Network Working Group E. McMurry
Internet-Draft B. Campbell
Intended status: Standards Track Tekelec
Expires: October 19, 2013 April 17, 2013
Diameter Overload Control Requirements
draft-ietf-dime-overload-reqs-06
Abstract
When a Diameter server or agent becomes overloaded, it needs to be
able to gracefully reduce its load, typically by informing clients to
reduce sending traffic for some period of time. Otherwise, it must
continue to expend resources parsing and responding to Diameter
messages, possibly resulting in congestion collapse. The existing
Diameter mechanisms, listed in Section 3 are not sufficient for this
purpose. This document describes the limitations of the existing
mechanisms in Section 4. Requirements for new overload management
mechanisms are provided in Section 7.
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
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This Internet-Draft will expire on October 19, 2013.
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document authors. All rights reserved.
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to this document. Code Components extracted from this document must
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Causes of Overload . . . . . . . . . . . . . . . . . . . . 3
1.2. Effects of Overload . . . . . . . . . . . . . . . . . . . 5
1.3. Overload vs. Network Congestion . . . . . . . . . . . . . 5
1.4. Diameter Applications in a Broader Network . . . . . . . . 5
1.5. Documentation Conventions . . . . . . . . . . . . . . . . 6
2. Overload Scenarios . . . . . . . . . . . . . . . . . . . . . . 6
2.1. Peer to Peer Scenarios . . . . . . . . . . . . . . . . . . 7
2.2. Agent Scenarios . . . . . . . . . . . . . . . . . . . . . 9
2.3. Interconnect Scenario . . . . . . . . . . . . . . . . . . 12
3. Existing Mechanisms . . . . . . . . . . . . . . . . . . . . . 13
4. Issues with the Current Mechanisms . . . . . . . . . . . . . . 14
4.1. Problems with Implicit Mechanism . . . . . . . . . . . . . 15
4.2. Problems with Explicit Mechanisms . . . . . . . . . . . . 15
5. Diameter Overload Case Studies . . . . . . . . . . . . . . . . 16
5.1. Overload in Mobile Data Networks . . . . . . . . . . . . . 16
5.2. 3GPP Study on Core Network Overload . . . . . . . . . . . 17
6. Extensibility and Application Independence . . . . . . . . . . 18
7. Solution Requirements . . . . . . . . . . . . . . . . . . . . 19
8. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 23
9. Security Considerations . . . . . . . . . . . . . . . . . . . 23
9.1. Access Control . . . . . . . . . . . . . . . . . . . . . . 24
9.2. Denial-of-Service Attacks . . . . . . . . . . . . . . . . 24
9.3. Replay Attacks . . . . . . . . . . . . . . . . . . . . . . 24
9.4. Man-in-the-Middle Attacks . . . . . . . . . . . . . . . . 25
9.5. Compromised Hosts . . . . . . . . . . . . . . . . . . . . 25
10. References . . . . . . . . . . . . . . . . . . . . . . . . . . 25
10.1. Normative References . . . . . . . . . . . . . . . . . . . 25
10.2. Informative References . . . . . . . . . . . . . . . . . . 25
Appendix A. Contributors . . . . . . . . . . . . . . . . . . . . 26
Appendix B. Acknowledgements . . . . . . . . . . . . . . . . . . 26
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 27
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1. Introduction
When a Diameter [RFC6733] server or agent becomes overloaded, it
needs to be able to gracefully reduce its load, typically by
informing clients to reduce sending traffic for some period of time.
Otherwise, it must continue to expend resources parsing and
responding to Diameter messages, possibly resulting in congestion
collapse. The existing mechanisms provided by Diameter are not
sufficient for this purpose. This document describes the limitations
of the existing mechanisms, and provides requirements for new
overload management mechanisms.
This document draws on the work done on SIP overload control
([RFC5390], [RFC6357]) as well as on experience gained via overload
handling in Signaling System No. 7 (SS7) networks and studies done by
the Third Generation Partnership Project (3GPP) (Section 5).
Diameter is not typically an end-user protocol; rather it is
generally used as one component in support of some end-user activity.
For example, a SIP server might use Diameter to authenticate and
authorize user access. Overload in the Diameter backend
infrastructure will likely impact the experience observed by the end
user in the SIP application.
The impact of Diameter overload on the client application (a client
application may use the Diameter protocol and other protocols to do
its job) is beyond the scope of this document.
This document presents non-normative descriptions of causes of
overload along with related scenarios and studies. Finally, it
offers a set of normative requirements for an improved overload
indication mechanism.
1.1. Causes of Overload
Overload occurs when an element, such as a Diameter server or agent,
has insufficient resources to successfully process all of the traffic
it is receiving. Resources include all of the capabilities of the
element used to process a request, including CPU processing, memory,
I/O, and disk resources. It can also include external resources such
as a database or DNS server, in which case the CPU, processing,
memory, I/O, and disk resources of those elements are effectively
part of the logical element processing the request.
Overload can occur for many reasons, including:
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Inadequate capacity: When designing Diameter networks, that is,
application layer multi-node Diameter deployments, it can be very
difficult to predict all scenarios that may cause elevated
traffic. It may also be more costly to implement support for some
scenarios than a network operator may deem worthwhile. This
results in the likelihood that a Diameter network will not have
adequate capacity to handle all situations.
