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RFC6185

  1. RFC 6185
Internet Engineering Task Force (IETF)                     T. Kristensen
Request for Comments: 6185                                      P. Luthi
Category: Standards Track                                       TANDBERG
ISSN: 2070-1721                                                 May 2011


                         RTP Payload Format for
        H.264 Reduced-Complexity Decoding Operation (RCDO) Video

Abstract

   This document describes an RTP payload format for the Reduced-
   Complexity Decoding Operation (RCDO) for H.264 Baseline profile
   bitstreams, as specified in ITU-T Recommendation H.241.  RCDO reduces
   the decoding cost and resource consumption of the video processing.
   The RCDO RTP payload format is based on the H.264 RTP payload format.

Status of This Memo

   This is an Internet Standards Track document.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Further information on
   Internet Standards is available in Section 2 of RFC 5741.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   http://www.rfc-editor.org/info/rfc6185.

Copyright Notice

   Copyright (c) 2011 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (http://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must
   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.






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   This document may contain material from IETF Documents or IETF
   Contributions published or made publicly available before November
   10, 2008.  The person(s) controlling the copyright in some of this
   material may not have granted the IETF Trust the right to allow
   modifications of such material outside the IETF Standards Process.
   Without obtaining an adequate license from the person(s) controlling
   the copyright in such materials, this document may not be modified
   outside the IETF Standards Process, and derivative works of it may
   not be created outside the IETF Standards Process, except to format
   it for publication as an RFC or to translate it into languages other
   than English.

Table of Contents

   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  2
   2.  Conventions Used in This Document  . . . . . . . . . . . . . .  3
   3.  Media Format Background  . . . . . . . . . . . . . . . . . . .  3
   4.  Payload Format . . . . . . . . . . . . . . . . . . . . . . . .  3
   5.  Congestion Control Considerations  . . . . . . . . . . . . . .  3
   6.  Payload Format Parameters  . . . . . . . . . . . . . . . . . .  3
     6.1.  Media Type Definition  . . . . . . . . . . . . . . . . . .  4
   7.  Mapping to SDP . . . . . . . . . . . . . . . . . . . . . . . . 19
     7.1.  Offer/Answer Considerations  . . . . . . . . . . . . . . . 20
     7.2.  Declarative SDP Considerations . . . . . . . . . . . . . . 20
   8.  IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 20
   9.  Security Considerations  . . . . . . . . . . . . . . . . . . . 20
   10. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 21
   11. References . . . . . . . . . . . . . . . . . . . . . . . . . . 21
     11.1. Normative References . . . . . . . . . . . . . . . . . . . 21
     11.2. Informative References . . . . . . . . . . . . . . . . . . 21

1.  Introduction

   ITU-T Recommendation H.241 [3] specifies a Reduced-Complexity
   Decoding Operation (RCDO) for use with H.264 [2] Baseline profile
   bitstreams.  It also specifies a bitstream constraint associated with
   RCDO and a mechanism for signaling RCDO within the bitstream.  The
   RCDO signaling indicates that the bitstream conforms to the bitstream
   constraint and that the decoder shall apply the RCDO decoding process
   to the bitstream.

   RCDO for H.264 offers a solution to support higher resolutions at the
   same high frame rates used in current implementations.  This is
   achieved by reducing the processing requirements and thus reducing
   the decoding cost/resource consumption of the video processing.

   This document defines media type parameters and allows use in systems
   based on the Session Description Protocol (SDP) [8] for signaling.



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2.  Conventions Used in This Document

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in [4].

3.  Media Format Background

   The Reduced-Complexity Decoding Operation (RCDO) for H.264 Baseline
   profile bitstreams is specified in Annex B of H.241 [3].  RCDO is
   specified as a separate H.264 mode and is distinct from any profile
   defined in H.264.  An RCDO bitstream obeys all the constraints of the
   Baseline profile.

   The media format is based on the H.264 RTP payload format as
   specified in RFC 6184 [1].  Therefore, RFC 6184 constitutes the basis
   for this document and is referred to several times.

   In order to signal H.264 additional modes, Table 8-13 of H.241 [3]
   specifies an AdditionalModesSupported parameter.  Currently, the only
   additional mode defined is RCDO.

      Informative note: Other additional modes may be defined in the
      future.  H.264 additional modes may or may not be distinct from
      the profiles in H.264.

   A separate media subtype, named H264-RCDO, is defined to ensure
   backward compatibility with deployed implementations of H.264.

4.  Payload Format

   The payload format defined in Section 5 of RFC 6184 [1] SHALL be
   used.  This includes the RTP header usage and the payload format in
   RFC 6184.  Examples of typical RTP packets can be found in RFC 6184.

5.  Congestion Control Considerations

   Congestion control for RTP SHALL be used in accordance with RFC 3550
   [6] and with any applicable RTP profile, e.g., RFC 3551 [7].  If
   best-effort service is being used, users of this payload format SHALL
   monitor packet loss to ensure that the packet loss rate is within
   acceptable parameters.

6.  Payload Format Parameters

   This RTP payload format is identified using the H264-RCDO media
   subtype, which is registered in accordance with RFC 4855 [10], and
   using the template of RFC 4288 [13].



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6.1.  Media Type Definition

      Informative note: The media subtype definition for H264-RCDO is
      based on the definition of the H264 media subtype as specified in
      Section 8.1 of RFC 6184 [1].  Except for the profile-level-id
      parameter, for which new semantics are specified below, the
      optional parameters are copied from RFC 6184 [1] in order to
      provide a complete, self-contained media subtype registration to
      IANA.  The references are updated to match the numbering used in
      this document.

   The media subtype for RCDO for H.264 has been allocated from the IETF
   tree.

