random
— Generate pseudo-random numbers¶
Source code: Lib/random.py
This module implements pseudo-random number generators for various distributions.
For integers, there is uniform selection from a range. For sequences, there is uniform selection of a random element, a function to generate a random permutation of a list in-place, and a function for random sampling without replacement.
On the real line, there are functions to compute uniform, normal (Gaussian), lognormal, negative exponential, gamma, and beta distributions. For generating distributions of angles, the von Mises distribution is available.
Almost all module functions depend on the basic function random()
, which
generates a random float uniformly in the half-open range 0.0 <= X < 1.0
.
Python uses the Mersenne Twister as the core generator. It produces 53-bit precision
floats and has a period of 2**19937-1. The underlying implementation in C is
both fast and threadsafe. The Mersenne Twister is one of the most extensively
tested random number generators in existence. However, being completely
deterministic, it is not suitable for all purposes, and is completely unsuitable
for cryptographic purposes.
The functions supplied by this module are actually bound methods of a hidden
instance of the random.Random
class. You can instantiate your own
instances of Random
to get generators that don’t share state.
Class Random
can also be subclassed if you want to use a different
basic generator of your own devising: see the documentation on that class for
more details.
The random
module also provides the SystemRandom
class which
uses the system function os.urandom()
to generate random numbers
from sources provided by the operating system.
Warning
The pseudo-random generators of this module should not be used for
security purposes. For security or cryptographic uses, see the
secrets
module.
See also
M. Matsumoto and T. Nishimura, “Mersenne Twister: A 623-dimensionally equidistributed uniform pseudorandom number generator”, ACM Transactions on Modeling and Computer Simulation Vol. 8, No. 1, January pp.3–30 1998.
Complementary-Multiply-with-Carry recipe for a compatible alternative random number generator with a long period and comparatively simple update operations.
Bookkeeping functions¶
- random.seed(a=None, version=2)¶
Initialize the random number generator.
If a is omitted or
None
, the current system time is used. If randomness sources are provided by the operating system, they are used instead of the system time (see theos.urandom()
function for details on availability).If a is an int, it is used directly.
With version 2 (the default), a
str
,bytes
, orbytearray
object gets converted to anint
and all of its bits are used.With version 1 (provided for reproducing random sequences from older versions of Python), the algorithm for
str
andbytes
generates a narrower range of seeds.Changed in version 3.2: Moved to the version 2 scheme which uses all of the bits in a string seed.
- random.getstate()¶
Return an object capturing the current internal state of the generator. This object can be passed to
setstate()
to restore the state.
- random.setstate(state)¶
state should have been obtained from a previous call to
getstate()
, andsetstate()
restores the internal state of the generator to what it was at the timegetstate()
was called.
Functions for bytes¶
- random.randbytes(n)¶
Generate n random bytes.
This method should not be used for generating security tokens. Use
secrets.token_bytes()
instead.New in version 3.9.
Functions for integers¶
- random.randrange(stop)¶
- random.randrange(start, stop[, step])
Return a randomly selected element from
range(start, stop, step)
.This is roughly equivalent to
choice(range(start, stop, step))
but supports arbitrarily large ranges and is optimized for common cases.The positional argument pattern matches the
range()
function.Keyword arguments should not be used because they can be interpreted in unexpected ways. For example
randrange(start=100)
is interpreted asrandrange(0, 100, 1)
.Changed in version 3.2:
randrange()
is more sophisticated about producing equally distributed values. Formerly it used a style likeint(random()*n)
which could produce slightly uneven distributions.Changed in version 3.12: Automatic conversion of non-integer types is no longer supported. Calls such as
randrange(10.0)
andrandrange(Fraction(10, 1))
now raise aTypeError
.
- random.randint(a, b)¶
Return a random integer N such that
a <= N <= b
. Alias forrandrange(a, b+1)
.
