One document matched: draft-baset-sipping-p2pcommon-00.txt
SIPPING WG S. Baset
Internet-Draft H. Schulzrinne
Expires: April 19, 2007 Columbia University
E. Shim
Panasonic
October 16, 2006
A Protocol for Implementing Various DHT Algorithms
draft-baset-sipping-p2pcommon-00
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Copyright (C) The Internet Society (2006).
Abstract
This document defines DHT-independent and DHT-dependent features of
DHT algorithms and presents a comparison of Chord, Pastry and
Kademlia. It then describes key DHT operations and their information
requirements.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. Description of DHT Specific Metrics . . . . . . . . . . . . . 5
3.1. Distance Function . . . . . . . . . . . . . . . . . . . . 5
3.2. Routing Table Rigidity . . . . . . . . . . . . . . . . . . 5
3.3. Learning from Lookup Queries . . . . . . . . . . . . . . . 6
3.4. Sequential vs. Parallel Lookups . . . . . . . . . . . . . 6
3.5. Iterative vs. Recursive Lookups . . . . . . . . . . . . . 7
4. Chord, Pastry and Kademlia . . . . . . . . . . . . . . . . . . 8
4.1. Chord . . . . . . . . . . . . . . . . . . . . . . . . . . 8
4.2. Pastry . . . . . . . . . . . . . . . . . . . . . . . . . . 9
4.3. Kademlia . . . . . . . . . . . . . . . . . . . . . . . . . 10
5. DHT Commonalities . . . . . . . . . . . . . . . . . . . . . . 12
6. DHT Protocol Operations and their Semantics . . . . . . . . . 13
6.1. Related Work . . . . . . . . . . . . . . . . . . . . . . . 13
6.2. Join . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
6.3. Leave . . . . . . . . . . . . . . . . . . . . . . . . . . 14
6.4. Insert (put) . . . . . . . . . . . . . . . . . . . . . . . 15
6.5. Lookup (get) . . . . . . . . . . . . . . . . . . . . . . . 15
6.6. Remove . . . . . . . . . . . . . . . . . . . . . . . . . . 16
6.7. Keep-alive . . . . . . . . . . . . . . . . . . . . . . . . 16
6.8. Replicate . . . . . . . . . . . . . . . . . . . . . . . . 16
7. Security Considerations . . . . . . . . . . . . . . . . . . . 18
8. References . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 20
Intellectual Property and Copyright Statements . . . . . . . . . . 21
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1. Introduction
Over the last few years a number of distributed hash table (DHT)
algorithms [7][8][9][10] have been proposed. These DHTs are based on
the idea of consistent hashing [10] and they share a fundamental
principle: route a message to a node responsible for an identifier
(key) in O(log_{b}N) steps using a certain routing metric where N is
the number of nodes in the system and b is the base of the logarithm
with values 2, 4, 16 and so on. Identifiers are logically considered
to be arranged in a circle in Chord [7], Kademlia [9] and Pastry [10]
and a routing metric may determine if the message can traverse only
in one direction ([anti-]clockwise) or both directions on the
identifier circle. However, independent of the routing metric and
despite the fact that the author of these DHT algorithms have given
different names to the routing messages and tables, the basic routing
concept of O(log_{2}N) operations is the same across DHTs.
In this paper, we want to understand if it is possible to exploit the
commonalities in the DHT algorithms such as Chord [7], Pastry [9],
and Kademlia [10] to define a protocol by which any of these
algorithms can be implemented. We have chosen Chord, Pastry and
Kademlia because either they are being actively researched (Chord and
Pastry) or they have been used in a well-deployed application
(Kademlia in eDonkey [15]). We envision that the protocol should not
contain any algorithm-specific details and possibly have an extension
mechanism to incorporate an algorithm-specific feature. The goal is
to minimize the possibility of extensions that may unnecessarily
complicate the protocol.
