     
     
     
           Gateway Region                   Gateway Region
      +--------+  +--------+           +--------+  +--------+
      |   FC   |  |  FC    |           |   FC   |  |   FC   |
      | Device |  | Device | Fibre     | Device |  | Device |  Fibre
      |........|  |........| Channel   |........|  |........|  Channel
      | N_PORT |  | N_PORT |<.........>| N_PORT |  | N_PORT |  Device
      +---+----+  +---+----+ Traffic   +----+---+  +----+---+  Domain
          |           |                     |           |         ^
      +---+----+  +---+----+           +----+---+  +----+---+     |
      | Fabric |  | Fabric |           | Fabric |  | Fabric |     |
      | Port   |  | Port   |           | Port   |  | Port   |     |
     =+========+==+========+===========+========+==+========+==========
      |    iFCP Layer      |<--------->|     iFCP Layer     |     |
      |....................|     ^     |....................|     |
      |     iFCP Portal    |     |     |     iFCP Portal    |     v
      +--------+-----------+     |     +----------+---------+    IP
           iFCP|Gateway      Control          iFCP|Gateway      Network
               |              Data                |
               |                                  |
               |                                  |
               |<------Encapsulated Frames------->|
               |      +------------------+        |
               |      |                  |        |
               +------+    IP Network    +--------+
                      |                  |
                      +------------------+
                             Figure 10 -- An iFCP Fabric
     
     
         Figure 10 shows an implementation of an equivalent iFCP fabric
         consisting of two gateways, each in control of a single gateway
         region.
     
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         Each iFCP gateway contains two standards-compliant fibre channel
         ports and an iFCP Portal for attachment to the IP network. Fibre
         Channel devices in the region are those directly connected to the
         iFCP fabric through the gateway fabric ports.
     
         Looking into the fabric port, the gateway appears as a Fibre
         Channel switch element. At this interface, remote N_PORTs are
         presented as fabric-attached devices. Conversely, on the IP network
         side, the gateway presents each locally connected N_PORT as a
         logical Fibre Channel device.
     
     5.1      Fibre Channel Fabric Topologies Supported by iFCP
     
         A property of this architecture, not shown in the examples, is that
         the Fibre Channel fabric configuration and topology within the
         gateway region are invisible to the IP network and other gateway
         regions.  That is, the topology in the gateway region, whether it
         is loop- or switch-based, is hidden from the IP network and from
         other gateway regions. As a result, support for specific FC fabric
         topologies becomes a gateway implementation issue.  In such cases,
         the gateway may implement any standards-compliant Fibre Channel
         interface by incorporating the functionality required to present
         locally attached N_PORTs as logical iFCP devices.
     
     5.2      iFCP Transport Services
     
         N_PORT to N_PORT communications that traverse a TCP/IP network
         require the intervention of the iFCP layer within the gateway. This
         consists of the following operations:
     
         a) Execution of the frame addressing and mapping functions
            described in section 5.5.
     
         b) Execution of fabric-supplied link services addressed to one of
            the well-known Fibre Channel N_PORT addresses.
     
         c) Encapsulation of Fibre Channel frames for injection into the
            TCP/IP network and de-encapsulation of Fibre Channel frames
            received from the TCP/IP network.
     
         d) Establishment of an N_PORT login session in response to a PLOGI
            directed to a remote device.
     
         The following sections discuss the frame addressing mechanism and
         the way in which it is used to achieve communications transparency
         between N_PORTs.
     
     5.2.1   Fibre Channel Transport Services Supported by iFCP
     
         An iFCP fabric supports Class 2 and Class 3 Fibre Channel transport
         services as specified in [FC-FS].  An iFCP fabric does not support
         class 4, class 6 or the Class 1 (dedicated connection) service. An
     
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         N_PORT discovers the classes of transport services supported by the
         fabric during fabric login.
     
     5.3      iFCP Device Discovery and Configuration Management
     
         An iFCP implementation performs device discovery and iFCP fabric
         management. through the Internet Storage Name Service defined in
         [ISNS]. Access to an iSNS server is required to perform the
         following functions::
     
         a) Emulation of the services provided by the Fibre Channel name
            server described in section 4.3.1, including a mechanism for
            asynchronously notifying an N_PORT of changes in the iFCP fabric
            configuration,
     
         b) Aggregation of gateways into iFCP fabrics for interoperation,
     
         c) Segmentation of an iFCP fabric into  Fibre Channel zones through
            the definition and management of device discovery scopes,
            referred to as 'discovery domains',
     
         d) Storage and distribution of security policies as described in
            section 11.2.9.
     
         e) Implementation of the Fibre Channel broadcast mechanism.
     
     5.4      iFCP Fabric Properties
     
         A collection of iFCP gateways may be configured for interoperation
         as either a bounded or unbounded iFCP fabric.
     
         Gateways in a bounded iFCP fabric operate in address transparent
         mode as described in section 5.5.1. In this mode, the scope of a
         Fibre Channel N_PORT address is fabric-wide and is derived from
         domain I/Ds issued by the iSNS server from a common pool.  As
         discussed below, the maximum number of domain I/Ds allowed by Fibre
         Channel limits the configuration of a bounded iFCP fabric.
     
         Gateways in an unbounded iFCP fabric operate in address translation
         mode as described in section 5.5.2.  In this mode, the scope of an
         N_PORT address is local to a gateway region. For Fibre Channel
         traffic between regions, the translation of frame-embedded N_PORT
         addresses is performed by the gateway.  As discussed below, an
         unbounded iFCP fabric may have any number of switch elements and
         gateways.
     
         All iFCP gateways MUST unbounded iFCP fabrics.  Support for bounded
         iFCP fabrics is OPTIONAL.
     
         The decision to support bounded iFCP fabrics in a gateway
         implementation depends on the address transparency, configuration
         scalability, and fault tolerance considerations discussed below.
     
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     5.4.1   Address Transparency
     
         Although an iFCP gateways in an unbounded fabric will convert
         N_PORT addresses in the frame header and payload of standard link
         service messages, the gateway cannot convert such addresses in the
         payload of vendor- or user-specific Fibre Channel frame traffic.
     
         Consequently, while both bounded and unbounded iFCP fabrics support
         the standards-compliant FC-4 protocols and link services used by
         mainstream Fibre Channel applications, a bounded iFCP fabric may
         also support vendor- or user-specific protocol and link service
         implementations that carry N_PORT I/Ds in the frame payload.
     
     5.4.2   Configuration Scalability
     
         The scalability limits of a bounded fabric configuration are a
         consequence of the Fibre Channel address allocation policy
         previously discussed. As noted, a bounded iFCP fabric using this
         address allocation scheme is limited to a combined total of 238
         gateways and Fibre Channel switch elements. As the system expands,
         the network may grow to include many switch elements and gateways,
         each of which controls a small number of devices.  In this case,
         the limitation in switch and gateway count may become a barrier to
         extending and fully integrating the storage network.
     
         Since N_PORT Fibre Channel addresses in an unbounded iFCP fabric
         are not fabric-wide, there are no architectural limits on the
         number of iFCP gateways, Fibre Channel devices and switch elements
         that may be internetworked. In exchange for improved scalability,
         however, implementations must consider the incremental overhead of
         address conversion as well as the address transparency issues
         discussed below.
     
     5.4.3   Fault Tolerance
     
         In an unbounded iFCP fabric, limiting the scope of an N_PORT
         address to a gateway region reduces the likelihood that
         reassignment of domain I/Ds caused by a disruption in one gateway
         region will cascade to others.
     
         In addition, a bounded iFCP fabric has an increased dependency on
         the iSNS server, which must act as the central address assignment
         authority. If connectivity with the server is lost, new DOMAIN_ID
         values cannot be automatically allocated as gateways and Fibre
         Channel switch elements are added to the logical fabric.
     
         Finally, adding a gateway to a bounded fabric is more likely to
         disrupt the operation of all devices in the gateway region along
         with those already in the fabric as new, fabric-wide N_PORT
         addresses are assigned. Furthermore, before the new gateway can be
         merged, its iSNS server must be slaved to the iSNS server in the
         bounded fabric to centralize the issuance of domain I/Ds.
     
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         In contrast, adding a new gateway to an unbounded iFCP fabric can
         be done non-disruptively and requires only that new gateway's iSNS
         server import client attributes from the other iSNS servers.
     
     5.5      The iFCP N_PORT Address Model
     
         This section discusses iFCP extensions to the Fibre Channel
         addressing model of section 4.7.1, which are required for the
         transparent routing of frames between locally and remotely attached
         N_PORTs.
     
         In the iFCP protocol, an N_PORT is represented by the following
         addresses:
     
         a) A 24-bit N_PORT I/D.  Depending on the gateway addressing mode,
            the scope is either local to a region or fabric-wide. In either
            mode, communications between N_PORTs in the same gateway region
            use the N_PORT I/D.
     
         b) A 24-bit N_PORT alias.  An address assigned by a gateway
            operating in address translation mode to identify a remotely
            attached N_PORT. Frame traffic is directed to a remotely
            attached N_PORT by means of the N_PORT alias.
     
         c) An N_PORT network address. A tuple consisting of the gateway IP
            address, TCP port number and N_PORT I/D.  The N_PORT network
            address identifies the source and destination N_PORTs for Fibre
            Channel traffic on the IP network.
     
     
     
         To provide transparent communications between remote and local
         N_PORTs, a gateway in address translation mode maintains an
         association between the remote N_PORT alias and the remote device's
         N_PORT network address. To establish this association the iFCP
         gateway assigns and manages Fibre Channel N_PORT fabric addresses
         as described in the following paragraphs.
     
         In an iFCP fabric, the iFCP gateway performs the address assignment
         and frame routing functions of an FC switch element. Unlike an FC
         switch, however, an iFCP gateway must also direct frames to
         external devices attached to remote gateways on the IP network.
     
         In order to be transparent to FC devices, the gateway must deliver
         such frames using only the 24-bit destination address in the frame
         header. By exploiting its control of address allocation and access
         to frame traffic entering or leaving the gateway region, it is able
         to achieve the necessary transparency.
     
         N_PORT addresses within a gateway region may be allocated in one of
         two ways:
     
     
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         a) Address Translation Mode û A mode of N_PORT address assignment
            in which the scope of an N_PORT address is unique to the gateway
            region. The address of a remote device is represented in that
            gateway region by its gateway assigned N_PORT alias.
     
         b) Address Transparent Mode û A mode of N_PORT address assignment
            in which the scope of an N_PORT address is unique across the set
            of gateway regions comprising a bounded iFCP fabric.
     
         In address transparent mode, gateways within a bounded fabric
         cooperate in the assignment of addresses to locally attached
         N_PORTs. Each gateway in control of a region is responsible for
         obtaining and distributing unique domain I/Ds from the address
         assignment authority as described in section 5.5.1.1. Consequently,
         within the scope of a bounded fabric, the address of each N_PORT is
         unique.  For that reason, gateway-assigned aliases are not required
         to represent remote N_PORTs.
     
         All iFCP implementations MUST support operation in address
         translation mode. Implementation of address transparent mode is
         OPTIONAL but MUST be provided if bounded iFCP fabric configurations
         are to be supported.
     
         The mode of gateway operation is settable in an implementation-
         specific manner.  The implementation MUST NOT allow the mode to be
         changed after the gateway begins processing fibre channel frame
         traffic.
     
     5.5.1   Operation in Address Transparent Mode
     
         The following considerations and requirements apply to this mode of
         operation:
     
         a) iFCP gateways in address transparent mode will not interoperate
            with iFCP gateways that are not in transparent mode.
     
         b) When interoperating with locally attached Fibre Channel switch
            elements, each iFCP gateway MUST assume control of DOMAIN_ID
            assignments in accordance with the appropriate Fibre Channel
            standard or vendor-specific protocol specification.  As
            described in section 5.5.1.1, DOMAIN_ID values assigned to FC
            switches in attached fabrics must be issued by the iSNS server.
     
         c) When operating in address transparent Mode, no Fibre Channel
            address translation SHALL take place.
     
         The process for establishing the TCP/IP context associated with an
         N_PORT login session in this mode is similar to that specified for
         address translation mode (section 5.5.2).
     
     5.5.1.1  Transparent Mode Domain I/D Management
     
     
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         As described above, each gateway and Fibre Channel switch in a
         bounded iFCP fabric MUST have a unique domain I/D.  In a gateway
         region containing Fibre Channel switch elements, each element
         obtains a domain I/D by querying the principal switch as described
         in  \* MERGEFORMAT [FC-SW2] -- in this case the iFCP gateway
         itself.  The gateway in turn may obtain domain I/Ds on demand from
         the iSNS name server acting as the central address allocation
         authority . In effect, the iSNS server assumes the role of master
         switch for the bounded fabric. In that case, the iSNS database
         contains:
     
         a) The definition for one or more bounded iFCP fabrics,
     
         b) For each bounded fabric, a world-wide unique name identifying
            each gateway in the fabric. A gateway in address transparent
            mode MUST reside in one and only one bounded fabric.
     
         In its role as principle switch, an iFCP gateway in address
         transparent mode SHALL obtain domain I/Ds for use in the gateway
         region by issuing the appropriate iSNS query using its world-wide
         name.
     
     5.5.1.2  Incompatibility with Address Translation Mode
     
         iFCP gateways in address transparent mode SHALL NOT  originate or
         accept frames that do not have the TRN bit set to one in the iFCP
         flags field of the encapsulation header (see section 6.4.1).  The
         iFCP gateway SHALL immediately terminate all N_PORT login sessions
         with the iFCP gateway from which it receives such frames.
     
     5.5.2   Operation in Address Translation Mode
     
         This section describes the process for managing the assignment of
         addresses within a gateway region, including the modification of FC
         frame addresses embedded in the frame header for frames sent and
         received from remotely attached N_PORTs.
     
         As described above, the scope of N_PORT addresses in this mode is
         local to the gateway region.  A principal switch within the gateway
         region, possibly the iFCP gateway itself, oversees the assignment
         of such addresses in accordance with the rules specified in [FC-FS]
         and [FC-FLA].
     
         The assignment of N_PORT addresses to locally attached devices is
         controlled by the switch element to which the device is connected.
     
         When a remotely attached N_PORT is accessed, the gateway assigns a
         locally significant N_PORT alias.  This alias is used in place of
         the N_PORT I/D assigned by the remote gateway.  To perform address
         conversion and enable the appropriate routing, the gateway
         maintains a table mapping N_PORT aliases to the appropriate TCP/IP
         connection context and N_PORT ID of all remotely accessed  N_PORTs.
     
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         The means by which translation table entries are created and
         updated are described in section 5.5.3.
     
     5.5.3   Address Translation
     
         This section describes how address translation SHALL be performed
         by a gateway operating in address translation mode. For descriptive
         purposes, the gateway is assumed to maintain a table containing one
         entry for each remotely attached N_PORT as shown in Figure 11.
     
                          +--------------------------------+
                          |  Network Address of Remote     |
                          |  Gateway                       |
                          +--------------------------------+
                          |  N_PORT I/D of Remote N_PORT   |
                          +--------------------------------+
                          |  N_PORT Alias                  |
                          +--------------------------------+
                          |  N_PORT World-wide Unique Name |
                          +--------------------------------+
            Figure 11 -- Address Translation Table Entry for Remote N_PORT
     
         Each entry contains the following information:
     
             Network Address of Remote Gateway -- IP address and TCP port
             number of the gateway to which the remote device is attached.
     
             N_PORT I/D --  N_PORT address assigned to the remote device by
             the remote iFCP gateway.
     
             N_PORT Alias -- N_PORT address assigned to the remote device by
             the 'local' iFCP gateway.
     
             N_PORT World-wide Unique Name -- 64-bit N_PORT world wide name
             as specified in [FC-FS].
     
         An iFCP gateway SHALL have one and only one entry for each remotely
         attached N_PORT it accesses. If an entry does not exist, one SHALL
         be built in response to one of the following transactions:
     
         a) A Fibre Channel Name Server request issued by a locally-attached
            N_PORTs as part of Fibre Channel device discovery (see section
            4.5) or,
     
         b) An N_PORT PLOGI request received from the remote Fibre Channel
            device (see section 8.3.1.7).
     
         An iFCP gateway SHALL convert each Fibre Channel Name Server
         request to an iSNS server query. Information returned in response
         to the query includes the IP address, TCP port number, N_PORT ID
         and N_PORT world wide unique name for each remote device included
         in the query response. After building the table entry containing
     
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         this information for a specific N_PORT, the iFCP layer SHALL create
         and add the 24-bit N_PORT alias.  This alias SHALL then be returned
         to the local N_PORT as the Fibre Channel address of the remotely
         attached device.
     
         If a PLOGI is received from a remotely attached device and no
         translation table entry exists for that device, an entry SHALL be
         created using the following information:
     
         a) The world-wide unique name of the N_PORT contained in the PLOGI
            payload,
     
         b) The IP address and TCP port number of the remote device obtained
            from the TCP connection context,
     
         c) The N_PORT I/D obtained from the S_ID field in the PLOGI frame
            header.
     
         The N_PORT alias SHALL then be assigned and used in address
         translation as specified in section 5.5.2.
     
     5.5.3.1.1  Updating an Address Translation
     
     
     
         An address translation may become stale as the result of any event
         that invalidates or triggers a change in the fabric-assigned N_PORT
         network address of the remote device, such as a fabric
         reconfiguration or the device's removal or replacement.
     
         A collateral effect of such an event is that a Fibre Channel device
         that has been added or whose N_PORT I/D has changed will have no
         N_PORT login sessions. Consequently, frames directed to an N_PORT
         as the result of a stale translation table entry will be rejected
         or discarded by the receiving Fibre Channel device.
     
