IPsec Working Group                                              S. Kent
Internet Draft                                          BBN Technologies
draft-ietf-ipsec-esp-v3-06.txt                                 July 2003
Expires January 2004







                IP Encapsulating Security Payload (ESP)





Status of This Memo

   This document is an Internet Draft and is subject to all provisions
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   Copyright (C) The Internet Society (2003).  All Rights Reserved.

Abstract

   This document describes an updated version of the Encapsulating
   Security Payload (ESP) protocol, which is designed to provide a mix
   of security services in IPv4 and IPv6. ESP is used to provide
   confidentiality, data origin authentication, connectionless
   integrity, an anti-replay service (a form of partial sequence
   integrity), and limited traffic flow confidentiality.  This document
   is based upon RFC 2406 (November 1998).

   Comments should be sent to Stephen Kent (kent@bbn.com).





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Table of Contents

   1. Introduction...................................................4
   2. Encapsulating Security Payload Packet Format...................6
       2.1  Security Parameters Index (SPI).........................11
       2.2  Sequence Number.........................................12
          2.2.1  Extended (64-bit) Sequence Number..................12
       2.3  Payload Data............................................13
       2.4  Padding (for Encryption)................................14
       2.5  Pad Length..............................................15
       2.6  Next Header.............................................15
       2.7  Traffic Flow Confidentiality (TFC) Padding..............16
       2.8  Integrity Check Value (ICV).............................16
   3. Encapsulating Security Protocol Processing....................17
       3.1  ESP Header Location.....................................17
          3.1.1  Transport Mode Processing..........................17
          3.1.2  Tunnel Mode Processing.............................18
       3.2  Algorithms..............................................19
          3.2.1  Encryption Algorithms..............................20
          3.2.2  Integrity Algorithms...............................20
          3.2.3  Combined Mode Algorithms...........................21
       3.3  Outbound Packet Processing..............................21
          3.3.1  Security Association Lookup........................21
          3.3.2  Packet Encryption and Integrity Check Value (ICV)
                 Calculation........................................21
              3.3.2.1 Separate Confidentiality and Integrity
                      Algorithms....................................22
              3.3.2.2 Combined Confidentiality and Integrity
                      Algorithms....................................23
          3.3.3  Sequence Number Generation.........................24
          3.3.4  Fragmentation......................................25
       3.4  Inbound Packet Processing...............................25
          3.4.1  Reassembly.........................................25
          3.4.2  Security Association Lookup........................26
          3.4.3  Sequence Number Verification.......................26
          3.4.4  Integrity Check Value Verification.................28
              3.4.4.1 Separate Confidentiality and Integrity
                      Algorithms....................................28
              3.4.4.2 Combined Confidentiality and Integrity
                      Algorithms....................................30
   4. Auditing......................................................31
   5. Conformance Requirements......................................32
   6. Security Considerations.......................................33
   7. Differences from RFC 2406.....................................33
   Acknowledgements.................................................34
   References.......................................................34
   Disclaimer.......................................................35
   Author Information...............................................35


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   Appendix -- Extended Sequence Number.............................36
   Full Copyright Statement.........................................42
















































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1.  Introduction

   This document assumes that the reader is familiar with the terms and
   concepts described in the "Security Architecture for the Internet
   Protocol" [KA98], hereafter referred to as the Security Architecture
   document.  In particular, the reader should be familiar with the
   definitions of security services offered by the Encapsulating
   Security Payload (ESP) and the IP Authentication Header (AH), the
   concept of Security Associations, the ways in which ESP can be used
   in conjunction with the Authentication Header (AH), and the different
   key management options available for ESP and AH.

   The keywords MUST, MUST NOT, REQUIRED, SHALL, SHALL NOT, SHOULD,
   SHOULD NOT, RECOMMENDED, MAY, and OPTIONAL, when they appear in this
   document, are to be interpreted as described in RFC 2119 [Bra97].

   The Encapsulating Security Payload (ESP) header is designed to
   provide a mix of security services in IPv4 and IPv6.  ESP may be
   applied alone, in combination with the IP Authentication Header (AH)
   [Ken03], or in a nested fashion, (see the Security Architecture
   document [KA98]).  Security services can be provided between a pair
   of communicating hosts, between a pair of communicating security
   gateways, or between a security gateway and a host.  For more details
   on how to use ESP and AH in various network environments, see the
   Security Architecture document [KA98].

   The ESP header is inserted after the IP header and before the next
   layer protocol header (transport mode) or before an encapsulated IP
   header (tunnel mode). These modes are described in more detail below.

   ESP can be used to provide confidentiality, data origin
   authentication, connectionless integrity, an anti-replay service (a
   form of partial sequence integrity), and (limited) traffic flow
   confidentiality. The set of services provided depends on options
   selected at the time of Security Association (SA) establishment and
   on the location of the implementation in a network topology.

   Using encryption-only for confidentiality is allowed by ESP.
   However, it should be noted that in general, this will provide
   defense only against passive attackers.  Using encryption without a
   strong integrity mechanism on top of it (either in ESP or separately
   via AH) may render the confidentiality service insecure against some
   forms of active attacks [Bel96, Kra01].  Moreover, an underlying
   integrity service, such as AH, applied before encryption does not
   necessarily protect the encryption-only confidentiality against
   active attackers [Kra01].  ESP allows encryption-only SAs because
   this may offer considerably better performance and still provide
   adequate security, e.g., when higher layer authentication/integrity


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   protection is offered independently.  However, this standard does not
   require ESP implementations to offer an encryption-only service.

   Data origin authentication and connectionless integrity are joint
   services, hereafter referred to jointly as "integrity." (This term is
   employed because, on a per-packet basis, the computation being
   performed provides connectionless integrity directly; data origin
   authentication is provided indirectly as a result of binding the key
   used to verify the integrity to the identity of the IPsec peer.
   Typically this binding is effected through the use of a shared,
   symmetric key.) Integrity-only ESP MUST be offered as a service
   selection option, e.g., it must be negotiable in SA management
   protocols and MUST be configurable via management interfaces.
   Integrity-only ESP is an attractive alternative to AH in many
   contexts, e.g., because it is faster to process and more amenable to
   pipelining in many implementations.

   Although confidentiality and integrity can be offered independently,
   ESP typically will employ both services, i.e., packets will be
   protected with regard to confidentiality and integrity. Thus there
   are three possible ESP security service combinations involving these
   services:
            - confidentiality-only (MAY be supported)
            - integrity-only (MUST be supported)
            - confidentiality and integrity (MUST be supported)

   The anti-replay service may be selected for an SA only if the
   integrity service is selected for that SA. The selection of this
   service is solely at the discretion of the receiver and thus need not
   be negotiated. However, to make use of the extended sequence number
   feature in an interoperable fashion, ESP does impose a requirement on
   SA management protocols to be able to negotiate this feature (see
   Section 2.2.1 below).

   The traffic flow confidentiality (TFC) service generally is effective
   only if ESP is employed in a fashion that conceals the ultimate
   source and destination addresses of correspondents, e.g., in tunnel
   mode between security gateways, and only if sufficient traffic flows
   between IPsec peers (either naturally or as a result of generation of
   masking traffic) to conceal the characteristics of specific,
   individual subscriber traffic flows.  (ESP may be employed as part of
   a higher layer TFC system, e.g., Onion Routing [Syverson], but such
   systems are outside the scope of this standard.) New TFC features
   present in ESP facilitate efficient generation and discarding of
   dummy traffic and better padding of real traffic, in a backwards
   compatible fashion.

   Section 7 provides a brief review of the differences between this


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   document and RFC 2406.


2.  Encapsulating Security Payload Packet Format

   The (outer) protocol header (IPv4, IPv6, or Extension) that
   immediately precedes the ESP header SHALL contain the value 50 in its
   Protocol (IPv4) or Next Header (IPv6, Extension) field (see IANA web
   page at http://www.iana.org/assignments/protocol-numbers). Figure 1
   illustrates the top level format of an ESP packet. The packet begins
   with two 4-byte fields (SPI and Sequence Number). Following these
   fields is the Payload Data, which has substructure that depends on
   the choice of encryption algorithm and mode, and on the use of TFC
   padding, which is examined in more detail later.  Following the
   Payload Data are Padding and Pad Length fields, and the Next Header
   field. The optional Integrity Check Value (ICV) field completes the
   packet.


    0                   1                   2                   3
    0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ ----
   |               Security Parameters Index (SPI)                 | ^Integ.
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |Cov-
   |                      Sequence Number                          | |erage
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | ----
   |                    Payload Data* (variable)                   | |   ^
   ~                                                               ~ |   |
   |                                                               | |Conf.
   +               +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |Cov-
   |               |     Padding (0-255 bytes)                     | |erage*
   +-+-+-+-+-+-+-+-+               +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |   |
   |                               |  Pad Length   | Next Header   | v   v
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ ------
   |         Integrity Check Value-ICV   (variable)                |
   ~                                                               ~
   |                                                               |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

               Figure 1.  Top Level Format of an ESP Packet

       * If included in the Payload field, cryptographic synchronization
         data, e.g., an Initialization Vector (IV, see Section 2.3),
         usually is not encrypted per se, although it often is referred
         to as being part of the ciphertext.

   The (transmitted) ESP Trailer consists of the Padding, Pad Length,
   and Next Header fields. Additional, implicit ESP Trailer data (which


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   is not transmitted) is included in the integrity computation, as
   described below.

