I wouldn't know how to do it statically, except with *dependent types* (example), which Scala doesn't have. If you only dealt with constants it should be possible to use macros or a compiler plug-in that performs the necessary checks, but if you have arbitrary float-typed expressions it is very likely that you have to resort to runtime checks.

Here is an approach. Define a class that performs a runtime check to ensure that the float value is in the required range:

```
abstract class AbstractRangedFloat(lb: Float, ub: Float) {
require (lb <= value && value <= ub, s"Requires $lb <= $value <= $ub to hold")
def value: Float
}
```

You could use it as follows:

```
case class NormalisedFloat(val value: Float)
extends AbstractRangedFloat(0.0f, 1.0f)
NormalisedFloat(0.99f)
NormalisedFloat(-0.1f) // Exception
```

Or as:

```
case class RangedFloat(val lb: Float, val ub: Float)(val value: Float)
extends AbstractRangedFloat(lb, ub)
val RF = RangedFloat(-0.1f, 0.1f) _
RF(0.0f)
RF(0.2f) // Exception
```

It would be nice if one could use value classes in order to gain some performance, but the call to `requires`

in the constructor (currently) prohibits that.

**EDIT :** addressing comments by @paradigmatic

Here is an intuitive argument why types depending on natural numbers can be encoded in a type system that does not (fully) support *dependent types*, but ranged floats probably cannot: The natural numbers are an enumerable set, which makes it possible to encode each element as path-dependent types using Peano numerals. The real numbers, however, are not enumerable any more, and it is thus no longer possible to systematically create types corresponding to each element of the reals.

Now, computer floats and reals are eventually finite sets, but still way to large to be reasonably efficiently enumerable in a type system. The set of computer natural numbers is of course also very large and thus poses a problem for arithmetic over Peano numerals encoded as types, see the last paragraph of this article. However, I claim that it is often sufficient to work with the first *n* (for a rather small *n*) natural numbers, as, for example, evidenced by HLists. Making the corresponding claim for floats is less convincing - would it be better to encode 10,000 floats between 0.0 and 1.0, or rather 10,000 between 0.0 and 100.0?