# Ideas ## Design ### Extendable Syntax Kari should have a pure syntax, that simply consists of words and nothing else. Nicer syntax could be implemented on top of that, but should be reducable to pure syntax. Consider the following array literal: ``` kari [ 3 5 8 ] ``` This would then become syntax sugar for the following: ``` kari 3 5 8 3 array ``` `array` would just be a built-in function that creates an array from values on the stack, and the right-most argument would define the length of that array. The same could be done for all literals except maybe numbers. (Although, if you think about it, numbers are just words that follow a certain format. We could treat these as built-in functions that are specially handled, or allow functions with regexes as names. Then numbers wouldn't be special syntax at all.) Special syntax should be implemented as an extension of the parser. These extensions could be implemented in Rust code, by implementing a trait, or in Kari, by providing a function. ### Limiting Kari Programs There's often a conflict between making Kari powerful and keeping it reasonable. I think I know how to solve this conflict: Make Kari as powerful as it can be, including seemingly unreasonable stuff like extending syntax and deleting functions. However, if functions can be deleted, then a piece of code that has access to function deletion can just delete the `delete` function to limit any code from then on. The same would go for other functions of course. Another possibility would be an opt-in model: If builtin functions were organized in modules, and all modules would need to be passed as an argument in order to be accessed, then a module/function could only access whatever has been passed to it from the outside. ### Type Annotations I've found that more complicated code benefits from comments that explicitely point out which types are currently at the top of the stack. But of course, such comments can go out of date, or be wrong in the first place. There should be a builtin that takes a list of types and fails, if those are not the types currently on the stack. So something like this: ``` # on stack: symbol dup # => symbol symbol to_list # => symbol [ word ] swap wrap # => [ word ] [ symbol ] swap prepend # => [ [ word ] symbol ] ``` Would become something like this: ``` # on stack: symbol [ symbol ] on_stack dup [ symbol symbol ] on_stack to_list [ symbol [ word ] ] on_stack swap wrap [ [ word ] [ symbol ] ] on_stack swap prepend [ [ [ word ] symbol ] ] on_stack ``` There's one advantage of the comment approach though: Thanks to syntax highlighting, the annotations are visually distinct. It might make sense to use a special syntax here, to preserve that attribute. Maybe create a special list syntax that creates a list of types on the stack, then executes a functions the checks said list against the stack. Maybe something like this: ``` kari [: symbol :] # verifies that a symbol is on top of the stack ``` This would just be syntax sugar for the following: ``` kari [ symbol ] annotation ``` ### Overloading via Type Inference It is highly desirable to support function overloading of user-defined functions. It would be nice to use type inference to determine the signatures, then there wouldn't need to be explicit type annotations in many cases. Even in cases where type annotations are necessary or desirable, type inference would enable the use of inline type annotations for this. Then there wouldn't need to be a special syntax for function types. ### Function Types Currently, each list has an associated scope, as each list could be a function. This is unnecessary from a design perspective, and makes some things slightly more complicated from an implementation perspective. Maybe it would be nicer to distinguish functions and list. A list would be just a list, while a function would be a composite type that has a list and a scope. It would be possible to define functions like this: ``` kari [ a b c ] fn ``` This would put an anonymous function on the stack that could then be `define`d as usual. It might make sense to make functions more visually distinct (also through syntax highlighting) by creating a special syntax for this: ``` kari [! a b c !] ``` There could even be special syntax for more specific function types. For example, if functions that evaluate to a boolean had special syntax, `if` might become easier to read. ``` kari [! do_stuff !] [? a b = ?] if ``` ### Maps as Composite Types Instead of having different types for lists, structs, tuples, maps, etc., all of those could be implemented through an ordered map type. Maps would be defined through a general syntax, but list syntax would still exist and desugar into that. While representing all composite types as maps is kinda neat from a conceptual and implementation perspective, I don't think it's nice from a typing perspective, as everything would be structurally types. I think there's a way to embrace this, without letting go of nominal typing, by making type structure and type names othorgonal concepts. I think this can be done by introducing the concept of a named type, which can be created like this: ``` map :name type ``` This would create a type called `name`, which under the hood is a map. Every function that accepts a `name` would accept a `name`only, and passing any other map would lead to a type error. Of course all of this is pretty course-grained, if `name` is supposed to be some kind of struct, for example. In the short term, I think this could be solved by somehow making direct manipulation of the map private to the module where the type was defined. In the long term, it might be possible to use refinement types to refine maps down to more specific structures. ### Builtin modules All builtin functions currently live in a global scope. It would be better if they were integrated with the module system. Then they wouldn't use up as much of the namespace, and the difference between builtin and non-builtin functions would become smaller. ## Implementation ### Builtin Input/Output Builtins already need to define their input. It probably makes sense to make that directly available to them as an argument to the builtin function. This would be less work and less error-prone. It might even be possible to take stack manipulation out of them completely, if outputs are also defined at some point. ### `Evaluator` as `Stream` of side effects If I ever end up modelling side effects somehow, then `Evaluator` could be turned into a stream of side effects that the runner pulls out of it. ### Error Messages - Add spans to functions, so a type error for a function can point to where the function is defined. - Make it possible to return multiple spans per error. For example the type error message can point to the expression that has the wrong type, as well as the operator that expects a different one. - Give spans a type, so operands and operators can be colored differently in error messages. - Extend the spans of expressions that are the result of an evaluation, so they also point to the operator that did the evaluation (like `eval`, `each`). This requires support for discontinuous spans, or maybe expressions can just have different spans. - When a function definition conlicts with an existing definition, that definition should be shown. ### REPL Add a REPL. As far as debugging tools go, this is probably the most bang for the buck. Could it even be possible to emulate some debugging features by implementing a `step` builtin, which evaluates the first word of a list, but leaves the rest of the list? Over time, it might be possible to make the language so powerful, that a debugger can just be implemented as a library that is used with the REPL. ### Pipeline Extend the pipeline with more stages. Add a stage that converts expressions to values. Not sure if that's possible without full evaluation, as that stage would have to keep track of scopes, but it seems to be worth a try. Maybe more features of the evaluator can be split out into simple pipeline stages. ### Define scope-less `define` in `std` Once non-builtin functions support overloading, the scope-less `define` can be implemented in terms of the builtin, scope-taking `define`.