We first define the terminology used in our comparison of DHTs and
then give a brief description of Chord, Pastry and Kademlia. The
authors of these algorithms have proposed a number of heuristics to
improve the lookup speed and performance such as proximity neighbor
selection (PNS) which should not be considered part of the core
algorithm. We carefully separate DHT-independent heuristics from
DHT-specific details and try to expose the commonality in these
algorithms. Using this commonality, we then define algorithm-
independent functions such as join, leave, keep-alive, insert and
lookup and discuss protocol semantics and information requirements
for these functions.
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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 RFC 2119 [1].
Some of the terminology has been borrowed from the P2P terminology
draft [16].
P2PSIP Overlay Peer (or Peer). As defined by Willis et al. [16], a
P2PSIP peer is a node participating in a P2PSIP overlay that provides
storage and routing services to other nodes in P2P overlay and is
capable of performing several different operations such as joining
and leaving the overlay and routing requests within the overlay. We
use the term node and peer interchangeably.
P2PSIP Client (or Client). As defined by Willis et al. [16], a
P2PSIP client is a node participating in a P2PSIP overlay that
provides neither routing nor route storage and retrieval functions to
that P2PSIP Overlay.
P2PSIP Peer-ID (or Peer Key). As defined by Willis et al. [16], a
Peer-ID is a information that uniquely identifies a peer within a
given P2PSIP overlay. In the DHT approach, this is a numeric value
in the hash space. We use the term identifier and key
interchangeably.
Routing table. A routing table is used by a node to map a key to a
peer responsible for it. It contains a list of overlay peer keys and
their IP addresses stored against identifiers that are exponentially
away from the peer key. Simplistically, a routing table contains
logN number of entries where N is the number of nodes in the system.
Routing table row. A row in a routing table stores the peer-ID and
IP address of peer(s) against a routing table key. The routing table
key is computed from the peer key according to a particular routing
metric e.g., a Chord peer computes its ith routing table key by
performing the following modulo arithmetic:
(PeerKey + 2^{i-1}) mod 2^{M}
where M is the key length and i is between 1 and M. A peer can only
store in its ith row a reference to a peer whose key lies between (i)
and (i+1) rows of the routing table.
Routing table row interval or range. The interval for row 'i' is
defined as the keys that lie between (i) and (i+1) rows according to
a particular routing metric.
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3. Description of DHT Specific Metrics
Below, we give an explanation of metrics which we believe are
significant in our comparison of DHTs.
3.1. Distance Function
Any peer which receives a query for a key k must forward it to a peer
whose key is `closer' to k than its own key. This rule guarantees
that the query eventually arrives at the peer responsible for the
key. The closeness does not represent the way a routing table is
filled but rather how a node in the routing table is selected to
route the query towards its destination. Closeness is defined as
follows in Chord, Pastry and Kademlia [12] :
Chord. Numeric difference between two keys. Specifically: (b - a)
mod 2 ^M. where M is the length of the key produced by a hash
function.
Pastry. Inverse of the number of common prefix-bits between two
keys.
Kademlia. Bit-wise exclusive-or (XOR) of the two keys.
Specifically: a XOR b
Pastry uses numerical difference when prefix-matching does not match
any additional bits and the peers which are closer by prefix-matching
metric may not be closer by the numerical difference metric.
3.2. Routing Table Rigidity
There are two ways in which a peer can select a node to fill its ith
routing table row. It can be a node whose peer-ID either immediately
succeeds or precedes the routing table row interval or it can be any
node whose ID lies within the interval. For its ith row, Chord
selects a node with an ID which immediately succeeds the interval
while Pastry and Kademlia pickup any node with an ID that lies within
the interval. The effect of this is that Pastry and Kademlia have
more flexibility in selecting peers for their routing table while
Chord has a rather strict criteria. It is possible to loosen the
selection criteria in Chord by selecting any node in the interval
without violating the log_{2}N bound.
