Peer-specific Redirection for Traversal Using Relays around NAT (TURN)
draft-williams-peer-redirect-02
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| Document | Type | Active Internet-Draft (individual) | |
|---|---|---|---|
| Authors | Brandon Williams , Tirumaleswar Reddy.K | ||
| Last updated | 2014-12-29 | ||
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draft-williams-peer-redirect-02
Network Working Group B. Williams
Internet-Draft Akamai
Intended status: Standards Track T. Reddy
Expires: July 2, 2015 Cisco
December 29, 2014
Peer-specific Redirection for Traversal Using Relays around NAT (TURN)
draft-williams-peer-redirect-02
Abstract
This specification describes a peer-specific redirection method that
allows the TURN server to redirect a client for the purpose of
improving communication with a specific peer without negatively
affecting communication with other peers.
Status of this Memo
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provisions of BCP 78 and BCP 79.
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This Internet-Draft will expire on July 2, 2015.
Copyright Notice
Copyright (c) 2014 IETF Trust and the persons identified as the
document authors. All rights reserved.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Redirection for Performance . . . . . . . . . . . . . . . 3
1.2. Redirection for Load Balancing . . . . . . . . . . . . . . 5
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 5
3. Peer-specific Server Redirect Mechanism . . . . . . . . . . . 5
3.1. Attribute Usage . . . . . . . . . . . . . . . . . . . . . 5
3.2. Sending a CreatePermission or ChannelBind Request . . . . 7
3.2.1. The CHECK-ALTERNATE Attribute . . . . . . . . . . . . 7
3.2.2. The XOR-OTHER-ADDRESS attribute . . . . . . . . . . . 8
3.3. Receiving a CreatePermission or ChannelBind Request . . . 8
3.4. Receiving a CreatePermission or ChannelBind Error
Response . . . . . . . . . . . . . . . . . . . . . . . . . 9
3.5. Receiving a CreatePermission or ChannelBind Success
Response . . . . . . . . . . . . . . . . . . . . . . . . . 10
4. Security Considerations . . . . . . . . . . . . . . . . . . . 10
4.1. CHECK-ALTERNATE Flood . . . . . . . . . . . . . . . . . . 11
4.2. Unsolicited or Invalid ALTERNATE-SERVER . . . . . . . . . 11
5. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 12
6. References . . . . . . . . . . . . . . . . . . . . . . . . . . 12
6.1. Normative References . . . . . . . . . . . . . . . . . . . 12
6.2. Informative References . . . . . . . . . . . . . . . . . . 12
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 13
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1. Introduction
A Traversal Using Relay around NAT (TURN) [RFC5766] service provider
may provide multiple candidate TURN servers for use by a host, but it
might not possible to determine which candidate TURN server will
provide the best performance until both peers have been identified.
This could be true for a variety of reasons, including:
o Using the selected relay for a specific peer results in a sub-
optimal end-to-end Internet path.
o Load conditions on the selected relay have changed since the
allocation was established such that it cannot support the new
data flow.
At the same time, the above conditions might apply to one peer but
not another, such that it would be best to selectively use the
existing relay allocation for peers that will receive reasonable
performance and redirect data flows for other peers to an alternate
server. These scenarios are discussed in greater detail below.
The Session Traversal Utilities for NAT (STUN) protocol [RFC5389]
defines an ALTERNATE-SERVER mechanism with which a server can
redirect a client to another server by replying to a request message
with an error response with error code 300 (Try Alternate). The TURN
protocol describes error code 300 as one of the possible error codes
for an Allocate error response.
This specification describes an additional use of the ALTERNATE-
SERVER STUN attribute for TURN that allows the TURN server to
redirect a client for the purpose of improving communication with a
specific peer without negatively affecting communication with other
peers. The client application indicates the nature of the desired
response, which allows the client to treat the alternate server
selection as either a requirement or a suggestion. This flexibility
gives the client the option to choose the best way for the
Interactive Connectivity Establishment (ICE) protocol [RFC5245] to
respond (e.g. discarding the existing relay candidate for
communication with this peer versus evaluating the two candidate
servers using ICE connectivity checks and selecting the best one).
