Internet DRAFT - draft-jennings-vipr-overview
draft-jennings-vipr-overview
VIPR WG M. Barnes, Ed.
Internet-Draft Polycom
Intended status: Informational C. Jennings
Expires: June 12, 2014 Cisco
J. Rosenberg
jdrosen.net
M. Petit-Huguenin
Unaffiliated
December 09, 2013
Verification Involving PSTN Reachability: Requirements and Architecture
Overview
draft-jennings-vipr-overview-06
Abstract
The Session Initiation Protocol (SIP) has seen widespread deployment
within individual domains, typically supporting voice and video
communications. Though it was designed from the outset to support
inter-domain federation over the public Internet, such federation has
not materialized. The primary reasons for this are the complexities
of inter-domain phone number routing and concerns over security.
This document reviews this problem space, outlines requirements, and
then describes a model and technique for inter-domain federation with
SIP involving the Public Switched Telephone Network (PSTN), called
Verification Involving PSTN Reachability (VIPR). VIPR addresses the
problems that have prevented inter-domain federation over the
Internet. It provides fully distributed inter-domain routing for
phone numbers, authorized mappings from phone numbers to domains, a
new technique for automated SIP anti-spam, and privacy of number
ownership, all while preserving the trapezoidal model of SIP.
Status of This Memo
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This Internet-Draft will expire on June 12, 2014.
Copyright Notice
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Conventions and Terminology . . . . . . . . . . . . . . . . . 4
3. Problem Statement . . . . . . . . . . . . . . . . . . . . . . 4
3.1. The Phone Number Routing Problem . . . . . . . . . . . . 4
3.2. The Open Pinhole Problem . . . . . . . . . . . . . . . . 6
3.3. Quality of Service Problem . . . . . . . . . . . . . . . 6
3.4. Troubleshooting Problem . . . . . . . . . . . . . . . . . 7
4. Summary of Existing Solutions . . . . . . . . . . . . . . . . 7
4.1. Domain Routing . . . . . . . . . . . . . . . . . . . . . 7
4.2. Public ENUM . . . . . . . . . . . . . . . . . . . . . . . 8
4.3. Private Federations . . . . . . . . . . . . . . . . . . . 8
5. Key Requirements . . . . . . . . . . . . . . . . . . . . . . 9
6. Executive Overview . . . . . . . . . . . . . . . . . . . . . 10
6.1. Key Properties . . . . . . . . . . . . . . . . . . . . . 10
6.2. Challenging Past Assumptions . . . . . . . . . . . . . . 12
6.3. Technical Overview . . . . . . . . . . . . . . . . . . . 13
6.3.1. Storage of Phone Numbers . . . . . . . . . . . . . . 14
6.3.2. PSTN First Call . . . . . . . . . . . . . . . . . . . 15
6.3.3. Validation and Caching . . . . . . . . . . . . . . . 16
6.3.4. SIP Call . . . . . . . . . . . . . . . . . . . . . . 20
7. Security Considerations . . . . . . . . . . . . . . . . . . . 21
7.1. Attacks on the DHT . . . . . . . . . . . . . . . . . . . 21
7.2. Theft of Phone Numbers . . . . . . . . . . . . . . . . . 22
7.3. Spam . . . . . . . . . . . . . . . . . . . . . . . . . . 23
7.4. Eavesdropping . . . . . . . . . . . . . . . . . . . . . . 23
7.5. Privacy Leakage and Malicious Servers . . . . . . . . . . 23
8. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 25
9. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 25
10. References . . . . . . . . . . . . . . . . . . . . . . . . . 25
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10.1. Normative References . . . . . . . . . . . . . . . . . . 25
10.2. Informative References . . . . . . . . . . . . . . . . . 26
Appendix A. Changes since last version . . . . . . . . . . . . . 28
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 29
1. Introduction
The Session Initiation Protocol (SIP) was originally published as
[RFC2543] in May of 1999. This was followed by subsequent
publication of [RFC3261], which brought the protocol to sufficient
maturity to enable large scale market adoption.
SIP has achieved large scale market adoption with hundreds of
implementations, spanning consumer products, enterprise servers, and
large scale carrier equipment. It carries billions and billions of
minutes of calls, and has become the standard for interconnection
between products from different vendors. If one measures success in
deployment, then clearly SIP is a success.
SIP was designed from the ground up to enable communications between
users in different domains, all over the public Internet. The
intention was that real-time communications should be no different
than email or the web, with the same any-to-any connectivity that has
fueled the successes of those technologies. However, when SIP is
used between domains, it is typically through private federation
agreements. While such agreements are positive, they have typically
been limited to voice, which has limited the use of video and the
growth of advanced SIP features, thus preventing the innovation that
SIP was expected to drive. Thus, the any-to-any Internet federation
model envisioned by SIP has not materialized at scale.
This document introduces a technology, called Verification Involving
PSTN Reachability (VIPR), that breaks down the barriers that have
prevented inter-domain voice, video and other multimedia services.
By stepping back and changing some of the most fundamental
assumptions about federation, VIPR is able to address the key
problems preventing its deployment. VIPR focuses on incremental
deployability. At the same time, VIPR ensures that SIP's trapezoidal
model of direct federation between domains without any intermediate
processing beyond IP transport is realized. That model is required
in order to allow innovative new services to be deployed.
Despite the advantages of the VIPR system, its open, peer-to-peer
character makes it vulnerable to certain security and privacy
vulnerabilities (see especially Section 7.5). After consideration of
potential countermeasures, the VIPR working group elected not to
pursue VIPR for standardization. This document therefore describes
VIPR for informational purposes, as VIPR has seen some field
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deployment, and it is furthermore believed that the techniques
utilized by VIPR might be reused in new standard architectures in the
future.
2. Conventions and Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in
[RFC2119].
Call Agent: An entity in a SIP enabled domain that supports VIPR.
The Call Agent performs call processing on behalf of one or more
user agents represented by E.164 numbers within the domain.
Ticket: A shared secret that is generated after a PSTN call to
enable secure call setup on a subsequent inter-domain IP call
enabled by VIPR.
User Agent: As defined in [RFC3261], with the restriction that the
user agent must have an associated E.164 number.
