# accurate single pass penny computation

We have a cost C which must be assigned to departments 1..n. Another computation produces the share for each department, it is a number from 0 to 1, with more than 5 decimal places. The sum of all department shares is exactly 1, but they are not necessarily equal.

The goal is to compute the exact dollars and cents to bill to each department. The sum of the bill must EXACTLY match the cost C, it cannot be a few pennies under or over. Furthermore, each department's share must be not require fractional pennies. Additionally, although it is not fair to just dump the remainder onto the last department, it is not necessary to look back to previous timeframes. Note that simply rounding each department's share to the penny almost always results in an over/under of a few pennies.

Grossly oversimplified example: C = 33.34 , 4 departments each with exactly 0.2500 share. Because 33.34 * 0.25 = 8.335 so you can see that two departments must pay 8.33 and two must pay 8.34. One correct assignment would be: d1=8.33, d2=8.34, d3=8.33, d4=8.34. If you round, every department pays 8.34 which results in an overage of \$0.02. If you multiply this by many more departments and many more costs, you end up with hundred dollar discrepancies.

I want to do this in 1 pass, that is, I don't want to loop through, find out I am off by 0.02, then loop again and tweak values until it is correct. I want to do this in 1 pass. I would also like to know if this algorithm has a name.

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In Perl:

``````#!/usr/bin/perl

use strict;
use warnings;

use Data::Dumper;

use List::AllUtils qw( sum );

print Dumper allocate(10_000, .23, .37, .4);
print Dumper allocate(33.34, .25, .25, .25, .25);
print Dumper allocate(100, 1/3, 1/3, 1/3);

sub allocate {
my (\$C, @shares) = @_;

my @alloc;

while ( my \$share = shift @shares ) {
push @alloc, sprintf '%.2f', \$C * \$share;
\$C -= \$alloc[-1];
my \$denom = sum @shares;
\$_ /= \$denom for @shares;
}

return \@alloc;
}
``````

Output:

```\$VAR1 = [
'2300.00',
'3700.00',
'4000.00'
];
\$VAR1 = [
'8.34',
'8.33',
'8.34',
'8.33'
];
\$VAR1 = [
'33.33',
'33.34',
'33.33'
];
```
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I think I get the gist of this, thanks –  user130582 Dec 1 '09 at 2:41

Don't use floats. Use either fixed point decimal numbers, or use ints such that you can divide by whatever your scaling factor is to get the value in dollars.

Never, ever, ever calculate money using floats.

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I'd call it "running total" and implement it as follows:

1. Calculate the share owed by dept #1 (may have rounding errors)
2. Make dept #1 pay the amount calculated in step 1
3. Calculate the share that's jointly owed by dept #1 and dept #2
4. Make dept #1 pay the amount calculated in step 3, minus the amount actually paid in step 2.
5. Etc. for the amount that's jointly owed by depts #s 1, 2, and 3.

This will ensure that the error experienced by any department is at most one rounding error (not a sum of several rounding errors), and that the final total is correct.

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