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RFC1624 - Computation of the Internet Checksum via Incremental Update

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Network Working Group                             A. Rijsinghani, Editor
Request for Comments: 1624                 Digital Equipment Corporation
Updates: 1141                                                   May 1994
Category: Informational

                  Computation of the Internet Checksum
                         via Incremental Update

Status of this Memo

   This memo provides information for the Internet community.  This memo
   does not specify an Internet standard of any kind.  Distribution of
   this memo is unlimited.

Abstract

   This memo describes an updated technique for incremental computation
   of the standard Internet checksum.  It updates the method described
   in RFC1141.

Table of Contents

   1. IntrodUCtion ..........................................  1
   2. Notation and Equations ................................  2
   3. Discussion ............................................  2
   4. Examples ..............................................  3
   5. Checksum verification by end systems ..................  4
   6. Historical Note .......................................  4
   7. Acknowledgments .......................................  5
   8. Security Considerations ...............................  5
   9. Conclusions ...........................................  5
   10. Author's Address .....................................  5
   11. References ...........................................  6

1.  Introduction

   Incremental checksum update is useful in speeding up several
   types of operations routinely performed on IP packets, such as
   TTL update, IP fragmentation, and source route update.

   RFC1071, on pages 4 and 5, describes a procedure to
   incrementally update the standard Internet checksum.  The
   relevant discussion, though comprehensive, was not complete.
   Therefore, RFC1141 was published to replace this description
   on Incremental Update.  In particular, RFC1141 provides a
   more detailed eXPosure to the procedure described in RFC1071.
   However, it computes a result for certain cases that differs

   from the one oBTained from scratch (one's complement of one's
   complement sum of the original fields).

   For the sake of completeness, this memo briefly highlights key
   points from RFCs 1071 and 1141.  Based on these discussions,
   an updated procedure to incrementally compute the standard
   Internet checksum is developed and presented.

2.  Notation and Equations

   Given the following notation:

          HC  - old checksum in header
          C   - one's complement sum of old header
          HC' - new checksum in header
C' - one's complement sum of new header m - old value of a 16-bit field m' - new value of a 16-bit field RFC1071 states that C' is: C' = C + (-m) + m' -- [Eqn. 1] = C + (m' - m) As RFC1141 points out, the equation above is not useful for direct use in incremental updates since C and C' do not refer to the actual checksum stored in the header. In addition, it is pointed out that RFC1071 did not specify that all arithmetic must be performed using one's complement arithmetic. Finally, complementing the above equation to get the actual checksum, RFC1141 presents the following: HC' = ~(C + (-m) + m') = HC + (m - m') = HC + m + ~m' -- [Eqn. 2] 3. Discussion Although this equation appears to work, there are boundary conditions under which it produces a result which differs from the one obtained by checksum computation from scratch. This is due to the way zero is handled in one's complement arithmetic. In one's complement, there are two representations of zero: the all zero and the all one bit values, often referred to as +0 and -0. One's complement addition of non-zero inputs can produce -0 as a result, but never +0. Since there is guaranteed to be at least one non-zero field in the IP header, and the checksum field in the protocol header is the complement of the sum, the checksum field can never contain ~(+0), which is -0 (0xFFFF). It can, however, contain ~(-0), which is +0 (0x0000). RFC1141 yields an updated header checksum of -0 when it should be +0. This is because it assumed that one's complement has a distributive property, which does not hold when the result is 0 (see derivation of [Eqn. 2]). The problem is avoided by not assuming this property. The correct equation is given below: HC' = ~(C + (-m) + m') -- [Eqn. 3] = ~(~HC + ~m + m') 4. Examples Consider an IP packet header in which a 16-bit field m = 0x5555 changes to m' = 0x3285. Also, the one's complement sum of all other header octets is 0xCD7A. Then the header checksum would be: HC = ~(0xCD7A + 0x5555) = ~0x22D0 = 0xDD2F The new checksum via recomputation is: HC' = ~(0xCD7A + 0x3285) = ~0xFFFF = 0x0000 Using [Eqn. 2], as specified in RFC1141, the new checksum is computed as: HC' = HC + m + ~m' = 0xDD2F + 0x5555 + ~0x3285 = 0xFFFF which does not match that computed from scratch, and moreover can never obtain for an IP header. Applying [Eqn. 3] to the example above, we get the correct result: HC' = ~(C + (-m) + m') = ~(0x22D0 + ~0x5555 + 0x3285) = ~0xFFFF
= 0x0000 5. Checksum verification by end systems If an end system verifies the checksum by including the checksum field itself in the one's complement sum and then comparing the result against -0, as recommended by RFC1071, it does not matter if an intermediate system generated a -0 instead of +0 due to the RFC 1141 property described here. In the example above: 0xCD7A + 0x3285 + 0xFFFF = 0xFFFF 0xCD7A + 0x3285 + 0x0000 = 0xFFFF However, implementations exist which verify the checksum by computing it and comparing against the header checksum field. It is recommended that intermediate systems compute incremental checksum using the method described in this document, and end systems verify checksum as per the method described in RFC1071. The method in [Eqn. 3] is slightly more expensive than the one in RFC 1141. If this is a concern, the two additional instructions can be eliminated by subtracting complements with borrow [see Sec. 7]. This would result in the following equation: HC' = HC - ~m - m' -- [Eqn. 4] In the example shown above, HC' = HC - ~m - m' = 0xDD2F - ~0x5555 - 0x3285 = 0x0000 6. Historical Note A historical aside: the fact that standard one's complement arithmetic produces negative zero results is one of its main drawbacks; it makes for difficulty in interpretation. In the CDC 6000 series computers [4], this problem was avoided by using subtraction as the primitive in one's complement arithmetic (i.e., addition is subtraction of the complement). 7. Acknowledgments The contribution of the following individuals to the work that led to this document is acknowledged: Manu Kaycee - Ascom Timeplex, Incorporated Paul Koning - Digital Equipment Corporation Tracy Mallory - 3Com Corporation Krishna Narayanaswamy - Digital Equipment Corporation Atul Pandya - Digital Equipment Corporation The failure condition was uncovered as a result of IP testing on a product which implemented the RFC1141 algorithm. It was analyzed, and the updated algorithm devised. This algorithm was also verified using simulation. It was also shown that the failure condition disappears if the checksum verification is done as per RFC1071. 8. Security Considerations Security issues are not discussed in this memo. 9. Conclusions It is recommended that either [Eqn. 3] or [Eqn. 4] be the implementation technique used for incremental update of the standard Internet checksum. 10. Author's Address Anil Rijsinghani Digital Equipment Corporation 550 King St Littleton, MA 01460 Phone: (508) 486-6786 EMail: anil@levers.enet.dec.com 11. References [1] Postel, J., "Internet Protocol - DARPA Internet Program Protocol
Specification", STD 5, RFC791, DARPA, September 1981. [2] Braden, R., Borman, D., and C. Partridge, "Computing the Internet Checksum", RFC1071, ISI, Cray Research, BBN Laboratories, September 1988. [3] Mallory, T., and A. Kullberg, "Incremental Updating of the Internet Checksum", RFC1141, BBN Communications, January 1990. [4] Thornton, J., "Design of a Computer -- the Control Data 6600", Scott, Foresman and Company, 1970.