Dependency failures: A Diameter node can become overloaded because a
resource on which it is dependent has failed or become overloaded,
greatly reducing the logical capacity of the node. In these
cases, even minimal traffic might cause the node to go into
overload. Examples of such dependency overloads include DNS
servers, databases, disks, and network interfaces.
Component failures: A Diameter node can become overloaded when it is
a member of a cluster of servers that each share the load of
traffic, and one or more of the other members in the cluster fail.
In this case, the remaining nodes take over the work of the failed
nodes. Normally, capacity planning takes such failures into
account, and servers are typically run with enough spare capacity
to handle failure of another node. However, unusual failure
conditions can cause many nodes to fail at once. This is often
the case with software failures, where a bad packet or bad
database entry hits the same bug in a set of nodes in a cluster.
Network Initiated Traffic Flood: Issues with the radio access
network in a mobile network such as radio overlays with frequent
handovers, and operational changes are examples of network events
that can precipitate a flood of Diameter signaling traffic, such
as an avalanche restart. Failure of a Diameter proxy may also
result in a large amount of signaling as connections and sessions
are reestablished.
Subscriber Initiated Traffic Flood: Large gatherings of subscribers
or events that result in many subscribers interacting with the
network in close time proximity can result in Diameter signaling
traffic floods. For example, the finale of a large fireworks show
could be immediately followed by many subscribers posting
messages, pictures, and videos concentrated on one portion of a
network. Subscriber devices, such as smartphones, may use
aggressive registration strategies that generate unusually high
Diameter traffic loads.
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DoS attacks: An attacker, wishing to disrupt service in the network,
can cause a large amount of traffic to be launched at a target
element. This can be done from a central source of traffic or
through a distributed DoS attack. In all cases, the volume of
traffic well exceeds the capacity of the element, sending the
system into overload.
1.2. Effects of Overload
Modern Diameter networks, comprised of application layer multi-node
deployments of Diameter elements, may operate at very large
transaction volumes. If a Diameter node becomes overloaded, or even
worse, fails completely, a large number of messages may be lost very
quickly. Even with redundant servers, many messages can be lost in
the time it takes for failover to complete. While a Diameter client
or agent should be able to retry such requests, an overloaded peer
may cause a sudden large increase in the number of transaction
transactions needing to be retried, rapidly filling local queues or
otherwise contributing to local overload. Therefore Diameter devices
need to be able to shed load before critical failures can occur.
1.3. Overload vs. Network Congestion
This document uses the term "overload" to refer to application-layer
overload at Diameter nodes. This is distinct from "network
congestion", that is, congestion that occurs at the lower networking
layers that may impact the delivery of Diameter messages between
nodes. The authors recognize that element overload and network
congestion are interrelated, and that overload can contribute to
network congestion and vice versa.
Network congestion issues are better handled by the transport
protocols. Diameter uses TCP and SCTP, both of which include
congestion management features. Analysis of whether those features
are sufficient for transport level congestion between Diameter nodes,
and any work to further mitigate network congestion is out of scope
both for this document, and for the work proposed by this document.
1.4. Diameter Applications in a Broader Network
Most elements using Diameter applications do not use Diameter
exclusively. It is important to realize that overload of an element
can be caused by a number of factors that may be unrelated to the
processing of Diameter or Diameter applications.
A element communicating via protocols other than Diameter that is
also using a Diameter application needs to be able to signal to
Diameter peers that it is experiencing overload regardless of the
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cause of the overload, since the overload will affect that element's
ability to process Diameter transactions. The element may also need
to signal this on other protocols depending on its function and the
architecture of the network and application it is providing services
for. Whether that is necessary can only be decided within the
context of that architecture and application. A mechanism for
signaling overload with Diameter, which this specification details
the requirements for, provides applications the ability to signal
their Diameter peers of overload, mitigating that part of the issue.
Applications may need to use this, as well as other mechanisms, to
solve their broader overload issues. Indicating overload on
protocols other than Diameter is out of scope for this document, and
for the work proposed by this document.
1.5. Documentation Conventions
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].
The terms "client", "server", "agent", "node", "peer", "upstream",
and "downstream" are used as defined in [RFC6733].
2. Overload Scenarios
Several Diameter deployment scenarios exist that may impact overload
management. The following scenarios help motivate the requirements
for an overload management mechanism.
These scenarios are by no means exhaustive, and are in general
simplified for the sake of clarity. In particular, the authors
assume for the sake of clarity that the client sends Diameter
requests to the server, and the server sends responses to client,
even though Diameter supports bidirectional applications. Each
direction in such an application can be modeled separately.
In a large scale deployment, many of the nodes represented in these
scenarios would be deployed as clusters of servers. The authors
assume that such a cluster is responsible for managing its own
internal load balancing and overload management so that it appears as
a single Diameter node. That is, other Diameter nodes can treat it
as single, monolithic node for the purposes of overload management.
These scenarios do not illustrate the client application. As
mentioned in Section 1, Diameter is not typically an end-user
protocol; rather it is generally used in support of some other client
application. These scenarios do not consider the impact of Diameter
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overload on the client application.
2.1. Peer to Peer Scenarios
This section describes Diameter peer-to-peer scenarios. That is,
scenarios where a Diameter client talks directly with a Diameter
server, without the use of a Diameter agent.
Figure 1 illustrates the simplest possible Diameter relationship.
