Network Working Group L-E. Jonsson
INTERNET-DRAFT G. Pelletier
Expires: May 2007 K. Sandlund
Ericsson
November 29, 2006
The RObust Header Compression (ROHC) Framework
<draft-ietf-rohc-rfc3095bis-framework-04.txt>
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Abstract
The RObust Header Compression (ROHC) protocol provides an efficient,
flexible and future-proof header compression concept. It is designed
to operate efficiently and robustly over various link technologies
with different characteristics.
The ROHC framework, along with a set of compression profiles, was
initially defined in RFC 3095. To improve and simplify the ROHC
specifications, this document explicitly defines the ROHC framework
separately, and thus replaces the framework specification of RFC
3095.
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Table of Contents
1. Introduction.....................................................3
2. Terminology......................................................4
2.1. Acronyms....................................................4
2.2. ROHC Terminology............................................4
3. Background (Informative).........................................6
3.1. Header Compression Fundamentals.............................7
3.2. A Short History of Header Compression.......................7
4. Overview of Robust Header Compression (ROHC) (Informative).......8
4.1. General Principles..........................................8
4.2. Compression Efficiency, Robustness and Transparency.........9
4.3. Developing the ROHC Protocol...............................10
4.4. Operational Characteristics of the ROHC Channel............11
4.5. Compression and Master Sequence Number (MSN)...............12
4.6. Static and Dynamic Parts of a Context......................13
5. The ROHC Framework (Normative)..................................13
5.1. The ROHC Channel...........................................13
5.1.1. Contexts and Context Identifiers......................13
5.1.2. Per-Channel Parameters................................14
5.1.3. Persistence of decompressor contexts..................15
5.2. ROHC Packets and Packet Types..............................15
5.2.1. General Format of ROHC Packets........................16
5.2.1.1. Format of the Padding Octet......................16
5.2.1.2. Format of the Add-CID Octet......................17
5.2.1.3. General Format of Header.........................17
5.2.2. Initialization and Refresh (IR) Packet Types..........18
5.2.2.1. ROHC IR Packet Type..............................18
5.2.2.2. ROHC IR-DYN Packet Type..........................19
5.2.3. ROHC Initial Decompressor Processing..................19
5.2.4. ROHC Feedback.........................................21
5.2.4.1. ROHC Feedback Format.............................21
5.2.5. ROHC Segmentation.....................................23
5.2.5.1. Segmentation Usage Considerations................23
5.2.5.2. Segmentation Protocol............................24
5.3. General Encoding Methods...................................25
5.3.1. Header Compression CRCs, Coverage and Polynomials.....25
5.3.1.1. 8-bit CRCs in IR and IR-DYN Headers..............25
5.3.1.2. 3-bit CRC in Compressed Headers..................25
5.3.1.3. 7-bit CRC in Compressed Headers..................26
5.3.1.4. 32-bit Segmentation CRC..........................26
5.3.2. Self-describing Variable-length Values................27
5.4. ROHC UNCOMPRESSED -- No Compression (Profile 0x0000)......27
5.4.1. IR Packet.............................................28
5.4.2. Normal Packet.........................................28
5.4.3. Decompressor Operation................................29
5.4.4. Feedback..............................................30
6. Overview of a ROHC Profile (Informative)........................30
7. Security Considerations.........................................31
8. IANA Considerations.............................................31
9. Acknowledgments.................................................32
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10. References.....................................................32
10.1. Normative References......................................32
10.2. Informative References....................................33
11. Authors' Addresses.............................................34
Appendix A - CRC Algorithm.........................................35
1. Introduction
For many types of networks, reducing the deployment and operational
costs by improving the usage of the bandwidth resources is of vital
importance. Header compression over a link is possible because some
of the information carried within the header of a packet becomes
compressible between packets belonging to the same flow.
For links where the overhead of the IP header(s) is problematic, the
total size of the header may be significant. Applications carrying
data carried within RTP [13] will then, in addition to link layer
framing, have an IPv4 [10] header (20 octets), a UDP [12] header (8
octets), and an RTP header (12 octets) for a total of 40 octets. With
IPv6 [11], the IPv6 header is 40 octets for a total of 60 octets.
Applications transferring data using TCP [14] will have 20 octets for
the transport header, for a total size of 40 octets for IPv4 and 60
octets for IPv6.
The relative gain for specific flows (or applications) depends on the
size of the payload used in each packet. For applications such as
Voice-over-IP, where the size of the payload containing coded speech
can be as small as 15-20 octets, this gain will be quite significant.
Similarly, relative gains for TCP flows carrying large payloads (such
as file transfers) will be less than for flows carrying smaller
payloads (such as application signaling, e.g. session initiation).
As more and more wireless link technologies are being deployed to
carry IP traffic, care must be taken to address the specific
characteristics of these technologies within the header compression
algorithms. Legacy header compression schemes, such as those defined
in [16] and [17], have been shown to perform inadequately over links
where both the lossy behavior and the round-trip times are non-
negligible, such as those observed for example in wireless links and
IP tunnels.
In addition, a header compression scheme should handle the often non-
trivial residual errors, i.e. where the lower layer may pass a packet
that contains undetected bit errors to the decompressor. It should
also handle loss and reordering before the compression point, as well
as on the link between the compression and decompression points [7].
The RObust Header Compression (ROHC) protocol provides an efficient,
flexible and future-proof header compression concept. It is designed
to operate efficiently and robustly over various link technologies
with different characteristics.
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RFC 3095 [3] defines the ROHC framework along with an initial set of
compression profiles. To improve and simplify the specification, the
framework and the profiles parts have been split into separate
documents. This document explicitly defines the ROHC framework, and
thus replaces the framework specification of RFC 3095.
2. Terminology
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 [1].
2.1. Acronyms
This section lists most acronyms used for reference.
ACK Acknowledgment.
CID Context Identifier.
CO Compressed packet format.
CRC Cyclic Redundancy Check.
IR Initialization and Refresh.
IR-DYN Initialization and Refresh, Dynamic part.
LSB Least Significant Bit(s).
MRRU Maximum Reconstructed Reception Unit.
MSB Most Significant Bit(s).
MSN Master Sequence Number.
NACK Negative Acknowledgment.
ROHC RObust Header Compression.
2.2. ROHC Terminology
Context
The context of the compressor is the state it uses to compress a
header. The context of the decompressor is the state it uses to
decompress a header. Either of these or the two in combination
are usually referred to as "context", when it is clear which is
intended. The context contains relevant information from previous
headers in the packet flow, such as static fields and possible
reference values for compression and decompression. Moreover,
additional information describing the packet flow is also part
of the context, for example information about the change behavior
of fields (e.g. the IP Identifier behavior, or the typical inter-
packet increase in sequence numbers and timestamps).
Context damage
When the context of the decompressor is not consistent with the
context of the compressor, decompression may fail to reproduce the
original header. This situation can occur when the context of the
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decompressor has not been initialized properly or when packets
have been lost or damaged between compressor and decompressor.
Packets which cannot be decompressed due to inconsistent contexts
are said to be lost due to context damage. Packets that are
decompressed but contain errors due to inconsistent contexts are
said to be damaged due to context damage.
Context repair mechanism
Context repair mechanisms are used to resynchronize the contexts,
an important task since context damage causes loss propagation.
Examples of such mechanisms are NACK-based mechanisms, and the
periodic refreshes of important context information, usually
done in unidirectional operation. There are also mechanisms that
can reduce the context inconsistency probability, for example
repetition of the same type of information in multiple packets,
and CRCs that protect context-updating information.
CRC-8 validation
The CRC-8 validation refers to the validation of the integrity
against bit error(s) in a received IR and IR-DYN header, using the
8-bit CRC included in the IR/IR-DYN header.
