Many applications require off-chain generation of random numbers for efficiency, security, etc.

This class allows you to generate a stream of deterministic, high-quality,
cryptographically secure random numbers.

By seeding it with a Chainlink VRF result that is requested only once for the project,
it can be used to demonstrate that the random numbers are not cherry-picked.

Python (2.1 to 3.x)

PIP:

pip install chainrand

Or you can clone/download this GitHub repository.

git clone https://github.com/chainrand/chainrand-py
cd chainrand-py
python setup.py install

rng = chainrand.CRNG("base10(<RNG_VRF_RESULT>)" + "<RNG_SEED_KEY>")
// prints 10 determinstic random numbers between [0, 1)
for i in range(10):
    print(rng())

Current and future versions of this library will generate the same stream of random numbers from the same seed.

chainrand.CRNG(seed)

Creates an instance of the crng initialized with the seed.

Parameters:

• seed: str If empty, defaults to the empty string "".

Example:

crng = chainrand.CRNG("base10(<RNG_VRF_RESULT>)" + "<RNG_SEED_KEY>")

crng.random(): float

Alias for crng(). Returns a random number uniformly distributed in [0, 1).
The numbers are in multiples of 2**-53.

Parameters: none

Returns: A random number uniformly distributed in [0, 1).

crng.randrange(start, stop[, step]): float
crng.randrange(stop): float

Returns a random integer uniformly distributed in [start, stop).
The integers are spaced with intervals of |step|.

Parameters:

• start: int The start of the range. (optional, default=0)
• stop: int The end of the range.
• step: int The interval step. (optional, default=1)

Returns:

A random integer uniformly distributed in [start, stop).

Examples:

r = crng.randrange(3) # returns a random number in {0,1,2}
r = crng.randrange(-3) # returns a random number in {0,-1,-2}
r = crng.randrange(0, 6, 2) # returns a random number in {0,2,4}
r = crng.randrange(5, 0, 1) # returns a random number in {5,4,3,2,1}
r = crng.randrange(5, -5, -2) # returns a random number in {5,3,1,-1,-3}

crng.randint(start, stop): int
crng.randint(stop): int

Returns a random integer uniformly distributed in [start, stop].
The integers are spaced with intervals of |step|.

Parameters:

• start: int The start of the range. (optional, default=0)
• stop: int The end of the range.

Returns:

A random integer uniformly distributed in [start, stop].

Examples:

r = crng.randint(3) # returns a random number in {0,1,2,3}
r = crng.randint(-3) # returns a random number in {0,-1,-2,-3}
r = crng.randint(-3, 1) # returns a random number in {-3,-2,-1,0,1}
r = crng.randint(3, -1) # returns a random number in {3,2,1,0,-1}

crng.choice(population[, weights]): list

Returns a random element from the population.

If weights is not provided, every element of population will be equally weighted.

If weights is a non-empty array and is of different length to population,
only the first Math.min(population.length, weights.length) elements of population are sampled.

If the sum of the weights is less than or equal to zero,
every element of population will be equally weighted.

Parameters:

• population: list The population.
• weights: list<float> The weights of the population. (optional)

Returns:

A random element in the population.

Examples:

# returns a random number in {1,2,3} 
r = crng.choice([1,2,3]) 

# returns a random number in {1,2,3}
# with the weights {1:10, 2:1, 3:0.1} 
r = crng.choice([1,2,3], [10,1,0.1]) 

crng.sample(population, k=1[, weights]): list

Returns k random elements from the population, sampling without replacement.

If k is more than the length of the population, only k elements will be returned.

If weights is not provided, every element of population will be equally weighted.

If weights is a non-empty array and is of different length to population,
only the first Math.min(population.length, weights.length) elements of population are sampled.

If the sum of the weights is less than or equal to zero,
every element of population will be equally weighted.

Parameters:

• population: list The population.
• k: int The number of elements to choose.
• weights: list<float> The weights of the population. (optional)

Returns:

An array of k random elements from the population.

Examples:

# returns an array of 1 random element from {1,2,3}
r = crng.sample([1,2,3]) 

# returns an array of 2 random elements from {1,2,3}
r = crng.sample([1,2,3], 2) 

# returns an array of 2 random elements from {1,2,3}
# with the weights {1:10, 2:1, 3:0.1} 
r = crng.sample([1,2,3], 2, [10,1,0.1]) 

crng.shuffle(population)

Shuffles the array in-place.

Parameters:

• population: list The population.

Returns:

The shuffled array.

crng.gauss(mu=0.0, sigma=1.0): float

Normal distribution, also called the Gaussian distribution.

Parameters:

• mu: float The mean. (optional, default=0.0)
• sigma: float The standard deviation. (optional, default=1.0)

Returns:

A random number from the Gaussian distribution.

MIT