         Once the originating N_PORT learns of the reconfiguration, usually
         through the name serverstate change notification mechanism, the
         normal name server lookup and PLOGI mechanisms needed to
         reestablish the N_PORT login session will automatically purge such
         stale translations from the gateway.
     
     5.5.3.2  Frame Address Translation
     
         For outbound frames, the gateway-resident address translation SHALL
         be referenced to map the Destination N_PORT alias to the TCP
         connection context and N_PORT ID assigned by the remote gateway.
         The translation process for outbound frames is shown below.
     
     
     
     
     
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              Raw Fibre Channel Frame
     +--------+-----------------------------------+    +--------------+
     |        |  Destination N_PORT Alias         |--->| Lookup TCP   |
     +--------+-----------------------------------+    | connection   |
     |        |  Source N_PORT ID                 |    | context      |
     +--------------------------------------------+    | and N_PORT ID|
     |                                            |    +------+-------+
     |        Control information,                |           | TCP
     |        Payload and FC CRC                  |           | conn
     |                                            |           | context
     +--------------------------------------------+           | &
                                                              | N_PORT
                                                              | ID
                                                              |
     After Address Translation and Encapsulation              |
     +--------------------------------------------+           |
     |          FC Encapsulation Header           |           |
     +--------------------------------------------+           |
     |            SOF Delimiter Word              |           |
     +============================================+           |
     |        |  Destination N_PORT ID            |<----------+
     +--------+-----------------------------------+
     |        |  Source N_PORT ID                 |
     +--------+-----------------------------------+
     |                                            |
     |        Control information, Payload        |
     |        and FC CRC                          |
     +============================================+
     |         EOF Delimiter Word                 |
     +--------------------------------------------+
         Figure 13 -- Outbound Frame Address Translation
     
         For inbound frames, a translation SHALL be performed to regenerate
         the N_PORT alias from the TCP connection context and N_PORT ID
         contained in Source N_PORT I/D field of theencapsulated FC frame.
         The translation process for inbound frames is shown below.
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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          Network Format of Inbound Frame
     +--------------------------------------------+     TCP
     |          FC Encapsulation Header           |     Connection
     +--------------------------------------------+     Context
     |            SOF Delimiter Word              |         |
     +============================================+         V
     |        |  Destination N_PORT ID            |     +---+----+
     +--------+-----------------------------------+     | Lookup |
     |        |  Source N_PORT ID                 |---->| Source |
     +--------+-----------------------------------+     | N_PORT |
     |                                            |     | Alias  |
     |        Control information, Payload        |     +----+---+
     |        and FC CRC                          |          | Source
     +============================================+          | N_PORT
     |         EOF Delimiter Word                 |          | Alias
     +--------------------------------------------+          |
                                                             |
                                                             |
     Frame after Address Translation and De-encapsulation    |
     +--------+-----------------------------------+          |
     |        |  Destination N_PORT ID            |          |
     +--------+-----------------------------------+          |
     |        |  Source N_PORT Alias              |<---------+
     +--------+-----------------------------------+
     |                                            |
     |        Control information, Payload,       |
     |        and FC CRC                          |
     +--------------------------------------------+
         Figure 14 -- Inbound Frame Address Translation
     
         In both cases, the gateway MUST recalculate the FC CRC after
         altering the frame contents.
     
     5.5.3.3  Incompatibility with Address Transparent Mode
     
         iFCP gateways in address translation mode SHALL NOT originate or
         accept frames that have the TRN bit set to one in the iFCP flags
         field of the encapsulation header.  The iFCP gateway SHALL
         immediately abort all iFCP sessions with the iFCP gateway from
         which it receives such frames as described in section 6.2.3.2.
     
     6.       iFCP Protocol
     
     6.1      Overview
     
     6.1.1   iFCP Transport Services
     
         The main function of the iFCP protocol layer is to transport Fibre
         Channel frame images between locally and remotely attached N_PORTs.
     
         When transporting frames to a remote N_PORT, the iFCP layer
         encapsulates and routes the Fibre Channel frames comprising each
     
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         Fibre Channel Information Unit via a predetermined TCP connection
         for transport across the IP network.
     
         When receiving Fibre Channel frame images from the IP network, the
         iFCP layer de-encapsulates  and delivers each frame to the
         appropriate N_PORT.
     
         The iFCP layer processes the following types of traffic:
     
         a)  FC-4 frame images associated with a Fibre Channel application
             protocol.
     
         b)  FC-2 frames comprising Fibre Channel link service requests and
             responses
     
         c)  Fibre Channel broadcast frames
     
         d)  iFCP control messages required to setup, manage or terminate an
             iFCP session.
     
         For FC-4 N_PORT traffic and most FC-2 messages the iFCP layer never
         interprets the contents of the frame payload.
     
         iFCP does interpret and process iFCP control messages and certain
         link service messages as described in section 6.1.2
     
     6.1.2   iFCP Support for  Link Services
     
         iFCP must intervene in the processing of those Fibre Channel link
         service messages which contain N_PORT addresses in the message
         payload or require other special handling, such as an N_PORT login
         request (PLOGI).
     
         In the former case, an iFCP gateway operating in address
         translation mode MUSTsupplement the payload with additional
         information that enables the receiving gateway to convert such
         embedded N_PORT addresses to its frame of reference.
     
         For out-bound Fibre Channel frames comprising such a link service,
         the iFCP layer creates the supplemental information based on frame
         content, modifies the frame payload, then transmits the resulting
         Fibre Channel frame with supplemental data through the appropriate
         TCP connection.
     
         For incoming iFCP frames containing supplemented Fibre Channel link
         service frames, iFCP interprets the frame, including any
         supplemental information, modifies the frame content, and forwards
         the resulting frame to the destination N_PORT for further
         processing.
     
         Section 8.1 describes the processing of these link service messages
         in detail.
     
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     6.2      TCP Stream Transport of iFCP Frames
     
     6.2.1   iFCP Session Model
     
         An iFCP session consists of the pair of N_PORTs comprising the
         session endpoints joined by a single TCP/IP connection.
     
         An N_PORT is identified by its network address consisting of:
     
         a) The N_PORT I/D assigned by the gateway to which the N_PORT is
            locally attached and
     
         b) The iFCP Portal address, consisting of its IP address and TCP
            port number.
     
         Since only one iFCP session may exist between a pair of N_PORTs,
         the iFCP session is uniquely identified by the network addresses of
         the session end points.
     
         TCP connections that may be used for iFCP sessions between pairs of
         iFCP portals are either "bound" or "unbound".  An unbound
         connection is a TCP connection that is not actively supporting an
         iFCP session.  A gateway implementation MAY establish a pool of
         unbound connections to reduce the session setup time.  Such pre-
         existing TCP connections between iFCP Portals remain unbound and
         uncommitted until allocated to an iFCP session through a CBIND
         message (see section 7.1).
     
         When the iFCP layer detects a Port Login (PLOGI) message creating
         an iFCP session between a pair of N_PORTs, it may select an
         existing unbound TCP connection or establish a new TCP connection,
         and send the CBIND message down that TCP connection.  This
         allocates the TCP connection to that PLOGI login session.
     
     6.2.2   iFCP Session Management
     
         This section describes the protocols for establishing and
         terminating an N_PORT login session.
     
     6.2.2.1  Creating an iFCP Session
     
         An iFCP session may be in one of the following states:
     
         a) OPEN  --  The session state in which Fibre Channel frame images
            may be sent and received.
     
         b) OPEN PENDING -- The session state after a gateway has issued a
            CBIND request but no response has yet been received.  No Fibre
            Channel frames may be sent.
     
     
     
     
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         The gateway SHALL initiate the creation of an iFCP session in
         response to a PLOGI ELS directed to a remote N_PORT from a locally
         attached N_PORT as described in the following steps.
     
         a) If no iFCP session exists, allocate a TCP connection to the
            gateway to which the remote N_PORT is locally attached.  An
            implementation may use an existing connection in the Unbound
            state or a new connection may be created and placed in the
            Unbound state. The network address of the remote gateway is
            obtained from the address translation table created as described
            in section 5.5.3
     
         b) If a connection cannot be allocated or created due to limited
            resources, the gateway SHALL terminate the PLOGI with an LS_RJT
            response. The Reason Code field in the LS_RJT message shall be
            set to 0x09 (Unable to Perform Command Request) and the Reason
            Explanation SHALL be set to 0x29 (Insufficient Resources to
            Support Login).
     
         c) If an iFCP session in the OPEN state already exists to the
            remote N_PORT, the gateway SHALL forward the PLOGI ELS using the
            existing session.
     
         d) If the iFCP session does not exist, the gateway SHALL issue a
            CBIND session control message (see section 7.1) and place the
            session in the OPEN PENDING state.
     
         e) If a CBIND response is returned with one of the following
            statuses, the PLOGI shall be terminated with an LS_RJT message.
            Depending on the CBIND failure status, the Reason Code and
            Reason Explanation SHALL be set to the following values
            specified in [FC-FS].
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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             CBIND Failure     LS_RJT Reason     LS_RJT Reason Code
             Status            Code              Explanation
             -------------     -------------     ------------------
     
             Unspecified       Unable to Perform No additional
             Reason (16)       Command Request   explanation (0x00)
                               (0x09)
     
             No Such Device    Unable to Perform Invalid N_PORT Name
             (17)              Command Request   (0x0D).
                               (0x09)
     
             Lack of           Unable to Perform Insufficient
             Resources (19)    Command Request   Resources to Support
                               (0x09).           Login (0x29).
     
             Incompatible      Unable to Perform No additional
             address           Command Request   Explanation (0x00)
             translation mode  (0x09)
             (20)
     
             Incorrect iFCP    Unable to Perform No additional
             protocol version  Command Request   explanation (0x00)
             number (21)       (0x09)
     
         f) A CBIND response with a CBIND STATUS of "N_PORT session already
            exists" indicates that the remote gateway has concurrently
            initiated a CBIND request to create an iFCP session between the
            same pair of N_PORTs. The receiving gateway SHALL terminate this
            attempt, return the connection to the Unbound state and prepare
            to respond to an incoming CBIND request as described below.
     
         The gateway receiving a CBIND request SHALL respond as follows:
     
         a) If the receiver has a duplicate iFCP session in the OPEN PENDING
            state, then the receiving gateway SHALL compare the Source Port
            Name in the incoming CBIND payload with the Destination Port
            Name.
     
         b) If the Source Port Name is greater, the receiver SHALL issue a
            CBIND response of "Success" and SHALL place the session in the
            OPEN state.
     
         c) If the Source Port Name is less, the receiver shall issue a
            CBIND RESPONSE of Failed - N_PORT session already exists. The
            state of the receiver-initiated iFCP session SHALL BE unchanged.
     
         d) If there is no duplicate iFCP session, the receiving gateway
            SHALL issue a CBIND response. If a status of Success is
            returned, the receiving gateway SHALL create the iFCP session
            and place it in the OPEN state.
     
     
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     6.2.2.2  Monitoring iFCP Connectivity
     
         During extended periods of inactivity, an iFCP session may be
         terminated due to a hardware failure within the gateway or through
         loss of TCP/IP connectivity.  The latter may occur when the session
         traverses a stateful intermediate device, such as a NAPT box or
         firewall, that detects and purges connections it believes to be
         idle.
     
         To test session liveness, expedite the detection of connectivity
         failures, and avoid spontaneous connection termination, an iFCP
         gateway may maintain a low level of session activity and monitor
         the session by requesting that the remote gateway periodically
         transmit the LTEST message described in section 7.3.  All iFCP
         gateways SHALL support liveness testing as described in this
         specification.
     
         A gateway requests the LTEST heartbeat by specifying a non-zero
         value for the LIVENESS TEST INTERVAL in the CBIND request or
         response message as described in section 7.1.  If both gateways
         wish to monitor liveness, each must set the LIVENESS TEST INTERVAL
         in the CBIND request or response.
     
         Upon receiving such a request, the gateway providing the
         connectivity probe SHALL transmit LTEST messages at the specified
         interval.  The first message SHALL be sent as soon as the iFCP
         session enters the OPEN state.  LTEST messages SHALL NOT be sent
         when the iFCP session is not in the OPEN state.
     
         An iFCP session SHALL be aborted as described in section 6.2.3.2
         if:
     
         a)  The contents of the LTEST message are incorrect
     
         b)  An LTEST message is not received within twice the specified
             interval or the iFCP session has been quiescent for longer than
             twice the specified interval.
     
             The gateway to receive the LTEST message SHALL measure the
             interval for the first expected LTEST message from when the
             session is placed in the OPEN state.  Thereafter, the interval
             SHALL be measured relative to the last LTEST message received.
     
         To maximize liveness test coverage, LTEST messages SHOULD flow
         through all the gateway components used to enter and retrieve Fibre
         Channel frames from the IP network.
     
         In addition to monitoring a session, information in the LTEST
         message encapsulation header may also be used to compute an
         estimate of network propagation delay as described in section
         9.2.1.  The propagation delay limit SHALL NOT be enforced however.
     
     
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     6.2.2.3  Use of TCP Features and Settings
     
         This section describes ground rules for the use of TCP features in
         an iFCP session.  The core TCP protocol is defined in [RFC793].
         TCP implementation requirements and guidelines are specified in
         [RFC1122].
     
         +-----------+------------+--------------+------------+------------+
         | Feature   | Applicable |  RFC         |  Peer-wise | Requirement|
         |           | RFCs       |  Status      |  agreement | Level      |
         |           |            |              |  required? |            |
         +===========+============+==============+============+============+
         | Keep Alive| [RFC1122]  |  None        |  No        | Should not |
         |           |(discussion)|              |            | use        |
         +-----------+------------+--------------+------------+------------+
         | Tiny      | [RFC896]   |  Standard    |  No        | Should not |
         | Segment   |            |              |            | use        |
         | Avoidance |            |              |            |            |
         | (Nagle)   |            |              |            |            |
         +-----------+------------+--------------+------------+------------+
         | Window    | [RFC1323]  |  Proposed    |  No        | Should use |
         | Scale     |            |  Standard    |            |            |
         +-----------+------------+--------------+------------+------------+
         | Wrapped   | [RFC1323]  |  Proposed    |  No        | Should use |
         | Sequence  |            |  Standard    |            |            |
         | Protection|            |              |            |            |
         | (PAWS)    |            |              |            |            |
         +-----------+------------+--------------+------------+------------+
                      Table 1 -- Usage of Optional TCP Features
     
         The following sections describe these options in greater detail.
     
     6.2.2.3.1  Keep Alive
     
         Keep Alive speeds the detection and cleanup of dysfunctional TCP
         connections by sending traffic when a connection would otherwise be
         idle.  The issues are discussed in [RFC1122].
     
         In order to test the device more comprehensively, Fibre Channel
         applications, such as storage, may implement an equivalent keep
         alive function at the FC4 level. For that reason and the
         considerations described in [RFC1122], keep alive at the transport
         layer should not be implemented.
     
     6.2.2.3.2  'Tiny' Segment Avoidance (Nagle)
     
         The Nagle algorithm described in [RFC896] is designed to avoid the
         overhead of small segments by delaying transmission in order to
         agglomerate transfer requests into a large segment.  In iFCP, such
         small transfers often contain I/O requests.  Hence, the
         transmission delay of the Nagle algorithm may decrease I/O
         throughput.  The Nagle algorithm should therefore not be used.
     
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     6.2.2.3.3  Window Scale
     
         Window scaling, as specified in [RFC1323], allows full utilization
         of links with large bandwidth - delay products and should be
         supported by an iFCP implementation.
     
     6.2.2.3.4  Wrapped Sequence Protection (PAWS)
     
         TCP segments are identified with 32-bit sequence numbers. In
         networks with large bandwidth - delay products, it is therefore
         possible for more than one TCP segment with the same sequence
         number to be in flight.  In iFCP, receipt of such a sequence out of
         order may cause out-of-order frame delivery or data corruption.
         Consequently, this feature SHOULD be supported as described in
         [RFC1323].
     
     
     
     6.2.3   Terminating an N_PORT Login Session
     
         An N_PORT login session SHALL be terminated or aborted in response
         to one of the following events:
     
         a)  An LS_RJT response is returned to the gateway that issued the
             PLOGI ELS.  The gateway SHALL forward the LS_RJT to the local
             N_PORT and complete the session as described in section
             6.2.3.1.
     
         b)  An ACC received from a remote device in response to a LOGO. The
             gateway SHALL forward the ACC to the local N_PORT and complete
             the session as described in section 6.2.3.1.
     
         c)  For an FC frame received from the IP network, a gateway detects
             a CRC error in the encapsulation header. The gateway shall
             abort the session as described in section 6.2.3.2.
     
         d)  The TCP connection associated with the login session fails for
             any reason.  The gateway detecting the failed connection shall
             abort the session as described in section 6.2.3.2.
     
         The disposition of the associated TCP connection is described in
         sections 6.2.3.1 and 6.2.3.2
     
     6.2.3.1  N_PORT Login Session Completion
     
         An N_PORT login session is completed in response to a rejected
         PLOGI request as described in section 6.2.3 or a successful LOGO
         ELS.
     
         The gateway receiving one of the above responses shall issue an
         Unbind session control ELS as described in section 7.2.
     
     
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         In response to the Unbind message, either gateway may choose to
         close the TCP connection or return it to a pool of unbound
         connections.
     