CRC verification
The CRC verification refers to the verification of the result of a
decompression attempt, using the 3-bit CRC or 7-bit CRC included
in the header of a compressed packet format.
Damage propagation
Delivery of incorrect decompressed headers due to context damage,
i.e. due to errors in (i.e., loss of or damage to) previous
header(s) or feedback.
Error detection
Detection of errors by lower layers. If error detection is not
perfect, there will be residual errors.
Error propagation
Damage propagation or loss propagation.
ROHC profile
A ROHC profile is a compression protocol, which specifies how to
compress specific header combinations. A ROHC profile may be
tailored to handle a specific set of link characteristics, e.g.
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loss characteristics, reordering between compression points, etc.
ROHC profiles provide the details of the header compression
framework defined in this document, and each compression profile
is associated with a unique ROHC profile identifier [21]. When
setting up a ROHC channel, the set of profiles supported by both
endpoints of the channel is negotiated, and when initializing new
contexts, a profile identifier from this negotiated set is used to
associate each compression context with one specific profile.
Link
A physical transmission path that constitutes a single IP hop.
Loss propagation
Loss of headers, due to errors in (i.e., loss of or damage to)
previous header(s) or feedback.
Packet flow
A sequence of packets where the field values and change patterns
of field values are such that the headers can be compressed using
the same context.
Residual error
Errors introduced during transmission and not detected by lower-
layer error detection schemes.
ROHC channel
A logical unidirectional point-to-point channel carrying ROHC
packets from one compressor to one decompressor, optionally
carrying ROHC feedback information on the behalf of another
compressor-decompressor pair operating on a separate ROHC channel
in the opposite direction. See also [5].
This document also makes use of the conceptual terminology defined by
"ROHC Terminology and Channel Mapping Examples", RFC 3759 [5].
3. Background (Informative)
This chapter provides a background to the subject of header
compression. The fundamental ideas are described together with a
discussion about the history of header compression schemes. The
motivations driving the development of the various schemes are
discussed, and their drawbacks identified, thereby providing the
foundations for the design of the ROHC framework and profiles [3].
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3.1. Header Compression Fundamentals
Header compression is possible because there is significant
redundancy between header fields; within the headers of a single
packet, but in particular between consecutive packets belonging to
the same flow. On the path end-to-end, the entire header information
is necessary for all packets in the flow, but over a single link some
of this information becomes redundant and can be reduced, as long as
it is transparently recovered at the receiving end of the link. The
header size can be reduced by first sending field information that is
expected to remain static for (at least most of) the lifetime of the
packet flow. Further compression is achieved for the fields carrying
information changing more dynamically by using compression methods
tailored to their respective assumed change behavior.
To achieve compression and decompression, some necessary information
from past packets is maintained in a context. The compressor and the
decompressor update their respective contexts upon certain, not
necessarily synchronized, events. Impairment events may lead to
inconsistencies in the decompressor context (i.e. context damage),
which in turn may cause incorrect decompression. A robust header
compression scheme needs mechanisms to minimize the possibility of
context damage, in combination with mechanisms for context repair.
3.2. A Short History of Header Compression
The first header compression scheme, CTCP [15], was introduced by Van
Jacobson. CTCP, also often referred to as VJ compression, compresses
the 40 octets of the TCP/IP header down to 4 octets. CTCP uses delta
encoding for sequentially changing fields. The CTCP compressor
detects transport-level retransmissions and sends a header that
updates the entire context when they occur. This repair mechanism
does not require any explicit signaling between compressor and
decompressor.
A general IP header compression scheme, IP header compression [16],
improves somewhat on CTCP. IPHC can compress arbitrary IP, TCP, and
UDP headers. When compressing non-TCP headers, IPHC does not use
delta encoding and is robust. The repair mechanism of CTCP is
augmented with negative acknowledgments, called CONTEXT_STATE
messages, which speeds up the repair. This context repair mechanism
is thus limited by the round-trip time of the link. IPHC does not
compress RTP headers.
CRTP [17] is an RTP extension to IPHC. CRTP compresses the 40 octets
of IPv4/UDP/RTP headers to a minimum of 2 octets when the UDP
Checksum is not enabled. If the UDP Checksum is enabled, the minimum
CRTP header is 4 octets.
On lossy links with long round-trip times, CRTP does not perform well
[20]. Each packet lost over the link causes decompression of several
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subsequent packets to fail, because the context becomes invalidated
during at least one link round-trip time from the lost packet.
Unfortunately, the large headers that CRTP sends when updating the
context waste additional bandwidth.
CRTP uses a local repair mechanism known as TWICE, which was
introduced by IPHC. TWICE derives its name from the observation that
when the flow of compressed packets is regular, the correct guess
when one packet is lost between the compression points is to apply
the update in the current packet twice. While TWICE improves CRTP
performance significantly, [20] also found that even with TWICE, CRTP
doubled the number of lost packets.
An enhanced variant of CRTP, called eCRTP [19], means to improve the
robustness of CRTP in the presence of reordering and packet losses,
while keeping the protocol almost unchanged from CRTP. As a result,
eCRTP does provide better means to implement some degree of
robustness, albeit at the expense of additional overhead leading to a
reduction in compression efficiency in comparison to CRTP.
4. Overview of Robust Header Compression (ROHC) (Informative)
4.1. General Principles
As mentioned earlier, header compression is possible per link due to
the fact that there is much redundancy between header field values
within packets, and especially between consecutive packets belonging
to the same flow. To utilize these properties for header compression,
there are a few essential steps to consider.
The first step consists in identifying and grouping packets together
into different "flows", so that packet-to-packet redundancy is
maximized in order to improve the compression ratio. Grouping packets
into flows is usually based on source and destination host (IP)
addresses, transport protocol type (e.g. UDP or TCP), process (port)
numbers and potentially additional unique application identifiers,
such as the SSRC in RTP [13]. The compressor and the decompressor
each establish a context for the packet flow, and identify the
context with a CID included in each compressed header.
The second step is to understand the change patterns of the various
header fields. On a high level, header fields fall into one of the
following classes:
INFERRED These fields contain values that can be inferred from
other fields or external sources, for example the size
of the frame carrying the packet can often be derived
from the link layer protocol, and thus does not have
to be transmitted by the compression scheme.
STATIC Fields classified as STATIC are assumed to be constant
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throughout the lifetime of the packet flow. The value
of each field is thus only communicated initially.
STATIC-DEF Fields classified as STATIC-DEF are used to define a
packet flow, as discussed above. Packets for which
respective values of these fields differ are treated
as belonging to different flows. These fields are in
general compressed as STATIC fields.
STATIC-KNOWN Fields classified as STATIC-KNOWN are expected to have
well-known values, and therefore their values do not
need to be communicated.
CHANGING These fields are expected to vary either randomly,
either within a limited value set or range, or in some
other manner. CHANGING fields are usually handled in
more sophisticated ways, based on a more detailed
classification of their expected change patterns.
Finally, the last step is to choose the encoding method(s) that will
be applied onto different fields, based on the classification. The
encoding methods, in combination with the identified field behavior,
provide the input to the design of the compressed header formats. The
analysis of the probability distribution of the identified change
patterns then provide the means to optimize the packet formats, where
the most frequently occurring change patterns for a field should be
encoded within the most efficient format(s).
However, compression efficiency has to be traded against two other
properties: the robustness of the encoding to losses and errors
between the compressor and the decompressor, and the ability to
detect and cope with errors in the decompression process.
4.2. Compression Efficiency, Robustness and Transparency
The performance of a header compression protocol can be described
with three parameters: its compression efficiency, its robustness and
its compression transparency.
Compression efficiency
The compression efficiency is determined by how much the average
header size is reduced by applying the compression protocol.
