Weights define a probability distribution function (pdf). Random numbers from any such pdf can be generated by applying its associated inverse cumulative distribution function to uniform random numbers between 0 and 1.

See also this SO explanation, or, as explained by Wikipedia:

If Y has a U[0,1] distribution then F⁻¹(Y) is distributed as F. This is
used in random number generation using
the inverse transform sampling-method.

```
import random
import bisect
import collections
def cdf(weights):
total = sum(weights)
result = []
cumsum = 0
for w in weights:
cumsum += w
result.append(cumsum / total)
return result
def choice(population, weights):
assert len(population) == len(weights)
cdf_vals = cdf(weights)
x = random.random()
idx = bisect.bisect(cdf_vals, x)
return population[idx]
weights=[0.3, 0.4, 0.3]
population = 'ABC'
counts = collections.defaultdict(int)
for i in range(10000):
counts[choice(population, weights)] += 1
print(counts)
# % test.py
# defaultdict(<type 'int'>, {'A': 3066, 'C': 2964, 'B': 3970})
enter code here
```

The `choice`

function above uses `bisect.bisect`

, so selection of a weighted random variable is done in `O(log n)`

where `n`

is the length of `weights`

.

Note that as of version 1.7.0, NumPy has a Cythonized np.random.choice function. For example, this generates 1000 samples from the population `[0,1,2,3]`

with weights `[0.1, 0.2, 0.3, 0.4]`

:

```
import numpy as np
np.random.choice(4, 1000, p=[0.1, 0.2, 0.3, 0.4])
```

`np.random.choice`

also has a `replace`

parameter for sampling with or without replacement.

A theoretically better algorithm is the Alias Method. It builds a table which requires `O(n)`

time, but after that, samples can be drawn in `O(1)`

time. So, if you need to draw many samples, in theory the Alias Method may be faster. There is a Python implementation of the Walker Alias Method here, and a numpy version here.