1.1. Redirection for Performance
Consider the following example:
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Boston
Peer C
Chicago [PC]
Peer B /
TURN Relay A ----------[PB]-------------[TC]
San Francisco ----------/ TURN Relay C
[TA]----------/ New York
|
[PA]
Peer A
Los Angeles
When Peer B wishes to communicate with either Peer A or Peer C, it
performs a DNS lookup and discovers TURN Relay C, the nearest of the
candidate TURN servers. Peer B then sends a TURN Allocate request to
TURN Relay C to determine the reflexive and relay candidates to
offer. After the reflexive candidate has been chosen, Peer B sends a
ChannelBind request to TURN Relay C to establish a channel for
communication with the peer. If Peer C is the remote peer, the
existing allocation will perform reasonably well, but if Peer A is
the remote peer, the latency for relayed packets will be nearly twice
as long as if TURN Relay A had been selected as the relay candidate.
The problem is worse if Peer B wishes to communicate with both Peer A
and Peer C, since there is no single relay candidate that would
provide optimum performance for both peers.
If TURN Relay C and TURN Relay A are part of a common TURN service,
it would be possible for TURN Relay C to determine that TURN Relay A
will provide optimal service for communication between Peer B and
Peer A. This allows the TURN service to redirect just the data
channel between Peer A and Peer B to TURN relay A, thus providing
optimal performance for both relay channels.
The above example describes the problem in terms of physical
geography instead of network geography in order to help clarify the
discussion. However, readers should note that the problem of
selecting a relay server to achieve optimal end-to-end routing is
much more complicated than the above description suggests, requiring
a detailed real-time view of network connectivity characteristics and
the peering relationships between autonomous systems. A naive
approach based solely on the physical location of the hosts involved
is just as likely to produce negative results as positive ones.
That said, a relay service provider with a broadly distributed system
for actively monitoring network performance across the relevant parts
of the Internet could make use of the resulting data set to select
the optimal relay for each peer pair.
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1.2. Redirection for Load Balancing
At the point when a relay allocation is first established, it can be
difficult to determine how much aggregate concurrent load could
eventually be associated with that allocation. The initiating peer
could attempt to use that allocation for any number of peer-to-peer
data flows over an extended period of time, during which time load
conditions on the relay could change substantially, such that quality
of service for already established flows would degrade if the relay
were to accept additional flows.
Under these conditions, a TURN service provider with multiple relay
hosts and distributed capacity could improve service quality by
redirecting data flows to a different host that has more available
capacity. At the same time, it is desirable to avoid disrupting
established data flows by continuing to handle established flows on
the current relay and only redirecting new flows elsewhere.
2. Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC2119].
3. Peer-specific Server Redirect Mechanism
This specification describes two new uses of the existing STUN
ALTERNATE-SERVER attribute. In the first case, the ALTERNATE-SERVER
attribute is included with either a CreatePermission error response
or a ChannelBind error response. In the second case, the ALTERNATE-
SERVER attribute is included with either a CreatePermission success
response or a ChannelBind success response.
This specification also defines two new comprehension-optional STUN
attributes: CHECK-ALTERNATE and XOR-OTHER-ADDRESS. The CHECK-
ALTERNATE attribute is used by the client to request that the server
perform peer-specific redirection. The XOR-OTHER-ADDRESS is used by
the client to provide an alternate peer address for location
identification in the event that the XOR-PEER-ADDRESS attribute in
the CreatePermission or ChannelBind request is not expected to
reliably serve this purpose.
3.1. Attribute Usage
When sending a CreatePermission or a ChannelBind request, the CHECK-
ALTERNATE STUN attribute allows a TURN client to indicate support for
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peer-specific server redirection. To maintain backward compatibility
with [RFC5766] compliant TURN servers that do not support peer-
specific redirection, this attribute is defined as comprehension-
optional, which allows a TURN server that does not support peer-
specific redirection to ignore the attribute. To maintain backward
compatibility with [RFC5766] compliant TURN clients that do not
support peer-specific redirection, a TURN server only sends the
ALTERNATE-SERVER attribute in CreatePermission and ChannelBind
responses when the CHECK-ALTERNATE STUN attribute was present in the
request. This prevents transmission of the ALTERNATE-SERVER
attribute in cases where the receiving client might not consider the
usage legitimate.
The CHECK-ALTERNATE STUN attribute's value indicates the expected
server response type: error or success. This capability to declare
the expected response type allows TURN client implementers greater
flexibility during session establishment. For example, a TURN client
implementer may wish to maintain the smallest number of permissions
possible during session establishment in order keep the internal
client implementation simple, in which case an error response would
be desirable. On the other hand, a TURN client implementer may wish
to optimize for faster session establishment by continuing to use a
sub-optimal allocation while setting up the new one, in which case a
success response would be desirable. This second case could be
achieved with an error response if the client were to send a second
request without the CHECK-ALTERNATE attribute, but such an approach
would require an extra RTT.
