5

I am working on a code challenge problem -- "find lucky triples". "Lucky triple" is defined as "In a list lst, for any combination of triple like (lst[i], lst[j], lst[k]) where i < j < k, where lst[i] divides lst[j] and lst[j] divides lst[k].

My task is to find the number of lucky triples in a given list. The brute force way is to use three loops but it takes too much time to solve the problem. I wrote this one and the system respond "time exceed". The problems looks silly and easy but the array is unsorted so general methods like binary search do not work. I am stun in the problem for one day and hope someone can give me a hint. I am seeking a way to solve the problem faster, at least the time complexity should be lower than O(N^3).

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  • 3
    " Is there any way faster to find the total number of lucky triples?" Presumably the answer is "yes" if this has been assigned as homework. What have you tried? – John Coleman Sep 27 '16 at 3:22
  • @JohnColeman I have written the brute force one. I have not figured out any other method so I am seeking for help. Why do you guys downvote this? Please let me know what I should improve. – Anderson Sep 27 '16 at 12:19
  • 1
    The way the question was phrased made it seem a bit too much like a mere statement of a homework problem with no evidence of effort on the student's part to solve it. Many of these types of question are posted each day and they tend to be heavily downvoted. Your question might have been mistaken for such a question. You would have gotten a much better response if you had said that you had implemented a brute-force solution and wanted some hints about finding a more efficient solution. If you edit your question slightly, I'll gladly change my downvote to an upvote. – John Coleman Sep 27 '16 at 12:40
  • @JohnColeman, Hi, John, I have modified the description. Hope it works fine. Any idea about the problem is appreciated. Thanks. – Anderson Sep 27 '16 at 13:03
  • If a%b = 0 and b%c = 0, what about a%c? – greybeard Sep 27 '16 at 13:32
15

A simple dynamic programming-like algorithm will do this in quadratic time and linear space. You just have to maintain a counter c[i] for each item in the list, that represents the number of previous integers that divides L[i].

Then, as you go through the list and test each integer L[k] with all previous item L[j], if L[j] divides L[k], you just add c[j] (which could be 0) to your global counter of triples, because that also implies that there exist exactly c[j] items L[i] such that L[i] divides L[j] and i < j.

int c[] = {0}
int nbTriples = 0
for k=0 to n-1
  for j=0 to k-1
    if (L[k] % L[j] == 0)
      c[k]++
      nbTriples += c[j]
return nbTriples

There may be some better algorithm that uses fancy discrete maths to do it faster, but if O(n^2) is ok, this will do just fine.

In regard to your comment:

  • Why DP? We have something that can clearly be modeled as having a left to right order (DP orange flag), and it feels like reusing previously computed values could be interesting, because the brute force algorithm does the exact same computations a lot of times.

  • How to get from that to a solution? Run a simple example (hint: it should better be by treating input from left to right). At step i, compute what you can compute from this particular point (ignoring everything on the right of i), and try to pinpoint what you compute over and over again for different i's: this is what you want to cache. Here, when you see a potential triple at step k (L[k] % L[j] == 0), you have to consider what happens on L[j]: "does it have some divisors on its left too? Each of these would give us a new triple. Let's see... But wait! We already computed that on step j! Let's cache this value!" And this is when you jump on your seat.

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    Very concise solution. I tried to use dynamic programming to solve it but do not find the rules. Could you share your thinking process? Like how to you come up with the idea use dp and how do you define the transition formula. – Anderson Sep 27 '16 at 15:06
  • Please tell me the answer for the following array according to your algorithm: a = [3, 6, 5, 30, 18] – User_Targaryen Sep 27 '16 at 15:14
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    There are 2 valid triples above, [3,6,18], [3,6,30]. Your code gives a different answer... – User_Targaryen Sep 27 '16 at 15:26
  • @User_Targaryen I'm sorry, I didn't verify, it may very well be the case. But I can't see how it fails: it will return 2 on your sample, won't it? Anyway, the important thing is that DP is applicable and very simple here. – Patrice Gahide Sep 27 '16 at 15:35
  • No, it doesn't return 2.. check again...Even I coded a similar solution like yours, but found the flaw.. – User_Targaryen Sep 27 '16 at 15:37
7

Full working solution in python:

c = [0] * len(l)
print c
count = 0

for i in range(0,len(l)):
  j=0
  for j in range(0, i):
    if l[i] % l[j] == 0:
      c[i] = c[i] + 1
      count = count + c[j]
    print j           

print c
print count
1
  • With multiplicity. – vesszabo Jul 14 '20 at 6:50
2

A precomputation step to the problem can help reduce time complexity.

Precomputation Step:

For every element(i), iterate the array to find which are the elements(j) such that lst[j]%lst[i]==0

for(i=0;i<n;i++)
{
   for(j=i+1;j<n;j++)
   {
      if(a[j]%a[i] == 0)
         // mark those j's. You decide how to store this data
   }
}

This Precomputation Step will take O(n^2) time.

