It seems the answer is "no".
When you call
Transform directly, you have to specify a type parameter:
int i = Transform<int>("");
So hypothetically, if you could pass an incompletely-constructed generic function like you want to, you'd need to specify the type parameters as well:
void GeneralizedFunction(string aStringA, string aStringB, Func<string, T> aAction)
A result1 = aAction<A>(aStringA);
B result2 = aAction<B>(aStringB);
// Do something with A and B here
So it seems to me that you could hypothetically do this, if C# had a syntax like that.
But what's the use case? Aside from transforming strings to the default value of an arbitrary type, I don't see much use for this. How could you define a function that would provide a meaningful result in either of two different types using the same series of statements?
An analysis of why it's not possible:
When you use a lambda expression in your code, it is compiled into either a delegate or an expression tree; in this case, it's a delegate. You can't have an instance of an "open" generic type; in other words, to create an object from a generic type, all type parameters must be specified. In other words, there's no way to have an instance of a delegate without providing arguments for all of its type parameters.
One of the C# compiler's helpful features is implicit method group conversions, where the name of a method (a "method group") can be implicitly converted to a delegate type representing one of the overloads of that method. Similarly, the compiler implicitly converts a lambda expression to a delegate type. In both cases, the compiler emits code to create an instance of the delegate type (in this case, to pass it to the function). But the instance of that delegate type still needs to have a type argument for each of its type parameters.
To pass the generic function as a generic function, it seems, the compiler would need to be able to pass the method group or the lambda expression to the method without conversion, so the
aAction parameter would somehow have a type of "method group" or "lambda expression." Then, the implicit conversion to a delegate type could happen at the call sites
A result1 = aAction<A>(aStringA); and
B result2 = aAction<B>(aStringB);. Of course, at this point, we are well into the universe of contrafactuals and hypotheticals.
The solution I came up with over lunch was this, assuming a function
Deserialize<T> that takes a string containing serialized data and returns an object of type
void GeneralizedFunction<T>(string aStringA, string aStringB, Func<T, string> stringGetter)
A result1 = Deserialize<A>(stringGetter(aStringA));
B result2 = Deserialize<B>(stringGetter(aStringB));
void Example(string serializedA, string serializedB, string pathToA, string pathToB, FileInfo a, FileInfo b)
GeneralizedFunction(serializedA, serializedB, s => s);
GeneralizedFunction(pathToA, pathToB, File.ReadAllText);
GeneralizedFunction(a, b, fi => File.ReadAllText(fi.FullName));