So this is weird. I'm in Ruby 1.9.3, and float addition is not working as I expect it would.
0.3 + 0.6 + 0.1 = 0.9999999999999999
0.6 + 0.1 + 0.3 = 1
I've tried this on another machine and get the same result. Any idea why this might happen?
So this is weird. I'm in Ruby 1.9.3, and float addition is not working as I expect it would.
0.3 + 0.6 + 0.1 = 0.9999999999999999
0.6 + 0.1 + 0.3 = 1
I've tried this on another machine and get the same result. Any idea why this might happen?
Floating point operations are inexact: they round the result to nearest representable float value.
That means that each float operation is:
float(a op b) = mathematical(a op b) + rounding-error( a op b )
As suggested by above equation, the rounding error depends on operands a & b.
Thus, if you perform operations in different order,
float(float( a op b) op c) != float(a op (b op c))
In other words, floating point operations are not associative.
They are commutative though...
As other said, transforming a decimal representation 0.1 (that is 1/10) into a base 2 representation (that is 1/16 + 1/64 + ... ) would lead to an infinite serie of digits. So float(0.1) is not equal to 1/10 exactly, it also has a rounding-error and it leads to a long serie of binary digits, which explains that following operations have a non null rounding-error (mathematical result is not representable in floating point)
It has been said many times before but it bears repeating: Floating point numbers are by their very nature approximations of decimal numbers. There are some decimal numbers that cannot be represented precisely due to the way the floating point numbers are stored in binary. Small but perceptible rounding errors will occur.
To avoid this kind of mess, you should always format your numbers to an appropriate number of places for presentation:
'%.3f' % (0.3 + 0.6 + 0.1)
# => "1.000"
'%.3f' % (0.6 + 0.1 + 0.3)
# => "1.000"
This is why using floating point numbers for currency values is risky and you're generally encouraged to use fixed point numbers or regular integers for these things.
First, the numerals “0.3”, “.6”, and “.1” in the source text are converted to floating-point numbers, which I will call a, b, and c. These values are near .3, .6, and .1 but not equal to them, but that is not directly the reason you see different results.
In each floating-point arithmetic operation, there may be a little rounding error, some small number e_{i}. So the exact mathematical results your two expressions calculate is:
(a + b + e_{0}) + c + e_{1} and (b + c + e_{2}) + a + e_{3}.
That is, in the first expression, a is added to b, and there is a slight rounding error e_{0}. Then c is added, and there is a slight rounding error e_{1}. In the second expression, b is added to c, and there is a slight rounding error e_{2}. Finally, a is added, and there is a slight rounding error e_{3}.
The reason your results differ is that e_{0} + e_{1} ≠ e_{2} + e_{3}. That is, the rounding that was necessary when a and b were added was different from the rounding that was necessary when b and c were added and/or the roundings that were necessary in the second additions of the two cases were different.
There are rules that govern these errors. If you know the rules, you can make deductions about them that bound the size of the errors in final results.
This is a common limitation of floating point numbers, due to their being encoded in base 2 instead of base 10. It can be difficult to understand, but once you do, you can easily avoid problems like this. I recommend this guide, which goes in depth to explain it.
For this problem specifically, you might try rounding your result to the nearest millionths place:
result = (0.3+0.6+0.1)
=> 0.9999999999999999
(result*1000000.0).round/1000000.0
=> 1.0
As for why the order matters, it has to do with rounding. When those numbers are turned into floats, they are converted to binary, and all of them become repeating fractions, like ⅓ is in decimal. Since the result gets rounded during each addition, the final answer depends on the order of the additions. It appears that in one of those, you get a round-up, where in the other, you get a round-down. This explains the discrepancy.
It is worth noting what the actual difference is between those two answers: approximately 0.0000000000000001.
In view you can use also the number_with_precision
helper:
result = 0.3 + 0.6 + 0.1
result = number_with_precision result, :precision => 3