Moreover, in Chord, a lookup query will never overshoot the key i.e.,
it will never be sent to a node whose ID is greater than the key
being queried. Since Pastry and Kademlia can pickup any node in the
interval, a lookup query can possibly overshoot the key. Figure 1
shows how a peer having the same key selects routing table entries in
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Chord, Kademlia and Pastry.
Please see pdf version of this file for Figure 1.
3.3. Learning from Lookup Queries
The mechanism for selecting a node for a routing table row directly
impacts whether a peer can update its routing table from a lookup
query it receives. If, for its ith routing table row, a peer always
selects a node with an ID that immediately precedes or succeeds the
interval, then the number of such peers is only one. However,
choosing any peer whose ID lies within the interval provides more
flexibility as the number of candidate nodes increases from one to
the number of peers in the interval. A node which intends to update
its routing table from the lookup queries it receives has a better
chance of doing so.
3.4. Sequential vs. Parallel Lookups
If a querying node's routing table row contains references to two or
more DHT nodes, then it may send a lookup query to both of them. The
reason any node will send parallel lookup queries is because the
routing table peers may not have been refreshed for sometime and thus
may not be online. If all nodes in a DHT frequently refresh their
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routing table, then there may not be a need to send parallel queries
even in a reasonably high churn environment. Clearly, there is a
tradeoff between sending keep-alives to routing table peers, and
sending parallel lookup queries.
3.5. Iterative vs. Recursive Lookups
In an iterative lookup, the querying peer sends a query to a node in
its routing table which replies with the IP address of the next hop
if it is not responsible for the key. The querying peer then sends
the query to this hop. In a recursive lookup, the querying peer
sends a query to a node in its routing table which after receiving
the lookup query applies the appropriate DHT metric and forwards it
to a peer without replying to the querying peer. This process
repeats till the key is found or the query cannot be forwarded which
implies that the key does not exist. Rhea [13] explains the
differences between iterative vs recursive lookups. The recursive
lookup can possibly cause a mis-configured or misbehaving node to
start a flood of queries in a DHT. On the other hand, recursive
lookup provides lower latencies than iterative lookup.
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4. Chord, Pastry and Kademlia
In this section, we try to expose commonalities in Chord, Pastry and
Kademlia. These algorithms are based on the idea of consistent
hashing [11] i.e., keys are mapped onto nodes by a hash function that
can be resolved by any node in the system via queries to other nodes
and the arrival or departure of a node does not require all keys to
be rehashed. We start by comparing DHT-independent details of these
algorithms as defined by their authors in Table 1 and then algorithm
specific details in Table 2 and then give a brief description of
Chord, Pastry and Kademlia.
Key Recursive/ Sequential/ Routing Neighbor
length Iterative Parallel table nodes
name
---------------------------------------------------------------
Chord 160 Both Sequential Finger Successor
table list
Pastry 128 Recursive Sequential Routing Leaf-set
table
Kademlia 160 Iterative Parallel Routing None
table
Table 1. Paper specific details of Chord, Pastry and Kademlia.
Routing Routing Symmetric Learning Overshooting
data table row
structure selection
---------------------------------------------------------------------
Chord Skip-list Immediately No No No
succeed the
interval
Pastry Tree-like Any node in Yes Yes Yes
the interval
Kademlia Tree-like Any node in Yes Yes Maybe
the interval
Table 2. Algorithm specific details of Chord, Pastry and Kademlia.
4.1. Chord
The identifiers or keys in Chord can be logically considered to be
arranged on a circle. Each node in Chord maintains two data
structures, a 'successor list' which is the list of peers immediately
succeeding the node key and a 'finger table'. A finger table is a
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routing table which contains the IP address of peers halfway around
the ID space from the node, a quarter-of-the-way, an eighth-of-the-
way and so forth in a data structure that resembles a skiplist [6].
A node forwards a query for a key k to a node in its finger (routing)
table with the highest ID not exceeding k. The skiplist structure
ensures that a key can be found in O(log_{2}N) steps where N is the
number of nodes in the system.
