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Versions: 00 01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 21 22 RFC 4815

Network Working Group                             L-E. Jonsson, Ericsson
INTERNET-DRAFT                                       P. Kremer, Ericsson
Expires: December 2004                                      June 9, 2004

                         ROHC Implementer's Guide

Status of this memo

   By submitting this Internet-Draft, I (we) certify that any applicable
   patent or other IPR claims of which I am (we are) aware have been
   disclosed, and any of which I (we) become aware will be disclosed, in
   accordance with RFC 3668 (BCP 79).

   By submitting this Internet-Draft, I (we) accept the provisions of
   Section 3 of RFC 3667 (BCP 78).

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF), its areas, and its working groups. Note that other
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   Internet-Drafts are draft documents valid for a maximum of six months
   and may be updated, replaced, or obsoleted by other documents at any
   time. It is inappropriate to use Internet-Drafts as reference
   material or cite them other than as "work in progress".

   The list of current Internet-Drafts can be accessed at

   The list of Internet-Draft Shadow Directories can be accessed at

   This document is a submission of the IETF ROHC WG. Comments should be
   directed to the ROHC WG mailing list, rohc@ietf.org.


   This document describes common misinterpretations and some ambiguous
   points of ROHC [1], which defines the framework and four profiles of
   a robust and efficient header compression scheme.  These points have
   been identified by the members of the ROHC working group during
   different interoperability test events.

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Table of Contents

   1. Introduction.....................................................3
   2. CRC calculation and coverage issues..............................3
      2.1. CRC calculation.............................................3
      2.2. Padding octet in CRC........................................3
      2.3. CRC coverage in CRC feedback options........................3
      2.4. CRC coverage of the ESP NULL header.........................4
   3. Enhanced mode transition procedures..............................4
      3.1. Modified transition logic for enhanced transitions..........4
      3.2. Transition from Reliable to Optimistic mode.................5
      3.3. Transition to Unidirectional mode...........................6
   4. Timestamp encoding considerations................................6
      4.1. Encoding of TS values.......................................6
      4.2. Interpretation intervals for TS encoding....................6
      4.3. Recalculating TS_OFFSET.....................................7
      4.4. TS_STRIDE and the Tsc flag in Extension 3...................7
   5. List compression issues..........................................7
      5.1. Generic extension header list...............................7
      5.2. CSRC list items in RTP dynamic chain........................8
      5.3. RTP dynamic chain...........................................8
      5.4. Compressed lists in UO-1-ID packets.........................8
      5.5. Bit masks in list compression...............................8
      5.6. Headers compressed with list compression....................9
      5.7. ESP NULL header list compression............................9
   6. Updating properties..............................................9
      6.1. Implicit updates............................................9
      6.2. Updating properties of UO-1*................................9
   7. Other protocol clarifications...................................10
      7.1. Meaning of NBO.............................................10
      7.2. IP-ID......................................................10
      7.3. Extension-3 in UO-1-ID packets.............................10
      7.4. Extension-3 in UOR-2* packets..............................10
      7.5. Multiple SN options in one feedback packet.................11
      7.6. Multiple CRC options in one feedback packet................11
      7.7. Packet decoding during mode transition.....................11
      7.8. How to respond to lost feedback links?.....................11
      7.9. What does "presumed zero if absent" mean on page 88?.......12
      7.10. UOR-2 in profile 2 (UDP)..................................12
      7.11. Sequence number LSB's in IP extension headers.............12
   8. ROHC negotiation clarifications.................................12
   9. PROFILES suboption in ROHC-over-PPP.............................13
   10. Test Configuration.............................................13
   11. Security considerations........................................14
   12. Acknowledgment.................................................14
   13. References.....................................................14
   14. Authors' Addresses.............................................14
   Appendix A - Sample CRC algorithm..................................15
   Appendix B - Potential improvements in updated profiles............17
   Appendix C - Issues identified but not yet resolved................17

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1. Introduction

   ROHC [1] defines a robust and efficient header compression algorithm,
   and its description is rather long and complex.  During the
   implementation and the interoperability tests of the algorithm some
   unclear areas have been identified.  This document tries to collect
   and clarify these points.  Note that all section and chapter
   references in this document refer to [1], if not stated otherwise.

