From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc2508.txt | 1347 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1347 insertions(+) create mode 100644 doc/rfc/rfc2508.txt (limited to 'doc/rfc/rfc2508.txt') diff --git a/doc/rfc/rfc2508.txt b/doc/rfc/rfc2508.txt new file mode 100644 index 0000000..0515519 --- /dev/null +++ b/doc/rfc/rfc2508.txt @@ -0,0 +1,1347 @@ + + + + + + +Network Working Group S. Casner +Request for Comments: 2508 Cisco Systems +Category: Standards Track V. Jacobson + Cisco Systems + February 1999 + + + Compressing IP/UDP/RTP Headers for Low-Speed Serial Links + +Status of this Memo + + This document specifies an Internet standards track protocol for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "Internet + Official Protocol Standards" (STD 1) for the standardization state + and status of this protocol. Distribution of this memo is unlimited. + +Copyright Notice + + Copyright (C) The Internet Society (1999). All Rights Reserved. + +Abstract + + This document describes a method for compressing the headers of + IP/UDP/RTP datagrams to reduce overhead on low-speed serial links. + In many cases, all three headers can be compressed to 2-4 bytes. + + Comments are solicited and should be addressed to the working group + mailing list rem-conf@es.net and/or the author(s). + + The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", + "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this + document are to be interpreted as described in RFC 2119. + +1. Introduction + + Since the Real-time Transport Protocol was published as an RFC [1], + there has been growing interest in using RTP as one step to achieve + interoperability among different implementations of network + audio/video applications. However, there is also concern that the + 12-byte RTP header is too large an overhead for 20-byte payloads when + operating over low speed lines such as dial-up modems at 14.4 or 28.8 + kb/s. (Some existing applications operating in this environment use + an application-specific protocol with a header of a few bytes that + has reduced functionality relative to RTP.) + + + + + + +Casner & Jacobson Standards Track [Page 1] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + Header size may be reduced through compression techniques as has been + done with great success for TCP [2]. In this case, compression might + be applied to the RTP header alone, on an end-to-end basis, or to the + combination of IP, UDP and RTP headers on a link-by-link basis. + Compressing the 40 bytes of combined headers together provides + substantially more gain than compressing 12 bytes of RTP header alone + because the resulting size is approximately the same (2-4 bytes) in + either case. Compressing on a link-by-link basis also provides + better performance because the delay and loss rate are lower. + Therefore, the method defined here is for combined compression of IP, + UDP and RTP headers on a link-by-link basis. + + This document defines a compression scheme that may be used with + IPv4, IPv6 or packets encapsulated with more than one IP header, + though the initial focus is on IPv4. The IP/UDP/RTP compression + defined here is intended to fit within the more general compression + framework specified in [3] for use with both IPv6 and IPv4. That + framework defines TCP and non-TCP as two classes of transport above + IP. This specification creates IP/UDP/RTP as a third class extracted + from the non-TCP class. + +2. Assumptions and Tradeoffs + + The goal of this compression scheme is to reduce the IP/UDP/RTP + headers to two bytes for most packets in the case where no UDP + checksums are being sent, or four bytes with checksums. It is + motivated primarily by the specific problem of sending audio and + video over 14.4 and 28.8 dialup modems. These links tend to provide + full-duplex communication, so the protocol takes advantage of that + fact, though the protocol may also be used with reduced performance + on simplex links. This compression scheme performs best on local + links with low round-trip-time. + + This specification does not address segmentation and preemption of + large packets to reduce the delay across the slow link experienced by + small real-time packets, except to identify in Section 4 some + interactions between segmentation and compression that may occur. + Segmentation schemes may be defined separately and used in + conjunction with the compression defined here. + + It should be noted that implementation simplicity is an important + factor to consider in evaluating a compression scheme. + Communications servers may need to support compression over perhaps + as many as 100 dial-up modem lines using a single processor. + Therefore, it may be appropriate to make some simplifications in the + design at the expense of generality, or to produce a flexible design + that is general but can be subsetted for simplicity. Higher + compression gain might be achieved by communicating more complex + + + +Casner & Jacobson Standards Track [Page 2] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + models for the changing header fields from the compressor to the + decompressor, but that complexity is deemed unnecessary. The next + sections discuss some of the tradeoffs listed here. + +2.1. Simplex vs. Full Duplex + + In the absence of other constraints, a compression scheme that worked + over simplex links would be preferred over one that did not. + However, operation over a simplex link requires periodic refreshes + with an uncompressed packet header to restore compression state in + case of error. If an explicit error signal can be returned instead, + the delay to recovery may be shortened substantially. The overhead + in the no-error case is also reduced. To gain these performance + improvements, this specification includes an explicit error + indication sent on the reverse path. + + On a simplex link, it would be possible to use a periodic refresh + instead. Whenever the decompressor detected an error in a particular + packet stream, it would simply discard all packets in that stream + until an uncompressed header was received for that stream, and then + resume decompression. The penalty would be the potentially large + number of packets discarded. The periodic refresh method described + in Section 3.3 of [3] applies to IP/UDP/RTP compression on simplex + links or links with high delay as well as to other non-TCP packet + streams. + +2.2. Segmentation and Layering + + Delay induced by the time required to send a large packet over the + slow link is not a problem for one-way audio, for example, because + the receiver can adapt to the variance in delay. However, for + interactive conversations, minimizing the end-to-end delay is + critical. Segmentation of large, non-real-time packets to allow + small real-time packets to be transmitted between segments can reduce + the delay. + + This specification deals only with compression and assumes + segmentation, if included, will be handled as a separate layer. It + would be inappropriate to integrate segmentation and compression in + such a way that the compression could not be used by itself in + situations where segmentation was deemed unnecessary or impractical. + Similarly, one would like to avoid any requirements for a reservation + protocol. The compression scheme can be applied locally on the two + ends of a link independent of any other mechanisms except for the + requirements that the link layer provide some packet type codes, a + packet length indication, and good error detection. + + + + + +Casner & Jacobson Standards Track [Page 3] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + Conversely, separately compressing the IP/UDP and RTP layers loses + too much of the compression gain that is possible by treating them + together. Crossing these protocol layer boundaries is appropriate + because the same function is being applied across all layers. + +3. The Compression Algorithm + + The compression algorithm defined in this document draws heavily upon + the design of TCP/IP header compression as described in RFC 1144 [2]. + Readers are referred to that RFC for more information on the + underlying motivations and general principles of header compression. + +3.1. The basic idea + + In TCP header compression, the first factor-of-two reduction in data + rate comes from the observation that half of the bytes in the IP and + TCP headers remain constant over the life of the connection. After + sending the uncompressed header once, these fields may be elided from + the compressed headers that follow. The remaining compression comes + from differential coding on the changing fields to reduce their size, + and from eliminating the changing fields entirely for common cases by + calculating the changes from the length of the packet. This length + is indicated by the link-level protocol. + + For RTP header compression, some of the same techniques may be + applied. However, the big gain comes from the observation that + although several fields change in every packet, the difference from + packet to packet is often constant and therefore the second-order + difference is zero. By maintaining both the uncompressed header and + the first-order differences in the session state shared between the + compressor and decompressor, all that must be communicated is an + indication that the second-order difference was zero. In that case, + the decompressor can reconstruct the original header without any loss + of information simply by adding the first-order differences to the + saved uncompressed header as each compressed packet is received. + + Just as TCP/IP header compression maintains shared state for multiple + simultaneous TCP connections, this IP/UDP/RTP compression SHOULD + maintain state for multiple session contexts. A session context is + defined by the combination of the IP source and destination + addresses, the UDP source and destination ports, and the RTP SSRC + field. A compressor implementation might use a hash function on + these fields to index a table of stored session contexts. The + compressed packet carries a small integer, called the session context + identifier or CID, to indicate in which session context that packet + should be interpreted. The decompressor can use the CID to index its + table of stored session contexts directly. + + + + +Casner & Jacobson Standards Track [Page 4] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + Because the RTP compression is lossless, it may be applied to any UDP + traffic that benefits from it. Most likely, the only packets that + will benefit are RTP packets, but it is acceptable to use heuristics + to determine whether or not the packet is an RTP packet because no + harm is done if the heuristic gives the wrong answer. This does + require executing the compression algorithm for all UDP packets, or + at least those with even port numbers (see section 3.4). + + Most compressor implementations will need to maintain a "negative + cache" of packet streams that have failed to compress as RTP packets + for some number of attempts in order to avoid further attempts. + Failing to compress means that some fields in the potential RTP + header that are expected to remain constant most of the time, such as + the payload type field, keep changing. Even if the other such fields + remain constant, a packet stream with a constantly changing SSRC + field SHOULD be entered in the negative cache to avoid consuming all + of the available session contexts. The negative cache is indexed by + the source and destination IP address and UDP port pairs but not the + RTP SSRC field since the latter may be changing. When RTP + compression fails, the IP and UDP headers MAY still be compressed. + + Fragmented IP Packets that are not initial fragments and packets that + are not long enough to contain a complete UDP header MUST NOT be sent + as FULL_HEADER packets. Furthermore, packets that do not + additionally contain at least 12 bytes of UDP data MUST NOT be used + to establish RTP context. If such a packet is sent as a FULL_HEADER + packet, it MAY be followed by COMPRESSED_UDP packets but MUST NOT be + followed by COMPRESSED_RTP packets. + +3.2. Header Compression for RTP Data Packets + + In the IPv4 header, only the total length, packet ID, and header + check-sum fields will normally change. The total length is redundant + with the length provided by the link layer, and since this + compression scheme must depend upon the link layer to provide good + error detection (e.g., PPP's CRC [4]), the header checksum may also + be elided. This leaves only the packet ID, which, assuming no IP + fragmentation, would not need to be communicated. However, in order + to maintain lossless compression, changes in the packet ID will be + transmitted. The packet ID usually increments by one or a small + number for each packet. (Some systems increment the ID with the + bytes swapped, which results in slightly less compression.) In the + IPv6 base header, there is no packet ID nor header checksum and only + the payload length field changes. + + + + + + + +Casner & Jacobson Standards Track [Page 5] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + In the UDP header, the length field is redundant with the IP total + length field and the length indicated by the link layer. The UDP + check-sum field will be a constant zero if the source elects not to + generate UDP checksums. Otherwise, the checksum must be communicated + intact in order to preserve the lossless compression. Maintaining + end-to-end error detection for applications that require it is an + important principle. + + In the RTP header, the SSRC identifier is constant in a given context + since that is part of what identifies the particular context. For + most packets, only the sequence number and the timestamp will change + from packet to packet. If packets are not lost or misordered + upstream from the compressor, the sequence number will increment by + one for each packet. For audio packets of constant duration, the + timestamp will increment by the number of sample periods conveyed in + each packet. For video, the timestamp will change on the first + packet of each frame, but then stay constant for any additional + packets in the frame. If each video frame occupies only one packet, + but the video frames are generated at a constant rate, then again the + change in the timestamp from frame to frame is constant. Note that + in each of these cases the second-order difference of the sequence + number and timestamp fields is zero, so the next packet header can be + constructed from the previous packet header by adding the first-order + differences for these fields that are stored in the session context + along with the previous uncompressed header. When the second-order + difference is not zero, the magnitude of the change is usually much + smaller than the full number of bits in the field, so the size can be + reduced by encoding the new first-order difference and transmitting + it rather than the absolute value. + + The M bit will be set on the first packet of an audio talkspurt and + the last packet of a video frame. If it were treated as a constant + field such that each change required sending the full RTP header, + this would reduce the compression significantly. Therefore, one bit + in the compressed header will carry the M bit explicitly. + + If the packets are flowing through an RTP mixer, most commonly for + audio, then the CSRC list and CC count will also change. However, + the CSRC list will typically remain constant during a talkspurt or + longer, so it need be sent only when it changes. + +3.3. The protocol + + The compression protocol must maintain a collection of shared + information in a consistent state between the compressor and + decompressor. There is a separate session context for each + IP/UDP/RTP packet stream, as defined by a particular combination of + the IP source and destination addresses, UDP source and destination + + + +Casner & Jacobson Standards Track [Page 6] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + ports, and the RTP SSRC field. The number of session contexts to be + maintained MAY be negotiated between the compressor and decompressor. + Each context is identified by an 8- or 16-bit identifier, depending + upon the number of contexts negotiated, so the maximum number is + 65536. Both uncompressed and compressed packets MUST carry the + context ID and a 4-bit sequence number used to detect packet loss + between the compressor and decompressor. Each context has its own + separate sequence number space so that a single packet loss need only + invalidate one context. + + The shared information in each context consists of the following + items: + + o The full IP, UDP and RTP headers, possibly including a CSRC + list, for the last packet sent by the compressor or + reconstructed by the decompressor. + + o The first-order difference for the IPv4 ID field, initialized to + 1 whenever an uncompressed IP header for this context is + received and updated each time a delta IPv4 ID field is received + in a compressed packet. + + o The first-order difference for the RTP timestamp field, + initialized to 0 whenever an uncompressed packet for this + context is received and updated each time a delta RTP timestamp + field is received in a compressed packet. + + o The last value of the 4-bit sequence number, which is used to + detect packet loss between the compressor and decompressor. + + o The current generation number for non-differential coding of UDP + packets with IPv6 (see [3]). For IPv4, the generation number + may be set to zero if the COMPRESSED_NON_TCP packet type, + defined below, is never used. + + o A context-specific delta encoding table (see section 3.3.4) may + optionally be negotiated for each context. + + In order to communicate packets in the various uncompressed and + compressed forms, this protocol depends upon the link layer being + able to provide an indication of four new packet formats in addition + to the normal IPv4 and IPv6 packet formats: + + FULL_HEADER - communicates the uncompressed IP header plus any + following headers and data to establish the uncompressed header + state in the decompressor for a particular context. The FULL- + HEADER packet also carries the 8- or 16-bit session context + identifier and the 4-bit sequence number to establish + + + +Casner & Jacobson Standards Track [Page 7] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + synchronization between the compressor and decompressor. The + format is shown in section 3.3.1. + + COMPRESSED_UDP - communicates the IP and UDP headers compressed to + 6 or fewer bytes (often 2 if UDP checksums are disabled), followed + by any subsequent headers (possibly RTP) in uncompressed form, + plus data. This packet type is used when there are differences in + the usually constant fields of the (potential) RTP header. The + RTP header includes a potentially changed value of the SSRC field, + so this packet may redefine the session context. The format is + shown in section 3.3.3. + + COMPRESSED_RTP - indicates that the RTP header is compressed along + with the IP and UDP headers. The size of this header may still be + just two bytes, or more if differences must be communicated. This + packet type is used when the second-order difference (at least in + the usually constant fields) is zero. It includes delta encodings + for those fields that have changed by other than the expected + amount to establish the first-order differences after an + uncompressed RTP header is sent and whenever they change. The + format is shown in section 3.3.2. + + CONTEXT_STATE - indicates a special packet sent from the + decompressor to the compressor to communicate a list of context + IDs for which synchronization has or may have been lost. This + packet is only sent across the point-to-point link so it requires + no IP header. The format is shown in section 3.3.5. + + When this compression scheme is used with IPv6 as part of the general + header compression framework specified in [3], another packet type + MAY be used: + + COMPRESSED_NON_TCP - communicates the compressed IP and UDP + headers as defined in [3] without differential encoding. If it + were used for IPv4, it would require one or two bytes more than + the COMPRESSED_UDP form listed above in order to carry the IPv4 ID + field. For IPv6, there is no ID field and this non-differential + compression is more resilient to packet loss. + + Assignments of numeric codes for these packet formats in the Point- + to-Point Protocol [4] are to be made by the Internet Assigned Numbers + Authority. + +3.3.1. FULL_HEADER (uncompressed) packet format + + The definition of the FULL_HEADER packet given here is intended to be + the consistent with the definition given in [3]. Full details on + design choices are