   Type name: video

   Subtype name: H264-RCDO

   Required parameters:

   rate:  Indicates the RTP timestamp clock rate.  The rate value MUST
      be 90000.

   Optional parameters:

   profile-level-id:  A base16 RFC 4648 [9] (hexadecimal) representation
      of the following three bytes in the sequence parameter set NAL
      unit is specified in H.264 [2]: 1) profile_idc, 2) a byte herein
      referred to as profile-iop, composed of the values of
      constraint_set0_flag, constraint_set1_flag, constraint_set2_flag,
      constraint_set3_flag, constraint_set4_flag, constraint_set5_flag,
      and reserved_zero_2bits in bit-significance order, starting from
      the most-significant bit, and 3) level_idc.  Note that
      reserved_zero_2bits is required to be equal to 0 in H.264 [2], but
      other values for it may be specified in the future by ITU-T or
      ISO/IEC.

      The profile-level-id parameter indicates the default sub-profile
      (i.e., the subset of coding tools that may have been used to
      generate the stream or that the receiver supports) and the default
      level of the stream or the receiver supports.

      RCDO is distinct from any profile; this implies that the profile
      value 0 (no profile) and the profile_idc byte of the profile-
      level-id parameter are equal to 0.  An RCDO bitstream MUST obey
      all the constraints of the Baseline profile.  Therefore, only
      constraint_set0_flag is equal to 1 in the profile-iop part of the
      profile-level-id parameter; the remaining bits are set to 0.



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      If the profile-level-id parameter is used to indicate properties
      of a NAL unit stream, it indicates that, to decode the stream, the
      minimum subset of coding tools a decoder has to support is the
      default sub-profile, and the lowest level the decoder has to
      support is the default level.

      If the profile-level-id parameter is used for capability exchange
      or session setup, it indicates the subset of coding tools, which
      is equal to the default sub-profile, that the codec supports for
      both receiving and sending.  If max-recv-level is not present, the
      default level from profile-level-id indicates the highest level
      the codec wishes to support.  If max-recv-level is present, it
      indicates the highest level the codec supports for receiving.  For
      either receiving or sending, all levels that are lower than the
      highest level supported MUST also be supported.

      For example, if a codec supports level 1.3, the profile-level-id
      becomes 00800d, in which 00 indicates the "no profile" value, 80
      indicates the constraints of the Baseline profile, and 0d
      indicates level 1.3.  When level 2.1 is supported, the profile-
      level-id becomes 008015.

      If no profile-level-id is present, level 1 (i.e., equivalent to
      profile-level-id 00800a) MUST be implied.

         Informative note: The definitions of the remaining optional
         parameters below are copied verbatim from Section 8.1 of RFC
         6184 [1].  Only the references are updated to match the
         numbering used in this document.

   max-recv-level:  This parameter MAY be used to indicate the highest
      level a receiver supports when the highest level is higher than
      the default level (the level indicated by profile-level-id).  The
      value of max-recv-level is a base16 (hexadecimal) representation
      of the two bytes after the syntax element profile_idc in the
      sequence parameter set NAL unit specified in H.264 [2]: profile-
      iop (as defined above) and level_idc.  If the level_idc byte of
      max-recv-level is equal to 11 and bit 4 of the profile-iop byte of
      max-recv-level is equal to 1 or if the level_idc byte of max-recv-
      level is equal to 9 and bit 4 of the profile-iop byte of max-recv-
      level is equal to 0, the highest level the receiver supports is
      Level 1b.  Otherwise, the highest level the receiver supports is
      equal to the level_idc byte of max-recv-level divided by 10.

      max-recv-level MUST NOT be present if the highest level the
      receiver supports is not higher than the default level.





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   max-mbps, max-smbps, max-fs, max-cpb, max-dpb, and max-br:  These
      parameters MAY be used to signal the capabilities of a receiver
      implementation.  These parameters MUST NOT be used for any other
      purpose.  The highest level conveyed in the value of the profile-
      level-id parameter or the max-recv-level parameter MUST be such
      that the receiver is fully capable of supporting. max-mbps, max-
      smbps, max-fs, max-cpb, max-dpb, and max-br MAY be used to
      indicate capabilities of the receiver that extend the required
      capabilities of the signaled highest level, as specified below.

      When more than one parameter from the set (max-mbps, max-smbps,
      max-fs, max-cpb, max-dpb, max-br) is present, the receiver MUST
      support all signaled capabilities simultaneously.  For example, if
      both max-mbps and max-br are present, the signaled highest level
      with the extension of both the frame rate and bitrate is
      supported.  That is, the receiver is able to decode NAL unit
      streams in which the macroblock processing rate is up to max-mbps
      (inclusive), the bitrate is up to max-br (inclusive), the coded
      picture buffer size is derived as specified in the semantics of
      the max-br parameter below, and the other properties comply with
      the highest level specified in the value of the profile-level-id
      parameter or the max-recv-level parameter.

      If a receiver can support all the properties of Level A, the
      highest level specified in the value of the profile-level-id
      parameter or the max-recv-level parameter MUST be Level A (i.e.,
      MUST NOT be lower than Level A).  In other words, a receiver MUST
      NOT signal values of max-mbps, max-fs, max-cpb, max-dpb, and
      max-br that taken together meet the requirements of a higher level
      compared to the highest level specified in the value of the
      profile-level-id parameter or the max-recv-level parameter.