2. CRC calculation and coverage issues

2.1. CRC calculation

   ROHC uses CRC checksum in order to provide some protection against
   bit errors. CRC is used in the segmentation protocol and in the
   compressed packets, as well.

   Section describes the segmentation protocol and refers to
   [3], which describes a well-defined CRC algorithm for 32 bit
   checksums.  Although, Section 5.9 only defines the polynomials for 3,
   7 and 8-bit long checksum, the same algorithm can be used in these
   cases as well.

   A PERL implementation of the algorithm (written by Carsten Bormann)
   can be found in Appendix A.

2.2. Padding octet in CRC

   According to Section 5.9.1, in case of IR and IR-DYN packets the CRC
   "is calculated over the entire IR or IR-DYN packet, excluding Payload
   and including CID or Add-CID octet".  Padding isn't meant to be
   meaningful part of a packet and not included in CRC calculation.  As
   a result, CRC doesn't cover the Add-CID octet for CID 0, either.

2.3. CRC coverage in CRC feedback options

   Section states "The CRC option contains an 8-bit CRC computed
   over the entire feedback payload, without the packet type and code
   octet, but including any CID fields, using the polynomial of section
   5.9.1". However, it does not mention how the "size" field is handled,
   if present. Since the "size" field can be considered an extension of
   the "code" field, it must be treated as the "code" field, i.e. the
   "size" field is not covered by the CRC.

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2.4. CRC coverage of the ESP NULL header

   Section 5.8.7 gives the CRC coverage of the ESP NULL header as
   "Entire ESP header". This should be interpreted as being only the
   initial part of the header (i.e. SPI and Sequence number), and not
   the trailer part at the end of the payload. Therefore, the ESP NULL
   header will have the same CRC coverage as the ESP header used in the
   ESP profile (section

3. Enhanced mode transition procedures

   To reduce transmission overhead and computational complexity
   (including CRC calculation) associated with feedback packets sent for
   each decompressed packet during mode transition, a decompressor can
   be implemented with slightly modified mode transition procedures,
   compared to those defined in [1].

   These modifications affect transitions to Optimistic and
   Unidirectional modes of operation, i.e. the transitions described in
   sections 5.6.5 and 5.6.6 of [1], and make those transition diagrams
   more consistent with the diagram describing the transition to R-mode.
   However, the differences between the original diagrams of [1] were
   motivated by robustness concerns for mode transitions to Optimistic
   and Unidirectional modes. To avoid deadlock situations in mode
   transitions, these aspects must be addressed also when a decompressor
   implements the enhanced transition procedures, and that is done by
   following a slightly modified definition of the decompressor
   transition states. All aspects related to implementation of the
   enhanced transition procedures are described in subsequent chapters.

   Note that these modified operations should be seen only as an
   improved decompressor implementation, since interoperability is not
   at all affected. A decompressor implemented according to the
   optimized procedures would be able to interoperate with an RFC3095
   compressor, as well as a decompressor implemented according to the
   procedures described in RFC3095 would do.

3.1. Modified transition logic for enhanced transitions

   The intent with these enhanced transition procedures is to allow the
   decompressor to stop sending feedback packets for all packets
   decompressed during the second half of the transition procedure, i.e.
   after an appropriate IR/IR-DYN/UOR-2 packet has been received from
   the compressor. In the transition diagrams, sections 3.2 and 3.3
   below, this is realized by allowing the decompressor transition
   parameter (D_TRANS) to be set to P (Pending) at that stage. However,
   as mentioned above, there are robustness concerns related to this
   optimization, and to avoid deadlock situations with never completed
   transitions as a result of feedback losses, the decompressor must
   continue to send feedback at least periodically, also when in Pending

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   transition state. That would be the equivalence of enhancing the
   D_TRANS parameter definition in section 5.6.1 of [1], to include a
   definition of Pending state operation.

