Re: Haskell 1.3
We are still in the middle of a bunch of minor last-minute changes. While the technical aspects of Haskell 1.3 are stable, we're still fiddling with the prelude and the wording of the report. We've now set a `final' final release date at May 1. As before, the working version of the report is available via the web at http://haskell.cs.yale.edu/haskell-report/haskell-report.html More importantly, there is a lot of work going on to get the implementations ready. I hope people will be able to start using Haskell 1.3 soon after we release the report. John Peterson [EMAIL PROTECTED] Yale Haskell Project
Re: Haskell 1.3
Lennart Augustsson wrote: > It looks ugly, but we could say that a data declaration does not > have to have any constructors: > > data Empty = Philip Wadler responded: > I'm not keen on the syntax you propose. How about if we allow the > rhs of a data declaration to be just `empty', where `empty' is a > keyword? > > data Empty = empty Another suggestion is to omit the equal sign, as in data Empty Cheers, Ronny Wichers Schreur [EMAIL PROTECTED]
Re: Haskell 1.3
Philip Wadler writes: > > > It looks ugly, but we could say that a data declaration does not > > have to have any constructors: > > > >data Empty = > > > >-- Lennart > > I agree that the best way to fix this is to have a form of data > declaration with no constructors, but I'm not keen on the syntax you > propose. How about if we allow the rhs of a data declaration to be > just `empty', where `empty' is a keyword? > > data Empty = empty > > -- P I would like to propose an alternative that in my view has both good syntax, and does not introduce a new keyword: data Empty /Magnus
Re: Haskell 1.3
> It looks ugly, but we could say that a data declaration does not > have to have any constructors: > > data Empty = > >-- Lennart I agree that the best way to fix this is to have a form of data declaration with no constructors, but I'm not keen on the syntax you propose. How about if we allow the rhs of a data declaration to be just `empty', where `empty' is a keyword? data Empty = empty -- P
Re: Haskell 1.3
> Suggestion: Include among the basic types of Haskell a type `Empty' > that contains no value except bottom. Absolutely! But I don't think it should be built in (unless absolutely necessary). It looks ugly, but we could say that a data declaration does not have to have any constructors: data Empty = -- Lennart PS. There are other ways of getting empty types, but they are all convoluted, like data Empty = Empty !Empty
Re: Haskell 1.3
> Suggestion: Include among the basic types of Haskell a type `Empty' > that contains no value except bottom. Absolutely! But I don't think it should be built in (unless absolutely necessary). It looks ugly, but we could say that a data declaration does not have to have any constructors: data Empty = -- Lennart PS. There are other ways of getting empty types, but they are all convoluted, like data Empty = Empty !Empty
Re: Haskell 1.3: modules & module categories
>Date: Mon, 2 Oct 1995 05:53:44 -0400 >Reply-To: [EMAIL PROTECTED] >From: Manuel Chakravarty <[EMAIL PROTECTED]> > >> To me, one of the most regrettable characteristics of >> the Algolic family of languages is the tendency of the >> compiler to turn into a giant black box of facilities >> open only to an elite minority of compiler hackers, which >> then begins inexorably sucking the entire programming >> support environment down its event horizon. >> >> I would much prefer that the concept of "compiler" in this >> sense did not exist, and that instead one had a nicely >> factored translation toolset wide open to the application >> programmer. Lisp and Forth begin to approach this ideal. > > Would you mind divulging the identity of your hilarious correspondent? I got the impression that his original mail was distributed to the whole Haskell mailing list. Anyway, I append it at this message. Cheers, Manuel P.S.: As it seems that there are a number of people who didn't get the mail I responded to, I CC this to the whole mailing list. Sorry, for any duplicates. --- Date: Sat, 30 Sep 1995 10:09:08 -0700 From: [EMAIL PROTECTED] (Jeff Prothero) To: [EMAIL PROTECTED] Subject: Re: Haskell 1.3: modules & module categories Cc: [EMAIL PROTECTED] Manuel Chakravarty <[EMAIL PROTECTED]> writes: | [...] it is desirable to be able to | restrict the access to some modules in a way that the | compiler can control when a group of people is working | in one module hierarchy. Too illustrate this, assume | that we classify the modules into different levels of | abstraction, say, three levels: [...] To me, one of the most regrettable characteristics of the Algolic family of languages is the tendency of the compiler to turn into a giant black box of facilities open only to an elite minority of compiler hackers, which then begins inexorably sucking the entire programming support environment down its event horizon. I would much prefer that the concept of "compiler" in this sense did not exist, and that instead one had a nicely factored translation toolset wide open to the application programmer. Lisp and Forth begin to approach this ideal. At the least, it would be very nice if the compiler could be kept distinct enough from the rest of the programming support environment that it doesn't begin sucking what sound to me like logically separate project management concerns (above) into its orbit. Would it be possible to define an interface which allows the above sort of "Not if you're a left-handed programmer and it's Tuesday" restrictions to be separately implemented and kept out of the core language? (To my mind, one of the successes of C -- as distinct from C++, say -- is that it clearly defined what was and wasn't the task of the compiler, and stuck to its guns, resulting in that very rare bird: An Algolic language with a stable language definition and compiler.)
