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ALTO M. Stiemerling
Internet-Draft NEC Europe Ltd.
Intended status: Informational S. Kiesel
Expires: April 28, 2011 University of Stuttgart
October 25, 2010
ALTO Deployment Considerations
draft-stiemerling-alto-deployments-05
Abstract
Many Internet applications are used to access resources, such as
pieces of information or server processes, which are available in
several equivalent replicas on different hosts. This includes, but
is not limited to, peer-to-peer file sharing applications. The goal
of Application-Layer Traffic Optimization (ALTO) is to provide
guidance to these applications, which have to select one or several
hosts from a set of candidates, that are able to provide a desired
resource. The protocol is under specification in the ALTO working
group. This memo discusses deployment related issues of ALTO for
peer-to-peer and CDNs, some preliminary security considerations, and
also initial guidance for application designers using ALTO.
Status of this Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF). Note that other groups may also distribute
working documents as Internet-Drafts. The list of current Internet-
Drafts is at http://datatracker.ietf.org/drafts/current/.
Internet-Drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
material or to cite them other than as "work in progress."
This Internet-Draft will expire on April 28, 2011.
Copyright Notice
Copyright (c) 2010 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
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(http://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.1. General Placement of ALTO . . . . . . . . . . . . . . . . 4
2.2. Provided Guidance . . . . . . . . . . . . . . . . . . . . 6
2.2.1. Keeping Traffic Local in Network . . . . . . . . . . . 6
2.2.2. Off-Loading Traffic from Network . . . . . . . . . . . 7
2.2.3. Intra-Network Localization/Bottleneck Off-Loading . . 8
3. Using ALTO for Peer-to-Peer . . . . . . . . . . . . . . . . . 11
3.1. Using ALTO for Tracker-based Peer-to-Peer Applications . . 13
3.2. Expectations of ALTO . . . . . . . . . . . . . . . . . . . 15
4. Using ALTO for CDNs . . . . . . . . . . . . . . . . . . . . . 16
5. Cascading ALTO Servers . . . . . . . . . . . . . . . . . . . . 17
6. Known Limitations of ALTO . . . . . . . . . . . . . . . . . . 19
6.1. Limitations of Map-based Approaches . . . . . . . . . . . 19
6.2. Limitiations of Non-Map-based Approaches . . . . . . . . . 20
6.3. General Challenges . . . . . . . . . . . . . . . . . . . . 20
7. API between ALTO Client and Application . . . . . . . . . . . 22
8. Security Considerations . . . . . . . . . . . . . . . . . . . 23
8.1. Information Leakage from the ALTO Server . . . . . . . . . 23
8.2. ALTO Server Access . . . . . . . . . . . . . . . . . . . . 23
8.3. Faking ALTO Guidance . . . . . . . . . . . . . . . . . . . 24
9. Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . 25
10. References . . . . . . . . . . . . . . . . . . . . . . . . . . 26
10.1. Normative References . . . . . . . . . . . . . . . . . . . 26
10.2. Informative References . . . . . . . . . . . . . . . . . . 26
Appendix A. Acknowledgments . . . . . . . . . . . . . . . . . . . 28
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 29
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1. Introduction
Many Internet applications are used to access resources, such as
pieces of information or server processes, which are available in
several equivalent replicas on different hosts. This includes, but
is not limited to, peer-to-peer file sharing applications and Content
Delivery Networks (CDNs). The goal of Application-Layer Traffic
Optimization (ALTO) is to provide guidance to applications, which
have to select one or several hosts from a set of candidates, that
are able to provide a desired resource. The basic ideas of ALTO are
described in the problem space of ALTO is described in [RFC5693] and
the set of requirements is discussed in [I-D.ietf-alto-reqs].
However, there are no considerations about what operational issues
are to be expected once ALTO will be deployed. This includes, but is
not limited to, location of the ALTO server, imposed load to the ALTO
server, or from whom the queries are performed.
Comments and discussions about this memo should be directed to the
ALTO working group: alto@ietf.org.
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2. Overview
The ALTO protocol is a client/server protocol, operating between a
number of ALTO clients and an ALTO server, as sketched in Figure 1.
The ALTO working groups defines the ALTO protocol
[I-D.ietf-alto-protocol].
