Karatsuba's algorithm only requires O(n) space.

```
(A0 2^n + B0)(A1 2^n + B1)
= A0 A1 2^(2n) + B0 B1 + ((A0+B0)(A1+B1) - A0 A1 - B0 B1)2^n
```

Here is a rough inductive argument. Inductively, suppose multiplying n-digit numbers using Karatsuba's algorithm takes only cn space. To multiply 2n-digit numbers, we can multiply A0 A1 in cn space, then **save the answer in 2n space**, then multiply B0 B1 in cn space, then save the answer in 2n space, then multiply (A0+B0)(A1+B1) in cn space. At this point we are using at most (c+4)n space. Then we perform the subtractions and record the answer in 4n space. The peak space usage was (c+4)n which is less than max(c,4)(2n) space. So, as long as c>4, if it takes cn space to multiply n digit numbers, then it takes c(2n) space to multiply 2n digit numbers. This was imprecise because (A0+B0) and (A1+B1) may have n+1 digits instead of n. So, a rigorous inductive argument is more messy, but it can be done following the same basic pattern.

The premise of the question is wrong. Karatsuba multiplication only requires O(n) space, not Omega(n log n). It is possible that some implementations would require more space not necessarily limited to O(n log n), such as if you do the calculations in parallel.

In fact, it is possible to do Karatsuba multiplication in O(log n) extra bits beyond the answer.

`O(n log(n))`

memory? On each level of recursion problem size decreases by a factor, so it should sum to linear at any point.`n + n/a + n/a^2 + ... + n/a^i = O(n)`

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