To join a Chord ring, a node contacts any peer in the Chord network
and requests it to lookup its ID. It then inserts itself at the
appropriate position in the Chord network. The predecessors of the
newly joined node must update their successor lists. The newly
joined node should also update its finger table. Successor list is
the only requirement for correctness while finger table is used to
speedup the lookups.
To guard against node failures, Chord sends keep-alives to its
successors and finger table entries and continuously repairs them.
The routing table size is log_{2}N.
Chord suggests two ways for key/data replication. In the first
method, an application replicates data by storing it under two
different Chord keys derived from the data's key. Alternatively, a
Chord node can replicate key/value pair on each of its r successors.
4.2. Pastry
Like Chord, the identifiers or keys in Pastry can be logically
considered to be arranged on a circle; however, the routing is done
in a tree-based (prefix-matching) fashion. Each node in Pastry
contains two data structures, a 'leaf-set' and a 'routing table'.
The leaf-set L contains |L|/2 closest nodes with numerically smaller
identifiers than the node n and |L|/2 closest nodes with numerically
larger identifiers than n and is conceptually similar to Chord
successor list [12]. The routing table contains the IP address of
nodes with no prefix match, b bits prefix match, 2b prefix match and
so on where b is typically 2, 4, 6, 8 etc. The maximum size of
routing table is log_{2^b}N x 2^b. At each step, a node n tries to
route the message to a node that has a longest sharing prefix than
the node n with the sought key. If there is no such node, the node n
routes the message to a node whose shared prefix is at least as long
as n and whose ID is numerically closer to the key. The expected
number of hops is at most log_{2^b}N.
To join the Pastry network, a node contacts any node in the Pastry
network and builds routing tables and leaf sets by obtaining
information from the nodes along the path from bootstrapping node and
the node closest in ID space to itself. When a node gracefully
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leaves the network, the leaf-sets of its neighbors are immediately
updated. The routing table information is corrected only on demand.
The routing table of a Pastry node is initialized such that each
entry i with a common prefix p_{i} is closer to the node (in the
network sense) among all other live nodes having a prefix p_{i}.
This technique is commonly known as proximity neighbor selection
(PNS). Pastry performs recursive lookups. However, PNS and
recursive lookups are orthogonal to the Pastry operation.
Pastry replicates data by storing the key/value pair on k nodes with
the numerically closest nodeIds to a key [9]. This method is
conceptually similar to Chord's replication of key/value pairs on its
successor list.
4.3. Kademlia
Like Chord and Pastry, the identifiers in Kademlia can be logically
thought of being arranged on a circle; however the routing is done in
a tree-based (prefix-matching) fashion. Each node in Kademlia
contains a \emph{routing table}. Kademlia contains only one data
structure i.e. the routing table. Unlike Chord and Pastry, there are
no successor lists or leaf sets. Rather, the first entry in the
routing table serves as the immediate neighbor.
Kademlia uses XOR metric to compute the distance between two
identifiers. i.e. d(x,y)=x XOR y. XOR metric is non-Euclidean and it
offers the triangle property: d(x,y)+d(y,z) >= d(x,z). Essentially,
XOR metric is a prefix matching algorithm which tries to route a
message to a node with the longest matching prefix and the smallest
XOR value for non-prefix bits.
Kademlia maintains up to k entries for a routing table row and allows
parallel lookups to all nodes in a row. However, this is not really
a Kademlia specific feature and other DHT algorithms can implement it
by maintaining multiple entries for the same routing table row. The
latest incarnation of Chord contains more than one finger entry.
The routing table size is log_{2}N. The lookup speed can be increased
by considering IDs b bits at a time instead of one bit at a time
which implies increasing the routing table size. By increasing the
routing table size to 2^b x log_{2^b}N x k entries, the number of
lookup hops can be reduced to log_{2^b}N.
Kademlia replicates data by finding k closest nodes to a key and
storing the key/value pair on them. The Kademlia paper suggests a
value of 20 for k.
