the syntax is slightly based on protobuf, but kotlinized :D
message Person {
required string name = 1;
required int32 id = 2;
optional string email = 3;
}
for example, this protobuf snippet would generate - a model class/interface - a builder - a serializer - a deserializer - a visitor (one per module) that would contain a `visit/accept` function for this type
the code parser tool basically has all antlr features + - left recursive (and right recursive) patterns, - inheritance based lexer tokens, - type based pattern matching, - priority based pattern lists (with some options of handling recursion) - and dynamic grammar (the ability to add rules/options to the grammar at runtime)
Well, the higher-kinded stuff would be allowing you to declare types/functions that could act on both Tree and Stuff in a common way without the need to specify what their generic type parameters are.
I just dont understand the use case of higher kinded polymorphism
and no one is able to give me an example of where it is actually useful
to be more exact... where it is 1, actually useful 2, not because of a bad design 3, impossible to solve in a better way (of which we know how to do it)
I have a List<Words> collection in a Paragraph type. I'd like to check if any of the word has ':' in it, if that index is > -1, I also want to check if there is any other word after that colon's index in paragraph.
The paragraph type also has a property 'Text' string which has all the words in it as one string.
I want to set a property of a paragraph enum, if ':' if the last character in the paragraph, enum.ContainsKeyAndColon else if there's any word\characters(except empty string) present, enum.ContainsKeyColonValue
a word is set of characters without space in it. so word usually has : at the end all the time
in the same cell if there are more than one : and words before and after, i could stills set contains key value pair enum. Processing that will be next stage
@Wietlol Oh! I remembered what the advantage was over your IFunctor<T> example. The return type would be the type that is implementing the Functor, and not IFunctor<T>. ie if IEnumerable<T> was implementing it, the result of Map<T,U> would be IEnumerable<U>, not IFunctor<U> while still maintaining the contract.