One document matched: draft-irtf-dtnrg-sdnv-03.txt
Differences from draft-irtf-dtnrg-sdnv-02.txt
Network Working Group W. Eddy
Internet-Draft Verizon
Intended status: Informational August 18, 2009
Expires: February 19, 2010
Using Self-Delimiting Numeric Values in Protocols
draft-irtf-dtnrg-sdnv-03
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Abstract
Self-Delimiting Numeric Values (SDNVs) have recently been introduced
as a field type in proposed Delay-Tolerant Networking protocols.
SDNVs encode an arbitrary-length non-negative integer with minimum
wire-overhead. They are intended to provide protocol flexibility
without sacrificing economy, and to assist in future-proofing
protocols under development. This document describes formats and
algorithms for SDNV encoding and decoding, along with notes on
implementation and usage.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Problems with Fixed Value Fields . . . . . . . . . . . . . 3
1.2. SDNVs for DTN Protocols . . . . . . . . . . . . . . . . . 4
1.3. SDNV Usage . . . . . . . . . . . . . . . . . . . . . . . . 5
2. Definition of SDNVs . . . . . . . . . . . . . . . . . . . . . 7
3. Basic Algorithms . . . . . . . . . . . . . . . . . . . . . . . 8
3.1. Encoding Algorithm . . . . . . . . . . . . . . . . . . . . 8
3.2. Decoding Algorithm . . . . . . . . . . . . . . . . . . . . 8
4. Comparison to Alternatives . . . . . . . . . . . . . . . . . . 10
5. Security Considerations . . . . . . . . . . . . . . . . . . . 14
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 15
7. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 16
8. Informative References . . . . . . . . . . . . . . . . . . . . 17
Appendix A. SNDV Python Source Code . . . . . . . . . . . . . . . 19
Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . 21
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1. Introduction
This document is a product of the Internet Research Task Force (IRTF)
Delay-Tolerant Networking (DTN) Research Group (DTNRG). The document
has received review and support within the DTNRG, as discussed in the
Acknowledgements section of this document.
This document begins by describing a common problem encountered in
network protocol engineering. It then provides some background on
the Self-Delimiting Numeric Values (SDNVs) proposed for use in DTN
protocols, and motivates their potential applicability in other
networking protocols. The DTNRG has created SDNVs to meet the
challenges it attempts to solve, and it has been noted that SDNVs
closely resemble certain constructs within ASN.1 and even older ITU
protocols, so the problems are not new or unique to DTN, nor is the
solution too radical for more mundane uses.
SDNVs are tersely defined in both the bundle protocol [RFC5050] and
LTP [RFC5326] specifications, due to the flow of document production
in the DTNRG. This document clarifies and further explains the
motivations and engineering decisions behind SDNVs.
1.1. Problems with Fixed Value Fields
Protocol designers commonly face an optimization problem in
determining the proper size for header fields. There is a strong
desire to keep fields as small as possible, in order to reduce the
protocol's overhead on the wire, and also allow for fast processing.
Since protocols can be used many years (even decades) after they are
designed, and networking technology has tended to change rapidly, it
is not uncommon for the use, deployment, or performance of a
particular protocol to be limited or infringed upon by the length of
some header field being too short. Two well-known examples of this
phenomenon are the TCP advertised receive window, and the IPv4
address length.
TCP segments contain an advertised receive window field that is fixed
at 16 bits [RFC0793], encoding a maximum value of around 65
kilobytes. The purpose of this value is to provide flow control, by
allowing a receiver to specify how many sent bytes its peer can have
outstanding (unacknowledged) at any time, thus allowing the receiver
to limit its buffer size. As network speeds have grown by several
orders of magnitude since TCP's inception, the combination of the 65
kilobyte maximum advertised window and long round-trip times
prevented TCP senders from being able to acheive the high-rates that
the underlying network supported. This limitation was remedied
through the use of the Window Scale option [RFC1323], which provides
a multiplier for the advertised window field. However, the Window
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Scale multiplier is fixed for the duration of the connection,
requires bi-directional support, and limits the precision of the
advertised receive window, so this is certainly a less-than-ideal
solution. Because of the field width limit in the original design
however, the Window Scale is necessary for TCP to reach high sending
rates.