given there. + + + +Casner & Jacobson Standards Track [Page 8] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + The format of the FULL_HEADER packet is the same as that of the + original packet. In the IPv4 case, this is usually an IP header, + followed by a UDP header and UDP payload that may be an RTP header + and its payload. However, the FULL_HEADER packet may also carry IP + encapsulated packets, in which case there would be two IP headers + followed by UDP and possibly RTP. Or in the case of IPv6, the packet + may be built of some combination of IPv6 and IPv4 headers. Each + successive header is indicated by the type field of the previous + header, as usual. + + The FULL_HEADER packet differs from the corresponding normal IPv4 or + IPv6 packet in that it must also carry the compression context ID and + the 4-bit sequence number. In order to avoid expanding the size of + the header, these values are inserted into length fields in the IP + and UDP headers since the actual length may be inferred from the + length provided by the link layer. Two 16-bit length fields are + needed; these are taken from the first two available headers in the + packet. That is, for an IPv4/UDP packet, the first length field is + the total length field of the IPv4 header, and the second is the + length field of the UDP header. For an IPv4 encapsulated packet, the + first length field would come from the total length field of the + first IP header, and the second length field would come from the + total length field of the second IP header. + + As specified in Sections 5.3.2 of [3], the position of the context ID + (CID) and 4-bit sequence number varies depending upon whether 8- or + 16-bit context IDs have been selected, as shown in the following + diagram (16 bits wide, with the most-significant bit is to the left): + + For 8-bit context ID: + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |0|1| Generation| CID | First length field + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | 0 | seq | Second length field + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + For 16-bit context ID: + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |1|1| Generation| 0 | seq | First length field + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | CID | Second length field + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + + +Casner & Jacobson Standards Track [Page 9] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + The first bit in the first length field indicates the length of the + CID. The length of the CID MUST either be constant for all contexts + or two additional distinct packet types MUST be provided to + separately indicate COMPRESSED_UDP and COMPRESSED_RTP packet formats + with 8- and 16-bit CIDs. The second bit in the first length field is + 1 to indicate that the 4-bit sequence number is present, as is always + the case for this IP/UDP/RTP compression scheme. + + The generation field is used with IPv6 for COMPRESSED_NON_TCP packets + as described in [3]. For IPv4-only implementations that do not use + COMPRESSED_NON_TCP packets, the compressor SHOULD set the generation + value to zero. For consistent operation between IPv4 and IPv6, the + generation value is stored in the context when it is received by the + decompressor, and the most recent value is returned in the + CONTEXT_STATE packet. + + When a FULL_HEADER packet is received, the complete set of headers is + stored into the context selected by the context ID. The 4-bit + sequence number is also stored in the context, thereby + resynchronizing the decompressor to the compressor. + + When COMPRESSED_NON_TCP packets are used, the 4-bit sequence number + is inserted into the "Data Field" of that packet and the D bit is set + as described in Section 6 of [3]. When a COMPRESSED_NON_TCP packet + is received, the generation number is compared to the value stored in + the context. If they are not the same, the context is not up to date + and MUST be refreshed by a FULL_HEADER packet. If the generation + does match, then the compressed IP and UDP header information, the + 4-bit sequence number, and the (potential) RTP header are all stored + into the saved context. + + The amount of memory required to store the context will vary + depending upon how many encapsulating headers are included in the + FULL_HEADER packet. The compressor and decompressor MAY negotiate a + maximum header size. + +3.3.2. COMPRESSED_RTP packet format + + When the second-order difference of the RTP header from packet to + packet is zero, the decompressor can reconstruct a packet simply by + adding the stored first-order differences to the stored uncompressed + header representing the previous packet. All that need be + communicated is the session context identifier and a small sequence + number (not related to the RTP sequence number) to maintain + synchronization and detect packet loss between the compressor and + decompressor. + + + + + +Casner & Jacobson Standards Track [Page 10] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + If the second-order difference of the RTP header is not zero for some + fields, the new first-order difference for just those fields is + communicated using a compact encoding. The new first-order + difference values are added to the corresponding fields in the + uncompressed header in the decompressor's session context, and are + also stored explicitly in the context to be added to the + corresponding fields again on each subsequent packet in which the + second-order difference is zero. Each time the first-order + difference changes, it is transmitted and stored in the context. + + In practice, the only fields for which it is useful to store the + first-order difference are the IPv4 ID field and the RTP timestamp. + For the RTP sequence number field, the usual increment is 1. If the + sequence number changes by other than 1, the difference must be + communicated but does not set the expected difference for the next + packet. Instead, the expected first-order difference remains fixed + at 1 so that the difference need not be explicitly communicated on + the next packet assuming it is in order. + + For the RTP timestamp, when a FULL_HEADER, COMPRESSED_NON_TCP or + COMPRESSED_UDP packet is sent to refresh the RTP state, the stored + first-order difference is initialized to zero. If the timestamp is + the same on the next packet (e.g., same video frame), then the + second-order difference is zero. Otherwise, the difference between + the timestamps of the two packets is transmitted as the new first- + order difference to be added to the timestamp in the uncompressed + header stored in the decompressor's context and also stored as the + first-order difference in that context. Each time the first-order + difference changes on subsequent packets, that difference is again + transmitted and used to update the context. + + Similarly, since the IPv4 ID field frequently increments by one, the + first-order