         Informative note: When the OPTIONAL media type parameters are
         used to signal the properties of a NAL unit stream, max-mbps,
         max-smbps, max-fs, max-cpb, max-dpb, and max-br are not
         present, and the value of profile-level-id must always be such
         that the NAL unit stream complies fully with the specified
         profile and level.

   max-mbps:  The value of max-mbps is an integer indicating the maximum
      macroblock processing rate in units of macroblocks per second.
      The max-mbps parameter signals that the receiver is capable of
      decoding video at a higher rate than is required by the signaled
      highest level conveyed in the value of the profile-level-id
      parameter or the max-recv-level parameter.  When max-mbps is
      signaled, the receiver MUST be able to decode NAL unit streams
      that conform to the signaled highest level, with the exception
      that the MaxMBPS value in Table A-1 of H.264 [2] for the signaled



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      highest level is replaced with the value of max-mbps.  The value
      of max-mbps MUST be greater than or equal to the value of MaxMBPS
      given in Table A-1 of H.264 [2] for the highest level.  Senders
      MAY use this knowledge to send pictures of a given size at a
      higher picture rate than is indicated in the signaled highest
      level.

   max-smbps:  The value of max-smbps is an integer indicating the
      maximum static macroblock processing rate in units of static
      macroblocks per second, under the hypothetical assumption that all
      macroblocks are static macroblocks.  When max-smbps is signaled,
      the MaxMBPS value in Table A-1 of H.264 [2] should be replaced
      with the result of the following computation:

      o If the parameter max-mbps is signaled, set a variable
        MaxMacroblocksPerSecond to the value of max-mbps.  Otherwise,
        set MaxMacroblocksPerSecond equal to the value of MaxMBPS in
        Table A-1 of H.264 [2] for the signaled highest level conveyed
        in the value of the profile-level-id parameter or the
        max-recv-level parameter.

      o Set a variable P_non-static to the proportion of non-static
        macroblocks in picture n.

      o Set a variable P_static to the proportion of static macroblocks
        in picture n.

      o The value of MaxMBPS in Table A-1 of H.264 [2] should be
        considered by the encoder to be equal to:

         MaxMacroblocksPerSecond * max-smbps / (P_non-static * max-smbps
         + P_static * MaxMacroblocksPerSecond)

      The encoder should recompute this value for each picture.  The
      value of max-smbps MUST be greater than or equal to the value of
      MaxMBPS given explicitly as the value of the max-mbps parameter or
      implicitly in Table A-1 of H.264 [2] for the signaled highest
      level.  Senders MAY use this knowledge to send pictures of a given
      size at a higher picture rate than is indicated in the signaled
      highest level.

   max-fs:  The value of max-fs is an integer indicating the maximum
      frame size in units of macroblocks.  The max-fs parameter signals
      that the receiver is capable of decoding larger picture sizes than
      are required by the signaled highest level conveyed in the value
      of the profile-level-id parameter or the max-recv-level parameter.
      When max-fs is signaled, the receiver MUST be able to decode NAL
      unit streams that conform to the signaled highest level, with the



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      exception that the MaxFS value in Table A-1 of H.264 [2] for the
      signaled highest level is replaced with the value of max-fs.  The
      value of max-fs MUST be greater than or equal to the value of
      MaxFS given in Table A-1 of H.264 [2] for the highest level.
      Senders MAY use this knowledge to send larger pictures at a
      proportionally lower frame rate than is indicated in the signaled
      highest level.

   max-cpb:  The value of max-cpb is an integer indicating the maximum
      coded picture buffer size in units of 1000 bits for the VCL HRD
      parameters and in units of 1200 bits for the NAL HRD parameters.
      Note that this parameter does not use units of cpbBrVclFactor and
      cpbBrNALFactor (see Table A-1 of H.264 [2]).  The max-cpb
      parameter signals that the receiver has more memory than the
      minimum amount of coded picture buffer memory required by the
      signaled highest level conveyed in the value of the
      profile-level-id parameter or the max-recv-level parameter.  When
      max-cpb is signaled, the receiver MUST be able to decode NAL unit
      streams that conform to the signaled highest level, with the
      exception that the MaxCPB value in Table A-1 of H.264 [2] for the
      signaled highest level is replaced with the value of max-cpb
      (after taking cpbBrVclFactor and cpbBrNALFactor into consideration
      when needed).  The value of max-cpb (after taking cpbBrVclFactor
      and cpbBrNALFactor into consideration when needed) MUST be greater
      than or equal to the value of MaxCPB given in Table A-1 of H.264
      [2] for the highest level.  Senders MAY use this knowledge to
      construct coded video streams with greater variation of bitrate
      than can be achieved with the MaxCPB value in Table A-1 of H.264
      [2].

         Informative note: The coded picture buffer is used in the
         hypothetical reference decoder (Annex C of H.264).  The use of
         the hypothetical reference decoder is recommended in H.264
         encoders to verify that the produced bitstream conforms to the
         standard and to control the output bitrate.  Thus, the coded
         picture buffer is conceptually independent of any other
         potential buffers in the receiver, including de-interleaving
         and de-jitter buffers.  The coded picture buffer need not be
         implemented in decoders as specified in Annex C of H.264, but
         rather standard-compliant decoders can have any buffering
         arrangements provided that they can decode standard-compliant
         bitstreams.  Thus, in practice, the input buffer for a video
         decoder can be integrated with de-interleaving and de-jitter
         buffers of the receiver.







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   max-dpb:  The value of max-dpb is an integer indicating the maximum
      decoded picture buffer size in units of 8/3 macroblocks.  The max-
      dpb parameter signals that the receiver has more memory than the
      minimum amount of decoded picture buffer memory required by the
      signaled highest level conveyed in the value of the
      profile-level-id parameter or the max-recv-level parameter.  When
      max-dpb is signaled, the receiver MUST be able to decode NAL unit
      streams that conform to the signaled highest level, with the
      exception that the MaxDpbMbs value in Table A-1 of H.264 [2] for
      the signaled highest level is replaced with the value of max-dpb *
      3 / 8.  Consequently, a receiver that signals max-dpb MUST be
      capable of storing the following number of decoded frames,
      complementary field pairs, and non-paired fields in its decoded
      picture buffer:

         Min(max-dpb * 3 / 8 / ( PicWidthInMbs * FrameHeightInMbs), 16)

      Wherein PicWidthInMbs and FrameHeightInMbs are defined in H.264
      [2].