An IPv4 address is fixed at 32 bits [RFC0791] (as a historical note,
earlier versions of the IP specification supported variable-length
addresses). Due to the way that subnetting and assignment of address
blocks was performed, the number of IPv4 addresses has been seen as a
limit to the growth of the Internet [Hain05]. Two divergent paths to
solve this problem have been the use of Network Address Translators
(NATs) and the development of IPv6. NATs have caused a number of
side-issues and problems [RFC2993], leading to increased complexity
and fragility, as well as forcing work-arounds to be engineered for
many other protocols to function within a NATed environment. The
IPv6 solution's transitional work has been underway for several
years, but has still only begun to have visible impact on the global
Internet.
Of course, in both the case of the TCP receive window and IPv4
address length, the field size chosen by the designers seemed like a
good idea at the time. The fields were more than big enough for the
originally perceived usage of the protocols, and yet were small
enough to allow the total headers to remain compact and relatively
easy and efficient to parse on machines of the time. The fixed sizes
that were defined represented a tradeoff between the scalability of
the protocol versus the overhead and efficiency of processing. In
both cases, these engineering decisions turned out to be painfully
restrictive in the longer term.
1.2. SDNVs for DTN Protocols
In specifications for the DTN Bundle Protocol (BP) [RFC5050] and
Licklider Transmission Protocol (LTP) [RFC5326], SDNVs have been used
for several fields including identifiers, payload/header lengths, and
serial (sequence) numbers. SDNVs were developed for use in these
types of fields, to avoid sending more bytes than needed, as well as
avoiding fixed sizes that may not end up being appropriate. For
example, since LTP is intended primarily for use in long-delay
interplanetary communications [RFC5325], where links may be fairly
low in capacity, it is desirable to avoid the header overhead of
routinely sending a 64-bit field where a 16-bit field would suffice.
Since many of the nodes implementing LTP are expected to be beyond
the current range of human spaceflight, upgrading their on-board LTP
implementations to use longer values if the defined fields are found
to be too short would also be problematic. Furthermore, extensions
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similar in mechanism to TCP's Window Scale option are unsuitable for
use in DTN protocols since due to high delays, DTN protocols must
avoid handshaking and configuration parameter negotiation to the
greatest extent possible. All of these reasons make the choice of
SDNVs for use in DTN protocols attractive.
1.3. SDNV Usage
In short, an SDNV is simply a way of representing non-negative
integers (both positive integers of arbitrary magnitude and 0),
without expending too-much unneccessary space. This definition
allows SDNVs to represent many common protocol header fields, such
as:
o Random identification fields as used in the IPsec Security
Parameters Index or in IP headers for fragment reassembly (Note:
the 16-bit IP ID field for fragment reassembly was recently found
to be too short in some environments [RFC4963]),
o Sequence numbers as in TCP or SCTP,
o Values used in cryptographic algorithms such as RSA keys, Diffie-
Hellman key-agreement, or coordinates of points on elliptic
curves.
o Message lengths as used in file transfer protocols.
o Nonces and cookies.
o Etc.
The use of SDNVs rather than fixed length fields gives protocol
designers the ability to somewhat circumvent making difficult-to-
reverse field-sizing decisions, since the SDNV wire-format grows and
shrinks depending on the particular value encoded. SDNVs do not
necessarily provide optimal encodings for values of any particular
length, however they allow protocol designers to avoid potential
blunders in assigning fixed lengths, and remove the complexity
involved with either negotiating field lengths or constructing
protocol extensions.
To our knowledge, at this time, no IETF transport or network-layer
protocol designed for use outside of the DTN domain have proposed to
use SDNVs, however there is no inherent reason not to use SDNVs more
broadly in the future. The two examples cited here of fields that
have proven too-small in general Internet protocols are only a small
sampling of the much larger set of similar instances that the authors
can think of. Outside the Internet protocols, within ASN.1 and
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previous ITU protocols, constructs very similar to SDNVs have been
used for many years due to engineering concerns very similar to those
facing the DTNRG.
Many protocols use a Type-Length-Value method for encoding variable
length strings (e.g. TCP's options format, or many of the fields in
IKEv2). An SDNV is equivalent to combining the length and value
portions of this type of field, with the overhead of the length
portion amortized out over the bytes of the value. The penalty paid
for this in an SDNV may be several extra bytes for long values (e.g.
1024 bit RSA keys). See Section 4 for further discussion and a
comparison.
