# Fast arbitrary distribution random sampling

The `random` module (http://docs.python.org/2/library/random.html) has several fixed functions to randomly sample from. For example `random.gauss` will sample random point from a normal distribution with a given mean and sigma values.

I'm looking for a way to extract a number `N` of random samples between a given interval using my own distribution as fast as possible in `python`. This is what I mean:

``````def my_dist(x):
# Some distribution, assume c1,c2,c3 and c4 are known.
f = c1*exp(-((x-c2)**c3)/c4)
return f

# Draw N random samples from my distribution between given limits a,b.
N = 1000
N_rand_samples = ran_func_sample(my_dist, a, b, N)
``````

where `ran_func_sample` is what I'm after and `a, b` are the limits from which to draw the samples. Is there anything of that sort in `python`?

• You can just call your function N times. However, you still need to specify what distribution you want your `x` values to be chosen from. – BrenBarn Jan 13 '14 at 20:28
• My distribution is my function. I need to evaluate that function randomly N times between a certain interval. – Gabriel Jan 13 '14 at 20:30
• Your function isn't a distribution. You need to decide what the distribution is on the arguments you call it with. If you want to pass it N random values "between a certain interval", where are you specifying that interval in your code example? Do you want the random `x` values to be chosen uniformly from that interval, or in some other way? – BrenBarn Jan 13 '14 at 20:32
• I forgot to specify the interval, I'll add it to the code. You are right, I explained myself poorly giving a `x**2` function and not a distribution. I'll try to fix that now. – Gabriel Jan 13 '14 at 20:34
• I have such code for discrete distributions. Everything can be approximated with a discrete distribution, and it makes things a lot simpler (though still nontrivial, to get numerical robustness). If that helps you I could wrap it up. – Eelco Hoogendoorn Jan 13 '14 at 21:06

You need to use Inverse transform sampling method to get random values distributed according to a law you want. Using this method you can just apply inverted function to random numbers having standard uniform distribution in the interval [0,1].

After you find the inverted function, you get 1000 numbers distributed according to the needed distribution this obvious way:

``````[inverted_function(random.random()) for x in range(1000)]
``````

More on Inverse Transform Sampling:

Also, there is a good question on StackOverflow related to the topic:

• I implemented a function doing the inverse transform sampling with a help of SymPy and asked for a review on a Code Review Stack Exchange: Link. Maybe someone can find it helpful. – Georgy Jun 11 '18 at 15:59
• Many functions that one may wish to draw random samples from are not analytically invertible. – Mead Feb 1 at 5:27

This code implements the sampling of n-d discrete probability distributions. By setting a flag on the object, it can also be made to be used as a piecewise constant probability distribution, which can then be used to approximate arbitrary pdf's. Well, arbitrary pdfs with compact support; if you efficiently want to sample extremely long tails, a non-uniform description of the pdf would be required. But this is still efficient even for things like airy-point-spread functions (which I created it for, initially). The internal sorting of values is absolutely critical there to get accuracy; the many small values in the tails should contribute substantially, but they will get drowned out in fp accuracy without sorting.

``````class Distribution(object):
"""
draws samples from a one dimensional probability distribution,
by means of inversion of a discrete inverstion of a cumulative density function

the pdf can be sorted first to prevent numerical error in the cumulative sum
this is set as default; for big density functions with high contrast,
it is absolutely necessary, and for small density functions,

a call to this distibution object returns indices into density array
"""
def __init__(self, pdf, sort = True, interpolation = True, transform = lambda x: x):
self.shape          = pdf.shape
self.pdf            = pdf.ravel()
self.sort           = sort
self.interpolation  = interpolation
self.transform      = transform

#a pdf can not be negative
assert(np.all(pdf>=0))

#sort the pdf by magnitude
if self.sort:
self.sortindex = np.argsort(self.pdf, axis=None)
self.pdf = self.pdf[self.sortindex]
#construct the cumulative distribution function
self.cdf = np.cumsum(self.pdf)
@property
def ndim(self):
return len(self.shape)
@property
def sum(self):
"""cached sum of all pdf values; the pdf need not sum to one, and is imlpicitly normalized"""
return self.cdf[-1]
def __call__(self, N):
"""draw """
#pick numbers which are uniformly random over the cumulative distribution function
choice = np.random.uniform(high = self.sum, size = N)
#find the indices corresponding to this point on the CDF
index = np.searchsorted(self.cdf, choice)
#if necessary, map the indices back to their original ordering
if self.sort:
index = self.sortindex[index]
#map back to multi-dimensional indexing
index = np.unravel_index(index, self.shape)
index = np.vstack(index)
#is this a discrete or piecewise continuous distribution?
if self.interpolation:
index = index + np.random.uniform(size=index.shape)
return self.transform(index)

if __name__=='__main__':
shape = 3,3
pdf = np.ones(shape)
pdf=0
dist = Distribution(pdf, transform=lambda i:i-1.5)
print dist(10)
import matplotlib.pyplot as pp
pp.scatter(*dist(1000))
pp.show()
``````

