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> On May 18, 2016, at 2:35 AM, Austin Zheng <[email protected]> wrote: > > I've put together a considerably more detailed draft proposal, taking into > account as much of Matthew's feedback as I could. You can find it below: > > https://github.com/austinzheng/swift-evolution/blob/az-existentials/proposals/XXXX-enhanced-existentials.md > > Since there is no chance this will come up for review anytime soon, I expect > to make significant revisions to it over the next month or so. Any feedback > would be greatly appreciated. Thank you for working on this! Great progress. Minor nit, but I think the proper word is constraint rather than requirement here: "Within the angle brackets < and > are zero or more requirements. Requirements are separated by commas." Another tweak: "P can be used in lieu of Any<P>, where P is a protocol with or without associated type or self requirements." This proposal is introducing generalized existentials. P and Any<P> should be interchangeable for any protocol regardless of requirements of the protocol. Existentials of protocols with self or associated type requirements that do not include constraints will just expose limited direct functionality. It would still be possible to attempt cast them to concrete types to recover more functionality. In the future (after a follow on proposal) it will also be possible to open the existential. Thorsten pointed out that there should only be one where clause for the whole existential. This follows the structure of generic type and function constraints. It may also be worth removing the 'as' alias from this proposal. This could be introduced as a stand alone proposal where it would apply to any context with generic constraints. Another item: // NOT ALLOWED let a : Any<Any<ProtocolA, ProtocolB>> Why is this not allowed? It is pointless, but should be allowed and considered identical to the flattened syntax. On dynamic casting, I don't believe it should be restricted in the way you have defined here. Casting *to* an existential doesn't have anything to do with opening an existential. We should allow casting to any existential type. On a similar note, I completely disagree with the limitation you specify for use of Any in generic constraints precisely because of your counterargument. In the discussion about moving the where clause it has been noted that sometime it is necessary to apply a lot of constraints to get the necessary effect. A mechanism for factoring constraints is highly desirable and will greatly improve the readability of generic code. Typealiases bound to Any can provide such a mechanism. Let's not artificially restrict the use of it. The section regarding members of a partly constrained existential needs to be more fleshed out. We can't simply punt it to a future proposal. However, I do think it is a good idea to wait until the core team has time to participate in the discussion. The section about defining typealias also should not be left to the future. It is possible to define typealias with protocol<> today and to use that alias in a generic constraint. Removing that capability would be a regression. In fact, it's utility will increase significantly with this proposal. In general, I don't think we need the distinction between simple and full Any. The whole idea of this proposal IMO should be fully generalizing existentials. If restrictions are necessary they should be due to (hopefully temporary) implementation considerations. > > Austin > >>>> On Tue, May 17, 2016 at 9:52 PM, Austin Zheng <[email protected]> >>>> wrote: >>> >>> >>>> On Tue, May 17, 2016 at 1:25 PM, Matthew Johnson <[email protected]> >>>> wrote: >>>>> >>>>> >>>>>> >>>>>> Within the angle brackets are zero or more 'clauses'. Clauses are >>>>>> separated by semicolons. (This is so commas can be used in where >>>>>> constraints, below. Better ideas are welcome. Maybe it's not necessary; >>>>>> we can use commas exclusively.) >>>>> >>>>> I’m not a fan of the semicolon idea. I don’t see any reason for this. >>>>> The `where` keyword separates the protocol list from the constraints just >>>>> fine. The list on either side should be able to use commas with no >>>>> problem (or line breaks if that proposal goes through). >>>> >>>> I'm leaning towards getting rid of the commas, but would like to write out >>>> a few 'dummy' examples to see if there are any readability issues that >>>> arise. >>> >>> Replaced with what? Whitespace separation? I suppose that might work for >>> the protocol list but it feels inconsistent with the rest of Swift. Commas >>> plus (hopefully) the alternative of newline seem like the right direction >>> to me. >> >> Sorry, I completely misspoke (mistyped?). I meant I want to get rid of the >> semicolons and use commas. I've come to the conclusion that there are no >> readability issues, protocol<> already uses commas, and semicolons used in >> this manner don't have a precedent anywhere else in the language. >> >>> >>>>>> >>>>>> There are five different possible clauses: >>>>>> >>>>>> 'class'. Must be the first clause, if present. Places a constraint on >>>>>> the existential to be any class type. (Implies: Only one can exist. >>>>>> Mutually exclusive with class name clause.) >>>>>> >>>>>> (In the future a follow-up proposal should add in 'struct' or 'value' as >>>>>> a counterpart.) >>>>> >>>>> If we’re going to allow `struct` we should also allow `enum`. `value` >>>>> would allow either of those. >>>> >>>> Of course. A future proposal can allow list members to discuss the exact >>>> details as to how struct, value, or enum specifiers should work. >>> >>> Yep, agree. Just mentioning that if we’re going to reference it we should >>> not leave obvious holes in what would be considered. :) >> >> Absolutely. >> >>> >>>>>> >>>>>> Class name. Must be the first clause, if present. (Implies: Only one can >>>>>> exist. Mutually exclusive with 'class'.) Places a constraint on the >>>>>> existential (not really an existential anymore) to be an instance of the >>>>>> class, or one of its subclasses. >>>>> >>>>> It is still be an existential if it includes protocol requirements that >>>>> the class does not fulfill. For example, you might have Any<UIView, >>>>> SomeProtocol> where UIView does not conform to SomeProtocol, but various >>>>> subclasses do. >>>> >>>> Fair enough. (I don't think the way things work would be affected.) >>>> >>>>> Your proposal doesn’t discuss composing Any in the way that Adrian’s did >>>>> like this: >>>>> >>>>> typealias Foo = Any<SomeClass, SomeProtocol, OtherProtocol> >>>>> Any<AnotherProtocol, Foo> >>>> >>>> I didn't think it needed to be discussed. An Any<...> existential type is >>>> a type 'expression' just like any other, and should be allowed to >>>> participate in other Any<...>s. >>>> >>>>> >>>>> I like the idea of composition as it allows us to factor out constraints. >>>>> If we are going to do that we should allow a class to be specified in >>>>> the composition as long is it is a subclass of all class requirements of >>>>> Any types it composes. For example, this should be allowed: >>>>> >>>>> typealias Bar = Any<SubclassOfSomeClass, Foo, AnotherProtocol> >>>>> >>>>> This is still one class requirement for Bar, it just refines the class >>>>> requirement of Foo to be SubclassOfSomeClass rather than just SomeClass. >>>> >>>> This is a good point. There should be clarification as to how special >>>> cases of Any<...> used in another Any<...> behave. For example, like you >>>> said Any<MyClass, Any<SomeSubclassOfMyClass, Protocol>> should be valid. >>>> This will go into any proposal that emerges from the discussion. >>> >>> Yes, this is why we need to discuss Any composition. There are also cases >>> of incompatible associated type constraints which need to be rejected (such >>> as composing two Any’s where one has Element == String and another has >>> Element == Int). >>> >>>> >>>>> >>>>>> Example: Any<UIViewController; UITableViewDataSource; >>>>>> UITableViewDelegate> >>>>>> "Any UIViewController or subclass which also satisfies the table view >>>>>> data source and delegate protocols" >>>>>> Dynamic protocol. This is entirely composed of the name of a protocol >>>>>> which has no associated types or Self requirement. >>>>>> Example: Any<CustomStringConvertible; BooleanType> >>>>>> "Any type which conforms to both the CustomStringConvertible and >>>>>> BooleanType protocols" >>>>>> >>>>>> I'm going to use 'static protocol' to refer to a protocol with >>>>>> associated types or self requirements. Feel free to propose a more sound >>>>>> name. >>>>>> >>>>>> Self-contained static protocol, simple. This is composed of the name of >>>>>> a static protocol, optionally followed by a 'where' clause in which the >>>>>> associated types can be constrained (with any of the three basic >>>>>> conformance types: subclassing, protocol conformance, or type equality). >>>>>> Associated types are referred to with a leading dot. >>>>> >>>>> Please do not introduce terms “dynamic