As is shown in later sections, for large values, the current SDNV
scheme is fairly inefficient in terms of space (1/8 of the bits are
overhead) and not particularly easy to encode/decode in comparison to
alternatives. The best use of SDNVs may often be to define the
Length field of a TLV structure to be an SDNV whose value is the
length of the TLV's Value field. In this way, one can avoid forcing
large numbers from being directly encoded as an SDNV, yet retain the
extensibility that using SDNVs grants.
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2. Definition of SDNVs
An early definition of the SDNV format bore resemblance to the ASN.1
[ASN1] Basic Encoding Rules (BER) [ASN1-BER] for lengths (Section
8.1.3 of X.690). The current SDNV format is the one used by ASN.1
BER for encoding tag identifiers greater than or equal to 31 (Section
8.1.2.4.2 of X.690). A comparison between the current SDNV format
and the early SDNV format is made in Section 4.
The currently-used format is very simple. Before encoding, an
integer is represented as a left-to-right bitstring beginning with
its most significant bit, and ending with its least signifcant bit.
On the wire, the bits are encoded into a series of bytes. The most
significant bit of each wire format byte specifies whether it is the
final byte of the encoded value (when it holds a 0), or not (when it
holds a 1). The remaining 7 bits of each byte in the wire format are
taken in-order from the integer's bitstring representation. If the
bitstring's length is not a multiple of 7, then the string is left-
padded with 0s.
For example:
o 1 (decimal) is represented by the bitstring "0000001" and encoded
as the single byte 0x01 (in hexadecimal)
o 128 is represented by the bitstring "10000001 00000000" and
encoded as the bytes 0x81 followed by 0x00.
o Other values can be found in the test vectors of the source code
in Appendix A
To be perfectly clear, and avoid potential interoperability issues
(as have occurred with ASN.1 BER time values), we explicitly state
two considerations regarding zero-padding. (1) When encoding SDNVs,
any leading (most significant) zero bits in the input number might be
discarded by the SDNV encoder. Protocols that use SDNVs should not
rely on leading-zeros being retained after encoding and decoding
operations. (2) When decoding SDNVs, the relevant number of leading
zeros required to pad up to a machine word or other natural data unit
might be added. These are put in the most-significant positions in
order to not change the value of the number. Protocols using SDNVs
should consider situations where lost zero-padding may be
problematic.
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3. Basic Algorithms
This section describes some simple algorithms for creating and
parsing SDNV fields. These may not be the most efficient algorithms
possible, however, they are easy to read, understand, and implement.
Appendix A contains Python source code implementing the routines
described here. Only SDNV's of the currently-used form are
considered in this section.
3.1. Encoding Algorithm
There is a very simple algorithm for the encoding operation that
converts a non-negative integer (n, of length 1+floor(log_2 n) bits)
into an SDNV. This algorithm takes n as its only argument and
returns a string of bytes:
o (Initial Step) Set the return value to a byte sharing the least
significant 7 bits of n, and with 0 in the most significant bit,
but do not return yet. Right shift n 7 bits and use this as the
new n value. If implemented using call-by-reference rather than
call-by-value, make a copy of n for local use at the start of the
function call.
o (Recursion Step) If n == 0, return. Otherwise, take the byte
0x80, and bitwise-or it with the 7 least significant bits left in
n. Set the return value to this result with the previous return
string appended to it. Set n to itself shifted right 7 bits
again. Repeat Recursion Step.
This encoding algorithm can easily be seen to have time complexity of
O(log_2 n), since it takes a number of steps equal to ceil(n/7), and
no additional space beyond the size of the result (8/7 log_2 n) is
required. One aspect of this algorithm is that it assumes strings
can be efficiently appended to new bytes. One way to implement this
is to allocate a buffer for the expected length of the result and
fill that buffer one byte at a time from the right end.
If, for some reason, an implementation requires an encoded SDNV to be
some specific length (possibly related to a machine word), any
leftmost zero-padding included needs to properly set the high-order
bit in each byte of padding.
3.2. Decoding Algorithm
Decoding SNDVs is a more difficult operation than encoding them, due
to the fact that no bound on the resulting value is known until the
SDNV is parsed, at which point the value itself is already known.
This means that if space is allocated for decoding the value of an
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SDNV into, it is never known whether this space will be overflowed
until it is 7 bits away from happening.
(Initial Step) Set the result to 0. Set a pointer to the beginning
of the SDNV.
