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RFC3237 - Requirements for Reliable Server Pooling

王朝other·作者佚名  2008-05-31
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Network Working Group M. Tuexen

Request for Comments: 3237 Siemens AG

Category: Informational Q. Xie

Motorola

R. Stewart

M. Shore

Cisco

L. Ong

Ciena

J. Loughney

M. Stillman

Nokia

January 2002

Requirements for Reliable Server Pooling

Status of this Memo

This memo provides information for the Internet community. It does

not specify an Internet standard of any kind. Distribution of this

memo is unlimited.

Copyright Notice

Copyright (C) The Internet Society (2002). All Rights Reserved.

Abstract

This document defines a basic set of requirements for reliable server

pooling.

The goal of Reliable Server Pooling (RSerPool) is to develop an

architecture and protocols for the management and operation of server

pools supporting highly reliable applications, and for client Access

mechanisms to a server pool.

1. IntrodUCtion

1.1. Overview

The Internet is always on. Many users eXPect services to be always

available; many businesses depend upon connectivity 24 hours a day, 7

days a week, 365 days a year. In order to fulfill this level of

performance, many proprietary solutions and operating system

dependent solutions have been developed to provide highly reliable

and highly available servers.

This document defines requirements for an architecture and protocols

enabling pooling of servers to support high reliability and

availability for applications.

The range of applications that can benefit from reliable server

pooling includes both mobile and real-time applications. Reliable

server pooling mechanisms will be designed to support functionality

for flexible pooling such as registration and deregistration, and

load balancing of traffic across the server pool. Mechanisms will

need to balance the needs of scalability, overhead traffic and

response time to changes in pool status, as discussed below.

1.2. Terminology

This document uses the following terms:

Operation scope:

The part of the network visible to pool users by a specific

instance of the reliable server pooling protocols.

Pool (or server pool):

A collection of servers providing the same application

functionality.

Pool handle (or pool name):

A logical pointer to a pool. Each server pool will be

identifiable in the operation scope of the system by a unique

pool handle or "name".

Pool element:

A server entity having registered to a pool.

Pool user:

A server pool user.

Pool element handle (or endpoint handle):

A logical pointer to a particular pool element in a pool,

consisting of the name of the pool and one or more destination

transport addresses for the pool element.

Name space:

A cohesive structure of pool names and relations that may be

queried by an internal or external agent.

Name server:

Entity which is responsible for managing and maintaining the

name space within the RSerPool operation scope.

RSerPool:

The architecture and protocols for reliable server pooling.

1.3. Abbreviations

PE: Pool element

PU: Pool user

SCTP: Stream Control Transmission Protocol

TCP: Transmission Control Protocol

2. Requirements

2.1. Robustness

The solution must allow itself to be implemented and deployed in such

a way that there is no single point of failure in the system.

2.2. Failover Support

The RSerPool architecture must be able to detect failure of pool

elements and name servers supporting the pool, and support failover

to available alternate resources.

2.3. Communication Model

The general architecture should support flexibility of the

communication model between pool users and pool elements, especially

allowing for a peer-to-peer relationship to support some

applications.

2.4. Processing Power

It should be possible to use the protocol stack in small devices,

like handheld wireless devices. The solution must scale to devices

with a differing range of processing power.

2.5. Transport Protocol

The protocols used for the pool handling should not cause network

congestion. This means that it should not generate heavy traffic,

even in case of failures, and has to use flow control and congestion

avoidance algorithms which are interoperable with currently deployed

techniques, especially the flow control of TCP [RFC793] and SCTP

[RFC2960] and must be compliant with [RFC2914].

The architecture should not rely on multicast capabilities of the

underlying layer. Nevertheless, it can make use of it if multicast

capabilities are available.

Network failures have to be handled and concealed from the

application layer as much as possible by the transport protocol.

This means that the underlying transport protocol must provide a

strong network failure handling capability on top of an acknowledged

error-free non-duplicated data delivery service. The failure of a

network element must be handled by the transport protocol in such a

way that the timing requirements are still fulfilled.

2.6. Support of RSerPool Unaware Clients

The architecture should allow for ease of interaction between pools

and non-RSerPool-aware clients. However, it is assumed that only

RSerPool-aware participants will receive maximum timing and

notification benefits the architecture offers.

2.7. Registering and Deregistering

Another important requirement is that servers should be able to

register to (become PEs) and deregister from a server pool

transparently without an interruption in service. This means that

after a PE has deregistered, it will continue to serve PUs which

started their connection before the deregistration of the PE. New

connections will be directed towards an alternative PE.

Servers should be able to register in multiple server pools which may

belong to different namespaces.

2.8. Naming

Server pools are identified by pool handles. These pool handles are

only valid inside the operation scope. Interoperability between

different namespaces has to be provided by other mechanisms.

2.9. Name Resolution

The name resolution should not result in a pool element which is not

operational. This might be important for fulfilling the timing

requirements described below.

2.10. Server Selection

The RSerPool mechanisms must be able to support different server

selection mechanisms. These are called server pool policies.

Examples of server pool policies are:

- Round Robin

- Least used

- Most used

The set of supported policies must be extensible in the sense that

new policies can be added as required. Non-stochastic and stochastic

policies can be supported.

There must be a way for the client to provide operational status

feedback to the name server about the pool elements.

The name server protocols must be extensible to allow more refined

server selection mechanisms to be implemented as they are developed

in the future.

For some applications it is important that a client repeatedly

connects to the same server in a pool if it is possible, i.e., if

that server is still alive. This feature should be supported through

the use of pool element handles.

2.11. Timing Requirements and Scaling

Handling of name resolution must be fast to support real-time

applications. Moreover, the name space should reflect pool

membership changes to the client application as rapidly as possible,

i.e., not waiting until the client application next reconnects.