   - D_TRANS:
      Possible values for the D_TRANS parameter are (I)NITIATED,
      (P)ENDING and (D)ONE. D_TRANS MUST be initialized to D, and a mode
      transition can be initiated only when D_TRANS is D. While D_TRANS
      is I, the decompressor sends a NACK or ACK carrying a CRC option
      for each packet received. When D_TRANS is set to P, the
      decompressor do not have to send a NACK or ACK for each packet
      received, but it MUST continue to send feedback on a regular
      basis, and all feedback packets sent MUST include the CRC option.
      This ensures that all mode transitions will be completed also in
      case of feedback losses.

3.2. Transition from Reliable to Optimistic mode

   The enhanced procedure for transition from Reliable to Optimistic
   mode is shown below:

            Compressor                     Decompressor
                 |                               |
                 |        ACK(O)/NACK(O) +-<-<-<-| D_TRANS = I
                 |       +-<-<-<-<-<-<-<-+       |
     C_TRANS = P |-<-<-<-+                       |
     C_MODE = O  |                               |
                 |->->->-+ IR/IR-DYN/UOR-2(SN,O) |
                 |       +->->->->->->->-+       |
                 |->-..                  +->->->-| D_TRANS = P
                 |->-..                          | D_MODE = O
                 |           ACK(SN,O)   +-<-<-<-|
                 |       +-<-<-<-<-<-<-<-+       |
     C_TRANS = D |-<-<-<-+                       |
                 |                               |
                 |->->->-+  UO-0, UO-1*          |
                 |       +->->->->->->->-+       |
                 |                       +->->->-| D_TRANS = D
                 |                               |

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3.3. Transition to Unidirectional mode

   The enhanced procedure for transition to Unidirectional mode is shown
   on the following figure:

                Compressor                     Decompressor
                 |                               |
                 |        ACK(U)/NACK(U) +-<-<-<-| D_TRANS = I
                 |       +-<-<-<-<-<-<-<-+       |
     C_TRANS = P |-<-<-<-+                       |
     C_MODE = U  |                               |
                 |->->->-+ IR/IR-DYN/UOR-2(SN,U) |
                 |       +->->->->->->->-+       |
                 |->-..                  +->->->-| D_TRANS = P
                 |->-..                          |
                 |           ACK(SN,U)   +-<-<-<-|
                 |       +-<-<-<-<-<-<-<-+       |
     C_TRANS = D |-<-<-<-+                       |
                 |                               |
                 |->->->-+  UO-0, UO-1*          |
                 |       +->->->->->->->-+       |
                 |                       +->->->-| D_TRANS = D
                 |                               | D_MODE= U

4. Timestamp encoding considerations

4.1. Encoding of TS values

   RTP Timestamp values (TS) are always encoded using W-LSB encoding,
   both when sent scaled and when sent unscaled. For TS values sent in
   Extension 3, W-LSB encoded values are sent using the self-describing
   variable-length format (section 4.5.6), and this applies to both
   scaled and unscaled values.

4.2. Interpretation intervals for TS encoding

   Section 4.5.4 defines the interpretation interval, p, for timer-based
   compression of the RTP timestamp.  However, Section 5.7 defines a
   different interpretation interval, which is defined as the
   interpretation interval to use for all TS values.  It is thus unclear
   which p-value to use, at least for timer-based compression.

   The way this should be interpreted is that the p-value differs
   depending on whether timer-based compression is enabled or not.  For
   timer-based compression, the interpretation interval of section
   4.5.4, p = 2^(k-1) - 1, is used for TS.  Otherwise, the interval of
   section 5.7, p = 2^(k-2) - 1, is used for TS with regular W-LSB

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   Since two different p-values are used, the compressor must take this
   into account during the process of enabling timer-based compression.
   Before timer-based compression can be used, the decompressor will
   have to inform the compressor (on a per-channel basis) about its
   clock resolution, and the compressor has to send (on a per-context
   basis) a non-zero TIME_STRIDE to the decompressor.

