i2rs R. White
Internet-Draft IETF
Intended status: Informational S. Hares
Expires: February 28, 2014 ADARA
A. Retana
Cisco Systems, Inc.
August 27, 2013
Protocol Independent Use Cases for an Interface to the Routing System
draft-white-i2rs-use-case-01
Abstract
Programmatic interfaces to provide control over individual forwarding
devices in a network promise to reduce operational costs while
improving scaling, control, and visibility into the operation of
large scale networks. To this end, several programmatic interfaces
have been proposed. OpenFlow, for instance, provides a mechanism to
replace the dynamic control plane processes on individual forwarding
devices throughout a network with off box processes that interact
with the forwarding tables on each device. Another example is
NETCONF, which provides a fast and flexible mechanism to interact
with device configuration and policy.
There is, however, no proposal which provides an interface to all
aspects of the routing system as a system. Such a system would not
interact with the forwarding system on individual devices, but rather
with the control plane processes already used to discover the best
path to any given destination through the network, as well as
interact with the routing information base (RIB), which feeds the
forwarding table the information needed to actually switch traffic at
a local level.
This document describes a set of use cases such a system could
fulfill. It is designed to provide underlying support for the
framework, policy, and other drafts describing the Interface to the
Routing System (I2RS).
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
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working documents as Internet-Drafts. The list of current Internet-
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
2. Distributed Reaction to Network Based Attacks . . . . . . . . 3
3. Remote Service Routing . . . . . . . . . . . . . . . . . . . 4
4. Within Data Center Routing . . . . . . . . . . . . . . . . . 6
5. Temporary Overlays between Data Centers . . . . . . . . . . . 7
6. References . . . . . . . . . . . . . . . . . . . . . . . . . 9
6.1. Normative References . . . . . . . . . . . . . . . . . . 9
6.2. Informative References . . . . . . . . . . . . . . . . . 9
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 9
1. Introduction
The Interface to the Routing System Framework
[I-D.ward-i2rs-framework] describes a mechanism where the distributed
control plane can be augmented by an outside control plane through an
open, accessible interface, including the Routing Information Base
(RIB), in individual devices. This represents a "halfway point"
between completely replacing the traditional distributed control
plane and directly configuring devices to distribute policy or
modifications to routing through off-board processes. This draft
proposes a set of use cases that explain where the work described in
[I2RS - should this be a reference to the framework as above, or to
the architecture, or the WG charter or ??] will be useful. The goal
is to inform not only the community's understanding of where I2RS
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fits in the larger scheme of SDN proposals, but also to inform the
requirements, framework, and specification of I2RS to provide the
best fit for the purposes which make the most sense for this type of
programmatic interface.
Towards this end the authors have searched for a number of different
use cases representing not only complex modifications of the control
plane, including interaction with applications and network
conditions, but also simpler use cases. The array of use cases
presented here should provide the reader with a solid understanding
of the power of an SDN solution that will augment, rather than
replace, traditional distributed control planes.
Each use case is presented in its own section.
2. Distributed Reaction to Network Based Attacks
Quickly modifying the control plane to reroute traffic for one
destination while leaving a standard configuration in place (filters,
metrics, and other policy mechanisms) is a challenge --but this is
precisely the challenge of a network engineer attempting to deal with
a network incursion. The ability to redirect specific flows of
information or specific classes of traffic into, through, and back
out of traffic analyzers on the fly is crucial in these situations.
The following network diagram provides an illustration of the
problem.
Valid Source---\ /--R2--------------------\
R1 R3---Valid Destination
Attack Source--/ \--Monitoring Device-----/
Modifying the cost of the link between R1 and R2 to draw the attack
traffic through the monitoring device in the distributed control
plane will, of necessity, also draw the valid traffic through the
monitoring device. Drawing valid traffic through a monitoring device
introduces delay, jitter, and other quality of service issues, as
well as posing a problem for the monitoring device itself in terms of
traffic load and management.
An I2RS controller could stand between the detection of the attack
and the control plane to facilitate the rapid modification of control
and forwarding planes to either block the traffic or redirect it to
analysis devices connected to the network.
Summary of IRS Capabilities and Interactions:
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o The ability to monitor the available routes installed in the RIB
of each forwarding device, including near real time notification
of route installation and removal. This information must include
the destination prefix (NLRI), a table identifier (if the
forwarding device has multiple forwarding instances), the metric
of the installed route, and an identifier indicating the
installing process.
o The ability to install source and destination based routes in the
local RIB of each forwarding device. This must include the
ability to supply the destination prefix (NLRI), the source prefix
(NLRI), a table identifier (if the forwarding device has multiple
forwarding instances), a route preference, a route metric, a next
hop, an outbound interface, and a route process identifier.
o The ability to install a route to a null destination, effectively
filtering traffic to this destination.
o The ability to interact with various policies configured on the
forwarding devices, in order to inform the policies implemented by
the dynamic routing processes. This interaction should be through
existing configuration mechanisms, such as NETCONF, and should be
recorded in the configuration of the local device so operators are
aware of the full policy implemented in the network from the
running configuration.
o The ability to interact with traffic flow and other network
traffic level measurement protocols and systems, in order to
determine path performance, top talkers, and other information
required to make an informed path decision based on locally
configured policy.