Robustness
A robust protocol tolerates packet losses, residual bit errors, and
out-of-order delivery on the link over which header compression
takes place, without losing additional packets or introducing
additional errors in decompressed headers.
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Compression transparency
The compression transparency is a measure of the extent to which
the scheme maintains the semantics of the original headers. If all
decompressed headers are bitwise identical to the corresponding
original headers, the scheme is transparent.
4.3. Developing the ROHC Protocol
The challenge in developing a header compression protocol is to
conciliate compression efficiency and robustness, while maintaining
transparency, as increasing robustness will always come at the
expense of a lower compression efficiency, and vice-versa. The scheme
should also be flexible enough in its design to minimize the impacts
from the varying round-trip times and loss patterns of links where
header compression will be used.
To achieve this, the header compression scheme must provide
facilities for the decompressor to verify decompression and detect
potential context damage, as well as context recovery mechanisms such
as feedback. Header compression schemes prior to the ones developed
by the RObust Header Compression (ROHC) WG were not designed with the
above high-level objectives in mind.
The ROHC WG has developed header compression solutions to meet the
needs of today's and future link technologies. While special
attention has been put towards meeting the more stringent
requirements stemming out from the characteristics of wireless links,
the results are equally applicable to many other link technologies.
RFC 3095 [3], "RObust Header Compression (ROHC): Framework and four
profiles: RTP, UDP, ESP, and uncompressed", was published 2001, as
the first output of the ROHC WG. ROHC is a general and extendable
framework for header compression, on top of which profiles can be
defined for compression of different protocols headers. RFC 3095
introduced a number of new compression techniques, and was successful
at living up to the requirements placed on it, as described in [18].
Interoperability testing of RFC 3095 confirms the capabilities of
ROHC to meet its purposes, but feedback from implementers has also
indicated that the protocol specification is complex and sometimes
obscure. Most importantly, a clear distinction between framework and
profiles is not obvious in [3], which also makes development of
additional profiles troublesome. This document therefore aims at
explicitly specifying the ROHC framework, while a companion document
[8] specifies revised versions of the compression profiles of RFC
3095.
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4.4. Operational Characteristics of the ROHC Channel
Robust header compression can be used over many type of link
technologies. The ROHC framework provides flexibility for profiles to
address a wide range of applications, and this section lists some of
the operational characteristics of the ROHC channel (see also [5]).
Multiplexing over a single logical channel
The ROHC channel provides a mechanism to identify a context within
the general ROHC packet format. The Context Identifier (CID) makes
it possible for a logical channel that supports ROHC to transport
multiple header-compressed flows, while still making it possible
for a channel to be dedicated to one single packet flow without
any CID overhead. More specifically, ROHC uses a distinct context
identifier space per logical channel, and the context identifier
can be omitted for one of the flows over the ROHC channel when
configured to use a small CID space.
Establishment of channel parameters
A link layer defining support for the ROHC channel must provide
the means to establish header compression channel parameters (see
section 5.1). This can be achieved either through a negotiation
mechanism, static provisioning or some out-of-band signaling.
Packet type identification
The ROHC channel defines a packet type identifier space, and puts
restrictions with respect to the use of a number of identifiers
that are common for all ROHC profiles. Identifiers that have no
restrictions, i.e. identifiers that are not defined by this
document, are available to each profile. The identifier is part
of each compressed header, and this makes it possible for the link
that supports the ROHC channel to allocate one single link layer
payload type for ROHC.
Out-of-order delivery between compression endpoints
Each profile defines its own level of robustness, including
tolerance to reordering of packets before but especially between
compression endpoints, if any.
For profiles specified in [3], the channel between compressor and
decompressor is required to maintain in-order delivery of the
packets, i.e. the definition of these profiles assumes that the
decompressor always receives packets in the same order as the
compressor sent them. The impacts of reordering on the performance
of these profiles is described in [7]. Reordering before the
compression point, however, is handled, i.e. these profiles make
no assumption that the compressor will receive packets in-order.
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For the ROHCv2 profiles specified in [8], their definition assume
that the decompressor can receive packets out-of-order, i.e. not
in the same order as the compressor sent them. Reordering before
the compression point is also dealt with.
Duplication of packets
The link supporting the ROHC channel is required to not duplicate
packets (duplication before the compression point, however, is
dealt with, i.e., there is no assumption that the compressor will
receive only one copy of each packet).
Framing
The link layer must provide framing that makes it possible to
distinguish frame boundaries and individual frames.
Error detection/protection
ROHC profiles should be designed to cope with residual errors in
the headers delivered to the decompressor. CRCs are used to detect
decompression failures and to prevent or reduce damage
propagation. However, it is recommended that lower layers deploy
error detection for ROHC headers and to not deliver ROHC headers
with high residual error rates.
4.5. Compression and Master Sequence Number (MSN)
Compression of header fields is based on the establishment of a
function to a sequence number, called the Master Sequence Number
(MSN). This function describes the change pattern of the field with
respect to a change in the MSN.
Change patterns include e.g. fields that increase monotonically or by
a small value, but also fields that seldom change as well as fields
that remain unchanging for the entire lifetime of the packet flow, in
which case the function to the MSN is equivalent to a constant value.
The compressor first establishes functions for each of the header
fields, and then reliably communicates the MSN. When the change
pattern of the field does not match the established function, i.e.,
the existing function gives a result that is different from the field
in the header being compressed, additional information can be sent to
update the parameters of that function.
The MSN is defined per profile. It can be either derived directly
from one of the fields of the protocol being compressed (e.g. the RTP
SN [8]), or it can be created and maintained by the compressor (e.g.
the MSN for compression of UDP in profile 0x0102 [8] or the MSN in
ROHC-TCP [9]).
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4.6. Static and Dynamic Parts of a Context
A compression context can be conceptually divided into two different
parts, the static context and the dynamic context, each based on the
properties of the fields that are being compressed.
The static part includes the information necessary to compress and
decompress the fields whose change behavior is classified as STATIC,
STATIC-KNOWN or STATIC-DEF (as described in section 4.1 above).
The dynamic part includes the state maintained for all the other
fields, i.e. those that are classified as CHANGING.
5. The ROHC Framework (Normative)
This section normatively defines the parts common to all ROHC
profiles, i.e. the framework. The framework specifies the
requirements and functionality of the ROHC channel, including how to
handle multiple compressed packet flows over the same channel.
Finally, this section specifies encoding methods used in the packet
formats that are common to all profiles. These encoding methods may
be reused within profile specifications for encoding fields in
profile-specific parts of a packet format, without requiring their
redefinition.
5.1. The ROHC Channel
5.1.1. Contexts and Context Identifiers
Associated with each compressed flow is a context. The context is the
state that the compressor and the decompressor maintain in order to
correctly compress or decompress the headers of the packet in the
flow. Each context is identified using a Context Identifier (CID).
A context is considered to be a new context when the CID is
associated with a profile for the first time since the creation of
the ROHC channel, or when the CID gets associated from the reception
of an IR (this does not apply to the IR-DYN) with a different profile
than the profile in the context.
Context information is conceptually kept in a table. The context
table is indexed using the CID, which is sent along with compressed
headers and feedback information.
The CID space can be either small, which means that CIDs can take the
values 0 through 15, or large, which means that CIDs take values
between 0 and 2^14 - 1 = 16383. Whether the CID space is large or
small MUST be established, possibly by negotiation, before any
compressed packet may be sent over the ROHC channel.
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The CID space is distinct for each channel, i.e., CID 3 over channel
A and CID 3 over channel B do not refer to the same context, even if
the endpoints of A and B are the same nodes. In particular, CIDs for
any pair of ROHC channels are not related (two associated ROHC
channels serving as feedback channels for one another do not even
need to have CID spaces of the same size).