Re: Haskell 1.3: modules & module categories
Date: Mon, 2 Oct 1995 05:53:44 -0400 Reply-To: [EMAIL PROTECTED] From: Manuel Chakravarty <[EMAIL PROTECTED]> > To me, one of the most regrettable characteristics of > the Algolic family of languages is the tendency of the > compiler to turn into a giant black box of facilities > open only to an elite minority of compiler hackers, which > then begins inexorably sucking the entire programming > support environment down its event horizon. > > I would much prefer that the concept of "compiler" in this > sense did not exist, and that instead one had a nicely > factored translation toolset wide open to the application > programmer. Lisp and Forth begin to approach this ideal. Would you mind divulging the identity of your hilarious correspondent? David
Re: Haskell 1.3: modules & module categories
> > With present Haskell modules, it seems that `with' > > automatically comes with `use' and clutters up your namespace. > > That's why you sometimes need re-naming when importing. Sorry, I missed that one. Manuel pointed out that with/use is already contained in the `qualified names'-proposal. When I'm comparing Haskell to Ada, it seems that basically import Foo = with Foo; use Foo; import qualified Foo= with Foo; Still I'd like to have Ada's `use' on its own, as in with Text_Io; package Foo is ... procedure Bar is use Text_Io; begin ... end; ... end Foo; And while we're at it, what about - nested modules - with possibly private sub-modules similar to the Ada(-95) things. -- Johannes Waldmann, Institut f\"ur Informatik, UHH, Jena, D-07740 Germany, (03641) 630793 [EMAIL PROTECTED] http://www.minet.uni- jena.de/~joe/ ... Im naechsten Heft: Als Arbeiter in einer Radiofabrik - Freundschaft mit dem Sohn eines Luftwaffengenerals - Das KGB ueberwacht den Amerikaner auf Schritt und Tritt - Alarmierende Verdachtsmomente bei der Kaninchenjagd - Ungluecklich verliebt in eine rothaarige Juedin
Re: Haskell 1.3: modules & module categories
Has the Ada solution been properly considered? What I really like about Ada packages is that you have `with' and `use' as separate operations (on namespaces). Typical (simplified) examples are: Put_Line ("Foo."); -- won't work with Text_Io; Text_Io.Put_Line ("Foo."); -- will work with Text_Io; Put_Line ("Foo."); -- won't work with Text_Io; use Text_Io; Put_Line ("Foo."); -- will work use Text_Io; Put_Line ("Foo."); -- won't work That is, `with Bar' makes module Bar's namespace accessible, but prefixed with that module's name. On the other hand, `use Bar' adds `Bar.' to a set of default prefixes that are tried when looking up names from then on. If an ambiguity arises, the compiler complains. You may resolve this by using the prefixed name. You can only `use' what you have `with'ed, and all `with's have to go at the very start of a module, so you (or a configuration management system) can easily check on what packages your code depends. With present Haskell modules, it seems that `with' automatically comes with `use' and clutters up your namespace. That's why you sometimes need re-naming when importing. (As I'm mostly using Gofer/Hugs, you may imagine that I'm not so sure about Haskell modules. However, I _do_ like the Ada solution. Please correct me if the above is basically wrong or inapplicable.) -- Johannes Waldmann, Institut f\"ur Informatik, UHH, Jena, D-07740 Germany, (03641) 630793 [EMAIL PROTECTED] http://www.minet.uni- jena.de/~joe/ ... Im naechsten Heft: Als Arbeiter in einer Radiofabrik - Freundschaft mit dem Sohn eines Luftwaffengenerals - Das KGB ueberwacht den Amerikaner auf Schritt und Tritt - Alarmierende Verdachtsmomente bei der Kaninchenjagd - Ungluecklich verliebt in eine rothaarige Juedin
Re: Haskell 1.3: modules & module categories
> To me, one of the most regrettable characteristics of > the Algolic family of languages is the tendency of the > compiler to turn into a giant black box of facilities > open only to an elite minority of compiler hackers, which > then begins inexorably sucking the entire programming > support environment down its event horizon. > > I would much prefer that the concept of "compiler" in this > sense did not exist, and that instead one had a nicely > factored translation toolset wide open to the application > programmer. Lisp and Forth begin to approach this ideal. I am a bit puzzled about this statement. I used to think about Lisp environments just in the same way that you characterize the compilers for Algol-style languages. The typical Common Lisp environment is one big engine with thousands of features and it takes a rather long time to get to the status of an experienced user. Maybe it is a matter of familiarity with either style of environment. > Would it be possible to define an interface which > allows the above sort of "Not if you're a left-handed > programmer and it's Tuesday" restrictions to be > separately implemented and kept out of the core > language? I am not sure if you can separate these issues, but there is one important requirement. There must not be an easy or even moderately difficult way to circumvent the restrictions. As they say, there is always a bad programmer in your team. Cheers, Manuel
Re: Haskell 1.3: modules & module categories
If you could email me the piece of code you are having this problem, I can look at it and try to see what is wrong. -- Ming
Re: Haskell 1.3
JL writes, A formal treatment of parametricity in the presence of overloading has not been written up (Eric Meijer has talked of doing so). The problem with writing it up is that it's too simple: it reduces to a single observation, namely that the parametricity theorem coming from an overloaded type is the regular parametricity theorem that arises after performing the dictionary expansion. You can find this observation in Section 3.4 of the original `Theorems for Free'. So it is written up! -- P
Re: Haskell 1.3 (newtype)
Sebastian suggests using some syntax other than pattern matching to express the isomorphism involved in a newtype. I can't see any advantage in this. Further, Simon PJ claims that if someone has written data Age = Age Int foo (Age n) = (n, Age (n+1)) that we want to be able to make a one-line change newtype Age = Age Int leaving all else the same: in particular, no need to add twiddles, and no changes of the sort Sebastian suggests. I strongly support this! (No, Simon and I are not in collusion; indeed, we hardly ever talk to each other! :-) Cheers, -- P
Re: Haskell 1.3 (newtype)
In a recent message Sebastian Hunt suggests a solution to the 'newtype' problem. Let me recall another approach which can cure several things at a time (probably introducing new problems though). Some time ago Mark Jones wrote a paper " From Hindley-Milner Types to Modular Structures". He suggested introducing record types like type Point = {x,y: Real} If we define records to be unlifted then the type Int and {int: Int} will be isomorphic and there is no reason to introduce a special 'newtype' syntax. There is a problem with class instances - type synonyms are not allowed there. May be, the restriction could be relaxed to allow types defined as structures to be subject to instantiating. It's worth noting that with Mark's ideas the records of the 1.3 proposal can be replaced by something more general - another step forward. I don't like neither 'newtype' nor the records of Haskell 1.3. Both mean a lot of syntax with little semantics. Even if Mark's ideas seem premature at this stage it's worth working on them and not introducing some bad syntax to be withdrawn from the language later. Removing even the worst syntax >from a language is always a painful process, vide the n+k patterns. Rysiek PS. I've written the above without Mark's permit. Sorry, Mark, it was too difficult for me to wait...
