I am stuck on a problem, where it says, given a number N and a set of numbers, S = {s1,s2,.....sn} where s1 < s2 < sn < N, remove all the multiples of {s1, s2,....sn} from range 1..N


Let N = 10
S = {2,4,5}
Output: {1, 7, 9}
Explanation: multiples of 2 within range: 2, 4, 6, 8
             multiples of 4 within range: 4, 8
             multiples of 5 within range: 5, 10 

I would like to have an algorithmic approach, psuedocode rather than complete solution.

What I have tried:

(Considering the same example as above) 

 1. For the given N, find all the prime factors of that number.
    Therefore, for 10, prime-factors are: 2,3,5,7
    In the given set, S = {2,4,5}, the prime-factors missing from 
    {2,3,5,7} are {3,7}.  
 2. First, check prime-factors that are present: {2,5}
    Hence, all the multiples of them will be removed 
 3. Check for non-prime numbers in S = {4}
 4. Check, if any divisor of these numbers has already been 
    previously processed.
         > In this case, 2 is already processed.
         > Hence no need to process 4, as all the multiples of 4 
           would have been implicitly checked by the previous 
    If not,
         > Remove all the multiples from this range.
 5. Repeat for all the remaining non primes in the set.

Please suggest your thoughts!


It is possible to solve it in O(N log(n)) time and O(N) extra memory using something similar to the Sieve of Eratosthenes.

isMultiple[1..N] = false

for each s in S:
    t = s
    while t <= N:
        isMultiple[t] = true
        t += s

for i in 1..N:
    if not isMultiple[i]:
        print i

This uses O(N) memory to store the isMultiple array.

The time complexity is O(N log(n)). Indeed, the inner while loop will be performed N / s1 times for the first element in S, then N / s2 for the second, and so on.

We need to estimate the magnitude of N / s1 + N / s2 + ... + N / sn.

N / s1 + N / s2 + ... + N / sn = N * (1/s1 + 1/s2 + ... + 1/sn) <= N * (1/1 + 1/2 + ... + 1/n).

The last inequality is due to the fact that s1 < s2 < ... < sn, thus the worst case is when they take values {1, 2, .. n}.

However, the harmonic series 1/1 + 1/2 + ... + 1/n is in O(log(n)), (e.g. see this), thus the time complexity of the above algorithm is O(N log(n)).


basic solution:

let set X be our output set.

for each number, n, between 1 and N:
    for each number, s, in set S:
        if s divides n:
            stop searching S, and move onto the next number,n.
        else if s is the last element in S:
            add n to the set X.

you can obviously remove multiples in S before running this algorithm, but I don't think prime numbers are the way to go


Since S is sorted, we can guarantee O(N) complexity by skipping elements in S already marked (http://codepad.org/Joflhb7x):

N = 10
S = [2,4,5]
marked = set()
i = 0
curr = 1

while curr <= N:
  while curr < S[i]:
    print curr
    curr = curr + 1

  if not S[i] in marked:
    mult = S[i]

    while mult <= N:
      mult = mult + S[i]

  i = i + 1
  curr = curr + 1

  if i == len(S):
    while curr <= N:
      if curr not in marked:
        print curr
      curr = curr + 1

print list(marked)

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