# How to get it working in O(n)? [duplicate]

I came across an interview task/question that really got me thinking ... so here it goes:

You have an array A[N] of N numbers. You have to compose an array Output[N] such that Output[i] will be equal to multiplication of all the elements of A[N] except A[i]. For example Output[0] will be multiplication of A[1] to A[N-1] and Output[1] will be multiplication of A[0] and from A[2] to A[N-1]. Solve it without division operator and in O(n).

I really tried to come up with a solution but I always end up with a complexity of O(n^2). Perhaps the is anyone smarter than me who can tell me an algorithm that works in O(n) or at least give me a hint...

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## marked as duplicate by KennyTM, Matthew Flaschen, Paul R, Pavel Shved, GuffaMay 26 '10 at 8:08

I would refuse to answer this kind of interview questions, frankly. It was just ok until I read "without division operator". –  Daniel Daranas May 26 '10 at 7:52
@daniel: they didn't exclude `pow(n, -1)` and that question so richly deserves an answer using it... –  msw May 26 '10 at 8:00
@KennyTM, isn't it a company with a job ad on Stack Overflow which uses this interview question? :-) –  Pavel Shved May 26 '10 at 8:02

Construct two temporary arrays - B[N] and C[N]. Form each element of B[N] as the product of the A[N] elements to its left (including itself) - working left to right, N operations. Form each element of C[N] as the product of the A[N] elements to its right (including itself) - working right to left, N operations.

Then A[n] = B[n-1] * C[n+1] - another N operations to work this out. You end up with just short of 3N operations, which is O(N). It's just short, because B[0] and C[N-1], and the first and last A, don't require multiplication. Also, C[0] = B[N-1], so I think you should need exactly 3N-5 operations.

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What is the logic behind this idea? I implemented it and it works fine , but any logic behind? –  Barry Dec 12 '11 at 15:25
Barry, take sequence "1 2 3 4" for example, draw matrix 4x4 and fill those values in each row with center diagonal leaving empty. You will see logic behind this idea. –  Dalius Sep 5 '13 at 11:21

You generate two intermediate arrays, `L`, where `L[i] = products of A[0]..A[i-1]`, and `U` where `U[i] = products of A[i+1]..A[N-1]`. These can both be generated in O(n). Your output value `B[i]` will just be `L[i] * U[i]` - again this is O(n).

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Cheating I know but:-

``````for (x = 0 ; x < n ; x++) {
bigtot = bigtot * in[x];
}
for (x = 0 ; x < n ; x++) {
out[n] = bigot;
for ( y = in[x]; y > 0 ; y--) {
out[n] = out[n] - in[x]
}
}
``````
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That doesn't look like O(N) to me ? –  Paul R May 26 '10 at 8:02
Not realy the second loop is dependent on the individual value of a particular table entry -- so its bad for each entry, but adding another entry just affects the new entry so it is O(N) even though each n is pretty awful –  James Anderson May 27 '10 at 2:10