Your question is already answered in the article to which you referred: "Karatsuba's basic step works for any base B and any m, but the recursive algorithm is most efficient when m is equal to n/2, rounded up" ... `n`

being the number of digits, and 0 <= value_of_digit < B.

Some perspective that might help:

You are allowed (and required!) to use **elementary** operations like `number_of_digits // 2`

and `divmod(digit_x * digit_x, B)`

... in school arithmetic, where B is 10, you are required (for example) to know that `divmod(9 * 8, 10)`

produces `(7, 2)`

.

When implementing large number arithmetic on a computer, it is usual to make B the largest power of 2 that will support the elementary multiplication operation conveniently. For example in the CPython implementation on a 32-bit machine, B is chosen to to be 2 ** 15 (i.e. 32768), because then `product = digit_x * digit_y; hi = product >> 15; lo = product & 0x7FFF;`

works without overflow and without concern about a sign bit.

I'm not sure what you are trying to achieve with an implementation in Python that uses B == 2, with numbers represented by Python ints, whose implementation in C already uses the Karatsuba algorithm for multiplying numbers that are large enough to make it worthwhile. It can't be speed.

As a learning exercise, you might like to try representing a number as a list of digits, with the base B being an input parameter.