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I have two sets of elements and I want an optimal algorithm to find their differences or in math form: A U B - A ∩ B

One way I thought is

Bfound=0;
for (1->Na,i)
{
 flag=0;
 for (1->Nb,j)
 {
  if(A[i]==B[j])
  {
   flag=1;
   Bfound[j]=1;
  }

 }
 if (flag==0)
 print A[i]
}

for(1->Nb,i)
{
  if(Bfound[i]==0)
  print B[i]
}

Is this optimal?

share|improve this question
    
if there are number, the best way is to sort the arrays (universes) with what would be like a Quick sort and then compare each element of one array with the ones of the other using the dichotomy method –  발렌탕 Mar 11 '12 at 22:19
    
No AUB is union meaning elements that belong to set A or B or both, well I asked for the symmetric difference or: A∪B-A∩B, so should I accept this question? –  George Panic Mar 11 '12 at 23:11

2 Answers 2

up vote 3 down vote accepted

To answer your question - no, this is not optimal. The complexity of your solution is O(nm) time, where n and m are the sizes of A and B, respectively. You can improve this time to O(nlogn + mlogm), if n ~ m.

  1. Sort both arrays, in n log n + m log m time.
  2. Find the intersection in n+m time:

    i = 0; 
    j = 0;
    while(i < n && j < m) {
      if (A[i] == B[j]) {
        print(A[i]);
        i++;
        j++;
      } else if (A[i] < B[j]) {
        i++;
      } else {
        j++;
      } 
    }
    
share|improve this answer
    
Thanks! what I want is the symmetric difference A∪B-A∩B so I will print on the other two cases of the if close –  George Panic Mar 11 '12 at 23:15

Symmetric difference: A∪B - A∩B i.e., return a new set with elements in either A or B but not both. The straightforward way from the definition:

# result = A ^ B
result = set() # start with empty set

# add all items that are in A but not in B
for item in A: # for each item in A; O(|A|), where |A| - number of elements in A
    if item not in B: # amortized O(1) (for hash-based implementation)
       result.add(item) # amortized O(1) (for hash-based implementation)

# add all items that are in B but not in A
for item in B:
    if item not in A:
       result.add(item)

Complexity O(|A|+|B|).

In C++ the type is unordered_set, in Java, C# -- HashSet, in Python -- set.

Another approach (used in Python) is to copy A into result and then try to remove B items from the result:

# result = A ^ B
result = set(A) # copy A into result
for item in B:
    try: result.remove(item) # O(1)
    except KeyError: # item was not in the result
        result.add(item) # add previously not-found item

Complexity O(|A|+|B|).

share|improve this answer
    
I like the approach used in python I don't understand |A|+|B|, I think the complexity will still be O(mn) unless you consider the sets ordered –  George Panic Mar 11 '12 at 23:40
    
@George Panic: |x| - number of elements in the set x. + is arithmetic operator 2+3 == 5. The complexity is O(n + m), where n is number of elements in A, m -- number of elements in B. If the sets are ordered (tree-based implementation instead of hash-based one) then the complexity is O(n*log(n) + m*log(m)) i.e., it is worse. –  J.F. Sebastian Mar 11 '12 at 23:46

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