3. Problem Statement
The first question that must be asked is this - why haven't we seen
widespread adoption of inter-domain SIP federation? The reason for
this is due to problems with the following - summarized in order of
importance/impact:
1. Phone number routing
2. Open pinhole
3. Quality of service
4. Troubleshooting
The first two are the most significant.
3.1. The Phone Number Routing Problem
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Inter-domain federation requires that the sending domain determine
the address of the receiving domain, in the form of a DNS name
(example.com) or one or more IP addresses that can be used to reach
the domain. In email and in the web, this is easy. The identifiers
used by those services - the email address and web URL respectively -
embed the address of the receiving domain. A simple DNS lookup is
all that is required to route the connection. SIP was designed to
use the same email-style identifiers.
However, most SIP deployments utilize phone numbers in the form of
E.164 numbers [E.164], and not email-style SIP URIs. This is due to
the huge installed base of users that continue to exist solely on the
PSTN. In order to be reached by users on the PSTN, and in order to
reach them, users in SIP deployments need to be assigned a PSTN phone
number. Users in SIP deployments need to place that phone number on
business cards, use it in their email signatures, and in general,
give it out to their friends and colleagues, in order to be reached.
While those users could additionally have an email style SIP URI, the
phone number serves as a single, global identifier that works for
receiving calls from users on the PSTN as well as users within the
same SIP domain.
There are several reasons why two identifiers are used when one will
suffice. The universality of PSTN phone numbers is the reason why
most SIP deployments continue to use them - often exclusively.
Another reason is that many SIP deployments utilize hardphones or
telephony adaptors, and the user interfaces on these devices -
patterned after existing phones - only allow phone number based
dialing. Consequently, these users are only allocated PSTN phone
numbers, and not email-style SIP URI.
Finally, a large number of SIP deployments are in domains where the
endpoints are not IP. Rather, they are circuit based devices,
connected to a SIP network through a gateway. SIP is used within the
core of the network, providing lower cost transit, or providing add-
on services. Clearly, in these deployments, only phone numbers are
used.
Consequently, to make inter-domain federation incrementally
deployable and widely applicable, it needs to work with PSTN phone
numbers rather than email-style SIP URIs. Telephone numbers, unlike
email addresses, do not provide any indication of the address of the
domain which "owns" the phone number. Indeed, the notion of phone
number ownership is somewhat cloudy. Phone numbers can be ported
between carriers. They can be assigned to a user or enterprise, and
then later re-assigned to someone else. Phone numbers are granted to
users and enterprises through a complex delegation process involving
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the ITU, governments, and telecommunications carriers, often
involving local regulations that vary from country to country.
Therefore, in order to deploy inter-domain federation, domains are
required to utilize some kind of mechanism to map phone numbers to
the address of the domain to which calls should be routed. Though
several techniques have been developed to address this issue, none
have achieved large-scale Internet deployments.
3.2. The Open Pinhole Problem
The inter-domain federation mechanism built into SIP borrows heavily
from email. Each domain runs a SIP server on an open port. When one
domain wishes to contact another, it looks up the domain name in the
DNS, and connects to that server on the open port. Here, "open"
means that the server is reachable from anywhere on the public
Internet, and is not blocked by firewalls.
This simple design worked well in the early days of email. However,
the email system has now become plagued with spam. This has resulted
in administrators spending a significant amount of time maintaining
spam filters. This does not always benefit the end users as in some
cases valid emails are dropped without the user being notified.
Thus, administrators of SIP domains are rightfully concerned that if
they make a SIP server available for anyone on the Internet to
contact, it will open the floodgates for SIP spam, which is far more
disruptive than email-based spam [RFC5039]. Administrators are also
concerned that an open server will create a back-door for denial-of-
service and other attacks that can potentially disrupt their voice
and video services. Administrators are often not willing to take
that risk since voice deployments demand higher uptimes and better
levels of reliability than email, especially for enterprises.
Fears around spam and denial-of-service attacks, when put together,
form the "open pinhole problem" - that domains are not willing to
enable SIP on an open port facing the Internet.
To fix this, a new model for federation is needed - a model where
these problems are addressed as part of the fundamental design rather
than after the functionality has been deployed.
3.3. Quality of Service Problem
The Internet does not provide any Quality of Service (QoS)
guarantees. All traffic is best effort. This is not an issue for
data transaction services, like web and email. It is, however, a
concern when using real-time services, such as voice and video.
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That said, there are a large number of existing SIP deployments that
run over the Internet. Though the lack of QoS is a concern, it has
not proven a barrier to deployment. It is believed that if if the
more fundamental issues - the phone number routing and open pinhole
problems - can be addressed, the QoS problem will be a non-issue. As
such, QoS is not discussed further in this or other VIPR
specifications.
3.4. Troubleshooting Problem
The final problem that is prohibing large scale inter-domain
federation is troubleshooting. When connecting calls between
domains, problems can occur. Calls can be blocked. Calls can be
misdelivered. Features sometimes don't work. There can be one-way
media or no media at all. The video may not start. Call quality can
be poor.
These problems are common in SIP deployments, and they are tough to
troubleshoot even within a single administrative domain. When real-
time services extend inter-domain, the problem becomes worse.
Fortunately, some work has been completed to improve the ability for
network administrators to diagnose SIP problems. A Common log format
[RFC6873] has been developed. Other work underway, such as
consistent session IDs [I-D.ietf-insipid-session-id-reqts] and
[I-D.jones-insipid-session-id] can help troubleshoot interdomain
calls.
In addition to the above, any new technology that facilitates inter-
domain federation needs to have troubleshooting built-in, so that it
is not a barrier to deployment. Further consideration of necessary
built-in techniques for troubleshooting is required for successful
deployment of VIPR.
4. Summary of Existing Solutions
Given the value of inter-domain SIP federation, there are existing
deployed solutions summarized below. However, each solution approach
has fundamental limitations that have inhibited widespread
deployment.
4.1. Domain Routing
The first solution for SIP inter-domain federation is built into SIP
itself - domain routing. In this technique, users utilize email-
style SIP URIs as identifiers. By utilizing the DNS lookup mechanism
defined in [RFC3263], SIP enables calls to be routed between domains
in much the same way email is routed between domains.
