# Optimizing a recursive function

I'm creating a program that returns the least quantity of sums required to get to a number (n) using only 1, 2, 6 and 13. It works perfectly for small values of n, but once n gets to values like 200 it takes the program too much time to calculate the result.

Therefore, I have two questions:

1. Is there any way to make the recursion faster?

2. Should I avoid using recursion and use a loop instead?

Here's the commented code:

``````#include <iostream>
#define MAX 500000

using namespace std;

void cal(int inp, int &mini, int counter = 0);

int main (void)
{
//Gets input
int n;
cin >> n;

//Defines mini as the MAX result we can get
int mini = MAX;

//Calls the function
cal(n, mini);

//Prints the best result
cout << mini << endl;

return 0;
}

void cal(int inp, int &mini, int counter)
{
//Breaks recursion if it finds an answer
if(!inp)
{
if(counter<mini) mini = counter;
return;
}

//Breaks recursion if the input is negative
//or the counter is more than the best result
else if((inp<0) || (counter>mini)) return;

//Counts amount of recursions
counter++;

//Tries every combination
cal(inp-13, mini, counter);
cal(inp-6, mini, counter);
cal(inp-2, mini, counter);
cal(inp-1, mini, counter);

return;
}
``````

Thank you

• Loop will almost always be faster then recursion. Commented Jan 9, 2016 at 16:32
• Performance issue is not because of recursion. It is because of your brute force algorithm. Commented Jan 9, 2016 at 16:34
• You need an asymptotically better algorithm, not micro-optimisations. Commented Jan 9, 2016 at 16:36
• Don't use recursion. Minimize the number of function calls / branches. Most processors can process data and move instructions faster than branch instructions. A branch may cause the processor to empty its instruction pipeline and reload or go through a branch prediction algorithm. In either case, this is time the processor could be using for other purposes. So, minimize the recursive calls. Commented Jan 9, 2016 at 17:16

The problem is your brute force. Let me suggest something better:

Preliminaries: If you have two 1s, it is always better to use a 2. If you have three 2s, it is better to use a 6. If you have thirteen 6s, it is better to use six thirteens.

So the any admissable sum will always look like `n = 13m+k` where `k` is written as a sum of 1, 2, and 6. With the preliminaries, we know that for the optimal sum `k` will never exceed `1+2*2+12*6 = 77`. (The reverse doesn't hold. Not any number below 78 is best written without 13s of course.) So brute forcing those is good enough. You can then use a lookup table.

This could still be optimized further, but it should not break down at 200.

Assuming you have found your first 77 entries (which can be optimized as well) you can do this (still unoptimized ;-):

``````int num_13 = ((n-78) / 13) + 1;
int sum_length = MAX;
for (i = num_13; i*13 < n; i++) {
int tmp = entries_77[n-i*13]+i;
if (tmp < sum_length) {
num_13 = i;
sum_length = tmp;
}
}
``````

I would be even quicker to compile an array for the equivalence classes modulo 13, since for any given equivalence class any number exceeding 78 will have the same `k`.

You can use DP (Dynamic Programming) approach to solve your problem. It's well known Coins Problem

• Brilliant answer, definitely the most elegant one. Thank you! Commented Jan 9, 2016 at 18:51
• @Just_a_newbie happy if it was helpful )) Commented Jan 9, 2016 at 18:52

Your recursion needs a memoization to avoid repetitive calculation. And no need for the second and third parameter of the recursion. I have updated and put explanation on your code. Let me know if you have any confusion.

``````#include <iostream>
#include <string.h>
#define INF 999999

using namespace std;

int cal(int inp);
int mem[502];
int main (void)
{
//Gets input
int n;
cin >> n;

//initialzing the array for using with memoization
memset(mem,-1,sizeof(mem));

//Calls the function
//Prints the best result
cout << cal(n) << endl;

return 0;
}

//returns the minimum quantity of sum operations to get inp.
int cal(int inp)
{
//Breaks recursion if it finds an answer.
//Return cost 0. As in this stage no processing was done.
if(!inp)
return 0;

// Returning infinite cost for invalid case.
if(inp < 0)
return INF;

int _ret = mem[inp];

// If already visited here before then no need to calcuate again.
// Just return previous calculation. This is called memoisation.
// If not visited then _ret would have equal to -1.
if(_ret >=0 )
return _ret;

_ret = INF;

//Tries every combination and takes the minimum cost.
_ret = min(_ret, cal(inp-13)+1);
_ret = min(_ret,cal(inp-6)+1);
_ret = min(_ret,cal(inp-2)+1);
_ret = min(_ret,cal(inp-1)+1);

// Updating the value so that can be used for memoization.
mem[inp] = _ret;

return _ret;
}
``````

This will also work for larger numbers. Complexity is 4*n.

• Thanks, this gives me another solution to the problem. Definitely a method that I will apply from time to time. Commented Jan 9, 2016 at 18:53