     6.2.3.2  Aborting an N_PORT Login Session
     
         An N_PORT login session SHALL be aborted if the TCP connection is
         spontaneously terminated or whenever one of the following occurs:
     
         a) An encapsulation error is detected as described in section
            6.4.3.
     
         b) The gateway receives an encapsulated frame from a gateway
            operating in an incompatible address translation mode as
            specified in section 5.5.3.3 or 5.5.1.2.
     
         In any event, the TCP connection SHOULD be terminated with a
         connection reset (RST).  If the local N_PORT has logged in to the
         remote N_PORT, the gateway SHALL send a LOGO to the local N_PORT.
     
     6.3      IANA Considerations
     
         The IANA-assigned port for iFCP traffic is port number 3420.
     
         An iFCP Portal may initiate a connection using any TCP port number
         consistent with its implementation of the TCP/IP stack, provided
         each port number is unique.  To prevent the receipt of stale data
         associated with a previous connection using a given port number,
         the provisions of [RFC1323], Appendix B SHOULD be observed.
     
     6.4      Encapsulation of Fibre Channel Frames
     
         This section describes the iFCP encapsulation of Fibre Channel
         frames.  The encapsulation is based on the common encapsulation
         format defined in [ENCAP].
     
         The format of an encapsulated frame is shown below:
     
                       +--------------------+
                       |       Header       |
                       +--------------------+-----+
                       |        SOF         |   f |
                       +--------------------+ F r |
                       |  FC frame content  | C a |
                       +--------------------+   m |
                       |        EOF         |   e |
                       +--------------------+-----+
                        Figure 15 -- Encapsulation Format
     
         The encapsulation consists of a 7-word header, an SOF delimiter
         word, the FC frame (including the Fibre Channel CRC), and an EOF
         delimiter word.  The header and delimiter formats are described in
     
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         the following sections. When operating in Address Translation mode,
         (see section 5.5.2) the iFCP gateway must recalculate the Fibre
         Channel CRC.
     
     6.4.1   Encapsulation Header Format
     
     W|------------------------------Bit------------------------------|
     o|                                                               |
     r|3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1                    |
     d|1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0|
      +---------------+---------------+---------------+---------------+
     0|   Protocol#   |    Version    |  -Protocol#   |   -Version    |
      +---------------+---------------+---------------+---------------+
     1|                  Reserved (must be zero)                      |
      +---------------+---------------+---------------+---------------+
     2| LS_COMMAND    |  iFCP Flags   |     SOF       |      EOF      |
      +-----------+---+---------------+-----------+---+---------------+
     3|   Flags   |   Frame Length    |   -Flags  |   -Frame Length   |
      +-----------+-------------------+-----------+-------------------+
     4|                      Time Stamp [integer]                     |
      +---------------------------------------------------------------+
     5|                      Time Stamp [fraction]                    |
      +---------------------------------------------------------------+
     6|                              CRC                              |
      +---------------------------------------------------------------+
     
     
         Common Encapsulation Fields:
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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          Protocol#            IANA-assigned protocol number
                                identifying the protocol using the
                                encapsulation.  For iFCP the value is
                                (/TBD/).
     
          Version              Encapsulation version
     
          -Protocol#           Ones complement of the protocol#
     
          -Version             Ones complement of the version
     
          Flags                Encapsulation flags (see 6.4.1.1)
     
          Frame Length         Contains the length of the entire FC
                                Encapsulated frame including the FC
                                Encapsulation Header and the FC frame
                                (including SOF and EOF words) in units
                                of 32-bit words.
     
          -Flags               Ones-complement of the Flags field.
     
          -Frame Length        Ones-complement of the Frame Length
                                field.
     
          Time Stamp [integer] Integer component of the frame time
                                stamp in SNTP format [RFC2030].
     
          Time Stamp           Fractional component of the time stamp
          [fraction]           in SNTP format [RFC2030].
     
          CRC                  Header CRC.  MUST be valid for iFCP.
     
     
     
             The time stamp fields are used to enforce the limit on the
             lifetime of a Fibre Channel frame as described in section
             9.2.1.
     
          iFCP-specific fields:
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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          LS_COMMAND           For a special link service ACC
                                response to be processed by iFCP, the
                                LS_COMMAND field SHALL contain bits 31
                                through 24 of the LS_COMMAND to which
                                the ACC applies. Otherwise the
                                LS_COMMAND field shall be set to zero.
     
          iFCP Flags           iFCP-specific flags (see below)
     
          SOF                  Copy of the SOF delimiter encoding
                                (see section 6.4.2)
     
          EOF                  Copy of the EOF delimiter encoding
                                (see section 6.4.2)
     
     
     
         The iFCP flags word has the following format:
     
            |------------------------Bit----------------------------|
            |                                                       |
            |  23     22     21     20     19     18     17    16   |
            +------+------+------+------+------+------+------+------+
            |             Reserved             | SES  | TRN  |  SPC |
            +------+------+------+------+------+------+------+------+
                             Figure 16 -- iFCP Flags Word
     
         iFCP Flags:
     
         SES         1 = Session control frame (TRN and SPC MUST be
                          0)
     
         TRN         1 = Address transparent mode enabled
     
                      0 = Address translation mode enabled
     
         SPC         1 = Frame is part of an ELS requiring special
                          processing by iFCP prior to forwarding to
                          the destination N_PORT.
     
     
     
     6.4.1.1  Common Encapsulation Flags
     
         The iFCP usage of the common encapsulation flags is shown below:
     
     
     
     
     
     
     
     
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           |------------------------Bit--------------------------|
           |                                                     |
           |   31       30       29       28       27       26   |
           +--------------------------------------------+--------+
           |                  Reserved                  |  CRCV  |
           +--------------------------------------------+--------+
     
     
         For iFCP, the CRC field MUST be valid and CRCV MUST be set to one.
     
     6.4.2   SOF and EOF Delimiter Fields
     
         The format of the delimiter fields is shown below.
     
     W|------------------------------Bit------------------------------|
     o|                                                               |
     r|3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1                    |
     d|1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0|
      +---------------+---------------+-------------------------------+
     0|      SOF      |      SOF      |     -SOF      |     -SOF      |
      +---------------+---------------+-------------------------------+
     1|                                                               |
      +-----                   FC frame content                  -----+
      |                                                               |
      +---------------+---------------+-------------------------------+
     n|      EOF      |      EOF      |     -EOF      |     -EOF      |
      +---------------+---------------+-------------------------------+
     Figure 17 -- FC Frame Encapsulation Format
     
          SOF (bits 31-24 and bits 23-16 in word 0):  iFCP uses the
          following subset of the SOF fields described in [ENCAP].
     
                               +-------+----------+
                               |  FC   |          |
                               |  SOF  | SOF Code |
                               +-------+----------+
                               | SOFi2 |   0x2D   |
                               | SOFn2 |   0x35   |
                               | SOFi3 |   0x2E   |
                               | SOFn3 |   0x36   |
                               +-------+----------+
             Table 2-- Translation of FC SOF Values to SOF Field Contents
     
         -SOF (bits 15-8 and 7-0 in word 0): The -SOF fields contain the
         ones complement of the value in the SOF fields.
     
         EOF (bits 31-24 and 23-16 in word n):  iFCP uses the following
         subset of EOF fields specified in [ENCAP].
     
     
     
     
     
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                               +-------+----------+
                               |  FC   |          |
                               |  EOF  | EOF Code |
                               +-------+----------+
                               | EOFn  |   0x41   |
                               | EOFt  |   0x42   |
                               +-------+----------+
            Table 3 -- Translation of FC EOF Values to EOF Field Contents
     
         -EOF (bits 15-8 and 7-0 in word n): The -EOF fields contain the
         one's complement of the value in the EOF fields.
     
         iFCP implementations SHALL place a copy of the SOF and EOF
         delimiter codes in the appropriate header fields.
     
     6.4.3   Frame Encapsulation
     
         A Fibre Channel Frame to be encapsulated MUST first be validated as
         described in [FC-FS].  Any frames received from a locally attached
         Fibre Channel device that do not pass the validity tests in [FC-FS]
         SHALL be discarded by the gateway.
     
         Frames types submitted for encapsulation and forwarding on the IP
         network SHALL have one of the SOF delimiters in Table 2 and an EOF
         delimiter from Table 3.  Other valid frame types MUST be processed
         internally by the gateway as specified in the appropriate Fibre
         Channel specification.
     
         Prior to submitting a frame for encapsulation, a gateway in address
         translation mode SHALL replace the D_ID address, and, if processing
         a special ELS requiring the inclusion of supplemental data, SHALL
         format the frame payload and add the supplemental information as
         specified in section 8.1.  The gateway SHALL then calculate a new
         FC CRC on the reformatted frame.
     
         A gateway in address transparent mode MAY encapsulate and transmit
         the frame image without recalculating the FC CRC.
     
         The frame originator MUST then create and fill in the header and
         the SOF and EOF delimiter words as specified above.
     
     6.4.4   Frame De-encapsulation
     
         The receiving gateway SHALL perform de-encapsulation as follows:
     
         Upon receiving the encapsulated frame, the gateway SHALL check the
         header CRC.  If the header CRC is invalid, the gateway SHALL
         terminate the N_PORT login session as described in section 6.2.3.2.
     
         After validating the header CRC, the receiving gateway SHALL verify
         the frame propagation delay as described in section 9.2.1. If the
         propagation delay is too long, the frame SHALL be discarded.
     
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         Otherwise, the gateway SHALL check the SOF and EOF in the
         encapsulation header.  A frame SHALL be discarded if it has an SOF
         code that is not in Table 2 or an EOF code that is not in Table 3.
     
         The gateway shall then de-encapsulate the frame.  If operating in
         address translation mode, the gateway SHALL:
     
         a) Check the FC CRC and discard the frame if the CRC is invalid.
     
         b) Replace the S_ID with the N_PORT alias of the frame originator
     
         c) If processing an augmented ELS, replace the ELS frame with a
            copy whose payload has been modified as specified in section
            8.1.
     
         The de-encapsulated frame SHALL then be delivered to the N_PORT
         specified in the D_ID field.  If the frame contents have been
         modified by the receiving gateway, a new FC CRC SHALL be
         calculated.
     
     7.       TCP Session Control Messages
     
         TCP session control messages are used to create and manage an iFCP
         session as described in section 6.2.2. They are passed between peer
         iFCP Portals and are only processed within the iFCP layer.
     
         The message format is based on the Fibre Channel extended link
         service message template shown below.
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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         Word
           31<Bits>24 23<---------------Bits------------------------->0
          +------------+------------------------------------------------+
         0| R_CTL      |            D_ID [0x00 00 00]                   |
          |[Req = 0x22]| [Destination of extended link Service request] |
          |[Rep = 0x23]|                                                |
          +------------+------------------------------------------------+
         1| CS_CTL     |            S_ID [0x00 00 00]                   |
          | [0x0]      | [Source of extended link service request]      |
          +------------+------------------------------------------------+
         2|TYPE [0x1]  |               F_CTL [0]                        |
          +------------+------------------+-----------------------------+
         3|SEQ_ID      | DF_CTL [0x00]    |          SEQ_CNT [0x00]     |
          |[0x0]       |                  |                             |
          +------------+------------------+-----------------------------+
         4|         OX_ID [0x0000]        |          RX_ID_[0x0000]     |
          +-------------------------------+-----------------------------+
         5|                           Parameter                         |
          |                         [ 00 00 00 00 ]                     |
          +-------------------------------------------------------------+
         6|                        LS_COMMAND                           |
          |                [Session Control Command Code]               |
          +-------------------------------------------------------------+
         7|                                                             |
         .|             Additional Session Control Parameters           |
         .|                      ( if any )                             |
         n|                                                             |
          +=============================================================+
         n|                    Fibre Channel CRC                        |
         +|                                                             |
         1+=============================================================+
                    Figure 18 -- Format of Session Control Message
     
     
         The LS_COMMAND value for the response remains the same as that used
         for the request.
     
         The session control ELS frame is terminated with a Fibre Channel
         CRC.  The frame SHALL be encapsulated and de-encapsulated according
         to the rules specified in section 6.4.
     
         The encapsulation header for the link Service frame carrying a TCP
         ELS message SHALL be set as follows:
     
         Encapsulation Header Fields:
     
     
     
     
     
     
     
     
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          LS_COMMAND           0
     
          iFCP Flags           SES = 1
     
                                TRN = 0
     
                                INT = 0
     
          SOF code             SOFi3 encoding (0x2E)
     
          EOF code             EOFt encoding (0x42)
     
     
     
         The encapsulation time stamp words SHALL be set as described for
         each message type.
     
         The SOF and EOF delimiter words SHALL be set based on the SOF and
         EOF codes specified above.
     
         The following lists the session control messages and their
         corresponding LS_COMMAND values.
     
                     Request            LS_COMMAND Short Name  iFCP Support
                     -------            ---------- ----------  -----------
         Connection Bind                  0xE0       CBIND      REQUIRED
         Unbind Connection                0xE4      UNBIND      REQUIRED
         Test Connection Liveness         0xE5       LTEST      Required
     
     
     7.1      Connection Bind (CBIND)
     
         As described in section 6.2.2.1, the CBIND message and response are
         used to bind an N_PORT login session to a specific TCP connection
         and establish an iFCP session.  In the CBIND request message, the
         source and destination N_Ports are identified by the N_PORT network
         address (iFCP portal address and N_PORT ID). The time stamp words
         in the encapsulation header shall be set to zero in the request and
         response message frames.
     
         The following shows the format of the CBIND request.
     
     
     
     
     
     
     
     
     
     
     
     
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         +------+------------+------------+-----------+----------+
         | Word |   Byte 0   |   Byte 1   |   Byte 2  |  Byte 3  |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0xE0 |   0x00     |   0x00    |  0x00    |
         +------+------------+------------+-----------+----------+
         | 1    |  LIVENESS TEST INTERVAL | Addr Mode | iFCP Ver |
         |      |        (Seconds)        |           |          |
         +------+-------------------------+-----------+----------+
         | 2    |                  USER INFO                     |
         +------+------------+------------+-----------+----------+
         | 3    |                                                |
         +------+              SOURCE N_PORT NAME                |
         | 4    |                                                |
         +------+------------------------------------------------+
         | 5    |                                                |
         +------+              DESTINATION N_PORT NAME           |
         | 6    |                                                |
         +------+------------------------------------------------+
     
         Addr Mode:             The addressing mode of the originating
                                 gateway.  0 = Address Translation mode, 1 =
                                 Address Transparent mode.
     
         iFCP Ver:              iFCP version number. SHALL be set to 1.
     
         LIVENESS TEST          If non-zero, requests that the receiving
         INTERVAL:              gateway transmit an LTEST message at the
                                 specified interval in seconds.
     
         USER INFO:             Contains any data desired by the requestor.
                                 This information MUST be echoed by the
                                 recipient in the CBIND response message.
     
         SOURCE N_PORT NAME:    The World Wide Port Name (WWPN) of the
                                 N_PORT locally attached to the gateway
                                 originating the CBIND request.
     
         DESTINATION N_PORT     The World Wide Port Name (WWPN) of the
         NAME:                  N_PORT locally attached to the gateway
                                 receiving the CBIND request.
     
     
     
     
         The following shows the format of the CBIND response.
     
     
     
     
     
     
     
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         +------+------------+------------+-----------+----------+
         | Word |   Byte 0   |   Byte 1   |   Byte 2  |  Byte 3  |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0xE0 |   0x00     |   0x00    |  0x00    |
         +------+------------+------------+-----------+----------+
         | 1    |  LIVENESS TEST INTERVAL | Addr Mode | iFCP Ver |
         |      |      (Seconds)          |           |          |
         +------+-------------------------+-----------+----------+
         | 2    |                  USER INFO                     |
         +------+------------+------------+-----------+----------+
         | 3    |                                                |
         +------+               SOURCE N_PORT NAME               |
         | 4    |                                                |
         +------+------------------------------------------------+
         | 5    |                                                |
         +------+              DESTINATION N_PORT NAME           |
         | 6    |                                                |
         +------+-------------------------+----------------------+
         | 7    |        Reserved         |     CBIND Status     |
         +------+-------------------------+----------------------+
         | 8    |        Reserved         |  CONNECTION HANDLE   |
         +------+-------------------------+----------------------+
                                   Total Length = 32
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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         Addr Mode:             The address translation mode of the
                                 responding gateway.  0 = Address
                                 Translation mode, 1 = Address Transparent
                                 mode.
     
         iFCP Ver:              iFCP version number. Shall be set to 1.
     
         LIVENESS TEST          If non-zero, requests that the gateway
         INTERVAL:              receiving the CBIND RESPONSE transmit an
                                 LTEST message at the specified interval in
                                 seconds.
     
         USER INFO:             Echoes the value received in the USER INFO
                                 field of the CBIND request message.
     
         SOURCE PORT NAME:      Contains the World Wide Port Name (WWPN) of
                                 the N_PORT locally attached to the gateway
                                 issuing the CBIND request.
     
         DESTINATION PORT       Contains the World Wide Port Name (WWPN) of
         NAME:                  the N_PORT locally attached to the gateway
                                 issuing the CBIND response.
     
         CBIND STATUS:          Indicates success or failure of the CBIND
                                 request.  CBIND values are shown below.
     
         CONNECTION HANDLE:     Contains a value assigned by the gateway to
                                 identify the connection. The connection
                                 handle is required when issuing the UNBIND
                                 request.
     