The client and server share a one-to-one peer-to-peer relationship.
If the server becomes overloaded, either because the client exceeds
the server's capacity, or because the server's capacity is reduced
due to some resource dependency, the client needs to reduce the
amount of Diameter traffic it sends to the server. Since the client
cannot forward requests to another server, it must either queue
requests until the server recovers, or itself become overloaded in
the context of the client application and other protocols it may also
use.
+------------------+
| |
| |
| Server |
| |
+--------+---------+
|
|
+--------+---------+
| |
| |
| Client |
| |
+------------------+
Figure 1: Basic Peer to Peer Scenario
Figure 2 shows a similar scenario, except in this case the client has
multiple servers that can handle work for a specific realm and
application. If server 1 becomes overloaded, the client can forward
traffic to server 2. Assuming server 2 has sufficient reserve
capacity to handle the forwarded traffic, the client should be able
to continue serving client application protocol users. If server 1
is approaching overload, but can still handle some number of new
request, it needs to be able to instruct the client to forward a
subset of its traffic to server 2.
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+------------------+ +------------------+
| | | |
| | | |
| Server 1 | | Server 2 |
| | | |
+--------+-`.------+ +------.'+---------+
`. .'
`. .'
`. .'
`. .'
+-------`.'--------+
| |
| |
| Client |
| |
+------------------+
Figure 2: Multiple Server Peer to Peer Scenario
Figure 3 illustrates a peer-to-peer scenario with multiple Diameter
realm and application combinations. In this example, server 2 can
handle work for both applications. Each application might have
different resource dependencies. For example, a server might need to
access one database for application A, and another for application B.
This creates a possibility that Server 2 could become overloaded for
application A but not for application B, in which case the client
would need to divert some part of its application A requests to
server 1, but should not divert any application B requests. This
requires server 2 to be able to distinguish between applications when
it indicates an overload condition to the client.
On the other hand, it's possible that the servers host many
applications. If server 2 becomes overloaded for all applications,
it would be undesirable for it to have to notify the client
separately for each application. Therefore it also needs a way to
indicate that it is overloaded for all possible applications.
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+---------------------------------------------+
| Application A +----------------------+----------------------+
|+------------------+ | +----------------+ | +------------------+|
|| | | | | | | ||
|| | | | | | | ||
|| Server 1 | | | Server 2 | | | Server 3 ||
|| | | | | | | ||
|+--------+---------+ | +-------+--------+ | +-+----------------+|
| | | | | | |
+---------+-----------+----------+-----------+ | |
| | | | |
| | | | Application B |
| +----------+----------------+-----------------+
``-.._ | |
`-..__ | _.-''
`--._ | _.-''
``-._ | _.-''
+-----`-.-''-----+
| |
| |
| Client |
| |
+----------------+
Figure 3: Multiple Application Peer to Peer Scenario
2.2. Agent Scenarios
This section describes scenarios that include a Diameter agent,
either in the form of a Diameter relay or Diameter proxy. These
scenarios do not consider Diameter redirect agents, since they are
more readily modeled as end-servers.
Figure 4 illustrates a simple Diameter agent scenario with a single
client, agent, and server. In this case, overload can occur at the
server, at the agent, or both. But in most cases, client behavior is
the same whether overload occurs at the server or at the agent. From
the client's perspective, server overload and agent overload is the
same thing.
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+------------------+
| |
| |
| Server |
| |
+--------+---------+
|
|
+--------+---------+
| |
| |
| Agent |
| |
+--------+---------+
|
|
+--------+---------+
| |
| |
| Client |
| |
+------------------+
Figure 4: Basic Agent Scenario
Figure 5 shows an agent scenario with multiple servers. If server 1
becomes overloaded, but server 2 has sufficient reserve capacity, the
agent may be able to transparently divert some or all Diameter
requests originally bound for server 1 to server 2.
In most cases, the client does not have detailed knowledge of the
Diameter topology upstream of the agent. If the agent uses dynamic
discovery to find eligible servers, the set of eligible servers may
not be enumerable from the perspective of the client. Therefore, in
most cases the agent needs to deal with any upstream overload issues
in a way that is transparent to the client. If one server notifies
the agent that it has become overloaded, the notification should not
be passed back to the client in a way that the client could
mistakenly perceive the agent itself as being overloaded. If the set
of all possible destinations upstream of the agent no longer has
sufficient capacity for incoming load, the agent itself becomes
effectively overloaded.
On the other hand, there are cases where the client needs to be able
to select a particular server from behind an agent. For example, if
a Diameter request is part of a multiple-round-trip authentication,
or is otherwise part of a Diameter "session", it may have a
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DestinationHost AVP that requires the request to be served by server
1. Therefore the agent may need to inform a client that a particular
upstream server is overloaded or otherwise unavailable. Note that
there can be many ways a server can be specified, which may have
different implications (e.g. by IP address, by host name, etc).
+------------------+ +------------------+
| | | |
| | | |
| Server 1 | | Server 2 |
| | | |
+--------+-`.------+ +------.'+---------+
`. .'
`. .'
`. .'
`. .'
