ECRIT H. Schulzrinne
Internet-Draft Columbia U.
Intended status: Informational July 8, 2007
Expires: January 9, 2008
Location-to-URL Mapping Architecture and Framework
draft-ietf-ecrit-mapping-arch-02
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Abstract
This document describes an architecture for a global, scalable,
resilient and administratively distributed system for mapping
geographic location information to URLs, using the Location-to-
Service (LoST) protocol. The architecture generalizes well-known
approaches found in hierarchical lookup systems such as DNS.
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Table of Contents
1. The Mapping Problem . . . . . . . . . . . . . . . . . . . . . 3
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. Definitions . . . . . . . . . . . . . . . . . . . . . . . . . 4
4. Overview of Architecture . . . . . . . . . . . . . . . . . . . 5
4.1. Minimal System Architecture . . . . . . . . . . . . . . . 6
5. Seeker . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
6. Resolver . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
7. Trees: Maintaining Authoritative Knowledge . . . . . . . . . . 7
7.1. Basic Operation . . . . . . . . . . . . . . . . . . . . . 7
7.2. Answering Queries . . . . . . . . . . . . . . . . . . . . 10
7.3. Overlapping Coverage Regions . . . . . . . . . . . . . . . 10
7.4. Scaling and Reliability . . . . . . . . . . . . . . . . . 11
8. Forest Guides . . . . . . . . . . . . . . . . . . . . . . . . 11
9. Configuring Service Numbers . . . . . . . . . . . . . . . . . 12
10. Security Considerations . . . . . . . . . . . . . . . . . . . 14
11. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 15
12. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 15
13. References . . . . . . . . . . . . . . . . . . . . . . . . . . 15
13.1. Normative References . . . . . . . . . . . . . . . . . . . 15
13.2. Informative References . . . . . . . . . . . . . . . . . . 15
Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . 16
Intellectual Property and Copyright Statements . . . . . . . . . . 17
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1. The Mapping Problem
It is often desirable to allow users to access a service that
provides a common function, but is actually offered by a variety of
local service providers. In many of these cases, the service
provider chosen depends on the location of the person wishing to
access that service. Among the best-known public services of this
kind is emergency calling, where emergency calls are routed to the
most appropriate public safety answering point (PSAP), based on the
caller's physical location. Other services, from food delivery to
directory services and roadside assistance, also follow this general
pattern. This is a mapping problem [8], where a geographic location
and a service identifier (URN) [10] is translated into a set of URIs,
the service URIs, that allow the Internet system to contact an
appropriate network entity that provides the service.
The caller does not need to know where the service is being provided
from, and the location of the service provider may change over time,
e.g., to deal with temporary overloads, failures in the primary
service provider location or long-term changes in system
architecture. For emergency services, this problem is described in
more detail in [6].
The overall emergency calling architecture [6] separates mapping from
placing calls or otherwise invoking the service, so the same
mechanism can be used to verify that a mapping exists ("address
validation") or to obtain test service URIs.
Mapping locations to URIs describing services requires a distributed,
scalable and highly resilient infrastructure. Authoritative
knowledge about such mappings is distributed among a large number of
autonomous entities that may have no direct knowledge of each other.
In this document, we describe an architecture for such a global
service. It allows significant freedom to combine and split
functionality among actual servers and imposes few requirements as to
who should operate particular services.
Besides determining the service URI, end systems also need to
determine the local service numbers. As discussed in Section 9, the
architecture described here can also address that problem.
The architecture described here uses the Location-to-Service
Translation (LoST) [2] protocol, although much of the discussion
would also apply for other mapping protocols satisfying the mapping
requirements [8].
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2. Terminology
In this document, the key words "MUST", "MUSTNOT", "REQUIRED",
"SHALL", "SHALLNOT", "SHOULD", "SHOULDNOT", "RECOMMENDED", "MAY", and
"OPTIONAL" are to be interpreted as described in RFC 2119 [1] and
indicate requirement levels for compliant implementations.
3. Definitions
In addition to the terms defined in [8], this document uses the
following terms to describe LoST clients and servers:
authoritative mapping server (AMS): An authoritative mapping server
(AMS) is a LoST server that can provide the authoritative answer
to a particular set of queries, e.g., covering a set of PIDF-LO
civic labels or a particular region described by a geometric
shape. In some (rare) cases of territorial disputes, two
resolvers may be authoritative for the same region. An AMS may
redirect or forward a query to other AMS within the tree.
child: A child is an AMS that is authoritative for a subregion of
another AMS. A child can in turn be parent for another AMS.
