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Suppose we have N people and there might be a group of celebrities inside.

Every person knows every celebrity and every celebrity knows only every other celebrity.

If you are given the function of know x y which returns true or false, identify the group of celebrities.

This problem is to identify a group of celebrities, and it is not identifying the only celebrity among the people, such as http://www.geeksforgeeks.org/the-celebrity-problem/.


Using brute force is easy. I can construct all possible sub-sequences of N people and filter them with the condition (everyone knows every celebrity and every celebrity knows only other celebrity).

Also I know there must be only one celebrity group or none.

Proof:

Suppose we have two celebrity groups, C1 and C2. Because everyone knows ci from C1, so every cj from C2 also knows ci; symmetrically, every ci knows cj; So C1 and C2 actually belongs to one group. So we have at most one celebrity group or none.

Any ideas on possible linear algorithm?

edit

There might be a group of celebrity and there might be none.

share|improve this question
    
A single celebrity knows every other celebrity? As in, ANY single celebrity knows EVERY other celebrity? – isick Jan 7 '14 at 22:28
    
@isick yes, exactly – Jackson Tale Jan 7 '14 at 22:30
    
Can a non-celebrity know any number of other non-celebrities as well, or not? – Dukeling Jan 7 '14 at 22:39
3  
The most challenging case is if everyone knows everyone, since this requires N*(N-1) calls to know to verify that everyone is a celebrity. – Daniel Jan 7 '14 at 22:57
1  
Wouldn't the answer be the intersection of everyone's set of persons they know? – Eugen Constantin Dinca Jan 7 '14 at 23:39
up vote 8 down vote accepted

Yes, this is possible in O(N) (but see 2nd edit below). Here's one algorithm.

Enumerate all N people from 0 to N-1.

int find_a_celebrity()
{
    int C = 0; // C is a potential celebrity
    for( int i=0 ; i<N ; ++i )
      if( !know(i,C) ) // C is not a celebrity nor are all j<i, but i might be.
        C = i; 
    for( int i=0 ; i<N ; ++i ) // Loop a second time to check everyone knows C.
      if( !know(i,C) ) return -1;
    return C;
}
int C = find_a_celebrity();

If C==-1 then there are no celebrities. Otherwise the set { y | know(C,y) } is the set of all celebrities. All together, this took at most 3 iterations through all N people, so this is discovered in time O(N).

Edit:

// Output the set of celebrities
if( C == -1 ) std::cout << "There are no celebrities.";
else for( int i=0 ; i<N ; ++i ) if( know(C,i) ) std::cout << i << ' ';
std::cout << std::endl;

Edit 2:

There are two interpretations to this problem:

  1. The definition of a celebrity is that they are known by everyone. By a constraint of the problem, all celebrities only know other celebrities.
  2. The definition of a celebrity is that they are known by everyone, and celebrities only know other celebrities.

The above algorithm solves this for case #1. This works for case #2 as well, as long as we can assume that there exists at least one celebrity. Otherwise we will have to verify at the end that the list of potential celebrities only know each other, which requires O(N*M) time where M is the number of potential celebrities.

share|improve this answer
    
could you please complete the code? – Jackson Tale Jan 7 '14 at 23:43
    
@JacksonTale Done. Hope that helps. – Matt Jan 7 '14 at 23:50
    
All non-celebrities don't necessarily know each other, so I don't think this will work (you start off with C = a non-celeb A, non-celeb B doesn't know A, thus you assign C to B, then return -1 because everyone doesn't know B). – Dukeling Jan 8 '14 at 0:05
    
what @Dukeling says is true. We can't assume all non-celebrities know each other. – Jackson Tale Jan 8 '14 at 0:07
    
@Dukeling Yes that's correct, all non-celebs may not know each other, and that is not assumed. Your example is not complete - yes C=B, but it still checks the remainder of the list for other potential celebs. If it finds one, then it assigns it to C. If not, there there are no celebs and -1 is the correct return value. – Matt Jan 8 '14 at 0:13

EDIT: I didn't read the problem statement carefully enough. You don't have a list of all edges and we're assuming we can't generate it in linear time.

The key here is that every person knows every celebrity. Formulate this problem as a directed adjacency graph with V vertexes (celebrities) and E edges (relationships) connecting them.