   If the integrity service is selected, the integrity computation
   encompasses the SPI, Sequence Number, Payload Data, and the ESP
   Trailer (explicit and implicit).

   If the confidentiality service is selected, the ciphertext consists
   of the Payload Data (except for any cryptographic synchronization
   data that may be included) and the (explicit) ESP Trailer.

   As noted above, the Payload Data may have substructure. An encryption
   algorithm that requires an explicit Initialization Vector (IV), e.g.,
   CBC mode, often prefixes the Payload Data to be protected with that
   value. Some algorithm modes combine encryption and integrity into a
   single operation; this document refers to such algorithm modes as
   "combined mode algorithms." Accommodation of combined mode algorithms
   requires that the algorithm explicitly describe the payload
   substructure used to convey the integrity data.

   Some combined mode algorithms provide integrity only for data that is
   encrypted, while others can provide integrity for some additional
   data, data that is not encrypted for transmission. Since the SPI and
   Sequence Number fields require integrity as part of the integrity
   service, and they are not encrypted, it is necessary to ensure that
   they are afforded integrity whenever the service is selected,
   regardless of the style of combined algorithm mode employed.

   When any combined mode algorithm is employed, the algorithm itself is
   expected to return both decrypted plaintext and a pass/fail
   indication for the integrity check. For combined mode algorithms, the
   ICV that would normally appear at the end of the ESP packet (when
   integrity is selected) may be omitted. When the ICV is omitted and
   integrity is selected, it is the responsibility of the combined mode
   algorithm to encode within the payload data an ICV-equivalent means
   of verifying the integrity of the packet.

   If a combined mode algorithm offers integrity only to data that is
   encrypted, it will be necessary to replicate the SPI and Sequence
   Number as part of the Payload Data.

   Finally, a new provision is made to insert padding for traffic flow
   confidentiality after the Payload Data and before the ESP trailer.
   Figure 2 illustrates this substructure for Payload Data. (Note: This
   diagram shows bits-on-the-wire.  So even if extended sequence numbers
   are being used, only 32 bits of the Sequence Number will be
   transmitted (see Section 2.2.1).



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     0                   1                   2                   3
     0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   |               Security Parameters Index (SPI)                 |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   |                      Sequence Number                          |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+---
   |                    IV (optional)                              | ^ p
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | a
   |                    Rest of Payload Data  (variable)           | | y
   ~                                                               ~ | l
   |                                                               | | o
   +               +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | a
   |               |         TFC Padding * (optional, variable)    | v d
   +-+-+-+-+-+-+-+-+         +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+---
   |                         |        Padding (0-255 bytes)        |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   |                               |  Pad Length   | Next Header   |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   |         Integrity Check Value-ICV   (variable)                |
   ~                                                               ~
   |                                                               |
   +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+

               Figure 2. Substructure of Payload Data

         * If tunnel mode is being used, then the IPsec implementation
           can add Traffic Flow Confidentiality (TFC) padding (see
           Section 2.4)  after the Payload Data and before the Padding
           (0-255 bytes) field.

   If a combined algorithm mode is employed, the explicit ICV shown in
   Figures 1 and 2 may be omitted (see Section 3.3.2.2 below). Since
   algorithms and modes are fixed when an SA is established, the
   detailed format of ESP packets for a given SA (including the Payload
   Data substructure) is fixed, for all traffic on the SA.

   The tables below refer to the fields in the preceding Figures and
   illustrate how several categories of algorithmic options, each with a
   different processing model, affect the fields noted above. The
   processing details are described in later sections.









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           Table 1. Separate Encryption and Integrity Algorithms

                                             What    What    What
                            # of     Requ'd  Encrypt Integ    is
                            bytes      [1]   Covers  Covers  Xmtd
                            ------   ------  ------  ------  ------
    SPI                        4        M              Y     plain
    Seq# (low order bits)      4        M              Y     plain       p
                                                                  ------ a
    IV                      variable    O              Y     plain     | y
    IP datagram [2]         variable  M or D    Y      Y     cipher[3] |-l
    TFC padding [4]         variable    O       Y      Y     cipher[3] | o
                                                                  ------ a
    Padding                  0-255      M       Y      Y     cipher[3]   d
    Pad Length                 1        M       Y      Y     cipher[3]
    Next Header                1        M       Y      Y     cipher[3]
    Seq# (high order bits)     4     if ESN [5]        Y     not xmtd
    ICV Padding             variable if need           Y     not xmtd
    ICV                     variable   M [6]                 plain

            [1] M = mandatory; O = optional; D = dummy
            [2] If tunnel mode -> IP datagram
                If transport mode -> next header and data
            [3] ciphertext if encryption has been selected
            [4] Can be used only if payload specifies its "real" length
            [5] See section 2.2.1
            [6] mandatory if a separate integrity algorithm is used























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                  Table 2. Combined Mode Algorithms

                                             What    What    What
                            # of     Requ'd  Encrypt Integ    is
                            bytes      [1]   Covers  Covers  Xmtd
                            ------   ------  ------  ------  ------
    SPI                        4        M                    plain
    Seq# (low order bits)      4        M                    plain    p
                                                               ---    a
    IV                      variable    O              Y     plain  | y
    IP datagram [2]         variable  M or D    Y      Y     cipher |-l
    TFC padding [3]         variable    O       Y      Y     cipher | o
                                                                  --- a
    Padding                  0-255      M       Y      Y     cipher   d
    Pad Length                 1        M       Y      Y     cipher
    Next Header                1        M       Y      Y     cipher
    Seq# (high order bits)     4     if ESN [4]        Y     [5]
    ICV Padding             variable if need           Y     [5]
    ICV                     variable    O [6]                plain

            [1] M = mandatory; O = optional; D = dummy
            [2] If tunnel mode -> IP datagram
                If transport mode ->next header and data
            [3] Can be used only if payload specifies its "real" length
            [4] See section 2.2.1
            [5] The algorithm choices determines whether these are
                transmitted, but in either case, the result is invisible
                to ESP
            [6] The algorithm spec determines whether this field is
                present

   The following subsections describe the fields in the header format.
   "Optional" means that the field is omitted if the option is not
   selected, i.e., it is present in neither the packet as transmitted
   nor as formatted for computation of an Integrity Check Value (ICV,
   see Section 2.7).  Whether or not an option is selected is determined
   as part of Security Association (SA) establishment.  Thus the format
   of ESP packets for a given SA is fixed, for the duration of the SA.
   In contrast, "mandatory" fields are always present in the ESP packet
   format, for all SAs.

   Note: All of the cryptographic algorithms used in IPsec expect their
   input in canonical network byte order (see Appendix in RFC 791) and
   generate their output in canonical network byte order.  IP packets
   are also transmitted in network byte order.





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2.1  Security Parameters Index (SPI)

   The SPI is an arbitrary 32-bit value that is used by a receiver to
   identify the SA to which an incoming packet is bound. The SPI field
   is mandatory.

   For a unicast SA, the SPI can be used by itself to specify an SA, or
   it may be used in conjunction with the IPsec protocol type (in this
   case ESP). Since the SPI value is generated by the receiver for a
   unicast SA, whether the value is sufficient to identify an SA by
   itself, or whether it must be used in conjunction with the IPsec
   protocol value is a local matter. This mechanism for mapping inbound
   traffic to unicast SAs MUST be supported by all ESP implementations.

   If an IPsec implementation supports multicast, then it MUST support
   multicast SAs using the following algorithm for mapping inbound IPsec
   datagrams to SAs. (Implementations that support only unicast traffic
   need not implement this demultiplexing algorithm.)  Each entry in the
   Security Association Database (SAD) [KA98] must indicate whether the
   SA lookup makes use of the source and destination IP addresses, in
   addition to the SPI. (For multicast SAs, the protocol field is not
   employed for SA lookups.)  Nominally, this indication can be
   represented by two bits, one associated with the source IP address
   and the other for the destination IP address. A "1" value for each
   bit indicates the need to match against the corresponding address
   field as part of the SA lookup process. Thus, for example, unicast
   SAs would have both bits set to zero, since neither the source nor
   destination IP address is used for SA matching. (Only the SPI, and,
   optionally, the protocol field are employed.) For multicast methods
   that rely only on the destination address to specify a multicast
   group, only the second bit would be set to "1," implying the need to
   use the destination address plus the SPI to determine the appropriate
   SA. For multicast methods (e.g., SSM [HC03]) that also require the
   source address to identify a multicast group, both bits would be set
   to "1."  (There is no current requirement to support SA mapping based
   on the source address but not the destination address, thus one of
   the possible four values is not meaningful.) The indication whether
   source and destination address matching is required to map inbound
   IPsec traffic to SAs MUST be set either as a side effect of manual SA
   configuration or via negotiation using an SA management protocol,
   e.g., IKE.

   The set of SPI values in the range 1 through 255 are reserved by the
   Internet Assigned Numbers Authority (IANA) for future use; a reserved
   SPI value will not normally be assigned by IANA unless the use of the
   assigned SPI value is specified in an RFC. The SPI value of zero (0)
   is reserved for local, implementation-specific use and MUST NOT be
   sent on the wire. (For example, a key management implementation might


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   use the zero SPI value to mean "No Security Association Exists"
   during the period when the IPsec implementation has requested that
   its key management entity establish a new SA, but the SA has not yet
   been established.)