+----------+
| ALTO |
| Server |
+----------+
^
_.-----|------.
,-'' | `--.
,' | `.
( Network | )
`. | ,'
`--. | _.-'
`------|-----''
v
+----------+ +----------+ +----------+
| ALTO | | ALTO |...| ALTO |
| Client | | Client | | Client |
+----------+ +----------+ +----------+
Figure 1: Network Overview of ALTO Protocol
2.1. General Placement of ALTO
The ALTO server and ALTO clients can be situated at various entities
in a network deployment. The first differentiation is whether the
ALTO client is located on the actual host that runs the application,
as shown in Figure 2, (e.g., peer-to-peer filesharing application) or
if the ALTO client is located on resource directory, as shown in
Figure 3 (e.g., a tracker in peer-to-peer filesharing).
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+-----+
=====| |**
==== +-----+ *
==== * *
==== * *
+-----+ +------+===== +-----+ *
| |.....| |======================| | *
+-----+ +------+===== +-----+ *
Source of ALTO ==== * *
topological service ==== * *
information ==== +-----+ *
=====| |**
+-----+
Legend:
=== ALTO client protocol
*** Application protocol
... Provisioning protocol
Figure 2: Overview of protocol interaction between ALTO
elements,scenario without tracker
Figure 2 shows the operational model for applications that do not use
a tracker, such as, edonky, or in if the tracker should be the
querying party. This use case also holds true for CDNs. The ALTO
server can also be queried by CDNs to get a guidance about where the
a particular client accessing data in the CDN is exactly located in
the ISP's network.
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+-----+
**| |**
** +-----+ *
** * *
** * *
+-----+ +------+ +-----+** +-----+ *
| |.....| |=====| |**********| | *
+-----+ +------+ +-----+** +-----+ *
Source of ALTO Resource ** * *
topological service directory ** * *
information ("tracker") ** +-----+ *
**| |**
+-----+
Peers
Legend:
=== ALTO client protocol
*** Application protocol
... Provisioning protocol
Figure 3: Overview of protocol interaction between ALTO elements,
scenario with tracker
However, Figure 3 does not denote where the ALTO elements are
actually located, i.e., if the tracker and the ALTO server are in the
same ISP's domain, or if the tracker and the ALTO server are managed/
owned/located in different domains. The latter is the typical use
case, e.g., taking Pirate Bay as example that serves Bittorrent peers
world-wide.
2.2. Provided Guidance
ALTO gives guidance to applications on what IP addresses or IP
prefixes, and such which hosts are to be preferred according to the
operator of the ALTO server. The general assumption of the ALTO WG
is that a network operator would always express to prefer hosts in
its own network while hosts located outside its own network are to be
avoided (are undesired to be considered by the applications). This
might be applicable in some cases but may not be applicable in the
general case. The ALTO protocol gives only the means to let the ALTO
server operator to express is preference, whatever this preference
is. This section explores this space.
2.2.1. Keeping Traffic Local in Network
ALTO guidance can be used to let applications prefer other peers
within the same network operator's network instead of randomly
connecting to other peers which are located in another operator's
network. Figure 4 shows such a scenario where peers prefer peers in
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the same network (e.g., Peer 1 and Peer 2 in ISP1 and Peer 3 and Peer
4 in ISP2).
,-------. +-----------+
,---. ,-' `-. | Peer 1 |
,-' `-. / ISP 1 ########|ALTO Client|
/ \ / # \ +-----------+
/ ISP X \ | # | +-----------+
/ \ \ ########| Peer 2 |
; +----------------------------|ALTO Client|
| | | `-. ,-' +-----------+
| | | `-------'
| | | ,-------. +-----------+
: | ; ,-' `########| Peer 3 |
\ | / / ISP 2 # \ |ALTO Client|
\ | / / # \ +-----------+
\ +---------+ # | +-----------+
`-. ,-' \ | ########| Peer 4 |
`---' \ +------------------|ALTO Client|
`-. ,-' +-----------+
`-------'
Legend:
### preferred "connections"
--- non-preferred "connections"
Figure 4: ALTO Traffic Network Localization
TBD: Describes limits of this approach (e.g., traffic localization
guidance is of less use if the peers cannot upload); describe how
maps would look like.