And as a more real-world relevant example:

``````x = np.linspace(-100, 100, 512)
p = np.exp(-x**2)
pdf = p[:,None]*p[None,:]     #2d gaussian
dist = Distribution(pdf, transform=lambda i:i-256)
print dist(1000000).mean(axis=1)    #should be in the 1/sqrt(1e6) range
import matplotlib.pyplot as pp
pp.scatter(*dist(1000))
pp.show()
``````
• Glad I could help. Does approximating the distribution as piecewise continuous suffice for your application? How fast this approach is depends on the resolution you aim for; generating the distribution is N log(N), and sampling has complexity N, with a low time constant. Though I havnt tested it, I could imagine it achieves sufficient accuracy much more efficiently in many scenarios, even where a closed form solution exists. But the main appeal to me is in the flexibility of the approach, permitting arbitrary distributions. – Eelco Hoogendoorn Jan 21 '14 at 22:45
• Could you please explain the nature of the transform ? I don't quite get what it does! – Sebastiano1991 Apr 9 at 13:42
• If left unspecified, the return values are identical to the indices of the input array specifying the discrete PDF. The transform simply allows you to remap those values; map them to a range [0..1) or whatever. Frankly it does not really belong in this class for the sake of answering this question; just ended up here from the project I extracted it from. – Eelco Hoogendoorn Apr 9 at 19:55
``````import numpy as np
import scipy.interpolate as interpolate

def inverse_transform_sampling(data, n_bins, n_samples):
hist, bin_edges = np.histogram(data, bins=n_bins, density=True)
cum_values = np.zeros(bin_edges.shape)
cum_values[1:] = np.cumsum(hist*np.diff(bin_edges))
inv_cdf = interpolate.interp1d(cum_values, bin_edges)
r = np.random.rand(n_samples)
return inv_cdf(r)
``````

So if we give our data sample that has a specific distribution, the `inverse_transform_sampling` function will return a dataset with exactly the same distribution. Here the advantage is that we can get our own sample size by specifying it in the `n_samples` variable.

I was in a similar situation but I wanted to sample from a multivariate distribution, so, I implemented a rudimentary version of Metropolis-Hastings (which is an MCMC method).

``````def metropolis_hastings(target_density, size=500000):
burnin_size = 10000
size += burnin_size
x0 = np.array([[0, 0]])
xt = x0
samples = []
for i in range(size):
xt_candidate = np.array([np.random.multivariate_normal(xt, np.eye(2))])
accept_prob = (target_density(xt_candidate))/(target_density(xt))
if np.random.uniform(0, 1) < accept_prob:
xt = xt_candidate
samples.append(xt)
samples = np.array(samples[burnin_size:])
samples = np.reshape(samples, [samples.shape, 2])
return samples
``````

This function requires a function `target_density` which takes in a data-point and computes its probability.

For details check-out this detailed answer of mine.