difference for that field is initialized to one when the + state is refreshed by a FULL_HEADER packet, or when a + COMPRESSED_NON_TCP packet is sent since it carries the ID field in + uncompressed form. Thereafter, whenever the first-order difference + changes, it is transmitted and stored in the context. + + A bit mask will be used to indicate which fields have changed by + other than the expected difference. In addition to the small link + sequence number, the list of items to be conditionally communicated + in the compressed IP/UDP/RTP header is as follows: + + + + + + + + + +Casner & Jacobson Standards Track [Page 11] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + I = IPv4 packet ID (always 0 if no IPv4 header) + U = UDP checksum + M = RTP marker bit + S = RTP sequence number + T = RTP timestamp + L = RTP CSRC count and list + + If 4 bits are needed for the link sequence number to get a reasonable + probability of loss detection, there are too few bits remaining to + assign one bit to each of these items and still fit them all into a + single byte to go along with the context ID. + + It is not necessary to explicitly carry the U bit to indicate the + presence of the UDP checksum because a source will typically include + check-sums on all packets of a session or none of them. When the + session state is initialized with an uncompressed header, if there is + a nonzero checksum present, an unencoded 16-bit checksum will be + inserted into the compressed header in all subsequent packets until + this setting is changed by sending another uncompressed packet. + + Of the remaining items, the L bit for the CSRC count and list may be + the one least frequently used. Rather than dedicating a bit in the + mask to indicate CSRC change, an unusual combination of the other + bits may be used instead. This bit combination is denoted MSTI. If + all four of the bits for the IP packet ID, RTP marker bit, RTP + sequence number and RTP timestamp are set, this is a special case + indicating an extended form of the compressed RTP header will follow. + That header will include an additional byte containing the real + values of the four bits plus the CC count. The CSRC list, of length + indicated by the CC count, will be included just as it appears in the + uncompressed RTP header. + + The other fields of the RTP header (version, P bit, X bit, payload + type and SSRC identifier) are assumed to remain relatively constant. + In particular, the SSRC identifier is defined to be constant for a + given context because it is one of the factors selecting the context. + If any of the other fields change, the uncompressed RTP header MUST + sent as described in Section 3.3.3. + + The following diagram shows the compressed IP/UDP/RTP header with + dotted lines indicating fields that are conditionally present. The + most significant bit is numbered 0. Multi-byte fields are sent in + network byte order (most significant byte first). The delta fields + are often a single byte as shown but may be two or three bytes + depending upon the delta value as explained in Section 3.3.4. + + + + + + +Casner & Jacobson Standards Track [Page 12] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + 0 1 2 3 4 5 6 7 + +...............................+ + : msb of session context ID : (if 16-bit CID) + +-------------------------------+ + | lsb of session context ID | + +---+---+---+---+---+---+---+---+ + | M | S | T | I | link sequence | + +---+---+---+---+---+---+---+---+ + : : + + UDP checksum + (if nonzero in context) + : : + +...............................+ + : : + + "RANDOM" fields + (if encapsulated) + : : + +...............................+ + : M'| S'| T'| I'| CC : (if MSTI = 1111) + +...............................+ + : delta IPv4 ID : (if I or I' = 1) + +...............................+ + : delta RTP sequence : (if S or S' = 1) + +...............................+ + : delta RTP timestamp : (if T or T' = 1) + +...............................+ + : : + : CSRC list : (if MSTI = 1111 + : : and CC nonzero) + : : + +...............................+ + : : + : RTP header extension : (if X set in context) + : : + : : + +-------------------------------+ + | | + | RTP data | + / / + / / + | | + +-------------------------------+ + : padding : (if P set in context) + +...............................+ + + When more than one IPv4 header is present in the context as + initialized by the FULL_HEADER packet, then the IP ID fields of + encapsulating headers MUST be sent as absolute values as described in + + + + + +Casner & Jacobson Standards Track [Page 13] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + [3]. These fields are identified as "RANDOM" fields. They are + inserted into the COMPRESSED_RTP packet in the same order as they + appear in the original headers, immediately following the UDP + checksum if present or the MSTI byte if not, as shown in the diagram. + Only if an IPv4 packet immediately precedes the UDP header will the + IP ID of that header be sent differentially, i.e., potentially with + no bits if the second difference is zero, or as a delta IPv4 ID field + if not. If there is not an IPv4 header immediately preceding the UDP + header, then the I bit MUST be 0 and no delta IPv4 ID field will be + present. + +3.3.3. COMPRESSED_UDP packet format + + If there is a change in any of the fields of the RTP header that are + normally constant (such as the payload type field), then an + uncompressed RTP header MUST be sent. If the IP and UDP headers do + not also require updating, this RTP header MAY be carried in a + COMPRESSED_UDP packet rather than a FULL_HEADER packet. The + COMPRESSED_UDP packet has the same format as the COMPRESSED_RTP + packet except that the M, S and T bits are always 0 and the + corresponding delta fields are never included: + + 0 1 2 3 4 5 6 7 + +...............................+ + : msb of session context ID : (if 16-bit CID) + +-------------------------------+ + | lsb of session context ID | + +---+---+---+---+---+---+---+---+ + | 0 | 0 | 0 | I | link sequence | + +---+---+---+---+---+---+---+---+ + : : + + UDP checksum + (if nonzero in context) + : : + +...............................+ + : : + + "RANDOM" fields + (if encapsulated) + : : + +...............................