2.2.2. Off-Loading Traffic from Network
Another scenario where the use of ALTO can be beneficial is in mobile
broadband networks, e.g., CDMA200 or UMTS, but where the network
operator may have the desire to guide peers in its own network to use
peers in remote networks. One reason can be that the wireless
network is not made for the load cause by, e.g., peer-to-peer
applications, and the operator has the need that peers fetch their
data from remote peers in other parts of the Internet.
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,-------. +-----------+
,---. ,-' `-. | Peer 1 |
,-' `-. / ISP 1 +-------|ALTO Client|
/ \ / | \ +-----------+
/ ISP X \ | | | +-----------+
/ \ \ +-------| Peer 2 |
; #-###########################|ALTO Client|
| # | `-. ,-' +-----------+
| # | `-------'
| # | ,-------. +-----------+
: # ; ,-' `+-------| Peer 3 |
\ # / / ISP 2 | \ |ALTO Client|
\ # / / | \ +-----------+
\ ########### | | +-----------+
`-. ,-' \ # +-------| Peer 4 |
`---' \ ###################|ALTO Client|
`-. ,-' +-----------+
`-------'
Legend:
=== preferred "connections"
--- non-preferred "connections"
Figure 5: ALTO Traffic Network De-Localization
Figure 5 shows the result of such a guidance process where Peer 2
prefers a connection with Peer4 instead of Peer 1, as shown in
Figure 4.
TBD: Limits of this approach in general and with respect to p2p.
describe how maps would look like.
2.2.3. Intra-Network Localization/Bottleneck Off-Loading
The above sections described the results of the ALTO guidance on an
inter-network level. However, ALTO can also be used to guide peers
on which internal peers are to be preferred. For instance, to guide
Peers on a remote network side to prefer to connect to each other,
instead of crossing a bottleneck link, a backhaul link to connect the
side to the network core. Figure 6 shows such a scenario where Peer
1 and Peer 2 are located in Net 2 of ISP1 and connect via a low
capacity link to the core (Net 1) of the same ISP1. Peer1 and Peer 2
would both exchange their data with remote peers, probably clogging
the bottleneck link.
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,-------. +-----------+
,---. ,-' `-. | Peer 1 |
,-' `-. / ISP 1 #########|ALTO Client|
/ \ / Net 2 # \ +-----------+
/ ISP 1 \ | ######### | +-----------+
/ Net 1 \ \ # / | Peer 2 |
; ###; \ # ##########|ALTO Client|
| X~~~~~~~~~~~~X#######,-' +-----------+
| ### | ^ `-------'
| | |
: ; |
\ / Bottleneck
\ /
\ /
`-. ,-'
`---'
Legend:
### peer "connections"
~~~ bottleneck link
Figure 6: Without Intra-Network ALTO Traffic Localization
The operator can guide the peers in such a situation to try first
local peers in the same network islands, avoiding or at least
lowering the effect on the bottleneck link, as shown in Figure 7.
,-------. +-----------+
,---. ,-' `-. | Peer 1 |
,-' `-. / ISP 1 #########|ALTO Client|
/ \ / Net 2 # \ +-----------+
/ ISP 1 \ | # | +-----------+
/ Net 1 \ \ #########| Peer 2 |
; ; \ ##########|ALTO Client|
| #~~~~~~~~~~~########,-' +-----------+
| ### | ^ `-------'
| | |
: ; |
\ / Bottleneck
\ /
\ /
`-. ,-'
`---'
Legend:
### peer "connections"
~~~ bottleneck link
Figure 7: With Intra-Network ALTO Traffic Localization
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TBD: describe how maps would look like.
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3. Using ALTO for Peer-to-Peer
,-------.
,---. ,-' `-. +-----------+
,-' `-. / ISP 1 \ | Peer 1 |*****
/ \ / +-------------+ \ | | *
/ ISP X \ +=====>+ ALTO Server | )+-----------+ *
/ \ = \ +-------------+ / +-----------+ *
; +-----------+ : = \ / | Peer 2 | *
| | Tracker |<====+ `-. ,-' | |*****
| |ALTO Client|<====+ `-------' +-----------+ **
| +-----------+ | = ,-------. **
: * ; = ,-' `-. +-----------+ **
\ * / = / ISP 2 \ | Peer 3 | **
\ * / = / +-------------+ \ | |*****
\ * / +=====>| ALTO Server | )+-----------+ ***
`-. * ,-' \ +-------------+ / +-----------+ ***
`-*-' \ / | Peer 4 |*****
* `-. ,-' | | ****
* `-------' +-----------+ ****
* ****
* ****
***********************************************<******
Legend:
=== ALTO client protocol
*** Application protocol
Figure 8: Global tracker accessing ALTO server at various ISPs
Figure 8 depicts a tracker-based system, where the tracker embeds the
ALTO client. The tracker itself is hosted and operated by an entity
different than the ISP hosting and operating the ALTO server.