5.1.2. Per-Channel Parameters
The ROHC channel is based on a number of parameters that form part of
the established channel state and the per-context state. The state of
the ROHC channel MUST be established before the first ROHC packet may
be sent, which may be achieved using negotiation protocols provided
by the link layer (see also [4], which describes an option for
negotiation of ROHC parameters for PPP). This section describes some
of this channel state information in an abstract way:
LARGE_CIDS: Boolean; if false, the short CID representation (0 octets
or 1 prefix octet, covering CID 0 to 15) is used; if true, the
embedded CID representation (1 or 2 embedded CID octets covering
CID 0 to 16383) is used. See also 5.1.1 and 5.2.1.3.
MAX_CID: Non-negative integer; highest CID number to be used by the
compressor (note that this parameter is not coupled to, but in
effect further constrained by, LARGE_CIDS). This value represents
an agreement by the decompressor that it can provide sufficient
memory resources to host at least MAX_CID+1 contexts; the
decompressor MUST maintain established contexts within this space
until either the CID gets re-used by the establishment of a new
context, or until the channel is taken down.
PROFILES: Set of non-negative integers, where each integer indicates
a profile supported by both the compressor and the decompressor. A
profile is identified by a 16-bit value, where the 8 LSB bits
indicate the actual profile, and the 8 MSB bits indicate the
variant of that profile. The ROHC compressed header format
identifies the profile used with only the 8 LSB bits; this means
that if multiple variants of the same profile are available for a
ROHC channel, the PROFILES set after negotiation MUST NOT include
more than one variant of the same profile. The compressor MUST NOT
compress using a profile not in PROFILES.
FEEDBACK_FOR: Optional reference to a ROHC channel in the opposite
direction between the same compression endpoints. If provided,
this parameter indicates which other ROHC channel any feedback
sent on this ROHC channel refers to (see [5]).
MRRU: Non-negative integer. Maximum reconstructed reception unit.
This is the size of the largest reconstructed unit in octets that
the decompressor is expected to reassemble from segments (see
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5.2.5). This size includes the segmentation CRC. If MRRU is
negotiated to be 0, segmentation MUST NOT be used on the channel,
and received segments MUST be discarded by the decompressor.
5.1.3. Persistence of decompressor contexts
As part of the negotiated channel parameters, compressor and
decompressor have through the MAX_CID parameter agreed on the highest
context identification (CID) number to be used. By agreeing on
MAX_CID, the decompressor also agrees to provide memory resources to
host at least MAX_CID+1 contexts, and an established context with a
CID within this negotiated space SHOULD be kept by the decompressor
until either the CID gets re-used, or the channel is taken down or
re-negotiated.
5.2. ROHC Packets and Packet Types
This section uses the following convention in the diagrams when
representing various ROHC packet types, formats and fields:
- colons ":" indicate that the part is optional
- slashes "/" indicate variable length
The ROHC packet type indication scheme has been designed to provide
optional padding, a feedback packet type, an optional Add-CID octet
(which include 4 bits of CID), and a simple segmentation and
reassembly mechanism.
The following packet types are reserved at the ROHC framework level:
11100000 : Padding
1110nnnn : Add-CID octet (nnnn=CID with values 0x1 through 0xF)
11110 : Feedback
11111000 : IR-DYN packet
1111110 : IR packet
1111111 : Segment
Other packet types can be defined and used by individual profiles:
0 : available (not reserved by ROHC framework)
10 : available (not reserved by ROHC framework)
110 : available (not reserved by ROHC framework)
1111101 : available (not reserved by ROHC framework)
11111001 : available (not reserved by ROHC framework)
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5.2.1. General Format of ROHC Packets
A ROHC packet has the following general format:
--- --- --- --- --- --- --- ---
: Padding :
--- --- --- --- --- --- --- ---
: Feedback :
--- --- --- --- --- --- --- ---
: Header :
--- --- --- --- --- --- --- ---
: Payload :
--- --- --- --- --- --- --- ---
Padding: Any number (zero or more) of padding octets, where the
format of a padding octet is as defined in 5.2.1.1.
Feedback: Any number (zero or more) of feedback elements, where the
format of a feedback element is as defined in 5.2.4.1.
Header: Either a profile-specific CO header (see section 5.2.1.3), an
IR or IR-DYN header (see section 5.2.2), or a ROHC Segment (see
section 5.2.5). There can be at most one Header in a ROHC packet,
but it may also be omitted (if the packet contains Feedback only).
Payload: Corresponds to zero or more octets of payload from the
uncompressed packet, starting with the first octet in the
uncompressed packet after the last header compressible by the
current profile.
At least one of Feedback or Header MUST be present.
5.2.1.1. Format of the Padding Octet
Padding octet:
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| 1 1 1 0 0 0 0 0 |
+---+---+---+---+---+---+---+---+
Note: The Padding octet MUST NOT be interpreted as an Add-CID
octet for CID 0.
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5.2.1.2. Format of the Add-CID Octet
Add-CID octet:
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| 1 1 1 0 | CID |
+---+---+---+---+---+---+---+---+
CID: 0x1 through 0xF indicates CIDs 1 through 15.
Note: The Padding octet looks like an Add-CID octet for CID 0.
5.2.1.3. General Format of Header
All ROHC packet types have the following general Header format:
0 x-1 x 7
--- --- --- --- --- --- --- ---
: Add-CID octet : if CID 1-15 and small CIDs
+--- --- --- --- ---+--- --- ---+
| type indication | body | 1 octet (8-x bits of body)
+--- --- --- --- ---+--- --- ---+
: :
/ 0, 1, or 2 octets of CID / 1 or 2 octets if large CIDs
: :
+---+---+---+---+---+---+---+---+
/ body / variable length
+---+---+---+---+---+---+---+---+
type indication: ROHC packet type.
body: Interpreted according to the packet type indication and CID
information, as defined by individual profiles.
Header thus either starts with a packet type indication or has a
packet type indication immediately following an Add-CID octet.
When the ROHC channel is configured with a small CID space:
o If an Add-CID immediately precedes the packet type indication,
the packet has the CID of the Add-CID; otherwise it has CID 0.
o A small CID with the value 0 is represented using zero bits;
therefore a flow associated with CID 0 has no CID overhead in
the compressed header. In such case, Header starts with a
packet type indication.
o A small CID with a value from 1 to 15 is represented using the
Add-CID octet as described above. Header starts with the Add-
CID octet, followed by a packet type indication.
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o There is no large CID in the Header.
When the ROHC channel is configured with a large CID space:
o The large CID is always present and is represented using the
encoding scheme of section 5.3.2, limited to two octets. In
this case, Header starts with a packet type indication.
5.2.2. Initialization and Refresh (IR) Packet Types
IR packet types contain a profile identifier, which determines how
the rest of the header is to be interpreted. They also associate a
profile with a context. The stored profile parameter further
determines the syntax and semantics of the packet type identifiers
and packet types used with a specific context.
The IR and IR-DYN packets always update the context for all context-
updating fields carried in the header. They never clear the context,
except when initializing a new context (see section 5.1.1), or unless
the profile indicated in the Profile field specifies otherwise.
5.2.2.1. ROHC IR Packet Type
The IR header associates a CID with a profile, and typically also
initializes the context. It can typically also refresh all (or parts
of) the context. For IR, Header has the following general format:
0 1 2 3 4 5 6 7
--- --- --- --- --- --- --- ---
: Add-CID octet : if CID 1-15 and small CID
+---+---+---+---+---+---+---+---+
| 1 1 1 1 1 1 0 | x | IR type octet
+---+---+---+---+---+---+---+---+
: :
/ 0-2 octets of CID / 1 or 2 octets if large CIDs
: :
+---+---+---+---+---+---+---+---+
| Profile | 1 octet
+---+---+---+---+---+---+---+---+
| CRC | 1 octet
+---+---+---+---+---+---+---+---+
| |
/ profile specific information / variable length
| |
+---+---+---+---+---+---+---+---+
x: Profile specific information. Interpreted according to the
profile indicated in the Profile field of the IR header.
