# Perl for loop going haywire [duplicate]

I have a simple for loop in Perl

``````for (\$i=0; \$i <= 360; \$i += 0.01)
{
print "\$i ";
}
``````

Why is it that when I run this code I get the following output, where as soon as it gets to 0.81 it suddenly starts to add in a load more decimal places? I know I could simply round up to avoid this issue but I was wondering why it happens. An increment of 0.01 does not seem at all crazy to do.

`````` 0.77
0.78
0.79
0.8
0.81
0.820000000000001
0.830000000000001
0.840000000000001
0.850000000000001
0.860000000000001
0.870000000000001
``````
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learn.perl.org/faq/… –  mob Feb 6 '13 at 23:48
8.1 seems to be a remarkably hard number to convert. Years ago, I had a mini-project trying to find some way to manipulate a particular value: '8.10' accurately. Both Java and Perl, were having problems with this number. –  Axeman Feb 7 '13 at 0:41

## marked as duplicate by Jonathan Leffler, DocMax, ithcy, Sudarshan, TemplateRexFeb 7 '13 at 6:03

Computers use binary representations. Not all decimal floating point numbers have exact representations in binary notation, so some error can occur (its actually a rounding difference). This is the same reason why you shouldn't use floating point numbers for monetary values:

(Picture taken from dailywtf)

Most elegant way to get around this issue is using integers for calculations, dividing them to the correct number of decimal places and using `sprintf` to limit the number of decimal places printed. This will both make sure:

• There's always to correct result printed
• The rounding error doesn't accumulate

Try this code:

``````#!/usr/bin/perl
for (\$i=0; \$i <= 360*100; \$i += 1) {
printf "%.2f \n", \$i/100;
}
``````
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+1 for the documentary evidence of incorrect programming practices in the wild! –  Jonathan Leffler Feb 6 '13 at 23:56

To demonstrate Jonathan's answer, if you code up the same loop structure in C, you will get the same results. Although C and Perl may compile differently and be ran on different machines the underlying floating point arithmetic rules should cause consistent outputs. Note: Perl uses double-precision floating point for its floating point representation whereas in C the coder explicitly chooses float or double.

Loop in C:

``````    #include <stdio.h>

int main() {
double i;
for(i=0;i<=1;i+=.01)  {
printf("%.15f\n",i);
}
}
``````

Output:

``````    0.790000000000000
0.800000000000000
0.810000000000000
0.820000000000001
0.830000000000001
0.840000000000001
0.850000000000001
``````

To demonstrate the point even further, code the loop in C but now use single-precision floating point arithmetic and see that the output is less precise and even more erratic.

Output:

``````    0.000000000000000
0.009999999776483
0.019999999552965
0.029999999329448
0.039999999105930
0.050000000745058
0.060000002384186
0.070000000298023
0.079999998211861
0.089999996125698
0.099999994039536
``````
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1/10 is periodic in binary just like 1/3 is periodic in decimal. As such, it cannot be accurately stored in a floating point number.

``````>perl -E"say sprintf '%.17f', 0.1"
0.10000000000000001
``````

Either work with integers

``````for (0*100..360*100) {
my \$i = \$_/100;
print "\$i ";
}
``````

Or do lots of rounding

``````for (my \$i=0; \$i <= 360; \$i = sprintf('%.2f', \$i + 0.01)) {
print "\$i ";
}
``````
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Basically, because the decimal number 0.01 does not have an exact representation in binary floating point, so over time, adding the best approximation to 0.01 deviates from the answer you'd like.

This is basic property of (binary) floating point arithmetic and not peculiar to Perl. What Every Computer Scientist Should Know About Floating-Point Arithmetic is the standard reference, and you can find it very easily with a Google search.

Kernighan & Plauger say, in their old but classic book "The Elements of Programming Style", that:

• A wise old programmer once said "floating point numbers are like little piles of sand; every time you move one, you lose a little sand and gain a little dirt".

They also say:

• 10 * 0.1 is hardly ever 1.0

Both sayings point out that floating point arithmetic is not precise.

Note that some modern CPUs (IBM PowerPC) have IEEE 754:2008 decimal floating point arithmetic built-in. If Perl used the correct types (it probably doesn't), then your calculation would be exact.

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