# ruby floating point errors

Can somebody explain why multiplying by 100 here gives a less accurate result but multiplying by 10 twice gives a more accurate result?

``````± % sc
>> 129.95 * 100
12994.999999999998
>> 129.95*10
1299.5
>> 129.95*10*10
12995.0
``````
• Most likely due to binary representation of floating point numbers. You can't write extactly 129.95 in base 2 I assume. Oct 29, 2010 at 20:28
• Oct 29, 2010 at 21:00
• Any clues at to why this would NOT be happening for me? I'm trying to demonstrate this, and I enter 129.95 * 100 as above into IRB and I unexpectedly get the correct answer.
– Joel
Nov 12, 2013 at 4:57
• To answer my own question - seems Float#to_s rounds. Doing this works: printf("%.50f", 129.95 * 100)
– Joel
Nov 12, 2013 at 5:05

If you do the calculations by hand in double-precision binary, which is limited to 53 significant bits, you'll see what's going on:

129.95 = 1.0000001111100110011001100110011001100110011001100110 x 2^7

129.95*100 = 1.1001011000010111111111111111111111111111111111111111011 x 2^13

This is 56 significant bits long, so rounded to 53 bits it's

1.1001011000010111111111111111111111111111111111111111 x 2^13, which equals

12994.999999999998181010596454143524169921875

Now 129.95*10 = 1.01000100110111111111111111111111111111111111111111111 x 2^10

This is 54 significant bits long, so rounded to 53 bits it's 1.01000100111 x 2^10 = 1299.5

Now 1299.5 * 10 = 1.1001011000011 x 2^13 = 12995.

First off: you are looking at the string representation of the result, not the actual result itself. If you really want to compare the two results, you should format both results explicitly, using `String#%` and you should format both results the same way.

Secondly, that's just how binary floating point numbers work. They are inexact, they are finite and they are binary. All three mean that you get rounding errors, which generally look totally random, unless you happen to have memorized the entirety of IEEE754 and can recite it backwards in your sleep.

There is no floating point number exactly equal to `129.95`. So your language uses a value which is close to it instead. When that value is multiplied by 100, the result is close to 12995, but it just so happens to not equal 12995. (It is also not exactly equal to 100 times the original value it used in place of `129.95`.) So your interpreter prints a decimal number which is close to (but not equal to) the value of `129.95 * 100` and which shows you that it is not exactly 12995. It also just so happens that the result `129.95 * 10` is exactly equal to 1299.5. This is mostly luck.

Bottom line is, never expect equality out of any floating point arithmetic, only "closeness".