# C# Math.Pow() is broken

And no, this does not (to my understanding) involve integer division or floating-point rounding issues.

My exact code is:

``````    static void Main(string[] args)
{
double power = (double)1.0 / (double)7.0;
double expBase = -128.0;
System.Console.WriteLine("sanity check: expected: -128 ^ 0.142857142857143 = -2.    actual: " + expBase + " ^ " + power + " = " + Math.Pow(expBase, power));
}
``````

The output is:

```sanity check: expected: -128 ^ 0.142857142857143 = -2. actual: -128 ^ 0.14285 7142857143 = NaN```

The Target Framework for this code is (according to solution properties) .NET Framework 4.0 Client Profile.

Strangely I haven't found any mention of this anywhere on the Web. Am I taking crazy pills here!?

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I don't think the answer to this is what you expect: wolframalpha.com/input/?i=%28-128%29%5E%281%2F7%29 –  Greg Hewgill Jan 16 '13 at 20:44
No, the problem is one of precedence. The statement -128 ^ (1/7) could be interpreted as -(128^(1/7)) or as (-128)^(1/7). In this case, the latter is what is in use. –  Kenogu Labz Jan 16 '13 at 20:48
This is not about precedence. (-128)^(1/7) is -2, but 0.14285 7142857143 != 1/7. –  JLRishe Jan 16 '13 at 20:57
@JLRishe: This is neither about precedence nor about rounding. See my answer for the mathematical reasons. –  Greg Hewgill Jan 16 '13 at 21:10
Obviously this type of calculation is not supported by System.Math. Any suggestions on how to calculate the answer? –  cowlinator Jan 16 '13 at 22:29

Seems to be exactly as specified; from the Math.Pow() remarks section on `Pow(x,y)`;

Parameters
x < 0 but not NegativeInfinity; y is not an integer, NegativeInfinity, or PositiveInfinity.

Result
NaN

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Thank you very much. –  cowlinator Jan 16 '13 at 22:22

Joachim's answer explains that pow is behaving according to its specification.

Why is pow( ) specified that way? Because `1.0/7.0` is not equal to 1/7. You are asking for the `0.14285714285714285` power of `-128.0`, and there is no real number with that property, so the result is correctly NaN. For all odd `n != 1`, `1.0/(double)n` is not exactly representable, so you can't compute the nth root of x by using `pow(x, 1.0/(double)n)`. Therefore `pow(x, y)` is specified to return NaN for negative x and non-integer y -- there is no appropriate real result for any of those cases.

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It should return the representable value closest to (-128)**(.1428…). :-) –  Eric Postpischil Jan 16 '13 at 21:11
@EricPostpischil: Somehow I doubt the questioner expects the answer `1.8019377358048383`; it's really not very close at all. –  Stephen Canon Jan 16 '13 at 21:15
But think how much it would add to the questions on Stack Overflow. Instead of explaining how .1+.2 gives .30…01 due to correctly rounded arithmetic, we could explain how 1.8019… is the correctly rounded result of `pow(-128, 1/7.)`. –  Eric Postpischil Jan 16 '13 at 21:45
I guess I fail to understand how it has anything to do with 1/7 not being exactly representable, when 1/7 is still not representable if you use a positive base i.e. `double power = (double)1.0 / (double)7.0;' 'double expBase = 128.0;` results in exactly 2.0 –  cowlinator Jan 16 '13 at 22:06
@user1698736: the difference is that `pow(128.0, 1.0/7.0)` is a real number; specifically, it's `1.999999999999999923045204...`, which happens to round to `2.0` in double precision. `pow(-128.0, 1.0/7.0)`, by contrast, is not real-valued. Just like `sqrt(-1)`, which is also not real-valued, it returns NaN. –  Stephen Canon Jan 17 '13 at 10:59

The problem here is the mathematical definition of "seventh root" is a multivalued function. While it is true that

(-2)7 = -128

this does not mean that -2 is the only answer to (-128)1/7. In the complex plane, the seventh-root function is multivalued and has many possible answers (just as the square root of 4 can be considered to be either +2 or -2, but +2 is the usual answer).