      The value of max-dpb MUST be greater than or equal to the value of
      MaxDpbMbs * 3 / 8, wherein the value of MaxDpbMbs is given in
      Table A-1 of H.264 [2] for the highest level.  Senders MAY use
      this knowledge to construct coded video streams with improved
      compression.

         Informative note: This parameter was added primarily to
         complement a similar codepoint in the ITU-T Recommendation
         H.245, so as to facilitate signaling gateway designs.  The
         decoded picture buffer stores reconstructed samples.  There is
         no relationship between the size of the decoded picture buffer
         and the buffers used in RTP, especially de-interleaving and
         de-jitter buffers.

         Informative note: In RFC 3984, which is obsoleted by RFC 6184,
         the unit of this parameter was 1024 bytes.  The unit has been
         changed to 8/3 macroblocks in this document.  The reason for
         this change was due to the changes from the 2003 version of the
         H.264 specification referenced by RFC 3984 to the 2010 version
         of the H.264 specification referenced by this document,
         particularly the changes to Table A-1 in the H.264
         specification due to addition of color formats and bit depths
         not supported earlier.  The changed semantics of this parameter
         keeps backward compatibility to RFC 3984 and supports all
         profiles defined in the 2010 version of the H.264
         specification.





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   max-br:  The value of max-br is an integer indicating the maximum
      video bitrate in units of 1000 bits per second for the VCL HRD
      parameters and in units of 1200 bits per second for the NAL HRD
      parameters.  Note that this parameter does not use units of
      cpbBrVclFactor and cpbBrNALFactor (see Table A-1 of H.264 [2]).

      The max-br parameter signals that the video decoder of the
      receiver is capable of decoding video at a higher bitrate than is
      required by the signaled highest level conveyed in the value of
      the profile-level-id parameter or the max-recv-level parameter.

      When max-br is signaled, the video codec of the receiver MUST be
      able to decode NAL unit streams that conform to the signaled
      highest level, with the following exceptions in the limits
      specified by the highest level:

      o The value of max-br (after taking cpbBrVclFactor and
        cpbBrNALFactor into consideration when needed) replaces the
        MaxBR value in Table A-1 of H.264 [2] for the highest level.

      o When the max-cpb parameter is not present, the result of the
        following formula replaces the value of MaxCPB in Table A-1 of
        H.264 [2]: (MaxCPB of the signaled level) * max-br / (MaxBR of
        the signaled highest level).

      For example, if a receiver signals capability for Main profile
      Level 1.2 with max-br equal to 1550, this indicates a maximum
      video bitrate of 1550 kbits/sec for VCL HRD parameters, a maximum
      video bitrate of 1860 kbits/sec for NAL HRD parameters, and a CPB
      size of 4036458 bits (1550000 / 384000 * 1000 * 1000).

      The value of max-br (after taking cpbBrVclFactor and
      cpbBrNALFactor into consideration when needed) MUST be greater
      than or equal to the value MaxBR given in Table A-1 of H.264 [2]
      for the signaled highest level.

      Senders MAY use this knowledge to send higher bitrate video as
      allowed in the level definition of Annex A of H.264 to achieve
      improved video quality.

         Informative note: This parameter was added primarily to
         complement a similar codepoint in the ITU-T Recommendation
         H.245, so as to facilitate signaling gateway designs.  The
         assumption that the network is capable of handling such
         bitrates at any given time cannot be made from the value of
         this parameter.  In particular, no conclusion can be drawn that
         the signaled bitrate is possible under congestion control
         constraints.



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   redundant-pic-cap:  This parameter signals the capabilities of a
      receiver implementation.  When equal to 0, the parameter indicates
      that the receiver makes no attempt to use redundant coded pictures
      to correct incorrectly decoded primary coded pictures.  When equal
      to 0, the receiver is not capable of using redundant slices;
      therefore, a sender SHOULD avoid sending redundant slices to save
      bandwidth.  When equal to 1, the receiver is capable of decoding
      any such redundant slice that covers a corrupted area in a primary
      decoded picture (at least partly), and therefore a sender MAY send
      redundant slices.  When the parameter is not present, a value of 0
      MUST be used for redundant-pic-cap.  When present, the value of
      redundant-pic-cap MUST be either 0 or 1.

      When the profile-level-id parameter is present in the same
      signaling as the redundant-pic-cap parameter and the profile
      indicated in profile-level-id is such that it disallows the use of
      redundant coded pictures (e.g., Main profile), the value of
      redundant-pic-cap MUST be equal to 0.  When a receiver indicates
      redundant-pic-cap equal to 0, the received stream SHOULD NOT
      contain redundant coded pictures.

         Informative note: Even if redundant-pic-cap is equal to 0, the
         decoder is able to ignore redundant codec pictures provided
         that the decoder supports a profile (Baseline, Extended) in
         which redundant coded pictures are allowed.

         Informative note: Even if redundant-pic-cap is equal to 1, the
         receiver may also choose other error concealment strategies to
         replace or complement decoding of redundant slices.

   sprop-parameter-sets:  This parameter MAY be used to convey any
      sequence and picture parameter set NAL units (herein referred to
      as the initial parameter set NAL units) that can be placed in the
      NAL unit stream to precede any other NAL units in decoding order.
      The parameter MUST NOT be used to indicate codec capability in any
      capability exchange procedure.  The value of the parameter is a
      comma-separated (',') list of base64 RFC 4648 [9] representations
      of parameter set NAL units as specified in Sections 7.3.2.1 and
      7.3.2.2 of H.264 [2].  Note that the number of bytes in a
      parameter set NAL unit is typically less than 10, but a picture
      parameter set NAL unit can contain several hundred bytes.