Iterate through the list E to count how many times each person is known. Celebrities are known V-1 times; everyone else is a non-celebrity. Running time should be O(E).

share|improve this answer
    
I thought about a graph too, but constructing the graph would be expensive (there are a quadratic number of relationships already). – Dukeling Jan 7 '14 at 22:42
    
Strictly speaking, you only need the list of celebrities and the list of relationships; you don't need an actual matrix or 2D array to implement a graph. – Daniel Jan 7 '14 at 22:45
1  
Yeah but you don't have a list of relationships you only have a function to determine a relationship given two people. – isick Jan 7 '14 at 22:46
    
Oh, that's right... I've seen this problem before, let me see if I can remember the trick behind solving it in linear time. – Daniel Jan 7 '14 at 22:48
2  
@Daniel Not so. If everyone knows everyone, you can start with 1 person called C. Check that everyone knows C. Then C is a celebrity. By definition, everyone else that C knows is also a celebrity, and in fact that is all the celebrities, and you are done in O(N). See my answer. – Matt Jan 7 '14 at 23:34

Being a celebrity is the state of being known without knowing. Being normal is the state of knowing without being known. Therefore comparing each person to the person next to them would look something like:

foreach person in persons
{
  knows = know(person, next_person)
  isknown = know(next_person, person)

  if knows and !isknown then normal
  if !knows and isknown then celeb
  if !knows and !isknown then normal
  if knows and isknown then friends.add(person)

  foreach friend in friends
  {
      alsoknows = know(person, friend)
      if !alsoknows then normal; break;
  }
}
share|improve this answer
    
Construct a sublist of friends is an interesting approach. I think your criteria is a little off in that you can't say for certain that person is a celebrity just because another person knows them; everyone must know them. But the idea of creating a sublist is still interesting. However, you'll have to nest loops over the "friends" list to be certain your final list is exhaustive and exclusive. And in cases where everyone knows the next_person your friends list will be a clone of the starting "persons" list which means it's still O(N^2) – isick Jan 8 '14 at 5:04
    
Yes my solution is flawed. I only left it up because I thought it might contribute some notions. My wife told me to stop trying to solve this :) – Daniel C Jan 8 '14 at 10:12
    
@isick I should add that you can definitely say that someone is a celebrity because another person knows them AND they don't know that person. – Daniel C Jan 8 '14 at 10:44

Consider the case where all N*(N-1) possible evaluations of knows(x,y) are true. In this case, all N people are celebrities. Next, consider the case where all but one of the N*(N-1) evaluations of knows(x,y) are true. According to this comment by the asker, I expect that we should interpret this scenario as having zero celebrities. In order to distinguish these two situations, you need to evaluate all possible N*(N-1) pairs.

share|improve this answer

Let candidates be a list of all n people. Contstruct a cycle of all people:

1 -> 2 -> ... -> n -> 1.

Now, check one by one knows k,k+1. If true than k = k+1 and continue. If knows k,k+1 == False, then k+1 is not a celebrity so remove him from candidates and check k,k+2 instead.

We finish when we haven't removed anyone in last size(candidates) turns.

Proof:

If there is a celebrity in the list then:

  1. he will never be removed
  2. once we reach him we go further to the last celebrity
  3. algorithm will remove all non-celebrities 'after the last one' till we get another celebrity and then we get back to 2.

Finally we will get a cycle of celebrities.

If there is no celebrity in the list, then follow @Matt's answer.

share|improve this answer
    
it is not correct. suppose 0 doesn't know 1 or 2, and 1 doesn't know 0 either. in your algorithm, 0 will be the only one left, but it is not the correct answer – Jackson Tale Jan 7 '14 at 23:40
    
If 0 doesn't know 1 then 1 is not a celebrity and we may remove him - information he provides is redundant in the context of my algorithm. Now, if 0 stays in the cycle and there is at least 1 celebrity then at some point 0 will be removed. If there are no celebrities in the cycle then contradiction with "there is a group of celebrities inside" (I'm assuming it's size is positive). – Łukasz Kidziński Jan 8 '14 at 7:15
    
Ps. If we include possibility that there is no celebrities at all then it is impossible to solve the problem. For each group of people where there is a celebrity we can construct another group with exactly the same relation knows without celebrities. So we can't distinguish those two cases. – Łukasz Kidziński Jan 8 '14 at 16:57
1  
+1 Nice one. Like my answer, this works if we know there exists at least 1 celebrity. Otherwise, this produces only a list of potential celebrities, which then requires O(N*M) time to verify, where M is the size of the resulting list. – Matt Jan 8 '14 at 17:31
    
Actually if there is no celebrities and a clique of posers (non celebrities knowing only each other) we won't be able to verify. – Łukasz Kidziński Jan 8 '14 at 17:42

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