The XOR-OTHER-ADDRESS STUN attribute allows the TURN client to
provide an alternate peer address that can be used by the server to
identify the network geographic location of the peer when performing
the peer-specific redirection check. Use of this attribute is only
necessary if the XOR-PEER-ADDRESS already contained in the
CreatePermission or ChannelBind request does not adequately serve
this purpose, which should only be true when both peers require a
TURN relay for end-to-end data flow. In this case, the TURN
CreatePermission or ChannelBind request will provide the peer's TURN
relay address as the XOR-PEER-ADDRESS value. If the RTT between the
peer and its TURN relay server is very small, the TURN relay address
might still be an appropriate address to use for the peer-specific
redirection check. As the RTT grows, the TURN relay address will
become less suitable for this purpose. For this reason, it is
generally the case that the peer's public address (i.e. its host or
reflexive address) is a better indication of its network geographic
location than its TURN relay address.`
Even in cases where both peers require a TURN relay, a typical ICE
protocol implementation will give higher candidate priority to the
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peer's host and reflexive addresses, which means that the first
CreatePermission or ChannelBind request will provide the peer's
public address as the XOR-PEER-ADDRESS value and no XOR-OTHER-ADDRESS
attribute is necessary. However, although ICE recommends this
priority, it does not require it, and so the first request may
contain the peer's TURN relay address. With such an implementation,
the XOR-OTHER-ADDRESS attribute allows the client to provide the
peer's reflexive address in a request that populates the XOR-PEER-
ADDRESS attribute with the peer's relay address.
3.2. Sending a CreatePermission or ChannelBind Request
A client that supports peer-specific server redirection and desires
such redirection to be performed MUST include the CHECK-ALTERNATE
attribute in the first CreatePermission or ChannelBind request when
that request is expected to form a new permission or binding. A
client MUST NOT include the CHECK-ALTERNATE attribute in a
CreatePermission or ChannelBind request that is intended to extend
the lifetime of an existing permission or binding.
Peer-specific server redirection is only supported for requests that
include a single XOR-PEER-ADDRESS attribute. When forming a
CreatePermission request with multiple XOR-PEER-ADDRESS attributes,
the client MUST NOT include the CHECK-ALTERNATE attribute.
When the CreatePermission or ChannelBind request includes the CHECK-
ALTERNATE attribute, the client MAY also include an XOR-OTHER-ADDRESS
attribute with a value appropriate for the above described purpose.
The XOR-OTHER-ADDRESS attribute SHOULD NOT be included in the request
if its value will be identical to the request's XOR-PEER-ADDRESS
attribute.
3.2.1. The CHECK-ALTERNATE Attribute
When forming a CHECK-ALTERNATE attribute, the STUN Type is TBD-CA.
This type is in the comprehension-optional range, which means that
STUN agents can safely ignore the attribute if they do not understand
it.
The CHECK-ALTERNATE attribute takes a 1-byte Value, which means that
the Length is 1 and 3 bytes of padding are required after the Value.
The format of the Value is:
0
0 1 2 3 4 5 6 7
+-+-+-+-+-+-+-+-+
|E| RFFU |
+-+-+-+-+-+-+-+-+
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The Value contains a single 1-bit flag:
E: If 1, the server is requested to send a Try Alternate (300) error
response when redirection is expected. If 0, the server is
request to include an ALTERNATE-SERVER attribute in the success
response for the request.
The other 7 bits of the attribute's value must be set to zero on
transmission and ignored on reception.
3.2.2. The XOR-OTHER-ADDRESS attribute
When forming an XOR-OTHER-ADDRESS attribute, the STUN Type is TBD-
XOA. This type is in the comprehension-optional range, which means
that STUN agents can safely ignore the attribute if they do not
understand it.
The XOR-OTHER-ADDRESS value specifies an address and port suitable
for identification of the peer's network geographic location. It is
encoded in the same way as XOR-MAPPED-ADDRESS [RFC5389].
3.3. Receiving a CreatePermission or ChannelBind Request
When a server receives a CreatePermission or ChannelBind request that
includes a CHECK-ALTERNATE attribute, it processes as per the TURN
specification [RFC5766] plus the specific rules mentioned here.