Profile: The profile associated with the CID. In the IR header, the
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profile identifier is abbreviated to the 8 least significant bits
(see section 5.1.2).
CRC: 8-bit CRC (see section 5.3.1.1).
Profile specific information: The content of this part of the IR
header is defined by the individual profiles. It is interpreted
according to the profile indicated in the Profile field.
5.2.2.2. ROHC IR-DYN Packet Type
In contrast to the IR header, the IR-DYN header can never initialize
an non-initialized context. However, it can redefine what profile is
associated with a context, if the profile indicated in the IR-DYN
header allows this. Thus this packet type is also reserved at the
framework level. The IR-DYN header typically also initializes or
refreshes parts of a context. For IR-DYN, Header has the following
general format:
0 1 2 3 4 5 6 7
--- --- --- --- --- --- --- ---
: Add-CID octet : if CID 1-15 and small CID
+---+---+---+---+---+---+---+---+
| 1 1 1 1 1 0 0 0 | IR-DYN type octet
+---+---+---+---+---+---+---+---+
: :
/ 0-2 octets of CID / 1 or 2 octets if large CIDs
: :
+---+---+---+---+---+---+---+---+
| Profile | 1 octet
+---+---+---+---+---+---+---+---+
| CRC | 1 octet
+---+---+---+---+---+---+---+---+
| |
/ profile specific information / variable length
| |
+---+---+---+---+---+---+---+---+
Profile: The profile associated with the CID. This is abbreviated in
the same way as in IR packets.
CRC: 8-bit CRC (see section 5.3.1.1).
Profile specific information: The content of this part of the IR-DYN
header is defined by the individual profiles. It is interpreted
according to the profile indicated in the Profile field.
5.2.3. ROHC Initial Decompressor Processing
Initially, all contexts are in no context state. Thus, all packets
referencing an non-initialized context, except packets that have
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enough information on the static fields, can not be decompressed by
the decompressor.
When the decompressor receives a packet of type IR, the profile
indicated in the IR packet determines how it is to be processed.
o If the 8-bit CRC fails to verify the integrity of the Header,
the packet MUST NOT be decompressed and delivered to upper
layers. If a profile is indicated in the context, the logic of
that profile determines what, if any, feedback is to be sent. If
no profile is noted in the context, the logic used to determine
what, if any, feedback to send is up to the implementation.
However, it may be suitable to take no further actions as any
part of the IR header covered by the CRC may have caused the
failure.
When the decompressor receives a packet of type IR-DYN, the profile
indicated in the IR-DYN packet determines how it is to be processed.
o If the 8-bit CRC fails to verify the integrity of the header,
the packet MUST NOT be decompressed and delivered to upper
layers. If a profile is indicated in the context, the logic of
that profile determines what, if any, feedback is to be sent. If
no profile is noted in the context, the logic used to determine
what, if any, feedback to send is up to the implementation.
However, it may be suitable to take no further actions as any
part of the IR-DYN header covered by the CRC may have caused the
failure.
o If the context has not already been initialized, the packet MUST
NOT be decompressed and delivered to upper layers. The logic of
the profile indicated in the IR-DYN header (if verified by the
8-bit CRC), determines what, if any, feedback is to be sent.
If a parsing error occurs for any packet type, the decompressor MUST
discard the packet without further processing. For example, a CID
field is present in the compressed header when the large CID space is
used for the ROHC channel, and the field is coded using the self-
describing variable-length encoding of section 5.3.2; if the field
starts with 110 or 111, this would generate a parsing error for the
decompressor because this field must not be encoded with a size
larger than 2 octets.
It is RECOMMENDED that profiles disallow the decompressor to make a
decompression attempt for packets carrying only a 3-bit CRC after it
has invalidated some or the entire dynamic context, until a packet
that contains sufficient information on the dynamic fields is
received, decompressed and successfully verified by a 7- or an 8-bit
CRC.
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5.2.4. ROHC Feedback
Feedback carries information from decompressor to compressor.
Feedback can be sent over a ROHC channel that operates in the same
direction as the feedback.
The general ROHC packet format allows transport of feedback using
interspersion or piggybacking (see [5]), or a combination of both,
over a ROHC channel. This is facilitated by the following properties:
Reserved packet type:
A feedback packet type is reserved at the framework level. The
packet type can carry variable-length feedback information.
CID information:
The feedback information sent on a particular channel is passed
to, and interpreted by, the compressor associated with feedback on
that channel. Thus, each feedback element contains CID
information from the channel for which the feedback is sent. The
ROHC feedback scheme thus requires that a channel carries feedback
to at most one compressor. How a compressor is associated with the
feedback for a particular channel is outside the scope of this
specification. See also [5].
Length information:
The length of a feedback element can be determined by examining
the first few octets of the feedback. This enables piggybacking of
feedback, and also the concatenation of more than one feedback
element in a packet. The length information thus decouples the
decompressor from the associated same-side compressor, as the
decompressor can extract the feedback information from the
compressed header without parsing its content, and hand over the
extracted information.
The association between compressor-decompressor pairs operating in
opposite directions, for the purpose of exchanging piggyback and/or
interspersed feedback, SHOULD be maintained for the lifetime of the
ROHC channel. Otherwise, it is RECOMMENDED that the compressor be
notified if the feedback channel is no longer available: the
compressor SHOULD then restart compression by creating a new context
for each packet flow, and SHOULD use a CID value that was not
previously associated with the profile used to compress the flow.
5.2.4.1. ROHC Feedback Format
ROHC defines three different categories of feedback messages:
acknowledgment (ACK), negative ACK (NACK) and NACK for the entire
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context (STATIC-NACK). Other type of information may be defined in
profile-specific feedback information.
ACK : Acknowledges successful decompression of a packet.
Indicates that the decompressor considers its context
to be valid.
NACK : Indicates that the decompressor considers some or all
of the dynamic part of its context invalid.
STATIC-NACK : Indicates that the decompressor considers its entire
static context invalid, or that it has not been
established.
Feedback sent on a ROHC channel consists of one or more concatenated
feedback elements, where each feedback element has the following
format:
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| 1 1 1 1 0 | Code | feedback type
+---+---+---+---+---+---+---+---+
: Size : if Code = 0
+---+---+---+---+---+---+---+---+
: Add-CID octet : if for small CIDs and (CID != 0)
+---+---+---+---+---+---+---+---+
: :
/ large CID (5.3.2 encoding) / 1-2 octets if for large CIDs
: :
+---+---+---+---+---+---+---+---+
/ FEEDBACK data / variable length
+---+---+---+---+---+---+---+---+
Code: 0 indicates that a Size octet is present.
1-7 indicates the size of the feedback data field, in
octets.
Size: Indicates the size of the feedback data field, in octets.
FEEDBACK data: FEEDBACK-1 or FEEDBACK-2 (see below).
CID information in a feedback element indicates the context for which
feedback is sent. The LARGE_CIDS parameter that controls whether a
large CID is present is taken from the channel state of the receiving
compressor's channel, not from the state of the channel carrying the
feedback.
The large CID field, if present, is encoded according to section
5.3.2, and it MUST NOT be encoded using more than 2 octets.