+-------`.'--------+
| |
| |
| Agent |
| |
+--------+---------+
|
|
|
+--------+---------+
| |
| |
| Client |
| |
+------------------+
Figure 5: Multiple Server Agent Scenario
Figure 6 shows a scenario where an agent routes requests to a set of
servers for more than one Diameter realm and application. In this
scenario, if server 1 becomes overloaded or unavailable, the agent
may effectively operate at reduced capacity for application A, but at
full capacity for application B. Therefore, the agent needs to be
able to report that it is overloaded for one application, but not for
another.
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+--------------------------------------------+
| Application A +----------------------+----------------------+
|+------------------+ | +----------------+ | +------------------+|
|| | | | | | | ||
|| | | | | | | ||
|| Server 1 | | | Server 2 | | | Server 3 ||
|| | | | | | | ||
|+---------+--------+ | +-------+--------+ | +--+---------------+|
| | | | | | |
+----------+----------+----------+-----------+ | |
| | | | |
| | | | Application B |
| +----------+-----------------+----------------+
| | |
``--.__ | _.
``-.__ | __.--''
`--.._ | _..--'
+----``-+.''-----+
| |
| |
| Agent |
| |
+-------+--------+
|
|
+-------+--------+
| |
| |
| Client |
| |
+----------------+
Figure 6: Multiple Application Agent Scenario
2.3. Interconnect Scenario
Another scenario to consider when looking at Diameter overload is
that of multiple network operators using Diameter components
connected through an interconnect service, e.g. using IPX. IPX (IP
eXchange) [IR.34] is an Inter-Operator IP Backbone that provides
roaming interconnection network between mobile operators and service
providers. The IPX is also used to transport Diameter signaling
between operators [IR.88]. Figure 7 shows two network operators with
an interconnect network in-between. There could be any number of
these networks between any two network operator's networks.
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+-------------------------------------------+
| Interconnect |
| |
| +--------------+ +--------------+ |
| | Server 3 |------| Server 4 | |
| +--------------+ +--------------+ |
| .' `. |
+------.-'--------------------------`.------+
.' `.
.-' `.
------------.'-----+ +----`.-------------
+----------+ | | +----------+
| Server 1 | | | | Server 2 |
+----------+ | | +----------+
| |
Network Operator 1 | | Network Operator 2
-------------------+ +-------------------
Figure 7: Two Network Interconnect Scenario
The characteristics of the information that an operator would want to
share over such a connection are different from the information
shared between components within a network operator's network.
Network operators may not want to convey topology or operational
information, which limits how much overload and loading information
can be sent. For the interconnect scenario shown, Server 2 may want
to signal overload to Server 1, to affect traffic coming from Network
Operator 1.
This case is distinct from those internal to a network operator's
network, where there may be many more elements in a more complicated
topology. Also, the elements in the interconnect network may not
support Diameter overload control, and the network operators may not
want the interconnect network to use overload or loading information.
They may only want the information to pass through the interconnect
network without further processing or action by the interconnect
network even if the elements in the interconnect network do support
Diameter overload control.
3. Existing Mechanisms
Diameter offers both implicit and explicit mechanisms for a Diameter
node to learn that a peer is overloaded or unreachable. The implicit
mechanism is simply the lack of responses to requests. If a client
fails to receive a response in a certain time period, it assumes the
upstream peer is unavailable, or overloaded to the point of effective
unavailability. The watchdog mechanism [RFC3539] ensures that a
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certain rate of transaction responses occur even when there is
otherwise little or no other Diameter traffic.
The explicit mechanism can involve specific protocol error responses,
where an agent or server tells a downstream peer that it is either
too busy to handle a request (DIAMETER_TOO_BUSY) or unable to route a
request to an upstream destination (DIAMETER_UNABLE_TO_DELIVER),
perhaps because that destination itself is overloaded to the point of
unavailability.
Another explicit mechanism, a DPR (Disconnect-Peer-Request) message,
can be sent with a Disconnect-Cause of BUSY. This signals the
sender's intent to close the transport connection, and requests the
client not to reconnect.
Once a Diameter node learns that an upstream peer has become
overloaded via one of these mechanisms, it can then attempt to take
action to reduce the load. This usually means forwarding traffic to
an alternate destination, if available. If no alternate destination
is available, the node must either reduce the number of messages it
originates (in the case of a client) or inform the client to reduce
traffic (in the case of an agent.)
Diameter requires the use of a congestion-managed transport layer,
currently TCP or SCTP, to mitigate network congestion. It is
expected that these transports manage network congestion and that
issues with transport (e.g. congestion propagation and window
management) are managed at that level. But even with a congestion-
managed transport, a Diameter node can become overloaded at the
Diameter protocol or application layers due to the causes described
in Section 1.1 and congestion managed transports do not provide
facilities (and are at the wrong level) to handle server overload.
Transport level congestion management is also not sufficient to
address overload in cases of multi-hop and multi-destination
signaling.
4. Issues with the Current Mechanisms
The currently available Diameter mechanisms for indicating an
overload condition are not adequate to avoid service outages due to
overload. This inadequacy may, in turn, contribute to broader
congestion collapse due to unresponsive Diameter nodes causing
application or transport layer retransmissions. In particular, they
do not allow a Diameter agent or server to shed load as it approaches
overload. At best, a node can only indicate that it needs to
entirely stop receiving requests, i.e. that it has effectively
failed. Even that is problematic due to the inability to indicate
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durational validity on the transient errors available in the base
Diameter protocol. Diameter offers no mechanism to allow a node to
indicate different overload states for different categories of
messages, for example, if it is overloaded for one Diameter
application but not another.
