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This is an interview question: Impement a Set class with get, put, and getRandom.

I would consider the following options:

  • sorted/unsorted linked list: get - O(N), put - O(N), getRandom - O(N)
  • unsorted vector (resizable array): get - O(N), put - ?, getRandom - O(1)
  • sorted vector (resizable array): get - O(logN), put - ?, getRandom - O(1)
  • hash table: get - O(1), put - O(1), getRandom - O(table size)
  • balanced binary search tree: get - O(logN), put - O(logN), getRandom - O(N)

It looks like the best candidates are:

  • hash table if get/put are much more frequent than getRandom
  • sorted vector (resizable array) if getRandom is much more frequent than get/put

Now I wonder if we can combine a vector and hash table somehow to make up a better set.

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In a sorted linked list, lookup and insertion take linear time. –  larsmans Jun 16 '12 at 19:30
@larsmans Thanks. I will fix it. –  Michael Jun 16 '12 at 20:36

3 Answers 3

up vote 5 down vote accepted

You can make get, put and getRandom all be O(1) average time.

What you do is store 2 data structures. One is a hash. The other lists the elements in random order in a growable array.

When you put, you put it in the hash, add the element to the end of the array, then swap the end of the array for a random array element.

When you get, you look in the hash for the element.

When you getRandom, you take the last element of the array, and then swap that last element with another spot in the array.

If you want you can add delete as just removing the hash. Now getRandom is implemented by taking the element, checking whether it is in the hash, and if it is not then shrinking the array, and repeating. At this point getRandom is occasionally O(n) BUT the amortized average costs of all operations can be proven to be O(1).

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Wouldn't it be simpler to: store the elements in the array in insertion order, store the index in the array with the key in the hash table, implement getRandom by generating a random index into the array, and implement delete as deletion in a hash table + O(1) deletion from the array using the index that was stored in the array earlier? +1, btw. –  larsmans Jun 16 '12 at 19:54
@larsmans, how would you have O(1) deletion from an array? @btilly, I think your random method will be slightly skewed with subsequent deletions (i.e. put(x); delete(x); put(x)). –  ffao Jun 16 '12 at 20:21
@btilly Also, I don't see how could this be amortized O(1). Suppose you add n different items, then proceed to delete those n items and ask for a random element. You would do 2n + 1 operations in O(n²) time, making overall amortized cost O(n). Of course, it`s my fault not to notice the original problem had no deletions -- this answers the question perfectly as asked, for that +1. –  ffao Jun 16 '12 at 20:23
@ffao: easy. To delete element i, swap it with the last element and decrement the size so that the last one "falls off". Then, look up the last element in the hash table and change the index there. –  larsmans Jun 17 '12 at 0:07
@larsmans ah, makes sense, hadn't thought of that. –  ffao Jun 17 '12 at 0:34

If you keep a separate structure that tells you how many items there are in each bucket of a hash table, you can use binary search to find the n-th element, which would give you O(log n) for all three operations.

A balanced binary search tree augmented with a "count" for each node (that tells how many nodes has the subtree rooted at this node) would work as well for those bounds.

Some corrections to the above: you can't do random access in a linked list, so all operations are O(N). Also, put is O(n) in both vectors due to having to displace elements in the sorted version and checking for duplicates in the unsorted version.

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find ~O(1)
delete ~O(1)
add ~O(1)
For Random we use an array with all the elements and select a random element O(1)

#include <stdio.h>
#include <vector>
#define MOD 666013
using namespace std;

int N;
vector<int> G[MOD];

vector<int>::iterator find(int x)
    int list=x%MOD;                  // f(i) = i % MOD this is my hash function
    vector<int>::iterator it;

    for (it=G[list].begin();it!=G[list].end();++it)
        if (*it==x)
            return it;
    return G[list].end();

void add(int x)
    int list=x%MOD;                     //again this is my hash function that gives me the key
    if (find(x)==G[list].end())

void delete(int x)
    int list=x%MOD;
    vector<int>::iterator it=find(x);

    if (it!=G[list].end())
share|improve this answer
It would be pretty easy to just search/replace those few words, and rather convenient for those who don't speak Romanian. –  Junuxx Jun 16 '12 at 19:24
I'm baffled by the phrase "random is also O(1) if you know what are you looking [for]". Care to explain? –  larsmans Jun 16 '12 at 19:25
Find is O(1) so it all depends of your random function, if your random function gives an element in constant time than "Random an element" is O(1) –  Ionescu Robert Jun 16 '12 at 19:27
@larsmans he is saying to use this random function xkcd.com/221 –  ffao Jun 16 '12 at 19:29
You mean, generate a random hash value and look that up? That wouldn't work with a chained hash table, and in one that overallocates, you might find a bucket with no value in it. –  larsmans Jun 16 '12 at 19:30

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