Network Working Group P. Srisuresh
Request for Comments: 2391 Lucent Technologies
Category: Informational D. Gan
Juniper Networks, Inc.
August 1998
Load Sharing using IP Network Address Translation (LSNAT)
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 (1998). All Rights Reserved.
Preface
This document combines the idea of address translation described in
RFC 1631 with real-time load share algorithms to introduce Load Share
Network Address Translators(or, simply LSNATs). LSNATs would
transparently offload network load on a single server and distribute
the load across a pool of servers.
Abstract
Network Address Translators (NATs) translate IP addresses in a
datagram, transparent to end nodes, while routing the datagram. NATs
have traditionally been been used to allow private network domains to
connect to Global networks using as few as one globally unique IP
address. In this document, we extend the use of NATs to offer Load
share feature, where session load can be distributed across a pool of
servers, instead of directing to a single server. Load sharing is
beneficial to service providers and system administrators alike in
grappling with scalability of servers with increasing session load.
Traditionally, Network Address Translators, or simply NATs were used
to connect private network domains to globally unique public domain
IP networks. Applications originate in private domains and NATs would
transparently translate datagrams belonging to these applications in
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either direction. This document combines the characteristic of
transparent address translation with real-time load share algorithms
to introduce Load Share Network Address Translators.
The problem of Load sharing or Load balancing is not new and goes
back many years. A variety of techniques were applied to address the
problem. Some very ad-hoc and platform specific and some employing
clever schemes to reorder DNS resource records. REF [11] uses DNS
zone transfer program in name servers to periodically shuffle the
order of resource records for server nodes based on a pre-determined
load balancing algorithm. The problem with this approach is that
reordering time periods can be very large on the order of minutes and
does not reflect real-time load variations on the servers. Secondly,
all hosts in the server pool are assumed to have equal capability to
offer all services. This may not often be the case. In addition,
there may be requirement to support load balancing for a few specific
services only. The load share approach outlined in this document
addresses both these concerns and offers a solution that does not
require changes to clients or servers and one that can be tailored to
individual services or for all services.
For the reminder of this document, we will refer to NAT routers that
provide load sharing support as LSNATs. Unlike traditional NATs,
LSNATs are not required to operate between private and public domain
routing realms alone. LSNATs also operate in a single routing realm
and provide load sharing functionality.
The need for Load sharing arises when a single server is not able to
cope with increasing demand for multiple sessions simultaneously.
Clearly, load sharing across multiple servers would enhance
responsiveness and scale well with session load. Popular applications
inundating servers would include Web browsers, remote login, file
transfer and mail applications.
When a client attempts to access a server through an LSNAT router,
the router selects a node in server pool, based on a load share
algorithm and redirect the request to that node. LSNATs pose no
restriction on the organization and rearrangement of nodes in server
pool. Nodes in a pool may be replaced, new nodes may be added and
others may be in transition. Changes of this kind to server pool can
be shielded from client nodes by making LSNAT router the focal point
for change management.
There are limitations to using LSNATs. Firstly, it is mandatory that
all requests and responses pertaining to a session between a client
and server be routed via the same LSNAT router. For this reason, we
recommend LSNATs to be operated on a single border router to a stub
domain in which the server pool would be confined. This would ensure
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that all traffic directed to servers from clients outside the domain
and vice versa would necessarily traverse the LSNAT border router.
Later in the document, we will examine a special case of LSNAT setup,
which gets around the topological constraint on server pool. Another
limitation of LSNATs is the inability to switch loads between hosts
in the midst of sessions. This is because LSNATs measure load in
granularity of sessions. Once a session is assigned to a host, the
session cannot be moved to a different host till the end of that
session. Other limitations, inherent to NATs, as outlined in REF [1]
are also applicable to LSNATs.
As with traditional NATs, LSNATs have the disadvantage of taking away
the end-to-end significance of an IP address. The major advantage,
however, is that it can be installed without changes to clients or
servers.
For the reminder of this document, we will refer TCP/UDP ports
associated with an IP address simply as "TU ports".
For most TCP/IP hosts, TU port range 0-1023 is used by servers
listening for incoming connections. Clients trying to initiate a
connection typically select a TU port in the range of 1024-65535.
