Find the Element Occurring b times in an an array of size n*k+b

Question

Description

Given an Array of size (n*k+b) where n elements occur k times and one element occurs b times, in other words there are n+1 distinct Elements. Given that 0 < b < k find the element occurring b times.

My Attempted solutions

1. Obvious solution will be using hashing but it will not work if the numbers are very large. Complexity is O(n)

2. Using map to store the frequencies of each element and then traversing map to find the element occurring b times.As Map's are implemented as height balanced trees Complexity will be O(nlogn).

Both of my solution were accepted but the interviewer wanted a linear solution without using hashing and hint he gave was make the height of tree constant in tree in which you are storing frequencies, but I am not able to figure out the correct solution yet.

I want to know how to solve this problem in linear time without hashing?

EDIT:

Sample:

Input: n=2 b=2 k=3

Aarray: 2 2 2 3 3 3 1 1

Output: 1

Answer 1

An idea using cyclic groups.

To guess i-th bit of answer, follow this procedure:

1. Count how many numbers in array has i-th bit set, store as cnt
2. If cnt % k is non-zero, then i-th bit of answer is set. Otherwise it is clear.

To guess whole number, repeat the above for every bit.

This solution is technically O((n*k+b)*log max N), where max N is maximal value in the table, but because number of bits is usually constant, this solution is linear in array size.

No hashing, memory usage is O(log k * log max N).

Example implementation:

from random import randint, shuffle

def generate_test_data(n, k, b):
    k_rep = [randint(0, 1000) for i in xrange(n)]
    b_rep = [randint(0, 1000)]
    numbers = k_rep*k + b_rep*b
    shuffle(numbers)
    print "k_rep: ", k_rep
    print "b_rep: ", b_rep
    return numbers

def solve(data, k):
    cnts = [0]*10
    for number in data:
        bits = [number >> b & 1 for b in xrange(10)]
        cnts = [cnts[i] + bits[i] for i in xrange(10)]
    return reduce(lambda a,b:2*a+(b%k>0), reversed(cnts), 0)

print "Answer: ", solve(generate_test_data(10, 15, 13), 3)

Answer 2

I assume:

1. The elements of the array are comparable.
2. We know the values of n and k beforehand.
3. A solution O(n*k+b) is good enough.

Let the number occuring only b times be S. We are trying to find the S in an array of n*k+b size.

Recursive Step: Find the median element of the current array slice as in Quick Sort in lineer time. Let the median element be M.

After the recursive step you have an array where all elements smaller than M occur on the left of the first occurence of M. All M elements are next to each other and all element larger than M are on the right of all occurences of M.

Look at the index of the leftmost M and calculate whether S<M or S>=M. Recurse either on the left slice or the right slice.

So you are doing a quick sort but delving only one part of the divisions at any time. You will recurse O(logN) times but each time with 1/2, 1/4, 1/8, .. sizes of the original array, so the total time will still be O(n).

Clarification: Let's say n=20 and k = 10. Then, there are 21 distinct elements in the array, 20 of which occur 10 times and the last occur let's say 7 times. I find the medium element, let's say it is 1111. If the S<1111 than the index of the leftmost occurence of 1111 will be less than 11*10. If S>=1111 then the index will be equal to 11*10.

Full example: n = 4. k = 3. Array = {1,2,3,4,5,1,2,3,4,5,1,2,3,5} After the first recursive step I find the median element is 3 and the array is something like: {1,2,1,2,1,2,3,3,3,5,4,5,5,4} There are 6 elements on the left of 3. 6 is a multiple of k=3. So each element must be occuring 3 times there. So S>=3. Recurse on the right side. And so on.

Answer 3

In order to have a constant height B-tree containing n distinct elements, with height h constant, you need z=n^(1/h) children per nodes: h=log_z(n), thus h=log(n)/log(z), thus log(z)=log(n)/h, thus z=e^(log(n)/h), thus z=n^(1/h).

Example, with n=1000000, h=10, z=3.98, that is z=4.

The time to reach a node in that case is O(h.log(z)). Assuming h and z to be "constant" (since N=n.k, then log(z)=log(n^(1/h))=log(N/k^(1/h))=ct by properly choosing h based on k, you can then say that O(h.log(z))=O(1)... This is a bit far-fetched, but maybe that was the kind of thing the interviewer wanted to hear?

Answer 4

UPDATE: this one use hashing, so it's not a good answer :(

in python this would be linear time (set will remove the duplicates):

result = (sum(set(arr))*k - sum(arr)) / (k - b)

Answer 5

If 'k' is even and 'b' is odd, then XOR will do. :)