# c# float [] average loses accuracy

I am trying to calculate average for an array of floats. I need to use indices because this is inside a binary search so the top and bottom will move. (Big picture we are trying to optimize a half range estimation so we don't have to re-create the array each pass).

Anyway I wrote a custom average loop and I'm getting 2 places less accuracy than the c# Average() method

``````float test = input.Average();

int count = (top - bottom) + 1;//number of elements in this iteration
int pos = bottom;
float average = 0f;//working average
while (pos <= top)
{
average += input[pos];
pos++;
}
average = average / count;
``````

example:

```0.0371166766 - c#
0.03711666 - my loop

125090.148 - c#
125090.281 - my loop ```

http://pastebin.com/qRE3VrCt

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try storing `average` as a double and converting to a `float` at the end. –  Servy Feb 12 '13 at 18:32
I'd also rename your accumulator `sum` and use a new variable `average` in the end. –  CodesInChaos Feb 12 '13 at 18:36
Floating point numbers are almost always only an approximation. If your average calculation differs from the c# Average() you will get different results. Have a look at this: stackoverflow.com/questions/4664662/… –  Jobo Feb 12 '13 at 18:43
@Jobo Yes, they are an approximation, but adjusting your algorithm can reduce the error. –  Servy Feb 12 '13 at 18:49

I'm getting 2 places less accuracy than the c# Average()

No, you are only losing 1 significant digit. The float type can only store 7 significant digits, the rest are just random noise. Inevitably in a calculation like this, you can accumulate round-off error and thus lose precision. Getting the round-off errors to balance out requires luck.

The only way to avoid it is to use a floating point type that has more precision to accumulate the result. Not an issue, you have double available. Which is why the Linq Average method looks like this:

``````   public static float Average(this IEnumerable<float> source) {
if (source == null) throw Error.ArgumentNull("source");
double sum = 0;         // <=== NOTE: double
long count = 0;
checked {
foreach (float v in source) {
sum += v;
count++;
}
}
if (count > 0) return (float)(sum / count);
throw Error.NoElements();
}
``````

Use double to reproduce the Linq result with a comparable number of significant digits in the result.

-

I'd rewrite this as:

``````int count = (top - bottom) + 1;//number of elements in this iteration
double sum = 0;
for(int i = bottom; i <= top; i++)
{
sum += input[i];
}
float average = (float)(sum/count);
``````

That way you're using a high precision accumulator, which helps reduce rounding errors.

btw. if performance isn't that important, you can still use LINQ to calculate the average of an array slice:

``````input.Skip(bottom).Take(top - bottom + 1).Average()
``````

I'm not entirely sure if that fits your problem, but if you need to calculate the average of many subarrays, it can be useful to create a persistent sum array, so calculating an average simply becomes two table lookups and a division.

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You need a cast at the end. –  Servy Feb 12 '13 at 18:40

Just to add to the conversation, be careful when using Floating point primitives.

What Every Computer Scientist Should Know About Floating-Point Arithmetic

Internally floating point numbers store additional least significant bits that are not reflected in the displayed value (aka: Guard Bits or Guard Digits). They are, however, utilized when performing mathematical operations and equality checks. One common result is that a variable containing 0f is not always zero. When accumulating floating point values this can also lead to precision errors.