- random.getrandbits(k)¶
Returns a non-negative Python integer with k random bits. This method is supplied with the Mersenne Twister generator and some other generators may also provide it as an optional part of the API. When available,
getrandbits()
enablesrandrange()
to handle arbitrarily large ranges.Changed in version 3.9: This method now accepts zero for k.
Functions for sequences¶
- random.choice(seq)¶
Return a random element from the non-empty sequence seq. If seq is empty, raises
IndexError
.
- random.choices(population, weights=None, *, cum_weights=None, k=1)¶
Return a k sized list of elements chosen from the population with replacement. If the population is empty, raises
IndexError
.If a weights sequence is specified, selections are made according to the relative weights. Alternatively, if a cum_weights sequence is given, the selections are made according to the cumulative weights (perhaps computed using
itertools.accumulate()
). For example, the relative weights[10, 5, 30, 5]
are equivalent to the cumulative weights[10, 15, 45, 50]
. Internally, the relative weights are converted to cumulative weights before making selections, so supplying the cumulative weights saves work.If neither weights nor cum_weights are specified, selections are made with equal probability. If a weights sequence is supplied, it must be the same length as the population sequence. It is a
TypeError
to specify both weights and cum_weights.The weights or cum_weights can use any numeric type that interoperates with the
float
values returned byrandom()
(that includes integers, floats, and fractions but excludes decimals). Weights are assumed to be non-negative and finite. AValueError
is raised if all weights are zero.For a given seed, the
choices()
function with equal weighting typically produces a different sequence than repeated calls tochoice()
. The algorithm used bychoices()
uses floating point arithmetic for internal consistency and speed. The algorithm used bychoice()
defaults to integer arithmetic with repeated selections to avoid small biases from round-off error.New in version 3.6.
Changed in version 3.9: Raises a
ValueError
if all weights are zero.
- random.shuffle(x)¶
Shuffle the sequence x in place.
To shuffle an immutable sequence and return a new shuffled list, use
sample(x, k=len(x))
instead.Note that even for small
len(x)
, the total number of permutations of x can quickly grow larger than the period of most random number generators. This implies that most permutations of a long sequence can never be generated. For example, a sequence of length 2080 is the largest that can fit within the period of the Mersenne Twister random number generator.Changed in version 3.11: Removed the optional parameter random.
- random.sample(population, k, *, counts=None)¶
Return a k length list of unique elements chosen from the population sequence. Used for random sampling without replacement.
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.
Repeated elements can be specified one at a time or with the optional keyword-only counts parameter. For example,
sample(['red', 'blue'], counts=[4, 2], k=5)
is equivalent tosample(['red', 'red', 'red', 'red', 'blue', 'blue'], k=5)
.To choose a sample from a range of integers, use a
range()
object as an argument. This is especially fast and space efficient for sampling from a large population:sample(range(10000000), k=60)
.If the sample size is larger than the population size, a
ValueError
is raised.Changed in version 3.9: Added the counts parameter.
Changed in version 3.11: The population must be a sequence. Automatic conversion of sets to lists is no longer supported.
Discrete distributions¶
The following function generates a discrete distribution.
- random.binomialvariate(n=1, p=0.5)¶
Binomial distribution. Return the number of successes for n independent trials with the probability of success in each trial being p:
Mathematically equivalent to:
sum(random() < p for i in range(n))
The number of trials n should be a non-negative integer. The probability of success p should be between
0.0 <= p <= 1.0
. The result is an integer in the range0 <= X <= n
.New in version 3.12.
Real-valued distributions¶
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.
- random.random()¶
Return the next random floating point number in the range
0.0 <= X < 1.0
- random.uniform(a, b)¶
Return a random floating point number N such that
a <= N <= b
fora <= b
andb <= N <= a
forb < a
.The end-point value
b
may or may not be included in the range depending on floating-point rounding in the equationa + (b-a) * random()
.
- random.triangular(low, high, mode)¶
Return a random floating point number N such that
low <= N <= high
and with the specified mode between those bounds. The low and high bounds default to zero and one. The mode argument defaults to the midpoint between the bounds, giving a symmetric distribution.