Re: Haskell 1.3 (newtype)
I think that the following points have emerged from the recent discussion about the proposed newtype declaration: 1) Pattern matching against strict constructors will result in functions which are strict in the annotated constructor argument. For example: data T = A !Int f :: T -> Bool f (A n) = True results in f such that f (A undefined) = undefined This results in a loss of referential transparency because, before we can replace f (A e) by True, we must check that e is not undefined. Of course, a transformation in this direction can only make a program more defined, so perhaps we should be more worried by the fact that it would be unsafe to replace True by f (A e), in general. 2) It would be wrong to define the proposed newtype N = B G declaration as being equivalent to data N = B !G because a) it will restrict its use to G such that !G makes sense, and b) programmers will be tripped up by the strict pattern matching semantics above. On reflection, I think I agree with point 2, so if the proposed newtype syntax is adopted it will need to be given a semantics independently of that of strict constructors, as Simon has described. On the other hand, it also seems to me that the reason this discussion started is that the proposed newtype syntax hijacks the constructor syntax for a new purpose: the definition of an isomorphism. Since the declaration newtype N = B G means "let N be isomorphic to G and let B :: G -> N be one half of the isomorphism" it is clear that B is not a constructor in the usual sense at all. In Haskell and its antecedents (though not in the general setting of term rewriting systems) it is well established that for f (B e) = ... to be legal, B must be a constructor (with the consequence that f is strict). The proposed newtype syntax is a significant departure from this. Would it really be so inconvenient if pattern matching couldn't be used for the iso from G to N? How about a syntax which made both halves of the isomorphism explicit? newtype in :: N <-> G :: out The example from the earlier postings would then be rendered as newtype in :: Arg <-> Int :: out foo :: Arg -> (Int, Arg) foo a = (n, in (n + 1)), where n = out a Implementations would be free to implement in and out as id foo a = (n, id (n + 1)), where n = id a and then magic them away foo a = (a, a + 1) Sebastian Hunt
Re: Haskell 1.3 (newtype)
Phil says: | I think its vital that users know how to declare a new isomorphic | datatype; it is not vital that they understand strictness declarations. | Hence, I favor that | | newtype Age = Age Int | data Age = Age !Int | | be synonyms, but that both syntaxes exist. | | This is assuming I have understood Lennart correctly, and that | | foo (Age n) = (n, Age (n+1)) | foo' a = (n, Age (n+1)) where (Age n) = a | | are equivalent when Age is declared as a strict datatype. Unlike | Sebastian or Simon, I believe it would be a disaster if for a newtype | one had to distinguish these two definitions. I agree that it is rather undesirable for them to differ. If someone had declared a *non-strict* verion like this: data Age = Age Int foo (Age n) = (n, Age (n+1)) (where foo is patently non-strict in n), and then just wanted to say "do away with the Age constructor", I'd like it to be a one-line change (data --> newtype), rather than also having to add a twiddle to every pattern-match: foo ~(Age n) = (n, Age (n+1)) [which is eqiuvalent to using a where binding] In effect, newtype could be explained as (a) a data decl with a !, and (b) adding a ~ to every pattern match. This is a hard one to call: which version actually requires least explanation?! Simon
Re: Haskell 1.3 (newtype)
On Wed, 13 Sep 1995 [EMAIL PROTECTED] wrote: > Well, I'm glad to see I provoked some discussion! ... > Why should foo evaluate its argument? It sounds to me like > Lennart is right, and I should not have let Simon lead me astray! ... > This is assuming I have understood Lennart correctly, and that > > foo (Age n) = (n, Age (n+1)) > foo' a = (n, Age (n+1)) where (Age n) = a > > are equivalent when Age is declared as a strict datatype. Unlike > Sebastian or Simon, I believe it would be a disaster if for a newtype > one had to distinguish these two definitions. I don't see how these two can be equivalent, unless a special case is made in the semantics for data types with a single constructor when the constructor happens to be strict. Consider data G = F !Int | D Int f :: G -> Bool f (D _) = True f (F _) = False If Lennart is right about foo, doesn't it follow that f (D undefined) = True? In which case, since D is strict, we have f undefined = f (D undefined) = True and so, by monotonicity of f, f v = True for all v and, in particular, f (F e) = True This can't be right, surely? Sebastian
Re: Haskell 1.3 (newtype)
Well, I'm glad to see I provoked some discussion! Simon writes: Lennart writes: | So if we had | |data Age = Age !Int |foo (Age n) = (n, Age (n+1)) | | it would translate to | |foo (MakeAge n) = (n, seq MakeAge (n+1)) | | [makeAge is the "real" constructor of Age] Indeed, the (seq MakeAge (n+1) isn't eval'd till the second component of the pair is. But my point was rather that foo evaluates its argument (MakeAge n), and hence n, as part of its pattern matching. Hence foo is strict in n. Why should foo evaluate its argument? It sounds to me like Lennart is right, and I should not have let Simon lead me astray! I think its vital that users know how to declare a new isomorphic datatype; it is not vital that they understand strictness declarations. Hence, I favor that newtype Age = Age Int data Age = Age !Int be synonyms, but that both syntaxes exist. This is assuming I have understood Lennart correctly, and that foo (Age n) = (n, Age (n+1)) foo' a = (n, Age (n+1)) where (Age n) = a are equivalent when Age is declared as a strict datatype. Unlike Sebastian or Simon, I believe it would be a disaster if for a newtype one had to distinguish these two definitions. Cheers, -- P
Re: Haskell 1.3 (newtype)