The FEEDBACK data field can have either of the following two formats:
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FEEDBACK-1:
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| profile specific information | 1 octet
+---+---+---+---+---+---+---+---+
FEEDBACK-2:
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
|Acktype| |
+---+---+ profile specific / at least 2 octets
/ information |
+---+---+---+---+---+---+---+---+
Acktype: 0 = ACK
1 = NACK
2 = STATIC-NACK
3 is reserved (MUST NOT be used. Otherwise unparseable.)
5.2.5. ROHC Segmentation
ROHC defines a simple segmentation protocol. The compressor may
perform segmentation e.g. to accommodate packets that are larger than
a specific size configured for the channel.
5.2.5.1. Segmentation Usage Considerations
The ROHC segmentation protocol is not particularly efficient. It is
not intended to replace link layer segmentation functions; these
SHOULD be used whenever available and efficient for the task at hand.
The ROHC segmentation protocol has been designed with an assumption
of in-order delivery of packets between the compressor and the
decompressor, using only a CRC for error detection, and no sequence
numbers. If in-order delivery cannot be guaranteed, ROHC segmentation
MUST NOT be used.
The segmentation protocol also assumes all segments of a ROHC packet
corresponding to one context are received without interference from
other ROHC packets over the channel, including any ROHC packet
corresponding to a different context. Based on this assumption,
segments do not carry CID information, and can therefore not be
associated with a specific context until all segments have been
received and the whole unit has been reconstructed.
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5.2.5.2. Segmentation Protocol
ROHC segmentation is applied to the combination of the Header and the
Payload fields of the ROHC packet, as defined in section 5.2.1.
Segment format:
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| 1 1 1 1 1 1 1 | F | segment type
+---+---+---+---+---+---+---+---+
/ Segment / variable length
+---+---+---+---+---+---+---+---+
F: Final bit. If set, it indicates that this is the last segment of
a reconstructed unit.
Padding and/or Feedback may precede the segment type octet. There is
no per-segment CID, but CID information is of course part of the
reconstructed unit. The reconstructed unit MUST NOT contain padding,
segments or feedback.
When a final segment is received, the decompressor reassembles the
segment carried in this packet and any non-final segments that
immediately preceded it into a single reconstructed unit, in the
order they were received. All segments for one reconstructed unit
have to be received consecutively and in the correct order by the
decompressor. If a non-segment ROHC packet directly follows a non-
final segment, the reassembly of the current reconstructed unit is
aborted and the decompressor MUST discard the non-final segments so
far received on this channel.
Reconstructed unit:
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
/ Header / (see section 5.2.1)
+---+---+---+---+---+---+---+---+
: Payload : (see section 5.2.1)
+---+---+---+---+---+---+---+---+
/ CRC / 4 octets
+---+---+---+---+---+---+---+---+
CRC: 32-bit CRC computed using the polynomial of section 5.3.1.4.
If the reconstructed unit is 4 octets or less, or if the CRC fails,
or if it is larger than the channel parameter MRRU (see 5.1.2), the
reconstructed unit MUST be discarded by the decompressor. If the CRC
succeeds, the reconstructed unit can be further processed.
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5.3. General Encoding Methods
5.3.1. Header Compression CRCs, Coverage and Polynomials
This chapter describes how to calculate the CRCs used by ROHC. For
all CRCs, the algorithm used to calculate the CRC is the same as the
one used in [2], defined in appendix A of this document, with the
polynomials specified in subsequent sections.
5.3.1.1. 8-bit CRCs in IR and IR-DYN Headers
The coverage for the 8-bit CRC in IR and IR-DYN headers is profile-
dependent, but it MUST cover at least the initial part of the header
ending with the profile field, including CID or an Add-CID octet.
Feedback and padding are not part of Header (section 5.2.1) and are
thus not included in the CRC calculation. As a rule of thumb for
profile specifications, any other information which initializes the
decompressor context SHOULD also be covered by a CRC.
More specifically, the 8-bit CRC does not cover only and entirely the
original uncompressed header; therefore it does not provide the means
for the decompressor to verify a decompression attempt, or either the
means to verify the correctness of the entire decompressor context.
However, when successful, it does provide enough robustness for the
decompressor to update its context with the information carried
within the IR or the IR-DYN header.
The CRC polynomial for the 8-bit CRC is:
C(x) = 1 + x + x^2 + x^8
When computing the CRC, the CRC field in the header is set to zero,
and the initial content of the CRC register is set to all 1's.
5.3.1.2. 3-bit CRC in Compressed Headers
The 3-bit CRC in compressed headers is calculated over all octets of
the entire original header, before compression, in the following
manner.
The initial content of the CRC register is set to all 1's.
The polynomial for the 3-bit CRC is:
C(x) = 1 + x + x^3
The purpose of the 3-bit CRC is to provide the means for the
decompressor to verify the outcome of a decompression attempt for
small compressed headers, and to detect context damage based on
aggregated probability over a number of decompression attempts. It is
however too weak to provide enough success guarantees from the
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decompression of one single header. Therefore, compressed headers
carrying a 3-bit CRC are normally not suitable to perform context
repairs at the decompressor; hence profiles should refrain from
allowing decompression of such header when some or the entire
decompressor context is assumed invalid.
5.3.1.3. 7-bit CRC in Compressed Headers
The 7-bit CRC in compressed headers is calculated over all octets of
the entire original header, before compression, in the following
manner.
The initial content of the CRC register is set to all 1's.
The polynomial for the 7-bit CRC is:
C(x) = 1 + x + x^2 + x^3 + x^6 + x^7
The purpose of the 7-bit CRC is to provide the means for the
decompressor to verify the outcome of a decompression attempt for a
larger compressed header, and to provide enough protection to
validate a context repair at the decompressor. The 7-bit CRC is
strong enough to assume a repair to be successful from the
decompression of one single header; hence profiles may allow
decompression of a header carrying a 7-bit CRC when some of the
decompressor context is assumed invalid.
5.3.1.4. 32-bit Segmentation CRC
The 32-bit CRC is used by the segmentation scheme to verify the
reconstructed unit, and it is thus calculated over the segmented
unit, i.e. over the Header and the Payload fields of the ROHC packet.
The initial content of the CRC register is set to all 1's.
The polynomial for the 32-bit CRC is:
C(x) = x^0 + x^1 + x^2 + x^4 + x^5 + x^7 + x^8 + x^10 +
x^11 + x^12 + x^16 + x^22 + x^23 + x^26 + x^32.
The purpose of the 32-bit CRC is to verify the reconstructed unit.
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5.3.2. Self-describing Variable-length Values
The values of many fields and compression parameters can vary widely.
To optimize the transfer of such values, a variable number of octets
are used to encode them. The first few bits of the first octet
determine the number of octets used:
First bit is 0: 1 octet.
7 bits transferred.
Up to 127 decimal.
Encoded octets in hexadecimal: 00 to 7F
First bits are 10: 2 octets.
14 bits transferred.
Up to 16 383 decimal.
Encoded octets in hexadecimal: 80 00 to BF FF
First bits are 110: 3 octets.
21 bits transferred.
Up to 2 097 151 decimal.
Encoded octets in hexadecimal: C0 00 00 to DF FF FF
First bits are 111: 4 octets.
29 bits transferred.
Up to 536 870 911 decimal.
Encoded octets in hexadecimal: E0 00 00 00 to FF FF FF FF
5.4. ROHC UNCOMPRESSED -- No Compression (Profile 0x0000)
This section describes the uncompressed ROHC profile. The profile
identifier for this profile is 0x0000.
Profile 0x0000 provides a way to send IP packets without compressing
them. This can be used for any packet for which a compression profile
is not available in the set of profiles supported by the ROHC
channel, or for which compression is not desirable for some reason.
After initialization, the only overhead for sending packets using
Profile 0x0000 is the size of the CID. When uncompressed packets are
frequent, Profile 0x0000 should be associated with a CID with size
zero or one octet. Profile 0x0000 SHOULD be associated with at most
one CID.