However, this convention is not universal and not always followed. It
is possible for client nodes to initiate connections using a TU port
number in the range of 0-1023, and there are applications listening
on TU port numbers in the range of 1024-65535.
A complete list of TU port services may be found in REF [2]. The TU
ports used by servers to listen for incoming connections are called
"Server Ports" and the TU ports used by clients to initiate a
connection to server are called "Client Ports".
Connection or session flows are different from packet flows. A
session flow indicates the direction in which the session was
initiated with reference to a network port. Packet flow is the
direction in which the packet has traversed with reference to a
network port. A session flow is uniquely identified by the direction
in which the first packet of that session traversed.
Take for example, a telnet session. The telnet session consists of
packet flows in both inbound and outbound directions. Outbound telnet
packets carry terminal keystrokes from the client and inbound telnet
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packets carry screen displays from the telnet server. Performing
address translation for a telnet session would involve translation of
incoming as well as outgoing packets belonging to that session.
Packets belonging to a TCP/UDP session are uniquely identified by
the tuple of (source IP address, source TU port, target IP address,
target TU port). ICMP sessions that correlate queries and responses
using query id are uniquely identified by the tuple of (source IP
address, ICMP Query Identifier, target IP address). For lack of
well-known ways to distinguish, all other types of sessions are
lumped together and distinguished by the tuple of (source IP address,
IP protocol, target IP address).
The first packet of every TCP session tries to establish a session
and contains connection startup information. The first packet of a
TCP session may be recognized by the presence of SYN bit and absence
of ACK bit in the TCP flags. All TCP packets, with the exception of
the first packet must have the ACK bit set.
The first packet of every session, be it a TCP session, UDP session,
ICMP query session or any other session, tries to establish a
session. However, there is no deterministic way of recognizing the
start of a UDP session or any other non-TCP session.
Start of session is significant with NATs, as a state describing
translation parameters for the session is established at the start
of session. Packets pertaining to the session cannot undergo
translation, unless a state is established by NAT at the start of
session.
The end of a TCP session is detected when FIN is acknowledged by both
halves of the session or when either half receives RST bit in TCP
flags field. Within a short period (say, a couple of seconds) after
one of the session partners sets RST bit, the session can be safely
assumed to have been terminated.
For all other types of session, there is no deterministic way of
determining the end of session unless you know the application
protocol. Many heuristic approaches are used to terminate sessions.
You can make the assumption that TCP sessions that have not been used
for say, 24 hours, and non-TCP sessions that have not been used for
say, 1 minute, are terminated. Often this assumption works, but
sometimes it doesn't. These idle period session timeouts may vary
considerably across the board and may be made user configurable.
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Another way to handle session terminations is to timestamp sessions
and keep them as long as possible and retire the longest idle session
when it becomes necessary.
Basic NAT is a method by which hosts in a private network domain are
allowed access to hosts in the external network transparently. A
block of external addresses are set aside for translating addresses
of private hosts as the private hosts originate sessions to
applications in external domain. Once an external address is bound by
the NAT device to a specific private address, that address binding
remains in place for all subsequent sessions originating from the
same private host. This binding may be terminated when there are no
sessions left to use the binding.
Network Address Port Translation(NAPT) is a method by which hosts in
a private network domain are allowed simultaneous access to hosts in
the external network transparently using a single registered address.
This is made possible by multiplexing transport layer identifiers of
private hosts into the transport identifiers of the single assigned
external address. For this reason, only the applications based on TCP
and UDP protocols are supported by NAPT. ICMP query based
applications are also supported as the ICMP header carries a query
identifier that is used to corelate responses with requests.
Sessions other than TCP, UDP and ICMP query type are simply not
permitted from local nodes, serviced by a NAPT router.
Load sharing for the purpose of this document is defined as the
spread of session load amongst a cluster of servers which are
functionally similar or the same. In other words, each of the nodes
in cluster can support a client session equally well with no
discernible difference in functionality. Once a node is assigned to
service a session, that session is bound to that node till
termination. Sessions are not allowed to swap between nodes in the
midst of session.
Load sharing may be applicable for all services, if all hosts in
server cluster carry the capability to carry out all services.
Alternately, load sharing may be limited to one or more specific
services alone and not to others.
