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I need to generate n random numbers between a and b, but any two numbers cannot have a difference of less than c. All variables except n are floats (n is an int).

Solutions are preferred in java, but C/C++ is okay too.

Here is what code I have so far.:

static float getRandomNumberInRange(float min, float max) {
    return (float) (min + (Math.random() * (max - min)));

static float[] randomNums(float a, float b, float c, int n) {
    float minDistance = c;
    float maxDistance = (b - a) - (n - 1) * c;
    float[] randomNumArray = new float[n];
    float random = getRandomNumberInRange(minDistance, maxDistance);
    randomNumArray[0] = a + random;
    for (int x = 1; x < n; x++) {
        maxDistance = (b - a) - (randomNumArray[x - 1]) - (n - x - 1) * c;
        random = getRandomNumberInRange(minDistance, maxDistance);
        randomNumArray[x] = randomNumArray[x - 1] + random;
    return randomNumArray;

If I run the function as such (10 times), I get the following output:

Input: randomNums(-1f, 1f, 0.1f, 10)

[-0.88, 0.85, 1.23, 1.3784, 1.49, 1.59, 1.69, 1.79, 1.89, 1.99]

[-0.73, -0.40, 0.17, 0.98, 1.47, 1.58, 1.69, 1.79, 1.89, 1.99]

[-0.49, 0.29, 0.54, 0.77, 1.09, 1.56, 1.69, 1.79, 1.89, 1.99]

share|improve this question
is there a problem with what you have? Also, you didn't ask a question. – Hunter McMillen Jul 26 '11 at 19:18
and what is wrong with your code, that you're not satisfied with it ? – woliveirajr Jul 26 '11 at 19:19
@retrodone Its actually to randomly generate platforms in my game, as two platforms can't be too close to each other, not homework. – Amandeep Grewal Jul 26 '11 at 19:20
Question edited to show incorrect output. – Amandeep Grewal Jul 26 '11 at 19:25
You're really asking for trouble with the problem as you've put it. Do you need to generate a solution with a minimum number of platforms despite the possibility that if chosen badly they won't all fit between a and b? I'd just place a platform, go a random distance greater than c, and place another platform. – Brian Gordon Jul 26 '11 at 19:25
up vote 8 down vote accepted

I think a reasonable approach can be the following:


  1. Total "space" is (b - a)
  2. Remove the minimum required space (n-1)*c to obtain the remaining space
  3. Shot (n-1) random numbers between 0 and 1 and scale them so that the sum is this just computed "optional space". Each of them will be a "slice" of space to be used.
  4. First number is a
  5. For each other number add c and the next "slice" to the previous number. Last number will be b.

If you don't want first and last to match a and b exactly then just create n+1 slices instead of n-1 and start with a+slice[0] instead of a.

The main idea is that once you remove the required spacing between the points (totalling (n-1)*c) the problem is just to find n-1 values so that the sum is the prescribed "optional space". To do this with a uniform distribution just shoot n-1 numbers, compute the sum and uniformly scale those numbers so that the sum is instead what you want by multiplying each of them by the constant factor k = wanted_sum / current_sum.

To obtain the final result you just use as spacing between a value and the previous one the sum of the mandatory part c and one of the randomly sampled variable parts.

An example in Python of the code needed for the computation is the following

space = b - a
slack = space - (n - 1)*c
slice = [random.random() for i in xrange(n-1)]  # Pick (n-1) random numbers 0..1
k = slack / sum(slice)                          # Compute needed scaling
slice = [x*k for x in slice]                    # Scale to get slice sizes
result = [a]
for i in xrange(n-1):
    result.append(result[-1] + slice[i] + c)
share|improve this answer
That's what I was thinking, except for one slight change: remove the length of (n-1) slices, generate n (distinct) numbers, and insert the slices between the numbers (the first and last number won't be at a and b but random). – trutheality Jul 26 '11 at 19:46
Still falls victim to the early selections altering the distribution of latter selections. A few large slices at the beginning of the selection process can guarantee you will never select another equally large slice. In effect the latter selections demonstrate a decreasing variance. – Edwin Buck Jul 26 '11 at 19:57
@Edwin I don't think so. If you take n-1 random numbers, sort them, and scale their range then there's no meaning to "beginning" and "end" of the selection process. But I suspect there's still a problem because the 2 outliers have so much influence on the other numbers. – Brian Gordon Jul 26 '11 at 20:26
@Edwin: please read carefully. By picking N-1 random numbers and scaling them so that the sum is exactly the space to distribute the distribution will be uniform (on the part above the minimum). Random picking and sorting would not give a uniform distribution of slices of slack space. I didn't use sort exactly for this reason. I'll add the exact slice vector computation code to make it clearer. – 6502 Jul 26 '11 at 20:38
@6502 Yes, please add some code (or even pseduocode) to this, as I've having a little trouble understanding the algorithm. – Amandeep Grewal Jul 26 '11 at 20:42