+ + : delta IPv4 ID : (if I = 1) + +-------------------------------+ + | UDP data | + : (uncompressed RTP header) : + + Note that this constitutes a form of IP/UDP header compression + different from COMPRESSED_NON_TCP packet type defined in [3]. The + motivation is to allow reaching the target of two bytes when UDP + checksums are disabled, as IPv4 allows. The protocol in [3] does not + use differential coding for UDP packets, so in the IPv4 case, two + + + +Casner & Jacobson Standards Track [Page 14] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + bytes of IP ID, and two bytes of UDP checksum if nonzero, would + always be transmitted in addition to two bytes of compression prefix. + For IPv6, the COMPRESSED_NON_TCP packet type MAY be used instead. + +3.3.4. Encoding of differences + + The delta fields in the COMPRESSED_RTP and COMPRESSED_UDP packets are + encoded with a variable-length mapping for compactness of the more + commonly-used values. A default encoding is specified below, but it + is RECOMMENDED that implementations use a table-driven delta encoder + and decoder to allow negotiation of a table specific for each session + if appropriate, possibly even an optimal Huffman encoding. Encodings + based on sequential interpretation of the bit stream, of which this + default table and Huffman encoding are examples, allow a reasonable + table size and may result in an execution speed faster than a non- + table-driven implementation with explicit tests for ranges of values. + + The default delta encoding is specified in the following table. This + encoding was designed to efficiently encode the small changes that + may occur in the IP ID and in RTP sequence number when packets are + lost upstream from the compressor, yet still handling most audio and + video deltas in two bytes. The column on the left is the decimal + value to be encoded, and the column on the right is the resulting + sequence of bytes shown in hexadecimal and in the order in which they + are transmitted (network byte order). The first and last values in + each contiguous range are shown, with ellipses in between: + + Decimal Hex + + -16384 C0 00 00 + : : + -129 C0 3F 7F + -128 80 00 + : : + -1 80 7F + 0 00 + : : + 127 7F + 128 80 80 + : : + 16383 BF FF + 16384 C0 40 00 + : : + 4194303 FF FF FF + + For positive values, a change of zero through 127 is represented + directly in one byte. If the most significant two bits of the byte + are 10 or 11, this signals an extension to a two- or three-byte + + + +Casner & Jacobson Standards Track [Page 15] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + value, respectively. The least significant six bits of the first + byte are combined, in decreasing order of significance, with the next + one or two bytes to form a 14- or 22-bit value. + + Negative deltas may occur when packets are misordered or in the + intentionally out-of-order RTP timestamps on MPEG video [5]. These + events are less likely, so a smaller range of negative values is + encoded using otherwise redundant portions of the positive part of + the table. + + A change in the RTP timestamp value less than -16384 or greater than + 4194303 forces the RTP header to be sent uncompressed using a + FULL_HEADER, COMPRESSED_NON_TCP or COMPRESSED_UDP packet type. The + IP ID and RTP sequence number fields are only 16 bits, so negative + deltas for those fields SHOULD be masked to 16 bits and then encoded + (as large positive 16-bit numbers). + +3.3.5. Error Recovery + + Whenever the 4-bit sequence number for a particular context + increments by other than 1, except when set by a FULL_HEADER or + COMPRESSED_NON_TCP packet, the decompressor MUST invalidate that + context and send a CONTEXT_STATE packet back to the compressor + indicating that the context has been invalidated. All packets for + the invalid context MUST be discarded until a FULL_HEADER or + COMPRESSED_NON_TCP packet is received for that context to re- + establish consistent state (unless the "twice" algorithm is used as + described later in this section). Since multiple compressed packets + may arrive in the interim, the decompressor SHOULD NOT retransmit the + CONTEXT_STATE packet for every compressed packet received, but + instead SHOULD limit the rate of retransmission to avoid flooding the + reverse channel. + + When an error occurs on the link, the link layer will usually discard + the packet that was damaged (if any), but may provide an indication + of the error. Some time may elapse before another packet is + delivered for the same context, and then that packet would have to be + discarded by the decompressor when it is observed to be out of + sequence, resulting in at least two packets lost. To allow faster + recovery if the link does provide an explicit error indication, the + decompressor MAY optionally send an advisory CONTEXT_STATE packet + listing the last valid sequence number and generation number for one + or more recently active contexts (not necessarily all). For a given + context, if the compressor has sent no compressed packet with a + higher sequence number, and if the generation number matches the + current generation, no corrective action is required. Otherwise, the + compressor MAY choose to mark the context invalid so that the next + packet is sent in FULL_HEADER or COMPRESSED_NON_TCP mode (FULL_HEADER + + + +Casner & Jacobson Standards Track [Page 16] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + is required if the generation doesn't match). However, note that if + the link round-trip-time is large compared to the inter-packet + spacing, there may be several packets from multiple contexts in + flight across the link, increasing the probability that the sequence + numbers will already have advanced when the CONTEXT_STATE packet is + received by the compressor. The result could be that some contexts + are invalidated unnecessarily, causing extra bandwidth to be + consumed. + + The format of the CONTEXT_STATE packet is shown in the following + diagrams. The first byte is a type code to allow the CONTEXT_STATE + packet type to be shared by multiple compression schemes within the + general compression framework specified in [3]. The contents of the + remainder of the packet depends upon the compression scheme. For the + IP/UDP/RTP compression scheme specified here, the remainder of the + CONTEXT_STATE packet is structured as a list of blocks to allow the + state for multiple contexts to be indicated, preceded by a one-byte + count of the number of blocks. + + Two type code values are used for the IP/UDP/RTP compression scheme. + The value 1 indicates that 8-bit session context IDs are being used: + + 0 1 2 3 4 5 6 7 + +---+---+---+---+---+---+---+---+ + | 1 = IP/UDP/RTP with 8-bit CID | + +---+---+---+---+---+---+---+---+ + | context count | + +---+---+---+---+---+---+---+---+ + +---+---+---+---+---+---+---+---+ + | session context ID | + +---+---+---+---+---+---+---+---+ + | I | 0 | 0 | 0 | sequence | + +---+---+---+---+---+---+---+---+ + | 0 | 0 | generation | + +---+---+---+---+---+---+---+---+ + ... + +---+---+---+---+---+---+---+---+ + | session context ID | + +---+---+---+---+---+---+---+---+ + | I | 0 | 0 | 0 | sequence | + +---+---+---+---+---+---+---+---+ + | 0 | 0 | generation | + +---+---+---+---+---+---+---+---+ + + The value 2 indicates that 16-bit session context IDs are being used. + The session context ID is sent in network byte order (most + significant byte first): + + + + +Casner & Jacobson Standards Track [Page 17] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + 0 1 2 3 4 5 6 7 + +---+---+---+---+---+---+---+---+ + | 2 = IP/UDP/RTP with 16-bit