     
     
          CBIND Status  Description
          ------------  -----------
     
                0       Successful û No other status
             1 û 15     Reserved
               16       Failed û Unspecified Reason
               17       Failed û No such device
               18       Failed û N_PORT session already exists
               19       Failed û Lack of resources
               20       Failed - Incompatible address translation mode
               21       Failed - Incorrect protocol version number
             Others     Reserved
     
     
     7.2      Unbind Connection (UNBIND)
     
         UNBIND is used to release a bound TCP connection and return it to
         the pool of unbound TCP connections.  This message is transmitted
         in the connection that is to be unbound.  The time stamp words in
     
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         the encapsulation header shall be set to zero in the request and
         response message frames.
     
         The following is the format of the UNBIND request message.
     
         +------+------------+------------+-----------+----------+
         | Word |   Byte 0   |   Byte 1   |   Byte 2  |  Byte 3  |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0xE4 |   0x00     |   0x00    |  0x00    |
         +------+------------+------------+-----------+----------+
         | 1    |                  USER INFO                     |
         +------+------------+------------+-----------+----------+
         | 2    |       Reserved          |  CONNECTION HANDLE   |
         +------+------------+------------+----------------------+
         | 3    |                  Reserved                      |
         +------+------------+------------+-----------+----------+
         | 4    |                  Reserved                      |
         +------+------------+------------+-----------+----------+
     
     
         USER INFO              Contains any data desired by the requestor.
                                 This information MUST be echoed by the
                                 recipient in the UNBIND response message.
     
         CONNECTION HANDLE:     Contains the gateway-assigned value from
                                 the CBIND request.
     
     
     
         The following shows the format of the UNBIND response message.
     
         +------+------------+------------+-----------+----------+
         | Word |   Byte 0   |   Byte 1   |   Byte 2  |  Byte 3  |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0xE4 |   0x00     |   0x00    |  0x00    |
         +------+------------+------------+-----------+----------+
         | 1    |                  USER INFO                     |
         +------+------------+------------+-----------+----------+
         | 2    |       Reserved          |  CONNECTION HANDLE   |
         +------+------------+------------+-----------+----------+
         | 3    |                  Reserved                      |
         +------+------------+------------+-----------+----------+
         | 4    |                  Reserved                      |
         +------+------------+------------+-----------+----------+
         | 5    |         Reserved        |     UNBIND STATUS    |
         +------+------------+------------+-----------+----------+
     
     
     
     
     
     
     
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         USER INFO              Echoes the value received in the USER INFO
                                 field of the UNBIND request message.
     
         CONNECTION HANDLE:     Echoes the CONNECTION HANDLE specified in
                                 the UNBIND request message.
     
         UNBIND STATUS:         Indicates the success or failure of the
                                 UNBIND request as follows:
     
     
     
          Unbind Status Description
          ------------- -----------
     
                0       Successful û No other status
             1 û 15     Reserved
               16       Failed û Unspecified Reason
               18       Failed û Connection ID Invalid
             Others     Reserved
     
     
     7.3      LTEST -- Test Connection Liveness
     
         The LTEST message is sent at the interval specified in the CBIND
         request or response payload.  The LTEST encapsulation time stamp
         SHALL be set as described in section 9.2.1 and may be used by the
         receiver to compute an estimate of propagation delay.  However, the
         propagation delay limit SHALL NOT be enforced.
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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         +------+------------+------------+-----------+----------+
         | Word |   Byte 0   |   Byte 1   |   Byte 2  |  Byte 3  |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0xE5 |   0x00     |   0x00    |  0x00    |
         +------+------------+------------+-----------+----------+
         | 1    |  LIVENESS TEST INTERVAL |        Reserved      |
         |      |        (Seconds)        |                      |
         +------+-------------------------+----------------------+
         | 2    |                   COUNT                        |
         +------+------------+------------+-----------+----------+
         | 3    |                                                |
         +------+              SOURCE N_PORT NAME                |
         | 4    |                                                |
         +------+------------------------------------------------+
         | 5    |                                                |
         +------+              DESTINATION N_PORT NAME           |
         | 6    |                                                |
         +------+------------------------------------------------+
     
         LIVENESS TEST          Copy of the LIVENESS TEST INTERVAL
         INTERVAL:              specified in the CBIND request or reply
                                 message.
     
         COUNT:                 Monotonically increasing value, initialized
                                 to 0 and incremented by one for each
                                 successive LTEST message.
     
         SOURCE N_PORT NAME:    Contains a copy of the SOURCE N_PORT NAME
                                 specified in the CBIND request.
     
         DESTINATION N_PORT     Contains a copy of the DESTINATION N_PORT
         NAME:                  NAME specified in the CBIND request.
     
     
     
     
     
     8.       Fibre Channel Link Services
     
         Link services provide a set of Fibre Channel functions that allow a
         port to send control information or request another port to perform
         a specific control function.
     
         There are three types of link services:
     
         a) Basic
     
         b) Extended
     
         c) ULP-specific (FC-4)
     
     
     
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         Each link service message (request and reply) is carried by a Fibre
         Channel sequence, and can be segmented into multiple frames.
     
         The iFCP Layer is responsible for transporting link service
         messages across the IP fabric.  This includes mapping Link Service
         messages appropriately from the domain of the Fibre Channel
         transport to that of the IP network.  This process may require
         special processing and the inclusion of supplemental data by the
         iFCP layer.
     
         Each link service is processed according to one of the following
         rules:
     
         a) Transparent û The link service message and reply MUST be
            transported to the receiving N_PORT by the iFCP gateway without
            altering the message payload. The link service message and reply
            are not processed by the iFCP implementation.
     
         b) Special -  Applies to alink service reply or request requiring
            iFCP intervention before forwarding to the destination N_PORT.
            Such messages may contain Fibre Channel addresses in the payload
            or may require other special processing.
     
         c) Rejected û When issued by a locally attached N_PORT, the
            specified link service request MUST be rejected by the iFCP
            implementation.   The gateway SHALL respond to a rejected link
            service message by returning an LS_RJT response with a Reason
            Code of 0x0B (Command Not Supported) and a Reason Code
            Explanation of 0x0 (No Additional Explanation).
     
         This section describes the processing for special link services,
         including the manner in which supplemental data is added to the ELS
         payload.
     
         Appendix A enumerates all link services and the iFCP processing
         policy that applies to each.
     
     8.1      Special Link Service Messages
     
         Special link service messages require the intervention of the iFCP
         layer before forwarding to the destination N_PORT.  Such
         intervention is required in order to:
     
         a) Service any link service message which requires special
            handling, such as a PLOGI.
     
         b) In address translation mode only, service any link service
            message  which has an N_PORT address in the payload.
     
         Such messages are transmitted in a Fibre Channel frame having the
         format shown in Figure 19 for extended link services or Figure 21
         for FC-4 link services.:
     
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         Word
           31        24 23                                             0
          +------------+------------------------------------------------+
         0| R_CTL      |                     D_ID                       |
          |[Req = 0x22]|[Destination of extended link Service request]  |
          |[Rep = 0x23]|                                               |
          +------------+------------------------------------------------+
         1| CS_CTL     |                     S_ID                       |
          |            | [Source of extended link service request]      |
          +------------+------------------------------------------------+
         2| TYPE       |                     F_CTL                      |
          | [0x01]     |                                                |
          +------------+------------------+-----------------------------+
         3| SEQ_ID     |        DF_CTL    |          SEQ_CNT            |
          +------------+------------------+-----------------------------+
         4|          OX_ID                |             RX_ID           |
          +-------------------------------+-----------------------------+
         5|                         Parameter                           |
          |                      [ 00 00 00 00 ]                        |
          +-------------------------------------------------------------+
         6|                         LS_COMMAND                          |
          |               [Extended Link Service Command Code]          |
          +-------------==----------------------------------------------+
         7|                                                             |
         .|             Additional Service Request Parameters           |
         .|                      ( if any )                             |
         n|                                                             |
          +-------------------------------------------------------------+
                Figure 19 -- Format of an Extended Link Service Frame
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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         Word
           31        24 23                                             0
          +------------+------------------------------------------------+
         0| R_CTL      |                     D_ID                       |
          |[Req = 0x32]|   [Destination of FC-4 link Service request]   |
          |[Rep = 0x33]|                                                |
          +------------+------------------------------------------------+
         1| CS_CTL     |                     S_ID                       |
          |            |    [Source of FC-4 link service request]       |
          +------------+------------------------------------------------+
         2| TYPE       |                     F_CTL                      |
          | (FC-4      |                                                |
          |  specific) |                                                |
          +------------+------------------+-----------------------------+
         3| SEQ_ID     |        DF_CTL    |          SEQ_CNT            |
          +------------+------------------+-----------------------------+
         4|         OX_ID                 |             RX_ID           |
          +-------------------------------+-----------------------------+
         5|                        Parameter                            |
          |                     [ 00 00 00 00 ]                         |
          +-------------------------------------------------------------+
         6|                        LS_COMMAND                           |
          |               [FC-4 Link Service Command Code]              |
          +-------------------------------------------------------------+
         7|                                                             |
         .|             Additional Service Request Parameters           |
         .|                      ( if any )                             |
         n|                                                             |
          +-------------------------------------------------------------+
                  Figure 21 -- Format of an FC-4 Link Service Frame
     
     8.2      Link Services Requiring Payload Address Translation
     
         This section describes the handling for link service frames
         containing N_PORT addresses in the frame payload. Such addresses
         SHALL only be translated when the gateway is operating in address
         translation mode.  When operating in address transparent mode,
         these addresses SHALL NOT be translated. In addition, such link
         service messages SHALL NOT be sent as special frames unless other
         processing by the iFCP layer is required.
     
         Supplemental data includes information required by the receiving
         gateway to convert an N_PORT address in the payload to an N_PORT
         address in the receiving gatewayÆs address space. The following
         rules define the manner in which such supplemental data is packaged
         and referenced.
     
         For an N_PORT address field, the gateway originating the frame MUST
         set the value in the payload to identify the address translation
         type as follows:
     
     
     
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             0x00 00 01 û The gateway receiving the frame from the IP
             network MUST replace the contents of the field with the N_PORT
             alias of the frame originator.  This translation type MUST be
             used when the address to be converted is that of the source
             N_PORT.
     
             0x00 00 02 û The gateway receiving the frame from the IP
             network MUST replace the contents of the field with the N_PORT
             I/D of the destination N_PORT.  This translation type MUST be
             used when the address to be converted is that of the
             destination N_PORT
     
             0x00 00 03 û The gateway receiving the frame from the IP
             network MUST reference the specified supplemental data to set
             the field contents. The supplemental information is the 64-bit
             world wide identifier of the N_PORT as set forth in the Fibre
             Channel specification [FC-FS]. If not otherwise part of the
             ELS, this information MUST be appended in accordance with  the
             applicable link service description. Unless specified
             otherwise, this translation type SHALL NOT be used if the
             address to be converted corresponds to that of the frame
             originator or recipient.
     
         Since Fibre Channel addressing rules prohibit the assignment of
         fabric addresses with a domain I/D of 0, the above codes will never
         correspond to valid N_PORT fabric IDs.
     
         For translation type 3, the receiving gateway SHALL obtain the
         information needed to fill in the field in the link service frame
         payload by converting the specified N_PORT world-wide identifier to
         a gateway IP address and N_PORT ID.  This information MUST be
         obtained through a name server query. If the N_PORT is locally
         attached, the gateway MUST fill in the field with the N_PORT ID.
         If the N_PORT is remotely attached, the gateway MUST assign and
         fill in the field with an N_PORT alias.  If an N_PORT alias has
         already been assigned, it MUST be reused.
     
         In the event that the sending gateway cannot obtain the world wide
         identifier of an N_PORT, or a receiving gateway cannot obtain the
         IP address and N_PORT ID, the gateway detecting the error SHALL
         terminate the request with an LS_RJT message as described in [FCS].
         The Reason Code SHALL be set to 0x07 (protocol error) and the
         Reason Explanation SHALL be set to 0x1F (Invalid N_PORT
         identifier).
     
         Supplemental data is sent with the link service request or ACC
         frames in one of the following ways:
     
         a) By appending the necessary data to the end of the link service
            frame.
     
         b) By extending the sequence with additional frames.
     
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         In the first case, a new frame SHALL be created whose length
         includes the supplemental data. The procedure for extending the
         link service sequence with additional frames is dependent on the
         link service type.
     
         After applying the supplemental data, the receiving gateway SHALL
         forward the resulting link service frames to the destination N_PORT
         with the supplemental information removed.
     
         When the ACC response requires iFCP intervention,, the receiving
         gateway MUST act as a proxy for the originator, retaining the state
         needed to process the response from the N_PORT to which the request
         was directed.
     
     8.3      Fibre Channel Link Services Processed by iFCP
     
         The following Extended and FC-4 Link Service Messages must receive
         special processing.
     
         Extended Link Service Messages     LS_COMMAND      Mnemonic
         ------------------------------     ----------      --------
         Abort Exchange                    0x06 00 00 00       ABTX
         Discover Address                  0x52 00 00 00      ADISC
         Discover Address Accept           0x02 00 00 00    ADISC ACC
         FC Address Resolution Protocol    0x55 00 00 00    FARP-REPLY
         Reply
         FC Address Resolution Protocol    0x54 00 00 00     FARP-REQ
         Request
         Logout                            0x05 00 00 00       LOGO
         Port Login                        0x30 00 00 00      PLOGI
         Read Exchange Status Block        0x08 00 00 00       RES
         Read Exchange Status Block        0x02 00 00 00     RES ACC
         Accept
         Read Link Error Status Block      0x0F 00 00 00       RLS
         Read Sequence Status Block        0x09 00 00 00       RSS
         Reinstate Recovery Qualifier      0x12 00 00 00       RRQ
         Request Sequence Initiative       0x0A 00 00 00       RSI
         Third Party Process Logout        0x24 00 00 00      TPRLO
         Third Party Process Logout        0x02 00 00 00    TPRLO ACC
         Accept
     
     
     
         FC-4 Link Service Messages         LS_COMMAND      Mnemonic
         --------------------------         ----------      --------
         FCP Read Exchange Concise         0x13 00 00 00       REC
         FCP Read Exchange Concise         0x02 00 00 00     REC ACC
         Accept
     
         Each encapsulated Fibre Channel frame that is part of a special
         link service MUST have the SPC bit set to one in the iFCP FLAGS
         field of the encapsulation header as specified in section 6.4.1.
     
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         Supplemental data (if any) MUST be appended as described in the
         following section.
     
         The formats of each special link service message, including
         supplemental data where applicable, are shown in the following
         sections.  Eachdescription shows the basic format, as specified in
         the applicable FC standard, followed by supplemental data as shown
         in the example below.
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    |                  LS_COMMAND                    |
         +------+------------+------------+-----------+----------+
         | 1    |                                                |
         | .    |                                                |
         | .    |          Link Service Frame Payload            |
         |      |                                                |
         | n    |                                                |
         +======+============+============+===========+==========+
         | n+1  |                                                |
         |  .   |            Supplemental Data                   |
         |  .   |               (if any)                         |
         | n+k  |                                                |
         +======+================================================+
                 Figure 23 -- Special Link Service Frame Payload
     
     
     8.3.1   Special Extended Link Services
     
         The following sections define extended link services for which
         special processing is required.
     
     8.3.1.1  Abort Exchange (ABTX)
     
         ELS Format:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x6  |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | RRQ Status |     Exchange Originator S_ID      |
         +------+------------+------------+-----------+----------+
         | 2    |   OX_ID of Tgt exchange | RX_ID of tgt exchange|
         +------+------------+------------+-----------+----------+
         | 3-10 |  Optional association header (32 bytes         |
         +======+============+============+===========+==========+
     
     
         Fields Requiring       Translation   Supplemental Data
         Address Translation     Type (see      (type 3 only)
     
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         -------------------    section 8.2)     ------------
                                 -----------
     
         Exchange Originator        1, 2              N/A
         S_ID
     
     
         Other Special Processing:
     
             None
     
     8.3.1.2  Discover Address (ADISC)
     
         Format of ADISC ELS:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x52 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Reserved   |  Hard address of ELS Originator   |
         +------+------------+------------+-----------+----------+
         | 2-3  |     Port Name of Originator                    |
         +------+------------+------------+-----------+----------+
         | 4-5  |     Node Name of originator                    |
         +------+------------+------------+-----------+----------+
         | 6    |  Rsvd      |  N_PORT I/D of ELS Originator     |
         +======+============+============+===========+==========+
     
     
     
         Fields Requiring       Translation    Supplemental Data
         Address Translation     Type (see       (type 3 only)
         -------------------   section 8.2)      ------------
                                -------------
     
         N_PORT I/D of ELS           1                N/A
         Originator
     
     
     
         Other Special Processing:
     
             The Hard Address of the ELS originator SHALL be set to 0.
     
     8.3.1.3  Discover Address Accept (ADISC ACC)
     
         Format of ADISC ACC ELS:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
     
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         | 0    | Cmd = 0x20 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Reserved   |  Hard address of ELS Originator   |
         +------+------------+------------+-----------+----------+
         | 2-3  |     Port Name of Originator                    |
         +------+------------+------------+-----------+----------+
         | 4-5  |     Node Name of originator                    |
         +------+------------+------------+-----------+----------+
         | 6    |  Rsvd      |  N_PORT I/D of ELS Originator     |
         +======+============+============+===========+==========+
     
     
         Fields Requiring       Translation    Supplemental Data
         Address Translation     Type (see       (type 3 only)
         -------------------   section 8.2)      ------------
                                ------------
     
         N_PORT I/D of ELS           1                N/A
         Originator
     
     
         Other Special Processing:
     
             The Hard Address of the ELS originator SHALL be set to 0.
     