(Recursion Step) Shift the result left 7 bits. Add the lower 7 bits
of the value at the pointer to the result. If the high-order bit
under the pointer is a 1, move the pointer right one byte and repeat
the Recursion Step, otherwise return the current value of the result.
This decoding algorithm takes no more additional space than what is
required for the result (7/8 the length of the SDNV) and the pointer.
The complication is that before the result can be left-shifted in the
Recursion Step, an implementation needs to first make sure that this
won't cause any bits to be lost, and re-allocate a larger piece of
memory for the result, if required. The pure time complexity is the
same as for the encoding algorithm given, but if re-allocation is
needed due to the inability to predict the size of the result, in
reality decoding may be slower.
These decoding steps include removal of any leftmost zero-padding
that might be used by an encoder to create encodings of a certain
length.
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4. Comparison to Alternatives
This section compares three alternative ways of implementing the
concept of SDNVs: (1) the TLV scheme commonly used in the Internet
family, and many other families of protocols, (2) the old style of
SDNVs (both the SDNV-8 and SDNV-16) defined in an early stage of
LTP's development [BRF04], and (3) the current SDNV format.
The TLV method uses two fixed-length fields to hold the Type" and
Length elements that then imply the syntax and semantics of the
"value" element. This is only similar to an SDNV in that the value
element can grow or shrink within the bounds capable of being
conveyed by the Length field. Two fundamental differences between
TLVs and SDNVs are that through the Type element, TLVs also contain
some notion of what their contents are semantically, while SDNVs are
simply generic non-negative integers, and protocol engineers still
have to pick fixed-lengths for the Type and Length fields in the TLV
format.
Some protocols use TLVs where the value conveyed within the Length
field needs to be decoded into the actual length of the Value field.
This may be accomplished through simple multiplication, left-
shifting, or a look-up table. In any case, this tactic limits the
granularity of the possible Value lengths, and can contribute some
degree of bloat if Values do not fit neatly within the available
decoded Lengths.
In the SDNV format originally used by LTP, parsing the first byte of
the SDNV told an implementation how much space was required to hold
the contained value. There were two different types of SDNVs defined
for different ranges of use. The SDNV-8 type could hold values up to
127 in a single byte, while the SDNV-16 type could hold values up to
32,767 in 2 bytes. Both formats could encode values requiring up to
N bytes in N+2 bytes, where N<127. The major difference between this
old SDNV format and the currently-used SDNV format is that the new
format is not as easily decoded as the old format was, but the new
format also has absolutely no limitation on its length.
The advantage in ease of parsing the old format manifests itself in
two aspects: (1) the size of the value is determinable ahead of time,
in a way equivalent to parsing a TLV, and (2) the actual value is
directly encoded and decoded, without shifting and masking bits as is
required in the new format. For these reasons, the old format
requires less computational overhead to deal with, but is also very
limited, in that it can only hold a 1024-bit number, at maximum.
Since according to IETF Best Current Practices, an asymmetric
cryptography key needed to last for a long term requires using moduli
of over 1228 bits [RFC3766], this could be seen as a severe
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limitation of the old-style of SDNVs, which the currently-used style
does not suffer from.
Table 1 compares the maximum values that can be encoded into SDNVs of
various lengths using the old SDNV-8/16 method and the current SDNV
method. The only place in this table where SDNV-16 is used rather
than SDNV-8 is in the 2-byte row. Starting with a single byte, the
two methods are equivalent, but when using 2 bytes, the old method is
a more compact encoding by one-bit. From 3 to 7 bytes of length
though, the current SDNV format is more compact, since it only
requires one-bit per byte of overhead, whereas the old format used a
full byte. Thus, at 8 bytes, both schemes are equivalent in
efficiency since they both use 8 bits of overhead. Up to 129 bytes,
the old format is more compact than the current one, although after
this limit it becomes unusable.
