We are starting with your decimal number `59.858139`

Convert that number to binary: `111011.11011011101011101111111101011100011011000001000110100001000100...`

I.e. the number is an infinite fraction in binary. It is not possible to represent it exactly. (In the same way that it is not possible to represent 1/3 exactly with decimal numbers)

Rewrite the number to some form of binary scientific notation:

`10 ^ 101 * 1.1101111011011101011101111111101011100011011000001000110100001000100...`

Remember that this is still in binary, so the `10 ^ 101`

corresponds to `2 ^ 5`

in decimal notation.

Now... A float value can store 23 bits in the mantissa. If we round it up using "round to nearest" rounding mode, we get:

`10 ^ 101 * 1.11011110110111010111100`

Which is equal to:

`111011.110110111010111100`

That is all the precision that can fit into the float data type. Now convert that back to decimal:

`59.8581390380859375`

Seems pretty close to 59.858139 actually... But that is just luck. What happens if we convert the second closest float value to binary instead?

`111011.110110111010111011 = 59.858135223388671875`

So basically the resolution is approximately `0.000004`

.

So all we can really know from the float value is that the number is something like: `59.858139`

± `0.000002`

It could just as well be `59.858137`

or `59.858141`

.

Since the last digit is rather uncertain, I am guessing that the printing code is smart enough to understand that the last digit falls outside the precision of a float value, and hence, the value is rounded to `59.85814`

.

By the way, if you (like me are) are too lazy to convert between binary and decimal fractions by hand, you can use this converter. If you want to read more about the details of the floating point system, the wikipedia page for floating point representation is a great resource.