# Generating strongly biased radom numbers for tests

I want to run tests with randomized inputs and need to generate 'sensible' random numbers, that is, numbers that match good enough to pass the tested function's preconditions, but hopefully wreak havoc deeper inside its code.

`math.random()` (I'm using Lua) produces uniformly distributed random numbers. Scaling these up will give far more big numbers than small numbers,
and there will be very few integers.

I would like to skew the random numbers (or generate new ones using the old function as a randomness source) in a way that strongly favors 'simple' numbers, but will still cover the whole range, I.e. extending up to positive/negative infinity (or `±1e309` for `double`). This means:

• numbers up to, say, ten should be most common,
• integers should be more common than fractions,
• numbers ending in 0.5 should be the most common fractions,
• followed by 0.25 and 0.75; then 0.125,
• and so on.

A different description: Fix a base probability x such that probabilities will sum to one and define the probability of a number n as xk where k is the generation in which n is constructed as a surreal number1. That assigns x to 0, x2 to -1 and +1, x3 to -2, -1/2, +1/2 and +2, and so on. This gives a nice description of something close to what I want (it skews a bit too much), but is near-unusable for computing random numbers. The resulting distribution is nowhere continuous (it's fractal!), I'm not sure how to determine the base probability `x` (I think for infinite precision it would be zero), and computing numbers based on this by iteration is awfully slow (spending near-infinite time to construct large numbers).

Does anyone know of a simple approximation that, given a uniformly distributed randomness source, produces random numbers very roughly distributed as described above?

I would like to run thousands of randomized tests, quantity/speed is more important than quality. Still, better numbers mean less inputs get rejected.

Lua has a JIT, so performance is usually not much of an issue. However, jumps based on randomness will break every prediction, and many calls to `math.random()` will be slow, too. This means a closed formula will be better than an iterative or recursive one.

1 Wikipedia has an article on surreal numbers, with a nice picture. A surreal number is a pair of two surreal numbers, i.e. `x := {n|m}`, and its value is the number in the middle of the pair, i.e. (for finite numbers) `{n|m} = (n+m)/2` (as rational). If one side of the pair is empty, that's interpreted as increment (or decrement, if right is empty) by one. If both sides are empty, that's zero. Initially, there are no numbers, so the only number one can build is `0 := { | }`. In generation two one can build numbers `{0| } =: 1` and `{ |0} =: -1`, in three we get `{1| } =: 2`, `{|1} =: -2`, `{0|1} =: 1/2` and `{-1|0} =: -1/2` (plus some more complex representations of known numbers, e.g. `{-1|1} ? 0`). Note that e.g. `1/3` is never generated by finite numbers because it is an infinite fraction – the same goes for floats, `1/3` is never represented exactly.

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One thing to note is that floating-point numbers are not uniformly distributed in their range. –  lhf Oct 7 '12 at 2:38

How's this for an algorithm?

1. Generate a random float in (0, 1) with a library function
2. Generate a random integral roundoff point according to a desired probability density function (e.g. 0 with probability 0.5, 1 with probability 0.25, 2 with probability 0.125, ...).
3. 'Round' the float by that roundoff point (e.g. `floor((float_val << roundoff)+0.5)`)
4. Generate a random integral exponent according to another PDF (e.g. 0, 1, 2, 3 with probability 0.1 each, and decreasing thereafter)
5. Multiply the rounded float by 2exponent.
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For a surreal-like decimal expansion, you need a random binary number. Even bits tell you whether to stop or continue, odd bits tell you whether to go right or left on the tree:

``````> 0... => 0.0 [50%] Stop
> 100... => -0.5 [<12.5%] Go, Left, Stop
> 110... => 0.5 [<12.5%] Go, Right, Stop
> 11100... => 0.25 [<3.125%] Go, Right, Go, Left, Stop
> 11110... => 0.75 [<3.125%] Go, Right, Go, Right, Stop
> 1110100... => 0.125
> 1110110... => 0.375
> 1111100... => 0.625
> 1111110... => 0.875
``````

One way to quickly generate a random binary number is by looking at the decimal digits in math.random() and replace 0-4 with '1' and 5-9 with '1':

• 0.8430419054348022 becomes 1000001010001011 which becomes `-0.5`

• 0.5513009827118367 becomes 1100001101001011 which becomes `0.25` etc

Haven't done much lua programming, but in Javascript you can do:

``````Math.random().toString().substring(2).split("").map(
function(digit) { return digit >= "5" ? 1 : 0 }
);
``````

or true binary expansion:

``````Math.random().toString(2).substring(2)
``````

Not sure which is more genuinely "random" -- you'll need to test it.

You could generate surreal numbers in this way, but most of the results will be decimals in the form a/2^b, with relatively few integers. On Day 3, only 2 integers are produced (-3 and 3) vs. 6 decimals, on Day 4 it is 2 vs. 14, and on Day n it is 2 vs (2^n-2).

If you add two uniform random numbers from `math.random()`, you get a new distribution which has a "triangle" like distribution (linearly decreasing from the center). Adding 3 or more will get a more 'bell curve' like distribution centered around 0:

``````math.random() + math.random() + math.random()  - 1.5
``````

Dividing by a random number will get a truly wild number:

``````A/(math.random()+1e-300)
``````

This will return an results between A and (theoretically) A*1e+300, though my tests show that 50% of the time the results are between A and 2*A and about 75% of the time between A and 4*A.

Putting them together, we get:

``````round(6*(math.random()+math.random()+math.random() - 1.5)/(math.random()+1e-300))
``````

This has over 70% of the number returned between -9 and 9 with a few big numbers popping up rarely.

Note that the average and sum of this distribution will tend to diverge towards a large negative or positive number, because the more times you run it, the more likely it is for a small number in the denominator to cause the number to "blow up" to a large number such as 147,967 or -194,137.

See gist for sample code.

Josh

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