If you have random number X and you want another random number Y which is a minimum of A from X and a maximum of B from X, why not write that in your code?

float nextRandom(float base, float minDist, float maxDist) {
  return base + minDist + (((float)Math.random()) * (maxDist - minDist));

by trying to keep the base out of the next number routine, you add a lot of complexity to your algorithm.

share|improve this answer
If you're greedy and take almost all of the remaining space on your first number, there won't be room for the minDists for the rest. – Brian Gordon Jul 26 '11 at 19:46
There's no guarantee under the current algorithm that this doesn't happen either. In fact, it is not possible to generate truly random numbers according to the algorithm and always meet the criteria. If randomness is really important, best to generate a set of ten numbers and check it to see if it meets the criteria, throwing away undesirable sets. – Edwin Buck Jul 26 '11 at 19:51
the original algorithm does assure that it can generate n numbers, just had a small bug, see my answer. it does not create uniform distribution though – Karoly Horvath Jul 26 '11 at 20:05

Though this does not exactly do what you need and does not incorporate the techinque being described in this thread, I believe that this code will prove to be useful as it will do what it seems like you want.

static float getRandomNumberInRange(float min, float max)
    return (float) (min + (Math.random() * ((max - min))));
 static float[] randomNums(float a, float b, float c, int n) 
    float averageDifference=(b-a)/n; 
    float[] randomNumArray = new float[n];
    int random;
    for (int x = 1; x < n; x++)
    for (int x = 0; x < n; x++)
        random = getRandomNumberInRange(-averageDifference/2, averageDifference/2);
    return randomNumArray;
share|improve this answer
I will test this and the others posted tonight. – Amandeep Grewal Jul 26 '11 at 22:00
You'll get too nice a distribution, with one platform in every bin. However, it might not be a bad thing for the application considered. Also, your algorithm fails unless there is a lot of empty space ((b - a) > 2 * n * c), but again that's OK for the numerical example given in the original post. – toto2 Jul 26 '11 at 23:21

I need to generate n random numbers between a and b, but any two numbers cannot have a difference of less than c. All variables except n are floats (n is an int).

Solutions are preferred in java, but C/C++ is okay too.

First, what distribution? I'm going to assume a uniform distribution, but with that caveat that "any two numbers cannot have a difference of less than c". What you want is called "rejection sampling". There's a wikipedia article on the subject, plus a whole lot of other references on the 'net and in books (e.g. Pseudocode, using some function random_uniform() that returns a random number drawn from U[0,1], and assuming a 1-based array (many languages use a 0-based array):

function generate_numbers (a, b, c, n, result)
  result[1] = a + (b-a)*random_uniform()
  for index from 2 to n
    rejected = true
    while (rejected)
      result[index] = a + (b-a)*random_uniform()
      rejected = abs (result[index] < result[index-1]) < c
share|improve this answer
I guess you are also assuming that you are sorting result when adding an element. You should also check if it rejected by looking at the left and right neighbors. – toto2 Jul 26 '11 at 23:16
No, I'm not assuming anything of the such. The OP didn't specify what "any two numbers cannot have a difference of less than c" means. I assumed any two adjacent numbers. If the OP meant something different clarification is needed. – David Hammen Jul 26 '11 at 23:39
Then shouldn't you check all pairs abs (result[i] - result[j]) < c? When you generate a new result it can be to the left of the previous ones since they are all generated with a + (b-a)*random_uniform(). – toto2 Jul 26 '11 at 23:57
@David Sorry I meant no two numbers generated can be less than c apart. – Amandeep Grewal Jul 27 '11 at 2:27
@Amandeep: What are you trying to accomplish? What problem are you trying to solve? If the underlying process is discrete, use a discrete distribution. If the underlying process, well there is no physical process that I know of that will generate anything close to such a distribution. – David Hammen Jul 27 '11 at 5:44

Your solution was almost correct, here is the fix:

maxDistance = b - (randomNumArray[x - 1]) - (n - x - 1) * c;
share|improve this answer
I changed my two maxDistance lines to: float maxDistance = b - (n - 1) * c; and maxDistance = b - (randomNumArray[x - 1]) - (n - x - 1) * c;. Output here: In summary, the first number is always -0.9, and there are not enough negative numbers to be random. – Amandeep Grewal Jul 26 '11 at 19:44
nonono, the first maxDistance was fine! just fix what I've told – Karoly Horvath Jul 26 '11 at 19:47
Similarly, if I don't touch my first maxDistance, I get this output (not enough negative numbers): – Amandeep Grewal Jul 26 '11 at 19:57
right..:/ it fixed the bug but the main concept is flawed, it won't generate uniform distribution – Karoly Horvath Jul 26 '11 at 20:03
Ya, I didn't say my algorithm was on the right track, just the best I could come up with. – Amandeep Grewal Jul 26 '11 at 20:09