4.1. Problems with Implicit Mechanism
The implicit mechanism doesn't allow an agent or server to inform the
client of a problem until it is effectively too late to do anything
about it. The client does not know to take action until the upstream
node has effectively failed. A Diameter node has no opportunity to
shed load early to avoid collapse in the first place.
Additionally, the implicit mechanism cannot distinguish between
overload of a Diameter node and network congestion. Diameter treats
the failure to receive an answer as a transport failure.
4.2. Problems with Explicit Mechanisms
The Diameter specification is ambiguous on how a client should handle
receipt of a DIAMETER_TOO_BUSY response. The base specification
[RFC6733] indicates that the sending client should attempt to send
the request to a different peer. It makes no suggestion that the
receipt of a DIAMETER_TOO_BUSY response should affect future Diameter
messages in any way.
The Authentication, Authorization, and Accounting (AAA) Transport
Profile [RFC3539] recommends that a AAA node that receives a "Busy"
response failover all remaining requests to a different agent or
server. But while the Diameter base specification explicitly depends
on RFC3539 to define transport behavior, it does not refer to RFC3539
in the description of behavior on receipt of DIAMETER_TOO_BUSY.
There's a strong likelihood that at least some implementations will
continue to send Diameter requests to an upstream peer even after
receiving a DIAMETER_TOO_BUSY error.
BCP 41 [RFC2914] describes, among other things, how end-to-end
application behavior can help avoid congestion collapse. In
particular, an application should avoid sending messages that will
never be delivered or processed. The DIAMETER_TOO_BUSY behavior as
described in the Diameter base specification fails at this, since if
an upstream node becomes overloaded, a client attempts each request,
and does not discover the need to failover the request until the
initial attempt fails.
The situation is improved if implementations follow the [RFC3539]
recommendation and keep state about upstream peer overload. But even
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then, the Diameter specification offers no guidance on how long a
client should wait before retrying the overloaded destination. If an
agent or server supports multiple realms and/or applications,
DIAMETER_TOO_BUSY offers no way to indicate that it is overloaded for
one application but not another. A DIAMETER_TOO_BUSY error can only
indicate overload at a "whole server" scope.
Agent processing of a DIAMETER_TOO_BUSY response is also problematic
as described in the base specification. DIAMETER_TOO_BUSY is defined
as a protocol error. If an agent receives a protocol error, it may
either handle it locally or it may forward the response back towards
the downstream peer. (The Diameter specification is inconsistent
about whether a protocol error MAY or SHOULD be handled by an agent,
rather than forwarded downstream.) If a downstream peer receives the
DIAMETER_TOO_BUSY response, it may stop sending all requests to the
agent for some period of time, even though the agent may still be
able to deliver requests to other upstream peers.
DIAMETER_UNABLE_TO_DELIVER, or using DPR with cause code BUSY also
have no mechanisms for specifying the scope or cause of the failure,
or the durational validity.
The issues with error responses in [RFC6733] extend beyond the
particular issues for overload control and have been addressed in an
ad hoc fashion by various implementations. Addressing these in a
standard way would be a useful exercise, but it us beyond the scope
of this document.
5. Diameter Overload Case Studies
5.1. Overload in Mobile Data Networks
As the number of Third Generation (3G) and Long Term Evolution (LTE)
enabled smartphone devices continue to expand in mobility networks,
there have been situations where high signaling traffic load led to
overload events at the Diameter-based Home Location Registries (HLR)
and/or Home Subscriber Servers (HSS) [TR23.843]. The root causes of
the HLR congestion events were manifold but included hardware failure
and procedural errors. The result was high signaling traffic load on
the HLR and HSS.
The 3GPP architecture [TS23.002] makes extensive use of Diameter. It
is used for mobility management [TS29.272] (and others), (IP
Multimedia Subsystem) IMS [TS29.228] (and others), policy and
charging control [TS29.212] (and others) as well as other functions.
The details of the architecture are out of scope for this document,
but it is worth noting that there are quite a few Diameter
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applications, some with quite large amounts of Diameter signaling in
deployed networks.
The 3GPP specifications do not currently address overload for
Diameter applications or provide an equivalent load control mechanism
to those provided in the more traditional SS7 elements in (Global
System for Mobile Communications) GSM [TS29.002]. The capabilities
specified in the 3GPP standards do not adequately address the
abnormal condition where excessively high signaling traffic load
situations are experienced.
Smartphones, an increasingly large percentage of mobile devices,
contribute much more heavily, relative to non-smartphones, to the
continuation of a registration surge due to their very aggressive
registration algorithms. Smartphone behavior contributes to network
loading and can contribute to overload conditions. The aggressive
smartphone logic is designed to:
a. always have voice and data registration, and
b. constantly try to be on 3G or LTE data (and thus on 3G voice or
VoLTE) for their added benefits.
Non-smartphones typically have logic to wait for a time period after
registering successfully on voice and data.
The smartphone aggressive registration is problematic in two ways:
o first by generating excessive signaling load towards the HLR that
is ten times that from a non-smartphone,
o and second by causing continual registration attempts when a
network failure affects registrations through the 3G data network.