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This technique works well in theory, but it has two limitations which
have limited its deployment:
1. The majority of SIP deployments utilize phone numbers, often
exclusively. In such a case, domain routing cannot be used.
2. Domain federation brings with it the possibility (and strong
likelihood) of the same levels of spam and DoS attacks that have
plagued the email system.
These issues have already been discussed in sections Section 3.1 and
Section 3.2 respectively.
4.2. Public ENUM
Public ENUM, defined in [RFC6116] addresses the phone number routing
problem by placing phone numbers into the public DNS. Clients can
then perform a simple DNS lookup on a phone number, and retrieve a
SIP URI which can be used to route to that phone number.
Unfortunately, public ENUM requires that the entries placed into the
DNS be populated following a chain of responsibility that mirrors the
ownership of the numbers themselves. This means that, in order for a
number to be placed into the DNS, authorization to do so must start
with the ITU, and from there, move to the country, telecom regulator,
and ultimately the end user. The number of layers of bureaucracy
required to accomplish this is non-trivial. In addition, the telecom
operators - that would be partly responsible for populating the
numbers into the DNS - have little incentive to do so. As a
consequence, public ENUM is largely empty, and is likely to remain so
for the foreseeable future.
Instead, ENUM has evolved into a technique for federation amongst
closed peering partners, called private ENUM or infrastructure ENUM
[RFC5067]. While there is value in this technology, it does not
enable the open federation that public ENUM was designed to solve.
4.3. Private Federations
Private federations are a cooperative formed amongst a small number
of participating domains. The cooperative agrees to use a common
technique for federation, and through it, is able to connect to each
other. There are many such federations in use today.
Some of these federations rely on a central database, typically run
by the federation provider, that can be queried by participating
domains. The database contains mappings from phone numbers to
domains, and is populated by each of the participating domains, often
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manually. Each domain implements an agreed-upon query interface that
can be used to access the database when a number is called.
Sometimes ENUM is used for this interface (called private ENUM),
other times, a SIP redirection is used. Some federations also
utilize private IP networks in order to address QoS problems.
Private federations work, but they have one major limitation: scale.
As the number of participating domains grows, several problems arise.
Firstly, the size of the databases become difficult to manage.
Secondly, the correctness of the database becomes an issue, since the
odds of misconfigured numbers (either intentionally or accidentally)
increases. As the membership grows further, the odds increase that
malicious domains will be let in, introducing a source of spam and
further problems. The owner of the federation can - and often does -
assume responsibility for this, and can attempt to identify and shut
down misbehaving participants. Indeed, as the size of the
federations grow, the owner of the federation needs to spend
increasing levels of capital on maintaining it. This often results
in the owners charging for membership, which can be a barrier to
entry.
5. Key Requirements
From the discussion on the problems of inter-domain federation and
the solutions that have been attempted so far, several key
requirements emerge:
REQ-1: The solution must allow for federation between any number of
domains.
REQ-2: The solution must enable users in one domain to identify
users in another domain through the use of their existing E.164
based phone numbers.
REQ-3: The solution must work with deployments that utilize any kind
of endpoint, including non-IP phones connected through gateways,
IP softphones and hardphones.
REQ-4: The solution must not require any change in user behavior.
The devices and techniques that users have been using previously
to make inter-domain calls must continue to work, but now result
in inter-domain calls using IP.
REQ-5: The solution must work worldwide, for any domain anywhere.
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REQ-6: The solution must not require any new services from any kind
of centralized provider. A domain should be able to deploy
equipment and connect to the federation without any interaction
with or authorization from a centralized provider.
REQ-7: The solution must not require any prior arrangement between
domains in order to facilitate federation between those domains.
Federation must occur opportunistically - connections established
when they can be.
REQ-8: The solution must work for domains of any size - starting
with a single phone up to the largest telecom operator with tens
of millions of numbers.
REQ-9: The solution must have built-in mechanisms for preventing
spam and DoS attacks. These mechanisms must be fully automated.
REQ-10: The solution must not require any processing whatsoever by
SIP or RTP intermediaries. It must be possible for a direct SIP
connection to be established between participating domains.
REQ-11: The solution should adapt to VIPR call failures. The
solution should allow the user to make calls using the inter-
domain calling mechanism used prior to the initial VIPR-enabled
call.
6. Executive Overview
Verification Involving PSTN Reachability (VIPR) is aimed at solving
the problems that have prevented large-scale Internet-based SIP
federation of voice and video. VIPR solves these problems by
creating a hybrid of three technologies - the PSTN itself, a Peer to
Peer (P2P) network, and SIP. By using these three technologies
together, VIPR enables an incrementally deployable solution to
federation.
6.1. Key Properties
VIPR has several important properties that enable it to solve the
federation problem:
Works With Numbers: VIPR enables federation for existing PSTN phone
numbers. It does not require users or administrators to know or
configure email-style identifiers. It does not require the
allocation of new numbers. It does not require a change in user
behaviors.
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Works with Existing Endpoints: VIPR does not require any changes to
endpoints. Consequently, it works with existing SIP endpoints and
with non-IP endpoints connected through gateways.
Verified Mappings: VIPR ensures that phone calls cannot be misrouted
or numbers stolen. The biggest issue in mapping from a phone
number to a domain or IP address, is determining whether the
mapping is correct - i.e., does the domain really own the given
phone number? While solutions like ENUM have solved this problem
by relying on centralized delegations of authorization, VIPR
provides a secure mapping in a fully distributed way.
Worldwide: VIPR works worldwide. Any domain that is connected to
both the PSTN and the Internet can participate. Since VIPR does
not depend on availability of any regional services beyond IP and
PSTN access - both of which are already available globally - VIPR
itself is globally available.
Scalibility: VIPR is scaleable. Any number of domains can
participate.
Self-Scale: VIPR self-scales. This means that the amount of
computation, memory, and bandwidth that a domain must deploy
scales in direct proportion to the size of their own user base.
Self-Learning: VIPR is completely automated. A domain does not
require configuration of any information about another domain. It
does not require provisioning of IP addresses, domain names,
certificates, phone number prefixes or routing rules.
Automated Anti-Spam VIPR has a built-in mechanism for preventing SIP
spam, which is specific to SIP. It is fundamentally different
from existing SIP anti-spam techniques which borrow from email
[RFC5039]. This new technique is fully automated, and requires no
configuration by administrators and no participation from end
users.
