Now my question is that if this type is a distinct type from other unsigned int types or not.

Your question heavily depends on what exactly you mean with "*unsigned int types*". I'll assume this to refer to "*unsigned integer types*" as defined by the standard.

It can *not* be a type distinct from other *unsigned integer types*. All *unsigned integer types* are listed exclusively in [basic.fundamental]/2. These are the *standard unsigned integer types* `unsigned char`

, `unsigned short`

, `unsigned int`

, `unsigned long`

and `unsigned long long`

, and *extended unsigned integer types* if the implementation defines any (which isn't usually the case in the most common C++ implementations).

If you intend "*unsigned int types*" to refer to the *standard unsigned integer types* listed above, then the answer becomes that `size_t`

is neither required, nor prohibited, to be one of them, since it may also be one of the *extended unsigned integer types*. But if the implementation has none of those, then it must be one of the *standard unsigned integer types*.

If you intend "*unsigned int types*" to mean any "*integer types*" as defined in the standard which also have *unsigned* signdness, then the answer is again that it *cannot* be distinct from this set, since this set merely is a superset of the set of all *unsigned integer types*, adding `char8_t`

, `char16_t`

, `char32_t`

and potentially `char`

and `wchar_t`

(which have implementation-defined signdness).

(You can find definitions for all the mentioned terms from the standard in [basic.fundamental]/1 to 11 of the post-C++20 ISO C++ draft N4868 I linked above.)

Because if it is a distinct type, I should be able to have these overloads while if it is not, I should get redefinition error.

Regardless of the above, it is not guaranteed to cause a redefinition error, because while the types `uint16_t`

, `uint32_t`

and `uint64_t`

also must be *unsigned integer types* from the same category, they don't have to cover the whole category and in fact cannot, because there are at least 5 *unsigned integer types*, but you listed only three `uintX_t`

overloads. So `size_t`

doesn't need to match any of them and in fact doesn't need to match any `uintX_t`

at all.

For example on 64bit architectures, often `uint16_t`

is `unsigned short`

, `uint32_t`

is `unsigned int`

and `uint64_t`

is either `unsigned long`

or `unsigned long long`

, with the remaining one not being aliased by any `uintX_t`

.

So the overload set is not safe. `size_t`

may be one of the `uintX_t`

or it may not and neither the whole `uintX_t`

set, nor the whole set including `size_t`

must cover the set of all unsigned integer types.

If you want to overload for all unsigned integer types, overload by the actual (non-alias) type names for the standard unsigned integer types listed above, as well as all extended unsigned integer types if your implementation has them. However, consider whether a template, possibly constrained with a type trait, isn't a better option instead, since you can't portably know about extended integer types.

`size_t`

differently from, say,`uint64_t`

? They should be effectively bit for bit identical.`size_t`

isnotdirectly compatible/equivalent to some other defined`unsigned`

type? I wouldn't be surprised if some old systems did not adhere to this (e.g. they might have 8 and 16 bit normal integer types, but 32 bit pointers and`size_t`

s), but the systems I'm aware of like that are also pre-standard C++ IIRC, so systems like that might not be allowed by standard C++.`__STDCPP_DEFAULT_NEW_ALIGNMENT__`

must expand to an integer literal of type`std::size_t`

, and prior to C++23, there was no literal suffix for`std::size_t`

. This scenario makes it less trivial to make`std::size_t`

a distinct type (since equating it to an existing type means you can simply use the suffix for that type, even if you have to choose a suffix based on the target like Clang does).6more comments