protocol” and “static protocol”. >>>>> We want to support existentials of protocols that have self or associated >>>>> type requirements. The dynamic vs static distinction is a limitation of >>>>> the current implementation of Swift and doesn’t make sense for the long >>>>> term vision. >>>> >>>> I'm not trying to introduce new terms, these are just placeholders. At the >>>> same time "protocols with self or associated type requirements" is >>>> cumbersome to work with and it would be nice for someone to come up with a >>>> descriptive term of art for referring to them. >>> >>> I agree that a better term would be useful. In the meantime, I would >>> prefer something like “trivial” and “nontrivial” protocols. >> >> I've decided to just use the full name until the community comes up with >> better names. Clarity is preferable to brevity in this case. >> >>> >>>> >>>>> >>>>>> >>>>>> Example: Any<Collection where .Generator.Element : NSObject, >>>>>> .Generator.Element : SomeProtocol> >>>>>> "Any type that is a Collection, whose elements are NSObjects or their >>>>>> subclasses conforming to SomeProtocol.” >>>>> >>>>> Swift does not allow disjunction of requirements. Only conjunctions are >>>>> supported. That means the correct reading is: >>>>> >>>>> "Any type that is a Collection, whose elements are NSObjects and their >>>>> subclasses conforming to SomeProtocol.” >>>> >>>> Yes, that is what I meant. "whose elements are (NSObjects or their >>>> subclasses) conforming to SomeProtocol”. >>> >>> Ok, good. Wasn’t quite clear to me. >> >> Yes, the verbiage will need to be clearer in the future. That sentence could >> be ambiguously parsed. >> >>> >>>>>> >>>>>> Bound static protocol. This is the same as a self-contained static >>>>>> protocol, but with a leading "<name> as " which binds the protocol to a >>>>>> generic typealias. The name can be then be used in subsequent clauses to >>>>>> build constraints. >>>>>> >>>>>> Example: Any<T as Collection; IntegerLiteralConvertible where >>>>>> .IntegerLiteralType == T.Element>. >>>>>> "Any type that is a Collection, and also can be built from an integer >>>>>> literal, in which the collection elements are the same type as the type >>>>>> of the integer used for the integer literal conformance.” >>>>> >>>>> I’m not sure about this, but if we’re going to do it it should be the >>>>> other way around: `Collection as T` with the alias after the name of the >>>>> protocol. >>>> >>>> I like this, it flows better. "Protocol as T where Protocol.Foo == Int, >>>> Protocol.Bar : Baz”. >>> >>> Why did you introduce an alias here and then not use it? Did you mean >>> "Protocol as T where T.Foo == Int, T.Bar : Baz" >> >> Another result of rushing to compose an email. Sorry! >> >>> >>>> >>>>> You are also using “dot shorthand” here to refer to an associated type of >>>>> IntegerLiteralConvertible. I think “dot shorthand” should be limited to >>>>> cases where there is only one protocol that is getting constrained. In >>>>> other cases, we need to be clear about which protocol we are referring to. >>>> >>>> I borrowed dot shorthand from the generics manifesto. But you are right, >>>> it should only be allowed if there is one protocol with associated types >>>> or self requirements clause in the Any<...> construction. >>> >>> I would actually go further and limit it to one protocol period, and >>> possibly even to one protocol and no type names (as types can have nested >>> types and typealiases). When we allow shorthand it should be immediately >>> unambiguous what the shorthand references with no need to look at type or >>> protocol declarations. >> >> It might be desirable to propose the proposal with no allowance for >> shorthand, and have the dot shorthand be a smaller follow-up proposal. >> >>> >>>> >>>>> >>>>>> >>>>>> There will be rules to prevent recursive nesting. For example, if >>>>>> generic typealiases are allowed, they cannot refer to each other in a >>>>>> circular manner (like how structs can't contain themeselves, and you >>>>>> can't create a cyclic graph of enums containing themselves). >>>>>> >>>>>> How an existential can be used depends on what guarantees are provided >>>>>> by the clauses. For example, 'Any<Equatable>' can't be used for much; if >>>>>> there were any methods on Equatable that did not use the associated >>>>>> types at all you'd be able to call them, but that's about it. However, >>>>>> 'Any<Equatable where .Self == String>' would allow for == to be called >>>>>> on instances. (This is a stupid example, since