- random.betavariate(alpha, beta)¶
Beta distribution. Conditions on the parameters are
alpha > 0
andbeta > 0
. Returned values range between 0 and 1.
- random.expovariate(lambd=1.0)¶
Exponential distribution. lambd is 1.0 divided by the desired mean. It should be nonzero. (The parameter would be called “lambda”, but that is a reserved word in Python.) Returned values range from 0 to positive infinity if lambd is positive, and from negative infinity to 0 if lambd is negative.
Changed in version 3.12: Added the default value for
lambd
.
- random.gammavariate(alpha, beta)¶
Gamma distribution. (Not the gamma function!) The shape and scale parameters, alpha and beta, must have positive values. (Calling conventions vary and some sources define ‘beta’ as the inverse of the scale).
The probability distribution function is:
x ** (alpha - 1) * math.exp(-x / beta) pdf(x) = -------------------------------------- math.gamma(alpha) * beta ** alpha
- random.gauss(mu=0.0, sigma=1.0)¶
Normal distribution, also called the Gaussian distribution. mu is the mean, and sigma is the standard deviation. This is slightly faster than the
normalvariate()
function defined below.Multithreading note: When two threads call this function simultaneously, it is possible that they will receive the same return value. This can be avoided in three ways. 1) Have each thread use a different instance of the random number generator. 2) Put locks around all calls. 3) Use the slower, but thread-safe
normalvariate()
function instead.Changed in version 3.11: mu and sigma now have default arguments.
- random.lognormvariate(mu, sigma)¶
Log normal distribution. If you take the natural logarithm of this distribution, you’ll get a normal distribution with mean mu and standard deviation sigma. mu can have any value, and sigma must be greater than zero.
- random.normalvariate(mu=0.0, sigma=1.0)¶
Normal distribution. mu is the mean, and sigma is the standard deviation.
Changed in version 3.11: mu and sigma now have default arguments.
- random.vonmisesvariate(mu, kappa)¶
mu is the mean angle, expressed in radians between 0 and 2*pi, and kappa is the concentration parameter, which must be greater than or equal to zero. If kappa is equal to zero, this distribution reduces to a uniform random angle over the range 0 to 2*pi.
- random.paretovariate(alpha)¶
Pareto distribution. alpha is the shape parameter.
- random.weibullvariate(alpha, beta)¶
Weibull distribution. alpha is the scale parameter and beta is the shape parameter.
Alternative Generator¶
- class random.Random([seed])¶
Class that implements the default pseudo-random number generator used by the
random
module.Changed in version 3.11: Formerly the seed could be any hashable object. Now it is limited to:
None
,int
,float
,str
,bytes
, orbytearray
.Subclasses of
Random
should override the following methods if they wish to make use of a different basic generator:- seed(a=None, version=2)¶
Override this method in subclasses to customise the
seed()
behaviour ofRandom
instances.
- getstate()¶
Override this method in subclasses to customise the
getstate()
behaviour ofRandom
instances.
- setstate(state)¶
Override this method in subclasses to customise the
setstate()
behaviour ofRandom
instances.
- random()¶
Override this method in subclasses to customise the
random()
behaviour ofRandom
instances.
Optionally, a custom generator subclass can also supply the following method:
- getrandbits(k)¶
Override this method in subclasses to customise the
getrandbits()
behaviour ofRandom
instances.
- class random.SystemRandom([seed])¶
Class that uses the
os.urandom()
function for generating random numbers from sources provided by the operating system. Not available on all systems. Does not rely on software state, and sequences are not reproducible. Accordingly, theseed()
method has no effect and is ignored. Thegetstate()
andsetstate()
methods raiseNotImplementedError
if called.
Notes on Reproducibility¶
Sometimes it is useful to be able to reproduce the sequences given by a pseudo-random number generator. By reusing a seed value, the same sequence should be reproducible from run to run as long as multiple threads are not running.