5.2. 3GPP Study on Core Network Overload
A study in 3GPP SA2 on core network overload has produced the
technical report [TR23.843]. This enumerates several causes of
overload in mobile core networks including portions that are signaled
using Diameter. This document is a work in progress and is not
complete. However, it is useful for pointing out scenarios and the
general need for an overload control mechanism for Diameter.
It is common for mobile networks to employ more than one radio
technology and to do so in an overlay fashion with multiple
technologies present in the same location (such as 2nd or 3rd
generation mobile technologies along with LTE). This presents
opportunities for traffic storms when issues occur on one overlay and
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not another as all devices that had been on the overlay with issues
switch. This causes a large amount of Diameter traffic as locations
and policies are updated.
Another scenario called out by this study is a flood of registration
and mobility management events caused by some element in the core
network failing. This flood of traffic from end nodes falls under
the network initiated traffic flood category. There is likely to
also be traffic resulting directly from the component failure in this
case. A similar flood can occur when elements or components recover
as well.
Subscriber initiated traffic floods are also indicated in this study
as an overload mechanism where a large number of mobile devices
attempting to access services at the same time, such as in response
to an entertainment event or a catastrophic event.
While this 3GPP study is concerned with the broader effects of these
scenarios on wireless networks and their elements, they have
implications specifically for Diameter signaling. One of the goals
of this document is to provide guidance for a core mechanism that can
be used to mitigate the scenarios called out by this study.
6. Extensibility and Application Independence
Given the variety of scenarios Diameter elements can be deployed in,
and the variety of roles they can fulfill with Diameter and other
technologies, a single algorithm for handling overload may not be
sufficient. This effort cannot anticipate all possible future
scenarios and roles. Extensibility, particularly of algorithms used
to deal with overload, will be important to cover these cases.
Similarly, the scopes that overload information may apply to may
include cases that have not yet been considered. Extensibility in
this area will also be important.
The basic mechanism is intended to be application-independent, that
is, a Diameter node can use it across any existing and future
Diameter applications and expect reasonable results. Certain
Diameter applications might, however, benefit from application-
specific behavior over and above the mechanism's defaults. For
example, an application specification might specify relative
priorities of messages or selection of a specific overload control
algorithm.
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7. Solution Requirements
This section proposes requirements for an improved mechanism to
control Diameter overload, with the goals of improving the issues
described in Section 4 and supporting the scenarios described in
Section 2
REQ 1: The overload control mechanism MUST provide a communication
method for Diameter nodes to exchange load and overload
information.
REQ 2: The mechanism MUST allow Diameter nodes to support overload
control regardless of which Diameter applications they
support. Diameter clients must be able to use the received
load and overload information to support graceful behavior
during an overload condition. Graceful behavior under
overload conditions is best described by REQ 3.
REQ 3: The overload control mechanism MUST limit the impact of
overload on the overall useful throughput of a Diameter
server, even when the incoming load on the network is far in
excess of its capacity. The overall useful throughput under
load is the ultimate measure of the value of an overload
control mechanism.
REQ 4: Diameter allows requests to be sent from either side of a
connection and either side of a connection may have need to
provide its overload status. The mechanism MUST allow each
side of a connection to independently inform the other of
its overload status.
REQ 5: Diameter allows nodes to determine their peers via dynamic
discovery or manual configuration. The mechanism MUST work
consistently without regard to how peers are determined.
REQ 6: The mechanism designers SHOULD seek to minimize the amount
of new configuration required in order to work. For
example, it is better to allow peers to advertise or
negotiate support for the mechanism, rather than to require
this knowledge to be configured at each node.
REQ 7: The overload control mechanism and any associated default
algorithm(s) MUST ensure that the system remains stable. At
some point after an overload condition has ended, the
mechanism MUST enable capacity to stabilize and become equal
to what it would be in the absence of an overload condition.
Note that this also requires that the mechanism MUST allow
nodes to shed load without introducing non converging
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oscillations during or after an overload condition.
REQ 8: Supporting nodes MUST be able to distinguish current
overload information from stale information, and SHOULD make
decisions using the most currently available information.
REQ 9: The mechanism MUST function across fully loaded as well as
quiescent transport connections. This is partially derived
from the requirement for stability in REQ 7.
REQ 10: Consumers of overload information MUST be able to determine
when the overload condition improves or ends.
REQ 11: The overload control mechanism MUST be able to operate in
networks of different sizes.
REQ 12: When a single network node fails, goes into overload, or
suffers from reduced processing capacity, the mechanism MUST
make it possible to limit the impact of this on other nodes
in the network. This helps to prevent a small-scale failure
from becoming a widespread outage.
REQ 13: The mechanism MUST NOT introduce substantial additional work
for node in an overloaded state. For example, a requirement
for an overloaded node to send overload information every
time it received a new request would introduce substantial
work. Existing messaging is likely to have the
characteristic of increasing as an overload condition
approaches, allowing for the possibility of increased
feedback for information piggybacked on it.
REQ 14: Some scenarios that result in overload involve a rapid
increase of traffic with little time between normal levels
and overload inducing levels. The mechanism SHOULD provide
for rapid feedback when traffic levels increase.
REQ 15: The mechanism MUST NOT interfere with the congestion control
mechanisms of underlying transport protocols. For example,
a mechanism that opened additional TCP connections when the
network is congested would reduce the effectiveness of the
underlying congestion control mechanisms.
REQ 16: The overload control mechanism is likely to be deployed
incrementally. The mechanism MUST support a mixed
environment where some, but not all, nodes implement it.
