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211 lines
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Markdown
211 lines
10 KiB
Markdown
# Expanded Subtyping for Generic Function Types
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## Summary
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Extend the subtyping relation for function types to relate generic function
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types with compatible instantiated function types.
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## Motivation
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As Luau does not have an explicit syntax for instantiation, there are a number
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of places where the typechecker will automatically perform instantiation with
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the goal of permitting more programs. These instances of instantiation are
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ad-hoc and strategic, but useful in practice for permitting programs such as:
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```lua
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function id<T>(x: T): T
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return x
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end
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local idNum : (number) -> number
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idNum = id -- ok
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```
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However, they have also been a source of some typechecking bugs because of how
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they actually make a determination as to whether the instantation should happen,
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and they currently open up some potential soundness holes when instantiating
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functions in table types since properties of tables are mutable and thus need to
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be invariant (which the automatic-instantiation potentially masks).
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## Design
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The goal then is to rework subtyping to support the relationship we want in the
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first place: allowing polymorphic functions to be used where instantiated
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functions are expected. In particular, this means adding instantiation itself to
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the subtyping relation. Formally, that'd look something like:
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```
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instantiate(<a>(T1) -> T2) = (T1') -> T2'
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(T1') -> T2' <: (T3) -> T4
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--------------------------------------------
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<a>(T1) -> T2 <: (T3) -> T4)
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```
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Or informally, we'd say that a generic function type is a subtype of another
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function type if we can instantiate it and show that instantiated function type
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to be a subtype of the original function type. Implementation-wise, this loose
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formal rule suggests a strategy of when we'll want to apply instantiation.
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Namely, whenever the subtype and supertype are both functions with the potential
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subtype having some generic parameters and the supertype having none. So, if we
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look once again at our simple example from motivation, we can walk through how
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we expect it to type check:
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```lua
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function id<T>(x: T): T
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return x
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end
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local idNum : (number) -> number
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idNum = id -- ok
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```
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First, `id` is given the type `<T>(T) -> T` and `idNum` is given the type
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`(number) -> number`. When we actually perform the assignment, we must show that
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the type of the right-hand side is compatible with the type of the left-hand
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side according to subtyping. That is, we'll ask if `<T>(T) -> T` is a subtype of
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`(number) -> number` which matches the rule to apply instantiation since the
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would-be subtype has a generic parameter while the would-be supertype has no
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generic parameters. This contrasts with the current implementation which, before
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asking the subtyping question, checks if the type of the right-hand side
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contains any generics at any point and if the type of the left-hand side cannot
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_possibly_ contain generics and instantiates the right-hand side if so.
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Adding instantiation to subtyping does pose some additional questions still
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about when exactly to instantiate. Namely, we need to consider cases like
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function application. We can see why by looking at some examples:
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```lua
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function rank2(f: <a>(a) -> a): (number) -> number
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return f
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end
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```
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In this case, we expect to allow the instantiation of `f` from `<a>(a) -> a` to
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`(number) -> number`. After all, we can consider other cases like where the body
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instead applies `f` to some particular value, e.g. `f(42)`, and we'd want the
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instantiation to be allowed there. However, this means we'd potentially run into
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issues if we allowed call sites to `rank2` to pass in non-polymorphic functions.
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A naive approach to implementing this proposal would do exactly that because we
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currently treat contravariant subtyping positions (i.e. for the arguments of
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functions) as being the same as our normal (i.e. covariant) subtyping relation
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but with the arguments reversed. So, to type check an application like
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`rank2(function(str: string) return str + "s" end)` (where the function argument
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is of type `(string) -> string`), we would ask if `<a>(a) -> a` is a subtype of
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`(string) -> string`. This is precisely the question we asked in the original
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example, but in the contravariant context, this is actually unsound since
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`rank2` would then function as a general coercion from, e.g.,
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`(string) -> string` to `(number) -> number`.
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This sort of behavior does come up in other languages that mix polymorphism and
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subtyping. If we consider the same example in F#, we can compare its behavior:
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```fsharp
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let ranktwo (f : 'a -> 'a) : int -> int = f
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let pluralize (s : string) : string = s + "s"
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let x = ranktwo pluralize
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```
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For this example, F# produces one warning and one error. The warning is applied
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to the function definition of `ranktwo` itself (coded `FS0064`), and says "This
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construct causes code to be less generic than indicated by the type annotations.
