\section{\module{random} --- Generate pseudo-random numbers} \declaremodule{standard}{random} \modulesynopsis{Generate pseudo-random numbers with various common distributions.} This module implements pseudo-random number generators for various distributions. For integers, uniform selection from a range. For sequences, uniform selection of a random element, and a function to generate a random permutation of a list in-place. On the real line, there are functions to compute uniform, normal (Gaussian), lognormal, negative exponential, gamma, and beta distributions. For generating distribution of angles, the circular uniform and von Mises distributions are available. Almost all module functions depend on the basic function \function{random()}, which generates a random float uniformly in the semi-open range [0.0, 1.0). Python uses the standard Wichmann-Hill generator, combining three pure multiplicative congruential generators of modulus 30269, 30307 and 30323. Its period (how many numbers it generates before repeating the sequence exactly) is 6,953,607,871,644. While of much higher quality than the \function{rand()} function supplied by most C libraries, the theoretical properties are much the same as for a single linear congruential generator of large modulus. It is not suitable for all purposes, and is completely unsuitable for cryptographic purposes. The functions in this module are not threadsafe: if you want to call these functions from multiple threads, you should explicitly serialize the calls. Else, because no critical sections are implemented internally, calls from different threads may see the same return values. The functions supplied by this module are actually bound methods of a hidden instance of the \class{random.Random} class. You can instantiate your own instances of \class{Random} to get generators that don't share state. This is especially useful for multi-threaded programs, creating a different instance of \class{Random} for each thread, and using the \method{jumpahead()} method to ensure that the generated sequences seen by each thread don't overlap (see example below). Class \class{Random} can also be subclassed if you want to use a different basic generator of your own devising: in that case, override the \method{random()}, \method{seed()}, \method{getstate()}, \method{setstate()} and \method{jumpahead()} methods. Here's one way to create threadsafe distinct and non-overlapping generators: \begin{verbatim} def create_generators(num, delta, firstseed=None): """Return list of num distinct generators. Each generator has its own unique segment of delta elements from Random.random()'s full period. Seed the first generator with optional arg firstseed (default is None, to seed from current time). """ from random import Random g = Random(firstseed) result = [g] for i in range(num - 1): laststate = g.getstate() g = Random() g.setstate(laststate) g.jumpahead(delta) result.append(g) return result gens = create_generators(10, 1000000) \end{verbatim} That creates 10 distinct generators, which can be passed out to 10 distinct threads. The generators don't share state so can be called safely in parallel. So long as no thread calls its \code{g.random()} more than a million times (the second argument to \function{create_generators()}, the sequences seen by each thread will not overlap. The period of the underlying Wichmann-Hill generator limits how far this technique can be pushed. Just for fun, note that since we know the period, \method{jumpahead()} can also be used to ``move backward in time:'' \begin{verbatim} >>> g = Random(42) # arbitrary >>> g.random() 0.25420336316883324 >>> g.jumpahead(6953607871644L - 1) # move *back* one >>> g.random() 0.25420336316883324 \end{verbatim} Bookkeeping functions: \begin{funcdesc}{seed}{\optional{x}} Initialize the basic random number generator. Optional argument \var{x} can be any hashable object. If \var{x} is omitted or \code{None}, current system time is used; current system time is also used to initialize the generator when the module is first imported. If \var{x} is not \code{None} or an int or long, \code{hash(\var{x})} is used instead. If \var{x} is an int or long, \var{x} is used directly. Distinct values between 0 and 27814431486575L inclusive are guaranteed to yield distinct internal states (this guarantee is specific to the default Wichmann-Hill generator, and may not apply to subclasses supplying their own basic generator). \end{funcdesc} \begin{funcdesc}{whseed}{\optional{x}} This is obsolete, supplied for bit-level compatibility with versions of Python prior to 2.1. See \function{seed} for details. \function{whseed} does not guarantee that distinct integer arguments yield distinct internal states, and can yield no more than about 2**24 distinct internal states in all. \end{funcdesc} \begin{funcdesc}{getstate}{} Return an object capturing the current internal state of the generator. This object can be passed to \function{setstate()} to restore the state. \versionadded{2.1} \end{funcdesc} \begin{funcdesc}{setstate}{state} \var{state} should have been obtained from a previous call to \function{getstate()}, and \function{setstate()} restores the internal state of the generator to what it was at the time \function{setstate()} was called. \versionadded{2.1} \end{funcdesc} \begin{funcdesc}{jumpahead}{n} Change the internal state to what it would be if \function{random()} were called \var{n} times, but do so quickly. \var{n} is a non-negative integer. This is most useful