Feature Velocity: VIPR enables direct SIP connections between two
domains seeking to federate. There are no SIP intermediaries of
any sort between the two. This means that domains have no
dependencies on intermediaries for deployment of new features.
Secure: Security is a fundamental part of VIPR and cannot be
disabled.
Reliable: VIPR is reliable. Through its hybridization of the PSTN
and the Internet, it ensures that calls always go through, even in
cases of network failure or limited IP connectivity.
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In order to achieve a solution with these properties, past
assumptions about how federations should work must be challenged.
6.2. Challenging Past Assumptions
Two unstated assumptions of SIP federation are challenged by VIPR.
The first assumption that federation solutions have made is this:
The purpose of SIP federation is to eliminate the PSTN, and
consequently, we cannot assume the PSTN itself as part of the
solution.
Though unstated, this assumption has clearly been part of the design
of existing solutions. SIP federation based on email-style URIs, as
defined in RFC 3261, doesn't utilize nor make mention of the PSTN.
Solutions like ENUM, or private registries, also do not utilize nor
make mention of the PSTN. However, such approaches ignore an
incremental solution - a solution which utilizes the PSTN itself to
solve the hard problems in SIP federation.
There are many advantages to leveraging the PSTN. It reaches
worldwide. It provides a global numbering translation service that
maps phone numbers to circuits. It is highly reliable, and provides
QoS. It has been built up over decades to achieve these goals.
Thus, building upon rather than replacing the PSTN, can provide the
necessary functionality once another assumption is challenged.
This second assumption is:
A federation solution must be the same as the final target
federation architecture, and not just a step towards it.
SIP's email-style federation was a pure 'target architecture'. ENUM
was the same - a worldwide global DNS database with everyone's phone
numbers providing open connectivity.
Historically, technologies are more successful when they are
incrementally deployable. As such, VIPR is very much focused on
incremental deployability. It discards the notion of perfect IP
federation for a solution that federates most, but not all calls, by
relying on the PSTN to fill in the gaps.
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6.3. Technical Overview
A high level view of the VIPR architecture with an example is shown
in Figure 1. The figure shows four different domains, example.com,
example.net, example.org and example.edu, federated using VIPR
technology. Each domain is connected to both the public Internet and
to the traditional PSTN. For simplicity, the connection for the call
agents in example.org and example.edu to the PSTN is not indicated in
the diagram as that interface is not relevant to the subsequent
examples.
+-------+ +-------+
| Call | | Call |
example.org | Agent | | Agent | example.edu
| | | |
+-------+ +-------+
\ /
\ /
\ /
\ /
|
//--------\\
|// \\|
| Internet |
+-------+ |\\ //| +-------+
| Call |------ \\ _______//------| Call |
//\\ | Agent | | Agent | //\\
\ / | | | | \ /
\/ ---| | +-----------+ | |---- \/
User | |======| |======| | User
Agent +-------+ | PSTN | +-------+ Agent
example.com | | example.net
+-----------+
Figure 1: High Level Architecture
For purposes of explanation, it is easiest to think of each domain as
having a single call agent which participates in the federation
solution. The functionality is decomposed into several sub-
components, and this is discussed in more detail below. The call
agent is connected to one or more user agents in the domain, and is
responsible for routing calls, handling features, and processing call
state. The call agent is stateful, and is aware of when calls start
and stop. Additional detail for the functional components of this
architecture are provided in [I-D.petithuguenin-vipr-framework].
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Assume that all four domains have a 'fresh' installation of VIPR, and
that domain example.net 'owns' +1 408 555 5xxx, a block of 1000
numbers allocated by its PSTN provider.
The VIPR mechanism can be broken into four basic steps: storage of
phone numbers, PSTN first call, validation and caching, and
subsequent SIP call(s).
6.3.1. Storage of Phone Numbers
The first step is that the call agents form a single, worldwide P2P
network, using a VIPR specific usage
[I-D.petithuguenin-vipr-reload-usage] of RELOAD
[I-D.ietf-p2psip-base] with a variant of the Chord algorithm. This
P2P network forms a distributed hash table (DHT) running amongst all
participating domains. A distributed hash table is like a simple
database, allowing storage of key-value pairs, and lookup of objects
by key. Unlike a normal hash table, which resides in the memory of a
single computer, a distributed hash table is spread across all of the
servers which make up the P2P network. In this case, it is spread
across all of the domains participating in the VIPR federation.
The problem solved by the variant of the Chord algorithm (and by
other DHT algorithms), is an answer to the following: given that the
desired operation is to read or write an object with key K, which
node in the DHT is the box that currently stores the object with that
key? The P2P SIP variant of the Chord algorithm provides an
algorithm which routes read and write operations through nodes in the
DHT until they eventually arrive at the right place. With Chord,
this will take no more than log2N hops, where N is the number of
nodes in the DHT. Consequently, for a DHT with 1024 nodes, 10 hops
are required in the worst case. For 2048, 11 hops. And so on. The
logarithmic factor allows DHTs to achieve efficient scale and to
provide a large amount of storage summed across all of the nodes that
make up the DHT.
This logarithmic hopping behavior also means that each node in the
DHT does not need to establish a TCP/TLS connection to every other
node. Rather, connections are established to a smaller subset - just
log(N) of the nodes.
In DHTs, each participating entity is identified by a Node-ID. The
Node-ID is a 128 bit number, assigned randomly to each entity. They
have no inherent semantic meaning; they are not like domain names or
IP addresses.
In the case of VIPR, each call agent is identified by one or more
Node-IDs. For purposes of discussion, consider the case where the
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call agent has just one Node-ID. Each participating domain,
including example.net in our example, uses the DHT to store a mapping
from each phone number that it owns, to the domain's Node-ID. In the
case of example.net, it would store 1000 entries into the DHT, each
one being a mapping from one of its phone numbers, to the domain's
Node-ID. Furthermore, when the mappings are stored, the mapping is
actually from the SHA-1 hash of the phone number, to the Node-ID of
the call agent which claims ownership of that number.
