Using the identities...

       x^0 = 1
    x^(2n) = (x*x)^n
  x^(2n+1) = x * (x*x)^n

...we can write a Haskell function that calculates the kth power of x with fewer than k multiplications.

nat_pow :: Double -> Integer -> Double
nat_pow x 0 = 1
nat_pow x k
  | m==0 = nat_pow (x*x) n            -- k == 2*n  <=>  m == 0
  | otherwise = x * nat_pow (x*x) n   -- k == 2*n+1
    (n,m) = k `divMod` 2              -- n <- k `div` 2; m <- k `mod` 2

For example:

nat_pow x 6
= nat_pow x^2 3
= x^2 * natpow (x^2)^2 1
= x^2 * (x^2)^2  *  natpow ((x^2)^2)^2) 0
= x^2 * (x^2)^2  *         1

Further, we can look at the cross sum of a number w.r.t base 2.

crossSum_2 42 = 3                     (because (42)_10 = (101010)_2)

Question: What is the link between the number of multiplications nat_pow x k requires and crossSum_2 k?

What I have so far:

Let Q(k) be the binary cross sum of k; M(k) the number of multiplications of nat_pow n k. Then I can see that

M(2k)   = 1 + M(k)
M(2k+1) = 1 + M(2k)

Q(2k)   =     Q(k)
Q(2k+1) = 1 + Q(k)

So one could say that

  1. Q(n) is the number of "odd" cases of nat_pow; hence
  2. M(n) >= Q(n) always holds.

However, I think there must be more to it.

  • Isn't the cruss sum of 42, 3? – Willem Van Onsem May 17 at 15:09
  • Furthermore I actually think this belongs more to Mathematics or another SX network. – Willem Van Onsem May 17 at 15:11
  • Hint: what is the relation between the number of ones in a binary representation and the recursions of the last type in your first code fragment? – Willem Van Onsem May 17 at 15:14
  • @WillemVanOnsem thats right, fixed it. – ngmir May 17 at 15:20
  • @WillemVanOnsem thanks for reading, regarding your hint: I see that, just forgot to add it to the post. Anything else you could say about it? – ngmir May 17 at 15:21
up vote 3 down vote accepted
M(2k)   = 1 + M(k)
M(2k+1) = 1 + M(2k)

Q(2k)   =     Q(k)
Q(2k+1) = 1 + Q(k)

In fact, we can make the parallel between the two definitions even closer. In M(2k+1) = 1 + M(2k), we can unroll the equation we have for M(2k):

M(2k)   =     1 + M(k)
M(2k+1) = 1 + 1 + M(k)

Q(2k)   =     Q(k)
Q(2k+1) = 1 + Q(k)

Now it is clear that, compared to Q, M adds one more on each "recursive call". So M(k) will be Q(k) plus the total number of recursive calls M makes -- which in this case is also the total number of bits in k. (There is just one wrinkle: we haven't written about the base cases for Q and M above. Once we factor that in, does that change the answer? What would the base cases have to look like in a counterfactual world to give the other answer to "does that change the answer?"?)

  • That is nice, since you can express "number of bits" mathematically in terms of "log_2". It doesn't bother me that it does not hold generally, including base cases -- after all, the recursive definition has explicit base cases so theres bound to be different structure there. – ngmir May 17 at 19:38
  • cf this article: Number of bits in a decimal integer – ngmir May 18 at 7:35

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