Initially, the tracker has to look-up the ALTO server in charge for
each peer where it receives a ALTO query for. Therefore, the ALTO
server has to discover the handling ALTO server, as described in
[I-D.kiesel-alto-3pdisc]. However, the peers do not have any way to
query the server themselves. This setting allows to give the peers a
better selection of candidate peers for their operation at an initial
time, but does not consider peers learned through direct peer-to-peer
knowledge exchange, AKA peer exchange in various peer-to-peer
protocols.
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,-------. +-----------+
,---. ,-' `-. +==>| Peer 1 |*****
,-' `-. / ISP 1 \ = |ALTO Client| *
/ \ / +-------------+<=+ +-----------+ *
/ ISP X \ | + ALTO Server |<=+ +-----------+ *
/ \ \ +-------------+ /= | Peer 2 | *
; +---------+ : \ / +==>|ALTO Client|*****
| | Global | | `-. ,-' +-----------+ **
| | Tracker | | `-------' **
| +---------+ | ,-------. +-----------+ **
: * ; ,-' `-. +==>| Peer 3 | **
\ * / / ISP 2 \ = |ALTO Client|*****
\ * / / +-------------+<=+ +-----------+ ***
\ * / | | ALTO Server |<=+ +-----------+ ***
`-. * ,-' \ +-------------+ /= | Peer 4 |*****
`-*-' \ / +==>|ALTO Client| ****
* `-. ,-' +-----------+ ****
* `-------' ****
* ****
***********************************************<****
Legend:
=== ALTO client protocol
*** Application protocol
Figure 9: Global Tracker - Local ALTO Servers
The scenario in Figure 9 lets the peers directly communicate with
their ISP's ALTO server (i.e., ALTO client embedded in the peers),
giving thus the peers the most control on which information they
query for, as they can integrate information received from trackers
and through direct peer-to-peer knowledge exchange.
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,-------. +-----------+
,---. ,-' ISP 1 `-. ***>| Peer 1 |
,-' `-. /+-------------+\ * | |
/ \ / + Tracker |<** +-----------+
/ ISP X \ | +-----===-----+<** +-----------+
/ \ \ +-----===-----+ /* | Peer 2 |
; +---------+ : \+ ALTO Server |/ ***>| |
| | Global | | +-------------+ +-----------+
| | Tracker | | `-------'
| +---------+ | +-----------+
: ^ ; ,-------. | Peer 3 |
\ * / ,-' ISP 2 `-. ***>| |
\ * / /+-------------+\ * +-----------+
\ * / / + Tracker |<** +-----------+
`-. *,-' | +-----===-----+ | | Peer 4 |<*
`---* \ +-----===-----+ / | | *
* \+ ALTO Server |/ +-----------+ *
* +-------------+ *
* `-------' *
***********************************************
Legend:
=== ALTO client protocol
*** Application protocol
Figure 10: P4P approach with local tracker and local ALTO server
There are some attempts to let ISP's to deploy their own trackers, as
shown in Figure 10. In this case, the client has no chance to get
guidance from the ALTO server, other than talking to the ISP's
tracker. However, the peers would have still chance the contact
other trackers, deployed by entities other than the peer's ISP.
Figure 10 and Figure 8 ostensibly take peers the possibility to
directly query the ALTO server, if the communication with the ALTO
server is not permitted for any reason. However, considering the
plethora of different applications of ALTO, e.g., multiple tracker
and non-tracker based P2P systems and or applications searching for
relays, it seems to be beneficial for all participants to let the
peers directly query the ALTO server. The peers are also the single
point having all operational knowledge to decide whether to use the
ALTO guidance and how to use the ALTO guidance. This is a preference
for the scenario depicted in Figure Figure 9.