     8.3.1.4  FC Address Resolution Protocol Reply (FARP-REPLY)
     
         The FARP-REPLY ELS is used in conjunction with the FARP-REQ ELS
         (see section 8.3.1.5) to perform the address resolution services
         required by the FC-VI protocol [FC-VI] and the Fibre Channel
         mapping of IP and ARP specified in RFC 2625 [RFC2625].
     
         Format of FARP-REPLY ELS:
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x55 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Match Addr |  Requesting N_PORT Identifier     |
         |      | Code Points|                                   |
         +------+------------+------------+-----------+----------+
         | 2    | Responder  |  Responding N_PORT Identifier     |
         |      | Action     |                                   |
         +------+------------+------------+-----------+----------+
         | 3-4  |     Requesting N_PORT Port_Name                |
         +------+------------+------------+-----------+----------+
         | 5-6  |     Requesting N_PORT Node_Name                |
         +------+------------+------------+-----------+----------+
         | 7-8  |     Responding N_PORT Port_Name                |
         +------+------------+------------+-----------+----------+
         | 9-10 |     Responding N_PORT Node_Name                |
         +------+------------+------------+-----------+----------+
         | 11-14|     Requesting N_PORT IP Address               |
         +------+------------+------------+-----------+----------+
         | 15-18|     Responding N_PORT IP Address               |
         +======+============+============+===========+==========+
     
     
     
     
         Fields Requiring       Translation    Supplemental Data
         Address Translation     Type (see       (type 3 only)
         -------------------   section 8.2)   -----------------
                                -------------
     
         Requesting N_PORT           2                N/A
         Identifier
     
         Responding N_PORT           1                N/A
         identifier
     
     
     
         Other Special Processing:
     
             None.
     
     
     8.3.1.5  FC Address Resolution Protocol Request (FARP-REQ)
     
         The FARP-REQ ELS is used to in conjunction with the FC-VI protocol
         [FC-VI] and IP to FC mapping of RFC 2625 [RFC2625] to perform IP
         and FC address resolution in an FC fabric.  The FARP-REQ ELS is
         usually directed to the fabric broadcast server at well-known
         address 0xFF-FF-FF for retransmission to all attached N_PORTs.
     
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         Section 10.4 describes the iFCP implementation of FC broadcast
         server functionality in an iFCP fabric.
     
         Format of FARP_REQ ELS:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x54 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Match Addr |  Requesting N_PORT Identifier     |
         |      | Code Points|                                   |
         +------+------------+------------+-----------+----------+
         | 2    | Responder  |  Responding N_PORT Identifier     |
         |      | Action     |                                   |
         +------+------------+------------+-----------+----------+
         | 3-4  |     Requesting N_PORT Port_Name                |
         +------+------------+------------+-----------+----------+
         | 5-6  |     Requesting N_PORT Node_Name                |
         +------+------------+------------+-----------+----------+
         | 7-8  |     Responding N_PORT Port_Name                |
         +------+------------+------------+-----------+----------+
         | 9-10 |     Responding N_PORT Node_Name                |
         +------+------------+------------+-----------+----------+
         | 11-14|     Requesting N_PORT IP Address               |
         +------+------------+------------+-----------+----------+
         | 15-18|     Responding N_PORT IP Address               |
         +======+============+============+===========+==========+
     
     
         Fields Requiring       Translation   Supplemental Data
         Address Translation     Type (see      (type 3 only)
         -------------------   section 8.2)   -----------------
                                 -----------
     
         Requesting N_PORT           3        Requesting N_PORT
         Identifier                           Port Name
     
         Responding N_PORT           3        Responding N_PORT
         Identifier                           Port Name
     
     
         Other Special Processing:
     
             None.
     
     
     8.3.1.6  Logout (LOGO)
     
         ELS Format:
     
     
     
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         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x5  |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Rsvd       |     N_PORT I/D being logged out   |
         +------+------------+------------+-----------+----------+
         | 2-3  |  Port name of the LOGO originator (8 bytes)    |
         +======+============+============+===========+==========+
     
     
         This ELS shall always be sent as an augmented ELS regardless of the
         translation mode in effect.
     
         Fields Requiring       Translation   Supplemental Data
         Address Translation     Type(see       (type 3 only)
         -------------------   section 8.2)    --------------
                                 -----------
     
         N_PORT I/D Being            1               N/A
         Logged Out
     
     
     
         Other Special Processing:
     
             See section 6.2.3.1.
     
     
     8.3.1.7  Port Login (PLOGI) and PLOGI ACC
     
         PLOGI provides the mechanism for establishing a login session
         between two N_PORTs. In iFCP, a PLOGI request addressed to a
         remotely attached N_PORT may trigger the creation of an iFCP
         session, if one does not already exist.  Otherwise, the PLOGI and
         ACC payloads MUST be passed transparently to the destination
         N_PORT.
     
         The PLOGI request and ACC response carry information identifying
         the originating N_PORT, including specification of its capabilities
         and limitations.  If the destination N_PORT accepts the login
         request, it sends an accept (an ACC frame with PLOGI payload),
         specifying its capabilities and limitations.  This exchange
         establishes the operating environment for the two N_PORTs.
     
         The following figure is duplicated from [FC-FS], and shows the
         PLOGI message format for both request and accept (ACC) response.  A
         port will reject a PLOGI request by transmitting an LS_RJT message,
         which contains no payload.
     
     
     
     
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        Byte
        Offset
               +----------------------------------+
           0   |            LS_COMMAND            |     4 Bytes
               +----------------------------------+
           4   |     COMMON SERVICE PARAMETERS    |    16 Bytes
               +----------------------------------+
          20   |            PORT NAME             |     8 Bytes
               +----------------------------------+
          28   |            NODE NAME             |     8 Bytes
               +----------------------------------+
          36   |     CLASS 1 SERVICE PARAMETERS   |    16 Bytes
               +----------------------------------+
          52   |     CLASS 2 SERVICE PARAMETERS   |    16 Bytes
               +----------------------------------+
          68   |     CLASS 3 SERVICE PARAMETERS   |    16 Bytes
               +----------------------------------+
          86   |     CLASS 4 SERVICE PARAMETERS   |    16 Bytes
               +----------------------------------+
         102   |        VENDOR VERSION LEVEL      |    16 Bytes
               +----------------------------------+
                        Total Length = 116 bytes
                Figure 24 -- Format of PLOGI Request and ACC Payloads
     
     
     
         Details on the above fields, including common and class-based
         service parameters, can be found in [FC-FS].
     
     8.3.1.8  Read Exchange Status Block (RES)
     
         ELS Format:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x13 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Rsvd       |     Exchange Originator S_ID      |
         +------+------------+------------+-----------+----------+
         | 2    |          OX_ID          |         RX_ID        |
         +------+------------+------------+-----------+----------+
         | 3-10 |  Association header (may be optionally reqÆd)  |
         +======+============+============+===========+==========+
         | 11-12| Port name of the Exchange Originator (8 bytes) |
         +======+============+============+===========+==========+
     
     
     
     
     
     
     
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         Fields Requiring       Translation     Supplemental Data
         Address Translation     Type(see        (type 3 only)
         -------------------   section 8.2)    ------------------
                                 -----------
     
         Exchange Originator  1, 2 or 3      Port Name of the
         S_ID                                 Exchange Originator
     
     
     
         Other Special Processing:
     
             None.
     
     8.3.1.9  Read Exchange Status Block Accept
     
         Format of ELS Accept Response:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Acc = 0x02 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    |          OX_ID          |         RX_ID        |
         +------+------------+------------+-----------+----------+
         | 2    | Rsvd       | Exchange Originator N_PORT ID     |
         +------+------------+------------+-----------+----------+
         | 3    | Rsvd       | Exchange Responder N_PORT ID      |
         +------+------------+------------+-----------+----------+
         | 4    |          Exchange Status Bits                  |
         +------+------------+------------+-----------+----------+
         | 5    |               Reserved                         |
         +------+------------+------------+-----------+----------+
         | 6ûn  |    Service Parameters and Sequence Statuses    |
         |      |    as described in [FCS]                       |
         +======+============+============+===========+==========+
         |n+1-  | Port name of the Exchange Originator (8 bytes) |
         |n+2   |                                                |
         +======+============+============+===========+==========+
         |n+3-  | Port name of the Exchange Responder (8 bytes)  |
         |n+4  |                                                |
         +======+============+============+===========+==========+
     
     
     
     
     
     
     
     
     
     
     
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         Fields Requiring       Translation     Supplemental Data
         Address Translation     Type(see         (type 3 only)
         -------------------   section 8.2)    ------------------
                                 -----------
     
         Exchange Originator  1, 2 or 3      Port Name of the
         N_PORT I/D                           Exchange Originator
     
         Exchange Responder   1, 2 or 3      Port Name of the
         N_PORT I/D                           Exchange Responder
     
     
     
         When supplemental data is required, the ELS SHALL be extended by 4
         words as shown above. If the translation type for the Exchange
         Originator N_PORT I/D or the Exchange Responder N_PORT I/D is 1 or
         2, the corresponding 8-byte port name SHALL be set to all zeros.
     
         Other Special Processing:
     
             None.
     
     8.3.1.10 Read Link Error Status (RLS)
     
         ELS Format:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x0F |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Rsvd       |     N_PORT Identifier             |
         +======+============+============+===========+==========+
         | 2-3  |           Port name of the N_PORT (8 bytes)    |
         +======+============+============+===========+==========+
     
         Fields Requiring       Translation   Supplemental Data (type
         Address Translation     Type(see            3 only)
         -------------------   section 8.2)     ------------------
                                 -----------
     
         N_PORT Identifier    1, 2 or 3      Port Name of the N_PORT
     
     
     
         Other Special Processing:
     
             None.
     
     8.3.1.11 Read Sequence Status Block (RSS)
     
         ELS Format:
     
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         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x09 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | SEQ_ID     |     Exchange Originator S_ID      |
         +------+------------+------------+-----------+----------+
         | 2    |          OX_ID          |         RX_ID        |
         +======+============+============+===========+==========+
         | 3-4  |Port name of the Exchange Originator (8 bytes)  |
         +======+============+============+===========+==========+
     
         Fields Requiring       Translation    Supplemental Data
         Address Translation     Type(see        (type 3 only)
         -------------------   section 8.2)   ------------------
                                 -----------
     
         Exchange Originator  1, 2 or 3      Port Name of the
         S_ID                                 Exchange Originator
     
     
     
         Other Special Processing:
     
             None.
     
     8.3.1.12 Reinstate Recovery Qualifier (RRQ)
     
         ELS Format:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x12 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Rsvd       |     Exchange Originator S_ID      |
         +------+------------+------------+-----------+----------+
         | 2    |          OX_ID          |         RX_ID        |
         +------+------------+------------+-----------+----------+
         | 3-10 |  Association header (may be optionally reqÆd)  |
         +======+============+============+===========+==========+
     
     
         Fields Requiring       Translation   Supplemental Data
         Address Translation     Type(see       (type 3 only)
         -------------------   section 8.2)  ------------------
                                 -----------
     
         Exchange Originator      1 or 2             N/A
         S_ID
     
     
     
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         Other Special Processing:
     
             None.
     
     8.3.1.13 Request Sequence Initiative (RSI)
     
         ELS Format:
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x0A |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Rsvd       |     Exchange Originator S_ID      |
         +------+------------+------------+-----------+----------+
         | 2    |          OX_ID          |         RX_ID        |
         +------+------------+------------+-----------+----------+
         | 3-10 |  Association header (may be optionally reqÆd)  |
         +======+============+============+===========+==========+
     
         Fields Requiring       Translation   Supplemental Data
         Address Translation     Type(see       (type 3 only)
         -------------------   section 8.2)  ------------------
                                 -----------
     
         Exchange Originator      1 or 2             N/A
         S_ID
     
     
     
         Other Special Processing:
     
             None.
     
     8.3.1.14 Third Party Process Logout (TPRLO)
     
         TPRLO provides a mechanism for an N_PORT (third party) to remove
         one or more process login sessions that exist between the
         destination N_PORT and other N_PORTs specified in the command.
         This command includes one or more TPRLO LOGOUT PARAMETER PAGEs,
         each of which when combined with the destination N_PORT identifies
         a process login to be terminated by the command.
     
     
     
     
     
     
     
     
     
     
     
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         +--------+------------+--------------------+----------------------+
         | Word   | Bits 31û24 |    Bits 23û16      |     Bits 15 - 0      |
         +--------+------------+--------------------+----------------------+
         | 0      | Cmd = 0x24 | Page Length (0x10) |    Payload Length    |
         +--------+------------+--------------------+----------------------+
         | 1      |          TPRLO Logout Parameter Page 0                 |
         +--------+--------------------------------------------------------+
         | 5      |          TPRLO Logout Parameter Page 1                 |
         +--------+--------------------------------------------------------+
                                  ....
         +--------+--------------------------------------------------------+
         |(4*n)+1 |          TPRLO Logout Parameter page n                 |
         +--------+--------------------------------------------------------+
                         Figure 25 -- Format of TPRLO ELS
     
         Each TPRLO parameter page contains parameters identifying one or
         more image pairs and may be associated with a single FC4 protocol
         type, common to all FC4 protocol types between the specified image
         pair, or global to all specified image pairs. The format of aTPRLO
         page requiring address translation is shown in Figure 26.
         Additional information on TPRLO can be found in [FC-FS].
     
         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15-8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | TYPE Code  | TYPE CODE  |                      |
         |      | or         | EXTENSION  |      TPRLO Flags     |
         |      | Common SVC |            |                      |
         |      | Parameters |            |                      |
         +------+------------+------------+-----------+----------+
         | 1    |         Third Party Process Associator         |
         +------+------------+------------+-----------+----------+
         | 2    |         Responder Process Associator           |
         +------+------------+------------+-----------+----------+
         | 3    | Reserved   | Third Party Originator N_PORT ID  |
         +======+============+============+===========+==========+
         | 4-5  | World Wide Name of Third Party Originator      |
         |      | N_PORT                                         |
         +------+------------------------------------------------+
          Figure 26 -- Format of an Augmented TPRLO Parameter Page
     
         The TPRLO flags that affect the processing of the supplementedELS
         are as follows:
     
         Bit 12:   Global Process logout.  When set to one, this bit
                    indicates that all image pairs for all N_PORTs of the
                    specified FC4 protocol shall be invalidated. When the
                    value of this bit is one, only one logout parameter page
                    is permitted in the TPRLO payload.
     
         Bit 13:   Third party Originator N_PORT Validity.  When set to
                    one, this bit indicates that word 3, bits 23-00 (Third
     
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                    Party Originator N_PORT ID) are meaningful.
     
     
     
         If bit 13 has a value of zero and bit 12 has a value of one in the
         TPRLO flags field, then the ELS SHALL NOT be sent as a special ELS.
     
         Otherwise the originating gateway SHALL process the ELS as follows:
     
         a)  The first word of the TPRLO payload SHALL NOT be modified.
     
         b)  Each TPRLO parameter page shall be extended by two words as
             shown in Figure 26.
     
         c)  If word 0, bit 13 (Third Party Originator N_PORT I/D validity)
             in the TPRLO flags field has a value of one, then the sender
             shall place the world-wide port name of the fibre channel
             device's N_PORT in the extension words. The N_PORT I/D SHALL be
             set to 3. Otherwise, the contents of the extension words and
             the Third Party Originator N_PORT ID SHALL be set to zero.
     
         d)  The ELS originator SHALL set the SPC bit in the encapsulation
             header of each augmented frame comprising the ELS (see section
             6.4.1).
     
         e)  If the ELS contains a single TPRLO parameter page, the
             originator SHALL increase the frame length as necessary to
             include the extended parameter page.
     
         f)  If the ELS to be augmented contains multiple TPRLO parameter
             pages, the FC frames created to contain the augmented ELS
             payload SHALL NOT exceed the maximum frame size that can be
             accepted by the destination N_PORT.
     
             Each Fibre Channel frame SHALL contain an integer number of
             extended TPRLO parameter pages. The maximum number of extended
             TPRLO parameter pages in a frame SHALL be limited to the number
             that can be held without exceeding the above upper limit. New
             frames resulting from the extension of the TPRLO pages to
             include the supplemental data shall be created by extending the
             SEQ_CNT in the Fibre Channel frame header. The SEQ_ID SHALL NOT
             be modified.
     
         The gateway receiving the augmented TPRLO ELS SHALL generate ELS
         frames to be sent to the destination N_PORT by copying word 0 of
         the ELS payload and processing each augmented parameter page as
         follows:
     
         a) If word 0, bit 13 has a value of one, create a parameter page by
            copying words 0 through 2 of the augmented parameter page.  The
            Third Party Originator N_PORT I/D in word 3 shall be generated
     
     
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            by referencing the supplemental data as described in section
            8.2.
     
         b) If word 0, bit 13 has a value of zero, create a parameter page
            by copying words 0 through 3 of the augmented parameter page.
     
         The size of each frame to be sent to the destination N_PORT MUST
         NOT exceed the maximum frame size that the destination N_PORT can
         accept.  The sequence identifier in each frame header SHALL be
         copied from the augmented ELS and the sequence count shall be
         monotonically increasing.
     
     8.3.1.15 Third Party Logout Accept (TPRLO ACC)
     
         The format of the TPRLO ACC frame is shown in Figure 28.
     