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+-------+---------------+-------------+---------------+-------------+
| Bytes | SDNV-8/16 | SDNV | SDNV-8/16 | SDNV |
| | Maximum Value | Maximum | Overhead Bits | Overhead |
| | | Value | | Bits |
+-------+---------------+-------------+---------------+-------------+
| 1 | 127 | 127 | 1 | 1 |
| | | | | |
| 2 | 32,767 | 16,383 | 1 | 2 |
| | | | | |
| 3 | 65,535 | 2,097,151 | 8 | 3 |
| | | | | |
| 4 | 2^24 - 1 | 2^28 - 1 | 8 | 4 |
| | | | | |
| 5 | 2^32 - 1 | 2^35 - 1 | 8 | 5 |
| | | | | |
| 6 | 2^40 - 1 | 2^42 - 1 | 8 | 6 |
| | | | | |
| 7 | 2^48 - 1 | 2^49 - 1 | 8 | 7 |
| | | | | |
| 8 | 2^56 - 1 | 2^56 - 1 | 8 | 8 |
| | | | | |
| 9 | 2^64 - 1 | 2^63 - 1 | 8 | 9 |
| | | | | |
| 10 | 2^72 - 1 | 2^70 - 1 | 8 | 10 |
| | | | | |
| 16 | 2^120 - 1 | 2^112 - 1 | 8 | 16 |
| | | | | |
| 32 | 2^248 - 1 | 2^224 - 1 | 8 | 32 |
| | | | | |
| 64 | 2^504 - 1 | 2^448 - 1 | 8 | 64 |
| | | | | |
| 128 | 2^1016 - 1 | 2^896 - 1 | 8 | 128 |
| | | | | |
| 129 | 2^1024 - 1 | 2^903 - 1 | 8 | 129 |
| | | | | |
| 130 | N/A | 2^910 - 1 | N/A | 130 |
| | | | | |
| 256 | N/A | 2^1792 - 1 | N/A | 256 |
+-------+---------------+-------------+---------------+-------------+
Table 1
In general, it seems like the most promising use of SDNVs may be to
define the Length field of a TLV structure to be an SDNV whose value
is the length of the TLV's Value field. This leverages the strengths
of the SDNV format and limits the effects of its weaknesses.
Another aspect of comparison between SDNVs and alternatives using
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fixed-length fields is the result of errors in transmission. Bit-
errors in an SDNV can result in either errors in the decoded value,
or parsing errors in subsequent fields of the protocol. In fixed-
length fields, bit-errors always result in errors to the decoded
value rather than parsing errors in subsequent fields. If the
decoded values from either type of field encoding (SDNV or fixed-
length) are used as indexes, offsets, or lengths of further fields in
the protocol, similar failures result.
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5. Security Considerations
The only security considerations with regards to SDNVs are that code
which parses SDNVs should have bounds-checking logic and be capable
of handling cases where an SDNV's value is beyond the code's ability
to parse. These precautions can prevent potential exploits involving
SDNV decoding routines.
Stephen Farrell noted that very early definitions of SDNVs also
allowed negative integers. This was considered a potential security
hole, since it could expose implementations to underflow attacks
during SDNV decoding. There is a precedent in that many existing TLV
decoders map the Length field to a signed integer and are vulnerable
in this way. An SDNV decoder should be based on unsigned types and
not have this issue.
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6. IANA Considerations
This document has no IANA considerations.
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7. Acknowledgements
Scott Burleigh, Manikantan Ramadas, Michael Demmer, Stephen Farrell,
and other members of the IRTF DTN Research Group contributed to the
development and usage of SDNVs in DTN protocols. George Jones and
Keith Scott from Mitre, Lloyd Wood, Gerardo Izquierdo, Joel Halpern,
and Peter TB Brett also contributed useful comments on and criticisms
of this document. DTNRG last call comments on the draft were sent to
the mailing list by Lloyd Wood, Will Ivancic, Jim Wyllie, William
Edwards, Hans Kruse, Janico Greifenberg, Teemu Karkkainen, Stephen
Farrell, and Scott Burleigh.
Work on this document was performed at NASA's Glenn Research Center,
in support of the NASA Space Communications Architecture Working
Group (SCAWG), NASA's Earth Science Technology Office (ESTO), and the
FAA/Eurocontrol Future Communications Study (FCS).
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8. Informative References
[ASN1] ITU-T Rec. X.680, "Abstract Syntax Notation One (ASN.1).
Specification of Basic Notation", ISO/IEC 8824-1:2002,
2002.
[ASN1-BER]
ITU-T Rec. X.690, "Abstract Syntax Notation One (ASN.1).
Encoding Rules: Specification of Basic Encoding Rules
(BER), Canonical Encoding Rules (CER) and Distinguished
Encoding Rules (DER)", ISO/IEC 8825-1:2002, 2002.
[BRF04] Burleigh, S., Ramadas, M., and S. Farrell, "Licklider
Transmission Protocol",
draft-irtf-dtnrg-ltp-00 (replaced), May 2004.