In the Ultimate Step, use the details of the Precomputation Step, to help find the triplets..

4
  • It seems this way is the same as the brute force one. After precomputation, I got the eligible numbers of lst[j]. If I use the marked numbers lst[j], the whole process is like splitting three loops to two sections of two loops but the computation number is the same. – Anderson Sep 27 '16 at 12:24
  • @Anderson: If you have to enumerate all the different lucky triples, then the worst case has to be O(N^3). If you have to only count the number of such lucky triples, then you can find it in O(N^2) time with O(N) space. Do you want me to supply you with the code that only returns the count of such triples?? – User_Targaryen Sep 27 '16 at 14:15
  • @User_Targaryen Good point about the worst case (e.g. 2,4,8,...,2^N) but it seems like if the numbers are random you should be able to get to an average-time complexity which is quadratic. Maybe something involving building up a tree as the list is scanned. – John Coleman Sep 27 '16 at 14:22
  • @User_Targaryen, Thank you for your help, I only need count of triples. Just implement a O((N ^ 2 )* lgN) solution and it still yield to time exceed – Anderson Sep 27 '16 at 14:27
1

Read up on the Sieve of Eratosthenes, a common technique for finding prime numbers, which could be adapted to find your 'lucky triples'. Essentially, you would need to iterate your list in increasing value order, and for each value, multiply it by an increasing factor until it is larger than the largest list element, and each time one of these multiples equals another value in the list, the multiple is divisible by the base number. If the list is sorted when given to you, then the i < j < k requirement would also be satisfied.

e.g. Given the list [3, 4, 8, 15, 16, 20, 40]:

Start at 3, which has multiples [6, 9, 12, 15, 18 ... 39] within the range of the list. Of those multiples, only 15 is contained in the list, so record under 15 that it has a factor 3.

Proceed to 4, which has multiples [8, 12, 16, 20, 24, 28, 32, 36, 40]. Mark those as having a factor 4.

Continue through the list. When you reach an element that has an existing known factor, then if you find any multiples of that number in the list, then you have a triple. In this case, for 16, this has a multiple 32 which is in the list. So now you know that 32 is divisible by 16, which is divisible by 4. Whereas for 15, that has no multiples in the list, so there is no value that can form a triplet with 3 and 15.

2
  • It is good solution but the list is unsorted. DO you have any other idea? When dealing with unsorted array, the common methods may not work. I try to preprocess the data but I DO NOT WORK – Anderson Sep 27 '16 at 12:21
  • Sieve of Eratosthenes is a good reference that adds another perspective to the solution. There is lesson and some more code challenges on Codility which may be useful to others as it been to me. – Anit Shrestha Manandhar Nov 11 '20 at 15:46
0

Forming a graph - an array of the indices which are multiples ahead of the current index. Then calculating the collective sum of multiples of these indices, referred from the graph. It has a complexity of O(n^2)

For example, for a list {1,2,3,4,5,6} there will be an array of the multiples. The graph will look like { 0:[1,2,3,4,5], 1:[3,5], 2: [5], 3:[],4:[], 5:[]}

So, total triplets will be {0->1 ->3/5} and {0->2 ->5} ie., 3

package com.welldyne.mx.dao.core;

import java.util.LinkedList;
import java.util.List;

public class LuckyTriplets {

  public static void main(String[] args) {

    int[] integers = new int[2000];

    for (int i = 1; i < 2001; i++) {

        integers[i - 1] = i;
    }
    long start = System.currentTimeMillis();
    int n = findLuckyTriplets(integers);
    long end = System.currentTimeMillis();
    System.out.println((end - start) + " ms");
    System.out.println(n);

  }

  private static int findLuckyTriplets(int[] integers) {

    List<Integer>[] indexMultiples = new LinkedList[integers.length];

    for (int i = 0; i < integers.length; i++) {

        indexMultiples[i] = getMultiples(integers, i);
    }

    int luckyTriplets = 0;
    for (int i = 0; i < integers.length - 1; i++) {

        luckyTriplets += getLuckyTripletsFromMultiplesMap(indexMultiples, i);
    }
    return luckyTriplets;
  }

  private static int getLuckyTripletsFromMultiplesMap(List<Integer>[] indexMultiples, int n) {

    int sum = 0;

    for (int i = 0; i < indexMultiples[n].size(); i++) {

        sum += indexMultiples[(indexMultiples[n].get(i))].size();
    }

    return sum;
  }

  private static List<Integer> getMultiples(int[] integers, int n) {

    List<Integer> multiples = new LinkedList<>();
    for (int i = n + 1; i < integers.length; i++) {

        if (isMultiple(integers[n], integers[i])) {

            multiples.add(i);
        }
    }
    return multiples;
 }

 /*
  * if b is the multiple of a
  */
 private static boolean isMultiple(int a, int b) {

    return b % a == 0;
 }
}

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