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Good morning all,

I'm having some issues with floating point math, and have gotten totally lost in ".to_f"'s, "*100"'s and ".0"'s!

I was hoping someone could help me with my specific problem, and also explain exactly why their solution works so that I understand this for next time.

My program needs to do two things:

  1. Sum a list of decimals, determine if they sum to exactly 1.0
  2. Determine a difference between 1.0 and a sum of numbers - set the value of a variable to the exact difference to make the sum equal 1.0.

For example:

  1. [0.28, 0.55, 0.17] -> should sum to 1.0, however I keep getting 1.xxxxxx. I am implementing the sum in the following fashion:

    sum = array.inject(0.0){|sum,x| sum+ (x*100)} / 100
  2. The reason I need this functionality is that I'm reading in a set of decimals that come from excel. They are not 100% precise (they are lacking some decimal points) so the sum usually comes out of 0.999999xxxxx or 1.000xxxxx. For example, I will get values like the following:


To fix this, I am ok taking the sum of the first n-1 numbers, and then changing the final number slightly so that all of the numbers together sum to 1.0 (must meet validation using the equation above, or whatever I end up with). I'm currently implementing this as follows:

          sum = 0.0
          array.each do |item|
            sum += item * 100.0
          array[i] = (100 - sum.round)/100.0

I know I could do this with inject, but was trying to play with it to see what works. I think this is generally working (from inspecting the output), but it doesn't always meet the validation sum above. So if need be I can adjust this one as well. Note that I only need two decimal precision in these numbers - i.e. 0.56 not 0.5623225. I can either round them down at time of presentation, or during this calculation... It doesn't matter to me.

Thank you VERY MUCH for your help!

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3 Answers 3

up vote 5 down vote accepted

If accuracy is important to you, you should not be using floating point values, which, by definition, are not accurate. Ruby has some precision data types for doing arithmetic where accuracy is important. They are, off the top of my head, BigDecimal, Rational and Complex, depending on what you actually need to calculate.

It seems that in your case, what you're looking for is BigDecimal, which is basically a number with a fixed number of digits, of which there are a fixed number of digits after the decimal point (in contrast to a floating point, which has an arbitrary number of digits after the decimal point).

When you read from Excel and deliberately cast those strings like "0.9987" to floating points, you're immediately losing the accurate value that is contained in the string.

require "bigdecimal"

That value is precise. It is 0.9987. Not 0.998732109, or anything close to it, but 0.9987. You may use all the usual arithmetic operations on it. Provided you don't mix floating points into the arithmetic operations, the return values will remain precise.

If your array contains the raw strings you got from Excel (i.e. you haven't #to_f'd them), then this will give you a BigDecimal that is the difference between the sum of them and 1.

1 - array.map{|v| BigDecimal(v)}.reduce(:+)
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Thanks! Helpful answer. –  Brandon May 28 '12 at 17:30


  • continue using floats and round(2) your totals: 12.341.round(2) # => 12.34

  • use integers (i.e. cents instead of dollars)

  • use BigDecimal and you won't need to round after summing them, as long as you start with BigDecimal with only two decimals.

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I think that algorithms have a great deal more to do with accuracy and precision than a choice of IEEE floating point over another representation.

People used to do some fine calculations while still dealing with accuracy and precision issues. They'd do it by managing the algorithms they'd use and understanding how to represent functions more deeply. I think that you might be making a mistake by throwing aside that better understanding and assuming that another representation is the solution.

For example, no polynomial representation of a function will deal with an asymptote or singularity properly.

Don't discard floating point so quickly. I could be that being smarter about the way you use them will do just fine.

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