in multi-threaded programs, in conjuction with multiple instances of the \class{Random} class: \method{setstate()} or \method{seed()} can be used to force all instances into the same internal state, and then \method{jumpahead()} can be used to force the instances' states as far apart as you like (up to the period of the generator). \versionadded{2.1} \end{funcdesc} Functions for integers: \begin{funcdesc}{randrange}{\optional{start,} stop\optional{, step}} Return a randomly selected element from \code{range(\var{start}, \var{stop}, \var{step})}. This is equivalent to \code{choice(range(\var{start}, \var{stop}, \var{step}))}, but doesn't actually build a range object. \versionadded{1.5.2} \end{funcdesc} \begin{funcdesc}{randint}{a, b} Return a random integer \var{N} such that \code{\var{a} <= \var{N} <= \var{b}}. \end{funcdesc} Functions for sequences: \begin{funcdesc}{choice}{seq} Return a random element from the non-empty sequence \var{seq}. \end{funcdesc} \begin{funcdesc}{shuffle}{x\optional{, random}} Shuffle the sequence \var{x} in place. The optional argument \var{random} is a 0-argument function returning a random float in [0.0, 1.0); by default, this is the function \function{random()}. Note that for even rather small \code{len(\var{x})}, the total number of permutations of \var{x} is larger than the period of most random number generators; this implies that most permutations of a long sequence can never be generated. \end{funcdesc} \begin{funcdesc}{sample}{population, k} Return a \var{k} length list of unique elements chosen from the population sequence. Used for random sampling without replacement. \versionadded{2.3} Returns a new list containing elements from the population while leaving the original population unchanged. The resulting list is in selection order so that all sub-slices will also be valid random samples. This allows raffle winners (the sample) to be partitioned into grand prize and second place winners (the subslices). Members of the population need not be hashable or unique. If the population contains repeats, then each occurrence is a possible selection in the sample. To choose a sample from a range of integers, use \function{xrange} as an argument. This is especially fast and space efficient for sampling from a large population: \code{sample(xrange(10000000), 60)}. \end{funcdesc} The following functions generate specific real-valued distributions. Function parameters are named after the corresponding variables in the distribution's equation, as used in common mathematical practice; most of these equations can be found in any statistics text. \begin{funcdesc}{random}{} Return the next random floating point number in the range [0.0, 1.0). \end{funcdesc} \begin{funcdesc}{uniform}{a, b} Return a random real number \var{N} such that \code{\var{a} <= \var{N} < \var{b}}. \end{funcdesc} \begin{funcdesc}{betavariate}{alpha, beta} Beta distribution. Conditions on the parameters are \code{\var{alpha} > -1} and \code{\var{beta} > -1}. Returned values range between 0 and 1. \end{funcdesc} \begin{funcdesc}{cunifvariate}{mean, arc} Circular uniform distribution. \var{mean} is the mean angle, and \var{arc} is the range of the distribution, centered around the mean angle. Both values must be expressed in radians, and can range between 0 and \emph{pi}. Returned values range between \code{\var{mean} - \var{arc}/2} and \code{\var{mean} + \var{arc}/2} and are normalized to between 0 and \emph{pi}. \deprecated{2.3}{Instead, use \code{(\var{mean} + \var{arc} * (random.random() - 0.5)) \% math.pi}.} \end{funcdesc} \begin{funcdesc}{expovariate}{lambd} Exponential distribution. \var{lambd} is 1.0 divided by the desired mean. (The parameter would be called ``lambda'', but that is a reserved word in Python.) Returned values range from 0 to positive infinity. \end{funcdesc} \begin{funcdesc}{gammavariate}{alpha, beta} Gamma distribution. (\emph{Not} the gamma function!) Conditions on the parameters are \code{\var{alpha} > 0} and \code{\var{beta} > 0}. \end{funcdesc} \begin{funcdesc}{gauss}{mu, sigma} Gaussian distribution. \var{mu} is the mean, and \var{sigma} is the standard deviation. This is slightly faster than the \function{normalvariate()} function defined below. \end{funcdesc} \begin{funcdesc}{lognormvariate}{mu, sigma} Log normal distribution. If you take the natural logarithm of this distribution, you'll get a normal distribution with mean \var{mu} and standard deviation \var{sigma}. \var{mu} can have any value, and \var{sigma} must be greater than zero. \end{funcdesc} \begin{funcdesc}{normalvariate}{mu, sigma} Normal distribution. \var{mu} is the mean, and \var{sigma} is the standard deviation. \end{funcdesc} \begin{funcdesc}{vonmisesvariate}{mu, kappa} \var{mu} is the mean angle, expressed in radians between 0 and 2*\emph{pi}, and \var{kappa} is the concentration parameter, which must be greater than or equal to zero. If \var{kappa} is equal to zero, this distribution reduces to a uniform random angle over the range 0 to 2*\emph{pi}. \end{funcdesc} \begin{funcdesc}{paretovariate}{alpha} Pareto distribution. \var{alpha} is the shape parameter. \end{funcdesc} \begin{funcdesc}{weibullvariate}{alpha, beta} Weibull distribution. \var{alpha} is the scale parameter and \var{beta} is the shape parameter. \end{funcdesc} \begin{seealso} \seetext{Wichmann, B. A. \& Hill, I. D., ``Algorithm AS 183: An efficient and portable pseudo-random number generator'', \citetitle{Applied Statistics} 31 (1982) 188-190.} \end{seealso}