(tree node) cluster: A node cluster is a group of LoST servers that
all share the same mapping information and return the same results
for queries. Clusters provide redundancy and share query load.
Clusters are fully-meshed, i.e., they all exchange updates with
each other.
forest guide (FG): A forest guide (FG) has knowledge of the coverage
region of trees for a particular top-level service.
mapping: A mapping is a short-hand for 'mapping from a location
object to one or more URLs describing either another mapping
server or the desired service URLs'.
parent: A mapping server that covers the region of all of its
children. A mapping server without a parent is a root AMS.
resolver: A resolver is contacted by a seeker, consults a forest
mapping server and then resolves the query using an appropriate
tree. Resolvers may cache query results.
seeker: A seeker is a LoST client requesting a mapping. A seeker
does not provide mapping services to others, but may cache results
for its own use.
region map: A data object describing a contiguous area covered by an
AMS, either as a subset of a civic address or a geometric object.
tree: A tree consists of a self-contained hierarchy of authoritative
mapping servers. Each tree exports its coverage region to the
forest mapping servers.
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4. Overview of Architecture
In short, end users of the LoST-based [2] mapping mechanism, called
seekers, contact resolvers that cache query results and know one or
more "forest guides". Forest guides know the coverage region of
trees and direct queries to the node at the top of the appropriate
tree. Trees consist of authoritative mapping servers and maintain
the authoritative mapping information. Figure 1 shows the
interaction of the components.
/-\ /-\ +-----+ +-----+
| S +******* R ********* FG *-----------------+ FG |
\-/ \-/ | |* | |
+--+--+ * +--+--+
| * |
| * |
| * |
| * |
/-\ +--+--+ * +--+--+
| R +------>+ FG +-----*-----------+ FG |
\-/ | | * | |
+--+--+ * +--+--+
| * |
| * |
| * |
|*** ^
/ \ / \
/ \ / \
/ \ / \
/ \ / \
----------- -----------
tree tree
Architecture diagram, showing seekers (S), resolvers (R), forest
guides (FG) and trees. The star (*) line indicates the flow of the
query and responses in recursive mode.
Figure 1
The mapping function for the world is divided among trees. The
collection of trees may not cover the whole world and trees are added
and removed as the organization of mapping data changes. We call the
collection of trees a forest. There is no limit on the number of
trees within the forest, but the author guesses that the number of
trees will likely be somewhere between a few hundred and a few
thousand. The lower estimate would apply if each country operates
one tree. We assume that tree coverage information changes
relatively slowly, on the order of less than one change per year per
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tree, although the system imposes no specific threshold. Tree
coverage would change, for example, if a country is split or merged
or if two trees for different regions become part of a larger tree.
(On the other hand, information within a tree is likely to change
much more frequently.)
4.1. Minimal System Architecture
It is possible to build a functioning system consisting only of
seekers and resolvers if these resolvers have other means of
obtaining mapping data. For example, a company acting as a mapping
service provider could collect mapping records manually and make them
available to their customers through the resolver. While feasible as
a starting point, such an architecture is unlikely to scale globally.
Among other problems, it becomes very hard for providers of
authoritative data to ensure that all such providers have up-to-date
information. If new trees are set up, they would somehow make
themselves known to these providers. Such a mechanism would be
similar to the old "hosts.txt" mechanism for distributing host
information in the early Internet before DNS was developed.
Below, we describe the operation of each component in more detail.
5. Seeker
Clients desiring location-to-service mappings are known as seekers.
Seekers are consumers of mapping data and originate LoST queries as
LoST protocol clients. Seekers do not answer LoST queries. They
contact either forest guides or resolvers to find the appropriate
tree that can authoritatively answer their questions. Seekers can be
end systems or call routing entities such as SIP proxy servers.
Seekers may need to obtain mapping information in several steps,
i.e., they may obtain pointers to intermediate servers that lead them
closer to the final mapping. Seekers MAY cache query results for
later use, but otherwise have no obligations to other entities in the
system.
Seekers need to be able to identify appropriate resolvers. The
mechanism for providing seekers with that information is likely to
differ depending on who operates the resolvers. For example, if the
voice service provider operates the resolver, it might include the
location of the resolver in the SIP configuration information it
distributes to its user agents. An Internet access provider or
enterprise can provide a pointer to a resolver via DHCP [5]. In an
ad-hoc or zero-configuration environment, appropriate service
directories may advertise resolvers.