   When the compressor is confident that the decompressor has received
   the TIME_STRIDE value, it can switch to timer-based compression.
   During this transition from window-based compression to timer-based
   compression, it is necessary that the compressor keeps k large enough
   to cover both interpretation intervals.

4.3. Recalculating TS_OFFSET

   TS can be sent unscaled if the TS value change does not match the
   established TS_STRIDE, but the TS_STRIDE might still stay unchanged.
   To ensure correct decompression of subsequent packets, the
   decompressor should therefore always recalculate the RTP TS modulo,
   TS_OFFSET, when a packet with an unscaled TS value is received.

4.4. TS_STRIDE and the Tsc flag in Extension 3

   The Tsc flag in Extension 3 indicates whether TS is scaled or not. It
   must be noted that the Tsc value apply to all TS bits, also if there
   are no TS bits in the extension itself.

   Note also that if Tsc=1, TS is scaled using context(TS_STRIDE), not
   value(TS_STRIDE) as is said in the legend for Extension 3 in section

   When a compressor uses Extension 3 to re-establish a new value for
   TS_STRIDE, it must send unscaled TS together with TS_STRIDE for some
   packets until decompressor confidence is obtained. When the TS_STRIDE
   field is present in Extension 3, the Tsc flag must thus be set to 0.

5. List compression issues

5.1. Generic extension header list

   Section defines the static and dynamic parts of the IPv4
   header.  This section indicates a 'Generic extension header list'
   field in the dynamic chain, which has a variable length.  The
   detailed description of this field can be found in Section

   The generic extension header list starts with an octet that is always
   present, so its length is one octet, at least.  If the 'GP' bit in
   the first octet is set to 1 then the length of the list is two
   octets, even if the list is empty.

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5.2. CSRC list items in RTP dynamic chain

   Section defines the static and dynamic parts of the RTP
   header.  This section indicates a 'Generic CSRC list' field in the
   dynamic chain, which has a variable length.  This field uses the same
   encoding rules as the 'Generic extension header list' in the IPv4
   header, so the same rules apply to its length.

5.3. RTP dynamic chain

   Section defines the static and dynamic parts of the RTP
   header.  In the dynamic part, a 'CC' field indicates the number of
   CSRC items present in the 'Generic CSRC list'. A 'CC' field can also
   be found within the 'Generic CSRC list' (when present), and these
   fields would then have the same meaning. In order to decode a
   compressed packet correctly it's necessary to know the 'CC' value
   because it has serious impact on the packet's length.  In normal
   case, the values of the fields are equal.

   Proposed behavior if the values are different:
      Both fields are within the RTP dynamic part but only the second
      'CC' field resides inside the 'Generic CSRC list' together with
      the XI items.  Since the 'CC' value determines the number of XI
      items in the CSRC list and isn't used otherwise, the first CC
      field should be ignored and only the second field (inside the CSRC
      list) should be used for incoming packets.  For outgoing packets
      both fields should be set to the same value.

5.4. Compressed lists in UO-1-ID packets

   This section describes the situation when a UO-1-ID packet carries a
   compressed list.  Compressed lists are encoded using Encoding Type 0
   (section 5.7.5 and and every list may have a unique
   identifier (gen_id).  The identifier is present in U/O-mode when the
   compressor decides that it may use this list as a future reference.

   On one hand, the decompressor shouldn't save the list because UO-1-ID
   packets doesn't update the context.  On the other hand, the
   decompressor updates its translation table whenever an (Index, item)
   pair is received (section 5.8.1).  The decompressor must be able to
   handle such a packet, thus it has to behave as described in the
   latter case.  According to section, the compressor must
   increment Counter by 1.

5.5. Bit masks in list compression

   A 7-bit or 15-bit mask may be used in the insertion and/or removal
   schemes for compressed lists. It should be noted that even if a list
   has more than 7 items, a 7-bit mask could be used as long as changes
   are only applied in the first part of the reference list, and items
   with an index not covered by the 7-bit mask are thus kept unchanged.