CID| + +---+---+---+---+---+---+---+---+ + | context count | + +---+---+---+---+---+---+---+---+ + +---+---+---+---+---+---+---+---+ + | | + + session context ID + + | | + +---+---+---+---+---+---+---+---+ + | I | 0 | 0 | 0 | sequence | + +---+---+---+---+---+---+---+---+ + | 0 | 0 | generation | + +---+---+---+---+---+---+---+---+ + ... + +---+---+---+---+---+---+---+---+ + | | + + session context ID + + | | + +---+---+---+---+---+---+---+---+ + | I | 0 | 0 | 0 | sequence | + +---+---+---+---+---+---+---+---+ + | 0 | 0 | generation | + +---+---+---+---+---+---+---+---+ + + The bit labeled "I" is set to one for contexts that have been marked + invalid and require a FULL_HEADER of COMPRESSED_NON_TCP packet to be + transmitted. If the I bit is zero, the context state is advisory. + The I bit is set to zero to indicate advisory context state that MAY + be sent following a link error indication. + + Since the CONTEXT_STATE packet itself may be lost, retransmission of + one or more blocks is allowed. It is expected that retransmission + will be triggered only by receipt of another packet, but if the line + is near idle, retransmission MAY be triggered by a relatively long + timer (on the order of 1 second). + + If a CONTEXT_STATE block for a given context is retransmitted, it may + cross paths with the FULL_HEADER or COMPRESSED_NON_TCP packet + intended to refresh that context. In that case, the compressor MAY + choose to ignore the error indication. + + In the case where UDP checksums are being transmitted, the + decompressor MAY attempt to use the "twice" algorithm described in + section 10.1 of [3]. In this algorithm, the delta is applied more + than once on the assumption that the delta may have been the same on + the missing packet(s) and the one subsequently received. Success is + + + +Casner & Jacobson Standards Track [Page 18] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + indicated by a checksum match. For the scheme defined here, the + difference in the 4- bit sequence number tells number of times the + delta must be applied. Note, however, that there is a nontrivial + risk of an incorrect positive indication. It may be advisable to + request a FULL_HEADER or COMPRESSED_NON_TCP packet even if the + "twice" algorithm succeeds. + + Some errors may not be detected, for example if 16 packets are lost + in a row and the link level does not provide an error indication. In + that case, the decompressor will generate packets that are not valid. + If UDP checksums are being transmitted, the receiver will probably + detect the invalid packets and discard them, but the receiver does + not have any means to signal the decompressor. Therefore, it is + RECOMMENDED that the decompressor verify the UDP checksum + periodically, perhaps one out of 16 packets. If an error is + detected, the decompressor would invalidate the context and signal + the compressor with a CONTEXT_STATE packet. + +3.4. Compression of RTCP Control Packets + + By relying on the RTP convention that data is carried on an even port + number and the corresponding RTCP packets are carried on the next + higher (odd) port number, one could tailor separate compression + schemes to be applied to RTP and RTCP packets. For RTCP, the + compression could apply not only to the header but also the "data", + that is, the contents of the different packet types. The numbers in + Sender Report (SR) and Receiver Report (RR) RTCP packets would not + compress well, but the text information in the Source Description + (SDES) packets could be compressed down to a bit mask indicating each + item that was present but compressed out (for timing purposes on the + SDES NOTE item and to allow the end system to measure the average + RTCP packet size for the interval calculation). + + However, in the compression scheme defined here, no compression will + be done on the RTCP headers and "data" for several reasons (though + compression SHOULD still be applied to the IP and UDP headers). + Since the RTP protocol specification suggests that the RTCP packet + interval be scaled so that the aggregate RTCP bandwidth used by all + participants in a session will be no more than 5% of the session + bandwidth, there is not much to be gained from RTCP compression. + Compressing out the SDES items would require a significant increase + in the shared state that must be stored for each context ID. And, in + order to allow compression when SDES information for several sources + was sent through an RTP "mixer", it would be necessary to maintain a + separate RTCP session context for each SSRC identifier. In a session + with more than 255 participants, this would cause perfect thrashing + of the context cache even when only one participant was sending data. + + + + +Casner & Jacobson Standards Track [Page 19] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + Even though RTCP is not compressed, the fraction of the total + bandwidth occupied by RTCP packets on the compressed link remains no + more than 5% in most cases, assuming that the RTCP packets are sent + as COMPRESSED_UDP packets. Given that the uncompressed RTCP traffic + consumes no more than 5% of the total session bandwidth, then for a + typical RTCP packet length of 90 bytes, the portion of the compressed + bandwidth used by RTCP will be no more than 5% if the size of the + payload in RTP data packets is at least 108 bytes. If the size of + the RTP data payload is smaller, the fraction will increase, but is + still less than 7% for a payload size of 37 bytes. For large data + payloads, the compressed RTCP fraction is less than the uncompressed + RTCP fraction (for example, 4% at 1000 bytes). + +3.5. Compression of non-RTP UDP Packets + + As described earlier, the COMPRESSED_UDP packet MAY be used to + compress UDP packets that don't carry RTP. Whatever data follows the + UDP header is unlikely to have some constant values in the bits that + correspond to usually constant fields in the RTP header. In + particular, the SSRC field would likely change. Therefore, it is + necessary to keep track of the non-RTP UDP packet streams to avoid + using up all the context slots as the "SSRC field" changes (since + that field is part of what identifies a particular RTP context). + Those streams may each be given a context, but the encoder would set + a flag in the context to indicate that the changing SSRC field should + be ignored and COMPRESSED_UDP packets should always be sent instead + of COMPRESSED_RTP packets. + +4. Interaction With Segmentation + + A segmentation scheme may be used in conjunction with RTP header + compression to allow small, real-time packets to interrupt large, + presumably non-real-time packets in order to reduce delay. It is + assumed that the large packets bypass the compressor and decompressor + since the interleaving would modify the sequencing of packets at the + decompressor and cause the appearance of errors. Header compression + should be less important for large packets