         +--------+------------+--------------------+----------------------+
         | Word   | Bits 31û24 |    Bits 23û16      |     Bits 15 - 0      |
         +--------+------------+--------------------+----------------------+
         | 0      | Cmd = 0x2  | Page Length (0x10) |    Payload Length    |
         +--------+------------+--------------------+----------------------+
         | 1      |          TPRLO Logout Parameter Page 0                 |
         +--------+--------------------------------------------------------+
         | 5      |          TPRLO Logout Parameter Page 1                 |
         +--------+--------------------------------------------------------+
                                  ....
         +--------+--------------------------------------------------------+
         |(4*n)+1 |          TPRLO Logout Parameter page n                 |
         +--------+--------------------------------------------------------+
                         Figure 28 -- Format of TPRLO ACC ELS
     
         The format of the parameter page and rules for parameter page
         augmentation are as specified in section 8.3.1.14.
     
     8.3.2   Special FC-4 Link Services
     
         The following sections define FC-4 link services for which special
         processing is required.
     
     8.3.2.1  FC-4 Link Services defined by FCP
     
     8.3.2.1.1  Read Exchange Concise (REC)
     
         Link Service Request Format:
     
     
     
     
     
     
     
     
     
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         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Cmd = 0x13 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    | Rsvd       |     Exchange Originator S_ID      |
         +------+------------+------------+-----------+----------+
         | 2    |          OX_ID          |         RX_ID        |
         +======+============+============+===========+==========+
         | 3-4  |Port name of the exchange originator (8 bytes)  |
         |      |   (present only for translation type 3)        |
         +======+============+============+===========+==========+
     
     
         Fields Requiring       Translation   Supplemental Data
         Address Translation     Type(see       (type 3 only)
         -------------------   section 8.2)  ------------------
                                 -----------
     
         Exchange Originator  1, 2 or 3      Port Name of the
         S_ID                                 Exchange
                                               Originator
     
     
     
         Other Special Processing:
     
             None.
     
     8.3.2.1.2  Read Exchange Concise Accept (REC ACC)
     
         Format of REC ACC Response:
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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         +------+------------+------------+-----------+----------+
         | Word | Bits 31û24 | Bits 23û16 | Bits 15û8 | Bits 7-0 |
         +------+------------+------------+-----------+----------+
         | 0    | Acc = 0x02 |   0x00     |    0x00   |   0x00   |
         +------+------------+------------+-----------+----------+
         | 1    |          OX_ID          |         RX_ID        |
         +------+------------+------------+-----------+----------+
         | 2    | Rsvd       | Exchange Originator N_PORT ID     |
         +------+------------+------------+-----------+----------+
         | 3    | Rsvd       | Exchange Responder N_PORT ID      |
         +------+------------+------------+-----------+----------+
         | 4    |         Data Transfer Count                    |
         +------+------------+------------+-----------+----------+
         | 5    |         Exchange Status                        |
         +======+============+============+===========+==========+
         | 6-7  |Port name of the Exchange Originator (8 bytes)  |
         +======+============+============+===========+==========+
         | 8-9  |Port name of the Exchange Responder (8 bytes)   |
         +======+============+============+===========+==========+
     
         Fields Requiring       Translation     Supplemental Data
         Address Translation     Type(see        (type 3 only)
         -------------------   section 8.2)    ------------------
                                 -----------
     
         Exchange Originator  1, 2 or 3      Port Name of the
         N_PORT I/D                           Exchange Originator
     
         Exchange Responder   1, 2 or 3      Port Name of the
         N_PORT I/D                           Exchange Responder
     
     
     
         When supplemental data is required, the frame SHALL always be
         extended by 4 words as shown above.  If the translation type for
         the Exchange Originator N_PORT I/D or the Exchange Responder N_PORT
         I/D is 1 or 2, the corresponding 8-byte port name SHALL be set to
         all zeros.
     
         Other Special Processing:
     
         None.
     
     8.4      FLOGI Service Parameters Supported by an iFCP Gateway
     
         The FLOGI ELS is issued by an N_PORT that wishes to access the
         fabric transport services.
     
         The format of the FLOGI request and FLOGI ACC payloads are
         identical to the PLOGI request and ACC payloads described in
         section 8.3.1.7.  The figure in that section is duplicated below
         for convenience.
     
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         Byte
         Offset
               +----------------------------------+
           0   |            LS_COMMAND            |     4 Bytes
               +----------------------------------+
           4   |     COMMON SERVICE PARAMETERS    |    16 Bytes
               +----------------------------------+
          20   |            PORT NAME             |     8 Bytes
               +----------------------------------+
          28   |            NODE NAME             |     8 Bytes
               +----------------------------------+
          36   |     CLASS 1 SERVICE PARAMETERS   |    16 Bytes
               +----------------------------------+
          52   |     CLASS 2 SERVICE PARAMETERS   |    16 Bytes
               +----------------------------------+
          68   |     CLASS 3 SERVICE PARAMETERS   |    16 Bytes
               +----------------------------------+
          86   |     CLASS 4 SERVICE PARAMETERS   |    16 Bytes
               +----------------------------------+
         102   |        VENDOR VERSION LEVEL      |    16 Bytes
               +----------------------------------+
                  Figure 30 -- FLOGI Request and ACC Payload Format
     
         A full description of each parameter is given in [FC-FS].
     
         This section tabulates the protocol-dependant service parameters
         supported by a fabric port attached to an iFCP gateway.
     
         The service parameters carried in the payload of an FLOGI extended
         link service request MUST be set in accordance with
         Table 4.
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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         +-----------------------------------------+---------------+
         |                                         | Fabric Login  |
         |          Service Parameter              |    Class      |
         |                                         +---+---+---+---+
         |                                         | 1 | 2 | 3 | 4 |
         +-----------------------------------------+---+---+---+---+
         | Class Validity                          | n | M | M | n |
         +-----------------------------------------+---+---+---+---+
         | Service Options                         |               |
         +-----------------------------------------+---+---+---+---+
         |   Intermix Mode                         | n | n | n | n |
         +-----------------------------------------+---+---+---+---+
         |   Stacked Connect-Requests              | n | n | n | n |
         +-----------------------------------------+---+---+---+---+
         |   Sequential Delivery                   | n | M | M | n |
         +-----------------------------------------+---+---+---+---+
         |   Dedicated Simplex                     | n | n | n | n |
         +-----------------------------------------+---+---+---+---+
         |   Camp on                               | n | n | n | n |
         +-----------------------------------------+---+---+---+---+
         |   Buffered Class 1                      | n | n | n | n |
         +-----------------------------------------+---+---+---+---+
         |   Priority                              | n | n | n | n |
         +-----------------------------------------+---+---+---+---+
         | Initiator/Recipient Control             |               |
         +-----------------------------------------+---+---+---+---+
         |   Clock synchronization ELS capable     | n | n | n | n |
         +-----------------------------------------+---+---+---+---+
         Table 4 --  FLOGI Service Parameter Settings
     
         Notes:
     
              1) "n" indicates a parameter or capability that is not
                  supported by the iFCP protocol.
     
              2) "M" indicates an applicable parameter that MUST be
                  supported by an iFCP gateway.
     
     9.       iFCP Error Detection
     
     9.1      Overview
     
         [FC-FS] defines error detection and recovery procedures.  These
         Fibre Channel-defined mechanisms continue to be available in the
         iFCP environment.
     
     9.2      Stale Frame Prevention
     
         Recovery from Fibre Channel protocol error conditions requires that
         frames associated with a failed or aborted Exchange drain from the
         fabric before Exchange resources can be safely reused.
     
     
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         Since a Fibre Channel fabric may not preserve frame order, there is
         no deterministic way to purge such frames. Instead, the fabric
         guarantees that frame the lifetime will not exceed a specific limit
         (R_A_TOV).
     
         R_A_TOV is defined in [FC-FS] as "the maximum transit time within a
         fabric to guarantee that a lost frame will never emerge from the
         fabric".  For example, a value of 2 x R_A_TOV is the minimum time
         that the originator of an ELS request or FC-4 link service  request
         must wait for the response to that request. The Fibre Channel
         default value for R_A_TOV is 10 seconds.
     
         An iFCPgateway SHALL actively enforce limits on R_A_TOV as
         described in section 9.2.1.
     
     9.2.1   Enforcing R_A_TOV Limits
     
         The R_A_TOV limit on frame lifetimes SHALL be enforced by means of
         the time stamp in the encapsulation header (see section 6.4.1) as
         described in this section.
     
         The budget for R_A_TOV SHOULD include allowances for the
         propagation delay through the gateway regions of the sending and
         receiving N_PORTs plus the propagation delay through the IP
         network.  This latter component is referred to in this
         specification as IP_TOV.
     
         IP_TOV should be set well below the value of R_A_TOV specified for
         the iFCP fabric and should be stored in the iSNS server. IP_TOV
         should be set to 50 percent of R_A_TOV.
     
         The following paragraphs describe the requirements for
         synchronizing gateway time bases and the rules for measuring and
         enforcing propagation delay limits.
     
         The protocol for synchronizing a gateway time base is SNTP
         [RFC2030]. In order to insure that all gateways are time-aligned, a
         gateway SHOULD obtain the address of an SNTP-compatible time server
         via an iSNS query.  If multiple time server addresses are returned
         by the query, the servers must be synchronized and the gateway may
         use any server in the list. Alternatively, the server may return a
         multicast group address in support of operation in Anycast mode.
         Implementation of Anycast mode is as specified in [RFC2030],
         including the precautions defined in that document.  Multicast mode
         SHOULD NOT be used.
     
         An SNTP server may use any one of the time reference sources listed
         in [RFC2030]. The resolution of the time reference MUST be 125
         milliseconds or better.
     
         Stability of the SNTP server and gateway time bases should be 100
         ppm or better.
     
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         With regard to its time base, the gateway is in either the
         Synchronized or Unsynchronized state.  When in the Unsynchronized
         state, the gateway SHALL:
     
         a)  Set the time stamp field to 0,0 for all outgoing frames
     
         b)  Ignore the time stamp field for all incoming frames.
     
         When in the synchronized state, the gateway SHALL
     
         a)  Set the time stamp field for each outgoing frame in accordance
             with the gateway's internal time base
     
         b)  Check the time stamp field of each incoming frame, following
             validation of the encapsulation header CRC as described in
             section 6.4.4.
     
         c)  If the incoming frame has a time stamp of 0,0, the receiving
             gateway SHALL NOT test the frame to determine if it is stale.
     
         d)  If the incoming frame has a non-zero time stamp, the receiving
             gateway SHALL compute the absolute value of the time in flight
             and SHALL compare it against the value of IP_TOV specified for
             the IP fabric.
     
         e)  If the result in step (d) exceeds IP_TOV, the encapsulated
             frame shall be discarded.  Otherwise, the frame shall be de-
             encapsulated as described in section 6.4.4.
     
         A gateway SHALL enter the Synchronized state upon receiving a
         successful response to an SNTP query.
     
         A gateway shall enter the Unsynchronized state:
     
         a)  Upon power up and before successful completion of an SNTP query
     
         b)  Whenever the gateway looses contact with the SNTP server such
             that the gateway's time base may no longer be in alignment with
             that of the SNTP server. The criterion for determining loss of
             contact is implementation specific.
     
         Following loss of contact, it is recommended that the gateway enter
         the Unsynchronized state when the estimated time base drift
         relative to the SNTP reference is greater than ten percent of the
         IP_TOV limit. (Assuming all timers have an accuracy of 100 ppm and
         IP_TOV equals 5 seconds, the maximum allowable loss of contact
         duration would be about 42 minutes.)
     
         In response to loss of synchronization, a gateway enforcing R_A_TOV
         limits as described in this section should abort all N_PORT login
         sessions as described in section 6.2.3.2.
     
     
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     10.      Fabric Services Supported by an iFCP implementation
     
         An iFCP gateway implementation MUST support the following fabric
         services:
     
        N_PORT ID Value           Description             Section
        ---------------           -----------             -------
          0xFF-FF-FE             F_PORT Server              10.1
     
          0xFF-FF-FD           Fabric Controller            10.2
     
          0xFF-FF-FC         Directory/Name Server          10.3
     
     
     
     
     
         In addition, an iFCP gateway MAY support the FC broadcast server
         functionality described in section 10.4.
     
     10.1     F_PORT Server
     
         The F_PORT server SHALL support the FLOGI ELS as described in
         section 8.4 as well as the following ELSs specified in [FC-FS]:
     
         a) Request for fabric service parameters (FDISC),
     
         b) Request for the link error status (RLS),
     
         c) Read Fabric Timeout Values (RTV).
     
     10.2     Fabric Controller
     
         The Fabric Controller SHALL support the following ELSs as specified
         in [FC-FS]:
     
         a) State Change Notification (SCN),
     
         b) Registered State Change Notification (RSCN),
     
         c) State Change Registration (SCR).
     
     10.3     Directory/Name Server
     
         The Directory/Name server provides a registration service allowing
         an N_PORT to record or query the database for information about
         other N_PORTs.  The services are defined in [FC-GS3].  The queries
         are issued as FC-4 transactions using the FC-CT command transport
         protocol specified in [FC-GS3].
     
     
     
     
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         In iFCP, name server requests are translated to the iSNS queries
         defined in [ISNS]. The definitions of name server objects are
         specified in [FC-GS3].
     
         The name server SHALL support record and query operations for
         directory subtype 0x02 (Name Server) and 0x03 (IP Address Server)
         and MAY support the FC-4 specific services as defined in [FC-GS3].
     
     10.4     Broadcast Server
     
         Fibre Channel frames are broadcast throughout the fabric by
         addressing them to the Fibre Channel broadcast server at well-known
         Fibre Channel address 0xFF-FF-FF.   The broadcast server then
         replicates and delivers the frame to each attached N_PORT in all
         zones to which the originating device belongs.  Only class 3
         (datagram) service is supported.
     
         In an iFCP system, the Fibre Channel broadcast function is emulated
         by means of a two-tier architecture comprised of the following
         elements:
     
         a)  A local broadcast server residing in each iFCP gateway. The
             local server distributes broadcast traffic within the gateway
             region and forwards outgoing broadcast traffic to a global
             server for distribution throughout the network.
     
         b)  A global broadcast server which re-distributes broadcast
             traffic to the local server in each participating gateway.
     
         c)  An iSNS discovery domain defining the scope over which
             broadcast traffic is propagated. The discovery domain is
             populated with a global broadcast server and the set of local
             servers it supports.
     
         The local and global broadcast servers are logical iFCP devices
         that communicate using the iFCP protocol. The servers have an
         N_PORT Network Address consisting of an iFCP portal address and an
         N_PORT I/D set to the well-known Fibre Channel address of the FC
         broadcast server (0xff-ff-ff).
     
         As noted above, an N_PORT originates a broadcast by directing frame
         traffic to the Fibre Channel broadcast server. The gateway-resident
         local server distributes a copy of the frame locally and forwards a
         copy to the global server for redistribution to the local servers
         on other gateways.  The global server MUST NOT echo a broadcast
         frame to the originating local server.
     
     10.4.1  Establishing the Broadcast Configuration
     
         The broadcast configuration is managed using facilities provided by
         the iSNS server. Specifically:
     
     
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         a)  An iSNS discovery domain is created and seeded with the network
             address of the global broadcast server N_PORT.  The global
             server is identified as such by setting the appropriate N_PORT
             entity attribute.
     
         b)  Using the management interface, each broadcast server is preset
             with the identity of the broadcast domain..
     
         During power up, each gateway SHALL invoke the iSNS service to
         register its local broadcast server in the broadcast discovery
         domain.  After registration, the local server SHALL wait for the
         global broadcast server to establish an iFCP session.
     
         The global server SHALL register with the iSNS server as follows:
     
         a) The server SHALL query the iSNS name server by attribute to
            obtain the world-wide port name of the N_PORT pre-configured to
            provide global broadcast services.
     
         b) If the world-wide port name obtained above does not correspond
            to that of the server issuing the query, the N_PORT SHALL NOT
            perform global broadcast functions for N_PORTs in that discovery
            domain.
     
         c) Otherwise, the global server N_PORT shall register with the
            discovery domain and query the iSNS server to identify all
            currently-registered local servers.
     
         d) The global broadcast server shall initiate an iFCP session with
            each local broadcast server in the domain. When a new local
            server registers, the global server SHALL receive a state change
            notification and respond by initiating an iFCP session with the
            newly added server.  The gateway SHALL obtain these
            notifications using the iSNS provisions for lossless delivery.
     
         Upon receiving the CBIND request to initiate the iFCP session, the
         local server SHALL record the world-wide port name and N_PORT
         network address of the global server.
     
     10.4.2  Broadcast Session Management
     
         After the initial broadcast session is established, the local or
         global broadcast server MAY choose to manage the session in one of
         the following ways depending on resource requirements and the
         anticipated level of broadcast traffic:
     
         a)  A server MAY keep the session open continuously.  Since
             broadcast sessions are often quiescent for long periods of
             time, the server SHOULD monitor session connectivity as
             described in section 6.2.2.2.
     
     
     
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         b)  A server MAY open the broadcast session on demand, only when
             broadcast traffic is to be sent. If the session is reopened by
             the global server, the local server SHALL replace the
             previously recorded network address of the global broadcast
             server.
     
         O
     
     11.      iFCP Security
     
     11.1     Overview
     
         iFCP relies upon the IPSec protocol suite to provide data
         confidentiality and authentication services and IKE as the key
         management protocol. Section 11.2 describes the security
         requirements arising from iFCPÆs operating environment while
         Section 11.3 describes the resulting design choices, their
         requirement levels, and how they apply to the iFCP protocol.
     
     11.2     iFCP Security Operating Requirements
     
     11.2.1  Context
     
         iFCP is a protocol designed for use by gateway devices deployed in
         enterprise data centers.  Such environments typically have security
         gateways designed to provide network security through isolation
         from public networks.  Furthermore, iFCP data may need to traverse
         security gateways in order to support SAN-to-SAN connectivity
         across public networks.
     