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Keep-alive Lookup Store Join Updating Updating
routing neighbor
table nodes
---------------------------------------------------------------------
Chord fix_ find_ N/A join() fix_ stab()
fingers() successor() fingers()
Pastry N/A route(msg, N/A Side On demand N/A
,key) effect
of
lookups
Kademlia PING FIND_NODE, STORE N/A N/A N/A
FIND_VALUE,
lookup
Table 3. DHT specific RPC's
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5. DHT Commonalities
Table 1 and table 2 list the DHT-independent and DHT-specific aspects
of Chord, Pastry and Kademlia. From the above discussion, we can
think of following commonalities between Chord, Pastry and Kademlia.
The time to detect whether a routing entry node has failed is
independent of the DHT algorithm being used.
The flexibility in selecting a node for a routing table row impacts
whether a routing table may be updated with information from passing
lookup queries.
Lookup can be performed either iteratively or recursively. Lookup
messages can be forwarded either sequentially or parallel.
It is possible to define replication strategies independent of the
underling DHT algorithms.
The choice of hash function and the length of the key are independent
of the routing algorithm.
Each peer has knowledge about some neighbor nodes.
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6. DHT Protocol Operations and their Semantics
In this section, we define and describe DHT operations and
information requirements for each operation. But first, we give a
brief description of related work.
6.1. Related Work
Dabek et al. [14] defined a key based API (KBR) which can be used to
implement a DHT-level API. They define a RPC void route(key->K,
msg->M, nodehandle->hint) which forwards a message, M, towards the
root of the key K. The optional hint specifies a node that should be
used as a first hop in routing the message. The put() and get() DHT
operations may be implemented as follows:
route(key,[PUT,value,S],NULL). The 'put' operation routes a PUT
message containing 'value' and the local node's handle, S, to the
root of the key.
route(key,[GET,S],NULL). The 'get' operation routes a 'GET' message
to the root of the key which returns the value and its own handle in
a single hop using 'route(NULL,[value,R],S).
To replicate a newly received key (k) r times, the peer issues a
local RPC replicaSet(S,r) and sends a copy of the key to each
returned node. The operation implicitly makes the root of the key
and not the publisher responsible for replication.
Singh et al. [17] defined a XML-RPC based API for DHTs. Their
approach is based on OpenDHT [5] and they define a data interface
with and without authentication, which allows inserting, retrieving
and removing data on a DHT (put, get), and a service interface, which
allows a node to join a DHT for a service and another node to lookup
for a service node (join, lookup, leave).
We define six DHT operations (API) namely join, leave, insert (put),
lookup (get), remove, keep-alive and replicate which a node (peer)
participating in a DHT may initiate. A node (client) which does not
participate in a DHT network requests a peer in the DHT network to
perform these operations on its behalf and thus client-to-peer API is
independent of the DHT algorithm being used. The peer-to-peer API
can also be independent of the DHT algorithm being used because
determination of the next hop is done locally by a peer after
applying a particular routing metric.
6.2. Join
A node initiates a join operation to a peer already in the DHT to
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insert itself in the DHT network. The mechanism to discover a peer
already in the DHT is independent of any particular DHT being used.
The joining node and its neighbors must update their neighbors
accordingly.
A joining node may want to build its routing table by getting a full
or partial copy of its neighbors or any appropriate node's routing
table. It will also need to obtain key/value pairs it will be
responsible for.
A join operation initiated by a P2PSIP client does not change the
geometry of the DHT network. The operation is conceptually similar
to insert(put).
Following is the list of information that will be exchanged between
the newly joining node and existing peers.
[s] An overlay ID.
[s] Peer-ID of the joining node.
[s] Contact information or IP address of the joining node.
[s] Indication whether this peer should be inserted in the p2p
network thereby changing the geometry or merely stored on an
existing peer. This field accommodates overlay peers and clients
as defined in [16].