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The type variable 'a has been constrained to be type 'int'." This warning
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highlights the actual difference between our example in Luau and the F#
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translation. In F#, `'a` is really a free type variable, rather than a generic
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type parameter of the function `ranktwo`, as such, this code actually
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constrains the type of `ranktwo` to be `(int -> int) -> (int -> int)`. As such,
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the application on line 3 errors because our `(string -> string)` function is
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simply not compatible with that type. With higher-rank polymorphic function
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parameters, it doesn't make sense to warn on their instantiation (as illustrated
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by the example of actually applying `f` to some particular data in the
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definition of `rank2`), but it's still just as problematic if we were to accept
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instantiated functions at polymorphic types. Thus, it's important that we
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actually ensure that we only instantiate in covariant contexts. So, we must
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ensure that subtyping only instantiates in covariant contexts.
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It may also be helpful to consider an example of rank-1 polymorphism to
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understand the full scope of the behavior. So, we can look at what happens if we
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simply move the type parameter out in our working example:
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```lua
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function rank1<a>(f: (a) -> a): (number) -> number
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return f
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end
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```
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In this case, we expect an error to occur because the type of `f` depends on
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what we instantiate `rank1` with. If we allowed this, it would naturally be
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unsound because we could again provide a `(string) -> string` argument (by
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instantiating `a` with `string`). This reinforces the idea that the presence of
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the generic type parameter is likely to be a good option for determining
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instantiation (at least when compared to the presence of free type variables).
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## Drawbacks
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One of the aims of this proposal is to provide a clear and predictable mental
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model of when instantiation will take place in Luau. The author feels this
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proposal is step forward compared to the existing ad-hoc usage of instantiation
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in the typechecker, but it's possible that programmers are already comfortable
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with the mental model they have built for the existing implementation.
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Hopefully, this is mitigated by the fact that the new setup should allow all of
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the _sound_ uses of instantiation permitted by the existing system. Notably,
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however, programmers may be surprised by the added restriction when it comes to
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properties in tables. In particular, we can consider a small variation of our
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original example with identity functions:
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```lua
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function id<T>(x: T): T
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return x
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end
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local poly : { id : <a>(a) -> a } = { id = id }
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local mono : { id : (number) -> number }
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mono = poly -- error!
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mono.id = id -- also an error!
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```
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In this case, the fact that we're dealing with a _property_ of a table type
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means that we're in a context that needs to be invariant (i.e. not allow
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subtyping) to avoid unsoundness caused by interactions between mutable
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references and polymorphism (see things like the [value
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restriction in OCaml][value-restriction] to understand why). In most cases, we
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believe programmers will be using functions in tables as an implementation of
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methods for objects, so we don't anticipate that they'll actually _want_ to do
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the unsound thing here. The accepted RFC for [read-only
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properties][read-only-props] gives us a technically-precise solution since
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read-only properties would be free to be typechecked as a covariant context
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(since they disallow mutation), and thus if the property `id` was marked
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read-only, we'd be able to do both of the assignments in the above example.
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## Alternatives
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The main alternatives would likely be keeping the existing solution (and
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likely having to tactically fix future bugs where instantiation either happens
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too much or not enough), or removing automatic instantiation altogether in favor
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of manual instantiation syntax. The former solution (changing nothing) is cheap
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now (both in terms of runtime performance and also development cost), but the
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existing implementation involves extra walks of both types to make a decision
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about whether or not to perform instantiation. To minimize the performance
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impact, the functions that perform these questions (`isGeneric` and
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`maybeGeneric`) actually do not perform a full walk, and instead try to
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strategically look at only enough to make the decision. We already found and
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fixed one bug that was caused by these functions being too imprecise against
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their spec, but fleshing them out entirely could potentially be a noticeable
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performance regression since the decision to potentially instantiate is one that
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comes up often.
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Removing automatic instantiation altogether, by contrast, will definitely be
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"correct" in that we'll never instantiate in the wrong spot and programmers will
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always have the ability to instantiate, but it would be a marked regression on
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developer experience since it would increase the annotation burden considerably
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and generally runs counter to the overall design strategy of Luau (which focuses
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heavily on type inference). It would also require us to actually pick a syntax
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for manual instantiation (which we are still open to do in the future if we
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maintain an automatic instantiation solution) which is frought with parser
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ambiguity issues or requires the introduction of a sigil like Rust's turbofish
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for instantiation. Discussion of that syntax is present in the [generic
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functions][generic-functions] RFC.
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[value-restriction]: https://stackoverflow.com/questions/22507448/the-value-restriction#22507665
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[read-only-props]: https://github.com/Roblox/luau/blob/master/rfcs/property-readonly.md
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[generic-functions]: https://github.com/Roblox/luau/blob/master/rfcs/generic-functions.md
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