Most of the random module’s algorithms and seeding functions are subject to change across Python versions, but two aspects are guaranteed not to change:
If a new seeding method is added, then a backward compatible seeder will be offered.
The generator’s
random()
method will continue to produce the same sequence when the compatible seeder is given the same seed.
Examples¶
Basic examples:
>>> random() # Random float: 0.0 <= x < 1.0
0.37444887175646646
>>> uniform(2.5, 10.0) # Random float: 2.5 <= x <= 10.0
3.1800146073117523
>>> expovariate(1 / 5) # Interval between arrivals averaging 5 seconds
5.148957571865031
>>> randrange(10) # Integer from 0 to 9 inclusive
7
>>> randrange(0, 101, 2) # Even integer from 0 to 100 inclusive
26
>>> choice(['win', 'lose', 'draw']) # Single random element from a sequence
'draw'
>>> deck = 'ace two three four'.split()
>>> shuffle(deck) # Shuffle a list
>>> deck
['four', 'two', 'ace', 'three']
>>> sample([10, 20, 30, 40, 50], k=4) # Four samples without replacement
[40, 10, 50, 30]
Simulations:
>>> # Six roulette wheel spins (weighted sampling with replacement)
>>> choices(['red', 'black', 'green'], [18, 18, 2], k=6)
['red', 'green', 'black', 'black', 'red', 'black']
>>> # Deal 20 cards without replacement from a deck
>>> # of 52 playing cards, and determine the proportion of cards
>>> # with a ten-value: ten, jack, queen, or king.
>>> deal = sample(['tens', 'low cards'], counts=[16, 36], k=20)
>>> deal.count('tens') / 20
0.15
>>> # Estimate the probability of getting 5 or more heads from 7 spins
>>> # of a biased coin that settles on heads 60% of the time.
>>> sum(binomialvariate(n=7, p=0.6) >= 5 for i in range(10_000)) / 10_000
0.4169
>>> # Probability of the median of 5 samples being in middle two quartiles
>>> def trial():
... return 2_500 <= sorted(choices(range(10_000), k=5))[2] < 7_500
...
>>> sum(trial() for i in range(10_000)) / 10_000
0.7958
Example of statistical bootstrapping using resampling with replacement to estimate a confidence interval for the mean of a sample:
# https://www.thoughtco.com/example-of-bootstrapping-3126155
from statistics import fmean as mean
from random import choices
data = [41, 50, 29, 37, 81, 30, 73, 63, 20, 35, 68, 22, 60, 31, 95]
means = sorted(mean(choices(data, k=len(data))) for i in range(100))
print(f'The sample mean of {mean(data):.1f} has a 90% confidence '
f'interval from {means[5]:.1f} to {means[94]:.1f}')
Example of a resampling permutation test to determine the statistical significance or p-value of an observed difference between the effects of a drug versus a placebo:
# Example from "Statistics is Easy" by Dennis Shasha and Manda Wilson
from statistics import fmean as mean
from random import shuffle
drug = [54, 73, 53, 70, 73, 68, 52, 65, 65]
placebo = [54, 51, 58, 44, 55, 52, 42, 47, 58, 46]
observed_diff = mean(drug) - mean(placebo)
n = 10_000
count = 0
combined = drug + placebo
for i in range(n):
shuffle(combined)
new_diff = mean(combined[:len(drug)]) - mean(combined[len(drug):])
count += (new_diff >= observed_diff)
print(f'{n} label reshufflings produced only {count} instances with a difference')
print(f'at least as extreme as the observed difference of {observed_diff:.1f}.')
print(f'The one-sided p-value of {count / n:.4f} leads us to reject the null')
print(f'hypothesis that there is no difference between the drug and the placebo.')