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5.4.1. IR Packet
The initialization packet (IR packet) for Profile 0x0000 has the
following Header format:
0 1 2 3 4 5 6 7
--- --- --- --- --- --- --- ---
: Add-CID octet : if for small CIDs and (CID != 0)
+---+---+---+---+---+---+---+---+
| 1 1 1 1 1 1 0 |res|
+---+---+---+---+---+---+---+---+
: :
/ 0-2 octets of CID info / 1-2 octets if for large CIDs
: :
+---+---+---+---+---+---+---+---+
| Profile = 0x00 | 1 octet
+---+---+---+---+---+---+---+---+
| CRC | 1 octet
+---+---+---+---+---+---+---+---+
res: MUST be set to zero; otherwise the decompressor MUST discard the
packet.
Profile: 0x00
CRC: 8-bit CRC, computed using the polynomial of section
5.3.1.1. The CRC covers the first octet of the IR Header
through the Profile octet of the IR Header, i.e., it does not
cover the CRC itself. Neither does it cover any preceding
Padding or Feedback, nor the Payload.
For the IR packet, Payload has the following format:
--- --- --- --- --- --- --- ---
: : (optional)
/ IP packet / variable length
: :
--- --- --- --- --- --- --- ---
IP packet: An uncompressed IP packet may be included in the IR
packet. The decompressor determines if the IP packet is
present by considering the length of the IR packet.
5.4.2. Normal Packet
A Normal packet is a normal IP packet plus CID information. For the
Normal Packet, the following format corresponds to Header and Payload
(as defined in section 5.2.1):
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0 1 2 3 4 5 6 7
--- --- --- --- --- --- --- ---
: Add-CID octet : if for small CIDs and (CID != 0)
+---+---+---+---+---+---+---+---+
| first octet of IP packet |
+---+---+---+---+---+---+---+---+
: :
/ 0-2 octets of CID info / 1-2 octets if for large CIDs
: :
+---+---+---+---+---+---+---+---+
| |
/ rest of IP packet / variable length
| |
+---+---+---+---+---+---+---+---+
Note that the first octet of the IP packet starts with the bit
pattern 0100 (IPv4) or 0110 (IPv6). This does not conflict with any
reserved packet types.
When the channel uses small CIDs, and profile 0x0000 is associated
with a CID > 0, an Add-CID octet precedes the IP packet. When the
channel uses large CIDs, the CID is placed so that it starts at the
second octet of the combined Header/Payload format above.
A Normal Packet may carry Padding and/or Feedback as any other ROHC
packet, preceding the combined Header/Payload.
5.4.3. Decompressor Operation
When an IR packet is received, the decompressor first validates its
header using the 8-bit CRC.
o If the header fails validation, the decompressor MUST NOT deliver
the IP packet to upper layers.
o If the header is successfully validated, the decompressor;
1) initializes the context if it has no valid context for the
given CID already associated to the specified profile,
2) delivers the IP packet to upper layers if present,
3) MAY send an ACK.
When any other packet is received while the decompressor has no
context, it is discarded without further action.
When a Normal packet is received and the decompressor has a valid
context, the IP packet is extracted and delivered to upper layers.
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5.4.4. Feedback
The only kind of feedback defined by Profile 0x0000 is ACK, using the
FEEDBACK-1 format of section 5.2.4.1, where the value of the profile-
specific octet in the FEEDBACK-1 is 0 (zero). The FEEDBACK-2 format
is thus not defined for Profile 0x0000.
6. Overview of a ROHC Profile (Informative)
The ROHC protocol consists of a framework part and a profile part.
The framework defines the mechanisms common to all profiles, while
the profile defines the compression algorithm and profile specific
packet formats.
Section 5 specified the details of the ROHC framework. This section
provides an informative overview of the elements that make a profile
specification. The normative specification of individual profiles is
outside the scope of this document.
A ROHC profile defines the elements that build up the compression
protocol. A ROHC profile consists of:
Packet formats:
o Bits-on-the-wire
The profile defines the layout of the bits for profile-specific
packet types that it defines, and for the profile-specific parts
of packet types common to all profiles (e.g. IR and IR-DYN).
o Field encodings
Bits and groups of bits from the packet format layout, referred
to as compressed fields, represents the result of an encoding
method specific for that compressed field within a specific
packet format. The profile defines these encoding methods.
o Updating properties
The profile-specific packet formats may update the state of the
decompressor, and may do so in different ways. The profile
defines how individual profile-specific fields, or entire
profile-specific packet types, update the decompressor context.
o Verification
Packets that update the state of the decompressor are verified,
to prevent incorrect updates to the decompressor context. The
profile defines the mechanisms used to verify the decompression
of a packet.
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Context management:
o Robustness logic
Packets may be lost or reordered between the compressor and the
decompressor. The profile defines mechanism to minimize the
impacts of such events, and prevent damage propagation.
o Repair mechanism
Despite the robustness logic, impairment events may still lead to
decompression failure(s), and even to context damage at the
decompressor. The profile defines context repair mechanisms,
including feedback logic if used.
7. Security Considerations
Because encryption eliminates the redundancy that header compression
schemes try to exploit, there is some inducement to forego encryption
of headers in order to enable operation over low-bandwidth links.
A malfunctioning or malicious header compressor could cause the
header decompressor to reconstitute packets that do not match the
original packets but still have valid headers and possibly also valid
transport checksums. Such corruption may be detected with end-to-end
authentication and integrity mechanisms, which will not be affected
by the compression. Moreover, the ROHC header compression scheme uses
an internal checksum for verification of reconstructed headers, which
reduces the probability of producing decompressed headers not
matching the original ones without this being noticed.
Denial-of-service attacks are possible if an intruder can introduce
(for example) bogus IR, IR-DYN or FEEDBACK packets onto the link and
thereby cause compression efficiency to be reduced. However, an
intruder having the ability to inject arbitrary packets at the link
layer in this manner raises additional security issues that dwarf
those related to the use of header compression.
8. IANA Considerations
An IANA registry for "RObust Header Compression (ROHC) Profile
Identifiers" [21] was created by RFC 3095 [3]. The assignment policy,
as outlined by RFC 3095, is the following:
The ROHC profile identifier is a non-negative integer. In many
negotiation protocols, it will be represented as a 16-bit value. Due
to the way the profile identifier is abbreviated in ROHC packets, the
8 least significant bits of the profile identifier have a special
significance: Two profile identifiers with identical 8 LSBs should be
assigned only if the higher-numbered one is intended to supersede the
lower-numbered one. To highlight this relationship, profile
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identifiers should be given in hexadecimal (as in 0x1234, which would
for example supersede 0x0A34).
Following the policies outlined in [22], the IANA policy for
assigning new values for the profile identifier shall be
Specification Required: values and their meanings must be documented
in an RFC or in some other permanent and readily available reference,
in sufficient detail that interoperability between independent
implementations is possible. In the 8 LSBs, the range 0 to 127 is
reserved for IETF standard-track specifications; the range 128 to 254
is available for other specifications that meet this requirement
(such as Informational RFCs). The LSB value 255 is reserved for
future extensibility of the present specification.
The following profile identifiers have so far been allocated:
Profile Identifier Usage Reference
------------------ ---------------------- ---------
0x0000 ROHC uncompressed RFC 3095
0x0001 ROHC RTP RFC 3095
0x0002 ROHC UDP RFC 3095
0x0003 ROHC ESP RFC 3095
0x0004 ROHC IP RFC 3843
0x0005 ROHC LLA RFC 3242
0x0105 ROHC LLA with R-mode RFC 3408
0x0006 ROHC TCP RFC XXXX [RFC-ed]
0x0007 ROHC RTP/UDP-Lite RFC 4019
0x0008 ROHC UDP-Lite RFC 4019
New profiles will need new identifiers to be assigned by the IANA,
but this document does not require any additional IANA action.