2.2  Sequence Number

   This unsigned 32-bit field contains a counter value that increases by
   one for each packet sent, i.e., a per-SA packet sequence number. For
   a unicast SA or a single-sender multicast SA, the sender MUST
   increment this field for every transmitted packet. Sharing an SA
   among multiple senders is permitted, though generally not
   recommended. ESP provides no means of synchronizing packet counters
   among multiple senders or meaningfully managing a receiver packet
   counter and window in the context of multiple senders. Thus, for a
   multi-sender SA, the anti-replay features of ESP are not available
   (see Sections 3.3.3 and 3.4.3.)

   The field is mandatory and MUST always be present even if the
   receiver does not elect to enable the anti-replay service for a
   specific SA.  Processing of the Sequence Number field is at the
   discretion of the receiver, but all ESP implementations MUST be
   capable of performing the Sequence Number processing described in
   Sections 3.3.3 and 3.4.3. Thus the sender MUST always transmit this
   field, but the receiver need not act upon it (see the discussion of
   Sequence Number Verification in the "Inbound Packet Processing"
   section (3.4.3) below).

   The sender's counter and the receiver's counter are initialized to 0
   when an SA is established. (The first packet sent using a given SA
   will have a Sequence Number of 1; see Section 3.3.3 for more details
   on how the Sequence Number is generated.)  If anti-replay is enabled
   (the default), the transmitted Sequence Number must never be allowed
   to cycle.  Thus, the sender's counter and the receiver's counter MUST
   be reset (by establishing a new SA and thus a new key) prior to the
   transmission of the 2^32nd packet on an SA.

2.2.1  Extended (64-bit) Sequence Number

   To support high-speed IPsec implementations, extended sequence
   numbers SHOULD be implemented, as an extension to the current, 32-bit
   sequence number field. Use of an Extended Sequence Number (ESN) MUST
   be negotiated by an SA management protocol. (The ESN feature is
   applicable to multicast as well as unicast SAs.)

   The ESN facility allows use of a 64-bit sequence number for an SA.
   (See Appendix on "Extended (64-bit) Sequence Numbers" for details.)


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   Only the low order 32 bits of the sequence number are transmitted in
   the plaintext ESP header of each packet, thus minimizing packet
   overhead. The high order 32 bits are maintained as part of the
   sequence number counter by both transmitter and receiver and are
   included in the computation of the ICV (if the integrity service is
   selected).  If a separate integrity algorithm is employed, the high
   order bits are included in the implicit ESP trailer, but are not
   transmitted, analogous to integrity algorithm padding bits. If a
   combined mode algorithm is employed, the algorithm choice determines
   whether the high order ESN bits are transmitted, or are included
   implicitly in the computation. See Section 3.3.2.2 for processing
   details.


2.3  Payload Data

   Payload Data is a variable-length field containing data (from the
   original IP packet) described by the Next Header field. The Payload
   Data field is mandatory and is an integral number of bytes in length.
   If the algorithm used to encrypt the payload requires cryptographic
   synchronization data, e.g., an Initialization Vector (IV), then this
   data is carried explicitly in the Payload field, but it is not called
   out as a separate field in ESP, i.e., the transmission of an explicit
   IV is invisible to ESP. (See Figure 2.)  Any encryption algorithm
   that requires such explicit, per-packet synchronization data MUST
   indicate the length, any structure for such data, and the location of
   this data as part of an RFC specifying how the algorithm is used with
   ESP.  (Typically the IV immediately precedes the ciphertext. See
   Figure 2.)  If such synchronization data is implicit, the algorithm
   for deriving the data MUST be part of the algorithm definition RFC.
   (If included in the Payload field, cryptographic synchronization
   data, e.g., an Initialization Vector (IV), usually is not encrypted
   per se (see Tables 1 and 2), although it sometimes is referred to as
   being part of the ciphertext.)

   Note that the beginning of the next layer protocol header MUST be
   aligned relative to the beginning of the ESP header as follows. For
   IPv4, this alignment is a multiple of 4 bytes. For IPv6, the
   alignment is a multiple of 8 bytes.

   With regard to ensuring the alignment of the (real) ciphertext in the
   presence of an IV, note the following:
         o For some IV-based modes of operation, the receiver treats
           the IV as the start of the ciphertext, feeding it into the
           algorithm directly.  In these modes, alignment of the start
           of the (real) ciphertext is not an issue at the receiver.

         o In some cases, the receiver reads the IV in separately from


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           the ciphertext.  In these cases, the algorithm specification
           MUST address how alignment of the (real) ciphertext is to be
           achieved.

2.4  Padding (for Encryption)

   Two primary factors require or motivate use of the Padding field.
         o If an encryption algorithm is employed that requires the
           plaintext to be a multiple of some number of bytes, e.g.,
           the block size of a block cipher, the Padding field is used
           to fill the plaintext (consisting of the Payload Data,
           Padding, Pad Length and Next Header fields) to the size
           required by the algorithm.

         o Padding also may be required, irrespective of encryption
           algorithm requirements, to ensure that the resulting
           ciphertext terminates on a 4-byte boundary. Specifically,
           the Pad Length and Next Header fields must be right aligned
           within a 4-byte word, as illustrated in the ESP packet
           format figures above, to ensure that the ICV field (if
           present) is aligned on a 4-byte boundary.


   Padding beyond that required for the algorithm or alignment reasons
   cited above, could be used to conceal the actual length of the
   payload, in support of TFC. However, the Padding field described is
   too limited to be effective for TFC and thus should not be used for
   that purpose.  Instead, the separate mechanism described below (see
   Section 2.7) should be used when TFC is required.

   The sender MAY add 0 to 255 bytes of padding.  Inclusion of the
   Padding field in an ESP packet is optional, subject to the
   requirements noted above, but all implementations MUST support
   generation and consumption of padding.

         o For the purpose of ensuring that the bits to be encrypted
           are a multiple of the algorithm's blocksize (first bullet
           above), the padding computation applies to the Payload Data
           exclusive of any IV, but including the ESP trailer
           fields. If a combined algorithm mode requires transmission
           of the SPI and Sequence Number to effect integrity, e.g.,
           replication of the SPI and Sequence Number in the Payload
           Data, then the replicated versions of these data items, and
           any associated, ICV-equivalent data, are included in the
           computation of the pad length. (If the ESN option is
           selected, the high order 32 bits of the ESN also would enter
           into the computation, if the combined mode algorithm
           requires their transmission for integrity.)


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         o For the purposes of ensuring that the ICV is aligned on a
           4-byte boundary (second bullet above), the padding
           computation applies to the Payload Data inclusive of the IV,
           the Pad Length, and Next Header fields. If a combined mode
           algorithm is used, any replicated data and ICV-equivalent
           data are included in the Payload Data covered by the padding
           computation.

   If an encryption or combined mode algorithm imposes constraints on
   the values of the bytes used for padding they MUST be specified by
   the RFC defining how the algorithm is employed with ESP. If the
   algorithm requires checking of the values of the bytes used for
   padding, this too MUST be specified in that RFC.

2.5  Pad Length

   The Pad Length field indicates the number of pad bytes immediately
   preceding it in the Padding field.  The range of valid values is 0 to
   255, where a value of zero indicates that no Padding bytes are
   present. As noted above, this does not include any TFC padding bytes.
   The Pad Length field is mandatory.

2.6  Next Header

   The Next Header is a mandatory, 8-bit field that identifies the type
   of data contained in the Payload Data field, e.g., an IPv4 or IPv6
   packet, or a next layer header and data.  The value of this field is
   chosen from the set of IP Protocol Numbers defined on the web page of
   the IANA, e.g., a value of 4 indicates IPv4, a value of 41 indicates
   IPv6 and a value of 6 indicates TCP.

   To facilitate the rapid generation and discarding of the padding
   traffic in support of traffic flow confidentiality (see 2.4), the
   protocol value 59 (which means "no next header") MUST be used to
   designate a "dummy" packet. A transmitter MUST be capable of
   generating dummy packets marked with this value in the next protocol
   field, and a receiver MUST be prepared to discard such packets,
   without indicating an error. All other ESP header and trailer fields
   (SPI, Sequence number, Padding, Pad Length, Next Header, and ICV)
   MUST be present in dummy packets, but the plaintext portion of the
   payload, other than this Next Header field, need not be well-formed,
   e.g., the rest of the Payload Data may consist of only random bytes.
   Dummy packets are discarded without prejudice.






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2.7  Traffic Flow Confidentiality (TFC) Padding

   As noted above, the Padding field is limited to 255 bytes in length.
   This generally will not be adequate to hide traffic characteristics
   relative to traffic flow confidentiality requirements. An optional
   field, within the payload data, is provided specifically to address
   the TFC requirement.

   An IPsec implementation SHOULD be capable of padding traffic by
   adding bytes after the end of the Payload Data, prior to the
   beginning of the Padding field.  However, this padding (hereafter
   referred to as TFC padding) can be added only if the "Payload Data"
   field contains a specification of the length of the IP datagram,
   e.g., if tunnel mode is employed. This information will enable the
   receiver to discard the TFC padding, because the true length of the
   Payload Data will be known. (ESP trailer fields are located by
   counting back from the end of the ESP packet.)  Accordingly, if TFC
   padding is added, the field containing the specification of the
   length of the IP datagram MUST NOT be modified to reflect this
   padding. No requirements for the value of this padding are
   established by this standard.