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Like other entities in the system, seekers can cache responses. This
is particularly useful if the response describes the result for a
civic or geospatial region, rather than just a point. For example,
for mobile nodes, seekers would only have to update their resolution
results when they leave the coverage area of a service provider, such
as a PSAP for emergency services, and can avoid repeatedly polling
for this information whenever the location information changes
slightly. (Mobile nodes would also need a location update mechanism
that is either local or triggered when they leave the current service
area.) This will likely be of particular benefit for seekers
representing a large user population, such as the outbound proxy in a
corporate network. For example, rather than having to query
separately for each cubicle, information provided by the
authoritative node may indicate that the whole campus is covered by
the same service provider.
Given this caching mechanism and cache lifetimes of several days,
most mobile users traveling to and from work would only need to
obtain service area information along their commute route once during
each cache lifetime.
6. Resolver
A seeker can contact a forest guide (see below) directly, but may not
be able to easily locate such a guide. In addition, seekers in the
same geographic area may already have asked the same question. Thus,
it makes sense to introduce another entity, known as a resolver in
the architecture, that knows how to contact one or more forest guides
and caches earlier queries to accelerate the response to mapping
queries and to improve the resiliency of the system. Each resolver
can decide autonomously which FGs to use, with possibly different
choices for each top-level service.
ISPs or VSPs would include the address of a suitable resolver in
their configuration information, e.g., in SIP configuration for a VSP
or DHCP [5] for an ISP. Resolvers are manually configured with the
name of one or more forest guides.
7. Trees: Maintaining Authoritative Knowledge
7.1. Basic Operation
The architecture assumes that authoritative knowledge about the
mapping data is distributed among many independent administrative
entities, but clients (seekers) needing the information may
potentially need to find out mapping about any spot on earth.
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(Extensions to extra-terrestrial applications are left for future
exploration.) Information is organized hierarchically, in a tree,
with tree nodes representing larger geographic areas pointing to
several child nodes each representing a smaller area. Each tree node
can be a cluster of LoST servers that all contain the same
information and back up each other.
Each tree can map a location described by civic and geographic
coordinates for one type of service (such as 'sos.police', 'sos.fire'
or 'counseling'), although nothing prevents re-using the same tree
for multiple different services. The collection of all trees for one
service is known as a forest.
Each tree root announces its coverage region to one or more forest
guides.
Each tree node cluster knows the coverage region of its children and
sends queries to the appropriate server "down" the tree. Each such
tree node knows authoritatively about the service mappings for a
particular region, typically, but not necessarily, contiguous. The
region can be described by a polygon in geospatial coordinates or a
set of civic address descriptors (e.g., "country = DE, A1 =
Bavaria"). These coverage regions may be aligned with political
boundaries, but that is not required. In most cases, to avoid
confusion, only one cluster is responsible for a particular
geographic or civic location, but the system can also deal with cases
where coverage regions overlap.
There are no assumptions about the coverage region of a tree as a
whole. For example, a tree could cover a single city, or a state/
province or a whole country. Nodes within a tree need to loosely
coordinate their operation, but they do not need to be operated by
the same administrator.
The tree architecture is roughly similar to the domain name system
(DNS), except that delegation is not by label, but rather by region.
(Naturally, DNS does not have the notion of forest guides.) One can
also draw analogies to LDAP, when deployed in a distributed fashion.
Tree nodes maintain two types of information, namely coverage regions
and mappings. Coverage regions describe the region served by a child
node in the tree and point to a child node for further resolution.
Mappings contain an actual service URI leading to a service provider
or another signaling server representing a group of service
providers, which in turn might further route signaling requests to
more servers covering smaller regions.
Leaf nodes, i.e., nodes without children, only maintain mappings,
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while tree nodes above the leaf nodes only maintain coverage regions.
An example for emergency services of a leaf node entry is shown
below, indicating how queries for three towns are directed to
different PSAPs. Queries for Englewood are directed to another LoST
server instead.
country A1 A2 A3 resource
US NJ Bergen Leonia sip:psap@leonianj.gov
US NJ Bergen Fort Lee sip:emergency@fortleenj.org
US NJ Bergen Teaneck sip:police@teanecknjgov.org
US NJ Bergen Englewood lost:englewoodnj.gov
....
Coverage regions are described by sets of polygons enclosing
contiguous geographic areas or by descriptors enumerating groups of
civic locations. For the former, the LoST server performs a point-
in-polygon operation to find the polygon that contains the query
point. (More complicated geometric matching algorithms may be added
in the future.)