For example, if the Node-ID of the call agent in domain example.net
is 0x1234 (a shorter 16 bit value to simplify discussion), the
entries stored into the DHT by example.net would be:
Key | Value
----------------------------------
SHA1(+14085555000) | 0x1234
SHA1(+14085555001) | 0x1234
SHA1(+14085555002) | 0x1234
.....
SHA1(+14085555999) | 0x1234
Figure 2: DHT Contents
It is important to note that the DHT does not contain phone numbers
(it contains hashes of them), nor does it contain IP addresses or
domain names. Instead, it is a mapping from the hash of a phone
number (in E.164 format) to a Node-ID.
example.net will store this mapping when it starts up, or when a new
number is provisioned. The information is refreshed periodically by
example.net. The actual server on which these mappings are stored
depends on the variant of the Chord algorithm. Typically, the
entries will be uniformly distributed amongst all of the call agents
participating in the network.
6.3.2. PSTN First Call
At some point, a user agent (Alice) in example.com makes a call to +1
408 555 5432, which is her colleague Bob. Even though both sides have
VIPR, the call takes place over the plain old PSTN, per Figure 3.
Alice talks to Bob for a bit, and they hang up.
+-------+ +-------+
| Call | | Call |
//\\ | Agent | | Agent | //\\
\ / | | | | \ /
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\/ ---| | +-----------+ | |---- \/
Alice | |<=======<========>======>| | Bob
+-------+ | PSTN | +-------+
example.com | | example.net
+-----------+
Figure 3: PSTN First Call
At a random point in time after the call has completed, the call
agent in example.com "wakes up" and says to itself, "that's
interesting, someone in my domain called +1 408 555 5432, and it went
over the PSTN. I wonder if that number is reachable over IP
instead?". To make this determination, it hashes the called phone
number, and looks it up in the DHT. It is important to note that
this lookup is not at the time of an actual phone call - this lookup
process happens outside of any phone call, and is a background
process.
The query for +1 408 555 5432 will traverse the DHT, and eventually
arrive at the node that is responsible for storing the mapping for
that number. Typically, that node will not be example.net, but
rather one of the other nodes in the network (e.g., example.org). In
many cases, the called number will not find a matching mapping in the
DHT. This happens when the number that was dialed is not owned by a
domain participating in VIPR. When that happens, example.com takes
no further action. Next time there is another call to the same
number, it will repeat the process and check once more whether the
dialed number is in the DHT.
In this case, there is a match in the DHT, and example.com learns the
Node-ID of example.net. It then proceeds to the validation step per
Section 6.3.3. It is also possible that there are multiple matches
in the DHT. This can happen if another domain - example.edu for
example - also claims ownership of that number. When there are
multiple matching results, example.com learns all of them, and
performs the validation step with each.
6.3.3. Validation and Caching
Why not just store the domain in the DHT, instead of the Node-ID? If
the domain was stored in the DHT, once example.com performed the
lookup, it would immediately learn that the number maps to
example.net, and could then make a direct SIP call next time.
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The main reason this doesn't work is security. The information in
the DHT is completely untrusted. There is nothing so far that
enables example.com to know that example.net does, in fact, own the
phone number in question. Indeed, if multiple domains make a claim
on the number, it has no way to know which one (if any) actually owns
it.
To address this critical problem, VIPR requires a mechanism called
phone number validation. Phone number validation is a key concept in
VIPR. There are several models for this validation as detailed in
[I-D.petithuguenin-vipr-pvp]. The essential idea is that example.com
will connect to the example.net server, by asking the DHT to form a
connection to example.net's Node-ID. Once connected, example.com
demands proof of ownership of the phone number. This proof comes in
the form of demonstrated knowledge of the previous PSTN call. When a
call was placed from example.com to +1 408 555 5432, the details of
that call - including its caller ID, start time, and stop time,
create a shared secret referred to as a "ticket", - information that
is only known to entities that participated in the call. Thus, to
obtain proof that example.net really owns the number in question,
example.com will demand a knowledge proof - that example.net is aware
of the details of the call. A consequence of this is that the
following property is maintained:
A domain can only call a specific number over SIP, if it had
previously called that exact same number over the PSTN.
This property is key in fighting spam and denial-of-service attacks.
Because calling numbers on the PSTN costs money - especially
international calls - VIPR creates a financial disincentive for
spammers. For a spammer to ring every phone in a domain with a SIP
call, it must have previously called every number in the domain with
a PSTN call, and had a successfully completed call to each and every
one of them. [I-D.petithuguenin-vipr-sip-antispam] provides an
overview and further details on the security mechanisms for VIPR for
mitigation of SPAM.
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There are a great many details required for this validation protocol
to be secured. For example, the mechanism needs to handle the fact
that call start and stop times won't exactly match on both sides. It
needs to deal with the fact that many calls start on the top of the
hour. It needs to deal with the fact that caller ID is not often
delivered, and when it is delivered, is not reliable. It needs to
deal with the fact that example.com may in fact be the attacker,
trying to use the validation protocol to extract the shared secret
from example.net. All of this is, in fact, handled by the protocol.
The protocol is based on the Secure Remote Password for TLS
Authentication (SRP-TLS) [RFC5054], and is described more fully in
[I-D.petithuguenin-vipr-pvp].
Towards the end of the validation process, domains example.com and
example.net had determined that each was, in fact in possession of
the shared secret information about the prior PSTN call. However,
neither side has any information about the domain names of the other
side.
At the end of the validation process, both example.com and
example.net have been able to ascertain that the other side did in
fact participate in the previous PSTN call. At that point,
example.com sends its domain name to example.net as shown in Figure
4.
+-------+ +-------+
| Call | | Call |
example.org | Agent | | Agent | example.edu
| | | |
+-------+ +-------+
\ /
+----------------------+ \ /
| Hi, I am example.com.| \ /
| How do I reach you? | \ /
+--------------\-------+ //-------\\
\ // \\
+===\======>========>========>=====+
^ | Internet | |
| | | v
+-------+ |\\ //| +-------+
| Call |------ \\ _______//------| Call |
//\\ | Agent | | Agent | //\\
\ / | | | | \ /
\/ ---| | | |---- \/
Alice | | | | Bob
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+-------+ +-------+
example.com example.net
Figure 4: Ticket Validation Step 1
Next, the example.net domain generates the ticket. The ticket has
three fundamental parts to it:
1. The phone number that was just validated - in this case, +1 408
555 5432.