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REQ 17: In a mixed environment with nodes that support the overload
control mechanism and that do not, the mechanism MUST result
in at least as much useful throughput as would have resulted
if the mechanism were not present. It SHOULD result in less
severe congestion in this environment.
REQ 18: In a mixed environment of nodes that support the overload
control mechanism and that do not, the mechanism MUST NOT
preclude elements that support overload control from
treating elements that do not support overload control in a
equitable fashion relative to those that do. users and
operators of nodes that do not support the mechanism MUST
NOT unfairly benefit from the mechanism. The mechanism
specification SHOULD provide guidance to implementors for
dealing with elements not supporting overload control.
REQ 19: It MUST be possible to use the mechanism between nodes in
different realms and in different administrative domains.
REQ 20: Any explicit overload indication MUST be clearly
distinguishable from other errors reported via Diameter.
REQ 21: In cases where a network node fails, is so overloaded that
it cannot process messages, or cannot communicate due to a
network failure, it may not be able to provide explicit
indications of the nature of the failure or its levels of
congestion. The mechanism MUST result in at least as much
useful throughput as would have resulted if the overload
control mechanism was not in place.
REQ 22: The mechanism MUST provide a way for an node to throttle the
amount of traffic it receives from an peer node. This
throttling SHOULD be graded so that it can be applied
gradually as offered load increases. Overload is not a
binary state; there may be degrees of overload.
REQ 23: The mechanism MUST provide sufficient information to enable
a load balancing node to divert messages that are rejected
or otherwise throttled by an overloaded upstream node to
other upstream nodes that are the most likely to have
sufficient capacity to process them.
REQ 24: The mechanism MUST provide a mechanism for indicating load
levels even when not in an overloaded condition, to assist
nodes making decisions to prevent overload conditions from
occurring.
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REQ 25: The base specification for the overload control mechanism
SHOULD offer general guidance on which message types might
be desirable to send or process over others during times of
overload, based on application-specific considerations. For
example, it may be more beneficial to process messages for
existing sessions ahead of new sessions. Some networks may
have a requirement to give priority to requests associated
with emergency sessions. Any normative or otherwise
detailed definition of the relative priorities of message
types during an overload condition will be the
responsibility of the application specification.
REQ 26: The mechanism MUST NOT prevent a node from prioritizing
requests based on any local policy, so that certain requests
are given preferential treatment, given additional
retransmission, not throttled, or processed ahead of others.
REQ 27: The overload control mechanism MUST NOT provide new
vulnerabilities to malicious attack, or increase the
severity of any existing vulnerabilities. This includes
vulnerabilities to DoS and DDoS attacks as well as replay
and man-in-the middle attacks. Note that the Diameter base
specification [RFC6733] lacks end to end security and this
must be considered.
REQ 28: The mechanism MUST NOT depend on being deployed in
environments where all Diameter nodes are completely
trusted. It SHOULD operate as effectively as possible in
environments where other nodes are malicious; this includes
preventing malicious nodes from obtaining more than a fair
share of service. Note that this does not imply any
responsibility on the mechanism to detect, or take
countermeasures against, malicious nodes.
REQ 29: It MUST be possible for a supporting node to make
authorization decisions about what information will be sent
to peer nodes based on the identity of those nodes. This
allows a domain administrator who considers the load of
their nodes to be sensitive information to restrict access
to that information. Of course, in such cases, there is no
expectation that the overload control mechanism itself will
help prevent overload from that peer node.
REQ 30: The mechanism MUST NOT interfere with any Diameter compliant
method that a node may use to protect itself from overload
from non-supporting nodes, or from denial of service
attacks.
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REQ 31: There are multiple situations where a Diameter node may be
overloaded for some purposes but not others. For example,
this can happen to an agent or server that supports multiple
applications, or when a server depends on multiple external
resources, some of which may become overloaded while others
are fully available. The mechanism MUST allow Diameter
nodes to indicate overload with sufficient granularity to
allow clients to take action based on the overloaded
resources without unreasonably forcing available capacity to
go unused. The mechanism MUST support specification of
overload information with granularities of at least
"Diameter node", "realm", and "Diameter application", and
MUST allow extensibility for others to be added in the
future.
REQ 32: The mechanism MUST provide a method for extending the
information communicated and the algorithms used for
overload control.
REQ 33: The mechanism MUST provide a default algorithm that is
mandatory to implement.
REQ 34: The mechanism SHOULD provide a method for exchanging
overload and load information between elements that are
connected by intermediaries that do not support the
mechanism.
8. IANA Considerations
This document makes no requests of IANA.
9. Security Considerations
A Diameter overload control mechanism is primarily concerned with the
load and overload related behavior of nodes in a Diameter network,
and the information used to affect that behavior. Load and overload
information is shared between nodes and directly affects the behavior
and thus is potentially vulnerable to a number of methods of attack.
Load and overload information may also be sensitive from both
business and network protection viewpoints. Operators of Diameter
equipment want to control visibility to load and overload information
to keep it from being used for competitive intelligence or for
targeting attacks. It is also important that the Diameter overload
control mechanism not introduce any way in which any other
information carried by Diameter is sent inappropriately.
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Note that the Diameter base specification [RFC6733] lacks end to end
security, making verifying the authenticity and ownership of load and
overload information difficult for non-adjacent nodes.