3. Remote Service Routing
In hub and spoke overlay networks, there is always an issue with
balancing between the information held in the spoke routing table,
optimal routing through the network underlying the overlay, and
mobility. Most solutions in this space use some form of centralized
route server that acts as a directory of all reachable destinations
and next hops, a protocol by which spoke devices and this route
server communicate, and caches at the remote sites.
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An I2RS solution would use the same elements, but with a different
control plane. Remote sites would register (or advertise through
some standard routing protocol, such as BGP), the reachable
destinations at each site, along with the address of the router (or
other device) used to reach that destination. These would, as
always, be stored in a route server (or several redundant route
servers) at a central location.
When a remote site sends a set of packets to the central location
that are eventually destined to some other remote site, the central
location can forward this traffic, but at the same time simply
directly insert the correct routing information into the remote
site's routing table. If the location of the destination changes,
the route server can directly modify the routing information at the
remote site as needed.
An interesting aspect of this solution is that no new and specialized
protocols are needed between the remote sites and the centralized
route server(s). Normal routing protocols can be used to notify the
centralized route server(s) of modifications in reachability
information, and the route server(s) can respond as needed, based on
local algorithms optimized for a particular application or network.
For instance, short lived flows might be allowed to simply pass
through the hub site with no reaction, while longer lived flows might
warrant a specific route to be installed in the remote router.
Algorithms can also be developed that would optimize traffic flow
through the overlay, and also to remove routing entries from remote
devices when they are no longer needed based on far greater
intelligence than simple non-use for some period of time.
Summary of IRS Capabilities and Interactions:
o The ability to read the local RIB of each forwarding device,
including the destination prefix (NLRI), a table identifier (if
the forwarding device has multiple forwarding instances), the
metric of each installed route, a route preference, and an
identifier indicating the installing process.
o The ability to monitor the available routes installed in the RIB
of each forwarding device, including near real time notification
of route installation and removal. This information must include
the destination prefix (NLRI), a table identifier (if the
forwarding device has multiple forwarding instances), the metric
of the installed route, and an identifier indicating the
installing process.
o The ability to install destination based routes in the local RIB
of each forwarding device. This must include the ability to
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supply the destination prefix (NLRI), a table identifier (if the
forwarding device has multiple forwarding instances), a route
preference, a route metric, a next hop, an outbound interface, and
a route process identifier.
4. Within Data Center Routing
Data Centers have evolved into massive topologies with thousands of
server racks and millions of hosts. Data Centers use BGP with ECMP,
ISIS (with multiple LAGs), or other protocols to tie the data center
together. Data centers are currently designed around a three or four
tier structure with: server, top-of-rack switches, aggregation
switches, and router interfacing the data center to the Internet.
[I-D.lapukhov-bgp-routing-large-dc] examines many of these elements
of data center design.
One element of these Data Center routing infrastructures is the
ability to quickly read topology information and execute
configuration from a centralized location. Key to this environment
is the tight feedback loop between learning about topology changes or
loading changes, and instantiating new routing policy. Without I2RS,
may Data Centers are using extra physical topologies or logical
topologies to work around the features.
An I2RS solution would use the same elements, but with a different
control plane. The I2RS enabled control plane could provide the Data
Center 4 tier infrastructure the quick access to topology and data
flow information needed for traffic flow optimization. Changes to
the Data Center infrastructure done via I2RS could have a tight
feedback loop.
Again, this solution would reduce the need for new and specialized
protocols while giving the Data Center the control it desire. The
I2RS routing interface could be extended to virtual routers.
Summary of IRS Capabilities and Interactions:
o The ability to read the local RIB of each forwarding device,
including the destination prefix (NLRI), a table identifier (if
the forwarding device has multiple forwarding instances), the
metric of each installed route, a route preference, and an
identifier indicating the installing process.
o The ability to monitor the available routes installed in the RIB
of each forwarding device, including near real time notification
of route installation and removal. This information must include
the destination prefix (NLRI), a table identifier (if the
forwarding device has multiple forwarding instances), the metric
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of the installed route, and an identifier indicating the
installing process.
o The ability to install destination based routes in the local RIB
of each forwarding device. This must include the ability to
supply the destination prefix (NLRI), a table identifier (if the
forwarding device has multiple forwarding instances), a route
preference, a route metric, a next hop, an outbound interface, and
a route process identifier.
o The ability to read the tables of other local protocol processes
running on the device. This reading action should be supported
through an import/export interface which can present the
information in a consistent manner across all protocol
implementations, rather than using a protocol specific model for
each type of available process.
o The ability to inject information directly into the local tables
of other protocol processes running on the forwarding device.
