# Can I implement round half to even?

I need to do round half to even on floats, i.e.,

1. if the value is half-way between two integers (tie-breaking, fraction part of y is exactly 0.5) round to the nearest even integer,
2. else, standard round (which is Round to nearest Integer in Ruby).

These are some results, for example:

``````0.5=>0
1.49=>1
1.5=>2
2.5=>2
2.51=>3
3.5=>4
``````
• In floating point arithmetik, there no such thing as "exactly". even simple calculations can lead to things like 1.50000000000001 – Meier Feb 12 '16 at 10:25
• @Meier 0.5 in decimal representation is exactly 0.1 In binary representation. – sawa Feb 12 '16 at 10:32
• @sawa yes, but when you somehow calculated your number, you can easily get an difference in the last bit. – Meier Feb 12 '16 at 10:37
• @Meier: Not so. Any float has an exact value, and as it happens, the result of the round-half-to-even operation on a float (rounding to the nearest integer) is always exactly representable - at least, assuming IEEE 754 floating-point, so that operation can be performed exactly. – Mark Dickinson Feb 12 '16 at 13:49

I would reopen the Float class to create a round_half_to_even function :

``````class Float
def round_half_to_even(precision)
if self % 1 == 0.5
floor = self.to_i.to_f
return floor % 2 == 0 ? floor : floor + 1
else
return self.round(precision)
end
end
end
``````
• The question did not ask for a precision and you are unnecessarily complicating your code by adding that "feature". As is, `x = 2.2.round_half_to_even(0) #=> 2`, but `x = 2.5.round_half_to_even(0) #=> 2.0`. Suppose the next statement were `y=(x+1)/2`? In one case `y #=> 1`, in the other `y #=>1.5`. Including "precision" makes for a messy fix. Also, you don't need either `self.` or either `return`. I suggest you simplify to `def round_half_to_even; if self % 1 == 0.5; floor = to_i; floor.even? ? floor : floor + 1; else; round; end; end`. – Cary Swoveland Feb 20 '16 at 8:43

The `BigDecimal` class has the rounding mode half to even already implemented. You just have to set the `ROUND_MODE` to `:half_even` with `BigDecimal.mode` method:

``````require 'bigdecimal'

def round_half_to_even(float)
BigDecimal.mode(BigDecimal::ROUND_MODE, :half_even)
BigDecimal.new(float, 0).round
end
``````

Or by using the `round` with some arguments:

``````require 'bigdecimal'

def round_half_to_even(float)
BigDecimal.new(float, 0).round(0, :half_even).to_i
end
``````

Please note that `BigDecimal#round` returns an `Integer` when used without arguments, but a `BigDecimal` when used with arguments. Therefore the need to call `to_i` in the second example but not in the first.

``````def round_half_to_even f
q, r = f.divmod(2.0)
q * 2 +
case
when r <= 0.5 then 0
when r >= 1.5 then 2
else 1
end
end

round_half_to_even(0.5) # => 0
round_half_to_even(1.49) # => 1
round_half_to_even(1.5) # => 2
round_half_to_even(2.5) # => 2
round_half_to_even(2.51) # => 3
round_half_to_even(3.5) # => 4
``````

You could do the following:

``````def round_half_to_even(f)
floor = f.to_i
return f.round unless f==floor+0.5
floor.odd? ? f.ceil : floor
end

round_half_to_even(2.4) #=> 2
round_half_to_even(2.6) #=> 3
round_half_to_even(3.6) #=> 4
round_half_to_even(2.5) #=> 2
round_half_to_even(3.5) #=> 4
``````