Lennart writes: | So if we had | | data Age = Age !Int | foo (Age n) = (n, Age (n+1)) | | it would translate to | | foo (MakeAge n) = (n, seq MakeAge (n+1)) | | [makeAge is the "real" constructor of Age] | | Now, surely, seq does not evaluate its first argument when the | closure is built, does it? Not until we evaluate the second component | of the pair is n evaluated. Indeed, the (seq MakeAge (n+1) isn't eval'd till the second component of the pair is. But my point was rather that foo evaluates its argument (MakeAge n), and hence n, as part of its pattern matching. Hence foo is strict in n. Sebastian writes: | Is it really a good idea to extend the language simply to allow foo and | foo' to be equivalent? The effect of foo' can still be achieved if Age is | a strict data constructor: | | data Age = Age !Int | | foo'' :: Age -> (Int, Age) | foo'' a = (n, Age (n+1)) where (Age n) = a | | and compilers are free (obliged?) to represent a value of type Age by an | Int. Indeed, it's true that foo'' does just the right thing. Furthermore, I believe it's true that given the decl data T = MkT !S the compiler is free to represent a value of type T by one of type S (no constructor etc). Here are the only real objections I can think of to doing "newtype" via a strict constructor. None are fatal, but they do have a cumulative effect. 1. It requires some explanation... it sure seems a funny way to declare an ADT! 2. The programmer would have to use let/where bindings to project values >from the new type to the old, rather than using pattern matching. Perhaps not a big deal. 3. We would *absolutely require* to make (->) an instance of Data. It's essential to be able to get data T = MkT !(Int -> Int) 4. We would only be able to make a completely polymorphic "newtype" if we added a quite-spurious Data constraint, thus: data Data a => T a = MkT !a (The Data is spurious because a value of type (T a) is going to be represented by a value of type "a", and no seqs are actually going to be done.) 5. We would not be able to make a newtype at higher order: data T k = MkT !(k Int) because there's no way in the language to say that (k t) must be in class Data for all t. [This is a somewhat subtle restriction on where you can put strictness annotations, incidentally, unless I've misunderstood something.] Simon
Re: Haskell 1.3 (Bounded;fromEnum;type class synonyms)
Dear Sverker Nilsson, Thanks for your message - interesting ideas and interesting questions. [I'm copying the reply to the Haskell mailing list in case anyone wishes to support your suggestions.] First, one of Haskell's annoying features is that the scope of a type variable in a type signature or instance heading only extends over the signature. So, when you want to write: > instance (FromInt a, ToInt a, MinVal a, MaxVal a) => Enum a where > enumFrom c = map fromInt [toInt c .. toInt (maxVal :: a)] It doesn't work (because the "a" isn't in scope during the declarations) - you have to use "asTypeOf" instead: > instance (FromInt a, ToInt a, MinVal a, MaxVal a) => Enum a where > enumFrom c = map fromInt [toInt c .. toInt (maxVal `asTypeOf` c)] While developing something like the proposed "Bounded" class, you introduced separate classes for minVal and maxVal observing: > Something having a minimum value, in my view, didn't necessarily > imply it would have a maximum value. Yes, perfectly true. The best example is that there's a minimal list (the empty list) but even though there's a maximal Char (say), there's no maximal list of characters. Our primary motivation for adding Bounded is to clean up the {min,max}{Char,Int} situation and make the derived Enum instances slightly more regular (similar in spirit to your definitions above). For this purpose, insisting on having both a min and a max isn't a problem. However, for other purposes, having one bound but not the other is certainly possible and maybe useful. (I agree that defining a bogus instance in which "minVal" (say) is defined but "maxVal" is undefined or has a bogus value is at least untidy and at worst a bug waiting to happen. I tried (and failed) to get the Text instance of (a -> b) removed from the Prelude for this reason.) The major disadvantage of separating the two is that it introduces even more classes. If you read the preludechanges document carefully, you'll see that (even at this late stage) these are only proposed changes. Glasgow argue that it's hard enough to keep Ix and Enum separate in your mind - adding another can only worsen things. You were then surprised and disturbed to find that this isn't legal Haskell: > class (MinVal a, MaxVal a)=>Bounded a > > instance Bounded T where >maxVal = T3 >minVal = T1 There was a proposal to make this legal. As far as I know, there's no technical problems here - I guess it just got forgotten about (or the proposer decided that Haskell 1.3 had too many changes in it already!) > * Should Bounded be derived from Ord? > > The Bounded class that was suggested for Haskell 1.3 was derived from > Ord. Myself playing with similar things I derived MinVal and MaxVal > from nothing - I thought this more general. Maybe the reason for > having Bounded derived from Ord was to imply that its functions shall > satisfy certain laws, probably as being min/max as defined by the > ordering functions in Ord. But as I don't see how this can be > guaranteed by deriving Bounded from Ord, I would think that it could > as well be standalone (or derived from something like MinBound and > MaxBound if possible); for more generality and less dependency between > the classes in the system. Yes, the sole reason is because it seemed tidier to specify Ord - without knowing which comparision is being used, it doesn't make much sense to say you have a "maximum value". > For example, the new proposal says: > > > ... > > Programmers are free to define a class for partial orderings; here, we > > simply state that Ord is reserved for total orderings. > > That seems to imply also that a programmer should not use Bounded on > types that have no total ordering. I believe this might be an unnecessary > restriction. It certainly looks that way. > > The names fromEnum and toEnum are misleading since > > their types involve both Enum and Bounded. We couldn't face writing > > fromBoundedEnum and toBoundedEnum. Suggestions > > welcome. > > Maybe names like ToInt and FromInt could be used for this? > > How about the following, assuming the proposed diff and succ functions: > > class (Bounded a, Enum a) => ToInt a where toInt :: a -> Int [...] > class (Bounded a, Enum a) => FromInt a where fromInt :: Int -> a [...] These names look good. Three _minor_ concerns: 1) It introduces even more standard classes to confuse programmers with. Why allow the programmer to override them? 2) Several implementations have added a non-standard method fromInt :: Int -> a to the Num class to avoid unnecessary uses of fromInteger. However, I think most normal uses would work unchanged if "fromInt" had type: fromInt :: (Bounded a, Enum a) => Int -> a 3) There is a weak tradition of putting the name of the class into the name of the method. This tradition is often broken when it would get in the way of a good name. Action: 1) I'll remove the Ord c
Re: Haskell 1.3 (newtype)
On Tue, 12 Sep 1995, Lennart Augustsson wrote: > The posted semantics for strict constructors, illustrated by this example > from the Haskell 1.3 post, is to insert seq. > > > data R = R !Int !Int > > > > R x y = seq x (seq y (makeR x y)) -- just to show the semantics of R > > So if we had > > data Age = Age !Int > foo (Age n) = (n, Age (n+1)) > > it would translate to > > foo (MakeAge n) = (n, seq MakeAge (n+1)) > > [makeAge is the "real" constructor of Age] I had assumed (as Simon seems to) that the semantics of pattern matching against a strict constructor would accord with the following: 1. matching a simple pattern involves evaluating the expression being matched to the point that its outermost constructor is known 2. for strict constructors this must result in the annotated constructor argument(s) being evaluated >From what Lennart says, this is not the intended semantics. So what *is* the intended semantics? Sebastian Hunt