Simulation of arrival times and service deliveries for a multiserver queue:
from heapq import heapify, heapreplace
from random import expovariate, gauss
from statistics import mean, quantiles
average_arrival_interval = 5.6
average_service_time = 15.0
stdev_service_time = 3.5
num_servers = 3
waits = []
arrival_time = 0.0
servers = [0.0] * num_servers # time when each server becomes available
heapify(servers)
for i in range(1_000_000):
arrival_time += expovariate(1.0 / average_arrival_interval)
next_server_available = servers[0]
wait = max(0.0, next_server_available - arrival_time)
waits.append(wait)
service_duration = max(0.0, gauss(average_service_time, stdev_service_time))
service_completed = arrival_time + wait + service_duration
heapreplace(servers, service_completed)
print(f'Mean wait: {mean(waits):.1f} Max wait: {max(waits):.1f}')
print('Quartiles:', [round(q, 1) for q in quantiles(waits)])
See also
Statistics for Hackers a video tutorial by Jake Vanderplas on statistical analysis using just a few fundamental concepts including simulation, sampling, shuffling, and cross-validation.
Economics Simulation a simulation of a marketplace by Peter Norvig that shows effective use of many of the tools and distributions provided by this module (gauss, uniform, sample, betavariate, choice, triangular, and randrange).
A Concrete Introduction to Probability (using Python) a tutorial by Peter Norvig covering the basics of probability theory, how to write simulations, and how to perform data analysis using Python.
Recipes¶
These recipes show how to efficiently make random selections
from the combinatoric iterators in the itertools
module:
def random_product(*args, repeat=1):
"Random selection from itertools.product(*args, **kwds)"
pools = [tuple(pool) for pool in args] * repeat
return tuple(map(random.choice, pools))
def random_permutation(iterable, r=None):
"Random selection from itertools.permutations(iterable, r)"
pool = tuple(iterable)
r = len(pool) if r is None else r
return tuple(random.sample(pool, r))
def random_combination(iterable, r):
"Random selection from itertools.combinations(iterable, r)"
pool = tuple(iterable)
n = len(pool)
indices = sorted(random.sample(range(n), r))
return tuple(pool[i] for i in indices)
def random_combination_with_replacement(iterable, r):
"Choose r elements with replacement. Order the result to match the iterable."
# Result will be in set(itertools.combinations_with_replacement(iterable, r)).
pool = tuple(iterable)
n = len(pool)
indices = sorted(random.choices(range(n), k=r))
return tuple(pool[i] for i in indices)
The default random()
returns multiples of 2⁻⁵³ in the range
0.0 ≤ x < 1.0. All such numbers are evenly spaced and are exactly
representable as Python floats. However, many other representable
floats in that interval are not possible selections. For example,
0.05954861408025609
isn’t an integer multiple of 2⁻⁵³.
The following recipe takes a different approach. All floats in the interval are possible selections. The mantissa comes from a uniform distribution of integers in the range 2⁵² ≤ mantissa < 2⁵³. The exponent comes from a geometric distribution where exponents smaller than -53 occur half as often as the next larger exponent.
from random import Random
from math import ldexp
class FullRandom(Random):
def random(self):
mantissa = 0x10_0000_0000_0000 | self.getrandbits(52)
exponent = -53
x = 0
while not x:
x = self.getrandbits(32)
exponent += x.bit_length() - 32
return ldexp(mantissa, exponent)
All real valued distributions in the class will use the new method:
>>> fr = FullRandom()
>>> fr.random()
0.05954861408025609
>>> fr.expovariate(0.25)
8.87925541791544
The recipe is conceptually equivalent to an algorithm that chooses from
all the multiples of 2⁻¹⁰⁷⁴ in the range 0.0 ≤ x < 1.0. All such
numbers are evenly spaced, but most have to be rounded down to the
nearest representable Python float. (The value 2⁻¹⁰⁷⁴ is the smallest
positive unnormalized float and is equal to math.ulp(0.0)
.)
See also
Generating Pseudo-random Floating-Point Values a
paper by Allen B. Downey describing ways to generate more
fine-grained floats than normally generated by random()
.