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5.6. Headers compressed with list compression

   In section 5.8, it is stated that headers which can be part of
   extension header chains INCLUDE AH, null ESP, minimal encapsulation,
   GRE, and IPv6 extensions. This list of headers which can be
   compressed is correct, but the work INCLUDE should not be there,
   since only the header types listed can actually be handled.

5.7. ESP NULL header list compression

   Due to the offset of the fields in the trailer part of the ESP
   header, a compressor must only compress packets containing at most
   one NULL ESP header.

6. Updating properties

6.1. Implicit updates

   If an updating packet (e.g. R-0-CRC or UO-0) contains information
   about a specific field X (compressed RTP sequence number, typically),
   then X is updated according to the content of that packet.  But this
   packet implicitly updates all other inferred fields (i.e. RTP
   timestamp) according to the current mode and the appropriate mapping
   function of the updated and the inferred fields.

   An updating packet thus updates the reference values of all header
   fields, either explicitly or implicitly, with an exception for the
   UO-1-ID packet, which only updates TS, SN, IP-ID, and sequence
   numbers of IP extension headers (see 5.7.3). In UO-mode, all packets
   are updating packets, while in R-mode all packets with a CRC are
   updating packets.

   For example, a UO-0 packet contains the compressed RTP sequence
   number (SN). Such a packet also implicitly updates RTP timestamp,
   IPv4 ID, and sequence numbers of IP extension headers.

6.2. Updating properties of UO-1*

   In section 5.7.3, the updating properties of UO-1* are stated:

     "Values provided in extensions, except those in other SN, TS,
      or IP-ID fields, do not update the context."

   However, also sequence number fields of extension headers must be
   updated, which means the updating properties should be rephrased as:

     "The only values provided in extensions that update the context are
      the additional bits for the SN, TS, or IP-ID fields. Other values
      provided in extensions do not update the context. Note that
      sequence number fields of extension headers are also updated."

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7. Other protocol clarifications

7.1. Meaning of NBO

   In general, an unset flag indicates the normal operation and a set
   flag indicates unusual behavior.  However, in IPv4 dynamic part
   (Section, if the 'NBO' bit is set, it means that network
   byte order is used.

7.2. IP-ID

   According to Section 5.7 IP-ID means the compressed value of the IPv4
   header's 'Identification' field. Compressed packets contain this
   compressed value (IP-ID), while IR packets with dynamic chain and IR-
   DYN packets transmit the original, uncompressed Identification field
   value. The IP-ID field always represents the Identification value of
   the innermost IPv4 header whose corresponding RND flag is not 1.

   If RND or RND2 is set to 1, the corresponding IP-ID(s) is(are) sent
   as 16-bit original Identification value(s) at the end of the
   compressed base header, according to the IP-ID description (see the
   beginning of section 5.7).

   It should be noted that when RND*=0, IP-ID is always compressed, i.e.
   expressed as an SN offset and byte-swapped if NBO=0. This is the case
   even when 16 bits of IP-ID is sent in extension 3.

7.3. Extension-3 in UO-1-ID packets

   Extension-3 is applied to give values and indicate changes to fields
   other than SN, TS and IP-ID in IP header(s) and RTP header.  In case
   of UO-1-ID packets, it should be noted that values provided in
   extensions do not update the context, with an exception for SN, TS
   and IP-ID fields, which always update the context (Section 5.7.3.).
   It should also be noted that a UO-1-ID packet with Extension 3 must
   never be sent with RND flags that changes the packet interpretation,
   i.e. that would violate the base condition for UO-1-ID (at least one
   RND value must be 0).

   Besides, usage of Extension-3 in UO-1-ID can be useful to compress a
   transient change in a packet stream.  For example, if a field's value
   changes in the current packet but in the next packet it returns to
   its regular behavior.  E.g. changes in TTL.