This injection should be supported through an import/export
interface which can inject routing information in a consistent
manner across all protocol implementations, rather than using a
protocol specific model for each type of available process.
o The ability to interact with various policies configured on the
forwarding devices, in order to inform the policies implemented by
the dynamic routing processes. This interaction should be through
existing configuration mechanisms, such as NETCONF, and should be
recorded in the configuration of the local device so operators are
aware of the full policy implemented in the network from the
running configuration.
o The ability to interact with traffic flow and other network
traffic level measurement protocols and systems, in order to
determine path performance, top talkers, and other information
required to make an informed path decision based on locally
configured policy.
5. Temporary Overlays between Data Centers
Data Centers within one organization may operate as one single entity
even though they may be geographically distributed. Applications are
load balanced within Data Centers and between data centers to take
advantage of cost economics in power, storage, and server
availability for compute resources. Applications are also transfer
to alternate data centers in case of failures within a data center.
To reduce time during failure, Data Centers often replicate user
storage between two or more data centers. During the transfer of
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stored information prior to a Data Center to Data Center move, the
Data Center controllers need to dynamically acquire a large amount of
inter-data center bandwidth through an overlay network, often during
off hours.
I2RS could provide the connection between the overlay network
configuration, local policies, and the control plane to dynamically
bring a large bandwidth inter-data center overlay or channel into
use, and then to remove it from use when the data transfer is
completed.
Similarly, during a fail-over, a control process within data centers
interacts with a group host process and the network to seamless move
the processing to another data center. During the fail-over case,
additional process state may need to be moved as well to restart the
system. The difference between these data-to-data center moves is
immediate and urgent need to move systems. If an application (such
as medical or banking services) pays to have this type of fail-over,
it is likely the service will pay for preemption on network
bandwidth. I2RS can allow the Data Center network and the Network
connecting the data center to preempt other best-effort traffic to
send this priority data flow. After the high priority data flow has
finished, networks can return to their previous condition.
Summary of IRS Capabilities and Interactions:
o The ability to read the local RIB of each forwarding device,
including the destination prefix (NLRI), a table identifier (if
the forwarding device has multiple forwarding instances), the
metric of each installed route, a route preference, and an
identifier indicating the installing process.
o The ability to monitor the available routes installed in the RIB
of each forwarding device, including near real time notification
of route installation and removal. This information must include
the destination prefix (NLRI), a table identifier (if the
forwarding device has multiple forwarding instances), the metric
of the installed route, and an identifier indicating the
installing process.
o The ability to install destination based routes in the local RIB
of each forwarding device. This must include the ability to
supply the destination prefix (NLRI), a table identifier (if the
forwarding device has multiple forwarding instances), a route
preference, a route metric, a next hop, an outbound interface, and
a route process identifier.
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o The ability to interact with various policies configured on the
forwarding devices, in order to inform the policies implemented by
the dynamic routing processes. This interaction should be through
existing configuration mechanisms, such as NETCONF, and should be
recorded in the configuration of the local device so operators are
aware of the full policy implemented in the network from the
running configuration.
o The ability to interact with policies and configurations on the
forwarding devices using time based processing, either through
timed auto-rollback or some other mechanism. This interaction
should be through existing configuration mechanisms, such as
NETCONF, and should be recorded in the configuration of the local
device so operators are aware of the full policy implemented in
the network from the running configuration.
o The ability to interact with traffic flow and other network
traffic level measurement protocols and systems, in order to
determine path performance, top talkers, and other information
required to make an informed path decision based on locally
configured policy.
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
[I-D.lapukhov-bgp-routing-large-dc]
Lapukhov, P., Premji, A., and J. Mitchell, "Use of BGP for
routing in large-scale data centers", draft-lapukhov-bgp-
routing-large-dc-06 (work in progress), August 2013.
[I-D.ward-i2rs-framework]
Atlas, A., Nadeau, T., and D. Ward, "Interface to the
Routing System Framework", draft-ward-i2rs-framework-00
(work in progress), February 2013.
Authors' Addresses
Russ White
IETF
Email: russw@riw.us
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Susan Hares
ADARA
Email: shares@ndzh.com
Alvaro Retana
Cisco Systems, Inc.
7025 Kit Creek Road
Research Triangle Park, NC 27617
USA
Email: aretana@cisco.com
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