I know there is something wrong with the following reasoning but I'm not sure what it is.

The FFT:

given two polynomials

`A = a_0 + a_1 x + a_2 x^2 + ... + a_n x^n`

and

`B = b_0 + b_1 x + b_2 x^2 + ... + b_n x^n`

you can compute the coefficients of the product

`AB = \sum _k = 0 ^ 2n ( \sum _ j = 0 ^ k (a_j b_{k-j}))x^k`

in

`O(n log n )`

time.So given two vectors

`(a_0, ..., a_n)`

and`(b_0, ..., b_n)`

we can calculate the vector`v_i = \sum j = 0 ^ k ( a_j b_{k-j})`

in`O(n log n)`

time (by embedding the vectors in zeros.)Given the above, we should be able to calculate the dot product of

`A =(a_0, ..., a_n)`

and`B =(b_0, ..., b_n)`

which is`A.B = \sum_j=0 ^ n a_j b_j`

in`O(n log n)`

time by preprocessing one of the vectors say`B`

to be`B' = (b_n, b_{n-1}, ..., b_1, b_0)`

then computing the convolution as in 2. in`O(n log n)`

time.

If the above reasoning is correct, then that means we can implement Matrix Multiplication of two `nxn`

matrices in `O(n^2 log n )`

time by computing the dot product in `O(n log n)`

time `O(n)`

times.

However, the best run-time for matrix multiplication we know is about `O(n^2.4)`

so this seems unlikely to be true, which probably means of of the steps 1,2, or 3 is incorrect.