7.4. Extension-3 in UOR-2* packets

   If Extension-3 is used in a UOR-2* packet then the information of the
   extension updates the context (Section 5.7.4).  Some flags of the IP
   header in the extension (e.g. NBO or RND) changes the interpretation
   of fields in UOR-2* packets. In these cases, when a flag changes in
   Extension-3, a decompressor should re-parse the UOR-2* packet.

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7.5. Multiple SN options in one feedback packet

   The length of the sequence number field in the original ESP header is
   32 bits.  A decompressor can't send back all the 32 bits in a
   feedback packet unless it uses multiple SN options in one feedback
   packet.  Section declares that a FEEDABCK-2 packet can
   contain variable number of feedback options and the options can
   appear in any order.

   A compressor should be able to process multiple SN options in one
   feedback packet.

7.6. Multiple CRC options in one feedback packet

   Although it is never required to have more than one single CRC option
   in a feedback packet, having multiple CRC options is still allowed.
   If multiple CRC options are included, all such CRC options will be
   identical, as they will be calculated over the same header.

7.7. Packet decoding during mode transition

   Each ROHC profile defines its own set of packet formats, and also its
   own feedback packets. The use of various operational modes is also
   defined by each specific profile. A decompressor can therefore not
   initiate a mode transfer request before at least one packet of a new
   context has been correctly decompressed, establishing the context
   based on one specific profile (as specified in IR packets). First
   then the context has been established, the decompressor knows the
   profile used, which modes are defined by that profile, and the
   feedback packet formats available.

   If the transition procedures in sections 5.6.5 and 5.6.6 of [1] are
   followed (and not the enhanced procedures described in section 3 of
   this document), it is important to note that type 0 or type 1 packets
   may be received by the decompressor during the first half of the
   transition procedure, and these packets must not mistakenly be
   interpreted as the packets sent by the compressor to indicate
   completed transition. The decompressor side must therefore keep track
   of the transition status, e.g. with an additional parameter. If the
   enhanced transition procedures described in section 3 of this
   document are used, the D_TRANS parameter can serve this purpose since
   its definition and usage is slightly modified.

7.8. How to respond to lost feedback links?

   One potential issue that might have to be considered, depending on
   link technology, is whether feedback links might get lost, and in
   such cases how this is handled. When the compressor is notified that
   the feedback channel is down, the compressor must be able to handle

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   it by restarting compression with creating a new context. Creating a
   new context also implies to use a new CID value.

   Generally, feedback links are not expected to disappear when once
   present, but it should be noted that this might be the case for
   certain link technologies.

7.9. What does "presumed zero if absent" mean on page 88?

   On page 88, RFC 3095 says that R-P contains the absolute value of RTP
   Padding bit and it's presumed zero if absent.  It could be absent
   from RTP header flags and fields, from the extension type 3 or from
   the ROHC packet. It's been agreed that the RTP padding bit is
   presumed zero if absent from the RTP header flags.

7.10. UOR-2 in profile 2 (UDP)

   One single new format is defined for UOR-2 in profile 2, which
   replaces all three (UOR-2, UOR-2-ID, UOR-2-TS) formats from profile
   1. The same UOR-2 format is thus used independent of if there are IP
   headers with a corresponding RND=1 or not.

7.11. Sequence number LSB's in IP extension headers

   In section 5.8.5, formats are defined for compression of IP extension
   header fields. These include compressed sequence number fields, and
   it is said that these fields contain "LSB of sequence number". This
   means these sequence numbers are not "LSB-encoded" as e.g. the RTP
   sequence number with an interpretation interval, but are actually
   just the LSB's of the uncompressed fields.

8. ROHC negotiation clarifications

   Section 4.1 states that the link layer must provide means to
   negotiate e.g. the channel parameters listed in section 5.1.1.  One
   of these parameters is the PROFILES parameter, which is said to be a
   set of non-negative integers where each integer indicates a profile
   supported by the decompressor.  This can be interpreted as if it is
   sufficient to have a mechanism to announce profile support from
   decompressor to compressor.  However, things are a little bit more
   complicated than that.