   TFC padding takes advantage of an intrinsic feature of IP, i.e.,
   other data may be present in a buffer delivered to an IP interface,
   beyond the packet length indicated by the IP total length field.
   Thus, in tunnel mode, a compliant IP stack at a receiver should
   ignore this padding. In this sense, existing IPsec implementations
   could have made use of this capability previously, in a transparent
   fashion. However, because receivers may not have been prepared to
   deal with this padding, the SA management protocol MUST negotiate
   this service prior to a transmitter employing it, to ensure backward
   compatibility.  Combined with the convention described in section 2.6
   above, about the use of protocol ID 59, an ESP implementation is
   capable of generating dummy and real packets that exhibit much
   greater length variability, in support of TFC.

2.8  Integrity Check Value (ICV)

   The Integrity Check Value is a variable-length field computed over
   the ESP header, Payload, and ESP trailer fields. Implicit ESP trailer
   fields (integrity padding and high order ESN bits, if applicable) are
   included in the ICV computation. The ICV field is optional.  It is
   present only if the integrity service is selected and is provided by
   either a separate integrity algorithm or a combined mode algorithm
   that uses an ICV. The length of the field is specified by the
   integrity algorithm selected and associated with the SA. The
   integrity algorithm specification MUST specify the length of the ICV
   and the comparison rules and processing steps for validation.


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3.  Encapsulating Security Protocol Processing

3.1  ESP Header Location

   ESP may be employed in two ways: transport mode or tunnel mode.

3.1.1  Transport Mode Processing

   In transport mode, ESP is inserted after the IP header and before a
   next layer protocol, e.g., TCP, UDP, ICMP, etc. In the context of
   IPv4, this translates to placing ESP after the IP header (and any
   options that it contains), but before the next layer protocol.  (If
   AH is also applied to a packet, it is applied to the ESP header,
   Payload, ESP Trailer and ICV, if present.) (Note that the term
   "transport" mode should not be misconstrued as restricting its use to
   TCP and UDP.)  The following diagram illustrates ESP transport mode
   positioning for a typical IPv4 packet, on a "before and after" basis.
   (This and subsequent diagrams in this section show the ICV field, the
   presence of which is a function of the security services and the
   algorithm/mode selected.)

                  BEFORE APPLYING ESP
             ----------------------------
       IPv4  |orig IP hdr  |     |      |
             |(any options)| TCP | Data |
             ----------------------------

                  AFTER APPLYING ESP
             -------------------------------------------------
       IPv4  |orig IP hdr  | ESP |     |      |   ESP   | ESP|
             |(any options)| Hdr | TCP | Data | Trailer | ICV|
             -------------------------------------------------
                                 |<---- encryption ---->|
                           |<-------- integrity ------->|

   In the IPv6 context, ESP is viewed as an end-to-end payload, and thus
   should appear after hop-by-hop, routing, and fragmentation extension
   headers.  Destination options extension header(s) could appear
   before, after, or both before and after the ESP header depending on
   the semantics desired. However, since ESP protects only fields after
   the ESP header, it generally will be desirable to place the
   destination options header(s) after the ESP header. The following
   diagram illustrates ESP transport mode positioning for a typical IPv6
   packet.





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                      BEFORE APPLYING ESP
             ---------------------------------------
       IPv6  |             | ext hdrs |     |      |
             | orig IP hdr |if present| TCP | Data |
             ---------------------------------------

                      AFTER APPLYING ESP
             ---------------------------------------------------------
       IPv6  | orig |hop-by-hop,dest*,|   |dest|   |    | ESP   | ESP|
             |IP hdr|routing,fragment.|ESP|opt*|TCP|Data|Trailer| ICV|
             ---------------------------------------------------------
                                          |<--- encryption ---->|
                                      |<------ integrity ------>|

                 * = if present, could be before ESP, after ESP, or both

   Note that in transport mode, for "bump-in- the-stack" or "bump-in-
   the-wire" implementations, as defined in the Security Architecture
   document, inbound and outbound IP fragments may require an IPsec
   implementation to perform extra IP reassembly/fragmentation in order
   to both conform to this specification and provide transparent IPsec
   support.  Special care is required to perform such operations within
   these implementations when multiple interfaces are in use.

3.1.2  Tunnel Mode Processing

   In tunnel mode, the "inner" IP header carries the ultimate (IP)
   source and destination addresses, while an "outer" IP header contains
   the addresses of the IPsec "peers", e.g., addresses of security
   gateways.  In tunnel mode, ESP protects the entire inner IP packet,
   including the entire inner IP header.  The position of ESP in tunnel
   mode, relative to the outer IP header, is the same as for ESP in
   transport mode.  The following diagram illustrates ESP tunnel mode
   positioning for typical IPv4 and IPv6 packets.
















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                 BEFORE APPLYING ESP
            ----------------------------
      IPv4  |orig IP hdr  |     |      |
            |(any options)| TCP | Data |
            ----------------------------

                 AFTER APPLYING ESP

            -----------------------------------------------------------
      IPv4  | new IP hdr* |     | orig IP hdr*  |   |    | ESP   | ESP|
            |(any options)| ESP | (any options) |TCP|Data|Trailer| ICV|
            -----------------------------------------------------------
                                |<--------- encryption --------->|
                          |<------------- integrity ------------>|


                      BEFORE APPLYING ESP
            ---------------------------------------
      IPv6  |             | ext hdrs |     |      |
            | orig IP hdr |if present| TCP | Data |
            ---------------------------------------

                     AFTER APPLYING ESP

            ------------------------------------------------------------
      IPv6  | new* |new ext |   | orig*|orig ext |   |    | ESP   | ESP|
            |IP hdr| hdrs*  |ESP|IP hdr| hdrs *  |TCP|Data|Trailer| ICV|
            ------------------------------------------------------------
                                |<--------- encryption ---------->|
                            |<------------ integrity ------------>|

            * = if present, construction of outer IP hdr/extensions and
                modification of inner IP hdr/extensions is discussed in
                the Security Architecture document.

3.2  Algorithms

   The mandatory-to-implement algorithms for use with ESP are described
   in a separate RFC, to facilitate updating the algorithm requirements
   independently from the protocol per se. Additional algorithms, beyond
   those mandated for ESP, MAY be supported.  Note that although both
   confidentiality and integrity are optional, at least one of these
   services MUST be selected hence both algorithms MUST NOT be
   simultaneously NULL.






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3.2.1  Encryption Algorithms

   The encryption algorithm employed to protect an ESP packet is
   specified by the SA via which the packet is transmitted/received.
   Because IP packets may arrive out of order, and not all packets may
   arrive (packet loss) each packet must carry any data required to
   allow the receiver to establish cryptographic synchronization for
   decryption.  This data may be carried explicitly in the payload
   field, e.g., as an IV (as described above), or the data may be
   derived from the plaintext portions of the (outer IP or ESP) packet
   header. (Note that if plaintext header information is used to derive
   an IV, that information may become security critical and thus the
   protection boundary associated with the encryption process may grow.
   For example, if one were to use the ESP Sequence Number to derive an
   IV, the Sequence Number generation logic (hardware or software) would
   have to be evaluated as part of the encryption algorithm
   implementation. In the case of FIPS 140-2, this could significantly
   extend the scope of a cryptographic module evaluation.)  Since ESP
   makes provision for padding of the plaintext, encryption algorithms
   employed with ESP may exhibit either block or stream mode
   characteristics.  Note that since encryption (confidentiality) MAY be
   an optional service (e.g., integrity-only ESP), this algorithm MAY be
   "NULL" [KA98]

   To allow an ESP implementation to compute the encryption padding
   required by a block mode encryption algorithm, and to determine the
   MTU impact of the algorithm, the RFC for each encryption algorithm
   used with ESP must specify the padding modulus for the algorithm.

3.2.2  Integrity Algorithms

   The integrity algorithm employed for the ICV computation is specified
   by the SA via which the packet is transmitted/received. As was the
   case for encryption algorithms, any integrity algorithm employed with
   ESP must make provisions to permit processing of packets that arrive
   out of order and to accommodate packet loss. The same admonition
   noted above applies to use of any plaintext data to facilitate
   receiver synchronization of integrity algorithms. Note that since the
   integrity service MAY be optional, this algorithm may be "NULL".

   To allow an ESP implementation to compute any implicit integrity
   algorithm padding required, the RFC for each algorithm used with ESP
   must specify the padding modulus for the algorithm.







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3.2.3 Combined Mode Algorithms

   If a combined mode algorithm is employed, both confidentiality and
   integrity services are provided. As was the case for encryption
   algorithms, a combined mode algorithm must make provisions for per-
   packet cryptographic synchronization, to permit decryption of packets
   that arrive out of order and to accommodate packet loss. The means by
   which a combined mode algorithm provides integrity for the payload,
   and for the SPI and (Extended) Sequence Number fields, may vary for
   different algorithm choices. In order to provide a uniform, algorithm
   independent approach to invocation of combined mode algorithms, no
   payload substructure is defined. For example, the SPI and Sequence
   Number fields might be replicated within the ciphertext envelope and
   an ICV may be appended to the ESP Trailer. None of these details
   should be observable externally.

   To allow an ESP implementation to determine the MTU impact of a
   combined mode algorithm, the RFC for each algorithm used with ESP
   must specify a (simple) formula that yields encrypted payload size,
   as a function of the plaintext payload and sequence number sizes.