3.1. Using ALTO for Tracker-based Peer-to-Peer Applications
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............................. .............................
: Tracker : : Peer :
: ______ : : :
: +-______-+ : : k good :
: | | +--------+ : P2P App. : +--------+ peers +------+ :
: | N | | random | : Protocol : | ALTO- |------>| data | :
: | known |====>| pre- |*************>| biased | | ex- | :
: | peers, | | selec- | : transmit : | peer |------>| cha- | :
: | M good | | tion | : n peer : | select | n-k | nge | :
: +-______-+ +--------+ : IDs : +--------+ bad p.+------+ :
:...........................: :.....^.....................:
|
| ALTO
| client protocol
__|___
+-______-+
| |
| ALTO |
| server |
+-______-+
Figure 11: Tracker-based P2P Application with random peer
preselection
............................. .............................
: Tracker : : Peer :
: ______ : : :
: +-______-+ : : :
: | | +--------+ : P2P App. : k good peers & +------+ :
: | N | | ALTO- | : Protocol : n-k bad peers | data | :
: | known |====>| biased |******************************>| ex- | :
: | peers, | | peer | : transmit : | cha- | :
: | M good | | select | : n peer : | nge | :
: +-______-+ +--------+ : IDs : +------+ :
:.....................^.....: :...........................:
|
| ALTO
| client protocol
__|___
+-______-+
| |
| ALTO |
| server |
+-______-+
Figure 12: Tracker-based P2P Application with ALTO client in tracker
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TBD: explain why Figure 12 usually will yield better results wrt.
peer selection than Figure 11.
3.2. Expectations of ALTO
This section hints to some recent experiments conducted with ALTO-
like deployments in Internet Service Provider (ISP) network's. NTT
performed tests with their HINT server implementation and dummy nodes
to gain insight on how an ALTO-like service influence a peer-to-peer
systems [I-D.kamei-p2p-experiments-japan]. The results of an early
experiment conducted in the Comcast network are documented
here[RFC5632]
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4. Using ALTO for CDNs
Section 3 discussed the placement and usage of ALTO for P2P systems,
but not beyond. This section discuss the usage of ALTO for Content
Delivery Networks (CDNs). CDNs are used to bring a service (e.g., a
web page, videos, etc) closer to the location of the user - where
close refers to shorten the distance between the client and the
server in the IP topology. CDNs use several techniques to decide
which server is closest to a client requesting a service. One common
way to do so, is relying on the DNS system, but there are many other
ways, see [RFC3568].
The general issue for CDNs, independent of DNS or HTTP Redirect based
approaches (see, for instance, [I-D.penno-alto-cdn]), is that the CDN
logic has to match the client's IP address with the closest CDN
cache. This matching is not trivial, for instance, in DNS based
approaches, where the IP address of the DNS original requester is
unknown (see [I-D.vandergaast-edns-client-ip] for a discussion of
this and a solution approach).
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5. Cascading ALTO Servers
The main assumptions of ALTO seems to be each ISP operates its own
ALTO server independently, irrespectively of the ISP's situation.
This may true for most envisioned deployments of ALTO but there are
certain deployments that may have different settings. Figure 13
shows such setting, were for example, a university network is
connected to two upstream providers. ISP2 if the national research
network and ISP1 is a commercial upstream provider to this university
network. The university, as well as ISP1, are operating their own
ALTO server. The ALTO clients, located on the peers will contact the
ALTO server located at the university.
+-----------+
| ISP1 |
| ALTO |
| Server |
+----------=+
,-------= ,------.
,-' =`-. ,-' `-.
/ Upstream= \ / Upstream \
( ISP1 = ) ( ISP2 )
\ = / \ /
`-. =,-' `-. ,-'
`---+---= `+------'
| = |
| =======================
|,-------------. | =
,-+ `-+ +-----------+
,' University `. |University |
( Network ) | ALTO |
`. =======================| Server |
`-= +-' +-----------+
=`+------------'|
= | |
+--------+-+ +-+--------+
| Peer1 | | PeerN |
+----------+ +----------+
Figure 13: Cascaded ALTO Server
In this setting all "destinations" useful for the peers within ISP2
are free-of-charge for the peers located in the university network
(i.e., they are preferred in the rating of the ALTO server).