         Informative note: When several payload types are offered in the
         SDP Offer/Answer model, each with its own sprop-parameter-sets
         parameter, the receiver cannot assume that those parameter sets
         do not use conflicting storage locations (i.e., identical
         values of parameter set identifiers).  Therefore, a receiver




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         should buffer all sprop-parameter-sets and make them available
         to the decoder instance that decodes a certain payload type.

      The sprop-parameter-sets parameter MUST only contain parameter
      sets that are conforming to the profile-level-id, i.e., the subset
      of coding tools indicated by any of the parameter sets MUST be
      equal to the default sub-profile, and the level indicated by any
      of the parameter sets MUST be equal to the default level.

   sprop-level-parameter-sets:  This parameter MAY be used to convey any
      sequence and picture parameter set NAL units (herein referred to
      as the initial parameter set NAL units) that can be placed in the
      NAL unit stream to precede any other NAL units in decoding order
      and that are associated with one or more levels different than the
      default level.  The parameter MUST NOT be used to indicate codec
      capability in any capability exchange procedure.

      The sprop-level-parameter-sets parameter contains parameter sets
      for one or more levels that are different than the default level.
      All parameter sets associated with one level are clustered and
      prefixed with a three-byte field that has the same syntax as
      profile-level-id.  This enables the receiver to install the
      parameter sets for one level and discard the rest.  The three-byte
      field is named PLId, and all parameter sets associated with one
      level are named PSL, which has the same syntax as sprop-parameter-
      sets.  Parameter sets for each level are represented in the form
      of PLId:PSL, i.e., PLId followed by a colon (':') and the base64
      RFC 4648 [9] representation of the initial parameter set NAL units
      for the level.  Each pair of PLId:PSLs is also separated by a
      colon.  Note that a PSL can contain multiple parameter sets for
      that level, separated with commas (',').

      The subset of coding tools indicated by each PLId field MUST be
      equal to the default sub-profile, and the level indicated by each
      PLId field MUST be different than the default level.  All sequence
      parameter sets contained in each PSL MUST have the three bytes
      from profile_idc to level_idc, inclusive, equal to the preceding
      PLId.

         Informative note: This parameter allows for efficient level
         downgrade or upgrade in SDP Offer/Answer and out-of-band
         transport of parameter sets simultaneously.

   use-level-src-parameter-sets:  This parameter MAY be used to indicate
      a receiver capability.  The value MAY be equal to either 0 or 1.
      When the parameter is not present, the value MUST be inferred to
      be equal to 0.  The value 0 indicates that the receiver does not
      understand the sprop-level-parameter-sets parameter, does not



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      understand the "fmtp" source attribute as specified in Section 6.3
      of RFC 5576 [14], will ignore sprop-level-parameter-sets when
      present, and will ignore sprop-parameter-sets when conveyed using
      the "fmtp" source attribute.  The value 1 indicates that the
      receiver understands the sprop-level-parameter-sets parameter,
      understands the "fmtp" source attribute as specified in Section
      6.3 of RFC 5576 [14], and is capable of using parameter sets
      contained in the sprop-level-parameter-sets or contained in the
      sprop-parameter-sets that is conveyed using the "fmtp" source
      attribute.

         Informative note: An RFC 3984 receiver does not understand
         sprop-level-parameter-sets, use-level-src-parameter-sets, or
         the "fmtp" source attribute as specified in Section 6.3 of RFC
         5576 [14].  Therefore, during SDP Offer/Answer, an RFC 3984
         receiver as the answerer will simply ignore sprop-level-
         parameter-sets when present in an offer and sprop-parameter-
         sets conveyed using the "fmtp" source attribute, as specified
         in Section 6.3 of RFC 5576 [14].  Assume that the offered
         payload type was accepted at a level lower than the default
         level.  If the offered payload type included sprop-level-
         parameter-sets or included sprop-parameter-sets conveyed using
         the "fmtp" source attribute and if the offerer sees that the
         answerer has not included use-level-src-parameter-sets equal to
         1 in the answer, the offerer knows that in-band transport of
         parameter sets is needed.

   in-band-parameter-sets:  This parameter MAY be used to indicate a
      receiver capability.  The value MAY be equal to either 0 or 1.
      The value 1 indicates that the receiver discards out-of-band
      parameter sets in sprop-parameter-sets and sprop-level-parameter-
      sets; therefore, the sender MUST transmit all parameter sets in-
      band.  The value 0 indicates that the receiver utilizes out-of-
      band parameter sets included in sprop-parameter-sets and/or sprop-
      level-parameter-sets.  However, in this case, the sender MAY still
      choose to send parameter sets in-band.  When in-band-parameter-
      sets is equal to 1, use-level-src-parameter-sets MUST NOT be
      present or MUST be equal to 0.  When the parameter is not present,
      this receiver capability is not specified, and therefore the
      sender MAY send out-of-band parameter sets only, it MAY send in-
      band-parameter-sets only, or it MAY send both.

   level-asymmetry-allowed:  This parameter MAY be used in SDP Offer/
      Answer to indicate whether level asymmetry, i.e., sending media
      encoded at a different level in the offerer-to-answerer direction
      than the level in the answerer-to-offerer direction, is allowed.
      The value MAY be equal to either 0 or 1.  When the parameter is
      not present, the value MUST be inferred to be equal to 0.  The



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      value 1 in both the offer and the answer indicates that level
      asymmetry is allowed.  The value of 0 in either the offer or the
      answer indicates that level asymmetry is not allowed.