For example, a state-level tree node for New Jersey in the United
States may contain the following coverage region entries, indicating
that any query matching a location in Bergen County, for example,
would be redirected or forwarded to the node located at
bergen.nj.example.org. There is no requirement that all child nodes
cover the same level within the civic hierarchy. As an example, in
the table below, the city of Newark has decided to be listed directly
within the state node, rather than through the county. Longest-match
rules allow partial coverage, so that for queries for all other towns
within Essex county would be directed to the county node for further
resolution.
C A1 A2 A3 resource
US NJ Atlantic * lost:atlantic.nj.example.org/sos
US NJ Bergen * lost:bergen.nj.example.org/sos
US NJ Monmouth * lost:monmouth.nj.example.org/sos
US NJ Essex * lost:essex.nj.example.org/sos
US NJ Essex Newark lost:newark.example.com/sos
....
Thus, there is no substantial difference between coverage region and
mapping data. The only difference is that coverage regions return
LoST URLs, while mapping entries contain service URLs. Mapping
entries may be specific down to the house or floor level or may only
contain street-level information. For example, in the United States,
civic mapping data for emergency services is generally limited to
address ranges ("MSAG data"), so initial mapping databases may only
contain street-level information.
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To automate the maintenance of trees, the LoST synchronization
mechanism [11] allows nodes to query other nodes for mapping data and
coverage regions. In the example above, the state-run node would
query the county nodes and use the records returned to distribute
incoming LoST queries to the county nodes. Conversely, nodes could
also contact their parent nodes to tell them about their coverage
region. There is some benefit of child nodes contacting their
parents, as this allows changes in coverage region to propagate
quickly up the tree.
7.2. Answering Queries
Within a tree, the basic operation is straightforward: A query
reaches the root of the tree. That node determines which coverage
region matches that request and forwards the request to the URL
indicated in the coverage region record, returning a response to the
querier when it in turns receives an answer (recursion).
Alternatively, the node returns the URL of that child node to the
querier (iteration). This process applies to each node, i.e., a node
does not need to know whether the original query came from a parent
node, a seeker, a forest guide or a resolver.
For efficiency, a node MAY return region information instead of a
point answer. Thus, instead of returning that a particular
geospatial coordinate maps to a service or mapping URL, it MAY return
a polygon indicating the region for which this answer would be
returned, along with expiration time (time-to-live) information. The
querying node can then cache this information for future use.
For civic coordinates, trees may not include individual mapping
records for each floor, house number or street. To avoid giving the
wrong indication that a particular location has been found valid,
LoST can indicate which parts of the location information have
actually been used to look up a mapping.
7.3. Overlapping Coverage Regions
In some cases, coverage regions may overlap, either because there is
a dispute as to who handles a particular geographic region or, more
likely, since the resolution of the coverage map may not be
sufficiently high. For example, a node may "shave some corners" off
its polygon, so that its coverage region appears to overlap with its
geographic neighbor. For civic coordinates, houses on the same
street may be served by different PSAPs. The mapping mechanism needs
to work even if a coverage map is imprecise or if there are disputes
about coverage.
The solution for overlapping coverage regions is relatively simple.
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If a query matches multiple coverage regions, the node returns all
URLs, in redirection mode, or queries both children, if in recursive
mode. If the overlapping coverage is caused by imprecise coverage
maps, only one will return a result and the others will return an
error indication. If the particular location is disputed territory,
the response will contain all answers, leaving it to the querier to
choose the preferred solution or trying to contact all services in
turn.
7.4. Scaling and Reliability
Since they provide authoritative information, tree nodes need to be
highly reliable. Thus, while this document refers to tree nodes as
logical entities within the tree, an actual implementation would
likely replicate node information across several servers, forming a
cluster. Each such node would have the same information. Standard
techniques such as DNS SRV records can be used to select one of the
servers. Replication within the cluster can use any suitable
protocol mechanism, but a standardized incremental update mechanism
makes it easier to spread those nodes across multiple independently-
administered locations. The techniques developed for meshed SLP [3]
are applicable here.
