# Explanation and time/space complexity of tri tiling

I am having problems understanding what exactly is going on in the solve function below. I see what it does, however it still is unclear to me - I cannot visualize it, or just get myself to understand it. Can someone explain it?

In how many ways can you tile a 3xn rectangle with 2x1 dominoes?

Here is a sample tiling of a 3x12 rectangle.

Code (taken from here):

``````#include <stdio.h>
int dp[32];
int solve(int n)
{
if(dp[n]!=-1)
return dp[n];
else
{
int i;
int res = 3*solve(n-2);
for(i=4;i<=n;i+=2)
res+=2*solve(n-i);
return dp[n]=res;
}
}
int main()
{
int i;
for(i=0;i<32;i+=2)
dp[i]=-1;
for(i=1;i<32;i+=2)
dp[i]=0;
dp[0]=1;
scanf("%d",&i);
while(i!=-1)
{
printf("%d\n",solve(i));
scanf("%d",&i);
}
return 0;
}
``````

Another thing is, what could be the time and space complexity of this algorithm? Since it is a recursive function, it might be `O(log N)`, but I am not sure about that either.

-

Technically speaking, the runtime is O(1) because there is an upper bound on the size of the input (specifically, 32). But let's assume for a minute that the problem size isn't at most 32 and think about that problem. In that case, the runtime is O(n2). After a recursive call of some size has been made, any future recursive calls of the same size run in time O(1). This is due to the use of memoization in the `dp` table. This means that we can compute the total runtime by summing up, across all possible recursive calls that could be made, the amount of time required to fill in the `dp` table.