I'll try to clarify Anthony Pegram answer.
Generic type is covariant on some type argument when it returns values of said type (e.g.
Func<out TResult> returns instances of
IEnumerable<out T> returns instances of
T). That is, if something returns instances of
TDerived, you can as well work with such instances as if they were of
Generic type is contravariant on some type argument when it accepts values of said type (e.g.
Action<in TArgument> accepts instances of
TArgument). That is, if something needs instances of
TBase, you can as well pass in instances of
It seems quite logical that generic types which both accept and return instances of some type (unless it is defined twice in the generic type signature, e.g.
CoolList<TIn, TOut>) are not covariant nor contravariant on the corresponding type argument. For example,
List is defined in .NET 4 as
List<in T> or
Some compatibility reasons might have caused Microsoft to ignore that argument and make arrays covariant on their values type argument. Maybe they conducted an analysis and found that most people only use arrays as if they were readonly (that is, they only use array initializers to write some data into an array), and, as such, the advantages overweigh the disadvantages caused by possible runtime errors when someone will try to make use of covariance when writing into the array. Hence it is allowed but not encouraged.
As for your original question,
list.ToArray() creates a new
LinkLabel with values copied from original list, and, to get rid of (reasonable) warning, you'll need to pass in
list.ToArray<Control>() will do the job:
IEnumerable<TSource> as its argument and returns
List<LinkLabel> implements read-only
IEnumerable<out LinkLabel>, which, thanks to
IEnumerable covariance, could be passed to the method accepting
IEnumerable<Control> as its argument.