3.3  Outbound Packet Processing

   In transport mode, the sender encapsulates the next layer protocol
   information between the ESP header and the ESP trailer fields, and
   retains the specified IP header (and any IP extension headers in the
   IPv6 context).  In tunnel mode, the outer and inner IP
   header/extensions can be inter-related in a variety of ways.  The
   construction of the outer IP header/extensions during the
   encapsulation process is described in the Security Architecture
   document.

3.3.1  Security Association Lookup

   ESP is applied to an outbound packet only after an IPsec
   implementation determines that the packet is associated with an SA
   that calls for ESP processing.  The process of determining what, if
   any, IPsec processing is applied to outbound traffic is described in
   the Security Architecture document.

3.3.2  Packet Encryption and Integrity Check Value (ICV) Calculation

   In this section, we speak in terms of encryption always being applied
   because of the formatting implications.  This is done with the
   understanding that "no confidentiality" is offered by using the NULL
   encryption algorithm (RFC 2410).  There are several algorithmic
   options.



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3.3.2.1 Separate Confidentiality and Integrity Algorithms

   If separate confidentiality and integrity algorithms are employed,
   the Sender proceeds as follows:
         1. Encapsulate (into the ESP Payload field):
                 - for transport mode -- just the original next layer
                   protocol information.
                 - for tunnel mode -- the entire original IP datagram.

         2. Add any necessary padding -- Optional TFC padding and
            (encryption) Padding

         3. Encrypt the result using the key, encryption algorithm,
            and algorithm mode specified for the SA and using any
            required cryptographic synchronization data.
                 - If explicit cryptographic synchronization data,
                   e.g., an IV, is indicated, it is input to the
                   encryption algorithm per the algorithm specification
                   and placed in the Payload field.
                 - If implicit cryptographic synchronization data is
                   employed, it is constructed and input to the
                   encryption algorithm as per the algorithm
                   specification.
                 - If integrity is selected, encryption is performed
                   first, before the integrity algorithm is applied,
                   and the encryption does not encompass the ICV
                   field. This order of processing facilitates rapid
                   detection and rejection of replayed or bogus packets
                   by the receiver, prior to decrypting the packet,
                   hence potentially reducing the impact of denial of
                   service attacks.  It also allows for the possibility
                   of parallel processing of packets at the receiver,
                   i.e., decryption can take place in parallel with
                   integrity checking.  Note that since the ICV is not
                   protected by encryption, a keyed integrity algorithm
                   must be employed to compute the ICV.

         4. Compute the ICV over the ESP packet minus the ICV field.
            Thus the ICV computation encompasses the SPI, Sequence
            Number, Payload Data, Padding (if present), Pad Length, and
            Next Header. (Note that the last 4 fields will be in
            ciphertext form, since encryption is performed first.) If
            the ESN option is enabled for the SA, it the high-order 32
            bits of the Sequence Number are appended after the Next
            Header field for purposes of this computation, but are not
            transmitted.

   For some integrity algorithms, the byte string over which the ICV


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   computation is performed must be a multiple of a block size specified
   by the algorithm. If the length of ESP packet (as described above)
   does not match the block size requirements for the algorithm,
   implicit padding MUST be appended to the end of the ESP packet. (This
   padding is added after the Next Header field, or after the high-order
   32 bits of the Sequence Number, if ESN is selected.) The padding
   octets MUST have a value of zero.  The block size (and hence the
   length of the padding) is specified by the integrity algorithm
   specification. This padding is not transmitted with the packet. Note
   that MD5 and SHA-1 are viewed as having a 1-byte block size because
   of their internal padding conventions.

3.3.2.2 Combined Confidentiality and Integrity Algorithms


   If a combined confidentiality/integrity algorithm is employed, the
   Sender proceeds as follows:
         1. Encapsulate into the ESP Payload Data field:
                 - for transport mode -- just the original next layer
                   protocol information.
                 - for tunnel mode -- the entire original IP datagram.

         2. Add any necessary padding -- includes optional TFC padding
            and (encryption) Padding.

         3. Encrypt and integrity protect the result using the key
            and combined mode algorithm specified for the SA and using
            any required cryptographic synchronization data.
                 - If explicit cryptographic synchronization data,
                   e.g., an IV, is indicated, it is input to the
                   combined mode algorithm per the algorithm
                   specification and placed in the Payload field.
                 - If implicit cryptographic synchronization data is
                   employed, it is constructed and input to the
                   encryption algorithm as per the algorithm
                   specification.
                 - The Sequence Number (or Extended Sequence Number, as
                   appropriate) and the SPI are inputs to the
                   algorithm, as they must be included in the integrity
                   check computation. The means by which these values
                   are included in this computation are a function of
                   the combined mode algorithm employed and thus not
                   specified in this standard.
                 - The (explicit) ICV field MAY be a part of the ESP
                   packet format when a combined mode algorithm is
                   employed.  If one is not used, an analogous field
                   usually will be a part of the ciphertext payload. The
                   location of any integrity fields, and the means by


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                   which the Sequence Number and SPI are included in the
                   integrity computation MUST be defined in an RFC that
                   defines the use of the combined mode algorithm with
                   ESP.

3.3.3  Sequence Number Generation

   The sender's counter is initialized to 0 when an SA is established.
   The sender increments the Sequence Number (or ESN) for this SA and
   inserts the low-order 32 bits of the value into the Sequence Number
   field. Thus the first packet sent using a given SA will contain a
   Sequence Number of 1.

   If anti-replay is enabled (the default), the sender checks to ensure
   that the counter has not cycled before inserting the new value in the
   Sequence Number field.  In other words, the sender MUST NOT send a
   packet on an SA if doing so would cause the Sequence Number to cycle.
   An attempt to transmit a packet that would result in Sequence Number
   overflow is an auditable event. The audit log entry for this event
   SHOULD include the SPI value, current date/time, Source Address,
   Destination Address, and (in IPv6) the cleartext Flow ID.

   The sender assumes anti-replay is enabled as a default, unless
   otherwise notified by the receiver (see 3.4.3) or if the SA was
   configured using manual key management.  Thus typical behavior of an
   ESP implementation calls for the sender to establish a new SA when
   the Sequence Number (or ESN) cycles, or in anticipation of this value
   cycling.

   If anti-replay is disabled (as noted above), the sender does not need
   to monitor or reset the counter, e.g., in the case of manual key
   management (see Section 5).  However, the sender still increments the
   counter and when it reaches the maximum value, the counter rolls over
   back to zero. (This behavior is recommended for multi-sender,
   multicast SAs, unless anti-replay mechanisms outside the scope of
   this standard are negotiated between the sender and receiver.)

   If ESN (see Appendix) is selected, only the low order 32 bits of the
   sequence number are transmitted in the Sequence Number field,
   although both sender and receiver maintain full 64-bit ESN counters.
   The high order 32 bits are included in the integrity check in an
   algorithm/mode-specific fashion, e.g., the high order 32 bits may be
   appended after the Next Header field when a separate integrity
   algorithm is employed.






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3.3.4  Fragmentation

   If necessary, fragmentation is performed after ESP processing within
   an IPsec implementation.  Thus, transport mode ESP is applied only to
   whole IP datagrams (not to IP fragments).  An IP packet to which ESP
   has been applied may itself be fragmented by routers en route, and
   such fragments must be reassembled prior to ESP processing at a
   receiver.  In tunnel mode, ESP is applied to an IP packet, which may
   be a fragment of an IP datagram.  For example, a security gateway or
   a "bump-in-the-stack" or "bump-in-the-wire" IPsec implementation (as
   defined in the Security Architecture document) may apply tunnel mode
   ESP to such fragments.

   NOTE: For transport mode -- As mentioned at the end of Section 3.1.1,
   bump- in-the-stack and bump-in-the-wire implementations may have to
   first reassemble a packet fragmented by the local IP layer, then
   apply IPsec, and then fragment the resulting packet.

   NOTE: For IPv6 -- For bump-in-the-stack and bump-in-the-wire
   implementations, it will be necessary to examine all the extension
   headers to determine if there is a fragmentation header and hence
   that the packet needs reassembling prior to IPsec processing.

   Fragmentation, whether performed by an IPsec implementation or by
   routers along the path between IPsec peers, significantly reduces
   performance. Moreover, the requirement for an ESP receiver to accept
   fragments for reassembly creates denial of service vulnerabilities.
   Thus an ESP implementation MAY choose to not support fragmentation
   and may mark transmitted packets with the DF bit, to facilitate PMTU
   discovery. In any case, an ESP implementation MUST support generation
   of ICMP PMTU messages (or equivalent internal signaling for native
   host implementations) to minimize the likelihood of fragmentation.
   Details of the support required for MTU management are contained in
   the Security Architecture document.

3.4  Inbound Packet Processing

3.4.1  Reassembly

   If required, reassembly is performed prior to ESP processing. If a
   packet offered to ESP for processing appears to be an IP fragment,
   i.e., the OFFSET field is non-zero or the MORE FRAGMENTS flag is set,
   the receiver MUST discard the packet; this is an auditable event. The
   audit log entry for this event SHOULD include the SPI value,
   date/time received, Source Address, Destination Address, Sequence
   Number, and (in IPv6) the Flow ID.

   NOTE: For packet reassembly, the current IPv4 spec does NOT require


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   either the zeroing of the OFFSET field or the clearing of the MORE
   FRAGMENTS flag.  In order for a reassembled packet to be processed by
   IPsec (as opposed to discarded as an apparent fragment), the IP code
   must do these two things after it reassembles a packet.

