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I have a set of prime numbers and I have to generate integers using only those prime factors in increasing order.

For example, if the set is p = {2, 5} then my integers should be 1, 2, 4, 5, 8, 10, 16, 20, 25, …

Is there any efficient algorithm to solve this problem?

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Just to be clear, you want to generate the set which comprises all numbers of the form 2^m*5^n where m,n are integers >=0 ? –  High Performance Mark Apr 12 '12 at 15:04
    
Better to ask this on math.stackexchange.com –  Guanidene Apr 12 '12 at 15:25
    
@HighPerformanceMark yes, but in increasing order –  nims Apr 12 '12 at 15:57
    
Check out this related question. The accepted answer there gives O(n) Python code similar to my answer here, which can be adapted to arbitrary "bases" (primes set). –  Will Ness Apr 15 '12 at 18:05

4 Answers 4

up vote 6 down vote accepted

The basic idea is that 1 is a member of the set, and for each member of the set n so also 2n and 5n are members of the set. Thus, you begin by outputting 1, and push 2 and 5 onto a priority queue. Then, you repeatedly pop the front item of the priority queue, output it if it is different from the previous output, and push 2 times and 5 times the number onto the priority queue.

Google for "Hamming number" or "regular number" or go to A003592 to learn more.

----- ADDED LATER -----

I decided to spend a few minutes on my lunch hour to write a program to implement the algorithm described above, using the Scheme programming language. First, here is a library implementation of priority queues using the pairing heap algorithm:

(define pq-empty '())
(define pq-empty? null?)

(define (pq-first pq)
  (if (null? pq)
      (error 'pq-first "can't extract minimum from null queue")
      (car pq)))

(define (pq-merge lt? p1 p2)
  (cond ((null? p1) p2)
        ((null? p2) p1)
        ((lt? (car p2) (car p1))
          (cons (car p2) (cons p1 (cdr p2))))
        (else (cons (car p1) (cons p2 (cdr p1))))))

(define (pq-insert lt? x pq)
  (pq-merge lt? (list x) pq))

(define (pq-merge-pairs lt? ps)
  (cond ((null? ps) '())
        ((null? (cdr ps)) (car ps))
        (else (pq-merge lt? (pq-merge lt? (car ps) (cadr ps))
                            (pq-merge-pairs lt? (cddr ps))))))

(define (pq-rest lt? pq)
  (if (null? pq)
      (error 'pq-rest "can't delete minimum from null queue")
      (pq-merge-pairs lt? (cdr pq))))

Now for the algorithm. Function f takes two parameters, a list of the numbers in the set ps and the number n of items to output from the head of the output. The algorithm is slightly changed; the priority queue is initialized by pushing 1, then the extraction steps start. Variable p is the previous output value (initially 0), pq is the priority queue, and xs is the output list, which is accumulated in reverse order. Here's the code:

(define (f ps n)
  (let loop ((n n) (p 0) (pq (pq-insert < 1 pq-empty)) (xs (list)))
    (cond ((zero? n) (reverse xs))
          ((= (pq-first pq) p) (loop n p (pq-rest < pq) xs))
          (else (loop (- n 1) (pq-first pq) (update < pq ps)
                      (cons (pq-first pq) xs))))))

For those not familiar with Scheme, loop is a locally-defined function that is called recursively, and cond is the head of an if-else chain; in this case, there are three cond clauses, each clause with a predicate and consequent, with the consequent evaluated for the first clause for which the predicate is true. The predicate (zero? n) terminates the recursion and returns the output list in the proper order. The predicate (= (pq-first pq) p) indicates that the current head of the priority queue has been output previously, so it is skipped by recurring with the rest of the priority queue after the first item. Finally, the else predicate, which is always true, identifies a new number to be output, so it decrements the counter, saves the current head of the priority queue as the new previous value, updates the priority queue to add the new children of the current number, and inserts the current head of the priority queue into the accumulating output.

Since it is non-trivial to update the priority queue to add the new children of the current number, that operation is extracted to a separate function:

(define (update lt? pq ps)
  (let loop ((ps ps) (pq pq))
    (if (null? ps) (pq-rest lt? pq)
      (loop (cdr ps) (pq-insert lt? (* (pq-first pq) (car ps)) pq)))))

The function loops over the elements of the ps set, inserting each into the priority queue in turn; the if returns the updated priority queue, minus its old head, when the ps list is exhausted. The recursive step strips the head of the ps list with cdr and inserts the product of the head of the priority queue and the head of the ps list into the priority queue.