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Note, the term "Session load" used in the context of load share is
different from the term "system load" attributed to hosts by way of
CPU, memory and other resource usage on the system.
While both traditional NATs and LSNATs perform address translations,
and provide transparent connectivity between end nodes, there are
distinctions between the two. Traditional NATs initiate translations
on outbound sessions, by binding a private address to a global
address (basic NAT) or by binding a tuple of private address and
transport identifier (such as TCP/UDP port or ICPM query ID) to a
tuple of global address and transport identifier. LSNATs, on the
other hand, initiate translations on inbound sessions, by binding
each session represented by a tuple such as (client address, client
TU port, virtual server address, server TU port) to one of server
pool nodes, selected based on a real-time load-share algorithm. A
virtual server address is a globally unique IP address that
identifies a physical server or a group of servers that can provide
similar or same functionality.
For the reminder of this document, we will refer traditional NATs
simply as NATs and refer LSNATs exclusively in the context of load
share, without implying traditional NAT functionality.
LSNATs are not limited to operate between private and public domain
routing realms. LSNATs may operate within a single routing realm with
globally unique IP addresses, just as well as between private and
public network domains. The only requirement is that server pool be
confined to a stub domain, accessible to clients outside the domain
through a single LSNAT border router. However, as you will notice
later, this topology limitation on server pool can be overcome under
certain configurations.
Load Share NAT operates as follows. A client attempts to access a
server by using the server virtual address. The LSNAT router
transparently redirects the request to one of the hosts in server
pool, selected using a real-time load sharing algorithm. Multiple
sessions may be initiated from the same client, and each session
could be directed to a different host based on load balance across
server pool hosts at the time. If load share is desired for just a
few specific services, the configuration on LSNAT could be defined to
restrict load share for just the services desired.
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In the case where virtual server address is same as the interface
address of an LSNAT router, server applications (such as telnet) on
LSNAT router must be disabled for external access on that address.
This is the limitation to using address owned by LSNAT router as the
virtual server address.
Load share NAT operation is also applicable during individual server
upgrades as follows. Say, a server, that needs to be upgraded is
statically mapped to a backup server on the inbound. Subsequent to
this mapping, new session requests to the original server would be
redirected by LSNAT to the backup server. As an extension, it is
also possible to statically map a specific TU port service on a
server to that of backup sever.
We illustrate the operation of LSNAT in the following subsections,
where (a) servers are confined to a stub domain, and belong to
globally unique address space as shared by clients, (b) servers are
confined to private address space stub domain, and (c) servers are
not restrained by any topological limitations.
In this section, we will illustrate the operation of LSNAT in a
globally unique address space. The border router with LSNAT enabled
on WAN link would perform load sharing and address translations for
inbound sessions. However, sessions outbound from the hosts in server
pool will not be subject to any type of translation, as all nodes
have globally unique IP addresses.
In the example below, servers S1 (172.85.0.1), S2(172.85.0.2) and
S3(172.85.0.3) form a server pool, confined to a stub domain. LSNAT
on the border router is enabled on the WAN link, such that the
virtual server address S(172.87.0.100) is mapped to the server pool
consisting of hosts S1, S2 and S3. When a client 198.76.29.7
initiates a HTTP session to the virtual server S, the LSNAT router
examines the load on hosts in server pool and selects a host, say S1
to service the request. The transparent address and TU port
translations performed by the LSNAT router become apparent as you
follow the down arrow line. IP packets on the return path go through
similar address translation. Suppose, we have another client
198.23.47.2 initiating telnet session to the same virtual server S.
The LSNAT would determine that host S3 is a better choice to service
this session as S1 is busy with a session and redirect the session to
S3. The second session redirection path is delineated with colons.
The procedure continues for any number of sessions the same way.
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Notice that this requires no changes to clients or servers. All the
configuration and mapping necessary would be limited just to the
LSNAT router.
