Yes, this is supposed to be valid.

The way CTAD works is we perform overload resolution over a synthesized set of constructors to figure out what the class template parameters were. From C++17, that synthesized set of constructors is just based on the primary template's constructors and deduction guides (I'm changing the template parameter names because I find them very confusing):

```
template <class T=int, class U=float>
struct my_pair {
T first;
U second;
};
// default constructor
template <class T=int, class U=float>
auto __f() -> my_pair<T, U>;
// copy candidate
template <class T=int, class U=float>
auto __f(my_pair<T, U>) -> my_pair<T, U>;
// deduction guide
template <class... T>
auto __f(T...) -> my_pair<T...>;
```

C++20 adds a new aggregate deduction candidate. For each element of either the *initializer-list* or *designated-initializer-list*, we pick the corresponding element of the aggregate and use its type as the new candidate. For

```
my_pair x{.first = 20, .second = 20.f};
```

The type of `first`

is `T`

and the type of `second`

is `U`

, hence:

```
// aggregate deduction candidate
template <class T=int, class U=float>
auto __f(T, U) -> my_pair<T, U>;
```

Now, I wrote these four candidates as functions (because I find it easier to think of them as functions) but the wording defines them as constructors of a hypothetical class type. So when we perform overload resolution using `{.first = 20, .second = 20.f}`

, if you squint it kind of works.

The last candidate is the best candidate (only the aggregate deduction candidate and the deduction guide are viable, the aggregate deduction candidate is more specialized), so we end up with `my_pair<int, float>`

.

Having finished CTAD, we now start over and effectively do

```
my_pair<int, float> x{.first = 20, .second = 20.f};
```

Which of course works.