   Each profile is identified by a 16-bit value, where the 8 LSB bits
   indicate the actual profile, and the 8 MSB bits indicate the variant
   of that profile (see chapter 8).  In the ROHC headers sent over the
   link, the profile used is identified only with the 8 LSB bits, which
   means that the compressor and decompressor must have agreed on which
   variant to use for each profile.  This can be done in various ways,
   but the negotiation protocol must provide means to do it.

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   In conclusion, the negotiation protocol must be able to communicate
   to the compressor the set of profiles supported by the decompressor,
   and when multiple variants of the same profile are available, also
   provide means for the decompressor to know which variant will be used
   by the compressor.  This basically means that the PROFILES set after
   negotiation must not include more than one variant of the same

9. PROFILES suboption in ROHC-over-PPP

   The logical union of suboptions for IPCP and IPV6CP negotiations, as
   specified by ROHC over PPP [2], can not be used for the PROFILES
   suboption, as the whole union would then have to be considered within
   each of the two IPCP negotiations, to avoid getting an ambiguous
   profile set. An implementation of RFC 3241 must therefore make sure
   the same profile set is negotiated for both IPv4 and IPv6 (IPCP and

10. Test Configuration

   ROHC is used to compress IP/UDP/RTP, IP/UDP and IP/ESP headers, thus
   every ROHC implementation has an interface that can send and receive
   IP packets (i.e. Ethernet).  On the other hand, there must be an
   interface (a serial link for example) or other means of transport (an
   IP/UDP flow), which can transmit ROHC packets.  Having these two
   interfaces several configurations can be set up.  The figure below
   shows sample configurations that can be used for testing a ROHC

    IP/UDP/RTP +------------+      ROHC      +--------------+ IP/UDP/RTP
     packets   |    ROHC    |     packets    |     ROHC     | packets
    ---------->| Compressor |----->    ----->| Decompressor |---------->
               +------------+                +--------------+

   Unfortunately, comparing the IP/UDP/RTP packets at the endpoints can
   only show whether the reconstructed stream differs from the original
   or not.  In order to identify the place of the error more detailed
   tests are needed.  The next figure shows another possible scenario:

   IP/UDP/RTP +------------+  ROHC    ROHC   +--------------+ IP/UDP/RTP
    packets   |    ROHC    | packets packets |     ROHC     |  packets
       +----->| Compressor |----->+   +----->| Decompressor |----->+
       |      +------------+      |   |      +--------------+      |
       |                          |   |                            |
       |      +------------+      |   |       +------------+       |
       |      |    Test    |      |   |       |    Test    |       |
       +<-----| Equipment  |<-----+   +<------| Equipment  |<------+
              +------------+                  +------------+

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   In the first case, the test equipment generates the RTP stream and
   also acts as a ROHC decompressor.  The tester must recognize if the
   original RTP stream was compressed in a bad way and gives an alarm.
   In the second case, it is the test equipment that sends the
   compressed ROHC packets and the Decompressor reconstructs the RTP
   stream.  Since the tester knows the ROHC packets and the
   reconstructed RTP stream it can detect if the Decompressor makes a

11. Security considerations

   This document provides a number of clarifications to [1], but it does
   not make any changes or additions to the protocol.  As a consequence,
   the security considerations of [1] apply without additions.

12. Acknowledgment

   The authors would like thank Vicknesan Ayadurai, Carsten Bormann,
   Mikael Degermark, Ghyslain Pelletier, Zhigang Liu, Abigail Surtees,
   Mark West, Kristofer Sandlund, Tommy Lundemo, Alan Kennington and
   Remi Pelland for their contributions and comments.

13. References

   [1]  C. Bormann, et al., "RObust Header Compression (ROHC)",
        RFC 3095, July 2001.

   [2]  C. Bormann, "Robust Header Compression (ROHC) over PPP",
        RFC 3241, April 2002.

   [3]  W. Simpson, "PPP in HDLC-like Framing", RFC 1662, July 1994.