since the overhead ratio + is smaller. + + If some packets from an RTP session context are selected for + segmentation (perhaps based on size) and some are not, there is a + possibility of re-ordering. This would reduce the compression + efficiency because the large packets would appear as lost packets in + the sequence space. However, this should not cause more serious + problems because the RTP sequence numbers should be reconstructed + correctly and will allow the application to correct the ordering. + + + + + +Casner & Jacobson Standards Track [Page 20] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + Link errors detected by the segmentation scheme using its own + sequencing information MAY be indicated to the compressor with an + advisory CONTEXT_STATE message just as for link errors detected by + the link layer itself. + + The context ID byte is placed first in the COMPRESSED_RTP header so + that this byte MAY be shared with the segmentation layer if such + sharing is feasible and has been negotiated. Since the compressor + may assign context ID values arbitrarily, the value can be set to + match the context identifier from the segmentation layer. + +5. Negotiating Compression + + The use of IP/UDP/RTP compression over a particular link is a + function of the link-layer protocol. It is expected that such + negotiation will be defined separately for PPP [4], for example. The + following items MAY be negotiated: + + o The size of the context ID. + o The maximum size of the stack of headers in the context. + o A context-specific table for decoding of delta values. + +6. Acknowledgments + + Several people have contributed to the design of this compression + scheme and related problems. Scott Petrack initiated discussion of + RTP header compression in the AVT working group at Los Angeles in + March, 1996. Carsten Bormann has developed an overall architecture + for compression in combination with traffic control across a low- + speed link, and made several specific contributions to the scheme + described here. David Oran independently developed a note based on + similar ideas, and suggested the use of PPP Multilink protocol for + segmentation. Mikael Degermark has contributed advice on integration + of this compression scheme with the IPv6 compression framework. + + + + + + + + + + + + + + + + + +Casner & Jacobson Standards Track [Page 21] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + +7. References: + + [1] Schulzrinne, H., Casner, S., Frederick, R. and V. Jacobson, "RTP: + A Transport Protocol for real-time applications", RFC 1889, + January 1996. + + [2] Jacobson, V., "TCP/IP Compression for Low-Speed Serial Links", + RFC 1144, February 1990. + + [3] Degermark, M., Nordgren, B. and S. Pink, "Header Compression for + IPv6", RFC 2507, February 1999. + + [4] Simpson, W., "The Point-to-Point Protocol (PPP)", STD 51, RFC + 1661, July 1994. + + [5] Hoffman, D., Fernando, G., Goyal, V. and M. Civanlar, "RTP + Payload Format for MPEG1/MPEG2 Video", RFC 2250, January 1998. + +8. Security Considerations + + Because encryption eliminates the redundancy that this compression + scheme tries to exploit, there is some inducement to forego + encryption in order to achieve operation over a low-bandwidth link. + However, for those cases where encryption of data and not headers is + satisfactory, RTP does specify an alternative encryption method in + which only the RTP payload is encrypted and the headers are left in + the clear. That would allow compression to still be applied. + + A malfunctioning or malicious compressor could cause the decompressor + to reconstitute packets that do not match the original packets but + still have valid IP, UDP and RTP headers and possibly even valid UDP + check-sums. Such corruption may be detected with end-to-end + authentication and integrity mechanisms which will not be affected by + the compression. Constant portions of authentication headers will be + compressed as described in [3]. + + No authentication is performed on the CONTEXT_STATE control packet + sent by this protocol. An attacker with access to the link between + the decompressor and compressor could inject false CONTEXT_STATE + packets and cause compression efficiency to be reduced, probably + resulting in congestion on the link. However, an attacker with + access to the link could also disrupt the traffic in many other ways. + + A potential denial-of-service threat exists when using compression + techniques that have non-uniform receiver-end computational load. + The attacker can inject pathological datagrams into the stream which + are complex to decompress and cause the receiver to be overloaded and + degrading processing of other streams. However, this compression + + + +Casner & Jacobson Standards Track [Page 22] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + + does not exhibit any significant non-uniformity. + + A security review of this protocol found no additional security + considerations. + +9. Authors' Addresses + + Stephen L. Casner + Cisco Systems, Inc. + 170 West Tasman Drive + San Jose, CA 95134-1706 + United States + + EMail: casner@cisco.com + + + Van Jacobson + Cisco Systems, Inc. + 170 West Tasman Drive + San Jose, CA 95134-1706 + United States + + EMail: van@cisco.com + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Casner & Jacobson Standards Track [Page 23] + +RFC 2508 Compressing IP/UDP/RTP Headers February 1999 + + +10. Full Copyright Statement + + Copyright (C) The Internet Society (1999). All Rights Reserved. + + This document and translations of it may be copied and furnished to + others, and derivative works that comment on or otherwise explain it + or assist in its implementation may be prepared, copied, published + and distributed, in whole or in part, without restriction of any + kind, provided that the above copyright notice and this paragraph are + included on all such copies and derivative works. However, this + document itself may not be modified in any way, such as by removing + the copyright notice or references to the Internet Society or other + Internet organizations, except as needed for the purpose of + developing Internet standards in which case the procedures for + copyrights defined in the Internet Standards process must be + followed, or as required to translate it into languages other than + English. + + The limited permissions granted above are perpetual and will not be + revoked by the Internet Society or its successors or assigns. + + This document and the information contained herein is provided on an + "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING + TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING + BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION + HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF + MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. + + + + + + + + + + + + + + + + + + + + + + + + +Casner & Jacobson Standards Track [Page 24] + -- cgit v1.2.3