     11.2.2  Security Threats
     
         Communicating iFCP gateways are vulnerable to attacks. Examples of
         attacks include attempts by an adversary to:
     
         a) Acquire confidential data and identities by snooping data
            packets.
     
         b) Modify packets containing iFCP data and control messages.
     
         c) Inject new packets into the iFCP session.
     
         d) Hijack the TCP connection carrying the iFCP session.
     
         e) Launch denial of service attacks against the iFCP gateway.
     
         f) Disrupt security negotiation process.
     
         g) Impersonate a legitimate security gateway.
     
         h) Compromise communication with the iSNS server.
     
     
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         It is imperative to thwart these attacks, given that an iFCP
         gateway is the last line of defense for a whole Fibre Channel
         island, which may include several hosts and switches. To do so, the
         iFCP protocol MUST define confidentiality, authentication,
         integrity, and replay protection on a per-datagram basis.  It also
         MUST define a scalable approach to key management. Conformant
         implementations of the iFCP protocol MAY use such definitions.
     
     11.2.3  Interoperability Requirements with Security Gateways
     
         Enterprise data center networks are considered mission-critical
         facilities that must be isolated and protected from all possible
         security threats.  Such networks are usually protected by security
         gateways, which at a minimum provide a shield against denial of
         service attacks.  The iFCP security architecture must be able to
         leverage the protective services of the existing security
         infrastructure, including firewall protection, NAT and NAPT
         services, and IPSec VPN services available on existing security
         gateways.
     
     11.2.4  Statically and Dynamically Assigned IP Addresses
     
         As iFCP gateways and switches are deployed within enterprise
         networks, it is expected that, like most routers and switches,
         gateway IP addresses will be statically assigned.  Consequently,
         IKE and IPSec features focused on supporting DHCP and other dynamic
         IP address assignment capabilities for mobile hosts are not
         strictly required. Since the iFCP protocol cannot rule out the use
         of dynamically assigned IP addresses however, the security
         definitions for the iFCP protocol shall not exhibit any
         vulnerability in the case of dynamically assigned IP addresses
         (e.g., via DHCP [RFC2131]).
     
     11.2.5  Authentication Requirements
     
         iFCP is a peer-to-peer protocol.  iFCP sessions may be initiated by
         either or both peer gateways.  Consequently, bi-directional
         authentication of peer gateways MUST be provided.
     
         Fibre Channel, operating system and user identities are transparent
         to the iFCP protocol.  IKE and IPSec authentication used to protect
         iFCP traffic shall be based upon the IP addresses of the
         communicating peer gateways.
     
         iFCP gateways shall use Discovery Domain information obtained from
         the iSNS server [ISNS] to determine whether the initiating Fibre
         Channel N_PORT should be allowed access to the target N_PORT.
         N_PORT identities used in the Port Login (PLOGI) process shall be
         considered authenticated provided the PLOGI request is received
         from the remote gateway over a secure, IPSec-protected connection.
     
     
     
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         There is no requirement that the identities used in authentication
         be kept confidential.
     
     11.2.6  Confidentiality Requirements
     
         iFCP traffic may traverse insecure public networks, and therefore
         implementations MUST have per-packet encryption capabilities to
         provide confidentiality.
     
     11.2.7  Rekeying Requirements
     
         Due to the high data transfer rates and the amount of data
         involved, an iFCP gateway implementation MUST support the
         capability to rekey each phase 2 security association in time
         intervals as often as every 25 seconds. The iFCP gateway MUST
         provide the capability for forward secrecy in the rekeying process.
     
     11.2.8  Usage Requirements
     
         It must be possible for compliant iFCP implementations to
         administratively disable any and all security mechanisms.  It must
         also be possible to apply different security requirements to
         individual N_PORT login session. Implementations may elect to
         expose such fine level of control through a management interface or
         through interaction with the iSNS.
     
     11.2.9  iSNS Role
     
         iSNS [ISNS] is an invariant in all iFCP deployments.  iFCP gateways
         use iSNS for discovery services, and MAY use security policies
         configured in the iSNS database as the basis for algorithm
         negotiation in IKE. The iSNS specification defines mechanisms to
         secure communication between an iFCP gateway and iSNS server(s).
         Additionally, such specification indicates how elements of security
         policy concerning individual iFCP sessions can be retrieved from
         iSNS server(s).
     
     11.3     iFCP Security Design
     
     11.3.1  Enabling Technologies
     
         Applicable technology from IPsec and IKE is defined in the
         following suite of specifications:
     
           [RFC2401] Security Architecture for the Internet Protocol
     
           [RFC2402] IP Authentication Header
     
           [RFC2404] The Use of HMAC-SHA-1-96 Within ESP and AH
     
           [RFC2405] The ESP DES-CBC Cipher Algorithm With Explicit IV
     
     
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           [RFC2406] IP Encapsulating Security Payload
     
           [RFC2407] The Internet IP Security Domain of Interpretation for
                      ISAKMP
     
           [RFC2408] Internet Security Association and Key Management
                      Protocol (ISAKMP)
     
           [RFC2409] The Internet Key Exchange (IKE)
     
           [RFC2410] The NULL Encryption Algorithm and Its use with IPSEC
     
           [RFC2451] The ESP CBC-Mode Cipher Algorithms
     
           [RFC2709] Security Model with Tunnel-mode IPsec for NAT Domains
     
     
     
         The implementation of IPsec and IKE is required according the
         following guidelines.
     
         Support for the IP Encapsulating Security Payload (ESP) [RFC2406]
         is MANDATORY to implement. As stated in [RFC2406], the following
         authentication algorithms MUST be implemented:
     
         a) HMAC with SHA1 [RFC2404]
     
         b) NULL authentication
     
         The Advanced Encryption Standard [AES] in CBC MAC mode with
         Extended Cipher Block Chaining [XCBC] SHOULD be implemented.
     
         The following encryption algorithms MUST be implemented:
     
         a) NULL encryption [RFC2410]
     
         b) 3DES in CBC mode [RFC2451]
     
         AES counter mode encryption [AESCTR] SHOULD be implemented.
     
         Implementation of DES in CBC mode [RFC2405] is OPTIONAL. It is
         recommended that DES in CBC mode SHOULD NOT be used due to its
         inherent weakness. It is in fact well known that DES is crackable
         with modest computation resources, and so is inappropriate for use
         in any iFCP deployment scenario requiring levels of security.
     
         A conformant iFCP protocol implementation MUST implement IPsec ESP
         [RFC2406] in tunnel mode [RFC2401]. If minimizing the size of IPsec
         headers is a concern, transport mode should be supported. It shall
         be noted that transport mode continues to have a MUST implement
         requirement in those host scenarios where [RFC2401] makes it a MUST
     
     
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         (see Sections 3.3 and 4.1 of [RFC2401]).
     
     
     
     
         Regarding key management, iFCP implementations MUST support IKE
         [RFC2409] for peer authentication, negotiation of security
         associations, and key management, using the IPsec DOI. Manual
         keying MUST NOT be used since it does not provide the necessary
         keying support. According to [RFC2409], pre-shared secret key
         authentication is MANDATORY to implement, whereas certificate-based
         peer authentication using digital signatures MAY be implemented
         (see section 11.3.3 regarding the use of certificates). [RFC2409]
         defines the following requirement levels for IKE Modes:
     
         Phase-1 Main Mode MUST be implemented
     
         Phase-1 Aggressive Mode SHOULD be implemented
     
         Phase-2 Quick Mode MUST be implemented
     
         Phase-2 Quick Mode with key exchange payload MUST be implemented.
     
         Phase-1 Main Mode SHOULD NOT be used in conjunction with pre-shared
         keys, due to Main ModeÆs vulnerability to men-in-the-middle-
         attackers when group pre-shared keys are used. iFCP therefore
         requires that Aggressive Mode MUST be implemented as a valid
         alternative to Main Mode.
     
         Peer authentication using the public key encryption methods
         outlined in sections 5.2 and 5.3 of [RFC2409] SHOULD NOT be used.
     
         In all Phase 1 Modes, iFCP MUST use IP addresses as identities.
     
         The Phase 2 Quick Mode exchanges used to negotiate protection for
         the TCP connections used by iFCP MUST explicitly carry the Identity
         Payload fields (IDci and IDcr). The DOI [RFC2407] provides for
         several types of identification data.  However, when used in
         conformant iFCP security  implementations, each ID Payload MUST
         carry a single IP address and a single non-zero TCP port number,
         and MUST NOT use the IP Subnet or IP Address Range formats.  This
         allows the Phase 2 security association to correspond to specific
         TCP and iFCP connections.
     
     11.3.2  Use of IKE and IPsec
     
         Each IP address supporting iFCP communication shall be capable of
         establishing one or more Phase-1 IKE Security Associations (SA) to
         other IP addresses configured as peer iFCP gateways, using the IP
         address as the identity. Such a security association may be
         established at a gatewayÆs initialization time, or may be deferred
     
     
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         until the first TCP connection with security requirements is
         established.
     
         Unlike Phase-1 SAs, a Phase-2 SA maps to an individual TCP
         connection. It protects the setup process of the underlying TCP
         connection and all its subsequent TCP traffic. TCP connections
         protected by the phase 2 SA are either in the unbound state, or are
         bound to a specific N_PORT login session.  The creation of an IKE
         Phase-2 SA may be triggered by a policy rule supplied through a
         management interface, or by N_PORT properties registered with the
         iSNS server. Similarly, the use of Key Exchange payload in Quick
         Mode for perfect forward secrecy may be dictated through a
         management interface or by N_PORT properties registered with the
         iSNS server. This specification allows multiple implementation
         strategies, in which the establishment of an IKE Phase-2 SA occurs
         at different times. Examples of implementation strategies include:
     
         a) The definition of a unique security policy for all TCP
            connections regardless of their bound or unbound state. Thus, an
            unbound TCP connection can be bound to an N_PORT login session
            without the need to incur a new IKE Phase-2 SA.
     
         b) Multiple security policies for unbound TCP connections and
            active N_PORT login sessions. In this case, an unbound TCP
            connection becomes bound to an N_PORT login session after
            establishing a new IKE Phase-2 SA matching the new security
            policy for that N_PORT session.
     
         c) The implementation does not support unbound connections. In this
            case, a new IKE Phase-2 SA and TCP connection must be started
            from scratch anytime a new N_PORT login session is created.
     
         If the implementation does use unbound TCP connections, then an IKE
         Phase-2 SA MUST protect each of such unbound connections.
     
         As expected, the successful establishment of a IKE Phase-2 SA
         results in the creation of two uni-directional IPsec SAs fully
         qualified by the tuple <SPI, destination address, ESP>.
     
         Should a TCP connection be torn down (as opposed to joining a pool
         of unbound connections), the associated Phase-2 SA SHALL be
         terminated upon expiration of the TIME WAIT timeout value
         (according to [RFC793]).
     
         Upon receiving a Phase 1 delete message, an iFCP implementation
         SHALL tear down all the Phase 2 SAs spawned from that Phase 1 SA,
         followed by the Phase 1 SA itself. Upon receiving a Phase 2 delete
         message, iFCP implementations will behave according to the state of
         the TCP connection protected by the SA in question. If the TCP
         session was terminated (either via FINs or RSTs), then a Phase 2
         delete message SHALL terminate the IPsec SAs and any state formerly
         associated with that Phase 2 SA. If, however, the TCP session is
     
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         maintained, then a Phase 2 delete message shall trigger a new Quick
         Mode exchange.  To minimize the use of SA resources while the TCP
         connection is idle, the creation of the security association may be
         deferred until data is sent over the connection.
     
     11.3.3  Signatures and Certificate-based authentication
     
         Conformant iFCP implementations MAY support peer authentication via
         digital signatures and X.509 certificates. When X.509 certificate
         authentication is chosen within IKE, each iFCP gateway needs the
         certificate credentials of each peering iFCP gateway in order to
         establish a security association with that peer.
     
         Certificate credentials used by iFCP gateways MUST be those of the
         machine. Certificate credentials MAY be bound to the interface (IP
         Address) of the iFCP gateway used for the iFCP session, or the
         fabric WWN of the iFCP gateway itself. Since the value of a machine
         certificate is inversely proportional to the ease with which an
         attacker can obtain one under false pretenses, it is advisable that
         the machine certificate enrollment process be strictly controlled.
         For example, only administrators may have the ability to enroll a
         machine with a machine certificate. User certificates SHOULD NOT be
         used by iFCP gateways for establishment of SA's protecting iFCP
         sessions.
     
         If the gateway does not have the peer iFCP gateway's certificate
         credentials, then it can obtain them by
     
         a) Using the iSNS protocol to query for the peer gateway's
            certificate(s) stored in a trusted iSNS server, or
     
         b) Through use of the ISAKMP Certificate Request Payload (CRP)
            [RFC2408] to request the certificate(s) directly from the peer
            iFCP gateway.
     
         When certificate chains are long enough, then IKE exchanges using
         UDP as the underlying transport may yield IP fragments, which are
         known to work poorly across some intervening routers, firewalls,
         and NA(P)T boxes. As a result, the endpoints may be unable to
         establish an IPsec security association. The solutions to this
         problem are to send the end-entry machine certificate rather than
         the chain, to reduce the size of the certificate chain, to use IKE
         implementations over a reliable transport protocol (e.g., TCP)
         assisted by Path MTU discovery and code against black-holing as in
         [RFC2923], or to install network components that can properly
         handle fragments.
     
         IKE negotiators SHOULD check the pertinent Certificate Revocation
         List (CRL) [RFC2408] before accepting a certificate for use in
         IKE's authentication procedures.
     
     11.4     iSNS and iFCP Security
     
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         iFCP is required to use iSNS for discovery and management services.
         Consequently, the security of the iSNS protocol has an impact on
         the security of iFCP gateways.  In particular, the following
         threats exist:
     
         a) An attacker could alter iSNS protocol messages, so as to direct
            iFCP gateways to establish connections with rogue peer devices,
            or to weaken/eliminate IPSec protection for iFCP traffic.
     
         b) An attacker could masquerade as the real iSNS server using false
            iSNS heartbeat messages.  This could cause iFCP gateways to use
            rogue iSNS servers.
     
         c) An attacker could gain knowledge about iFCP gateways by snooping
            iSNS protocol messages.  Such information could aid an attacker
            in mounting a direct attack on iFCP gateways, such as a denial-
            of-service attack or outright physical theft.
     
         To address these threats, the following capabilities are required:
     
         a) Unicast iSNS protocol messages need to have both confidentiality
            and authentication support.
     
         b) Multicast iSNS protocol messages such as the iSNS heartbeat
            message need to have authentication support.
     
         There is no requirement that the communicating identities in iSNS
         protocol messages be kept confidential.  Specifically, the identity
         and location of the iSNS server shall not be considered
         confidential.
     
         However, in order to protect against an attacker masquerading as
         the real iSNS server, the iSNS server MUST have the capability to
         allow client gateways to authenticate broadcast or multicast
         messages such as the iSNS heartbeat.  The iSNS authentication block
         (which is identical in format to the SLP authentication block) may
         be used for this purpose.  Note that the authentication block is
         used only for iSNS broadcast or multicast messages, and SHOULD NOT
         be used in unicast iSNS messages.
     
         For protecting unicast iSNS protocol messages, iSNS servers MUST
         support the ESP protocol in tunnel mode for iFCP client gateways.
     
     11.5     Use of iSNS to Distribute Security Policy
     
         Once communication between iFCP gateways and the iSNS server have
         been secured through use of IPSec, the iFCP gateways have the
         capability to discover the security settings that they need to use
         to protect iFCP traffic.  This provides a potential scaling
         advantage over device-by-device configuration of individual
         security policies for each iFCP gateway.
     
     
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         The iSNS server stores security settings for each iFCP gateway.
         These security settings include use or non-use of IPSec, IKE, Main
         Mode, Aggressive Mode, PFS, Pre-shared Key, and certificates. These
         settings can be retrieved by peer iFCP gateways, who can then take
         the appropriate action.  For example, IKE may not be enabled for a
         particular iFCP gateway.  If a peer gateway can learn of this in
         advance by consulting the iSNS server, it will not need to waste
         time and resources attempting to initiate an IKE session with that
         iFCP gateway.
     
         Additionally, the iSNS server can store policies that are used for
         ISAKMP phase 1 and phase 2 negotiations between iFCP gateways.  The
         ISAKMP payload format includes a series of one or more proposals
         that the iFCP gateway will use when negotiating the appropriate
         IPSec policy to use to protect iFCP traffic.
     
     11.6     Minimal Security Policy for an iFCP gateway
     
         An iFCP implementation MAY be able to administratively disable
         security mechanisms for individual N_PORT login sessions. This
         implies that IKE and IPsec security associations may not be
         established for one or more of such sessions. A configuration of
         this type may be accomplished through a management interface or
         through attributes set in the iSNS server.
     
         For most IP networks, it is inappropriate to assume physical
         security, administrative security, and correct configuration of the
         network and all attached nodes (a physically isolated network in a
         test lab may be an exception).  Therefore, authentication SHOULD be
         used in order to provide a minimal assurance that connections have
         initially been opened with the intended counterpart. The minimal
         iFCP security policy thus only states that an iFCP gateway SHOULD
         authenticate its iSNS server(s) as described in [ISNS].
     
