Rate limiting

In computer networks, rate limiting is used to control the rate of requests sent or received by a network interface controller and is used to prevent DoS attacks.[1]

This article is about computer networks. For the rate-limiting step in chemical kinetics, see Rate-determining step. For rate limiting on Wikipedia, see meta:Tech/News/2018/30.

Hardware appliances

Hardware appliances can limit the rate of requests on layer 4 or 5 of the OSI model.

Rate limiting can be induced by the network protocol stack of the sender due to a received ECN-marked packet and also by the network scheduler of any router along the way.

While a hardware appliance can limit the rate for a given range of IP-addresses on layer 4, it risks blocking a network with many users which are masked by NAT with a single IP address of an ISP.

Deep packet inspection can be used to filter on the session layer but will effectively disarm encryption protocols like TLS and SSL between the appliance and the web server.

Web servers

Web servers typically use a central in-memory key-value database, like Redis or Aerospike, for session management. A rate limiting algorithm is used to check if the user session (or IP address) has to be limited based on the information in the session cache.

In case a client made too many requests within a given time frame, HTTP servers can respond with status code 429: Too Many Requests.

However, the session management and rate limiting algorithm usually must be built into the application running on the web server, rather than the web server itself.

Datacenters

Datacenters widely use rate limiting to control the share of resources given to different tenants and applications according to their service level agreement.[2] A variety of rate limiting techniques are applied in datacenters using software and hardware. Virtualized datacenters may also apply rate limiting at the hypervisor layer. Two important performance metrics of rate limiters in datacenters are resource footprint (memory and CPU usage) which determines scalability, and precision. There usually exists a trade-off, that is, higher precision can be achieved by dedicating more resources to the rate limiters. A considerable body of research exists with focus on improving performance of rate limiting in datacenters.[2]

See also
Algorithms
Libraries

References
  1. Richard A. Deal (September 22, 2004). "Cisco Router Firewall Security: DoS Protection". Retrieved April 16, 2017.
  2. M. Noormohammadpour, C. S. Raghavendra, "Datacenter Traffic Control: Understanding Techniques and Trade-offs," IEEE Communications Surveys & Tutorials, vol. PP, no. 99, pp. 1-1.
  3. Nikrad Mahdi (April 12, 2017). "An Alternative Approach to Rate Limiting". Retrieved April 16, 2017.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.