8. Forest Guides
Unfortunately, just having trees covering various regions of the
world is not sufficient as a client of the mapping protocol would not
generally be able to keep track of all the trees in the forest. To
facilitate orientation among the trees, we introduce a "forest guide"
(FG). It is a server that keeps track of the coverage regions of the
trees. For scalability and reliability, there will need to be a
large number of forest guides, all providing the same information. A
seeker can contact a suitable forest guide and will then be directed
to the right tree or, rarely, set of trees. Forest guides do not
provide mapping information themselves, but rather redirect to
mapping servers. In some configurations, not all forest guides may
provide the same information, due to policy reasons.
Introducing forest guides avoids creating a global root, with the
attendant management and control issues. Trees can also restrict
their cooperation to parts of the information. For example, if
country C does not recognize country T, C can propagate tree regions
for all but T.
For authenticity, the records SHOULD be digitally signed. They are
used by resolvers and possibly seekers to find the appropriate tree
for a particular area. All forest guides should have consistent
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information, i.e., a collection of all the coverage regions of all
the trees. A tree node at the top of a tree can contact any forest
guide and inject new coverage region information into the system.
One would expect that each tree announces its coverage to more than
one forest guide. Each forest guide peers with one or more other
guides and distributes new coverage region announcements to all other
guides.
Forest guides fulfill a similar role to root servers in DNS.
However, their number is likely to be larger, possibly counted in
hundreds. They distribute information, signed for authenticity,
offered by trees.
Forest guides can, in principle, be operated by anybody, including
voice service providers, Internet access providers, dedicated
services providers and enterprises.
As in routing, peering with other forest guides implies a certain
amount of trust in the peer. Thus, peering is likely to require some
negotiation between the administering parties concerned, rather than
automatic configuration. The mechanism itself does not imply a
particular policy as to who gets to advertise a particular coverage
region.
9. Configuring Service Numbers
The section below is not directly related to the problem of
determining service location, but is an instance of the more generic
problem solved by this architecture, namely mapping location
information to service-related parameters, such as service numbers.
For the foreseeable future, some user devices and software will
emulate the user interface of a telephone, i.e., the only way to
enter call address information is via a 12-button keypad with digits
and the asterisk and hash symbol. These devices use service numbers
to identify services. The best-known examples of service numbers are
emergency numbers, such as 9-1-1 in North America and 1-1-2 in
Europe. However, many other public and private service numbers have
been defined, ranging in the United States from 3-1-1 for non-
emergency local government services to 4-1-1 for directory assistance
to various "800" numbers for anything from roadside assistance to
legal services to home-delivery food.
Such service numbers are likely to be used until essentially all
communication devices feature IP connectivity and an alphanumeric
keyboard. Unfortunately, for emergency services, more than 60
emergency numbers are in use throughout the world, with many of those
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numbers serving non-emergency purposes elsewhere, e.g., identifying
repair or directory services. Countries also occasionally change
their emergency numbers to conform to regional agreements. An
example is the introduction of "1-1-2" for countries in Europe.
Thus, a system that allows devices to be used internationally to
place calls needs to allow devices to discover service numbers
automatically. In the Internet-based system proposed here [6], these
numbers are strictly used as a human user interface mechanism and are
generally not visible in call signaling messages, which carry the
service URN [10] instead.
For the best user experience, systems should be able to discover two
sets of service numbers, namely those used in the user's home country
and in the country the user is currently visiting. The user is most
likely to remember the former, but a companion borrowing a device in
an emergency, say, may only know the local emergency numbers.
Determining home and local service numbers is a configuration
problem, but unfortunately, existing configuration mechanisms are
ill-suited for this purpose. For example, a DHCP server might be
able to provide the local service numbers, but not the home numbers.
When virtual private networks (VPNs) are used, even DHCP may provide
numbers of uncertain origin, as a user may contact to the home
network or some local branch office of the corporate network.
Similarly, SIP configuration [4] would be able to provide the numbers
valid at the location of the SIP service provider, but even a SIP
service provider with national footprint may serve customers that are
visiting any number of other countries.
Also, while initially there are likely to be only a few service
numbers, e.g., for emergency services, the LoST architecture can be
used to support other services, as noted. Configuring every local
DHCP or SIP configuration server with that information is likely to
be error-prone and tedious.
For these reasons, the LoST-based mapping architecture supports
providing service numbers to end systems based on caller location.
The mapping operation is almost exactly the same as for determining
the service URL. The mapping can be obtained either along with
determining the service URL or separately. The major difference
between the two requests is that service numbers often have much
larger regions of validity than the service URL itself. Also, the
service number is likely to be valid longer than the service URL.
Finally, an end system may want to look up the service number for its
home location, not just the current (visited) location.