However, all traffic that is not towards ISP2 will be handled by the
ISP1 upstream provider. Therefore, the ALTO server at the university
has also to include the guidance given by the ISP1 ALTO server in its
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replies to the ALTO clients. This can be called cascaded ALTO
servers.
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6. Known Limitations of ALTO
This section describes some known limitations of ALTO in general or
specific mechanisms in ALTO.
6.1. Limitations of Map-based Approaches
The specification of the ALTO protocol [I-D.ietf-alto-protocol] uses,
amongst others mechanism, so-called network maps. The network map
approach uses Host Group Descriptors that group one or multiple
subnetworks (i.e., IP prefixes) to a single Host Group Descriptor. A
set of IP prefixes is called partition and the associated Host Group
Descriptor is called partition ID. The "costs" between the various
partition IDs is stored in a second map, the cost map. Map-based
approaches are chosen as they lower the signaling load on the server,
as the maps have only to be retrieved if they are changed.
The main assumption for map-based approaches is that the information
provided in these maps is static for a longer period of time, where
this period of time refers to days, but not hours or even minutes.
This assumption is fine, as long as the network operator does not
change any parameter, e.g., routing within the network and to the
upstream peers, IP address assignment stays stable (and thus the
mapping to the partitions). However, there are several cases where
this assumption is not valid, as:
1. ISPs reallocate IPv4 subnets from time to time;
2. ISPs reallocate IPv4 subnets on short notice;
3. IP prefix blocks may be assigned to a single DSLAM which serves a
variety of access networks.
For 1): ISPs reallocate IPv4 subnets within their infrastructure from
time to time, partly to ensure the efficient usage of IPv4 addresses
(a scarce resource), and partly to enable efficient route tables
within their network routers. The frequency of these "renumbering
events" depend on the growth in number of subscribers and the
availability of address space within the ISP. As a result, a
subscriber's household device could retain an IPv4 address for as
short as a few minutes, or for months at a time or even longer.
Some folks have suggested that ISPs providing ALTO services could
sub-divide their subscribers' devices into different IPv4 subnets
(or certain IPv4 address ranges) based on the purchased service
tier, as well as based on the location in the network topology.
The problem is that this sub-allocation of IPv4 subnets tends to
decrease the efficiency of IPv4 address allocation. A growing ISP
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that needs to maintain high efficiency of IPv4 address utilization
may be reluctant to jeopardize their future acquisition of IPv4
address space.
However, this is not an issue for map-based approaches if changes are
applied in the order of days.
For 2): ISPs can use techniques, such as ODAP (XXX) that allow the
reallocation of IP prefixes on very short notice, i.e., within
minutes. An IP prefix that has no IP address assignment to a host
anymore can be reallocate to areas where there is currently a high
demand for IP addresses.
For 3): In DSL-based access networks, IP prefixes are assigned to
DSLAMs which are the first IP-hop in the access-network between the
CPE and the Internet. The access-network between CPE and DSLAM
(called aggregation network) can have varying characteristics (and
thus associated costs), but still using the same IP prefix. For
instance one IP addresses IP11 out of a IP prefix IP1 can be assigned
to a VDSL (e.g., 2 MBit/s uplink) access-line while the subsequent IP
address IP12 is assigned to a slow ADSL line (e.g., 128 kbit/s
uplink). These IP addresses are assigned on a first come first
served basis, i.e., the a single IP address out of the same IP prefix
can change its associated costs quite fast. This may not be an issue
with respect to the used upstream provider (thus the cross ISP
traffic) but depending on the capacity of the aggregation-network
this may raise to an issue.
6.2. Limitiations of Non-Map-based Approaches
The specification of the ALTO protocol [I-D.ietf-alto-protocol] uses,
amongst others mechanism, a mechanism called Endpoint Cost Service.
ALTO clients can ask guidance for specific IP addresses to the ALTO
server. However, asking for IP addresses, asking with long lists of
IP addresses, and asking quite frequent may overload the ALTO server.
The server has to rank each received IP address which causes load at
the server. This may be amplified by the fact that not only a single
ALTO client is asking for guidance, but a larger number of them.
Caching of IP addresses at the ALTO client or the usage of the H12
approach [I-D.kiesel-alto-h12] in conjunction with caching may lower
the query load on the ALTO server.