Re: Haskell 1.3 (Bounded;fromEnum;type class synonyms)
* Playing around, learning the basics, reinventing the wheel... I had been playing around with some classes, primarily to learn for myself, being new to the Haskell language, when I got the report on the current status of Haskell 1.3. The classes I had played with had some similarities to some of the proposals for the new prelude, yet I had made it in a quite different way. Trying to combine the two styles, I ran into an unexpected problem. This problem I am naive enough to believe could be solved by a simple language extension. Using Gofer, I had made some classes that could be used for implementing ordering and other things for enumeration (data T=T1 | T2 | T3) types but not restricted to those. I made 4 minimal classes with just 1 function in each. (I thought this would be most general. Something having a minimum value, in my view, didn't necessarily imply it would have a maximum value.) So: class FromInt a where fromInt:: Int->a class ToInt a where toInt:: a->Int class MaxVal a where maxVal:: a class MinVal a where minVal:: a -- I then used this as follows: data T = T1 | T2 | T3 instance ToInt T where toInt e = case e of T1 -> 1 T2 -> 2 T3 -> 3 instance Eq T where a == b = toInt a == toInt b instance Ord T where a <= b = toInt a <= toInt b -- And so on. The MaxVal and MinVal classes also where used to make a generic -- implementation of a bounded Enum class, generalizing how it was made in the -- Gofer prelude for Char: instance (FromInt a, ToInt a, MinVal a, MaxVal a) => Enum a where enumFrom c = map fromInt [toInt c .. toInt (maxVal `asTypeOf` c)] enumFromThen c c' = map fromInt [toInt c, toInt c' .. toInt (lastVal `asTypeOf` c)] where lastVal = if c' < c then minVal else maxVal -- This worked to my great delight! And I had began to learn the basics -- of the type system in Haskell. My only problem was that I had to use -- (maxVal `asTypeOf` c) instead of (maxVal::a). I believe the reason -- for this might be clear when I learn more. Somebody have a clue? * Running into a problem: type class synonyms are not synonymous? Then, I got the report on the developments of Haskell 1.3 and began to read it with great curiosity. I then found the Bounded class, containing corresponding functions to MinVal and MaxVal. A question then occured to me: Why not have separate classes as I had done? Would not that perhaps be more general, increasing the possibilities for reuse? (Without having to stub out one of minBound or maxBound if you use it for a type without one of them.) On the other hand, I saw the convenience of having both minBound and maxBound in the same class, decreasing the number of classes that have to be mentioned in various cases. But I thought, then, why not derive the Bounded class >from MinVal and MaxVal - would not that then be equivalent? So I tried class (MinVal a, MaxVal a)=>Bounded a -- This was allowed, but then... instance Bounded T where maxVal = T3 minVal = T1 -- That didn't work! (Gofer said: ERROR "tst.gs" (line 45): No member "maxVal" in class "Bounded") Maybe I had done something wrong, or Gofer does not allow something that would be allowed in Haskell? I suspect however that I am simply not supposed to do this in either Haskell or Gofer... Instead I had to use two separate instantiaions, exactly as before I declared the Bounded class: instance MinVal T where minVal = T1 instance MaxVal T where maxVal = T3 This seems to be somewhat unnecessary, wouldn't it be quite possible for a compiler to transform the instantiation of Bounded to the two instantiations of MinVal and MaxVal? Maybe this would be a useful development of Haskell? * Should Bounded be derived from Ord? The Bounded class that was suggested for Haskell 1.3 was derived from Ord. Myself playing with similar things I derived MinVal and MaxVal >from nothing - I thought this more general. Maybe the reason for having Bounded derived from Ord was to imply that its functions shall satisfy certain laws, probably as being min/max as defined by the ordering functions in Ord. But as I don't see how this can be guaranteed by deriving Bounded from Ord, I would think that it could as well be standalone (or derived from something like MinBound and MaxBound if possible); for more generality and less dependency between the classes in the system. For example, the new proposal says: > ... > Programmers are free to define a class for partial orderings; here, we > simply state that Ord is reserved for total orderings. That seems to imply also that a programmer should not use Bounded on types that have no total ordering. I believe this might be an unnecessary restriction. * Can toInt be fromEnum and toEnum fromInt? New functions fromEnum and toEnum were proposed to be added
Re: Haskell 1.3 (lifted vs unlifted)
John Hughes mentioned a deficiency of Haskell: OK, so it's not the exponential of a CCC --- but Haskell's tuples aren't the product either, and I note the proposal to change that has fallen by the wayside. and Phil Wadler urged to either lift BOTH products and functions, or none of them. My two pence: If functions/products are not products and exponentials of a CCC, you should aim for the next best thing: an MCC, a monoidal closed category. But Haskell's product isn't even monoidal: There is no type I such that A*I and A are isomorphic. The obvious candidate (in a lazy language) would be the empty type 0, but A*0 is not isomorphic to A but to the lifting of A. Another problem: the function space A*B -> C should be naturally isomorphic to A -> (B -> C). What does the iso look like? One half is the obvious curry function: curry f x y = f(x,y) But what is the other half? Apparently, it should be either uncurry1 f (x,y) = f x y or uncurry2 f (~(x,y)) = f x y Which one is right depends on which one establishes the isomorphism. Consider the definition f1 (x,y) = () Now: uncurry1 (curry f1) undef = undef = f1 undef while on the other hand: uncurry2 (curry f1) undef = curry f1 (p1 undef, p2 undef) = f1(p1 undef,p2 undef) = () =/= f1 undef This suggests that uncurry2 is wrong and uncurry1 is right, but for f2 (~(x,y)) = () the picture is just the other way around. BTW It doesn't help to employ "seq" in the body of curry. Looks rather messy. Can some of this be salvaged somehow? -- Stefan Kahrs
Re: Haskell 1.3 (newtype)
