## Background

The requirement for a comparator on the key type of an associative container (for example std::map) is that it imposes a strict weak order on the elements of the key type.

For a given comparator `comp(x, y)`

we define `equiv(x, y) = !comp(x, y) && !comp(y, x)`

.

The requirements for `comp(x, y)`

being a strict weak order are

- Irreflexibility (
`!comp(x, x)`

for all`x`

) - Transitivity of the ordering (if
`comp(a, b)`

and`comp(b, c)`

then`comp(a, c)`

). - Transitivity of equivalence (if
`equiv(a, b)`

and`equiv(b, c)`

then`equiv(a, c)`

)

`std::less<float>`

(the default comparator) uses `operator<`

, which does not create a strict weak order because of `NaN`

. Because `x < NaN`

and `NaN < x`

are false for all `x`

, `NaN`

is equivalent to all floats under this comparator, this breaks condition #3: `equiv(1.0, NaN)`

and `equiv(NaN, 2.0)`

but not `equiv(1.0, 2.0)`

. For IEEE floats except NaN, it is a strict weak order (where each number has its own equivalence class except for `0`

and `-0`

).

## The question

Does this mean that one is not allowed by the C++ standard to use IEEE floats (and (long) doubles) as a key type in an associative container because of the above issue, even if I make sure that NaN never gets inserted into the container? I'm not quite sure about the "elements of `Key`

" wording in the standard—if it means all possible elements or just the elements that end up in the container.

Note: The question is not about issues wrt. truncation/rounding, I'll likely post a different question regarding that soon.

### Update:

*Sigh*. I should've posed the question without specifying float, I just thought it was a nice example.

**The question really is**: Is it allowed to use a comparator that only imposes a strict weak order on the elements that get put into the container, not all possible instances of the key type? Please don't just answer "yes" or "no", I'd like some references to the standard / prior discussions about this / an answer from a commitee member or something.