      If level-asymmetry-allowed is equal to 0 (or not present) in
      either the offer or the answer, level asymmetry is not allowed.
      In this case, the level to use in the direction from the offerer
      to the answerer MUST be the same as the level to use in the
      opposite direction.

   packetization-mode:  This parameter signals the properties of an RTP
      payload type or the capabilities of a receiver implementation.
      Only a single configuration point can be indicated; thus, when
      capabilities to support more than one packetization-mode are
      declared, multiple configuration points (RTP payload types) must
      be used.

      When the value of packetization-mode is equal to 0 or
      packetization-mode is not present, the single NAL mode MUST be
      used.  This mode is in use in standards using ITU-T Recommendation
      H.241 [3] (see Section 12.1).  When the value of packetization-
      mode is equal to 1, the non-interleaved mode MUST be used.  When
      the value of packetization-mode is equal to 2, the interleaved
      mode MUST be used.  The value of packetization-mode MUST be an
      integer in the range of 0 to 2, inclusive.

   sprop-interleaving-depth:  This parameter MUST NOT be present when
      packetization-mode is not present or the value of packetization-
      mode is equal to 0 or 1.  This parameter MUST be present when the
      value of packetization-mode is equal to 2.

      This parameter signals the properties of an RTP packet stream.  It
      specifies the maximum number of VCL NAL units that precede any VCL
      NAL unit in the RTP packet stream in transmission order and that
      follow the VCL NAL unit in decoding order.  Consequently, it is
      guaranteed that receivers can reconstruct NAL unit decoding order
      when the buffer size for NAL unit decoding order recovery is at
      least the value of sprop-interleaving-depth + 1 in terms of VCL
      NAL units.

      The value of sprop-interleaving-depth MUST be an integer in the
      range of 0 to 32767, inclusive.

   sprop-deint-buf-req:  This parameter MUST NOT be present when
      packetization-mode is not present or the value of packetization-
      mode is equal to 0 or 1.  It MUST be present when the value of
      packetization-mode is equal to 2.




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      sprop-deint-buf-req signals the required size of the
      de-interleaving buffer for the RTP packet stream.  The value of
      the parameter MUST be greater than or equal to the maximum buffer
      occupancy (in units of bytes) required in such a de-interleaving
      buffer that is specified in Section 7.2 of RFC 6184 [1].  It is
      guaranteed that receivers can perform the de-interleaving of
      interleaved NAL units into NAL unit decoding order, when the
      de-interleaving buffer size is at least the value of
      sprop-deint-buf-req in terms of bytes.

      The value of sprop-deint-buf-req MUST be an integer in the range
      of 0 to 4294967295, inclusive.

         Informative note: sprop-deint-buf-req indicates the required
         size of the de-interleaving buffer only.  When network jitter
         can occur, an appropriately sized jitter buffer has to be
         provisioned for as well.

   deint-buf-cap:  This parameter signals the capabilities of a receiver
      implementation and indicates the amount of de-interleaving buffer
      space in units of bytes that the receiver has available for
      reconstructing the NAL unit decoding order.  A receiver is able to
      handle any stream for which the value of the sprop-deint-buf-req
      parameter is smaller than or equal to this parameter.

      If the parameter is not present, then a value of 0 MUST be used
      for deint-buf-cap.  The value of deint-buf-cap MUST be an integer
      in the range of 0 to 4294967295, inclusive.

         Informative note: deint-buf-cap indicates the maximum possible
         size of the de-interleaving buffer of the receiver only.  When
         network jitter can occur, an appropriately sized jitter buffer
         has to be provisioned for as well.

   sprop-init-buf-time:  This parameter MAY be used to signal the
      properties of an RTP packet stream.  The parameter MUST NOT be
      present if the value of packetization-mode is equal to 0 or 1.

      The parameter signals the initial buffering time that a receiver
      MUST wait before starting decoding to recover the NAL unit
      decoding order from the transmission order.  The parameter is the
      maximum value of (decoding time of the NAL unit - transmission
      time of a NAL unit), assuming reliable and instantaneous
      transmission, the same timeline for transmission and decoding, and
      commencement of decoding when the first packet arrives.

      An example of specifying the value of sprop-init-buf-time follows.
      A NAL unit stream is sent in the following interleaved order, in



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      which the value corresponds to the decoding time and the
      transmission order is from left to right:

         0 2 1 3 5 4 6 8 7 ...

      Assuming a steady transmission rate of NAL units, the transmission
      times are:

         0 1 2 3 4 5 6 7 8 ...

      Subtracting the decoding time from the transmission time column-
      wise results in the following series:

         0 -1 1 0 -1 1 0 -1 1 ...

      Thus, in terms of intervals of NAL unit transmission times, the
      value of sprop-init-buf-time in this example is 1.  The parameter
      is coded as a non-negative base10 integer representation in clock
      ticks of a 90-kHz clock.  If the parameter is not present, then no
      initial buffering time value is defined.  Otherwise, the value of
      sprop-init-buf-time MUST be an integer in the range of 0 to
      4294967295, inclusive.