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10. Security Considerations
Security considerations for emergency services mapping are discussed
in [9], while [10] discusses issues related to the service URN, one
of the inputs into the mapping protocol. LoST-related security
considerations are naturally discussed in the LoST [2] specification.
The architecture addresses the following security issues, usually
through the underlying transport security associations:
Server impersonation: Seekers, resolvers, fellow tree guides and
cluster members can assure themselves of the identity of the
remote party by using the facilities in the underlying channel
security mechanism, such as TLS.
Query or query result corruption: To avoid that an attacker can
modify the query or its result, the architecture RECOMMENDS the
use of channel security, such as TLS. Results SHOULD also be
digitally signed, e.g., using XML digital signatures. Note,
however, that simple origin assertion may not provide the end
system with enough useful information as it has no good way of
knowing that a particular signer is authorized to represent a
particular geographic area. It might be necessary that certain
well-known Certificate Authorities (CAs) vet sources of mapping
information and provide special certificates for that purpose. In
many cases, a seeker will have to trust its local resolver to vet
information for trustworthiness; in turn, the resolver may rely on
trusted forest guides to steer it to the correct information.
Region corruption: To avoid that a third party or an untrustworthy
member of a server population introduces a region map that it is
not authorized for, any node introducing a new region map MUST
sign the object by encapsulating the data into a CMS wrapper. A
recipient MUST verify, through a local policy mechanism, that the
signing entity is indeed authorized to speak for that region.
Determining who can speak for a particular region is inherently
difficult unless there is a small set of authorizing entities that
participants in the mapping architecture can trust. Receiving
systems should be particularly suspicious if an existing region
map is replaced with a new one with a new mapping address. In
many cases, trust will be mediated: A seeker will have a trust
relationship with a resolver. The resolver, in turn, will contact
a trusted forest guide.
Additional threats that need to be addressed by operational measures
include denial-of-service attacks [7].
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11. IANA Considerations
Since this document describes an architecture, not a protocol, it
does not ask IANA to register any protocol constants.
12. Acknowledgments
Richard Barnes, Jong Yul Kim, Otmar Lendl, Andrew Newton, Murugaraj
Shanmugam, Richard Stastny, and Hannes Tschofenig provided helpful
comments.
13. References
13.1. Normative References
[1] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997.
[2] Hardie, T., "LoST: A Location-to-Service Translation Protocol",
draft-ietf-ecrit-lost-05 (work in progress), March 2007.
13.2. Informative References
[3] Zhao, W., Schulzrinne, H., and E. Guttman, "Mesh-enhanced
Service Location Protocol (mSLP)", RFC 3528, April 2003.
[4] Petrie, D. and S. Channabasappa, "A Framework for Session
Initiation Protocol User Agent Profile Delivery",
draft-ietf-sipping-config-framework-12 (work in progress),
June 2007.
[5] Schulzrinne, H., "A Dynamic Host Configuration Protocol (DHCP)
based Location-to-Service Translation Protocol (LoST)
Discovery Procedure", draft-ietf-ecrit-dhc-lost-discovery-01
(work in progress), March 2007.
[6] Rosen, B., "Framework for Emergency Calling in Internet
Multimedia", draft-ietf-ecrit-framework-01 (work in progress),
March 2007.
[7] Rosen, B. and J. Polk, "Best Current Practice for
Communications Services in support of Emergency Calling",
draft-ietf-ecrit-phonebcp-01 (work in progress), March 2007.
[8] Schulzrinne, H. and R. Marshall, "Requirements for Emergency
Context Resolution with Internet Technologies",
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draft-ietf-ecrit-requirements-13 (work in progress),
March 2007.
[9] Taylor, T., "Security Threats and Requirements for Emergency
Call Marking and Mapping", draft-ietf-ecrit-security-threats-04
(work in progress), April 2007.
[10] Schulzrinne, H., "A Uniform Resource Name (URN) for Services",
draft-ietf-ecrit-service-urn-06 (work in progress), March 2007.
[11] Schulzrinne, H., "Synchronizing Location-to-Service Translation
(LoST) Servers", draft-schulzrinne-ecrit-lost-sync-00 (work in
progress), November 2006.
Author's Address
Henning Schulzrinne
Columbia University
Department of Computer Science
450 Computer Science Building
New York, NY 10027
US
Phone: +1 212 939 7004
Email: hgs+ecrit@cs.columbia.edu
URI: http://www.cs.columbia.edu
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Full Copyright Statement
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