What "concept" are you talking about?

None of the numbers you mentioned are representable precisely in binary floating-point format (regardless of precision). All of the numbers you mentioned end up having *infinite* number of binary digits after the dot.

Since neither `float`

nor `double`

have infinite precision, in `float`

and `double`

formats the implementation will represent these values *approximately*, most likely by a nearest representable binary floating-point value. These approximate values will be different for `float`

and `double`

. And the approximate `float`

value might end up being greater or smaller than the approximate `double`

value. Hence the result you observe.

For example in my implementation, the value of `0.7`

is represented as

```
+6.9999998807907104e-0001 - float
+6.9999999999999995e-0001 - double
```

Meanwhile the value of `0.1`

is represented as

```
+1.0000000149011611e-0001 - float
+1.0000000000000000e-0001 - double
```

As you can see, `double`

representation is greater than `float`

representation in the first example, while in the second example it is the other way around. (The above are decimal notations, which are rounded by themselves, but they do have enough precision to illustrate the effect well enough.)

`0.6<=0.6`

or`0.8<=0.8`

– John Sep 6 '12 at 17:52