f(x) = 5x^2 + 4xlogx + 2 is
O(g(x) + k(x)) = max(O(g(x), k(x))
// and O(X^2) > O(xlogx)
//additionally coeffs are disregarded
O(c*g(x)) = O(g(x))
So if you have a sum you just select the largest complexity as at the end of the day, when n goes to infinity the largest component will give the most computational load. It also doesn't matter if you have any coeffs because you try to roughly estimate what's going to happen.
For your other sample see reasoning below
for (int i = 0; i < block.length; i++)
for (int j = 0; j < block.length; j++)
for (int k = 0; k < 5; k++)
g(); //assume worst case time performance of g() is O(1)
First convert loops into sums and work out the sums from right to left
Counter of O(1) from 1 to 5 is still O(1), remember you disregard coeffs
Sum(k=0, k=5) 1 = O(5k) = O(1)
So you end up with the middle sum, which counts a function of O(1) n times, this gives the complexity of O(n)
Sum(j=0, n) 1 = O(n)
Finally you get to the leftmost sum and notice that you count n n-times, i.e.
n+n+n..., which is equal to
Sum (i=0,n) n = O(n^2)
So the final answer is O(n^2).