Here's my understanding.

Suppose we have a generic type with 2 methods

```
type L<T>
T get();
void set(T);
```

Suppose we have a super type `P`

, and it has sub types `C1, C2 ... Cn`

. (for convenience we say `P`

is a subtype of itself, and is actually one of the `Ci`

)

Now we also got *n* concrete types `L<C1>, L<C2> ... L<Cn>`

, as if we have manually written *n* types:

```
type L_Ci_
Ci get();
void set(Ci);
```

We didn't have to manually write them, that's the point. There are *no* relations among these types

```
L<Ci> oi = ...;
L<Cj> oj = oi; // doesn't compile. L<Ci> and L<Cj> are not compatible types.
```

For C++ template, that's the end of story. It's basically macro expansion - based on one "template" class, it generates many concrete classes, with no type relations among them.

For Java, there's more. We also got a type `L<? extends P>`

, it is a super type of any `L<Ci>`

```
L<Ci> oi = ...;
L<? extends P> o = oi; // ok, assign subtype to supertype
```

What kind of method should exist in `L<? extends P>`

? As a super type, any of its methods must be hornored by its subtypes. This method would work:

```
type L<? extends P>
P get();
```

because in any of its subtype `L<Ci>`

, there's a method `Ci get()`

, which is compatible with `P get()`

- the overriding method has the same signature and covariant return type.

This can't work for `set()`

though - we cannot find a type `X`

, so that `void set(X)`

can be overridden by `void set(Ci)`

for any `Ci`

. Therefore `set()`

method doesn't exist in `L<? extends P>`

.

Also there's a `L<? super P>`

which goes the other way. It has `set(P)`

, but no `get()`

. If `Si`

is a super type of `P`

, `L<? super P>`

is a super type of `L<Si>`

.

```
type L<? super P>
void set(P);
type L<Si>
Si get();
void set(Si);
```

`set(Si)`

"overrides" `set(P)`

not in the usual sense, but compiler can see that any valid invocation on `set(P)`

is a valid invocation on `set(Si)`