\ | /
+---------------+
|Backbone Router|
+---------------+
WAN |
|
Stub domain border .......|.........
|
{s=198.76.29.7, 2745, v | {s=198.23.47.2, 3200,
d=172.87.0.100, 80 } v | d=172.87.0.100, 23 }
v +------------------+ :
v |Border Router with| :
v |LSNAT enabled on | :
v |WAN interface | :
v +------------------+ :
v | :
v | LAN :
------v----------------------:---
{s=198.76.29.7, 2745, v | | |:{s=198.23.47.2, 3200,
d=172.85.0.1, 80 } | | | d=172.85.0.3, 23 }
+--+ +--+ +--+
|S1| |S2| |S3|
|--| |--| |--|
/____\ /____\ /____\
172.85.0.1 172.85.0.2 172.85.0.3
Figure 1: Operation of LSNAT in Globally unique address space
In this section, we will illustrate the operation of LSNAT in
conjunction with NAT on the same router. The NAT configuration is
required for translation of outbound sessions and could be either
Basic NAT or NAPT. The illustration below will assume NAPT on the
outbound and LSNAT on the inbound on WAN link.
Say, an organization has a private IP network and a WAN link to
backbone router. The private network's stub router is assigned a
globally valid address on the WAN link and the remaining nodes in the
organization have IP addresses that have only local significance. The
border router is NAPT configured on the outbound allowing access to
external hosts, using the single registered IP address.
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In addition, say the organization has servers S1 (10.0.0.1),
S2(10.0.0.2) and S3 (10.0.0.3) that form a pool to provide inbound
access to external clients. This is made possible by enabling LSNAT
on the WAN link of the border router, such that virtual server
address S(198.76.28.4) is mapped to the server pool consisting of
hosts S1, S2 and S3. When an external client 198.76.29.7 initiates a
HTTP session to the virtual server S, the LSNAT router examines load
on hosts in server pool and selects a host, say S1 to service the
request. The transparent address and TU port translations performed
by the LSNAT router are apparent as you follow the down arrow line.
IP packets on the return path go through similar address translation.
Suppose, we have another client 198.23.47.2 initiating telnet session
to the same address. The LSNAT would determine that host S3 is a
better choice to service this session as S1 is busy with a session
and redirect the session to S3. The second session redirection path
is delineated with colons. The procedure continues for any number of
sessions the same way.
\ | /
+---------------+
|Backbone Router|
+---------------+
WAN |
|
Stub domain border ........|.........
|
{s=198.76.29.7, 2745, v | {s=198.23.47.2, 3200,
d=198.76.28.4, 80 }v | :d=198.76.28.4, 23 }
v+-------------------+:
v|Border Router with |:
v| LSNAT and NAPT |:
v|enabled on WAN link|:
v+-------------------+:
v | :
v | LAN :
------v---------------------:------
{s=198.76.29.7, 2745, v | | | : {s=198.23.47.2, 3200,
d=10.0.0.1, 80 } | | | d=10.0.0.3, 23 }
+--+ +--+ +--+
|S1| |S2| |S3|
|--| |--| |--|
/____\ /____\ /____\
10.0.0.1 10.0.0.2 10.0.0.3
Figure 2: Operation of LSNAT, in coexistence with NAPT
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RFC 2391 LSNAT August 1998
Once again, notice that this requires no changes to clients or
servers. The translation is completely transparent to end nodes.
Address mapping on the LSNAT performs load sharing and address
translations for inbound sessions. Sessions outbound from hosts in
server pool are subject to NAPT. Both NAT and LSNAT co-exist with
each other in the same router.
In this section, we will illustrate a configuration in which load
sharing can be accomplished on a router without enforcing topological
limitations on servers. In this configuration, virtual server address
will be owned by the router that supports load sharing. I.e., virtual
server address will be same as address of one of the interfaces of
load share router. We will distinguish this configuration from LSNAT
by referring this as "Load Share Network Address Port Translation"
(LS-NAPT). Routers that support the LS-NAPT configuration will be
termed "LS-NAPT routers", or simply LS-NAPTs.
In an LSNAT router, inbound TCP/UDP sessions, represented by the
tuple of (client address, client TU port, virtual server address,
service port) are translated into a tuple of (client address, client
TU port, selected server address, service port). Translation is
carried out on all datagrams pertaining to the same session, in
either direction. Whereas, LS-NAPT router would translate the same
session into a tuple of (virtual server address, virtual server TU
port, selected server, service port). Notice that LS-NAPT router
translates the client address and TU port with the address and TU
port of virtual server, which is same as the address of one of its
interfaces. By doing this, datagrams from clients as well as servers
are forced to bear the address of LS-NAPT router as the destination
address, thereby guaranteeing that the datagrams would necessarily
traverse the LS-NAPT router. As a result, there is no need to require
servers to be under topological constraints.
