Why does evaluating polynomials with n points using the Fast Fourier Transform take O(n log n) time? I am specifically talking about implementing a divide and conquer algorithm that divides the polynomial A(x) into its even powers and odd powers and then uses recursion.
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Let T(n) be time used by the FFT algorithm to evaluate a polynomial of degree n at n points. The algorithm splits A(x)=xB(x^2)+C(x^2), i.e. into two polynomials: odd and even coefficients. For example: 3x^3 + 2x^2 + 9x + 7 is split into x(3x^2 + 9) + (2x^2 + 7). Originally you wanted to compute 3x^3 + 2x^2 + 9x + 7 at points a,b,c,d. Now you want to compute 3x+9 and 2x+7 at points a^{2}, b^{2}, c^{2}, d^{2}. Later you will combine that to get values of 3x^3 + 2x^2 + 2x + 7 at a,b,c,d. The crucial idea: since you use roots of unity, half of the values in a^{2}, b^{2}, c^{2}, d^{2} are the same. Suppose that a^{2}=c^{2} and b^{2}=d^{2}. So you need to compute 3x+2 and 2x+7 at points a^{2}, b^{2}. This means you reduced an instance of size N into two instances of size N/2 and O(N) postprocessing. FFT repeats this process recursively. This is the same recursion equation as for mergesort, which is O(N log N) complexity. 