3.4.2  Security Association Lookup

   Upon receipt of a packet containing an ESP Header, the receiver
   determines the appropriate (unidirectional) SA via lookup in the SAD.
   For a unicast SA, this determination is based on the SPI or the SPI
   plus protocol field, as described in Section 2.1.  If an
   implementation supports multicast traffic, the destination address is
   also employed in the lookup (in addition to the SPI), and the sender
   address also may be employed, as described in Section 2.1. (This
   process is described in more detail in the Security Architecture
   document.) The SAD entry for the SA also indicates whether the
   Sequence Number field will be checked, whether 32 or 64-bit Sequence
   Numbers are employed for the SA, whether the (explicit) ICV field
   should be present (and if so, its size), and it will specify the
   algorithms and keys to be employed for decryption and ICV computation
   (if applicable).

   If no valid Security Association exists for this packet, the receiver
   MUST discard the packet; this is an auditable event.  The audit log
   entry for this event SHOULD include the SPI value, date/time
   received, Source Address, Destination Address, Sequence Number, and
   (in IPv6) the cleartext Flow ID.

   (Note that SA management traffic, e.g., IKE packets, does not need to
   be processed based on SPI, i.e., one can demultiplex this traffic
   separately, e.g., based on Next Protocol and Port fields.)

3.4.3  Sequence Number Verification

   All ESP implementations MUST support the anti-replay service, though
   its use may be enabled or disabled by the receiver on a per-SA basis.
   This service MUST NOT be enabled unless the ESP integrity service
   also is enabled for the SA, since otherwise the Sequence Number field
   has not been integrity protected. Anti-replay is applicable to
   unicast as well as multicast SAs. However, this standard specifies no
   mechanisms for providing anti-replay for a multi-sender SA (unicast
   or multicast). In the absence of negotiation (or manual
   configuration) of an anti-replay mechanism for such an SA, it is
   recommended that sender and receiver checking of the sequence number
   for the SA be disabled (via negotiation or manual configuration), as
   noted below.

   If the receiver does not enable anti-replay for an SA, no inbound


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   checks are performed on the Sequence Number. However, from the
   perspective of the sender, the default is to assume that anti-replay
   is enabled at the receiver. To avoid having the sender do unnecessary
   sequence number monitoring and SA setup (see section 3.3.3), if an SA
   establishment protocol is employed, the receiver SHOULD notify the
   sender, during SA establishment, if the receiver will not provide
   anti-replay protection.

   If the receiver has enabled the anti-replay service for this SA, the
   receive packet counter for the SA MUST be initialized to zero when
   the SA is established.  For each received packet, the receiver MUST
   verify that the packet contains a Sequence Number that does not
   duplicate the Sequence Number of any other packets received during
   the life of this SA.  This SHOULD be the first ESP check applied to a
   packet after it has been matched to an SA, to speed rejection of
   duplicate packets.

   ESP permits two-stage verification of packet sequence numbers. This
   capability is important whenever an ESP implementation (typically the
   cryptographic module portion thereof) is not capable of performing
   decryption and/or integrity checking at the same rate as the
   interface(s) to unprotected networks. If the implementation is
   capable of such "line rate" operation, then it is not necessary to
   perform the preliminary verification stage described below.

   The preliminary Sequence Number check is effected utilizing the
   Sequence Number value in the ESP Header and is performed prior to
   integrity checking and decryption. If this preliminary check fails,
   the packet is discarded, thus avoiding the need for any cryptographic
   operations by the receiver. If the preliminary check is successful,
   the receiver cannot yet modify it's local counter, since the
   integrity of the Sequence Number has not been verified at this point.

   Duplicates are rejected through the use of a sliding receive window.
   How the window is implemented is a local matter, but the following
   text describes the functionality that the implementation must
   exhibit.

   The "right" edge of the window represents the highest, validated
   Sequence Number value received on this SA. Packets that contain
   Sequence Numbers lower than the "left" edge of the window are
   rejected. Packets falling within the window are checked against a
   list of received packets within the window.  If the ESN option is
   selected for an SA, only the low-order 32 bits of the sequence number
   are explicitly transmitted, but the receiver employs the full
   sequence number computed using the high-order 32 bits for the
   indicated SA (from his local counter) when checking the received
   Sequence Number against the receive window. In constructing the full


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   sequence number, if the low order 32 bits carried in the packet are
   lower in value than the low order 32 bits of the receiver's sequence
   number, the receiver assumes that the high order 32 bits have been
   incremented, moving to a new sequence number subspace.  (This
   algorithm accommodates gaps in reception for a single SA as large as
   2**32-1 packets. If a larger gap occurs, additional, heuristic checks
   for resynchronization of the receiver sequence number counter MAY be
   employed, as described in the Appendix.)

   If the received packet falls within the window and is not a
   duplicate, or if the packet is to the right of the window, and if a
   separate integrity algorithm is employed, then the receiver proceeds
   to integrity verification. If a combined mode algorithm is employed,
   the integrity check is performed along with decryption. In either
   case, if the integrity check fails, the receiver MUST discard the
   received IP datagram as invalid; this is an auditable event.  The
   audit log entry for this event SHOULD include the SPI value,
   date/time received, Source Address, Destination Address, the Sequence
   Number, and (in IPv6) the Flow ID.  The receive window is updated
   only if the integrity verification succeeds. (If a combined mode
   algorithm is being used, then the integrity protected Sequence Number
   must also match the Sequence Number used for anti-replay protection.)

   A minimum window size of 32 packets MUST be supported when 32-bit
   sequence numbers are employed; a window size of 64 is preferred and
   SHOULD be employed as the default. Another window size (larger than
   the minimum) MAY be chosen by the receiver.  (The receiver does NOT
   notify the sender of the window size.)  The receive window size
   should be increased for higher speed environments, irrespective of
   assurance issues. Values for minimum and recommended receive window
   sizes for very high speed (e.g., multi-gigabit/second) devices are
   not specified by this standard.

3.4.4  Integrity Check Value Verification

   As with outbound processing, there are several options for inbound
   processing, based on features of the algorithms employed.

3.4.4.1 Separate Confidentiality and Integrity Algorithms

   If separate confidentiality and integrity algorithms are employed
   processing proceeds as follows:,
         1. If integrity has been selected, the receiver computes the
            ICV over the ESP packet minus the ICV, using the specified
            integrity algorithm and verifies that it is the same as the
            ICV carried in the packet.  Details of the computation are
            provided below.



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            If the computed and received ICV's match, then the datagram
            is valid, and it is accepted.  If the test fails, then the
            receiver MUST discard the received IP datagram as invalid;
            this is an auditable event.  The log data SHOULD include the
            SPI value, date/time received, Source Address, Destination
            Address, the Sequence Number, and (for IPv6) the cleartext
            Flow ID.

            Implementation Note:

            Implementations can use any set of steps that results in the
            same result as the following set of steps.  Begin by removing
            and saving the ICV field. Next check the overall length of
            the ESP packet minus the ICV field. If implicit padding is
            required, based on the blocksize of the integrity algorithm,
            append zero-filled bytes to the end of the ESP packet
            directly after the Next Header field, or afer the high-order
            32 bits of the Sequence Number if ESN is selected. Perform
            the ICV computation and compare the result with the saved
            value, using the comparison rules defined by the algorithm
            specification.

         2. The receiver decrypts the ESP Payload Data, Padding, Pad
            Length, and Next Header using the key, encryption algorithm,
            algorithm mode, and cryptographic synchronization data (if
            any), indicated by the SA. As in section 3.3.2, we speak
            here in terms of encryption always being applied because of
            the formatting implications.  This is done with the
            understanding that "no confidentiality" is offered by using
            the NULL encryption algorithm (RFC 2410).

                 - If explicit cryptographic synchronization data, e.g.,
                   an IV, is indicated, it is taken from the Payload
                   field and input to the decryption algorithm as per
                   the algorithm specification.

                 - If implicit cryptographic synchronization data is
                   indicated, a local version of the IV is constructed
                   and input to the decryption algorithm as per the
                   algorithm specification.

         3. The receiver processes any Padding as specified in the
            encryption algorithm specification. If the default padding
            scheme (see Section 2.4) has been employed, the receiver
            SHOULD inspect the Padding field before removing the padding
            prior to passing the decrypted data to the next layer.

         4. The receiver checks the Next Header field. If the value is


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            "59" (no next header), the (dummy) packet is discarded
            without further processing.

         5. The receiver reconstructs the original IP datagram from:
                 - for transport mode -- outer IP header plus the
                   original next layer protocol information in the ESP
                   Payload field
                 - for tunnel mode -- the entire IP datagram in the ESP
                   Payload field.

            The exact steps for reconstructing the original datagram
            depend on the mode (transport or tunnel) and are described
            in the Security Architecture document.  At a minimum, in an
            IPv6 context, the receiver SHOULD ensure that the decrypted
            data is 8-byte aligned, to facilitate processing by the
            protocol identified in the Next Header field. This
            processing "discards" any (optional) TFC padding that has
            been added for traffic flow confidentiality. (If present,
            this will have been inserted after the IP datagram (or
            transport-layer frame) and before the Padding field (see
            section 2.4).)

   If integrity checking and encryption are performed in parallel,
   integrity checking MUST be completed before the decrypted packet is
   passed on for further processing.  This order of processing
   facilitates rapid detection and rejection of replayed or bogus
   packets by the receiver, prior to decrypting the packet, hence
   potentially reducing the impact of denial of service attacks.

