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i have following problem from book introduction algorithm second edition by MIT university

problem is following

An array A[1 . . n] contains all the integers from 0 to n except one. It would be easy to determine the missing integer in O(n) time by using an auxiliary array B[0 . . n] to record which numbers appear in A. In this problem, however, we cannot access an entire integer in A with a single operation. The elements of A are represented in binary, and the only operation we can use to access them is “fetch the j th bit of A[i],” which takes constant time.

Show that if we use only this operation, we can still determine the missing integer in O(n) time

please help

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2 Answers 2

up vote 6 down vote accepted

Call your missing number M.

You can split your array into two parts depending on whether the least significant bit of A[i] is a 1 or a 0. The smaller of the two parts (call it P_1) is at most (n-1)/2 elements in size, and it tells you whether M's least significant bit is a 1 or a 0.

Now consider the 2nd bit for the elements of P_1. Again, this part can be split in two, and the smaller of the two parts (P_2) tells you whether this bit should be a 1 or a 0.

Carry on going (P_3, P_4, ...) until you've worked out what all the bits are.

You can prove that this is O(n) because you are essentially looking at n + n/2 + n/4 + ... different individual bits in your array, and this sum is less than 2n.

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And you can do the split array part in-place, using the Dutch National Flag algorithm. –  Aryabhatta May 31 '10 at 21:57
Great solution. But now I realize that it only works fine when n is a power of 2. What about other numbers? –  Eyal Schneider Jun 3 '10 at 21:01

Here is a Python implementation:

def bit_at(n, bit):
    return (n>>bit) & 1

def find_missing(a, bits):

    indexes = range(len(a))
    missing = 0

    for bit in range(bits):

        ones = [i for i in indexes if bit_at(a[i], bit)==1]
        zeroes = [i for i in indexes if bit_at(a[i], bit)==0]

        if len(ones) <= len(zeroes):
            indexes = ones
            missing |= (1<<bit) 
            indexes = zeroes

    return missing

print find_missing([7,2,6,4,1,5,0], 3)
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