14. Authors' Addresses

   Lars-Erik Jonsson
   Ericsson AB
   Box 920
   SE-971 28 Lulea, Sweden
   Phone: +46 70 513 56 21
   Fax:   +46 920 20 20 99
   EMail: lars-erik.jonsson@ericsson.com

   Peter Kremer
   Conformance and Software Test Laboratory
   Ericsson Hungary
   H-1300 Bp. 3., P.O. Box 107, HUNGARY
   Phone: +36-1-437-7033
   Fax:   +36-1-437-7767
   Email: Peter.Kremer@ericsson.com

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Appendix A - Sample CRC algorithm

   #!/usr/bin/perl -w
   use strict;
   # ROHC CRC demo - Carsten Bormann cabo@tzi.org 2001-08-02
   # This little demo shows the three types of CRC in use in RFC 3095,
   # the robust header compression standard.  Type your data in
   # hexadecimal form and the press Control+D.
   # utility
   sub dump_bytes($) {
       my $x = shift;
       my $i;
       for ($i = 0; $i < length($x); ) {
     printf("%02x ", ord(substr($x, $i, 1)));
     printf("\n") if (++$i % 16 == 0);
       printf("\n") if ($i % 16 != 0);

   # The CRC calculation algorithm.
   sub do_crc($$$) {
       my $nbits = shift;
       my $poly = shift;
       my $string = shift;

       my $crc = ($nbits == 32 ? 0xffffffff : (1 << $nbits) - 1);
       for (my $i = 0; $i < length($string); ++$i) {
     my $byte = ord(substr($string, $i, 1));
     for( my $b = 0; $b < 8; $b++ ) {
         if (($crc & 1) ^ ($byte & 1)) {
          $crc >>= 1;
          $crc ^= $poly;
         } else {
          $crc >>= 1;
         $byte >>= 1;
       printf "%2d bits, ", $nbits;
       printf "CRC: %02x\n", $crc;

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   # Test harness
   $/ = undef;
   $_ = <>;         # read until EOF
   my $string = ""; # extract all that looks hex:
   s/([0-9a-fA-F][0-9a-fA-F])/$string .= chr(hex($1)), ""/eg;

   # 32-bit segmentation CRC
   # Note that the text implies this is complemented like for PPP
   # (this differs from 8, 7, and 3-bit CRC)
   #      C(x) = x^0 + x^1 + x^2 + x^4 + x^5 + x^7 + x^8 + x^10 +
   #             x^11 + x^12 + x^16 + x^22 + x^23 + x^26 + x^32
   do_crc(32, 0xedb88320, $string);

   # 8-bit IR/IR-DYN CRC
   #      C(x) = x^0 + x^1 + x^2 + x^8
   do_crc(8, 0xe0, $string);

   # 7-bit FO/SO CRC
   #      C(x) = x^0 + x^1 + x^2 + x^3 + x^6 + x^7
   do_crc(7, 0x79, $string);

   # 3-bit FO/SO CRC
   #      C(x) = x^0 + x^1 + x^3
   do_crc(3, 0x6, $string);

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Appendix B - Potential improvements in updated profiles

   Regarding the CC field and CSRC list, the following interpretation
   has been proposed as an improvement:

   "It should be noted that when the value of this CC field is equal to
   zero, there is no Generic CSRC list present in the dynamic chain,
   i.e. the field comment should have said "variable length, present if
   CC > 0". "<introduction text>

Appendix C - Issues identified but not yet resolved

   These issues have been identified but are still under discussion on
   the ROHC WG mail list. Resolutions to these issues will have to be
   added in later revisions of this document.

   * Mode inheritance in case of context re-use

   * Slope used to compress/decompress RTP Timestamp

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Copyright Statement

   Copyright (C) The Internet Society (2004). This document is subject
   to the rights, licenses and restrictions contained in BCP 78, and
   except as set forth therein, the authors retain all their rights.

Disclaimer of Validity

   This document and the information contained herein are provided on an

This Internet-Draft expires December 9, 2004.

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