In order to simplify the mathematical handling of such expressions, the principal value is chosen by convention for the function in question so that the function becomes single-valued. In the case of seventh-root, the principal value is that given by Wolfram Alpha for (-128)1/7.

The `Math.Pow()` function in C# attempts to return the principal value for the `pow` function. When the principal value of the result would be a complex number, it returns `NaN`.

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That is not the problem. sqrt is in generally multivalued, but we define `sqrt` to return the positive root. `pow` could be similarly defined. The problem in this specific case is that `pow` is not being passed 1/7 for the power. It is being passed a `double` that is near 1/7, and it has no way to know that 1/7 was intended. –  Eric Postpischil Jan 16 '13 at 21:14
@EricPostpischil: There is no reason, even with exact calculations, why (-128)^(1/7) should return -2. That answer would be on a branch that wouldn't be considered a principal branch. Wolfram Alpha agrees and shows a result that is nowhere near -2. –  Greg Hewgill Jan 16 '13 at 21:23
@EricPostpischil Not a difference in principle, `1.0/7.0` is still a rational number, so the power is a finitely branched covering of the plane. –  Daniel Fischer Jan 16 '13 at 21:24
Err, make that "The Riemann surface of the power..." –  Daniel Fischer Jan 16 '13 at 21:35
None of which get the intended answer. I.e., the problem here is not that the function is multivalued. The problem is that information has been lost before `pow` has been called. There is no definition of a function that gives the correct answer given incorrect inputs (in general). –  Eric Postpischil Jan 16 '13 at 21:39

A fractional power of a negative real number is a complex number (see Math Forum for a detailed explanation).

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Not always. Given an odd whole number y and a real number x, x^(1/y) will always be real, even if x is negative. –  JLRishe Jan 16 '13 at 21:05
@JLRishe Not if you interpret a power function `\z -> z^e` as an analytic function. The analytic continuations of that from the positive half-line take nonreal values on the negative half-line for `e = 1/y`, `y > 1` integer. –  Daniel Fischer Jan 16 '13 at 21:20

I fixed Math.Pow().

It now has a larger accepted domain (i.e. for Parameters: x < 0 but not NegativeInfinity; y is a fraction with a numerator of 1 and an odd denominator), and returns a real number result for the new domain area.

In other words, (-128)^(1/7) returns -2.

Note: due to double-float precision limitations, it will work for most, but not all, fractional exponents.

Below is the code for the wrapper for Math.Pow() I wrote.

``````public class MathUtil
{
/// <summary>
/// Wrapper for Math.Pow()
/// Can handle cases like (-8)^(1/3) or  (-1/64)^(1/3)
/// </summary>
public static double Pow(double expBase, double power)
{
bool sign = (expBase < 0);
if (sign && HasEvenDenominator(power))
return double.NaN;  //sqrt(-1) = i
else
{
if (sign && HasOddDenominator(power))
return -1 * Math.Pow(Math.Abs(expBase), power);
else
return Math.Pow(expBase, power);
}
}

private static bool HasEvenDenominator(double input)
{
if(input == 0)
return false;
else if (input % 1 == 0)
return false;

double inverse = 1 / input;
if (inverse % 2 < double.Epsilon)
return true;
else
return false;
}

private static bool HasOddDenominator(double input)
{
if (input == 0)
return false;
else if (input % 1 == 0)
return false;

double inverse = 1 / input;
if ((inverse + 1) % 2 < double.Epsilon)
return true;
else
return false;
}
}
``````
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Why do you use HasOddDenominator. Cant you just say: !HasEvenDenominator ? –  Eystein Oct 7 '13 at 11:55
non-integers are neither even nor odd. –  cowlinator May 16 at 2:12