The server checks the following:
o If the CHECK-ALTERNATE attribute is not recognized, ignore the
attribute because its type indicates that it is comprehension-
optional. This should be the existing behavior.
o If the message is a CreatePermission request with multiple XOR-
PEER-ADDRESS attributes, ignore the CHECK-ALTERNATE attribute if
present.
o If peer-specific redirection is not supported by the server,
ignore the attribute.
o If the associated permission or binding already exists, ignore the
attribute.
If none of the above causes the attribute to be ignored and no other
cause for sending an error response has been found, the server
attempts to identify an alternate server that will provide better
performance for the session based on the criteria supported by the
TURN service (e.g. optimal data path and/or load balancing). When an
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XOR-OTHER-ADDRESS attribute is found in the request message, the
server SHOULD use this address for peer location identification.
Otherwise, the server SHOULD use the address provided in the XOR-
PEER-ADDRESS attribute.
If no alternate server is identified, the server replies with a
success response that does not include an ALTERNATE-SERVER attribute.
If an alternate server is identified and the client requested an
error response for redirection, the server rejects the request with a
300 (Try Alternate) error. No new permission or binding is generated
on the server in this case.
If an alternate server is identified and the client did not request
an error response for redirection, the server creates the permission
or binding. The server then replies to the request with a success
response, including an ALTERNATE-SERVER attribute in the message.
3.4. Receiving a CreatePermission or ChannelBind Error Response
If the client receives a CreatePermission or ChannelBind error
response with error code 420 (Unknown Attribute) and CHECK-ALTERNATE
is listed in the UNKNOWN-ATTRIBUTE attribute of the message, the
client SHOULD retransmit the original request without the CHECK-
ALTERNATE attribute. This case is not expected due to the use of a
comprehension-optional attribute type.
If the client receives a CreatePermission or ChannelBind error
response with error code 300 (Try Alternate), the client SHOULD
attempt to form an allocation to the TURN server indicated in the
ALTERNATE-SERVER attribute.
If the alternate server responds to the Allocate request with a
success response, the client SHOULD attempt to form a new permission
or binding using the new allocation from the alternate server. The
CreatePermission or ChannelBind request to the alternate server MAY
include a CHECK-ALTERNATE attribute but SHOULD NOT request
redirection via an error response. This helps to avoid the
possibility of redirection loops.
If the alternate server responds to the Allocate request with an
error response, the client MAY resend the original CreatePermission
or ChannelBind request, either without the CHECK-ALTERNATE attribute
or with a CHECK-ALTERNATE attribute that does not request an error
response.
See Section 4 below for discussion of how the client should respond
when receiving a Try Alternate error response that was not requested.
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3.5. Receiving a CreatePermission or ChannelBind Success Response
If the client receives a CreatePermission or ChannelBind success
response, it proceeds with processing according to the TURN
specification [RFC5766]. If the message does not include an
ALTERNATE-SERVER attribute, no additional processing is required.
If the success response includes an ALTERNATE-SERVER attribute, the
client SHOULD attempt to form an allocation to the TURN server
indicated in the ALTERNATE-SERVER attribute.
If the alternate server responds to the Allocate request with a
success response, the client SHOULD attempt to form a new permission
or binding using the new allocation from the alternate server. The
CreatePermission or ChannelBind request to the alternate server MAY
include a CHECK-ALTERNATE attribute with either attribute value. If
this is done, care should be taken in the client implementation to
recognize and avoid redirection loops.
While waiting for the new allocation and permission or binding to
form via the indicated alternate server, the client SHOULD use the
original permission or binding from the request that included the
CHECK-ALTERNATE attribute. In this way, peer-specific redirection
without an error response can be considered a "hint" that allows the
client to establish an alternate path and test its quality before
switching to it.
See Section 4 below for discussion of how the client should respond
when receiving an ALTERNATE-SERVER attribute that was not requested.
4. Security Considerations
This section considers attacks that are possible in a TURN deployment
through the specified protocol extension, and discusses how they are
mitigated by mechanisms in the protocol or recommended practices in
the implementation.
The specified mechanism affects the use of TURN CreatePermission
request messages, ChannelBind request messages, and their respective
success and error response messages. Each of these TURN message
types requires the MESSAGE-INTEGRITY STUN attribute, which limits
attacks that attempt to make use of the specified mechanism to
authenticated clients and servers.
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4.1. CHECK-ALTERNATE Flood
A compromised TURN client could send a large number of
CreatePermission or ChannelBind request messages, which would drive
increased load on the TURN server. The CHECK-ALTERNATE attribute
does not make such an attack more likely, though it could make it
possible to increase the impact of such an attack due to the
additional load associated with determining whether an alternate
server should be used by the client. The TURN server MAY be
configured to ignore the CHECK-ALTERNATE attribute under some
conditions in order to limit the associated load. The conditions
under which it is appropriate for a TURN server to ignore the CHECK-
ALTERNATE attribute are implementation dependent.