   Note: If the receiver performs decryption in parallel with integrity
   checking, care must be taken to avoid possible race conditions with
   regard to packet access and extraction of the decrypted packet.

3.4.4.2 Combined Confidentiality and Integrity Algorithms

   If a combined confidentiality and integrity algorithm is employed,
   then the receiver proceeds as follows:

         1. Decryps and integrity check the ESP Payload Data, Padding,
            Pad Length, and Next Header, using the key, algorithm,
            algorithm mode, and cryptographic synchronization data (if
            any), indicated by the SA. The SPI from the ESP header, and
            the (receiver) packet counter value (adjusted as required
            from the processing described in Section 3.4.3) are inputs
            to this algorithm, as they are required for the integrity
            check.

                 - If explicit cryptographic synchronization data, e.g.,


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                   an IV, is indicated, it is taken from the Payload
                   field and input to the decryption algorithm as per
                   the algorithm specification.

                 - If implicit cryptographic synchronization data, e.g.,
                   an IV, is indicated, a local version of the IV is
                   constructed and input to the decryption algorithm as
                   per the algorithm specification.

         2. If the integrity check performed by the combined mode
            algorithm fails, the receiver MUST discard the received IP
            datagram as invalid; this is an auditable event.  The log
            data SHOULD include the SPI value, date/time received,
            Source Address, Destination Address, the Sequence Number,
            and (in IPv6) the cleartext Flow ID.

         3. Process any Padding as specified in the encryption algorithm
            specification, if the algorithm has not already done so.

         4. The receiver checks the Next Header field. If the value is
            "59" (no next header), the (dummy) packet is discarded
            without further processing.

         5. Extract the original IP datagram (tunnel mode) or
            transport-layer frame (transport mode) from the ESP Payload
            Data field.  This implicitly discards any (optional) padding
            that has been added for traffic flow confidentiality. (If
            present, the TFC padding will have been inserted after the
            IP payload and before the Padding field (see section 2.4).)

4.  Auditing

   Not all systems that implement ESP will implement auditing.  However,
   if ESP is incorporated into a system that supports auditing, then the
   ESP implementation MUST also support auditing and MUST allow a system
   administrator to enable or disable auditing for ESP.  For the most
   part, the granularity of auditing is a local matter.  However,
   several auditable events are identified in this specification and for
   each of these events a minimum set of information that SHOULD be
   included in an audit log is defined.

         - No valid Security Association exists for a session.  The
           audit log entry for this event SHOULD include the SPI value,
           date/time received, Source Address, Destination Address,
           Sequence Number, and (for IPv6) the cleartext Flow ID.

         - A packet offered to ESP for processing appears to be an IP
           fragment, i.e., the OFFSET field is non-zero or the MORE


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           FRAGMENTS flag is set.  The audit log entry for this event
           SHOULD include the SPI value, date/time received, Source
           Address, Destination Address, Sequence Number, and (in IPv6)
           the Flow ID.

         - Attempt to transmit a packet that would result in Sequence
           Number overflow.  The audit log entry for this event SHOULD
           include the SPI value, current date/time, Source Address,
           Destination Address, Sequence Number, and (for IPv6) the
           cleartext Flow ID.

         - The received packet fails the anti-replay checks. The audit
           log entry for this event SHOULD include the SPI value,
           date/time received, Source Address, Destination Address, the
           Sequence Number, and (in IPv6) the Flow ID.

         - The integrity check fails.  The audit log entry for this
           event SHOULD include the SPI value, date/time received,
           Source Address, Destination Address, the Sequence Number, and
           (for IPv6) the Flow ID.

   Additional information also MAY be included in the audit log for each
   of these events, and additional events, not explicitly called out in
   this specification, also MAY result in audit log entries.  There is
   no requirement for the receiver to transmit any message to the
   purported sender in response to the detection of an auditable event,
   because of the potential to induce denial of service via such action.

5.  Conformance Requirements

   Implementations that claim conformance or compliance with this
   specification MUST implement the ESP syntax and processing described
   here for unicast traffic, and MUST comply with all additional packet
   processing requirements levied by the Security Architecture document
   [KA98].  Additionally, if an implementation claims to support
   multicast traffic, it MUST comply with the additional requirements
   specified for support of such traffic.  If the key used to compute an
   ICV is manually distributed, correct provision of the anti-replay
   service would require correct maintenance of the counter state at the
   sender, until the key is replaced, and there likely would be no
   automated recovery provision if counter overflow were imminent. Thus
   a compliant implementation SHOULD NOT provide anti-replay service in
   conjunction with SAs that are manually keyed.

   The mandatory-to-implement algorithms for use with ESP are described
   in a separate document, to facilitate updating the algorithm
   requirements independently from the protocol per se. Additional
   algorithms, beyond those mandated for ESP, MAY be supported.


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   Since use of encryption in ESP is optional, support for the "NULL"
   encryption algorithm also is required to maintain consistency with
   the way ESP services are negotiated. Support for the confidentiality-
   only service version of ESP is optional. If an implementation offers
   this service, it MUST also support the negotiation of the NULL
   integrity algorithm. NOTE that while integrity and encryption may
   each be "NULL" under the circumstances noted above, they MUST NOT
   both be "NULL".

6.  Security Considerations

   Security is central to the design of this protocol, and thus security
   considerations permeate the specification.  Additional security-
   relevant aspects of using the IPsec protocol are discussed in the
   Security Architecture document.

7.  Differences from RFC 2406

   This document differs from RFC 2406 in a number of significant ways.

         o Confidentiality-only service -- now a MAY, not a MUST.
         o SPI -- modified to specify a uniform algorithm for SAD lookup
           for unicast and multicast SAs, covering a wider range of
           multicast technologies. For unicast, the SPI may be used
           alone to select an SA, or may be combined with the protocol,
           at the option of the receiver.  For multicast SAs, the SPI is
           combined with the destination address, and optionally the
           source address, to select an SA.
         o Sequence number -- added a new option for a 64-bit sequence
           number for very high-speed communications. Clarified sender
           and receiver processing requirements for multicast SAs and
           multi-sender SAs.
         o Payload data -- broadened model to accommodate combined mode
           algorithms.
         o Padding for improved traffic flow confidentiality -- added
           requirement to be able to add bytes after the end of the IP
           Payload, prior to the beginning of the Padding field.
         o Next Header -- added requirement to be able to generate and
           discard dummy padding packets (Next Header = 59)
         o ICV -- broadened model to accommodate combined mode
           algorithms.
         o Algorithms -- Added combined confidentiality mode algorithms.
         o Moved references to mandatory algorithms to a separate
           document.
         o Inbound and Outbound packet processing -- there are now two
           paths -- (1) separate confidentiality and integrity
           algorithms, (2) combined confidentiality mode
           algorithms. Because of the addition of combined mode


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           algorithms, the encryption/decryption and integrity sections
           have been combined for both inbound and outbound packet
           processing.

Acknowledgements

   The author would like to acknowledge the contributions of Ran
   Atkinson, who played a critical role in initial IPsec activities, and
   who authored the first series of IPsec standards: RFCs 1825-1827.
   Karen Seo deserves special thanks for providing help in the editing
   of this and the previous version of this specification.  The author
   also would like to thank the members of the IPSEC and MSEC working
   groups who have contributed to the development of this protocol
   specification.

References

Normative


   [Bra97]   Bradner, S., "Key words for use in RFCs to Indicate
             Requirement Level", BCP 14, RFC 2119, March 1997.

   [KA98]    Kent, S., and R. Atkinson, "Security Architecture for the
             Internet Protocol", RFC 2401, November 1998.


Informative


   [Bel96]   Steven M. Bellovin, "Problem Areas for the IP Security
             Protocols", Proceedings of the Sixth Usenix Unix Security
             Symposium, July, 1996.

   [HC03]    Holbrook, H., and Cain, B., "Source Specific Multicast for
             IP", Internet Draft, draft-ietf-ssm-arch-01.txt, November
             3, 2002.

   [HC98]    Harkins, D., and D. Carrel, "The Internet Key Exchange
             (IKE)", RFC 2409, November 1998.

   [Ken03]   Kent, S., "IP Authentication Header", RFC ???, ??? 2003.

   [Kra01]   Krawczyk, H., "The Order of Encryption and Authentication
             for Protecting Communications (Or: How Secure Is SSL?)",
             CRYPTO' 2001.




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Disclaimer

   The views and specification here are those of the authors and are not
   necessarily those of their employers.  The authors and their
   employers specifically disclaim responsibility for any problems
   arising from correct or incorrect implementation or use of this
   specification.


Author Information

   Stephen Kent
   BBN Technologies
   10 Moulton Street
   Cambridge, MA  02138
   USA

   Phone: +1 (617) 873-3988
   EMail: kent@bbn.com































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Appendix -- Extended (64-bit) Sequence Numbers

A1. Overview

   This appendix describes an extended sequence number (ESN) scheme for
   use with IPsec (ESP and AH) that employs a 64-bit sequence number,
   but in which only the low order 32 bits are transmitted as part of
   each packet.  It covers both the window scheme used to detect
   replayed packets and the determination of the high order bits of the
   sequence number that are used both for replay rejection and for
   computation of the ICV.  It also discusses a mechanism for handling
   loss of synchronization relative to the (not transmitted) high order
   bits.

