Here is how you can calculate the value.

You compute the value iterratively for each number of digits in the binary representation of the upper limit. For each number of digits compute separately the sum of the degrees 1 to 4 of the numbers with even number of ones and of the numbers with odd number of ones in their binary representation. Having these values you should be able to compute the values for n+1 where n is the number of the digits in the binary representation.

Here are some observations on how to do that: If you have the sum of the k-th degrees of numbers with even number of ones, then multiply this by 2^k and you will get the sum of these numbers doubled. These numbers still will have even number of ones. In fact each number with n digits that has even number of ones is either doubled number with n-1 digits that has even number of ones, or is x * 2 + 1 where x is a number with odd number of ones and has n -1 digits. So the sum of the k-th degrees of the numbers that have even number of ones in their binary representation and have n digits is `Se(n,k) = 2^k * Se(n-1, k) + Sum(a : number with odd number of ones and n-1 digits){(2*a + 1)^k}`

. Here I use Se to denote the sum of the numbers with even number of ones. Now the interesting part is the second summand. It can be calculated using the binomial formula:

(2*a + 1)^k = 2^k*a*k + combination(1,k)*(2*a)^(k-1) + ... 1 And so after regrouping you have:
`Sum(a : number with odd number of ones and n digits){(2*a + 1)^k} = 2^k*So(n-1,k) + combination(1, k) * 2^(k-1)*So(n-1,k) + combination(2, k) * 2^(k-2)*So(n-1,k) + ...`

Now if you assume you have the So(sum of numbers with odd number of ones in their binary representation) calculated for n-1 you can also calculate this sum.

You have to write similar formula for So(n,k):

So(n,k) = 2^k*(So(n-1, k)) + Sum(a : number with EVEN number of ones and n-1 digits){(2*a + 1)^k

Keep in mind you have to compute this values for k = 1, ... 4 so that you can use them for the next iteration. Only one note - for So(n, 1) you have So(n, 1) = So(n-1,1)*2 + Se(n-1,1)*2 + 1, similarly Se(n, 1) = Se(n-1, 1) * 2 + So(n-1, 1).

Using these formulas you should be able to compute the value you need quite fast. You need to sum Se(1,4) + Se(2,4) + ... Se(64, 4). The algorithm will work for values quite higher then the given constraints. Please note that the value you are searching for will not fit in any "regular" integer type. You will need to use some kind of BigInteger implementation.

Hope this answers your question.