# Memoization in limited space

While trying to increase the speed for my answer for this contest, I have a function which takes two values n and k and produces an output. The calculations are repeated, so I'm memoizing it. I can't use a 2D array, since the constraints for n and k are 10^5! So I'm using a map:

std::map<std::pair<int,int>,double> m;

double solve(int n, int k)
{
if(k==0) return n;
if(k==1) return (n-1)/2.0;

std::pair<int,int> p = std::make_pair(n,k);
std::map<std::pair<int,int>,double>::iterator it;

if( (it=m.find(p)) != m.end())
return it->second;

double ans = 0;
for(int i=1 ; i<=n-1 ; i++)
ans += solve(i,k-1);
ans = ans/n;
m[p] = ans;

return ans;
}

But apparently, this approach is way too slow. Is there some problem with my memoization? Or can I get constant time fetches like an array instead of logarithmic fetches from a map?

This function solves this recurrence:

f(x,0) = x and f(x,1) = (x-1)/2

Can this be solved in a better way? Thanks a lot in advance.

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"Apparently"?.. –  Oli Charlesworth Mar 6 '13 at 19:26
unordered_map would help, but you are doing at least twice more lookups than necessary. –  Slava Mar 6 '13 at 19:34
I think for this code you'd get a lot more out of analyzing the logic than merely caching the results. A brief glance makes me think you should be able to calculate this in O(1) instead of the O(n*k) you have here. –  Mooing Duck Mar 6 '13 at 19:38
Given that if (k<n-1) then the result is zero, there's some serious optimization that can be done for those cases. Also, map takes more space than a 2d array for the same data range unless it's sparse, but a quick analysis shows your data won't be sparse. So either (A) use a 2d array, or (B) only cache sparcely. –  Mooing Duck Mar 6 '13 at 19:53
@Bruce The recurrence and the code differ. Does i start at 0 or at 1? And what about y < 2? Can I assume this is defined as it is implemented in code? –  SebastianK Mar 6 '13 at 19:59

You don't have to store a two-dimensional array of values. Instead of memoization, turn the problem around and use dynamic programming instead.

To save some time, note that f(x, y) = 0 if x <= y.

Calculate the values of f(i, 0) for 1 <= i <= x - k and store them into a one-dimensional array. Then calculate f(i, 1) for 2 <= i <= x - k + 1, f(i, 2) for 3 <= i <= x - k + 2, and so on, until you get f(i, k - 1) for k <= i <= x - 1. Then you can calculate f(x, k). At each step, you only need two arrays of length x - k.

Calculating f(i, j) takes i - j - 1 additions and a division. so the total time is ϴ((x - k)2 k). But it's faster if you compute the sums first and then divide, because each sum is just one element more than the previous, so then the total time is ϴ((x - k) k).

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I think this is a lot more additions than you claim, in fact, I think it's i*k additions and divisions. –  Mooing Duck Mar 7 '13 at 22:40