I'm coding a map generator based on a perlin noise and ran into a problem:

Lets say I would want 30% water and 70% dirt tiles. With a usual random generator there is no problem:

tile = rnd.nextFloat() < 0.7f ? DIRT : WATER;

But a perlin noise is normal distributed (ranges from -1 to 1, mean at 0) so it's not that easy.

Does anyone know a way to transform a normal to an uniform distribution or a different way I could get a percentage from a noise value?

EDIT: The 70% are just an example, I'd want to be able to use any value dynamically, at best with 0.1% precision.

EDIT2: I want to transformate perlin noise to a uniform distribution, not to normal (which it already is alike).


If you want to get exactly 30% water (or some other specified value), you could do this.

  1. Generate your height-map.
  2. Place all the height-values into a list.
  3. Sort the list.
  4. Pick the value, that appears 30% into the list, as your water-level.
  • TMHO this is by far the most simple and efficient solution the have been mentioned here !
    – AsTeR
    Jul 15 '12 at 8:44

The Perlin noise distribution is only gaussian like, it's not truly a normal distribution.

Furthermore, the peak is very narrow, with the standard deviation being around 0.1 (I can't find an exact figure).

Just pick your threshold at ~ 0.1, and that should give you approximately 70% values below that, and 30% above.

  • 2
    Any idea how to calculate the threshold dynamically?
    – DiddiZ
    Jul 14 '12 at 23:06
  • I don't think you can "calculate" it - you'd have to take a suitably large number of test samples and then find out what threshold gives you the desired percentile.
    – Alnitak
    Jul 14 '12 at 23:12

A solution I figured out: Firstly, I generate 100,000,000 perlin noises and store them in an array. I sort it, and afterwards I can take every 10,000 value as a threshold for one per mille. Now I can hardcode these thresholds, so I've just an array with 1,000 floats for lookup at runtime.


It's really fast, as it's just one array access at runtime.


If you change the algorithm, you have to regenerate your threshold array. Secondly, the mean scales to about 10 per mille, making a 50% threshold either 49.5% or 50.5% (depending on whether you use < or <= comperator). Thirdly, the increased memory footprint (4kb with per mill precision). You can reduce it by using percent precision or a logarithmic precision scale.

Generation code:

final PerlinNoiseGenerator perlin = new PerlinNoiseGenerator(new Random().nextInt());

final int size = 10000; //Size gets sqared, so it's actually 100,000,000

final float[] values = new float[size * size];
for (int x = 0; x < size; x++)
    for (int y = 0; y < size; y++) {
        final float value = perlin.noise2(x / 10f, y / 10f);
        values[x * size + y] = value;


final float[] steps = new float[1000];
steps[999] = 1;
for (int i = 0; i < 999; i++)
    steps[i] = values[size * size / 1000 * (i + 1)];
System.out.println("Calculated steps");

for (int i = 0; i < 10; i++) {
    for (int j = 0; j < 100; j++)
        System.out.print(steps[i * 100 + j] + "f, "); //Output usuable for array initialization

Lookup code:

public final static float[] perlinThresholds = new float[]{}; //Initialize it with the generated thresholds.

public static float getThreshold(float percent) {
    return perlinThresholds[(int)(percent * 1000)];

public static float getThreshold(int promill) {
    return perlinThresholds[promill];

  • 1
    would you care to share that resulting array somewhere? Maybe someone can figure out a "good enough" formula for its real cumulative distribution function.
    – Alnitak
    Jul 15 '12 at 13:09

Here's an analytic solution which doesn't depend on keeping data around, and is continuous. Following the method described here, I produced a histogram of perlin noise values, then approximated the continuous distribution function by summing the histogram, so cdf(x)

cdf(x) = sum(histogram[i] for all i < x)

Then I used Wolfram Alpha to approximate cdf(x) with a fifth-degree polynomial. This gave me this function:

function F(x) { return (((((0.745671 * x + 0.00309887) * x - 1.53841) * x - 0.00343488) * x + 1.29551) * x) + 0.500516;

x^5+0.00309887 x^4-1.53841 x^3-0.00343488 x^2+1.29551 x+0.500516 u = (u + 0.002591009999999949) / 1.0055419999999997; // cross (0,0) and (1,1)

F(x) = 0.745671 x^5 + 0.00309887 x^4 - 1.53841 x^3 - 0.00343488 x^2 + 1.29551 x + 0.500516

Now F(perlin.noise2(...)) gets reasonably close to being uniformly distributed.

This function doesn't quite pass through points (-1,0) and (1,1) so you could correct it as

F1(x) = (F(x) + 0.002591009999999949) / 1.0055419999999997

The function also strays just above 1 near x = 1 and just below 0 near x = -1, so you should clamp it between 0 and 1 if that matters to you.

F2(x) = max(min(F1(x), 1), 0)

(I'll leave this pretty terse unless someone who wants more detail appears. Leave a comment if so.)


Well, if it is almost Gaussian, then 70% would be everything below 0.75, see this table: http://www.roymech.co.uk/Useful_Tables/Statistics/Statistics_Normal_table.html


Simply add 1 and divide by 2 ? This would give you a distribution centered on 0.5 and from 0 to 1.

EDIT : your want a threshold splitting 70% vs 30% you have to use the cumulative distribution function of the normal law, you just have to find the x such as the probability of being under x is 0.7. Please note that this work for normal distribution only, if you distribution is always between -1 and 1, it's not a normal distribution. Normal distribution output interval is supposed to be -∞ and +∞. The solution mentionned by @paxinum could be simpler that doing the computation yourself.

  • Yeah, but it's still normal distributed and I don't know what 70% would be.
    – DiddiZ
    Jul 14 '12 at 22:17
  • Normal distributed means you can "normalize it" by substracting average dividing by standard deviation. Then a table (like the one mentioned by @Paxinum ) gives you the threshold to consider (which is 0.53 for having a split at 70%).
    – AsTeR
    Jul 19 '12 at 11:11

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