# How to find a number that was repeated (n/3) times an array of size n, in O(n) time and O(n) space?

I have this question that I just can't figure it out! Any hints would mean a lot. Thank you in advance. I have an array, `A`. It's size is `n`, and I want to find an algorithm that will find `x` that appears in this array at least `n/3` times. If there is no such x in the array then we will print that we didn't find one! I need to find an algorithm that does this in `O(n)` time and takes `O(n)` space.

For example:

``````A=[1 1 2 2 1 1 1 5 6 7]
``````

For the above array, the algorithm should return `1`.

Here is my solution in pseudocode; note that it is possible to have two solutions as well as one or none:

``````func anna(A, n)                  # array and length
ht := {}              # create empty hash table
for k in [0,n)             # iterate over array
if A[k] in ht             # previously seen
ht{k} := ht{k} + 1    # increment count
else                      # previously seen
ht{k} := 1           # initialize count
solved := False        # flag if solution found
for k in keys(ht)     # iterate over hash table
if ht{k} > n / 3           # found solution
solved := True            # update flag
print k                      # write it
if not solved               # no solution found
print "No solution"        # report failure
``````

The first `for` loop takes O(n) time. The second `for` loop potentially takes O(n) time if all items in the array are distinct, though most often the second `for` loop will take much less time. The hash table takes O(n) space if all items in the array are distinct, though most often it takes much less space.

It is possible to optimize the solution so it stops early and reports failure if there are no possible solutions. To do that, keep a variable max in the first `for` loop, increment it every time it is exceeded by a new hash table count, and check after each element is added to the hash table if max + n - k < n / 3.

If I was you, I write an algorithm that:

1. Instantiates a map (i.e. key/value pairs) in whatever language you're using. The key will be the integer you find, the value will be the number of times it has been seen so far.
2. Iterate over the array. For the current integer, check whether the number exists as a key in your map. If it exists, increment the map's value. If it doesn't exist, insert a new element with a count of 1.
3. After the iteration is complete, iterate over your map. If any elements have counts of greater than `n/3`, print it out. Handle the case where none are found, etc.
• But doesn't this require O(n^2) time ?? – anna Jan 26 at 4:16
• Not at all. The iteration over the array on happens once, so that’s O(n). The iteration of the map happens once. Since the map has at most n elements (if the array contained all unique elements), the time is again O(n). Since 2*O(n) is just O(n), the time complexity is O(n). The map takes O(n) space. Since that’s the only thing using memory in your code, it’s also O(n) space. – entpnerd Jan 26 at 4:25
• but here is the problem : each integer could be very big , so the map would take a lot of space (the integers range is not from 1 to n ) – anna Jan 26 at 13:15
• so if i went to an integer in the array , i want to check if it exists in the map , and lets say this integer does exists in the map , how would i find it in O(1) ? – anna Jan 26 at 13:17
• Maps aren't usually sorted by default. They're hashed (i.e. a hash map). For example, suppose I hash my numbers and choose the hashing function ` hash(n) = n mod k`, where `k` is the number of buckets. Now I still take roughly linear space, even for big integers. – entpnerd Jan 26 at 22:09