6.3. General Challenges
An ALTO server stores information about preferences (e.g., a list of
preferred autonomous systems, IP ranges, etc) and ALTO clients can
retrieve these preferences. However, there are basically two
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different approaches on where the preferences are actually processed:
1. The ALTO server has a list of preferences and clients can
retrieve this list via the ALTO protocol. This preference list
can be partially updated by the server. The actual processing of
the data is done on the client and thus there is no data of the
client's operation revealed to the ALTO server .
2. The ALTO server has a list of preferences or preferences
calculated during runtime and the ALTO client is sending
information of its operation (e.g., a list of IP addresses) to
the server. The server is using this operational information to
determine its preferences and returns these preferences (e.g., a
sorted list of the IP addresses) back to the ALTO client.
Approach 1 (we call it H1) has the advantage (seen from the client)
that all operational information stays within the client and is not
revealed to the provider of the server. On the other hand, does
approach 1 require that the provider of the ALTO server, i.e., the
network operator, reveals information about its network structure
(e.g., AS numbers, IP ranges, topology information in general) to the
ALTO client.
Approach 2 (we call it H2) has the advantage (seen from the operator)
that all operational information stays with the ALTO server and is
not revealed to the ALTO client. On the other hand, does approach 2
require that the clients send their operational information to the
server.
Both approaches have their pros and cons and are extensively
discussed on the ALTO mailing list. But there is basically a
dilemma: Approach 1 is seen as the only working solution by peer-to-
peer software vendors and approach 2 is seen as the only working by
the network operators. But neither the software vendors nor the
operators seem to willing to change their position. However, there
is the need to get both sides on board, to come to a solution.
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7. API between ALTO Client and Application
This sections gives some informational guidance on how the interface
between the actual application using the ALTO guidance and the ALTO
client can look like.
This is still TBD.
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8. Security Considerations
The ALTO protocol itself, as well as, the ALTO client and server
raise new security issues beyond the one mentioned in
[I-D.ietf-alto-protocol] and issues related to message transport over
the Internet. For instance, Denial of Service (DoS) is of interest
for the ALTO server and also for the ALTO client. A server can get
overloaded if too many TCP requests hit the server, or if the query
load of the server surpasses the maximum computing capacity. An ALTO
client can get overloaded if the responses from the sever are, either
intentionally or due to an implementation mistake, too large to be
handled by that particular client.
8.1. Information Leakage from the ALTO Server
The ALTO server will be provisioned with information about the owning
ISP's network and very likely also with information about neighboring
ISPs. This information (e.g., network topology, business relations,
etc) is consider to be confidential to the ISP and must not be
revealed.
The ALTO server will naturally reveal parts of that information in
small doses to peers, as the guidance given will depend on the above
mentioned information. This is seen beneficial for both parties,
i.e., the ISP's and the peer's. However, there is the chance that
one or multiple peers are querying an ALTO server with the goal to
gather information about network topology or any other data
considered confidential or at least sensitive. It is unclear whether
this is a real technical security risk or whether this is more a
perceived security risk.
8.2. ALTO Server Access
Depending on the use case of ALTO, several access restrictions to an
ALTO server may or may not apply. For an ALTO server that is solely
accessible by peers from the ISP network (as shown in Figure 9), for
instance, the source IP address can be used to grant only access from
that ISP network to the server. This will "limit" the number of
peers able to attack the server to the user's of the ISP (however,
including botnet computers).
On the other hand, if the ALTO server has to be accessible by parties
not located in the ISP's network (see Figure Figure 8), e.g., by a
third-party tracker or by a CDN system outside the ISP's network, the
access restrictions have to be more loose. In the extreme case,
i.e., no access restrictions, each and every host in the Internet can
access the ALTO server. This might no the intention of the ISP, as
the server is not only subject to more possible attacks, but also on
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the load imposed to the server, i.e., possibly more ALTO clients to
serve and thus more work load.
8.3. Faking ALTO Guidance
It has not yet been investigated how a faked or wrong ALTO guidance
by an ALTO server can impact the operation of the network and also
the peers.