2. The domain name that the originating side claims it has -
example.com in this case.
3. A signature generated by example.net, using a key known to itself
only, over the other two pieces of information.
Then, example.net sends to example.com - all over a secured channel -
a SIP URI to use for routing calls to this number, and a ticket, as
shown in Figure 5. The ticket is a cryptographic object, opaque to
example.com, but used by example.net to allow incoming SIP calls. It
is similar in concept to kerberos tickets - it is a grant of access.
In this case, it is a grant of access for example.com to call +1 408
555 5432, and only +1 408 555 5432.
+-------+ +-------+
| Call | | Call |
example.org | Agent | | Agent | example.edu
| | | |
+-------+ +-------+
\ /
\ / +------------------------+
\ / | Here is your ticket |
\ / | & SIP URI to reach Bob |
//-------\\ +----/-------------------+
// \\ /
+==========<========<========<===/=+
| | Internet | ^
v | | |
+-------+ |\\ //| +-------+
| Call |------ \\ _______//------| Call |
//\\ | Agent | | Agent | //\\
\ / | | | | \ /
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\/ ---| | | |---- \/
Alice | | | | Bob
+-------+ +-------+
example.com example.net
Figure 5: Ticket Validation Step 2
The example.com call agent receives the SIP URI and ticket, and
stores both of them in an internal cache. This cache builds up
slowly over time, containing the phone number, SIP URI, and ticket,
for those numbers which are called by example.com and validated using
VIPR. Because the cache entries are only built for numbers which
have actually been called by users in the enterprise, the size of the
cache self-scales. A call agent supporting only ten users will build
up a cache proportional to the volume of numbers called by ten
people, whereas a call agent supporting ten thousand users will build
up a cache which is typically a thousand times larger.
This cache, containing the phone number, SIP URI and ticket will be
accessed later when Alice (or another caller from the same call
agent) makes another call to Bob, as detailed in Section 6.3.4.
6.3.4. SIP Call
At some point in the future, another call is made to +1 408 555 5432.
The caller could be Alice, or it could be any other user attached to
the same call agent. This time, the call agent notes that it has a
cached entry (including the SIP URI and ticket) for the number in
question. It is possible that there are multiple entries for a given
number. For example, both an Enterprise and Service Provider may
register the same number in the RELOAD distributed database. It may
also be possible to fork a call using the multiple entries .
[Editor's note: this requires further discussion as to whether we
want to allow multiple entries.]
The example.com call agent attempts to contact the SIP URI by
establishing a TCP/TLS connection to the SIP URI it learned. If a
connection cannot be made and there are no other cached entries for
the number in question, the call agent proceeds with the call over
the PSTN. This ensures that, in the event of an Internet failure or
server failure, the call can still proceed. Assuming the connection
is established, the example.com call agent sends a SIP INVITE to the
terminating call agent, over this newly formed secure connection.
The SIP INVITE request also contains the ticket, placed into a new
SIP header field in the message.
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When the SIP INVITE arrives at the example.net call agent, the call
agent can extract the ticket from the new SIP header field. This
ticket is an object, opaque to example.com, that was previously
generated by the example.net call agent as described in
Section 6.3.3. example.net first verifies the signature over the
ticket. Remember that the example.net agent is the one that
generated the ticket in the first place; as such, it is in possession
of the key required to validate the signature. Once validated, it
performs two checks:
1. It compares the phone number in the call setup request (the
Request URI) against the phone number stored in the ticket.
2. It compares the domain name of the calling domain, learned from
the certificates in the mutual TLS exchange, against the domain
name stored in the ticket.
If both match, the example.net call agent knows that the calling
party is in fact the domain they claimed previously, and that they
had in fact gone through the validation process successfully for the
number in question. At this time, the call is now completed per
normal SIP processing.
7. Security Considerations
This section provides an overview of some of the key threats and how
they are handled at a high level. Note that the detailed security
solutions to handle the threats are detailed in the other relevant
VIPR documents as referenced in the sections below.
7.1. Attacks on the DHT
Attackers could attempt to disrupt service through a variety of
attacks on the DHT.
Firstly, it must be noted that the DHT is never used at call setup
time. It is accessed as a background task, solely to learn NEW
numbers and SIP URIs that are not already known. If an attacker was
able to completely destroy the P2P network, it would not result in a
single call to fail. Furthermore, it would not cause calls to revert
to the PSTN - calls to SIP URIs learned previously would still go
over the IP network. The only impact to such a devastating attack is
that a domain could not learn SIP URIs for new numbers, until the DHT
is restored to service. This service failure is hard for users and
administrators to even notice.
That said, VIPR prevents many of these attacks. The DHT itself is
secured using TLS - its usage is mandatory. Quota mechanisms are put
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into place that prevent an attacker from storing large amounts of
data in the DHT as described in
[I-D.petithuguenin-vipr-proportional-quota]. Other attacks are
prevented by mechanisms defined by RELOAD [I-D.ietf-p2psip-base]
itself, and are not VIPR specific.
7.2. Theft of Phone Numbers
A key security threat that VIPR is trying to address is the theft of
phone numbers. In particular, a malicious domain could store, in the
DHT, phone numbers that it does not own, in an attempt to steal calls
targeted to those numbers. This attack is prevented by the core
validation mechanism as described in [I-D.petithuguenin-vipr-pvp] ,
which performs a proof of knowledge check to verify ownership of
numbers.
An attacker could try to claim numbers it doesn't own, which are
claimed legitimately by other domains in the VIPR network. This
attack is prevented as well. Each domain storing information into
the DHT can never overwrite information stored by another domain. As
a consequence, if two domains claim the same number, two records are
stored in the DHT. An originating domain will validate against both,
and only one will validate - the real owner.
An attacker could actually own a phone number, use it for a while,
validate with it, and build up a cache of routes at other domains.
Then, it gives back the phone number to the PSTN provider, who
allocates it to someone else. However, the attacker still claims
ownership of the number, even though they no longer have it. This
attack is prevented by expiring the learned routes after a while.
Typically, operators do not re-assign a number for a few months, to
allow out-of-service messages to be played to people that still have
the old number. Thus, the TTL for cached routes is set to match the
duration that carriers typically hold numbers.