I would do this by just generating n random numbers between a and b. Then I would sort them and get the first order differences, kicking out any numbers that generate a difference less than c, leaving me with m numbers. If m < n, I would just do it again, this time for n - m numbers, add those numbers to my original results, sort again, generate differences...and so on until I have n numbers.

Note, first order differences means x[1] - x[0], x[2] - x[1] and so on.

I don't have time to write this out in C but in R, it's pretty easy:

   while(length(r) < n){
      r<-r[-(which(diff(r) <= c) + 1 )]


Note that if you are too aggresive with c relative to a and b, this kind of solution might take a long time to converge, or not converge at all if n * C > b -a

Also note, I don't mean for this R code to be a fully formed, production ready piece of code, just an illustration of the algorithm (for those who can follow R).

share|improve this answer
will this generate equal distribution? will it ever finish if (n_1)*c is close to b-a? I doubt it. – Karoly Horvath Jul 26 '11 at 19:34
I also think that there is an infinite loop possibility. If a=0, b=1, c=0.1, and n=10, and the numbers generated were 0, 1.5, 3, 4.5, 6, 7.5, 9. Now you only have 7 numbers but cant insert another number anywhere. – Amandeep Grewal Jul 26 '11 at 19:41
@Amandeep, that is a fundamental flaw with the way the problem is specified. – frankc Jul 26 '11 at 20:15
@yi_H It could be uniformly distributed. However I guess you would need to add the condition that when an interval is too short you reject the value at the start or end of the interval with 50-50 probability. Even then, I'm not sure it's enough for uniformity. It might be simpler to just generate n values and if there is a conflict than start over with n new values. But that would take even longer to reach a solution. – toto2 Jul 26 '11 at 21:37

How about using a shifting range as you generate numbers to ensure that they don't appear too close?

static float[] randomNums(float min, float max, float separation, int n) {
    float rangePerNumber = (max - min) / n;

    // Check separation and range are consistent.
    assert (rangePerNumber >= separation) : "You have a problem.";

    float[] randomNumArray = new float[n];

    // Set range for first random number
    float lo = min;
    float hi = lo + rangePerNumber;

    for (int i = 0; i < n; ++i) {
        float random = getRandomNumberInRange(lo, hi);

        // Shift range for next random number.
        lo = random + separation;
        hi = lo + rangePerNumber;

        randomNumArray[i] = random;
    return randomNumArray;
share|improve this answer
Your distribution will be heavily skewed to the left. – toto2 Jul 26 '11 at 23:27
Agreed. I wasn't sure this wasn't homework so I left in a deliberate error :). The issue is reducible by recalculating rangePerNumber anew for each iteration. – rossum Jul 27 '11 at 11:20

I know you already accepted an answer, but I like this problem. I hope it's unique, I haven't gone through everyone's answers in detail just yet, and I need to run, so I'll just post this and hope it helps.

Think of it this way: Once you pick your first number, you have a chunk +/- c that you can no longer pick in.

So your first number is


At this point, x is somewhere between a and b (assuming Random() returns in 0 to 1). Now, we mark out the space we can no longer pick in


If x is close to either end, then it's easy, we just pick in the remaining space

if (excludedMin<=a)

Here, x is so close to a, that you won't get y between a and x, so you just pick between x+c and b. Likewise:

else if (excludedMax>=b)

Now if x is somewhere in the middle, we have to do a little magic

  if (y>excludedMin) y+=2*c

What's going on here? Well, we know that the range y can lie in, is 2*c smaller than the whole space, so we pick a number somewhere in that smaller space. Now, if y is less than excludedMin, we know y "is to the left" of x-c, and we're all ok. However, if y>excluded min, we add 2*c (the total excluded space) to it, to ensure that it's greater than x+c, but it'll still be less than b because our range was reduced.

Now, it's easy to expand so n numbers, each time you just reduce the range by the excluded space among any of the other points. You continue until the excluded space equals the original range (b-a).

share|improve this answer

I know it's bad form to do a second answer, but I just thought of one...use a recursive search of the space:

Assume a global list of points: points

  if (range>0)

I'll let you follow the recursion, but at the end, you'll have a list in points that fills the space with density 1/c

share|improve this answer

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