[Hain05] Hain, T., "A Pragmatic Report on IPv4 Address Space
Consumption", Internet Protocol Journal Vol. 8, No. 3,
September 2005.
[RFC0791] Postel, J., "Internet Protocol", STD 5, RFC 791,
September 1981.
[RFC0793] Postel, J., "Transmission Control Protocol", STD 7,
RFC 793, September 1981.
[RFC1323] Jacobson, V., Braden, B., and D. Borman, "TCP Extensions
for High Performance", RFC 1323, May 1992.
[RFC2993] Hain, T., "Architectural Implications of NAT", RFC 2993,
November 2000.
[RFC3766] Orman, H. and P. Hoffman, "Determining Strengths For
Public Keys Used For Exchanging Symmetric Keys", BCP 86,
RFC 3766, April 2004.
[RFC4963] Heffner, J., Mathis, M., and B. Chandler, "IPv4 Reassembly
Errors at High Data Rates", RFC 4963, July 2007.
[RFC5050] Scott, K. and S. Burleigh, "Bundle Protocol
Specification", RFC 5050, November 2007.
[RFC5325] Burleigh, S., Ramadas, M., and S. Farrell, "Licklider
Transmission Protocol - Motivation", RFC 5325,
September 2008.
[RFC5326] Ramadas, M., Burleigh, S., and S. Farrell, "Licklider
Transmission Protocol - Specification", RFC 5326,
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March 2008.
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Appendix A. SNDV Python Source Code
# sdnv_decode() takes a string argument s, which is assumed to be an
# SDNV. The function returns a pair of the non-negative integer n
# that is the numeric value encoded in the SDNV, and and integer l
# that is the distance parsed into the input string. If the slen
# argument is not given (or is not a non-zero number) then, s is
# parsed up to the first byte whose high-order bit is 0 -- the
# length of the SDNV portion of s does not have to be pre-computed
# by calling code. If the slen argument is given as a non-zero
# value, then slen bytes of s are parsed. The value for n of -1 is
# returned for any type of parsing error.
#
# NOTE: In python, integers can be of arbitrary size. In other
# languages, such as C, SDNV-parsing routines should take
# precautions to avoid overflow (e.g. by using the Gnu MP library,
# or similar).
#
def sdnv_decode(s, slen=0):
n = long(0)
for i in range(0, len(s)):
v = ord(s[i])
n = n<<7
n = n + (v & 0x7F)
if v>>7 == 0:
slen = i+1
break
elif i == len(s)-1 or (slen != 0 and i > slen):
n = -1 # reached end of input without seeing end of SDNV
return (n, slen)
# sdnv_encode() returns the SDNV-encoded string that represents n.
# An empty string is returned if n is not a non-negative integer
def sdnv_encode(n):
r = ""
# validate input
if n >= 0 and (type(n) in [type(int(1)), type(long(1))]):
flag = 0
done = False
while not done:
# encode lowest 7 bits from n
newbits = n & 0x7F
n = n>>7
r = chr(newbits + flag) + r
if flag == 0:
flag = 0x80
if n == 0:
done = True
Eddy Expires February 19, 2010 [Page 19]
Internet-Draft Using SDNVs August 2009
return r
# test cases from LTP and BP internet-drafts, only print failures
def sdnv_test():
tests = [(0xABC, chr(0x95) + chr(0x3C)),
(0x1234, chr(0xA4) + chr (0x34)),
(0x4234, chr(0x81) + chr(0x84) + chr(0x34)),
(0x7F, chr(0x7F))]
for tp in tests:
# test encoding function
if sdnv_encode(tp[0]) != tp[1]:
print "sdnv_encode fails on input %s" % hex(tp[0])
# test decoding function
if sdnv_decode(tp[1])[0] != tp[0]:
print "sdnv_decode fails on input %s, giving %s" % \
(hex(tp[0]), sdnv_decode(tp[1]))
Eddy Expires February 19, 2010 [Page 20]
Internet-Draft Using SDNVs August 2009
Author's Address
Wesley M. Eddy
Verizon Federal Network Systems
NASA Glenn Research Center
21000 Brookpark Rd
Cleveland, OH 44135
Phone: 216-433-6682
Email: weddy@grc.nasa.gov
Eddy Expires February 19, 2010 [Page 21]
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