# Find two missing numbers

have a machine with O(1) memory. we want to pass n number (one by one) first time, and again we exclude two numbers and we will pass n-2 of them to machine. write an algorithm that finds missing numbers. This was an interview question and I couldn't solve it.

-
Sorry, I can't remember the numbers either. –  Cody Gray Apr 18 '12 at 22:09
are the numbers supposed to be a series? [1,....,n] and you need to find the missing element? –  amit Apr 18 '12 at 22:12
this is not possible with O(1) memory. –  Karoly Horvath Apr 18 '12 at 22:12
@Shedal Presumably it means "a constant amount of memory". –  sepp2k Apr 18 '12 at 22:14
@jpalecek That's not a duplicate. The OP said (in a comment) that the numbers aren't in a range. –  sepp2k Apr 18 '12 at 22:30

It can be done with O(1) memory.

You only need a few integers to keep track of some running sums. The integers do not require log n bits (where n is the number of input integers), they only require 2b+1 bits, where b is the number of bits in an individual input integer.

When you first read the stream add all the numbers and all of their squares, i.e. for each input number, n, do the following:

``````sum += n
sq_sum += n*n
``````

Then on the second stream do the same thing for two different values, sum2 and sq_sum2. Now do the following maths:

``````sum - sum2 = a + b
sq_sum - sq_sum2 = a^2 + b^2

(a + b)(a + b) = a^2 + b^2 + 2ab
(a + b)(a + b) - (a^2 + b^2) = 2ab
(sum*sum - sq_sum) = 2ab

(a - b)(a - b) = a^2 + b^2 - 2ab
= sq_sum - (sum*sum - sq_sum) = 2sq_sum - sum*sum
sqrt(2sq_sum - sum*sum) = sqrt((a - b)(a - b)) = a - b
((a + b) - (a - b)) / 2 = b
(a + b) - b = a
``````

You need 2b+1 bits in all intermediate results because you are storing products of two input integers, and in one case multiplying one of those values by two.

-
so thanks..this is best answer until now....are you sure this is optimal? –  amin k Apr 19 '12 at 7:04
Assuming the numbers are distinct positive integers [which is a valid input], then the largest number is at least `n`, which requires `logn` bits to represent - thus the answer is still `O(logn)` space, since `b` itself is linear in `logn`. Also: The OP did mention in comments the numbers are not necesseraly from a certain range. I agree it is `O(1)` if we can assume integers are at most 32 bits [or any other constant number...] –  amit Apr 19 '12 at 7:33
p.s. this assumption [constant number of bits] is contradicting the `O(1)` incapability because then the statement "input is not limited" is not true, there are finite number of possible answers if ints have a constant number of bits. Without this assumption, the `O(1)` infeasibility stands. –  amit Apr 19 '12 at 8:13
To say that this problem can't be solved in constant space is to say that we can't hold a single integer from the input in memory at a time, in which case the problem is just being silly. Since we clearly must have this much memory, call it M, it is within the O(1) constraint to require kM memory, and for this solution k is about 10. –  Running Wild Apr 19 '12 at 14:38
@amink, it's not true that x^2 + y^2 = c has a unique answer in integers. For example, if c is 4225, then (x,y) can be any of (16,63), (25, 60), (33,56), (39,52) not counting their permutations. –  Chandranshu Aug 7 at 5:13
show 1 more comment

Assuming the numbers are ranging from 1..N and 2 of them are missing - `x` and `y`, you can do the following:

Use Gauss formula: `sum = N(N+1)/2`

``````sum - actual_sum = x + y
``````

Use product of numbers: `product = 1*2..*N = N!`

``````product - actual_product = x * y
``````

Resolve x,y and you have your missing numbers.

In short - go through the array and sum up each element to get the `actual_sum`, multiply each element to get `actual_product`. Then resolve the two equations for `x` an `y`.

-
sum of N numbers cannot be stored in O(1) memory. –  Karoly Horvath Apr 18 '12 at 22:14
I agree, but I think this is what the interviewer meant to ask - I don't think you can do better. –  BrokenGlass Apr 18 '12 at 22:16
He also indicated [in comments] the numbers are not ranged [1,...,n]. I believe it's a kind of a trick question to show the interviewer you understand architecture limitations. –  amit Apr 18 '12 at 22:18
@Shedal: the sum of n positive integers is at least `n`, which needs `logn` bits to be represented. –  amit Apr 18 '12 at 22:21
@Shedal The same way you apply it to runtime. If, for some constants `c` and `N`, an algorithm consumes at most `c*f(n)` bytes of memory when processing input of size `n` for all `n > N`, the algorithm's memory consumption is in `O(f(n))`. –  sepp2k Apr 18 '12 at 22:22

It cannot be done with `O(1)` memory.

Assume you have a constant `k` bits of memory - then you can have `2^k` possible states for your algorithm.

However - input is not limited, and assume there are `(2^k) + 1` possible answers for `(2^k) + 1` different problem cases, from piegeonhole principle, you will return the same answer twice for 2 problems with different answers, and thus your algorithm is wrong.

-
But if numbers are in integer range may be constant number of 32 bit integers can be assumed in O(1) [I say this by his c++ tag, and seems it's not pute CS question] –  Saeed Amiri Apr 18 '12 at 22:19
@SaeedAmiri: If such an assumption exists - it should be explicit, rather then implicit in these type of questions I think. –  amit Apr 18 '12 at 22:21
I agreed, so I asked, even by such an assumption I couldn't come up to any algorithm :) –  Saeed Amiri Apr 18 '12 at 22:29
Anyway your proof is not true, e.g backtracking algorithm usually are P-SPACE, e.g n space, but their possible states can be 2^2^2^..... –  Saeed Amiri Apr 18 '12 at 22:36
@SaeedAmiri Why is it contradicting? P-Space allows linear, quadric or any polynomial amount of space, let it be `p(n)`, thus you can have `2^p(n)` amount of states. can you give a concrete counter-example where this solution fails? Or can you give an algorithm with 2^2^2^...n states that uses polynomial memory? –  amit Apr 18 '12 at 22:38

The following came to my mind as soon as I finished reading the question. But the answers above suggest that it is not possible with O(1) memory or that there should be a constraint on the range of numbers. Tell me if my understanding of the question is wrong. Ok, so here goes

You have O(1) memory - which means you have constant amount of memory.

When the n numbers are passed to you 1st time, just keep adding them in one variable and keep multiplying them in another. So at the end of 1st pass you have the sum and product of all the numbers in 2 variables S1 and P1. You have used 2 variable till now (+1 if you reading the numbers in memory).

When the (n-2) numbers are passed to you the second time, do the same. Store the sum and product of the (n-2) numbers in 2 other variables S2 and P2. You have used 4 variables till now (+1 if you reading the numbers in memory).

If the two missing numbers are x and y, then

``````x + y = S1 - S2
x*y = P1/P2;
``````

You have two equations in two variables. Solve them.

So you have used a constant amount of memory (independent of n).

-
This is similar to the approach suggested by @BrokenGlass - read the comments there and see why it is not `O(1)` memory. Note that this is not even linear in `n` - since the product of all elements is O(`n!`) [assuming unique elements], and you need `O(log(n!)) = O(nlogn)` to represent it. –  amit Apr 19 '12 at 7:40