Here are two examples of the algorithm:

> (f '(2 5) 20)
(1 2 4 5 8 10 16 20 25 32 40 50 64 80 100 125 128 160 200 250)
> (f '(2 3 5) 20)
(1 2 3 4 5 6 8 9 10 12 15 16 18 20 24 25 27 30 32 36)

You can run the program at http://ideone.com/sA1nn.

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Your algorithm is inefficient in that it over-produces the sequence past the end, and the use of PQ which is growing in size also incurs additional costs per number produced, which are greater than O(1) it seems. I've posted an answer without these two problems. BTW do you have complexity estimate for your pq-rest? pq-insert is O(1) always, and pq-rest seems to be O(size-of-pq) in worst case, but what about amortized? –  Will Ness Apr 15 '12 at 9:04
    
measuring your algorithm interpreted, in MIT-Scheme, it runs at about O(n^1.12) empirical complexity (between n=6k, 12k). The efficient algorithm with back-pointers should run at O(n). btw I could speed your code up by almost 20% (interpreted) with (define (update lt? pq ps) (pq-merge lt? (pq-rest lt? pq) (pq-from-ordlist (map (lambda(p)(* (pq-first pq) p)) ps)))) and (define (pq-from-ordlist xs) (cons (car xs) (map list (cdr xs)))). –  Will Ness Apr 15 '12 at 9:45
    
I've checked it now in Haskell interpreter (GHCi) and the "classic" algorithm indeed runs in O(n) between n=40k, 80k. –  Will Ness Apr 15 '12 at 9:52
    
sorry, didn't mention that I tested your (f '(2 3 5) N) in Scheme. btw between n=12k and n=24k the empirical complexity was O(n^1.08) so it does look like O(n log n) complexity. I measure empirical complexity as log(t2/t1) / log(n2/n1), where t_i is run time and n_i is problem size. –  Will Ness Apr 15 '12 at 10:12

This 2-dimensional exploring algorithm is not exact, but works for the first 25 integers, then mixes up 625 and 512.

Powers of 2 and 5

n = 0
exp_before_5 = 2
while true
  i = 0
  do
    output 2^(n-exp_before_5*i) * 5^Max(0, n-exp_before_5*(i+1))
    i <- i + 1
  loop while n-exp_before_5*(i+1) >= 0
  n <- n + 1
end while
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the thing to do here is to draw a line at atan( log(5)/log(2) ) * 180 / pi = 66.69958829239839 degrees angle to the horizontal axis and collect the points that cross it as we slide it out away from the top left point. –  Will Ness Jul 15 '12 at 7:17
    
Can you provide an algorithm for that ? –  Mikaël Mayer Jul 16 '12 at 8:35
    
I thought I did, in the comment above. :) No, I don't have working code yet. One thing to notice is log 5/log 2 = 2.321928094887362 and '7/3 = 2.333333333333333`. –  Will Ness Jul 16 '12 at 8:41

Based on user448810's answer, here's a solution that uses heaps and vectors from the STL.
Now, heaps normally output the largest value, so we store the negative of the numbers as a workaround (since a>b <==> -a<-b).

    #include <vector>
    #include <iostream>
    #include <algorithm>

    int main()
    {
        std::vector<int> primes;
        primes.push_back(2);
        primes.push_back(5);//Our prime numbers that we get to use

        std::vector<int> heap;//the heap that is going to store our possible values
        heap.push_back(-1);
        std::vector<int> outputs;
        outputs.push_back(1);
        while(outputs.size() < 10)
        {
            std::pop_heap(heap.begin(), heap.end());
            int nValue = -*heap.rbegin();//Get current smallest number
            heap.pop_back();
            if(nValue != *outputs.rbegin())//Is it a repeat?
            {
                outputs.push_back(nValue);
            }
            for(unsigned int i = 0; i < primes.size(); i++)
            {
                heap.push_back(-nValue * primes[i]);//add new values
                std::push_heap(heap.begin(), heap.end());
            }
        }
        //output our answer
        for(unsigned int i = 0; i < outputs.size(); i++)
        {
            std::cout << outputs[i] << " ";
        }
        std::cout << std::endl;
    }