Simon, I think you're mistaken. Simon writes: > > newtype Age = Age Int > > foo :: Age -> (Int, Age) > foo (Age n) = (n, Age (n+1)) > > Now, we intend that a value of type (Age Int) should be represented by > an Int. Thus, apart from the types involved, the following program should > be equivalent: > > type Age' = Int > > foo' :: Age' -> (Int, Age') > foo' n = (n, n+1) > > So is foo' strict in n? No, it isn't. What about foo? If newtype is just a > strict data constructor, then it *is* strict in n. The posted semantics for strict constructors, illustrated by this example >from the Haskell 1.3 post, is to insert seq. > data R = R !Int !Int > > R x y = seq x (seq y (makeR x y)) -- just to show the semantics of R So if we had data Age = Age !Int foo (Age n) = (n, Age (n+1)) it would translate to foo (MakeAge n) = (n, seq MakeAge (n+1)) [makeAge is the "real" constructor of Age] Now, surely, seq does not evaluate its first argument when the closure is built, does it? Not until we evaluate the second component of the pair is n evaluated. The other behaviour of strict constructors would worry me since we would loose referential transparency. I'm not opposing newtype, but an ordinary datatype with one constructor with one strict argument is very similar. The only way to distinguish them (and it is debatable if this is what you want) is like this data T = T !Int f (T _) = True newtype T' = T' Int f' (T' _) = True Now we get f undefined ==> undefined f' undefined ==> True -- Lennart
Re: Haskell 1.3 (newtype)
On Tue, 12 Sep 1995, Simon L Peyton Jones wrote: > > > Phil writes: > > | Make newtype equivalent to a datatype with one strict constructor. > | Smaller language, more equivalences, simpler semantics, simpler > | implementation. An all around win! > > I believe it would be a mistake to do this! Consider: > > newtype Age = Age Int > > foo :: Age -> (Int, Age) > foo (Age n) = (n, Age (n+1)) > > Now, we intend that a value of type (Age Int) should be represented by > an Int. Thus, apart from the types involved, the following program should > be equivalent: > > type Age' = Int > > foo' :: Age' -> (Int, Age') > foo' n = (n, n+1) Is it really a good idea to extend the language simply to allow foo and foo' to be equivalent? The effect of foo' can still be achieved if Age is a strict data constructor: foo'' :: Age -> (Int, Age) foo'' a = (n, Age (n+1)) where (Age n) = a and compilers are free (obliged?) to represent a value of type Age by an Int. It might even be rather confusing if foo were not strict, given that it appears to pattern match on its argument. (Of course, you could equally argue that it is confusing that case Foo undefined of Foo _ -> True = undefined in a lazy language, but that can't be helped if strict constructors are allowed - unless some lexical distinction is introduced, eg strict constructor names must start with `!'.) Why not keep things simple and, as Ryszard Kubiak suggests, abandon the newtype syntax altogether? Sebastian Hunt
Re: Haskell 1.3 (newtype)
In a recent message Phil Wadler argues: > ... > Make newtype equivalent to a datatype with one strict constructor. > Smaller language, more equivalences, simpler semantics, simpler > implementation. An all around win! I strongly agree with Phil and suggest that because of the equivalences the extra syntax for 'newtype' is simply omitted. It doesn't make sense to have syntax with so little semantic significance. Regards, Rysiek
Re: Haskell 1.3 (newtype)
Simon offers a compelling reason to make newtype distinct from a strict datatype with one constructor. And a semantics to boot! I withdraw my objection. -- P PS. The informal explanation might be modified to explain why newtype must be distinct from a strict datatype. strict datatype case Foo undefined of Foo _ -> True = undefined newtype case Foo undefined of Foo _ -> True = True The latter must be the right thing to do (as pointed out by Simon) because removing Foo should not change the meaning: case undefined of _ -> True = True Cheers, -- P
Re: Haskell 1.3 (newtype)
Phil writes: | By the way, with `newtype', what is the intended meaning of | | case undefined of Foo _ -> True ? | | I cannot tell from the summary on the WWW page. Defining `newtype' | in terms of `datatype' and strictness avoids any ambiguity here. | | Make newtype equivalent to a datatype with one strict constructor. | Smaller language, more equivalences, simpler semantics, simpler | implementation. An all around win! I believe it would be a mistake to do this! Consider: newtype Age = Age Int foo :: Age -> (Int, Age) foo (Age n) = (n, Age (n+1)) Now, we intend that a value of type (Age Int) should be represented by an Int. Thus, apart from the types involved, the following program should be equivalent: type Age' = Int foo' :: Age' -> (Int, Age') foo' n = (n, n+1) So is foo' strict in n? No, it isn't. What about foo? If newtype is just a strict data constructor, then it *is* strict in n. Here's what I wrote a little while ago: "This all very well, but it needs a more formal treatment. As it happens, I don't think it's difficult. In the rules for case expressions (Fig 3 & 4 in the 1.2 report) we need to say that the *dynamic* semantics of case e of { K v -> e1; _ -> e2 } is let v = e in e1 if K is the constructor of a "newtype" declaration. (Of course this translation breaks the static semantics.) Similarly, the dynamic semantics of (K e) is just that of "e", if K is the constructor of a "newtype" decl." Does that make the semantics clear, Phil? Simon
Re: Haskell 1.3 (newtype)
The design of newtype appears to me incorrect. The WWW page says that declaring newtype Foo = Foo Int is distinct from declaring data Foo = Foo !Int (where ! is a strictness annotation) because the former gives case Foo undefined of Foo _ -> True = True and the latter gives case Foo undefined of Foo _ -> True = undefined. Now, on the face of it, the former behaviour may seem preferable. But trying to write a denotational semantics is a good way to get at the heart of the matter, and the only way I can see to give a denotational semantics to the former is to make `newtype' define a LIFTED type, and then to use irrefutable pattern matching. This seems positively weird, because the whole point of `newtype' is that it should be the SAME as the underlying type. By the way, with `newtype', what is the intended meaning of case undefined of Foo _ -> True ? I cannot tell from the summary on the WWW page. Defining `newtype' in terms of `datatype' and strictness avoids any ambiguity here. Make newtype equivalent to a datatype with one strict constructor. Smaller language, more equivalences, simpler semantics, simpler implementation. An all around win! Cheers, -- P
Re: Haskell 1.3 (lifted vs unlifted)
To the Haskell 1.3 committee, Two choices in the design of Haskell are: Should products be lifted? Should functions be lifted? Currently, the answer to the first is yes, and to the second is no. This is ad hoc in the extreme, and I am severely embarrassed that I did not recognise this more clearly at the time we first designed Haskell. Dear committee, I urge you, don't repeat our earlier mistakes! John Hughes makes a compelling case for yes; and mathematical cleanliness makes a compelling case for no. I slightly lean toward yes. (John is a persuasive individual!) But unless someone presents a clear and clean argument for answering the two questions differently, please answer them consistently. If both questions are answered yes, then there is a choice as to whether or not to have a Data class. Indeed, there are two choices: Should polymorphic uses of seq be marked by class Data? Should polymorphic uses of recursion be marked by class Rec? John Launchbury and Ross Paterson have written a beautiful paper urging yes on the latter point; ask them for a copy. Here, I have a mild preference to answer both questions no, as I think the extra complication is not worthwhile. But again, please answer them consistently. Cheers, -- P