     12.      Quality of Service Considerations
     
     12.1     Minimal requirements
     
         Conforming iFCP protocol implementations SHALL correctly
         communicate gateway-to-gateway even across one or more intervening
         best-effort IP regions. The timings with which such gateway-to
         gateway communication is performed, however, will greatly depend
         upon BER, packet losses, latency, and jitter experienced throughout
         the best-effort IP regions. The higher these parameters, the higher
         will be the gap measured between iFCP observed behaviors and
         baseline iFCP behaviors (i.e., as produced by two iFCP gateways
         directly connected to one another).
     
     12.2     High-assurance
     
         It is expected that many iFCP deployments will benefit from a high
         degree of assurance regarding the behavior of intervening IP
     
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         regions, with resulting high-assurance on the overall end-to-end
         path, as directly experienced by Fibre Channel applications. Such
         assurance on the IP behaviors stems from the intervening IP regions
         supporting standard Quality-of-Service (QoS) techniques, fully
         complementary to iFCP, such as:
     
         a) Congestion avoidance by over-provisioning of the network
     
         b) Integrated Services [RFC1633] QoS
     
         c) Differentiated Services [RFC2475] QoS
     
         d) Multi-Protocol Label Switching [RFC3031].
     
            One may load an MPLS forwarding equivalence class (FEC) with QoS
            class significance, in addition to other considerations such as
            protection and diversity for the given path. The complementarity
            and compatibility of MPLS with Differentiated Services is
            explored in [MPSLDS], wherein the PHB bits are copied to the EXP
            bits of the MPLS shim header.
     
         In the most general definition, two iFCP gateways are separated by
         one or more independently managed IP regions, some of which
         implement some of the QoS solutions mentioned above. A QoS-capable
         IP region supports the negotiation and establishment of a service
         contract specifying the forwarding service through the region. Such
         contract and its negotiation rules are outside the scope of this
         document. In the case of IP regions with DiffServ QoS, the reader
         should refer to Service Level Specifications (SLS) and Traffic
         Conditioning Specifications (TCS) (as defined in [DIFTERM]). Other
         aspects of a service contract are expected to be non-technical and
         thus outside of the IETF scope.
     
         Due to the fact that Fibre Channel Class 2 and Class 3 do not
         currently support fractional bandwidth guarantees, and that iFCP is
         committed to  supporting Fibre Channel semantics, it is impossible
         for an iFCP gateway to autonomously infer bandwidth requirements
         from streaming Fibre Channel traffic. Rather, the requirements on
         bandwidth or other network parameters need to be administratively
         set into an iFCP gateway, or into the entity that will actually
         negotiate the forwarding service on the gateway's behalf. Depending
         on the QoS techniques available, the stipulation of a forwarding
         service may require interaction with network ancillary functions
         such admission control and bandwidth brokers (via RSVP or other
         signalling protocols that an IP region may accept).
     
         The administrator of a iFCP gateway may negotiate a forwarding
         service with IP region(s) for one, several, or all of an iFCP
         gateway's TCP sessions used by an iFCP gateway. Alternately, this
         responsibility may be delegated to a node downstream. Since one TCP
         connection is dedicated to each N_PORT login session , the traffic
     
     
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         in an individual N_PORT to N_PORT session can be singled out by
         iFCP-unaware network equipment as well.
     
         To render the best emulation of Fibre Channel possible over IP, it
         is anticipated that typical forwarding services will specify a
         fixed amount of bandwidth, null losses, and, to a lesser degree of
         relevance, low latency, and low jitter. For example, an IP region
         using DiffServ QoS may support SLSs of this nature by applying EF
         DSCPs to the iFCP traffic.
     
         13.             Author's Addresses
     
         Charles Monia                    Franco Travostino
         Rod Mullendore                   Director, Content
         Josh Tseng                       Internetworking Lab,
                                           Nortel Networks
         Nishan Systems                   3 Federal Street
         3850 North First Street          Billerica, MA  01821
         San Jose, CA  95134              Phone:  978-288-7708
         Phone: 408-519-3986              Email:
         Email:                           travos@nortelnetworks.com
         cmonia@nishansystems.com
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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         David Robinson                   Wayland Jeong
         Sun Microsystems                 Troika Networks
         Senior Staff Engineer            Vice President, Hardware
         M/S UNWK16-301                   Engineering
         901 San Antonio Road             2829 Townsgate Road Suite
         Palo Alto, CA  94303-4900        200
         Phone: 510-936-2337               Westlake Village, CA  91361
         Email:                            Phone: 805-370-2614
         David.Robinson@sun.com            Email:
                                           wayland@troikanetworks.com
     
         Rory Bolt                        Paul Rutherford
         Quantum/ATL                      ADIC
         Director, System Design          Vice President, Technology &
         101 Innovation Drive             Software
         Irvine, CA 92612                 1143 Willows Road N.E.
         Phone: 949-856-7760              P.O. Box 97057
         Email: rbolt@atlp.com            Redmond, WA  98073-9757
                                           Phone: 425-881-8004
                                           Email:
                                           paul.rutherford@adic.com
     
         Mark Edwards
         Senior Systems Architect
         Eurologic Development, Ltd.
         4th Floor, Howard House
         Queens Ave, UK.  BS8 1SD
         Phone: +44 (0)117 930 9600
         Email:
         medwards@eurologic.com
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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     14.      References
     
     14.1     Normative
     
         [RFC2026] Bradner, S., "The Internet Standards Process -- Revision
                 3", BCP 9, RFC 2026, October 1996.
     
         [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
                 Requirement Levels", BCP 14, RFC 2119, March 1997
     
         [FC-FS] dpANS X3.XXX-200X, "Fibre Channel Framing and Signaling
                 Interface", Revision 1.5, NCITS Project 1331-D, February
                 2001
     
         [FC-SW2] dpANS X3.XXX-2000X, "Fibre Channel Switch Fabric -2 (FC-
                 SW2)", revision 5.2, NCITS Project 1305-D, May 2001
     
         [FC-GS3] dpANS X3.XXX-200X, "Fibre Channel Generic Services -3 (FC-
                 GS3)", revision 7.01, NCITS Project 1356-D, November 2000
     
         [RFC793] Postel, J., "Transmission Control Protocol", RFC 793,
                 September, 1981
     
         [ENCAP] Weber, et-al., "FC Frame Encapsulation", draft-ietf-ips-
                 fcencapsulation-01.txt, May 2001
     
         [ISNS] Tseng, J., et-al., "iSNS Internet Storage Name Service",
                 draft-ietf-ips-04.txt, July 2001
     
         [RFC791] Postel, J., RFC 791, "The Internet Protocol", September
                 1981
     
         [RFC2401] Kent, S., Atkinson, R., RFC 2401, "Security Architecture
                 for the Internet Protocol", November 1998
     
         [RFC2402] Kent, S., Atkinson, R., RFC 2402, "IP Authentication
                 Header", November 1998
     
         [RFC2404] Glenn, R., Madson, C., "The Use of HMAC-SHA-1-96 Within
                 ESP and AH", RFC 2404, November 1998
     
         [RFC2406] Kent, S., Atkinson, R., RFC 2406, "Encapsulating Security
                 Protocol", November 1998
     
         [RFC2407] Piper, D., RFC 2407, " The Internet IP Security Domain of
                 Interpretation for ISAKMP", November 1998
     
         [RFC2408] Maughan, D., Schertler, M., Schneider, M., Turner, J.,
                 RFC 2408, "Internet Security Association and Key Management
                 Protocol (ISAKMP)" November 1998
     
     
     
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         [RFC2409] D. Harkins, D. Carrel, RFC 2409, "The Internet Key
                 Exchange (IKE)",  November 1998
     
         [RFC2410] Glenn, R., Kent, S., "The NULL Encryption Algorithm and
                 Its use with IPSEC", RFC 2410, November 1998
     
         [RFC2451] Adams, R., Pereira, R., "The ESP CBC-Mode Cipher
                 Algorithms", RFC 2451, November 1998
     
         [RFC2404] Glenn, R., Madson, C., "The Use of HMAC-SHA-1-96 Within
                 ESP and AH", RFC 2404, November 1998
     
         [RFC2410] Glenn, R., Kent, S., "The NULL Encryption Algorithm and
                 Its use with IPSEC", RFC 2410, November 1998
     
         [RFC2451] Adams, R., Pereira, R., "The ESP CBC-Mode Cipher
                 Algorithms", RFC 2451, November 1998
     
     14.2     Non-Normative
     
         [KEMCMP] Kembel, R., "Fibre Channel, A Comprehensive Introduction",
                 Northwest Learning Associates Inc., 2000, ISBN 0-931836-84-
                 0
     
         [KEMAbLP] Kembel, R., "The Fibre Channel Consultant, Arbitrated
                 Loop", Robert W. Kembel, Northwest Learning Associates,
                 2000, ISBN 0-931836-84-0
     
         [FC-AL2] dpANS X3.XXX-199X, "Fibre Channel Arbitrated Loop (FC-AL-
                 2)", revision 7.0, NCITS Project 1133D, April 1999
     
         [RFC896] Nagel, J., "Congestion Control in IP/TCP Networks", RFC
                 896, January 1984
     
         [RFC2625] Rajagopal, M., et-al., RFC 2625, "IP and ARP over Fibre
                 Channel", June 1999
     
         [RFC2131] Droms, R., "Dynamic Host Configuration Protocol", RFC
                 2131, March 1997
     
         [RFC2405] Doraswamy, N., Madson, C., "The ESP DES-CBC Cipher
                 Algorithm With Explicit IV" RFC 2405, November 1998
     
         [RFC2030] Mills, D., RFC 2030, "Simple Network Time Protocol
                 (SNTP)" Version 4, October 1996
     
         [RFC2709] Srisuresh, P., "Security Model with Tunnel-mode IPsec for
                 NAT Domains", RFC 2709, October 1999
     
         [RFC2923] Lahey, K., "TCP Problems with Path MTU Discovery", RFC
                 2923, September 2000
     
     
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         [RFC1633] Braden, R., Clark, D. and S. Shenker, "Integrated
                 Services in the Internet Architecture: an Overview", RFC
                 1633, June 1994
     
         [RFC2475] Blake, S., Black, D., Carlson, M., Davies, E., Wang, Z.
                 and W. Weiss, "An Architecture for Differentiated
                 Services", RFC 2475, December 1998
     
         [FC-FLA] TR-20-199X, "Fibre Channel Fabric Loop Attachment (FC-
                 FLA)", revision 2.7, NCITS Project 1235-D, August 1997
     
         [RFC1122] Braden, S., "Requirements for Internet Hosts --
                 Communication Layers", RFC 1122, October 1989
     
         [RFC1323] Jacobsen, V., et-al., "TCP Extensions for High
                 Performance", RFC 1323, May, 1992
     
         [AES] FIPS Publication XXX, "Advanced Encyption Standard (AES)",
                 Draft, 2001, Available from
                 http://csrc.nist.gov/publications/drafts/dfips-AES.pdf
     
         [XCBC] Black, J., Rogaway, P., "A Suggestion for Handling Arbitrary
                 Length Messages with the CBC MAC". Available from
                 http://csrc.nist.gov/encryption/modes/proposedmodes/xcbc-
                 mac/xcbc-mac-spec.pdf
     
         [AESCTR] Lipmaa, H., Rogaway, P., Wagner, D., "CTR-Mode
                 Encryption", 2001. Available from
                 http://csrc.nist.gov/encryption/modes/proposedmodes/ctr/ctr
                 -spec.pdf
     
         [RFC2405] Doraswamy, N., Madson, C., "The ESP DES-CBC Cipher
                 Algorithm With Explicit IV" RFC 2405, November 1998
     
         [RFC3031] Rosen, E., Viswanathan, A. and Callon, R., "Multi-
                 Protocol Label Switching Architecture", RFC 3031, January
                 2001
     
         [MPSLDS] F. Faucheur, L. Wu, B. Davie, S. Davari, P. Vaananen, R.
                 Krishnan, P. Cheval, J. Heinanen, "MPLS Support of
                 Differentiated Services", draft-ietf-mpls-diff-ext-09.txt,
                 April 2001.
     
         [DIFTERM] Grossman, D., "New Terminology and Clarifications for
                 Diffserv", draft-ietf-diffserv-new-terms-07.txt, December
                 2001
     
     
     
     
     
     
     
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                                    Appendix A
     
     A.       iFCP Support for Fibre Channel Link Services
     
         For reference purposes, this appendix enumerates all the Fibre
         Channel link services and the manner in which each shall be
         processed by an iFCP implementation. The iFCP processing policies
         are defined in section 8.
     
         In the following sections, the name of a link service specific to a
         particular FC-4 protocol is prefaced by a mnemonic identifying the
         protocol.
     
     A.1      Basic Link Services
     
         The basic link services are shown in the following table.
     
                                Basic Link Services
     
             Name              Description             iFCP Policy
             ----              -----------             ----------
     
           ABTS      Abort Sequence                   Transparent
           BA_ACC    Basic Accept                     Transparent
           BA_RJT    Basic Reject                     Transparent
           NOP       No Operation                     Transparent
           PRMT      Preempted                        Rejected
                                                       (Applies to
                                                       Class 1 only)
           RMC       Remove Connection                Rejected
                                                       (Applies to
                                                       Class 1 only)
     
     
     A.2      Link Services Processed Transparently
     
         The following link service requests and responses MUST be processed
         transparently as defined in section 8.
     
                Link Services Processed Transparently
     
             Name                Description
             ----                -----------
     
           ACC       Accept
           ADVC      Advise Credit
           CSR       Clock Synchronization Request
           CSU       Clock Synchronization Update
           ECHO      Echo
           ESTC      Estimate Credit
           ESTS      Establish Streaming
           FACT      Fabric Activate Alias_ID
     
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           FAN       Fabric Address Notification
           FCP_RJT   FCP FC-4 Link Service Reject
           FCP SRR   FCP Sequence Retransmission Request
           FDACT     Fabric Deactivate Alias_ID
           FDISC     Discover F_Port Service Parameters
           FLOGI     F_Port Login
           GAID      Get Alias_ID
           LCLM      Login Control List Management
           LINIT     Loop Initialize
           LIRR      Link Incident Record Registration
           LPC       Loop Port Control
           LS_RJT    Link Service Reject
           LSTS      Loop Status
           NACT      N_Port Activate Alias_ID
           NDACT     N_Port Deactivate Alias_ID
           PDISC     Discover N_Port Service Parameters
           PRLI      Process Login
           PRLO      Process Logout
           QoSR      Quality of Service Request
           RCS       Read Connection Status
           RLIR      Registered Link Incident Report
           RNC       Report Node Capability
           RNFT      Report Node FC-4 Types
           RNID      Request Node Identification Data
           RPL       Read Port List
           RPS       Read Port Status Block
           RPSC      Report Port Speed Capabilities
           RSCN      Registered State Change Notification
           RTV       Read Timeout Value
           RVCS      Read Virtual Circuit Status
           SBRP      Set Bit-error Reporting Parameters
           SCL       Scan Remote Loop
           SCN       State Change Notification
           SCR       State Change Registration
           TEST      Test
           TPLS      Test Process Login State
     
     
     A.3      iFCP-Processed Link Services
     
         The following extended and FC-4 link services are processed by the
         iFCP implementation as described in the referenced section listed
         in the table.
     
                           Special Link Services
     
               Name              Description           Section
               ----              -----------           -------
     
           ABTX         Abort Exchange                 8.3.1.1
           ADISC        Discover Address               8.3.1.2
           ADISC ACC    Discover Address Accept        8.3.1.3
     
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     iFCP Revision 8                                      January 2002
     
     
           FARP-REPLY   Fibre Channel Address          8.3.1.4
                         Resolution Protocol Reply
           FARP-REQ     Fibre Channel Address          8.3.1.5
                         Resolution Protocol Request
           LOGO         N_PORT Logout                  8.3.1.6
           PLOGI        Port Login                     8.3.1.7
           FCP REC      FCP Read Exchange Concise     8.3.2.1.1
           FCP REC ACC  FCP Read Exchange Concise     8.3.2.1.2
                         Accept
           RES          Read Exchange Status Block     8.3.1.8
           RES ACC      Read Exchange Status Block     8.3.1.9
                         Accept
           RLS          Read Link Error Status Block   8.3.1.10
           RRQ          Reinstate Recovery Qualifier   8.3.1.12
           RSI          Request Sequence Initiative    8.3.1.13
           RSS          Read Sequence Status Block     8.3.1.11
           TPRLO        Third Party Process Logout     8.3.1.14
           TPRLO ACC    Third Party Process Logout     8.3.1.15
                         Accept
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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     iFCP Revision 8                                      January 2002
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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     iFCP Revision 8                                      January 2002
     
     
     
     
     Full Copyright Statement
     
     
         "Copyright (C) The Internet Society, January 2002. All Rights
         Reserved. This document and translations of it may be copied and
         furnished to others, and derivative works that comment on or
         otherwise explain it or assist in its implmentation may be
         prepared, copied, published and distributed, in whole or in part,
         without restriction of any kind, provided that the above copyright
         notice and this paragraph are included on all such copies and
         derivative works. However, this document itself may not be modified
         in any way, such as by removing the copyright notice or references
         to the Internet Society or other Internet organizations, except as
         needed for the purpose of developing Internet standards in which
         case the procedures for copyrights defined in the Internet
         Standards process must be followed, or as required to translate it
         into languages other than English.
     
         The limited permissions granted above are perpetual and will not be
         revoked by the Internet Society or its successors or assigns.
     
         This document and the information contained herein is provided on
         an "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET
         ENGINEERING TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR
         IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF
         THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
         WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE."
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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     iFCP Revision 8                                      January 2002
     
     
     
     
     
        [RFC791] Postel, J., RFC 791, "The Internet Protocol", September
           1981
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
     
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