Authentication of load and overload information helps to alleviate
several of the security issues listed in this section.
This document includes requirements intended to mitigate the effects
of attacks and to protect the information used by the mechanism.
9.1. Access Control
To control the visibility of load and overload information, sending
should be subject to some form of authentication and authorization of
the receiver. It is also important to the receivers that they are
confident the load and overload information they receive is from a
legitimate source. Note that this implies a certain amount of
configurability on the nodes supporting the Diameter overload control
mechanism.
9.2. Denial-of-Service Attacks
An overload control mechanism provides a very attractive target for
denial-of-service attacks. A small number of messages may affect a
large service disruption by falsely reporting overload conditions.
Alternately, attacking servers nearing, or in, overload may also be
facilitated by disrupting their overload indications, potentially
preventing them from mitigating their overload condition.
A design goal for the Diameter overload control mechanism is to
minimize or eliminate the possibility of using the mechanism for this
type of attack.
As the intent of some denial-of-service attacks is to induce overload
conditions, an effective overload control mechanism should help to
mitigate the effects of an such an attack.
9.3. Replay Attacks
An attacker that has managed to obtain some messages from the
overload control mechanism may attempt to affect the behavior of
nodes supporting the mechanism by sending those messages at
potentially inopportune times. In addition to time shifting, replay
attacks may send messages to other nodes as well (target shifting).
A design goal for the Diameter overload control mechanism is to
minimize or eliminate the possibility of causing disruption by using
a replay attack on the Diameter overload control mechanism.
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9.4. Man-in-the-Middle Attacks
By inserting themselves in between two nodes supporting the Diameter
overload control mechanism, an attacker may potentially both access
and alter the information sent between those nodes. This can be used
for information gathering for business intelligence and attack
targeting, as well as direct attacks.
A design goal for the Diameter overload control mechanism is to
minimize or eliminate the possibility of causing disruption man-in-
the-middle attacks on the Diameter overload control mechanism. A
transport using TLS and/or IPSEC may be desirable for this.
9.5. Compromised Hosts
A compromised host that supports the Diameter overload control
mechanism could be used for information gathering as well as for
sending malicious information to any Diameter node that would
normally accept information from it. While is is beyond the scope of
the Diameter overload control mechanism to mitigate any operational
interruption to the compromised host, a reasonable design goal is to
minimize the impact that a compromised host can have on other nodes
through the use of the Diameter overload control mechanism. Of
course, a compromised host could be used to cause damage in a number
of other ways. This is out of scope for a Diameter overload control
mechanism.
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.
[RFC6733] Fajardo, V., Arkko, J., Loughney, J., and G. Zorn,
"Diameter Base Protocol", RFC 6733, October 2012.
[RFC2914] Floyd, S., "Congestion Control Principles", BCP 41,
RFC 2914, September 2000.
[RFC3539] Aboba, B. and J. Wood, "Authentication, Authorization and
Accounting (AAA) Transport Profile", RFC 3539, June 2003.
10.2. Informative References
[RFC5390] Rosenberg, J., "Requirements for Management of Overload in
the Session Initiation Protocol", RFC 5390, December 2008.
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[RFC6357] Hilt, V., Noel, E., Shen, C., and A. Abdelal, "Design
Considerations for Session Initiation Protocol (SIP)
Overload Control", RFC 6357, August 2011.
[TR23.843]
3GPP, "Study on Core Network Overload Solutions",
TR 23.843 0.6.0, October 2012.
[IR.34] GSMA, "Inter-Service Provider IP Backbone Guidelines",
IR 34 7.0, January 2012.
[IR.88] GSMA, "LTE Roaming Guidelines", IR 88 7.0, January 2012.
[TS23.002]
3GPP, "Network Architecture", TS 23.002 12.0.0,
September 2012.
[TS29.272]
3GPP, "Evolved Packet System (EPS); Mobility Management
Entity (MME) and Serving GPRS Support Node (SGSN) related
interfaces based on Diameter protocol", TS 29.272 11.4.0,
September 2012.
[TS29.212]
3GPP, "Policy and Charging Control (PCC) over Gx/Sd
reference point", TS 29.212 11.6.0, September 2012.
[TS29.228]
3GPP, "IP Multimedia (IM) Subsystem Cx and Dx interfaces;
Signalling flows and message contents", TS 29.228 11.5.0,
September 2012.
[TS29.002]
3GPP, "Mobile Application Part (MAP) specification",
TS 29.002 11.4.0, September 2012.
Appendix A. Contributors
Significant contributions to this document were made by Adam Roach
and Eric Noel.
Appendix B. Acknowledgements
Review of, and contributions to, this specification by Martin Dolly,
Carolyn Johnson, Jianrong Wang, Imtiaz Shaikh, Jouni Korhonen, Robert
Sparks, Dieter Jacobsohn, Janet Gunn, Jean-Jacques Trottin, Laurent
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Thiebaut, Andrew Booth, and Lionel Morand were most appreciated. We
would like to thank them for their time and expertise.
Authors' Addresses
Eric McMurry
Tekelec
17210 Campbell Rd.
Suite 250
Dallas, TX 75252
US
Email: emcmurry@computer.org
Ben Campbell
Tekelec
17210 Campbell Rd.
Suite 250
Dallas, TX 75252
US
Email: ben@nostrum.com
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