Take for example, figure 1 in section 3.1. Let us say the router on
which load sharing is enabled is not just a border router, but can be
any kind of router. Let us also say that the virtual server address S
(172.87.0.100) is same as the address of WAN link and LS-NAPT is
enabled on the WAN interface. Figure 3 summarizes the new router
configuration.
When a client 198.76.29.7 initiates a HTTP session to the virtual
server address S (i.e., address of the WAN interface), the LS-NAPT
router examines load on hosts in server pool and selects a host, say
S1 to service the request. Appropriately, the destination address is
translated to be S1 (172.85.0.1). Further, original client address
and TU port are replaced with the address and TU port of the WAN
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link. As a result, destination addresses as well as source address
and source TU port are translated when the packet reaches S1, as can
be noticed from the down-arrow path. IP packets on the return path go
through similar translation. The second client 198.23.47.2 initiating
telnet session to the same virtual server address S is load share
directed to S3. This packet once again undergoes LS-NAPT translation,
just as with the first client. The data path and translations can be
noticed following the colon line. The procedure continues for any
number of sessions the same way. The translations made to datagrams
in either direction are completely transparent to end nodes.
\ | /
+---------------+
| Router |
+---------------+
WAN |
|
|
{s=198.76.29.7, 2745, v | {s=198.23.47.2, 3200,
d=198.76.28.4, 80 }v | 198.76.28.4 :d=198.76.28.4, 23 }
v +----------------+ :
v | A Router with | :
v | LS-NAPT enabled| :
v | on WAN link | :
v +----------------+ :
v | :
v LAN | :
------v---------------------:------
{s=198.76.28.4, 7001, v| | |:{s=198.76.28.4,7002,
d=172.85.0.1, 80 } | | | d=172.85.0.3, 23 }
+--+ +--+ +--+
|S1| |S2| |S3|
|--| |--| |--|
/____\ /____\ /____\
172.85.0.1 172.85.0.2 172.85.0.3
Figure 3: LS-NAPT configuration on a router
As you will notice, datagrams from clients as well as servers are
forced to be directed to the router, because they use WAN interface
address of router as the destination address in their datagrams. With
the assurance that all packets from clients and servers would
traverse the router, there is no longer a requirement for servers to
be confined to a stub domain and for LSNAT to be enabled only on
border router to the stub domain.
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The LS-NAPT configuration described in this section involves more
translations and hence is more complex compared to LSNAT
configurations described in the previous sections. While the
processing is complex, there are benefits to this configuration.
Firstly, it breaks down restraints on server topology. Secondly, it
scales with bandwidth expansion for client access. Even if Service
providers have one link today for client access, the LS-NAPT
configuration allows them to expand to more links in the future
guaranteeing the same LS-NAPT load share service on newer links.
The configuration is not without its limitations. Server applications
(such as telnet) on the router box would have to be disabled for the
interface address assigned to be virtual server address. Load sharing
would be limited to TCP and UDP applications only. Maximum
concurrently allowed sessions would be limited by the maximum allowed
TCP/UDP client ports on the same address. Assuming that ports 0-1023
must be set aside as well-known service ports, that would leave a
maximum of 63K TCP client ports and 63K of UDP client ports on the
LS-NAPT router to communicate with each load-share server. As a
result, LS-NAPT routers will not be able to concurrently support more
than a maximum of (63K * count of Load-share servers) TCP sessions
and (63K * count of Load-share servers) UDP sessions.
Session binding is the phase in which an incoming session is
associated with the address of a host in server pool. This
association essentially sets the translation parameters for all
subsequent datagrams pertaining to the session. For addresses that
have static mapping, the binding happens at startup time. Otherwise,
each incoming session is dynamically bound to a different host based
on a load sharing algorithm.
Once session binding is established for a connection setup, all
subsequent packets belonging to the same connection will be subject
to session lookup for translation purposes.