Here is a list of examples how the ALTO guidance could be faked and
what possible consequences may arise:
Sorting An attacker could change to sorting order of the ALTO
guidance (given that the order is of importance, otherwise the
ranking mechanism is of interest), i.e., declaring peers located
outside the ISP as peers to be preferred. This will not pose a
big risk to the network or peers, as it would mimic the "regular"
peer operation without traffic localization, apart from the
communication/processing overhead for ALTO. However, it could
mean that ALTO is reaching the opposite goal of shuffling more
data across ISP boundaries, incurring more costs for the ISP.
Preference of a single peer A single IP address (thus a peer) could
be marked as to be preferred all over other peers. This peer can
be located within the local ISP or also in other parts of the
Internet (e.g., a web server). This could lead to the case that
quite a number of peers to trying to contact this IP address,
possibly causing a Denial of Service (DoS) attack.
This section is solely giving a first shot on security issues related
to ALTO deployments.
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9. Conclusion
This is the first version of the deployment considerations and for
sure the considerations are yet incomplete and imprecise.
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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.
[RFC3568] Barbir, A., Cain, B., Nair, R., and O. Spatscheck, "Known
Content Network (CN) Request-Routing Mechanisms",
RFC 3568, July 2003.
10.2. Informative References
[I-D.ietf-alto-protocol]
Alimi, R., Penno, R., and Y. Yang, "ALTO Protocol",
draft-ietf-alto-protocol-05 (work in progress), July 2010.
[I-D.ietf-alto-reqs]
Kiesel, S., Previdi, S., Stiemerling, M., Woundy, R., and
Y. Yang, "Application-Layer Traffic Optimization (ALTO)
Requirements", draft-ietf-alto-reqs-06 (work in progress),
October 2010.
[I-D.kamei-p2p-experiments-japan]
Kamei, S., Momose, T., Inoue, T., and T. Nishitani, "ALTO-
Like Activities and Experiments in P2P Network Experiment
Council", draft-kamei-p2p-experiments-japan-03 (work in
progress), May 2010.
[I-D.kiesel-alto-3pdisc]
Kiesel, S., Tomsu, M., Schwan, N., Scharf, M., and M.
Stiemerling, "Third-party ALTO server discovery",
draft-kiesel-alto-3pdisc-03 (work in progress), July 2010.
[I-D.kiesel-alto-h12]
Kiesel, S. and M. Stiemerling, "ALTO H12",
draft-kiesel-alto-h12-02 (work in progress), March 2010.
[I-D.penno-alto-cdn]
Penno, R., Raghunath, S., Medved, J., Bakshi, M., Alimi,
R., and S. Previdi, "ALTO and Content Delivery Networks",
draft-penno-alto-cdn-01 (work in progress), July 2010.
[I-D.vandergaast-edns-client-ip]
Contavalli, C., Gaast, W., Leach, S., and D. Rodden,
"Client IP information in DNS requests",
draft-vandergaast-edns-client-ip-01 (work in progress),
May 2010.
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[RFC5632] Griffiths, C., Livingood, J., Popkin, L., Woundy, R., and
Y. Yang, "Comcast's ISP Experiences in a Proactive Network
Provider Participation for P2P (P4P) Technical Trial",
RFC 5632, September 2009.
[RFC5693] Seedorf, J. and E. Burger, "Application-Layer Traffic
Optimization (ALTO) Problem Statement", RFC 5693,
October 2009.
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Appendix A. Acknowledgments
Martin Stiemerling is partially supported by the NAPA-WINE project
(Network-Aware P2P-TV Application over Wise Networks,
http://www.napa-wine.org), a research project supported by the
European Commission under its 7th Framework Program (contract no.
214412). The views and conclusions contained herein are those of the
authors and should not be interpreted as necessarily representing the
official policies or endorsements, either expressed or implied, of
the NAPA-WINE project or the European Commission.
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Authors' Addresses
Martin Stiemerling
NEC Laboratories Europe/University of Goettingen
Kurfuerstenanlage 36
Heidelberg 69115
Germany
Phone: +49 6221 4342 113
Fax: +49 6221 4342 155
Email: martin.stiemerling@neclab.eu
URI: http://ietf.stiemerling.org
Sebastian Kiesel
University of Stuttgart, Computing Center
Allmandring 30
Stuttgart 70550
Germany
Email: ietf-alto@skiesel.de
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