Output:

    1 2 4 5 8 10 16 20 25 32
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(I don't remember if I commented here previously, if so, my apologies) Using heaps leads to overproduction past the desired element and heapify takes additional time, usually O(log n), leading to O(n log n) behaviour. Edsger Dijkstra once shown an O(n) solution, check out the pseudocode in my answer. :) Take e.g. 400. The linear algorithm keeps just two look-back pointers, one to 80, another to 200. But when the priority queue algorithm gets to 400, it has 500,625,640,800,1000,1250,1280,1600,500,512,640 in its heap, past the point of interest. –  Will Ness Sep 2 '12 at 15:13

Removing a number and reinserting all its multiples (by the primes in the set) into a priority queue is wrong (in the sense of the question) - i.e. it produces correct sequence but inefficiently so.

It is inefficient in two ways - first, it overproduces the sequence; second, each PQ operation incurs extra costs (the operations remove_top and insert are not usually both O(1), certainly not in any list- or tree-based PQ implementation).

The efficient algorithm maintains pointers back into the sequence itself as it is being produced, to find and append the next number. In pseudocode:

  return array h where
    h[0]=1; n=0; ps=[2,3,5, ... ]; // base primes
    is=[0 for each p in ps];       // indices back into h
    xs=[p for each p in ps]        // next multiples: xs[k]==ps[k]*h[is[k]]
    repeat:
      h[++n] := minimum xs
      for each (i,x,p) in (is,xs,ps):
        if( x==h[n] )
          { x := p*h[++i]; }       // advance the minimal multiple/pointer

For each minimal multiple it advances its pointer, while at the same time calculating its next multiple value. This too effectively implements a PQ but with crucial distinctions - it is before the end point, not after; it doesn't create any additional storage except for the sequence itself; and its size is always the same whereas the size of past-the-end PQ grows as we progress along the sequence (in the case of Hamming sequence (based on {2,3,5} set), as n^(2/3), for n numbers of the sequence).


The classic Hamming sequence in Haskell is essentially the same algorithm: (general version follows, below)

h = 1 : map (2*) h `union` map (3*) h `union` map (5*) h

union a@(x:xs) b@(y:ys) = case compare x y of LT -> x : union  xs  b
                                              EQ -> x : union  xs  ys
                                              GT -> y : union  a   ys

It is also possible to directly calculate a slice of the sequence, by direct enumeration of the triples and assessing their value through logarithms, logval(i,j,k) = i*log 2+j*log 3+k*log 5. Using the Hamming sequence in Haskell as an example again,

slice hi w = (c, sortBy (compare `on` fst) b) where  -- hi is a top log2 value
  lb5=logBase 2 5 ; lb3=logBase 2 3                  -- w<1 (NB!) is (log2 width)
  (c,b)   = f 0                                      -- total count, the band
      [ ( i+1,                                       -- total triples w/this j,k
          [ (r,(i,j,k)) | frac < w ] )               -- store it, if inside band
        | k <- [ 0 .. floor ( hi   /lb5) ],  let p = fromIntegral k*lb5,
          j <- [ 0 .. floor ((hi-p)/lb3) ],  let q = fromIntegral j*lb3 + p,
          let (i,frac) = properFraction(hi-q) ;  r = hi - frac ]   -- r = i + q
    where 
          f !c []          = (c,[])    
          f !c ((c1,b1):r) = let (cr,br) = f (c+c1) r in
                              case b1 of { [v] -> (cr,v:br) 
                                         ;  _  -> (cr, br) }
       -- f 0 xs = (sum $ map fst xs, concat $ map snd xs)

We can generate smooth numbers for arbitrary base primes using foldi function (see wikipedia) to fold lists in a tree-like fashion, creating a priority queue as a tree of comparisons:

smooth base_primes = h   where       -- strictly increasing base_primes  NB!
    h = 1 : foldi g [] [map (p*) h | p <- base_primes]
    g (x:xs) ys = x : union xs ys

foldi f z []     = z
foldi f z (x:xs) = f x (foldi f z (pairs f xs))

pairs f (x:y:t)  = f x y : pairs f t
pairs f t        = t
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