Token bucket

The token bucket is an algorithm used in packet switched computer networks and telecommunications networks. It can be used to check that data transmissions, in the form of packets, conform to defined limits on bandwidth and burstiness (a measure of the unevenness or variations in the traffic flow). It can also be used as a scheduling algorithm to determine the timing of transmissions that will comply with the limits set for the bandwidth and burstiness: see network scheduler.

Overview

The token bucket algorithm is based on an analogy of a fixed capacity bucket into which tokens, normally representing a unit of bytes or a single packet of predetermined size, are added at a fixed rate. When a packet is to be checked for conformance to the defined limits, the bucket is inspected to see if it contains sufficient tokens at that time. If so, the appropriate number of tokens, e.g. equivalent to the length of the packet in bytes, are removed ("cashed in"), and the packet is passed, e.g., for transmission. The packet does not conform if there are insufficient tokens in the bucket, and the contents of the bucket are not changed. Non-conformant packets can be treated in various ways:

A conforming flow can thus contain traffic with an average rate up to the rate at which tokens are added to the bucket, and have a burstiness determined by the depth of the bucket. This burstiness may be expressed in terms of either a jitter tolerance, i.e. how much sooner a packet might conform (e.g. arrive or be transmitted) than would be expected from the limit on the average rate, or a burst tolerance or maximum burst size, i.e. how much more than the average level of traffic might conform in some finite period.

Algorithm

The token bucket algorithm can be conceptually understood as follows:

Variations

Implementers of this algorithm on platforms lacking the clock resolution necessary to add a single token to the bucket every seconds may want to consider an alternative formulation. Given the ability to update the token bucket every S milliseconds, the number of tokens to add every S milliseconds = .

Properties

Average rate

Over the long run the output of conformant packets is limited by the token rate, .

Burst size

Let M be the maximum possible transmission rate in bytes/second.

Then is the maximum burst time, that is the time for which the rate M is fully utilized.

The maximum burst size is thus

Uses

The token bucket can be used in either traffic shaping or traffic policing. In traffic policing, nonconforming packets may be discarded (dropped) or may be reduced in priority (for downstream traffic management functions to drop if there is congestion). In traffic shaping, packets are delayed until they conform. Traffic policing and traffic shaping are commonly used to protect the network against excess or excessively bursty traffic, see bandwidth management and congestion avoidance. Traffic shaping is commonly used in the network interfaces in hosts to prevent transmissions being discarded by traffic management functions in the network.

Comparison to leaky bucket

The token bucket algorithm is directly comparable to one of the two versions of the leaky bucket algorithm described in the literature.[1][2][3][4] This comparable version of the leaky bucket is described on the relevant Wikipedia page as the leaky bucket algorithm as a meter. This is a mirror image of the token bucket, in that conforming packets add fluid, equivalent to the tokens removed by a conforming packet in the token bucket algorithm, to a finite capacity bucket, from which this fluid then drains away at a constant rate, equivalent to the process in which tokens are added at a fixed rate.

There is, however, another version of the leaky bucket algorithm,[2] described on the relevant Wikipedia page as the leaky bucket algorithm as a queue. This is a special case of the leaky bucket as a meter, which can be described by the conforming packets passing through the bucket. The leaky bucket as a queue is therefore applicable only to traffic shaping, and does not, in general, allow the output packet stream to be bursty, i.e. it is jitter free. It is therefore significantly different from the token bucket algorithm.

These two versions of the leaky bucket algorithm have both been described in the literature under the same name. This has led to considerable confusion over the properties of that algorithm and its comparison with the token bucket algorithm. However, fundamentally, the two algorithms are the same, and will, if implemented correctly and given the same parameters, see exactly the same packets as conforming and nonconforming.

Hierarchical token bucket

The hierarchical token bucket (HTB) is a faster replacement for the class-based queueing (CBQ) queuing discipline in Linux.[5] It is useful to limit a client's download/upload rate so that the limited client cannot saturate the total bandwidth.

Conceptually, HTB is an arbitrary number of token buckets arranged in a hierarchy. The primary egress queuing discipline on any device is known as the root qdisc. The root qdisc will contain one class. This single HTB class will be set with two parameters, a rate and a ceil. These values should the same for the top-level class, and will represent the total available bandwidth on the link.

In HTB, rate means the guaranteed bandwidth available for a given class and ceil is short for ceiling, which indicates the maximum bandwidth that class is allowed to consume. Any bandwidth used between rate and ceil is borrowed from a parent class, hence the suggestion that rate and ceil be the same in the top-level class.

Hierarchical Token Bucket implements a classful queuing mechanism for the linux traffic control system, and provides rate and ceil to allow the user to control the absolute bandwidth to particular classes of traffic as well as indicate the ratio of distribution of bandwidth when extra bandwidth become available(up to ceil).

When choosing the bandwidth for a top-level class, traffic shaping only helps at the bottleneck between the LAN and the Internet. Typically, this is the case in home and office network environments, where an entire LAN is serviced by a DSL or T1 connection.

See also

References

  1. Turner, J., New directions in communications (or which way to the information age?). Communications Magazine, IEEE 24 (10): 8–15. ISSN 0163-6804, 1986.
  2. 1 2 Andrew S. Tanenbaum, Computer Networks, Fourth Edition, ISBN 0-13-166836-6, Prentice Hall PTR, 2003., page 401.
  3. ATM Forum, The User Network Interface (UNI), v. 3.1, ISBN 0-13-393828-X, Prentice Hall PTR, 1995.
  4. ITU-T, Traffic control and congestion control in B ISDN, Recommendation I.371, International Telecommunication Union, 2004, Annex A, page 87.
  5. "Linux HTB Home Page". Retrieved 2013-11-30.

Further reading

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