4.2. Unsolicited or Invalid ALTERNATE-SERVER
A compromised TURN server could send the "Try Alternate" error code
in response to a request message that did not contain the CHECK-
ALTERNATE attribute or where the value of the attribute did not
request an error response. For client connectivity, this is no worse
than any other error response code that could be sent. No matter
what the error response code may be, the client is unable to relay
data to the remote peer. The client MUST ignore the ALTERNATE-SERVER
attribute in error responses when the CHECK-ALTERNATE attribute was
not included in the associated request. The client SHOULD ignore the
ALTERNATE-SERVER attribute in error responses when the CHECK-
ALTERNATE attribute was included in the associated request if the
attribute value did not request an error response. The client MAY
discontinue use of the associated TURN allocation when an unsolicited
Try Alternate error is received.
A compromised TURN server could send an ALTERNATE-SERVER attribute in
a success response message for a request message that did not contain
the CHECK-ALTERNATE attribute. The client MUST ignore the ALTERNATE-
SERVER attribute in success responses when the CHECK-ALTERNATE
attribute was not included in the associated request message. The
client SHOULD ignore the ALTERNATE-SERVER attribute in success
responses when the CHECK-ALTERNATE attribute was included in the
associated request if the attribute value requested an error
response. The client MAY discontinue use of the associated TURN
allocation when an unsolicited ALTERNATE-SERVER attribute is
received.
A compromised TURN server could send an invalid ALTERNATE-SERVER
attribute value in either an error or a success response message,
where the value refers to an unaffiliated TURN server to which the
sending TURN server is not allowed to redirect traffic. Such an
attack is already allowed by the use of Try Alternate errors in
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response to Allocate request messages. Use of the ALTERNATE-SERVER
attribute in the context of peer-specific redirection does not make
such an attack more likely, though it could make it possible to
increase the scale of such an attack by allowing multiple ALTERNATE-
SERVER attributes to each client, one per requested permission or
binding. A client SHOULD ignore all future ALTERNATE-SERVER
attributes received from the TURN server after an authentication
failure with any server identified via an ALTERNATE-SERVER attribute.
A client MAY discontinue use of the associated TURN allocation after
an authentication failure with any server identified via an
ALTERNATE-SERVER attribute.
5. IANA Considerations
[Paragraphs below in braces should be removed by the RFC Editor upon
publication]
[The CHECK-ALTERNATE attribute requires that IANA allocate a value in
the "STUN attributes Registry" from the comprehension-optional range
(0x8000-0xFFFF), to be replaced for TBD-CA throughout this document]
This document defines the CHECK-ALTERNATE STUN attribute, described
in Section 3.2.1. IANA has allocated the comprehension-optional
codepoint TBD-CA for this attribute.
[The XOR-OTHER-ADDRESS attribute requires that IANA allocate a value
in the "STUN attributes Registry" from the comprehension-optional
range (0x8000-0xFFFF), to be replaced for TBD-XOA throughout this
document]
This document defines the XOR-OTHER-ADDRESS STUN attribute, described
in Section 3.2.2. IANA has allocated the comprehension-optional
codepoint TBD-XOA for this attribute.
6. References
6.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
6.2. Informative References
[RFC5245] Rosenberg, J., "Interactive Connectivity Establishment
(ICE): A Protocol for Network Address Translator (NAT)
Traversal for Offer/Answer Protocols", RFC 5245,
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April 2010.
[RFC5389] Rosenberg, J., Mahy, R., Matthews, P., and D. Wing,
"Session Traversal Utilities for NAT (STUN)", RFC 5389,
October 2008.
[RFC5766] Mahy, R., Matthews, P., and J. Rosenberg, "Traversal Using
Relays around NAT (TURN): Relay Extensions to Session
Traversal Utilities for NAT (STUN)", RFC 5766, April 2010.
Authors' Addresses
Brandon Williams
Akamai, Inc.
8 Cambridge Center
Cambridge, MA 02142
USA
Email: brandon.williams@akamai.com
Tirumaleswar Reddy
Cisco Systems, Inc.
Cessna Business Park, Varthur Hobli
Sarjapur Marathalli Outer Ring Road
Bangalore, Karnataka 560103
India
Email: tireddy@cisco.com
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