9. Acknowledgments
The authors would like to acknowledge all who have contributed to
previous ROHC work, and especially to the authors of RFC 3095 [3],
which is the technical basis for this document. Thanks also to the
various individuals who contributed to the RFC 3095 corrections and
clarifications document [6], from which technical contents, when
applicable, have been incorporated into this document. Committed WG
document reviewers were Carl Knutsson and Biplab Sarkar, who reviewed
the document during working group last-call.
10. References
10.1. Normative References
[1] S. Bradner, "Key words for use in RFCs to Indicate Requirement
Levels", RFC 2119, March 1997.
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10.2. Informative References
[2] W. Simpson, "PPP in HDLC-like framing", STD 51, RFC 1662, July
1994.
[3] C. Bormann, et al., "RObust Header Compression (ROHC): Framework
and four profiles: RTP, UDP, ESP, and uncompressed", RFC 3095,
July 2001.
[4] C. Bormann, "RObust Header Compression (ROHC) over PPP", RFC
3241, April 2002.
[5] L-E. Jonsson, "RObust Header Compression (ROHC): Terminology and
Channel Mapping Examples", RFC 3759, April 2004.
[6] L-E. Jonsson, et al., "RObust Header Compression (ROHC):
Corrections and Clarifications to RFC 3095", internet-draft
(work in progress), September 2006.
<draft-ietf-rohc-rtp-impl-guide-20.txt>
[7] G. Pelletier, L-E. Jonsson, and K. Sandlund, "RObust Header
Compression (ROHC): ROHC over Channels that can Reorder
Packets", RFC 4224, January 2006.
[8] G. Pelletier, and K. Sandlund, "RObust Header Compression
Version 2 (ROHCv2): Profiles for RTP, UDP, IP, ESP, and UDP-
Lite", internet-draft (work in progress), September 2006.
<draft-ietf-rohc-rfc3095bis-rohcv2-profiles-00.txt>
[9] G. Pelletier, L-E. Jonsson, K. Sandlund, and M. West, "RObust
Header Compression (ROHC): A Profile for TCP/IP (ROHC-TCP)",
internet-draft (work in progress), October 2006.
<draft-ietf-rohc-tcp-13.txt>
[10] J. Postel, "Internet Protocol", STD 5, RFC 791, September 1981.
[11] Deering, S. and R. Hinden, "Internet Protocol, Version 6 (IPv6)
Specification", RFC 2460, December 1998.
[12] J. Postel, "User Datagram Protocol", STD 6, RFC 768, August
1980.
[13] Schulzrinne, H., Casner, S., Frederick, R. and V. Jacobson,
"RTP: A Transport Protocol for Real-Time Applications", RFC
3550, July 2003.
[14] Postel, J., "Transmission Control Protocol", STD 7, RFC 793,
September 1981.
[15] V. Jacobson, "Compressing TCP/IP Headers for Low-Speed Serial
Links", RFC 1144, February 1990.
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INTERNET-DRAFT The ROHC Framework November 2006
[16] Degermark, M., Nordgren, B. and S. Pink, "IP Header
Compression", RFC 2507, February 1999.
[17] Casner, S. and V. Jacobson, "Compressing IP/UDP/RTP Headers for
Low-Speed Serial Links", RFC 2508, February 1999.
[18] M. Degermark, "Requirements for robust IP/UDP/RTP header
compression", RFC 3096, July 2001.
[19] T. Koren, et al., "Enhanced Compressed RTP (CRTP) for Links with
High Delay, Packet Loss and Reordering", RFC 3545, July 2003.
[20] Degermark, M., Hannu, H., Jonsson, L.E., and K. Svanbro,
"Evaluation of CRTP Performance over Cellular Radio Networks",
IEEE Personal Communication Magazine, Volume 7, number 4, pp.
20-25, August 2000.
[21] IANA registry, "RObust Header Compression (ROHC) Profile
Identifiers", http://www.iana.org/assignments/rohc-pro-ids
[22] Alvestrand, H. and T. Narten, "Guidelines for Writing an IANA
Considerations Section in RFCs", BCP 26, RFC 2434, October 1998.
11. Authors' Addresses
Lars-Erik Jonsson
Optand 737
SE-831 92 Ostersund, Sweden
Phone: +46 70 365 20 58
EMail: lars-erik@lejonsson.com
Ghyslain Pelletier
Ericsson AB
Box 920
SE-971 28 Lulea, Sweden
Phone: +46 8 404 29 43
Fax: +46 920 996 21
EMail: ghyslain.pelletier@ericsson.com
Kristofer Sandlund
Ericsson AB
Box 920
SE-971 28 Lulea, Sweden
Phone: +46 8 404 41 58
Fax: +46 920 996 21
EMail: kristofer.sandlund@ericsson.com
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Appendix A - CRC Algorithm
#!/usr/bin/perl -w
use strict;
#=================================
#
# ROHC CRC demo - Carsten Bormann cabo@tzi.org 2001-08-02
#
# This little demo shows the four types of CRC in use in RFC 3095,
# the specification for robust header compression. Type your data in
# hexadecimal form and then press Control+D.
#
#---------------------------------
#
# utility
#
sub dump_bytes($) {
my $x = shift;
my $i;
for ($i = 0; $i < length($x); ) {
printf("%02x ", ord(substr($x, $i, 1)));
printf("\n") if (++$i % 16 == 0);
}
printf("\n") if ($i % 16 != 0);
}
#---------------------------------
#
# The CRC calculation algorithm.
#
sub do_crc($$$) {
my $nbits = shift;
my $poly = shift;
my $string = shift;
my $crc = ($nbits == 32 ? 0xffffffff : (1 << $nbits) - 1);
for (my $i = 0; $i < length($string); ++$i) {
my $byte = ord(substr($string, $i, 1));
for( my $b = 0; $b < 8; $b++ ) {
if (($crc & 1) ^ ($byte & 1)) {
$crc >>= 1;
$crc ^= $poly;
} else {
$crc >>= 1;
}
$byte >>= 1;
}
}
printf "%2d bits, ", $nbits;
printf "CRC: %02x\n", $crc;
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}
#---------------------------------
#
# Test harness
#
$/ = undef;
$_ = <>; # read until EOF
my $string = ""; # extract all that looks hex:
s/([0-9a-fA-F][0-9a-fA-F])/$string .= chr(hex($1)), ""/eg;
dump_bytes($string);
#---------------------------------
#
# 32-bit segmentation CRC
# Note that the text implies this is complemented like for PPP
# (this differs from 8, 7, and 3-bit CRC)
#
# C(x) = x^0 + x^1 + x^2 + x^4 + x^5 + x^7 + x^8 + x^10 +
# x^11 + x^12 + x^16 + x^22 + x^23 + x^26 + x^32
#
do_crc(32, 0xedb88320, $string);
#---------------------------------
#
# 8-bit IR/IR-DYN CRC
#
# C(x) = x^0 + x^1 + x^2 + x^8
#
do_crc(8, 0xe0, $string);
#---------------------------------
#
# 7-bit FO/SO CRC
#
# C(x) = x^0 + x^1 + x^2 + x^3 + x^6 + x^7
#
do_crc(7, 0x79, $string);
#---------------------------------
#
# 3-bit FO/SO CRC
#
# C(x) = x^0 + x^1 + x^3
#
do_crc(3, 0x6, $string);
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Disclaimer of Validity
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This Internet-Draft expires May 29, 2007.
Jonsson, et. al [Page 37]
