I'll try my best to describe it more clearly. Worst case, I describe it *differently*.

The upper/lower inference is one part of a phased approach to type inference with regard to type arguments that are used for a particular generic method call. Obviously, upper/lower inference won't be applied if in the first phase if the argument (E) is explicitly typed. e.g.:

given

```
public static T Choose<T>(T first, T second) {
return (rand.Next(2) == 0)? first: second;
}
```

I can invoke `Choose`

with explicit type arguments:

```
Choose<String>("first", "second");
```

With regard to the upper- or lower-bounds inference, there are some implications throughout 7.5.2 that decide whether lower- or upper-bounds inference is even applicable. For example, 7.5.2.9 (and .10) detail that the type parameter is *unfixed* for either upper- or lower-bounds inference to occur. 7.5.2.5 details that a type parameter is only unfixed when that type parameter depends on another unfixed type parameter. For example

```
IEnumerable<TResult> Select<TSource, TResult>(IEnumerable<TSource> e,
Func<TSource, Result> f)
```

`TResult`

"depends on" `TSource`

, because the type of `TSource`

could possibly determine the type of `TResult`

. e.g. with a call like `Select(c, e->Name)`

, `TResult`

depends on the type of `Name`

in `TSource`

.

In terms of upper- and lower-bounds inferences, for a given unfixed type parameter (X) whose type (V) is not explicitly declared (see first paragraph), upper *or* lower bounds of type argument (E) of type U are deduced. If the type parameter is covariant (has `out`

modifier) and one of the types in the lower-bound set is a candidate for the parameter, then a lower-bound inference occurred. Conversely, if the type parameter is contravariant (has 'in' modifier) and one of the types in the upper-bound set is a candidate for the parameter, then an upper-bound inference occurred. e.g. with `Select(c, e->e.Name)`

and `c`

was `IEnumerable<Mammal>`

then the compiler would infer an **lower** bound of `Mammal`

because the type parameter in `IEnumerable`

is covariant (e.g. it's declared `IEnumerable<out T>`

. If it were declared `IEnumerable<in T>`

then an upper-bound would be inferred. And if it were declared `Enumerabale<T>`

--with no `in`

or `out`

then it would be *invariant* and neither upper- nor lower-bounds inference would apply.)

Clearly, if parameter type can be neither covariant nor contravariant then an exact match must occur

is. It's a set of instructions for what you're meant to do when you find (anywhere in 7.5.2) an instruction of e.g. "a lower-bound inference is made from U to T". And then 7.5.2.11 tells youhowthese inferences are used.