Any<Equatable where .Self >>>>>> == String> is equivalent to 'String', but there are almost certainly >>>>>> useful examples one could come up with.) >>>>>> >>>>>> In order of increasing 'power': >>>>>> Don't constrain any associated types. You can pass around >>>>>> Any<Equatable>s, but that's about it. >>>>>> Constrain associated types to conform to protocols. >>>>>> Fully constrain associated types. >>>>> >>>>> I think we need to spell out pretty clearly what members we expect to be >>>>> available or not available. This section probably needs the most design >>>>> and elaboration. >>>>> >>>>> For example, we probably can’t access a member who uses an associated >>>>> type as an input unless it is constrained to a specific type. On the >>>>> other hand output types probably don’t need to limit access to a member. >>>>> However, if the output type is Self or an associated type the visible >>>>> signature would have an output type which has the relevant constraints of >>>>> the existential applied, but no more. In some cases this means the >>>>> output type would simply be Any. >>>> >>>> Absolutely. This is vaguely what I had in mind but I wanted to get >>>> something down first. Thanks for thinking through some of the implications >>>> :). >>> >>> That’s what I thought. Just wanted to start the process of elaborating >>> expectations. >>> >>>> >>>>> >>>>> Where this really gets tricky is for compound types like functions, >>>>> generic types, etc. Working out the details in these cases is pretty >>>>> complex. I will defer to Doug on whether it is best to just defer those >>>>> cases to the future, leave them up to the implementer, or try to work out >>>>> all of the relevant details in the proposal (in which case we probably >>>>> need a type system expert to help!). >>>> >>>> Yes, exactly! For example, can Any<...> existentials involving protocols >>>> with associated types or self requirements be used within generic function >>>> or type definitions? Maybe there's an argument that existential types of >>>> this nature are redundant if you have access to generics (e.g. defining a >>>> property on a generic type that is a Collection containing Ints; you >>>> should be able to do that today). On the other hand, maybe there are use >>>> cases I haven't thought of… >>> >>> I see no reason they shouldn’t be. They are not redundant at all. For >>> example, you may want to store instances in a heterogeneous collection. >>> You need existentials to do that. >>> >>> A simple example of what I was referring to there is something like this: >>> >>> protocol P { >>> associatedtype Foo >>> >>> func bar(callback: (Foo) -> ()) >>> } >>> >>> In other words, types in the signature of a protocol member are complex >>> types that reference Self or associated types. I think you really need a >>> formal understanding of the type system to understand how to expose these >>> members through a constrained existential. We can probably understand the >>> expected behavior in some of the simpler cases on a case by case basis, but >>> that approach doesn’t scale at all and is arbitrary. If they’re going to >>> be supported an expert is going to need to be involved in the design. >> >> Yes. I have some ideas regarding this topic. >> >>> >>>> >>>>> >>>>> One area you didn’t touch on is “opening” the existential? Is that out >>>>> of scope for this proposal? That would be fine with me as this proposal >>>>> is already taking on a lot. But if so, you should mention something >>>>> about future directions as it is pretty closely related to this proposal. >>>> >>>> Yes, existential opening is explicitly separate from this (although I >>>> wanted to mention it in the section where I talk about how Any<Equatable> >>>> is not very useful). But you are absolutely right, this proposal should >>>> discuss how it wants to interact with possible future directions. >>>> >>>>> >>>>> Another area you didn’t touch on is whether Any constructs (and >>>>> typealiases referring to them) should be usable as generic constraints. >>>>> I would expect this to be possible but I think we need to spell it out. >>>> >>>> I'm hoping for community input. This is a tricky subject, and at some >>>> point we'll bump into implementation limitations. >>> >>> I don’t think it’s too tricky. You can just unpack the constraints of the >>> Any into the list of generic constraints. Maybe I’m missing something, but >>> I don’t think so. >>> >>>> >>>>> >>>>> -Matthew >
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