A2.  Anti-Replay Window

   The receiver will maintain an anti-replay window of size W.  This
   window will limit how far out of order a packet can be, relative to
   the packet with the highest sequence number that has been
   authenticated so far.  (No requirement is established for minimum or
   recommended sizes for this window, beyond the 32 and 64-packet values
   already established for 32-bit sequence number windows.  However, it
   is suggested that an implementer scale these values consistent with
   the interface speed supported by an implementation that makes use of
   the ESN option.  Also, the algorithm described below assumes that the
   window is no greater than 2^31 packets in width.)  All 2^32 sequence
   numbers associated with any fixed value for the high order 32 bits
   (Seqh) will hereafter be called a sequence number subspace.  The
   following table lists pertinent variables and their definitions.

        Var.   Size
        Name  (bits)            Meaning
        ----  ------  ---------------------------
        W       32    Size of window
        T       64    Highest sequence number authenticated so far,
                      upper bound of window
          Tl      32    Lower 32 bits of T
          Th      32    Upper 32 bits of T
        B       64    Lower bound of window
          Bl      32    Lower 32 bits of B
          Bh      32    Upper 32 bits of B
        Seq     64    Sequence number of received packet
          Seql    32    Lower 32 bits of Seq
          Seqh    32    Upper 32 bits of Seq

   When performing the anti-replay check, or when determining which high
   order bits to use to authenticate an incoming packet, there are two
   cases:


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     + Case A: Tl >= (W - 1).  In this case, the window is within one
                               sequence number subspace.  (See Figure 1)
     + Case B: Tl < (W - 1).   In this case, the window spans two
                               sequence number subspaces.  (See Figure 2)

   In the figures below, the bottom line ("----") shows two consecutive
   sequence number subspaces, with zero's indicating the beginning of
   each subspace.  The two shorter lines above it show the higher order
   bits that apply.  The "====" represents the window.  The "****"
   represents future sequence numbers, i.e., those beyond the current
   highest sequence number authenticated (ThTl).

        Th+1                         *********

        Th               =======*****

              --0--------+-----+-----0--------+-----------0--
                         Bl    Tl            Bl
                                        (Bl+2^32) mod 2^32

                            Figure 1 -- Case A


        Th                           ====**************

        Th-1                      ===

              --0-----------------+--0--+--------------+--0--
                                  Bl    Tl            Bl
                                                 (Bl+2^32) mod 2^32

                            Figure 2 -- Case B

A2.1.  Managing and Using the Anti-Replay Window

   The anti-replay window can be thought of as a string of bits where
   `W' defines the length of the string.  W = T - B + 1 and cannot
   exceed 2^32 - 1 in value.  The bottom-most bit corresponds to B and
   the top-most bit corresponds to T and each sequence number from Bl
   through Tl is represented by a corresponding bit.  The value of the
   bit indicates whether or not a packet with that sequence number has
   been received and authenticated, so that replays can be detected and
   rejected.

   When a packet with a 64-bit sequence number (Seq) greater than T is
   received and validated,




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      + B is increased by (Seq - T)
      + (Seq - T) bits are dropped from the low end of the window
      + (Seq - T) bits are added to the high end of the window
      + The top bit is set to indicate that a packet with that sequence
        number has been received and authenticated
      + The new bits between T and the top bit are set to indicate that
        no packets with those sequence numbers have been received yet.
      + T is set to the new sequence number

   In checking for replayed packets,

      + Under Case A: If Seql >= Bl (where Bl = Tl - W + 1) AND
        Seql <= Tl, then check the corresponding bit in the window to see
        if this Seql has already been seen.  If yes, reject the packet.
        If no, perform integrity check (see Section 2.2. below for
        determination of SeqH).

      + Under Case B: If Seql >= Bl (where Bl = Tl - W + 1) OR
        Seql <= Tl, then check the corresponding bit in the window to see
        if this Seql has already been seen.  If yes, reject the packet.
        If no, perform integrity check (see Section 2.2. below for
        determination of Seqh).

A2.2.  Determining the Higher Order Bits (Seqh) of the Sequence Number

   Since only `Seql' will be transmitted with the packet, the receiver
   must deduce and track the sequence number subspace into which each
   packet falls, i.e., determine the value of Seqh.  The following
   equations define how to select Seqh under "normal" conditions; see
   Section 3 for a discussion of how to recover from extreme packet
   loss.

      + Under Case A (Figure 1):
        If Seql >= Bl (where Bl = Tl - W + 1), then Seqh = Th
        If Seql <  Bl (where Bl = Tl - W + 1), then Seqh = Th + 1

      + Under Case B (Figure 2):
        If Seql >= Bl (where Bl = Tl - W + 1), then Seqh = Th - 1
        If Seql <  Bl (where Bl = Tl - W + 1), then Seqh = Th

A2.3.  Pseudo-code Example

   The following pseudo-code illustrates the above algorithms for anti-
   replay and integrity checks.  The values for `Seql', `Tl', `Th' and
   `W', are 32-bit unsigned integers.  Arithmetic is mod 2^32.





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        If (Tl >= W - 1)                            Case A
            If (Seql >= Tl - W + 1)
                Seqh = Th
                If (Seql <= Tl)
                    If (pass replay check)
                        If (pass integrity check)
                            Set bit corresponding to Seql
                            Pass the packet on
                        Else reject packet
                    Else reject packet
                Else
                    If (pass integrity check)
                        Tl = Seql (shift bits)
                        Set bit corresponding to Seql
                        Pass the packet on
                    Else reject packet
            Else
                Seqh = Th + 1
                If (pass integrity check)
                    Tl = Seql (shift bits)
                    Th = Th + 1
                    Set bit corresponding to Seql
                    Pass the packet on
                Else reject packet
        Else                                    Case B
            If (Seql >= Tl - W + 1)
                Seqh = Th - 1
                If (pass replay check)
                    If (pass integrity check)
                        Set the bit corresponding to Seql
                        Pass packet on
                    Else reject packet
                Else reject packet
            Else
                If (Seql <= Tl)
                    If (pass replay check)
                        If (pass integrity check)
                            Set the bit corresponding to Seql
                            Pass packet on
                        Else reject packet
                    Else reject packet
                Else
                    If (pass integrity check)
                        Tl = Seql (shift bits)
                        Set the bit corresponding to Seql
                        Pass packet on
                    Else reject packet



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A3.  Handling Loss of Synchronization due to Significant Packet Loss

   If there is an undetected packet loss of 2^32 or more consecutive
   packets on a single SA, then the transmitter and receiver will lose
   synchronization of the high order bits, i.e., the equations in
   Section 2.2. will fail to yield the correct value.  Unless this
   problem is detected and addressed, subsequent packets on this SA will
   fail authentication checks and be discarded.  The following procedure
   SHOULD be implemented by any IPsec (ESP or AH) implementation that
   supports the ESN option.

   Note that this sort of extended traffic loss seems unlikely to occur
   if any significant fraction of the traffic on the SA in question is
   TCP, because the source would fail to receive ACKs and would stop
   sending long before 2^32 packets had been lost.  Also, for any bi-
   directional application, even ones operating above UDP, such an
   extended outage would likely result in triggering some form of
   timeout.  However, a unidirectional application, operating over UDP
   might lack feedback that would cause automatic detection of a loss of
   this magnitude, hence the motivation to develop a recovery method for
   this case.

   The solution we've chosen was selected to:

     + minimize the impact on normal traffic processing

     + avoid creating an opportunity for a new denial of service attack
       such as might occur by allowing an attacker to force diversion of
       resources to a resynchronization process.

     + limit the recovery mechanism to the receiver -- since anti-replay
       is a service only for the receiver, and the transmitter generally
       is not aware of whether the receiver is using sequence numbers in
       support of this optional service, it is preferable for recovery
       mechanisms to be local to the receiver.  This also allows for
       backwards compatibility.

A3.1.  Triggering Resynchronization

   For each SA, the receiver records the number of consecutive packets
   that fail authentication.  This count is used to trigger the
   resynchronization process which should be performed in the background
   or using a separate processor.  Receipt of a valid packet on the SA
   resets the counter to zero.  The value used to trigger the
   resynchronization process is a local parameter.  There is no
   requirement to support distinct trigger values for different SAs,
   although an implementer may choose to do so.



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A3.2.  Resynchronization Process

   When the above trigger point is reached, a "bad" packet is selected
   for which authentication is retried using successively larger values
   for the upper half of the sequence number (Seqh).  These values are
   generated by incrementing by one for each retry.  The number of
   retries should be limited, in case this is a packet from the "past"
   or a bogus packet.  The limit value is a local parameter.  (Because
   the Seqh value is implicitly placed after the ESP (or AH) payload, it
   may be possible to optimize this procedure by executing the integrity
   algorithm over the packet up to the end point of the payload, then
   compute different candidate ICV's by varying the value of Seqh.)
   Successful authentication of a packet via this procedure resets the
   consecutive failure count and sets the value of T to that of the
   received packet.

   This solution requires support only on the part of the receiver,
   thereby allowing for backwards compatibility.  Also, because
   resynchronization efforts would either occur in the background or
   utilize an additional processor, this solution does not impact
   traffic processing and a denial of service attack cannot divert
   resources away from traffic processing.




























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Full Copyright Statement

   Copyright (C) The Internet Society (2003).  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 implementation 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
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   document itself may not be modified in any way, such as by removing
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   The limited permissions granted above are perpetual and will not be
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   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
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   HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
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Expires January 2004





















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