An attacker could advertise a lot of numbers, most of which are
correct, some of which are not. VIPR prevents this by requiring each
number to be validated individually.
An attacker could make a call so they know the call details of the
call they made and use this to forge a validation for that call.
They could then try to convince other users, which would have to be
in the same domain as the attacker, to trust this validation. This
is mitigated by not sharing validations inside of domains where the
users that can originate call from that domain are not trusted by the
domain.
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7.3. Spam
Another serious concern is that attackers may try to launch SIP spam
(also known as SPIT) calls into a domain. As described in
Section 6.3.3 and as detailed in
[I-D.petithuguenin-vipr-sip-antispam], VIPR prevents this by
requiring that a domain make a PSTN call to a number before it will
allow a SIP call to be accepted to that same number. This provides a
financial disincentive to spammers. The current relatively high cost
of international calling, and the presence of national do-not-call
regulations, have prevented spam on the PSTN to a large degree. VIPR
applies those same protections to SIP connections.
VIPR still lowers the cost of communications, but it does so by
amortizing that savings over a large number of calls. The costs of
communications remain high for infrequent calls to many numbers, and
become low for frequent calls to a smaller set of numbers. Since the
former is more interesting to spammers, VIPR gears its cost
incentives away from the spammers, and towards domains which
collaborate frequently.
It is important to note that VIPR does not completely address the
spam problem. A large spamming clearing house organization could
actually incur the costs of launching the PSTN calls to numbers, and
then, in turn, act as a conduit allowing other spammers to launch
their calls to those numbers for a fee. The clearinghouse would
actually need to transit the signaling traffic (or, divulge the
private keys to their domain name), which would incur some cost. As
such, while this is not an impossible situation, the barrier is set
reasonably high to start with - high enough that it is likely to
deter spammers until it becomes a highly attractive target, at which
point other mechanisms can be brought to bear.
7.4. Eavesdropping
Another class of attacks involves outsiders attempting to listen in
on the calls that run over the Internet, or obtain information about
the call through observation of signaling.
All of these attacks are prevented by requiring the usage of SIP over
TLS and SRTP. These are mandatory to use.
7.5. Privacy Leakage and Malicious Servers
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A further form of attack involves adding malicious VIPR servers to a
widely implemented (e.g., national or international) RELOAD overlay.
This attack is specific to an uncontrolled RELOAD overlay, in which
any individual or enterprise could add their own VIPR server to the
overlay without authorization, verification or bias.
In this scenario, a malicious VIPR server could be used for analyzing
number registration information for the purpose of spying on called
numbers associated with various participating parties. The
likelihood of this occurring on a large scale is small, because it
might require a prohibitive (and easily-detectable) number of VIPR
servers to capture all of the number registrations of a region under
surveillance; however, more targeted attacks are feasible and should
be recognized as a potential security consideration.
This security breach can occur because all registrations are
considered equally untrusted, and they will be verified by
establishing a TCP connection between the VIPR server of the source
of the call and the VIPR server that stored the registration for a
particular phone number. Multiple pieces of identifying information
are necessarily leaked in this verification process, but it is
specifically easy to identify the enterprise originating the TCP
connection by comparing its source address to public registry data
(such as in-addr.arpa).
For destination phone numbers using VIPR, the vulnerability arises
because the RELOAD overlay permits multiple entities to register for
the same number. The VIPR server at the source of the call may
therefore discover multiple candidate registrations; although
malicious servers registering themselves will not possess the call
details necessary to generate a shared secret, they may learn
sensitive information merely through participating in the
verification process. While it is possible that the real owner of
the number may be tried first and prevent other registrations to be
tried if successful, an attacker could register from multiple VIPR
servers in order to improve their chances of receiving a verification
request. One could easily imagine an attacker determined to learn
who will call a particular number generating a large set of
registrations that would make it very unlikely for the authentic
server to be selected first; with enough such registrations it might
effectively become a denial of service attack. Note however that
this problem is limited to server discovery: as soon as the real
owner sends a SIP route and ticket back, the malicious VIPR server
would no longer receive any information about the calls between the
enterprise and the destination number, with exception of the periodic
renewal of the ticket.
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The possible disclosed information includes more than the just the
connection verification. Here is a list of potential leaked
information:
If the malicious VIPR servers leverage a different VServiceId for
each registered phone number, the called number is always leaked.
The called number is leaked during the validation process for both
methods A and B [draft-petithuguenin-vipr-pvp-04, Section 7.2.1,
Section 7.2.2].
For method A, the caller-ID is leaked (this is encrypted, but it
is possible to decrypt).
For method B, a random time in the middle of the call is leaked.
For method C, the rounded start and stop time of the call are
leaked.
The source IP address of the TCP connection for the PVP
transaction is always leaked.
The addr_port in the AppAttachReq RELOAD message that was used to
establish the TCP connection is leaked. [draft-ietf-p2psip-
base-24]
The certificate of the signer of the AppAttachReq RELOAD message
is leaked. While the certificate does not contain information
about the sender, but it always contains the Node-ID, which can
always be resolved to an IP address by using an Attach request.
8. IANA Considerations
This specification does not require any actions from IANA.
9. Acknowledgements
Thanks for review comments from Ken Fischer, Rob Maidhof, Michael
Procter, Eric Burger, Richard Barnes and others. Thanks to Theo
Zourzouvillys for pointing out the 5th theft of phone numbers attack
as described in Section 7.2 .
10. References
10.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
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10.2. Informative References
[RFC3261] Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston,
A., Peterson, J., Sparks, R., Handley, M., and E.
Schooler, "SIP: Session Initiation Protocol", RFC 3261,
June 2002.
[I-D.ietf-p2psip-base]
Jennings, C., Lowekamp, B., Rescorla, E., Baset, S., and
H. Schulzrinne, "REsource LOcation And Discovery (RELOAD)
Base Protocol", draft-ietf-p2psip-base-26 (work in
progress), February 2013.
[I-D.petithuguenin-vipr-reload-usage]
Petit-Huguenin, M., Rosenberg, J., and C. Jennings, "A
Usage of Resource Location and Discovery (RELOAD) for
Public Switched Telephone Network (PSTN) Verification",
draft-petithuguenin-vipr-reload-usage-04 (work in
progress), March 2012.