Re: Haskell 1.3
Let me make one more attempt to persuade the committee to change the way strictness annotations are to be introduced. First of all, let's recognise that strictness annotations and the seq function are of enormous importance; this is a vital extension to the language, not a small detail. Space debugging consists to quite a large extent of placing applications of seq correctly, and we all know what dramatic effects space debugging has been able to achieve. The strictness features are going to be very heavily used in the future. Recording uses of polymorphic strictness annotations using class Data has both advantages and disadvantages. A big disadvantage is that curing a space bug may change the types of many functions in many modules, which at the least may require a lot of recompilation. The programmer who likes to state the type of each function will be especially hard hit, of course, which will unfortunately discourage such a style. But class Data seems to be vital for cheap deforestation, which is such an important optimisation as to outweigh the disadvantages. However, it is an independent question whether or not strictness annotations should be applicable to function types. And this is where I disagree with the committee. To quote `Introducing Haskell 1.3', Every data type, except ->, is a member of the Data class. In other words, in Haskell 1.3 FUNCTIONS ARE NOT FIRST-CLASS CITIZENS To design a functional language today, in which this is true, is in my view deeply mistaken. In the past, I've argued that it will be very frustrating for those programmers who do discover they need to apply seq to a function in order to cure a space bug, to find that they are unable to do so. Even more seriously, programmers weighing up a choice of representation for an abstract datatype, choosing between a representation as a function or as a `Data' type, will know that if they choose the function then problems with space debugging may lurk in the future. Excluding (->) from class Data is a step away from true `functional' programming towards a style in which higher-order functions are just a kind of macro. I see a very great cost in such a philosophical change, and I do not see that the arguments against strictly evaluating function values are so very compelling. Implementation difficulties? hbc has provided it for years, and even under the STG machine is the problem so very much harder than handling shared partial applications correctly? Semantic difficulties? The semantics of lifted function spaces are perfectly well defined. OK, so it's not the exponential of a CCC --- but Haskell's tuples aren't the product either, and I note the proposal to change that has fallen by the wayside. Weaker strictness analysis? I'd like to hear the effect quantified. How much slower will Haskell 1.3 run if function spaces are lifted in the semantics? Will it be measurable? I'm prepared to pay a few percent. So here's my proposal: change `Introducing Haskell 1.3' to read Every data type, including ->, is a member of the Data class. John Hughes
Re: Haskell 1.3
I would like to respond to John's note. My response is largely positive, though I disagree with a couple of points. >However, it is an independent question whether or not strictness annotations >should be applicable to function types. And this is where I disagree with >the committee. To quote `Introducing Haskell 1.3', > >Every data type, except ->, is a member of the Data class. > >In other words, in Haskell 1.3 > >FUNCTIONS ARE NOT FIRST-CLASS CITIZENS I cannot agree here. Functions are not members of the equality class either, but that does not demote them to second class citizens. However, John may be right in suggesting that people will become more reluctant to use functions as values if they cannot force their evaluation. >I see a very great cost in such a philosophical change, and I do not see >that the arguments against strictly evaluating function values are so very >compelling. > > Implementation difficulties? hbc has provided it for years, and > even under the STG machine is the problem so very much harder than handling > shared partial applications correctly? I haven't checked hbc, but I would be interested if someone would confirm that function strictify works properly. It didn't use to in LML. > Semantic difficulties? The semantics of lifted function spaces are > perfectly well defined. OK, so it's not the exponential of a CCC --- but > Haskell's tuples aren't the product either, and I note the proposal to > change that has fallen by the wayside. This is probably an important point. I see there being value in two sorts of functions: lifted and non-lifted (or equivalently boxed and unboxed). A lifted function may be expressed as a computation which delivers a function, just like lifted integers are computations which deliver integers. Under this view it would be entirely in keeping with the rest of Haskell for the standard functions to be lifted, and to leave open the possibility in the future of introducing unlifted functions. >So here's my proposal: change `Introducing Haskell 1.3' to read > >Every data type, including ->, is a member of the Data class. I am inclined to agree. Is there a problem then that every type is in Data? Not at all. The Data class indicates that forcing has been used in the body of an expression. This is valuable information that is exposed in the type. John.
Re: Haskell 1.3 Draft Report
Hi. For the TeX-impaired, is there any chance of sticking postscript files on an ftp site? Thanks! -- Dave >A draft of the Haskell 1.3 report is available by FTP from >ftp.dcs.glasgow.ac.uk [130.209.240.50] in > > pub/haskell/report/draft-report-1.3.dvi.gz [Report] > pub/haskell/report/draft-libraries-1.3.dvi.gz [Libraries] > >Highlights include: > > Monadic I/O > A split into prelude and libraries, with qualified names > Strict data types > Some minor syntactic revisions > >We are planning to revise this and release it in time for FPCA '95. >There will definitely be additional prelude and library changes; >including several new libraries. > >Feedback is welcome and will be taken into account when revising the >report, but please remember that we will be very busy over the next few >weeks (I am also away for the next two weeks!). Please mail typos., minor >notes on syntax etc. to me; substantive comments should be sent to >[EMAIL PROTECTED] > >Regards, >Kevin > > > -- Dave Bakin How much work would a work flow flow if a #include 510-922-5678work flow could flow work?
