When using floating-point numbers, the relational operators have meanings, but their meanings don't necessarily align with how actual numbers behave.

If floating-point values are used to represent actual numbers (their normal purpose), the operators tend to behave as follows:

`x > y`

and `x >= y`

both imply that the numeric quantity which `x`

is supposed to represent is likely greater than `y`

, and at worst probably not much less than `y`

.

`x < y`

and `x <= y`

both imply that the numeric quantity which `x`

is supposed to represent is likely less than than `y`

, and is at worst probably not much greater than `y`

.

`x == y`

implies that the numeric quantities which `x`

and `y`

represent are indistinguishable from each other

Note that if `x`

is of type `float`

, and `y`

is of type `double`

, the above meanings will be achieved if the `double`

argument is cast to `float`

. In the absence of a specific cast, however, C and C++ (and also many other languages) will convert a `float`

operand to `double`

before performing a comparison. Such conversion will greatly reduce the likelihood that the operands will be reported "indistinguishable", but will greatly increase the likelihood that the comparison will yield a result contrary to what the intended numbers actually indicate. Consider, for example,

```
float f = 16777217;
double d = 16777216.5;
```

If both operands are cast to `float`

, the comparison will indicate that the values are indistinguishable. If they are cast to `double`

, the comparison will indicate that `d`

is larger even though the value `f`

is supposed to represent is slightly bigger. As a more extreme example:

```
float f = 1E20f;
float f2 = f*f;
double d = 1E150;
double d2 = d*d;
```

Float `f2`

contains the best `float`

representation of 1E40. Double `d2`

contains the best `double`

representation of 1E400. The numerical quantity represented by `d2 is hundreds of orders of magnitude greater than that represented by`

f2`, but`

(double)f2 > d2`. By contrast, converting both operands to float would yield`

f2 == (float)d2`, correctly reporting that the values are *indistinguishable*.

PS--I am well aware that IEEE standards require that calculations be performed as though floating-point values represent precise power-of-two fractions, but few people seeing the code `float f2 = f1 / 10.0;`

as being "Set f2 to the representable power-of-two fraction which is closest to being one tenth of the one in f1". The purpose of the code is to make f2 be a tenth of f1. Because of imprecision, the code cannot fulfill that purpose perfectly, but in most cases it's more helpful to regard floating-point numbers as representing actual numerical quantities than to regard them as power-of-two fractions.