For outbound packets of a session, the source IP address (and source
TU port, in case of TCP/UDP sessions) and related fields (such as IP,
TCP, UDP and ICMP header checksums) will undergo translation. For
inbound packets of a session, the destination IP address (and
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destination TU port, in case of TCP/UDP sessions) and related fields
such as IP, TCP, UDP and ICMP header checksums) will undergo
translation.
The header and payload modifications made to IP datagrams subject to
LSNAT will be exactly same as those subject to traditional NATs,
described in section 5.0 of REF [1]. Hence, the reader is urged to
refer REF [1] document for packet translation process.
Session unbinding is the phase in which a server node is no longer
responsible for the session. Usually, session unbinding happens when
the end of session is detected. As described in the terminology
section, it is not always easy to determine end of session.
Many algorithms are available to select a host from a pool of servers
to service a new session. The load distribution is based primarily on
(a) cost of accessing the network on which a server resides and load
on the network interface used to access the server, and (b)resource
availability and system load on the server. A variety of policies can
be adapted to distribute sessions across the servers in a server
pool.
For simplicity, we will consider two types algorithms, based on
proximity between server nodes and LSNAT router. The higher the cost
of access to a sever, the farther the proximity of server is assumed
to be. The first kind of algorithms will assume that all server pool
members are at equal or nearly equal proximity to LSNAT router and
hence the load distribution can be based solely on resource
availability or system load on remote servers. Cost of network access
will be considered irrelevant. The second kind would assume that all
server pool members have equal resource availability and the criteria
for selection would be proximity to servers. In other words, we
consider algorithms which take into account the cost of network
access.
Ideally speaking, the selection process would have precise knowledge
of real-time resource availability and system load for each host in
server pool, so that the selection of host with maximum unutilized
capacity would be the obvious choice. However, this is not so easy to
achieve.
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We consider here two kinds of heuristic approaches to monitor session
load on server pool members. The first kind is where the load share
selector tracks system load on individual servers in non-intrusive
way. The second kind is where the individual members actively
participate in communicating with the load share selector, notifying
the selector of their load capacity.
Listed below are the most common selection algorithms adapted in the
non-intrusive category.
1. Round-Robin algorithm
This is the simplest scheme, where a host is selected simply on a
round robin basis, without regard to load on the host.
2. Least Load first algorithm
This is an improvement over round-robin approach, in that, the
host with least number of sessions bound to it is selected to
service a new session. This approach is not without its caveats.
Each session is assumed to be as resource consuming as any other
session, independent of the type of service the session represents
and all hosts in server pool are assumed to be equally
resourceful.
3. Least traffic first algorithm
A further improvement over the previous algorithm would be to
measure system load by tracking packet count or byte count
directed from or to each of the member hosts over a period of
time. Although packet count is not the same as system load, it is
a reasonable approximation.
4. Least Weighted Load first approach
This would be an enhancement to the first two. This would allow
administrators to assign (a) weights to sessions, based on likely
resource consumption estimates of session types and (b) weights to
hosts based on resource availability.
The sum of all session loads by weight assigned to a server,
divided by weight of server would be evaluated to select the
server with least weighted load to assign for each new session.
Say, FTP sessions are assigned 5 times the weight(5x) as a telnet
session(x), and server S3 is assumed to be 3 times as resourceful
as server S1. Let us also say that S1 is assigned 1 FTP session
and 1 telnet session, whereas S3 is assigned 2 FTP sessions and 5
telnet sessions. When a new telnet session need assignment, the
weighted load on S3 is evaluated to be (2*5x+5*x)/3 = 5x, and the
load on S1 is evaluated to be (1*5x+1*x) = 6x. Server S3 is
selected to bind the new telnet session, as the weighted load on
S3 is smaller than that of S1.
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5. Ping to find the most responsive host.
Till now, capacity of a member host is determined exclusively by
the LSNAT using heuristic approaches. In reality, it is impossible
to predict system capacity from remote, without interaction with
member hosts. A prudent approach would be to periodically ping
member hosts and measure the response time to determine how busy
the hosts really are. Use the response time in conjunction with
the heuristics to select the host most appropriate for the new
session.
In the active category, we involve individual member hosts in
resource utilization monitoring process. An agent software on each
node would notify the monitoring agent on resource availability.