[r] Full or partial routing table of an existing node(s).
[r] List of immediate neighbors.
where [s] is the information sent by the querying peer, [r] is the
information received by a peer and [a] is the information appended by
a peer to a request before forwarding it to the next hop.
6.3. Leave
A node initiates a leave operation to gracefully inform its neighbors
about its departure. The neighbors must update their neighbor
pointers and take over the keys the leaving node is responsible for.
[s] The departing node's key.
[s] List of key/value pairs to be transferred.
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6.4. Insert (put)
A node (overlay client or peer) initiates an insert operation to a
peer already in the DHT to insert a key/value pair. The insertion
involves locating the node responsible for key using the lookup
operation and then inserting either a reference to the key/value pair
publisher or the key/value pair itself. The insert operation is
different from the join operation in the sense that it does not
change the DHT geometry. The insert operation can also be used to
update the value for an already inserted key.
[s] Key for the object(value) to be inserted.
[s] Value. A sender may not send the value along with key. It
may only send the value only after the peer responsible for the
key has been discovered.
[s] Publisher of the key. Multiple publishers can publish data
under the same key and a node storing a key/value pair uses this
field to differentiate among the publishers.
[s] Key/value lifetime. The time until an online peer must keep
the key/value pair. The publisher of the key/value pair must
refresh it before the expiration of this time.
[s] A flag indicating whether the lookup should be performed
recursively or iteratively.
6.5. Lookup (get)
A node initiates a lookup operation to retrieve a key/value pair from
the DHT network. It locally applies DHT routing metric (Chord,
Pastry or Kademlia) on its routing table to determine the peer to
which it should route the message. The peer responsible for the key/
value pair (root of the key) sends it directly back to the querying
node. The value can be an IP address, a file or a complex record.
The lookup message can be routed in a sequential or parallel way.
The lookup message can also be routed iteratively or recursively. A
node routing a recursive query may add its own key and IP address
information in the lookup message before forwarding it to the next
hop.
Following is the list of information exchanged between the querier,
forwarding peers and the peer holding the key/value pair.
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[s] Key to lookup
[s] A flag indicating whether the lookup should be performed
recursively or iteratively.
[s] Publisher of the key. A non-empty value means that a node is
interested in the value inserted by a certain publisher.
[a] Forwarding peer's key and IP address. A node in the path of a
lookup query may add its own ID and IP address to the lookup query
before recursively forwarding it.
[r] Value of the key or an indication that key cannot be found.
6.6. Remove
Even though each stored key/value pair has an associated lifetime and
thus will expire unless refreshed by the publishing node in time,
sometimes the publishing node may want to remove the key/value pair
from the DHT before lifetime expiration. In this case, the
publishing node initiates the remove operation.
[s] Publishing node's key.
[s] Key for the key/value pair to be removed.
6.7. Keep-alive
A peer initiates a keep-alive operation to send keep-alive message to
its neighbors and routing table entries. The two immediate neighbors
do not need to send a periodic keep-alive message to each other. The
peers can use various heuristics for keep-alive timer such as
randomly sending a keep-alive within an interval.
If a neighbor fails, a peer has to immediately find a new neighbor to
ensure lookup correctness. If a routing entry fails, a node may
choose to repair it immediately or defer till a lookup request
arrives.
[s] Sending node's key.
[s] Keep-alive timer expiration.
6.8. Replicate
In order to ensure that a key is not lost when the node goes offline,
a node must replicate the keys it is responsible for. Heuristics
such as replicate to the next k nodes can be applied for this
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purpose.
A node may also need to replicate its keys when its neighbors are
updated.
[s] List of key/value pairs
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7. Security Considerations
TBD.
8. References
[1] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997.
[2] Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston, A.,
Petersen, J., Sparks, R., Handley, M., and E. Schooler, "SIP:
Session Initiation Protocol", RFC 3261, June 2002.