      In addition to the signaled sprop-init-buf-time, receivers SHOULD
      take into account the transmission delay jitter buffering,
      including buffering for the delay jitter caused by mixers,
      translators, gateways, proxies, traffic-shapers, and other network
      elements.

   sprop-max-don-diff:  This parameter MAY be used to signal the
      properties of an RTP packet stream.  It MUST NOT be used to signal
      transmitter, receiver, or codec capabilities.  The parameter MUST
      NOT be present if the value of packetization-mode is equal to 0 or
      1. sprop-max-don-diff is an integer in the range of 0 to 32767,
      inclusive.  If sprop-max-don-diff is not present, the value of the
      parameter is unspecified. sprop-max-don-diff is calculated as
      follows:

         sprop-max-don-diff = max{AbsDON(i) - AbsDON(j)}, for any i and
         any j>i,

      where i and j indicate the index of the NAL unit in the
      transmission order and AbsDON denotes a decoding order number of
      the NAL unit that does not wrap around to 0 after 65535.  In other
      words, AbsDON is calculated as follows: let m and n be consecutive
      NAL units in transmission order.  For the very first NAL unit in
      transmission order (whose index is 0), AbsDON(0) = DON(0).  For
      other NAL units, AbsDON is calculated as follows:



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      If DON(m) == DON(n), AbsDON(n) = AbsDON(m)

      If (DON(m) < DON(n) and DON(n) - DON(m) < 32768),

      AbsDON(n) = AbsDON(m) + DON(n) - DON(m)

      If (DON(m) > DON(n) and DON(m) - DON(n) >= 32768),

      AbsDON(n) = AbsDON(m) + 65536 - DON(m) + DON(n)

      If (DON(m) < DON(n) and DON(n) - DON(m) >= 32768),

      AbsDON(n) = AbsDON(m) - (DON(m) + 65536 - DON(n))

      If (DON(m) > DON(n) and DON(m) - DON(n) < 32768),

      AbsDON(n) = AbsDON(m) - (DON(m) - DON(n))

      where DON(i) is the decoding order number of the NAL unit having
      index i in the transmission order.  The decoding order number is
      specified in Section 5.5 of RFC 6184 [1].

         Informative note: Receivers may use sprop-max-don-diff to
         trigger which NAL units in the receiver buffer can be passed to
         the decoder.

   max-rcmd-nalu-size:  This parameter MAY be used to signal the
      capabilities of a receiver.  The parameter MUST NOT be used for
      any other purposes.  The value of the parameter indicates the
      largest NALU size in bytes that the receiver can handle
      efficiently.  The parameter value is a recommendation, not a
      strict upper boundary.  The sender MAY create larger NALUs but
      must be aware that the handling of these may come at a higher cost
      than NALUs conforming to the limitation.

      The value of max-rcmd-nalu-size MUST be an integer in the range of
      0 to 4294967295, inclusive.  If this parameter is not specified,
      no known limitation to the NALU size exists.  Senders still have
      to consider the MTU size available between the sender and the
      receiver and SHOULD run MTU discovery for this purpose.

      This parameter is motivated by, for example, an IP to H.223 video
      telephony gateway, where NALUs smaller than the H.223 transport
      data unit will be more efficient.  A gateway may terminate IP;
      thus, MTU discovery will normally not work beyond the gateway.

         Informative note: Setting this parameter to a lower than
         necessary value may have a negative impact.



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   sar-understood:  This parameter MAY be used to indicate a receiver
      capability and nothing else.  The parameter indicates the maximum
      value of aspect_ratio_idc (specified in H.264 [2]) smaller than
      255 that the receiver understands.  Table E-1 of H.264 [2]
      specifies aspect_ratio_idc equal to 0 as "unspecified"; 1 to 16,
      inclusive, as specific Sample Aspect Ratios (SARs); 17 to 254,
      inclusive, as "reserved"; and 255 as the Extended SAR, for which
      SAR width and SAR height are explicitly signaled.  Therefore, a
      receiver with a decoder according to H.264 [2] understands
      aspect_ratio_idc in the range of 1 to 16, inclusive, and
      aspect_ratio_idc equal to 255, in the sense that the receiver
      knows exactly what the SAR is.  For such a receiver, the value of
      sar-understood is 16.  In the future, if Table E-1 of H.264 [2] is
      extended, e.g., such that the SAR for aspect_ratio_idc equal to 17
      is specified, then for a receiver with a decoder that understands
      the extension, the value of sar-understood is 17.  For a receiver
      with a decoder according to the 2003 version of H.264 [2], the
      value of sar-understood is 13, as the minimum reserved
      aspect_ratio_idc therein is 14.

      When sar-understood is not present, the value MUST be inferred to
      be equal to 13.

   sar-supported:  This parameter MAY be used to indicate a receiver
      capability and nothing else.  The value of this parameter is an
      integer in the range of 1 to sar-understood, inclusive, equal to
      255.  The value of sar-supported equal to N smaller than 255
      indicates that the receiver supports all the SARs corresponding to
      H.264 aspect_ratio_idc values (see Table E-1 of H.264 [2]) in the
      range from 1 to N, inclusive, without geometric distortion.  The
      value of sar-supported equal to 255 indicates that the receiver
      supports all sample aspect ratios that are expressible using two
      16-bit integer values as the numerator and denominator, i.e.,
      those that are expressible using the H.264 aspect_ratio_idc value
      of 255 (Extended_SAR, see Table E-1 of H.264 [2]), without
      geometric distortion.

      H.264-compliant encoders SHOULD NOT send an aspect_ratio_idc equal
      to 0 or an aspect_ratio_idc larger than sar-understood and smaller
      than 255.  H.264-compliant encoders SHOULD send an
      aspect_ratio_idc that the receiver is able to display without
      geometrical distortion.  However, H.264-compliant encoders MAY
      choose to send pictures using any SAR.

      Note that the actual sample aspect ratio or extended sample aspect
      ratio, when present, of the stream is conveyed in the Video
      Usability Information (VUI) part of the sequence parameter set.




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   Encoding considerations:  This type is only defined for transfer via
      RTP (RFC 3550) and is framed and binary (see Section 4.8 in RFC
      4288).

   Security considerations:  See Section 9 of RFC 6185.