[I-D.petithuguenin-vipr-framework]
Petit-Huguenin, M., Jennings, C., and J. Rosenberg,
"Verification Involving PSTN Reachability (VIPR):
Framework", draft-petithuguenin-vipr-framework-00 (work in
progress), October 2011.
[I-D.petithuguenin-vipr-sip-antispam]
Petit-Huguenin, M., Rosenberg, J., and C. Jennings,
"Session Initiation Protocol (SIP) Extensions for Blocking
VoIP Spam Using PSTN Validation", draft-petithuguenin-
vipr-sip-antispam-03 (work in progress), January 2012.
[I-D.jennings-vipr-vap]
Jennings, C., Rosenberg, J., and M. Petit-Huguenin,
"Verification Involving PSTN Reachability: The ViPR Access
Protocol (VAP)", draft-jennings-vipr-vap-02 (work in
progress), March 2012.
[I-D.petithuguenin-vipr-pvp]
Petit-Huguenin, M., Rosenberg, J., and C. Jennings, "The
Public Switched Telephone Network (PSTN) Validation
Protocol (PVP)", draft-petithuguenin-vipr-pvp-04 (work in
progress), March 2012.
[I-D.petithuguenin-vipr-proportional-quota]
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Petit-Huguenin, M., Rosenberg, J., and C. Jennings,
"Proportional Quota in REsource LOcation And Discovery
(RELOAD)", draft-petithuguenin-vipr-proportional-quota-00
(work in progress), October 2011.
[RFC2543] Handley, M., Schulzrinne, H., Schooler, E., and J.
Rosenberg, "SIP: Session Initiation Protocol", RFC 2543,
March 1999.
[RFC3263] Rosenberg, J. and H. Schulzrinne, "Session Initiation
Protocol (SIP): Locating SIP Servers", RFC 3263, June
2002.
[E.164] ITU-T, "The International Public Telecommunication Number
Plan", Recommendation E.164, May 1997.
[RFC5039] Rosenberg, J. and C. Jennings, "The Session Initiation
Protocol (SIP) and Spam", RFC 5039, January 2008.
[RFC6116] Bradner, S., Conroy, L., and K. Fujiwara, "The E.164 to
Uniform Resource Identifiers (URI) Dynamic Delegation
Discovery System (DDDS) Application (ENUM)", RFC 6116,
March 2011.
[RFC5067] Lind, S. and P. Pfautz, "Infrastructure ENUM
Requirements", RFC 5067, November 2007.
[RFC5054] Taylor, D., Wu, T., Mavrogiannopoulos, N., and T. Perrin,
"Using the Secure Remote Password (SRP) Protocol for TLS
Authentication", RFC 5054, November 2007.
[RFC6873] Salgueiro, G., Gurbani, V., and A. Roach, "Format for the
Session Initiation Protocol (SIP) Common Log Format
(CLF)", RFC 6873, February 2013.
[I-D.jones-insipid-session-id]
Jones, P., Pearce, C., Polk, J., and G. Salgueiro, "End-
to-End Session Identification in IP-Based Multimedia
Communication Networks", draft-jones-insipid-session-id-02
(work in progress), February 2013.
[I-D.ietf-insipid-session-id-reqts]
Jones, P., Salgueiro, G., Polk, J., Liess, L., and H.
Kaplan, "Requirements for an End-to-End Session
Identification in IP-Based Multimedia Communication
Networks", draft-ietf-insipid-session-id-reqts-08 (work in
progress), July 2013.
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Appendix A. Changes since last version
This section must be removed before publication as an RFC.
Modifications between jennings-04 and jennings-03:
1. Updating references to SIPCLF and Session ID (INSIPID) documents.
Modifications between jennings-03 and jennings-02:
1. Reworded REQ -11 to clarify that in the case of call failures
(i.e., IP calls), the system should fallback to inter-domain
calling prior to VIPR.
2. Deleted REQ-12 (Handover) since it's really not specific
functionality provided by VIPR.
3. Moved some text from the -01 version in the Technical Overview
section back into the doc (not sure why it was removed
previously).
4. Other editorial changes:
- Added a Terminology section.
- Clarified the use of the term "Call Agent".
- Reworded discussion of email in section 2.2 (i.e., it's not
useless).
- Either changed or removed altogether terms like "neat",
"clever", "incredible", "enormous" and any text that read like
marketing literature as much as possible.
- Removed some of the more subjective and superfluous language -
i.e., condensed the text to be more concise (Section 5.2 and many
others per the previous change)
- Deleted explicit reference to "SIP Trunking" as the statement
didn't introduce additional information in that paragraph and the
term is not defined in this document.
- and other minor editorial fixes.
Modifications between jennings-02 and jennings-01:
1. Sections 6,7,8 moved to new VIPR framework document.
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2. Editorial changes.
3. Clarifications to re-enforce that the primary objective is not
PSTN bypass but rather to enable enhanced services such as video
between domains. Changed "VoIP" to "SIP" since the focus is not
specifically voice.
4. Added reference for new framework document.
5. Section 5.3: Added references to other documents as appropriate -
e.g., -pvp, -spam, etc.
6. Moved validation diagrams and text (from 5.3.4) into Validation
and caching section (5.3.3).
7. Condensed discussion of spam in section 5.3.3 and updated SPAM
section in security section.
Modifications between jennings-01 and rosenberg-04:
o Not specified.
Modifications between rosenberg-04 and rosenberg-03
o Nits.
o Shorter I-Ds references.
o Changed phone numbers to follow E.123 presentation.
o Expanded P2P initialisms.
o Uses +1 408 555 prefix for phone numbers in examples.
Authors' Addresses
Mary Barnes
Polycom
TX
US
Email: mary.ietf.barnes@gmail.com
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Cullen Jennings
Cisco
170 West Tasman Drive
MS: SJC-21/2
San Jose, CA 95134
USA
Phone: +1 408 421-9990
Email: fluffy@cisco.com
Jonathan Rosenberg
jdrosen.net
Monmouth, NJ
US
Email: jdrosen@jdrosen.net
URI: http://www.jdrosen.net
Marc Petit-Huguenin
Unaffiliated
Email: petithug@acm.org
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