When you do `T = TypeVar("T", bound=Union[A, B])`

, you are saying T can be bound to either `Union[A, B]`

or any subtype of `Union[A, B]`

. It's *upper-bounded* to the union.

So for example, if you had a function of type `def f(x: T) -> T`

, it would be legal to pass in values of any of the following types:

`Union[A, B]`

(or a union of any subtypes of A and B such as `Union[A, BChild]`

)
`A`

(or any subtype of A)
`B`

(or any subtype of B)

This is how generics behave in most programming languages: they let you impose a single upper bound.

But when you do `T = TypeVar("T", A, B)`

, you are basically saying `T`

*must* be either upper-bounded by A or upper-bounded by B. That is, instead of establishing a *single* upper-bound, you get to establish multiple!

So this means while it would be legal to pass in values of either types `A`

or `B`

into `f`

, it would *not* be legal to pass in `Union[A, B]`

since the union is neither upper-bounded by A nor B.

So for example, suppose you had a iterable that could contain either ints or strs.

If you want this iterable to contain any arbitrary mixture of ints or strs, you only need a single upper-bound of a `Union[int, str]`

. For example:

```
from typing import TypeVar, Union, List, Iterable
mix1: List[Union[int, str]] = [1, "a", 3]
mix2: List[Union[int, str]] = [4, "x", "y"]
all_ints = [1, 2, 3]
all_strs = ["a", "b", "c"]
T1 = TypeVar('T1', bound=Union[int, str])
def concat1(x: Iterable[T1], y: Iterable[T1]) -> List[T1]:
out: List[T1] = []
out.extend(x)
out.extend(y)
return out
# Type checks
a1 = concat1(mix1, mix2)
# Also type checks (though your type checker may need a hint to deduce
# you really do want a union)
a2: List[Union[int, str]] = concat1(all_ints, all_strs)
# Also type checks
a3 = concat1(all_strs, all_strs)
```

In contrast, if you want to enforce that the function will accept either a list of *all ints* or *all strs* but never a mixture of either, you'll need multiple upper bounds.

```
T2 = TypeVar('T2', int, str)
def concat2(x: Iterable[T2], y: Iterable[T2]) -> List[T2]:
out: List[T2] = []
out.extend(x)
out.extend(y)
return out
# Does NOT type check
b1 = concat2(mix1, mix2)
# Also does NOT type check
b2 = concat2(all_ints, all_strs)
# But this type checks
b3 = concat2(all_ints, all_ints)
```

alwaysdoes subtype checking, no matter what kind of TypeVar you're using or whether or not you're using generics. This is actually what pretty much all type systems with nominal subtyping will do -- for example, see Java and C++. The reason your example doesn't work is because while`MyUnion`

may be a subtype of`Union[int, str]`

, it isn't a subtype of`int`

.`Union[A, B]`

is a valid bound according to PEP 484 since that type does not contain any type variables -- a type variable is a type created by using TypeVar. So for example, if you did`T1 = TypeVar('T1')`

, it would then be illegal to try and use T1 within another TypeVar definition by doing either`T2 = TypeVar('T2', bound=T2)`

or`T3 = TypeVar('T3', T2, int)`

. This restriction exists mostly so type checkers wouldn't need to implement higher-order types, which is a pretty complex type system feature.