[3] Bryan, D. and C. Jennings, "A P2P Approach to SIP Registration
and Resource Location", draft-bryan-sipping-p2p-01 (work in
progress), July 2005.
[5] Rhea, S., Godfrey, B., Karp, B., Kubiatowicz, J., Ratnasamy,
S., Shenker, S., Stoica, I., and H. Yu, "OpenDHT: a public DHT
service and its uses", SIGCOMM '05: Proceedings of the 2005
conference on Applications, technologies, architectures, and
protocols for computer communications Philadelphia,
Pennsylvania, pp. 73-84, 2005.
[6] Pugh, W., "Skip Lists: A Probabilistic Alternative to Balanced
Trees", Workshop on Algorithms and Data Structures pp. 437-449,
1989.
[7] Stoica, I., Morris, R., Liben-Nowell, D., Karger, D., Kaashoek,
M., Dabek, F., and H. Balakrishnan, "Chord: A Scalable Peer-to-
peer Lookup Service for Internet Applications", IEEE/ACM
Transactions on Networking (To Appear).
[8] Ratmasamy, S., Francis, P., Handley, M., Karp, R., and S.
Shenker, "A Scalable Content-Addressable Network", Proc. ACM
SIGCOMM (San Diego, CA), pp. 161-172, August 2001.
[9] Rowstron, A. and P. Druschel, "Pastry: Scalable, distributed
object location and routing for large-scale peer-to-peer
systems", Proceedings of the 18th IFIP/ACM International
Conference on Distributed Systems Platforms (Middleware 2001),
March 2002.
[10] Maymounkov, P. and D. Mazieres, "Kademlia: A Peer-to-Peer
Information System Based on the XOR Metric", IPTPS'01: Revised
Papers from the First International Workshop on Peer-to-Peer
Systems London, UK: Springer-Verlag, pp. 53-65, March 2002.
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[11] Karger, D., Lehman, E., Leighton, T., Panigraphy, R., Levine,
M., and D. Lewin, "Consistent hashing and random trees:
distributed caching protocols for relieving hot spots on the
World Wide Web", STOC '97: Proceedings of the twenty-ninth
annual ACM symposium on Theory of computing , 1997.
[12] Balakrishnan, H., Kaashoek, F., Karger, D., Morris, R., and I.
Stoica, "Looking up data in P2P systems", Communications of the
ACM vol. 46, no. 2, pp. 43-48, 2003.
[13] Rhea, S., Geels, D., Roscoe, T., and J. Kubiatowicz, "Handling
Churn in a DHT", Proceedings of the 2004 USENIX Annual
Technical Conference (USENIX '04) Boston, Massachusetts,
June 2004.
[14] Dabek, F., Zhao, B., Druschel, P., Kubiatowicz, J., and I.
Stoica, "Towards a Common API for Structured Peer-to-Peer
Overlays", Proceedings of the 2nd International Workshop on
Peer-to-Peer Systems (IPTPS03) Berkeley, California,
February 2003.
[15] "eDonkey", <http://www.eDonkey.com>.
[16] Willis, D., Bryan, D., Matthews, P., and E. Shim, "Concepts and
Terminology for Peer-to-Peer SIP",
draft-willis-p2psip-concepts-02 (work in progress),
October 2006.
[17] Singh, K. and H. Schulzrinne, "Data format and interface to an
external peer-to-peer network for SIP location service",
draft-singh-p2p-sip-00 (work in progress), May 2006.
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Authors' Addresses
Salman A. Baset
Dept. of Computer Science
Columbia University
1214 Amsterdam Avenue
New York, NY 10027
USA
Email: salman@cs.columbia.edu
Henning Schulzrinne
Dept. of Computer Science
Columbia University
1214 Amsterdam Avenue
New York, NY 10027
USA
Email: hgs@cs.columbia.edu
Eunsoo Shim
Panasonic Princeton Laboratory
Two Research Way, 3rd Floor
Princeton, NJ 08540
USA
Email: eunsoo@research.panasonic.com
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