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I am looking for solution for :

Given a array and a number P , find two numbers in array whose product equals P.

Looking for solution better than O(n*2) . I am okay with using extra space or other datastructure .Any help is appreciated ?

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4  
this really sounds like homework. –  Ken Struys Sep 21 '10 at 4:55
    
Are there any restrictions on the types of numbers (such as just integers, just positive integers, etc.)? –  Michael Aaron Safyan Sep 21 '10 at 5:00
    
no restrictions on the number. –  TopCoder Sep 21 '10 at 5:01
    
if there are no restrictions on the numbers (aside from presumably real) the likelihood that there exists a solution approaches zero, especially if one or more of the numbers is a floating point approximation. Classic paper: docs.sun.com/source/806-3568/ncg_goldberg.html –  msw Sep 21 '10 at 5:20

6 Answers 6

up vote 9 down vote accepted

You can try a sliding window approach. First sort all the numbers increasingly, and then use two integers begin and end to index the current pair of numbers. Initialize begin to 0 and end to the last position. Then compare the product of v[begin] and v[end] with P:

  • If it is equal, you found the answer.
  • If it is lower, you must find a bigger product, move begin forward.
  • If it is higher, you must find a smaller product, move end backward.

Here is a C++ code with this idea implemented. This solution is O(n*log(n)) because of the sorting, if you can assume the data is sorted then you can skip the sorting for an O(n) solution.

pair<int, int> GetProductPair(vector<int>& v, int P) {
  sort(v.begin(), v.end());
  int begin = 0, end = static_cast<int>(v.size()) - 1;
  while (begin < end) {
    const int prod = v[begin] * v[end];
    if (prod == P) return make_pair(begin, end);
    if (prod < P) ++begin;
    else --end;
  }
  return make_pair(-1, -1);
}
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1  
I have the intuition that this might not find the solution. –  pascal Sep 21 '10 at 5:51
6  
@pascal: This technique works, and it can be proven. However, doing this after sorting is not useful in terms of complexity. You can simply scan the items and use binary search to find the complementing operand. The overall complexity is still O(N Log N). The advantage of this technique is when the array is already sorted, so you can achieve linear time. –  Eyal Schneider Sep 21 '10 at 7:39
1  
Yes, you're right. I was thinking about moving begin once too far, and having to move it back in order to try a pair with a larger end. But in this mental image, I neglect that the array was also sorted on the end side... –  pascal Sep 21 '10 at 7:53

Make a pass through the array, and add the elements to a Hashtable. For each element x added, check whether P/x already exists in the Hashtable - if it does then x and P/x is one of your solutions. This'd be about as optimal as you'll get.

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Except that they can be arbitrary floating point :( –  Michael Aaron Safyan Sep 21 '10 at 5:09
    
This will work . thanks! –  TopCoder Sep 21 '10 at 5:10
1  
@Michael - does that matter? Granted P/x might not be exactly spot-on an element in the Hashtable - if this poses a problem then sorting the array and binary searching to locate the closest element to P/x and multiplying that element by x to check for P might be a better choice. –  Will A Sep 21 '10 at 5:12
    
your answer is, of course, spot on. However, some level of quantization / binning must be done in the implementation for this to work. Then again, such quantization is also necessary for the O(n^2) algorithm. Please forgive comments posted late in the evening. :) –  Michael Aaron Safyan Sep 22 '10 at 0:41

This one would work only for integers: Decompose P as product of prime numbers. By dividing these in two groups you can obtain the pairs that gives P as product. Now you just have to check both of them are present in the array, this is where a hash table would be very useful. Also, while creating the hash table, you could also filter the array of repeating values, values that are greater than P, or even values that have prime factors not contained in P.

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Good idea, although decomposing might be a little bit more than O(n²). –  liori Sep 21 '10 at 9:17
    
@liori: Not necessarily, if you have a precomputed list of prime numbers, then it's O(n). –  ruslik Sep 21 '10 at 10:16
    
Yes, you're right. Although to store primes necessary to factorize any 64-bit integer you'd need ~0.8GB of memory. Anyway, +1. –  liori Sep 21 '10 at 17:36

1.sort the numbers into an array A, removing any zeroes, in O(nlogn) time

2.create an array B such that B[i] = P/A[I] in O(n) time

3.for every B[k] in B, do a binary search in A for that element, takes O(nlogn) time in the worst case

if the element B[k] exists in the array A at position m, then A[k] * A[m] = P otherwise no such pair exists

the total running time is O(nlogn)

Of course this may run into difficulties on a real machine due to floating point error

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Here's my shot, it only compares any factors with each other once

P <- The Number
theArray <- new array[theData]
factors <- new array[]
isFactor <- new map(init: false)
factorCount <- 0
i <- 0
while i is in theArray
    num <- theArray[i]
    if (isFactor[num])
        skip
    if num modulo P == 0
        isFactor[num] <- true
        j <- 0
        while j is in factors
            if factors[j] * num == P
                return (num, factors[j])
            j++
        factors.push(num)
        factorCount++
    i++
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Does factors ever have anything placed into it? –  Will A Sep 21 '10 at 5:19

Not sure if this is the best solution but it works. you can try and optimize it.

public class CombInput
    {
        public int ID;
        public string Value;
    }

  public List<string> GetCombinations(List<string> values)
        {

            List<CombInput> input = new List<CombInput>();
           List<string> outputvalues = new List<string>();
            int counter = 1;
             foreach (String c in values)
             {
                 input.Add(new CombInput { ID = counter, Value = c });

                 counter++;
             }
            var Output = from i in input
                        select i;

            string Final = Output.Select(query => query.Value).Aggregate((a, b) => a + "|" + b);

            while (!Output.ToList().Exists(s=>s.Value.ToString()==Final))
            {
                var store = Output;  
                var  Output1= 
                (from o in Output
                          from v in input
                         where (v.ID < o.ID && !(store.Any(a=>a.Value==v.Value + "|" + o.Value)))
                               select new CombInput { ID = v.ID, Value = v.Value + "|" + o.Value });

                var Outputx = (from s in store select s)
                .Concat
                (from s in Output1.ToList() select s);
                Output = Outputx;
            }


            foreach (var v in Output)
                outputvalues.Add(v.Value);
            return outputvalues.ToList();
        }

 public List<string> GetProductCombinations(List<int> nums, int productCriteria)
        {
            List<string> input = (from i in nums
                                 select i.ToString()).ToList();
            input = GetCombinations(input);

            var O = from i in input
                    where i.Split('|').ToList().Select(x => Convert.ToInt32(x)).ToList().Aggregate((a, b) => a * b) == productCriteria
                    select i;


            List<string> output=new List<string>();
            foreach (string o in O)
            {
                output.Add(o);
            }
            return output;
        }


 private void button1_Click(object sender, EventArgs e)
        {

             List<string> output = new List<string>();
            List<int> nums = new List<int>();
            int[] numsarr ={1,2,3,4,6,7,8,12};
            nums = numsarr.ToList();
            output = GetProductCombinations(nums, 12);
}
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