   Interoperability considerations:  None

   Published specification:  RFC 6185 and its reference section

   Applications that use this media type:  Video streaming and
      conferencing applications

   Additional information:  None

      Magic number(s):

      File extension(s):

      Macintosh file type code(s):

   Person & email address to contact for further information:

      Tom Kristensen <tom.kristensen@tandberg.com>, <tomkri@ifi.uio.no>

   Intended usage:  COMMON

   Restrictions on usage:  This type depends on RTP framing; hence, it
      is only defined for transfer via RTP (see RFC 3550).  Transport
      within other framing protocols is not defined at this time.

   Author:  Tom Kristensen

   Change controller:  IETF Audio/Video Transport Working Group
      delegated from the IESG

7.  Mapping to SDP

   The mapping of the above defined payload format media subtype and its
   parameters SHALL be done according to Section 3 of RFC 4855 [10].

   An example of the "fmtp" attribute in the media representation of a
   level 2.2 bitstream is as follows:

      a=fmtp:97 profile-level-id=008016






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7.1.  Offer/Answer Considerations

   When H264-RCDO is offered over RTP using SDP in an Offer/Answer model
   [5] for unicast and multicast usage, the limitations and rules
   described in Section 8.2.2 of RFC 6184 [1] apply.  Note that the
   profile_idc byte of the H264-RCDO profile-level-id parameter can only
   take the value of 0 (no profile).

   For interoperability with systems not supporting H264-RCDO, it is
   RECOMMENDED to offer the H264 media subtype as well.  As specified in
   RFC 3264 [5], listing the payload number for H264-RCDO before H264 in
   the format list on the "m=" line signals that H264-RCDO is preferred
   over H264.  Following is an example where this scheme is applied:

      m=video 5555 RTP/AVP 97 98

      a=rtpmap:97 H264-RCDO/90000

      a=fmtp:97 profile-level-id=008016;max-mbps=42000;max-smbps=323500

      a=rtpmap:98 H264/90000

      a=fmtp:98 profile-level-id=428016;max-mbps=35000;max-smbps=323500

7.2.  Declarative SDP Considerations

   When H264-RCDO over RTP is offered with SDP in a declarative style,
   as in the Real Time Streaming Protocol (RTSP) [11] or the Session
   Announcement Protocol (SAP) [12], the considerations in Section 8.2.3
   of RFC 6184 [1] apply.  Note that the profile_idc byte of the H264-
   RCDO profile-level-id parameter can only take the value of 0 (no
   profile).

8.  IANA Considerations

   IANA has registered H264-RCDO as specified in Section 6.1.  The media
   subtype has also been added to the IANA registry for "RTP Payload
   Format MIME types" (http://www.iana.org).

9.  Security Considerations

   RTP packets using the payload format defined in this specification
   are subject to the security considerations discussed in the RTP
   specification [6] and in any applicable RTP profile.  Refer also to
   the security considerations of the RTP Payload Format for H.264 Video
   specification in RFC 6184 [1].  No additional security considerations
   are introduced by this specification.




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10.  Acknowledgements

   The authors would like to acknowledge Gisle Bjoentegaard and Arild
   Fuldseth for their technical contribution to the specification.  In
   the final phases, Roni Even did a helpful review.

11.  References

11.1.  Normative References

   [1]   Wang, Y., Even, R., Kristensen, T., and R. Jesup, "RTP Payload
         Format for H.264 Video", RFC 6184, May 2011.

   [2]   International Telecommunications Union, "Advanced video coding
         for generic audiovisual services", ITU-T Recommendation H.264,
         March 2010.

   [3]   International Telecommunications Union, "Extended video
         procedures and control signals for H.300-series terminals",
         ITU-T Recommendation H.241, May 2006.

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

   [5]   Rosenberg, J. and H. Schulzrinne, "An Offer/Answer Model with
         Session Description Protocol (SDP)", RFC 3264, June 2002.

   [6]   Schulzrinne, H., Casner, S., Frederick, R., and V. Jacobson,
         "RTP: A Transport Protocol for Real-Time Applications", STD 64,
         RFC 3550, July 2003.

   [7]   Schulzrinne, H. and S. Casner, "RTP Profile for Audio and Video
         Conferences with Minimal Control", STD 65, RFC 3551, July 2003.

   [8]   Handley, M., Jacobson, V., and C. Perkins, "SDP: Session
         Description Protocol", RFC 4566, July 2006.

   [9]   Josefsson, S., "The Base16, Base32, and Base64 Data Encodings",
         RFC 4648, October 2006.

   [10]  Casner, S., "Media Type Registration of RTP Payload Formats",
         RFC 4855, February 2007.

11.2.  Informative References

   [11]  Schulzrinne, H., Rao, A., and R. Lanphier, "Real Time Streaming
         Protocol (RTSP)", RFC 2326, April 1998.




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   [12]  Handley, M., Perkins, C., and E. Whelan, "Session Announcement
         Protocol", RFC 2974, October 2000.

   [13]  Freed, N. and J. Klensin, "Media Type Specifications and
         Registration Procedures", BCP 13, RFC 4288, December 2005.

   [14]  Lennox, J., Ott, J., and T. Schierl, "Source-Specific Media
         Attributes in the Session Description Protocol (SDP)",
         RFC 5576, June 2009.

Authors' Addresses

   Tom Kristensen
   TANDBERG
   Philip Pedersens vei 22
   N-1366 Lysaker
   Norway

   Phone: +47 67125125
   EMail: tom.kristensen@tandberg.com, tomkri@ifi.uio.no
   URI:   http://www.tandberg.com


   Patrick Luthi
   TANDBERG
   Philip Pedersens vei 22
   N-1366 Lysaker
   Norway

   EMail: patrick.luthi@tandberg.com
   URI:   http://www.tandberg.com




















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  1. RFC 6185