Using three self implemented functions `iPow(x, n)`

, `Ln(x)`

and `Exp(x)`

, I'm able to compute `fPow(x, a)`

, x and a being **doubles**. Neither of the functions below use library functions, but just iteration.

Some explanation about functions implemented:

(1) `iPow(x, n)`

: x is `double`

, n is `int`

. This is a simple iteration, as n is an integer.

(2) `Ln(x)`

: This function uses the Taylor Series iteration. The series used in iteration is `Σ (from int i = 0 to n) {(1 / (2 * i + 1)) * ((x - 1) / (x + 1)) ^ (2 * n + 1)}`

. The symbol `^`

denotes the power function `Pow(x, n)`

implemented in the 1st function, which uses simple iteration.

(3) `Exp(x)`

: This function, again, uses the Taylor Series iteration. The series used in iteration is `Σ (from int i = 0 to n) {x^i / i!}`

. Here, the `^`

denotes the power function, but it is **not** computed by calling the 1st `Pow(x, n)`

function; instead it is implemented within the 3rd function, concurrently with the factorial, using `d *= x / i`

. I felt **I had to use this trick**, because in this function, iteration takes some more steps relative to the other functions and the factorial `(i!)`

overflows most of the time. In order to make sure the iteration does not overflow, the power function in this part is iterated concurrently with the factorial. This way, I overcame the overflow.

(4) `fPow(x, a)`

: **x and a are both doubles**. This function does nothing but just call the other three functions implemented above. The main idea in this function depends on some calculus: `fPow(x, a) = Exp(a * Ln(x))`

. And now, I have all the functions `iPow`

, `Ln`

and `Exp`

with iteration already.

**n.b.** I used a `constant MAX_DELTA_DOUBLE`

in order to decide in which step to stop the iteration. I've set it to `1.0E-15`

, which seems reasonable for doubles. So, the iteration stops if `(delta < MAX_DELTA_DOUBLE)`

If you need some more precision, you can use `long double`

and decrease the constant value for `MAX_DELTA_DOUBLE`

, to `1.0E-18`

for example (1.0E-18 would be the minimum).

Here is the code, which works for me.

```
#define MAX_DELTA_DOUBLE 1.0E-15
#define EULERS_NUMBER 2.718281828459045
double MathAbs_Double (double x) {
return ((x >= 0) ? x : -x);
}
int MathAbs_Int (int x) {
return ((x >= 0) ? x : -x);
}
double MathPow_Double_Int(double x, int n) {
double ret;
if ((x == 1.0) || (n == 1)) {
ret = x;
} else if (n < 0) {
ret = 1.0 / MathPow_Double_Int(x, -n);
} else {
ret = 1.0;
while (n--) {
ret *= x;
}
}
return (ret);
}
double MathLn_Double(double x) {
double ret = 0.0, d;
if (x > 0) {
int n = 0;
do {
int a = 2 * n + 1;
d = (1.0 / a) * MathPow_Double_Int((x - 1) / (x + 1), a);
ret += d;
n++;
} while (MathAbs_Double(d) > MAX_DELTA_DOUBLE);
} else {
printf("\nerror: x < 0 in ln(x)\n");
exit(-1);
}
return (ret * 2);
}
double MathExp_Double(double x) {
double ret;
if (x == 1.0) {
ret = EULERS_NUMBER;
} else if (x < 0) {
ret = 1.0 / MathExp_Double(-x);
} else {
int n = 2;
double d;
ret = 1.0 + x;
do {
d = x;
for (int i = 2; i <= n; i++) {
d *= x / i;
}
ret += d;
n++;
} while (d > MAX_DELTA_DOUBLE);
}
return (ret);
}
double MathPow_Double_Double(double x, double a) {
double ret;
if ((x == 1.0) || (a == 1.0)) {
ret = x;
} else if (a < 0) {
ret = 1.0 / MathPow_Double_Double(x, -a);
} else {
ret = MathExp_Double(a * MathLn_Double(x));
}
return (ret);
}
```