Difference between revisions of "Load balancing"

From LVSKB
Jump to: navigation, search
(Layer-2 Load Balancing)
(Layer-2 Load Balancing)
Line 13: Line 13:
 
=== Layer-2 Load Balancing ===
 
=== Layer-2 Load Balancing ===
  
Layer-2 load balancing, aka link aggregation, etherchannel, or port trunking is to bond two or more links into a single, higher-bandwidth logical link. Aggregated links also provide redundancy and fault tolerance if each of the aggregated links follows a different physical path. Link aggregation may be used to improve access to public networks by aggregating modem links or digital lines. Link aggregation may also be used in the enterprise network to build multigigabit backbone links between Gigabit Ethernet switches. See also NIC teaming or Link Aggregation Control Protocol(LACP)
+
Layer-2 load balancing, aka link aggregation, etherchannel, or gigabit etherchannel port bundling is to bond two or more links into a single, higher-bandwidth logical link. Aggregated links also provide redundancy and fault tolerance if each of the aggregated links follows a different physical path. Link aggregation may be used to improve access to public networks by aggregating modem links or digital lines. Link aggregation may also be used in the enterprise network to build multigigabit backbone links between Gigabit Ethernet switches. See also NIC teaming or Link Aggregation Control Protocol(LACP)
  
 
The Linux kernel has the Linux bonding driver, which can aggregate multiple links for higher throughput or fault tolerance.
 
The Linux kernel has the Linux bonding driver, which can aggregate multiple links for higher throughput or fault tolerance.

Revision as of 07:46, 2 February 2008

In computing, load balancing is a technique used to spread work load among many processes, computers, networks, disks or other resources, so that no single resource is overloaded.

Load balancing can also be considered as distributing items into buckets:

  • data to memory locations
  • files to disks
  • tasks to processors
  • packets to network interfaces
  • requests to servers

Its goal is even distribution.

Network Load Balancing

Layer-2 Load Balancing

Layer-2 load balancing, aka link aggregation, etherchannel, or gigabit etherchannel port bundling is to bond two or more links into a single, higher-bandwidth logical link. Aggregated links also provide redundancy and fault tolerance if each of the aggregated links follows a different physical path. Link aggregation may be used to improve access to public networks by aggregating modem links or digital lines. Link aggregation may also be used in the enterprise network to build multigigabit backbone links between Gigabit Ethernet switches. See also NIC teaming or Link Aggregation Control Protocol(LACP)

The Linux kernel has the Linux bonding driver, which can aggregate multiple links for higher throughput or fault tolerance.

Layer-4 Load Balancing

Layer-4 load balancing is to distribute requests to the servers at transport layer, such as TCP, UDP and SCTP transport protocol. The load balancer distributes network connections from clients who know a single IP address for a service, to a set of servers that actually perform the work. Since connection must be established between client and server in connection-oriented transport before sending the request content, the load balancer usually selects a server without looking at the content of the request.

IPVS is an implementation of layer-4 load balancing for the Linux kernel, and has been ported to FreeBSD recently.

Layer-4 load balancing can also be used to balance traffic at mutliple Internet access links, in order to increase Internet access speed. See DSL load balancing for more information.

Layer-7 Load Balancing

Layer-7 load balancing, also known as application-level load balancing, is to parse requests in application layer and distribute requests to servers based on different types of request contents, so that it can provide quality of service requirements for different types of contents and improve overall cluster performance. The overhead of parsing requests in application layer is high, thus its scalability is limited, compared to layer-4 load balancing.

KTCPVS is an implementation of layer-7 load balancing for the Linux kernel. With the appropriate modules, the Apache, Lighttpd and nginx web servers can also provide layer-7 load balancing as a reverse proxy.

MPLS Load Balancing

MPLS load balancing is to balance network services based on the Multiprotocol Label Switching (MPLS) label information.

See MPLS Load Balancing for more information..

DNS Load Balancing

DNS load balancing is to distribute requests to different servers though resolving the domain name to different IP addresses of servers. When a DNS request comes to the DNS server to resolve the domain name, it gives out one of the server IP addresses based on scheduling strategies, such as simple round-robin scheduling or geographical scheduling. This redirects the request to one of the servers in a server group. Once the domain is resolved to one of the servers in specified time-to-live, subsequent requests from the clients using the same local caching DNS server are sent to the same server.

More information is on the DNS Load Balancing page.

Link Load Balancing

Link load balancing is to balance traffic among multiple links from different ISPs or one ISP for better scalability and availability of Internet connectivity, and also cost saving.

See Link Load Balancing for more information.

Database Load Balancing

Database load balancing is to balance database access requests among cluster of database servers, in order to achieve database scalability and high availability.

SIP Load Balancing

SIP Load Balancing is to load balance SIP related services, in order to achieve performance scalability and high availability of the services.

Computing Load Balancing

Computing load balancing is to split a computational task across many different nodes in the cluster, so that the whole cluster system can provide increased performance. This kind of cluster systems is also known as High-performance cluster, which is most commonly used in scientific computing.