Clearly, this would imply having an application program (one that
does not consume significant resources, by itself) to run on each
member node. This strategy of involving member hosts in system load
monitoring is likely to yield the most optimal results in the
selection process.
When server nodes are distributed geographically across different
areas and cost to access them vary widely, the load share selector
could use that information in selecting a server to service a new
session. In order to do this, the load share selector would need to
consult the routing tables maintained by routing protocols such as
RIP and OSPF to find the cost of accessing a server.
All algorithms listed below would be non-intrusive kind where the
server nodes do not actively participate in notifying the load share
selector of their load capacity.
1. Weighted Least Load first algorithm
The selection criteria would be based on (a) cost of access to
server, and (b) the number of sessions assigned to server. The
product of cost and session load for each server would be
evaluated to select the server with least weighted load for each
new session. Say, cost of accessing server S1 is twice as much as
that of server S2. In that case, S1 will be assigned twice as much
load as that of S2 during the distribution process. When a server
is not accessible due to network failure, the cost of access is
set to infinity and hence no further load can be assigned to that
server.
2. Weighted Least traffic first algorithm
An improvement over the previous algorithm would be
to measure network load by tracking packet count or byte
count directed from or to each of the member hosts over a
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RFC 2391 LSNAT August 1998
period of time. Although packet count is not the same as
system load, it is a reasonable approximation. So, the
product of cost and traffic load (over a fixed duration)
for each server would be evaluated to select the server
with least weighted traffic load for each new session.
As sessions are assigned to hosts, it is important to detect the
live-ness of the hosts. Otherwise, sessions could simply be black-
holed into a dead host. Many heuristic approaches are adopted.
Sending pings periodically would be one way to determine the live-
ness. Another approach would be to track datagrams originating from a
member host in response to new session assignments. If no response
is detected in a few seconds, declare the server dead and do not
assign new sessions to this host. The server can be monitored later
again after a long pause (say, in the order of a few minutes) by
periodically reassigning new sessions and monitoring response times
and so on.
The IETF has been notified of potential intellectual Property Rights
(IPR) issues with the technology described in this document.
Interested people are requested to look in the IETF web page
(http://www.ietf.org) under the Intellectual property Rights Notices
section for the current information.
All security considerations associated with NAT routers, described in
REF [1] are applicable to LSNAT routers as well.
REFERENCES
[1] Egevang, K. and P. Francis, "The IP Network Address Translator
(NAT)", RFC 1631, May 1994.
[2] Reynolds, J., and J. Postel, "Assigned Numbers", STD 2, RFC 1700,
October 1994. See also: http://www.iana.org/numbers.html
[3] Braden, R., "Requirements for Internet Hosts -- Communication
Layers", STD 3, RFC 1122, October 1989.
[4] Braden, R., "Requirements for Internet Hosts -- Application and
Support", STD 3, RFC 1123, October 1989.
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RFC 2391 LSNAT August 1998
[5] Baker, F., "Requirements for IP Version 4 Routers", RFC 1812,
June 1995.
[6] Postel, J., and J. Reynolds, "File Transfer Protocol (FTP)", STD
9, RFC 959, October 1985.
[7] Postel, J., "Transmission Control Protocol", STD 7, RFC 793,
September 1981.
[8] Postel, J., "Internet Control Message (ICMP) Specification", STD
5, RFC 792, September 1981.
[9] Postel, J., "User Datagram Protocol (UDP)", STD 6, RFC 768,
August 1980.
[10] Mogul, J., and J. Postel, "Internet Standard Subnetting
Procedure", STD 5, RFC 950, August 1985.
[11] Brisco, T., "DNS Support for Load Balancing", RFC 1794, April
1995.
Authors' Addresses
Pyda Srisuresh
Lucent Technologies
4464 Willow Road
Pleasanton, CA 94588-8519
U.S.A.
Voice: (925) 737-2153
Fax: (925) 737-2110
EMail: suresh@ra.lucent.com
Der-hwa Gan
Juniper Networks, Inc.
385 Ravensdale Drive.
Mountain View, CA 94043
U.S.A.
Voice: (650) 526-8074
Fax: (650) 526-8001
EMail: dhg@juniper.net
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RFC 2391 LSNAT August 1998
Full Copyright Statement
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