# Checking whether a number is prime when encoded in unary/binary

The following algorithm checks whether a number is prime:

``````Given a number n,loop over all numbers smaller than n and check whether they divide n.
``````

Now, I have to analyse the number of division operations performed by the algorithm as a function of the length of its input in the following two cases:

1) The number is encoded in unary (i.e, 4 is 1111). How do I show that the number of divisions is polynomial?

2) The number is encoded in binary (i.e, 4 is 100). How do I show that the number of divisions is exponential?

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Suppose we have `n` `1`'s strung together (notated `1^n`). `n` is the length of our input, obviously. We will divide all the integers from `11`, `111`, ... ,`1^(n-1)` into `1^n`. How many numbers will you be dividing into `1^n`, as a function of `n`? Is this a polynomial?

Note that it takes `log_2(x)` (log base 2 of `x`) bits to represent `x`, approximately, in binary. Also note that we will be performing `x-2` divisions (`2`, `3`, `4`, `5`, ... , `x-1` will be divided into `x`). So, for `log_2(x)` bits we use `x-2` divisions. Suppose, instead, that we let `n` be the size of our input. So we have `n = log_2(x)`. How many divisions will we take, then, in terms of a function of `n`?

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For the first one, we're dividing n-2 numbers, which is a polynomial. For the binary situation, isn't it still n-2? – Sorin Cioban Apr 24 '12 at 22:51
@SorinCioban in binary the number of digits is our problem size. `n` digits encode `2^n` magnitude value. – Will Ness Apr 25 '12 at 12:45
@SorinCioban What is your definition of `n` in the binary situation: the number of bits of the input or the magnitude of the number? – Words Like Jared Apr 25 '12 at 20:02
Yes, but we don't divide n to all the 2^n numbers, do we? We only divide them to the numbers that are smaller than n in both cases. – Sorin Cioban Apr 26 '12 at 13:07
You didn't answer my question. Suppose `x` is the magnitude. It takes `log_2(x)` bits to represent `x` in base 2. Let `f(x)` be the number of divisions we have to do to `x`. `f(x) = x-2` divisions, namely, `2`, `3`, `...` , `x-1`. However our input is `log_2(x)` bits, which we will say is `n`. So if `f(x) = x-2`, and `n = log_2(x)`, then `x = 2^n`. You should be able to figure out `f(n)`, now, which will represent the number of divisions you need to do on an input of size `n` bits. – Words Like Jared Apr 26 '12 at 13:43

Hint:

Define the problem size `n` as being the number of digits in the (binary|unary) representation of the number.

Now consider how many different numbers you can encode in `n` digits.

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For the given example...4 in unary = 1111; in 4 digits we can only encode one number; in binary, in 4 digits we can encode 15 numbers. But we won't be dividing by the ones that are higher than our current one, so isn't the number of divisions = givenNumber-2 either way? – Sorin Cioban Apr 24 '12 at 22:53