When you use 32-bit float, the computer represents the result of `2./3.`

as 11,184,811 / 16,777,216, which is exactly 0.666666686534881591796875. In the floating-point you are using, numbers are always represented as some integer multiplied by some power of two (which may be a negative power of two). Due to limits on how large the integer can be (when you use `float`

, the integer must fit in 24 bits, not including the sign), the closest representable value to 2/3 is 11,184,811 / 16,777,216.

The reason that `printf`

with '%5.6f` displays “0.666667” is because “%5.6f” requests just six digits, so the number is rounded at the sixth digit.

The reason that `printf`

with `%5.20f`

displays “0.66666668653488159000” is that your `printf`

implementation “gives up” after 17 digits, figuring that is close enough in some sense. Some implementations of `printf`

, which one might argue are better, print the represented value as closely as the requested format permits. In this case, they would display “0.66666668653488159180”, and, if you requested more digits, they would display the exact value, “0.666666686534881591796875”.

(The floating-point format is often presented as a sign, a fraction between 1 [inclusive] and 2 [exclusive], and an exponent, instead of a sign, an integer, and an exponent. Mathematically, they are the same with an adjustment in the exponent: Each number representable with a sign, a 24-bit unsigned integer, and an exponent is equal to some number with a sign, a fraction between 1 and 2, and an adjusted exponent. Using the integer version tends to make proofs easier and sometimes helps explanation.)

`%5.6`

is asking for. Or are you asking why 0.66666668653488159000 is as close to two thirds as the computer can get? – Pete Kirkham Jun 17 '13 at 15:31