The difference operator, (similar to the derivative operator), and the sum operator, (similar to the integration operator), can be used to change an algorithm because they are inverses.

```
Sum of (difference of y) = y
Difference of (sum of y) = y
```

An example of using them that way in a c program is below.

This c program demonstrates three approaches to making an array of squares.

- The first approach is the simple obvious approach,
`y = x*x`

. - The second approach uses the equation
`(difference in y) = (x0 + x1)*(difference in x)`

. - The third approach is the reverse and uses the equation
`(sum of y) = x(x+1)(2x+1)/6`

.

The second approach is consistently slightly faster then the first one, even though I haven't bothered optimizing it. I imagine that if I tried harder I could make it even better.

The third approach is consistently twice as slow, but this doesn't mean the basic idea is dumb. I could imagine that for some function other than `y = x*x`

this approach might be faster. Also there is an integer overflow issue.

Trying out all these transformations was very interesting, so now I want to know what are some other pairs of mathematical operators I could use to transform the algorithm?

Here is the code:

```
#include <stdio.h>
#include <time.h>
#define tries 201
#define loops 100000
void printAllIn(unsigned int array[tries]){
unsigned int index;
for (index = 0; index < tries; ++index)
printf("%u\n", array[index]);
}
int main (int argc, const char * argv[]) {
/*
Goal, Calculate an array of squares from 0 20 as fast as possible
*/
long unsigned int obvious[tries];
long unsigned int sum_of_differences[tries];
long unsigned int difference_of_sums[tries];
clock_t time_of_obvious1;
clock_t time_of_obvious0;
clock_t time_of_sum_of_differences1;
clock_t time_of_sum_of_differences0;
clock_t time_of_difference_of_sums1;
clock_t time_of_difference_of_sums0;
long unsigned int j;
long unsigned int index;
long unsigned int sum1;
long unsigned int sum0;
long signed int signed_index;
time_of_obvious0 = clock();
for (j = 0; j < loops; ++j)
for (index = 0; index < tries; ++index)
obvious[index] = index*index;
time_of_obvious1 = clock();
time_of_sum_of_differences0 = clock();
for (j = 0; j < loops; ++j)
for (index = 1, sum_of_differences[0] = 0; index < tries; ++index)
sum_of_differences[index] = sum_of_differences[index-1] + 2 * index - 1;
time_of_sum_of_differences1 = clock();
time_of_difference_of_sums0 = clock();
for (j = 0; j < loops; ++j)
for (signed_index = 0, sum0 = 0; signed_index < tries; ++signed_index) {
sum1 = signed_index*(signed_index+1)*(2*signed_index+1);
difference_of_sums[signed_index] = (sum1 - sum0)/6;
sum0 = sum1;
}
time_of_difference_of_sums1 = clock();
// printAllIn(obvious);
printf(
"The obvious approach y = x*x took, %f seconds\n",
((double)(time_of_obvious1 - time_of_obvious0))/CLOCKS_PER_SEC
);
// printAllIn(sum_of_differences);
printf(
"The sum of differences approach y1 = y0 + 2x - 1 took, %f seconds\n",
((double)(time_of_sum_of_differences1 - time_of_sum_of_differences0))/CLOCKS_PER_SEC
);
// printAllIn(difference_of_sums);
printf(
"The difference of sums approach y = sum1 - sum0, sum = (x - 1)x(2(x - 1) + 1)/6 took, %f seconds\n",
(double)(time_of_difference_of_sums1 - time_of_difference_of_sums0)/CLOCKS_PER_SEC
);
return 0;
}
```