The architecture should support control of timing parameters based on

specific needs, e.g., of an application or implementation.

In order to support more rapid and accurate response, the

requirements on scalability of the mechanism are limited to server

pools consisting of a suitably large but not Internet-wide number of

elements, as necessary to support bounded delay in handling real-time

name resolution.

Also, there is no requirement to support hierarchical organization of

name servers for scalability. Instead, it is envisioned that the set

of name servers supporting a particular pool is organized as a flat

space of equivalent servers. Accordingly, the impact of relatively

frequent updates to ensure accurate reflection of the status of pool

elements is limited to the set of name servers supporting a specific

pool.

2.12. Scalability

The RSerPool architecture should not require a limitation on the

number of server pools or on the number of pool users, although the

size of an individual pool may be limited by timing requirements as

defined above.

2.13. Security Requirements

2.13.1. General

- The scaling characteristics of the security architecture should be

compatible with those given previously.

- The security architecture should support hosts having a wide range

of processing powers.

2.13.2. Name Space Services

- It must not be possible for an attacker to falsely register as a

pool element with the name server either by masquerading as

another pool element or by registering in violation of local

authorization policy.

- It must not be possible for an attacker to deregister a server

which has successfully registered with the name server.

- It must not be possible for an attacker to spoof the response to a

query to the name server

- It must be possible to protect the privacy of queries to the name

server and responses to those queries from the name server.

- Communication among name servers must be afforded the same

protections as communication between clients and name servers.

2.13.3. Security State

The security context of an application is a subset of the overall

context, and context or state sharing is explicitly out-of-scope for

RSerPool. Because RSerPool does introduce new security

vulnerabilities to existing applications application designers

employing RSerPool should be aware of problems inherent in failing

over secured connections. Security services necessarily retain some

state and this state may have to be moved or re-established.

Examples of this state include authentication or retained ciphertext

for ciphers operating in cipher block chaining (CBC) or cipher

feedback (CFB) mode. These problems must be addressed by the

application or by future work on RSerPool.

3. Security Considerations

Security issues are discussed in section 2.13.

4. Acknowledgements

The authors would like to thank Bernard Aboba, Matt Holdrege, Eliot

Lear, Christopher Ross, Werner Vogels and many others for their

invaluable comments and suggestions.

5. References

[RFC793] Postel, J., "Transmission Control Protocol", STD 7, RFC

793, September 1981.

[RFC959] Postel, J. and J. Reynolds, "File Transfer Protocol (FTP)",

STD 9, RFC959, October 1985.

[RFC2026] Bradner, S., "The Internet Standards Process -- Revision

3", BCP 9, RFC2026, October 1996.

[RFC2608] Guttman, E., Perkins, C., Veizades, J. and M. Day, "Service

Location Protocol, Version 2", RFC2608, June 1999.

[RFC2719] Ong, L., Rytina, I., Garcia, M., Schwarzbauer, H., Coene,

L., Lin, H., Juhasz, I., Holdrege, M. and C. Sharp,

"Framework Architecture for Signaling Transport", RFC2719,

October 1999.

[RFC2914] Floyd, S., "Congestion Control Principles", BCP 41, RFC

2914, September 2000.

[RFC2960] Stewart, R., Xie, Q., Morneault, K., Sharp, C.,

Schwarzbauer, H., Taylor, T., Rytina, I., Kalla, M., Zhang,

L. and V. Paxson, "Stream Control Transmission Protocol",

RFC2960, November 2000.

6. Authors' Addresses

Michael Tuexen

Siemens AG

ICN WN CS SE 51

D-81359 Munich

Germany

Phone: +49 89 722 47210

EMail: Michael.Tuexen@icn.siemens.de

Qiaobing Xie

Motorola, Inc.

1501 W. Shure Drive, #2309

Arlington Heights, Il 60004

USA

Phone: +1 847 632 3028

EMail: qxie1@email.mot.com

Randall Stewart

Cisco Systems, Inc.

24 Burning Bush Trail

Crystal Lake, Il 60012

USA

Phone: +1 815 477 2127

EMail: rrs@cisco.com

Melinda Shore

Cisco Systems, Inc.

809 Hayts Rd

Ithaca, NY 14850

USA

Phone: +1 607 272 7512

EMail: mshore@cisco.com

Lyndon Ong

Ciena

10480 Ridgeview Court

Cupertino, CA 95014

USA

Phone: +1 408 366 3358

EMail: lyong@ciena.com

John Loughney

Nokia Research Center

PO Box 407

FIN-00045 Nokia Group

Finland

Phone: +358 50 483 6242

EMail: john.loughney@nokia.com

Maureen Stillman

Nokia

127 W. State Street

Ithaca, NY 14850

USA

Phone: +1 607 273 0724 62

EMail: maureen.stillman@nokia.com

7. Full Copyright Statement

Copyright (C) The Internet Society (2002). All Rights Reserved.

This document and translations of it may be copied and furnished to

others, and derivative works that comment on or otherwise explain it

or assist in its implementation may be prepared, copied, published

and distributed, in whole or in part, without restriction of any

kind, provided that the above copyright notice and this paragraph are

included on all such copies and derivative works. However, this

document itself may not be modified in any way, such as by removing

the copyright notice or references to the Internet Society or other

Internet organizations, except as needed for the purpose of

developing Internet standards in which case the procedures for

copyrights defined in the Internet Standards process must be

followed, or as required to translate it into languages other than

English.

The limited permissions granted above are perpetual and will not be

revoked by the Internet Society or its successors or assigns.

This document and the information contained herein is provided on an

"AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING

TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING

BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION

HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF

MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.

Acknowledgement

Funding for the RFCEditor function is currently provided by the

Internet Society.

 
 
 
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