Re: Haskell 1.3
Ian Holyer writes: > To go back to the debate on instances, here is a concrete proposal for > handling instances in Haskell 1.3: I can see what you're doing, but I dislike the idea of no longer being able to define instances local to a module. This limits my choice of class and type names, and may cause problems when importing libraries defined by other users. For global (exported) instances your rules make sense (a variant of these was considered at one point) with the caveats marked below. > 1) A C-T instance can be defined in any module in which C and T are > in scope. Fine, in conjunction with 5 and 2 or similar constraints. > 2) A C-T instance defined in module M is in scope in every module which > imports from M, directly or indirectly. (If C or T are not in scope, a > module just passes the instance on in its interface). You need to ignore local C-T instances (i.e. those where a class C or type T is defined locally and not exported), otherwise mayhem could result. Local instances will now also cause problems if there is a global C-T instance defined in any importing module. The interface is problematic if a new class with local name C or type with local type T is defined (or both!), especially if there is a (local) C-T instance. Getting round this would involve being much more explicit about global names in interface files (e.g. an M1.C-M2.T instance). There is also potential name capture of type, class, or operator names by the importing module, which would require additional checking of interfaces import (something we would like to avoid for efficiency reasons). > 3) A C-T instance may be imported more than once via different routes, > provided that the module of origin is the same. This implies annotating instances with their module of origin, as you note below. > 4) If an application of an overloaded function is resolved locally, the > relevant instance must be in scope. ...a relevant instance must be in scope... ^ > 5) There must be at most one C-T instance defined in the collection of > modules which make up any one program (global resolution occurs in Main). There should be at most one global C-T instance defined (otherwise you lose the ability to create local types with instances)... You also shouldn't specify where resolution takes place. Link resolution is much faster... > I would like to see the origin of instances in interface files. My preference > from an implementers point of view would be something like: > >interface M1 whereinterface M3 where >import M2 (C(..))or import M2 (C(..)) >import M3 (T(..),fT) type T = ... >instance C T where f = fT instance C T where f = fT > > The name fT is invented while compiling M3 and passed around in interface > files, but not exported from them into implementation modules. As well as > specifying the origin of the instance, it gives the code generator something > to link to. This really isn't a problem for an implementation. We can always link to a hidden name derived from the unique C-T combination. Introducing magic names in an interface sounds like a *very bad* idea -- you might well accidentally capture a user- or Prelude-defined name. For example, class From where from :: Int -> [a] -> a instance From Int where from = ... introduces fromInt in the interface, which will clash with the Prelude name. interface M1 where import M2(C(...)) import M3(T(...)) import M4(instance M2.C M3.T) is probably closer to what's required. Regards, Kevin
Re: Haskell 1.3 [instances]
Ian Holyer writes: The current restriction that instances must be defined either in the class module or the type module is painful. LISTEN TO THIS MAN! Trying to use the module system in (what we imagined to be) a sensible way on the Glasgow Haskell compiler [which is written in Haskell] has been a nightmare. Take a pile of mutually-dependent modules, add the "instance virus" [instances go with the class or type, and you can't stop them...], and you have semi-chaos. All attempts to have export/import lists that "show what's going on" have been undermined by having to add piles of cruft to keep instancery happy. I would go for either of the following not-thought-through choices: * Instances travel with the *type*, not the class. 99% of the time, this is what we want. If your instance isn't going, add an explicit export of the type constructor. Possibly have a special case for instances of user-defined classes for Prelude types... * Make it so that imported instances whose class/type is out-of-scope may be silently ignored (i.e., an exception to the closure rule). For example, if I write "import Foo" and Foo's interface includes "instance Wibble Wobble" and none of my "imports" happen to bring "Wibble" (or "Wobble") into scope, then a compiler may drop this instance silently. It is not an error. (Of course, if you try to *use* such an instance, you will get an error downstream.) Of course, something that involves new syntax/extra machinery would also be fine. Will PS: Get rid of "default" declarations, too. No-one uses them. (Hi, Kevin!)
Re: Haskell 1.3 trivia
> How about removing the `where' from `module...where' and > `interface...where' ... > > The reason we used the "module...where" convention is to allow for > multiple modules to be included in one "file". Your proposal is > workable, but requires saying something extra about what terminates > a module. I agree, however, that having to write "where" all the > time is a pain (I still forget to put it in sometimes!), so perhaps > you could complete the proposal with the wording required to say when > a module ends. I suggest: *) remove the paragraph about top-level indenting from 1.5 *) change 5.2: script -> module1 module2 ... (n>=1) module -> { [header ; body] [;] } | { header[;] } | { body[;] } header -> { [moddecl ; impfix] [;] } | { moddecl[;] } | { impfix[;] } impfix -> { [impdecls ; fixdecls] [;]} | { impdecls[;] } | { fixdecls[;] } moddecl -> `module' modid [exports] body-> topdecls NB The form { ... [[fixdecls ;] topdecls [;]] } in the current syntax is inconsistent in disallowing {;} which other blocks in the syntax allow. *) change the text of 5.2 to correspond, and in particular change the second paragraph to: If the first lexeme in a module is not a {, then the layout rule applies for the top level of the module. Several modules may appear in one script. Each module ends when the `module' keyword of the next is encountered. An abbreviated form of module is permitted, which omits the moddecl. If this is used, the moddecl is assumed to be `module Main'. An abbreviated module may not appear in the same script as some unabbreviated modules. NB The first paragraph of 5.2 *already* uses the term body for the topdecls alone, in contradiction to the current syntax. *) do the same for interfaces in 5.3 (we don't want modules and interfaces in the same file, do we?) and change B.4, B.5, B.6 to match. Ian
Re: Haskell 1.3 trivia
How about removing the `where' from `module...where' and `interface...where' so that these become ordinary topdecls like the rest. This would mean that the convention about topdecls not having to be indented would no longer be an ugly exception, it would be more consistent with implicit main programs which have no introductory `where', and it would be more consistent with the fact that the natural break between the header and body of a module comes after the fixity decls. The reason we used the "module...where" convention is to allow for multiple modules to be included in one "file". Your proposal is workable, but requires saying something extra about what terminates a module. I agree, however, that having to write "where" all the time is a pain (I still forget to put it in sometimes!), so perhaps you could complete the proposal with the wording required to say when a module ends. -Paul --- Professor Paul Hudak Department of Computer Science Yale University P.O. Box 208285 New Haven, CT 06520-8285 (203) 432-4715 [EMAIL PROTECTED]
Re: Haskell 1.3 (n+k patterns)
jl writes: > I feel the need to be inflamatory: > > I believe n+k should go. Again, I agree completely. Let's get rid of this horrible wart once and for all. It's a special case that makes the language more difficult to explain and implement. I've hardly seen any programs using it so I don't think backwards compat is a problem. Anyone who thinks this change will cause them more than 10 minutes work, plese speak up. -- Lennart