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19

Take an FD, e.g. ABâ†’C Augment until all attributes are mentioned, e.g. ABDEFG â†’ CDEFG (note that this is equivalent to ABDEFG â†’ ABCDEFG because it is trivially true that A->A and B->B). This tells you that ABDEFG is a superkey. Check the other FDs in which the LHS is a subset of your superkey, and that on its RHS contains some other attribute of your ...

18

Your instance works just fine, actually. Observe: main = print \$ two (3 :: Int, 4 :: Int) This works as expected. So why doesn't it work without the type annotation, then? Well, consider the tuple's type: (3, 4) :: (Num t, Num t1) => (t, t1). Because numeric literals are polymorphic, nothing requires them to be the same type. The instance is defined ...

15

Actually, it's a "functional dependency". In this case that means that m uniquely identifies w -- the type m determines the type w. (This may be a better link.)

14

To get the minimal cover, you have to make two steps. To demonstrate, I'll first split the dependencies into multiple (only one attribute on the right side) to make it more clean: A -> B ABCD -> E EF -> G EF -> H ACDF -> E ACDF -> G The following steps must be done in this order (#1 and then #2), otherwise you can get incorrect result. ...

13

Unless you have a good reason to, I would just skip the type classes and use a plain old ADT: data Time = Hour Int | Minute Int | Second Int instance Show Time where show (Hour x) = show x ++ "hrs" show (Minute x) = show x ++ "min" show (Second x) = show x ++ "sec" add x y = fromSeconds (toSeconds x + toSeconds y) toSeconds (Hour x) = 3600 * x ...

12

Have you tried actually using the second version? I'm guessing that while the instances compile, you'll start getting ambiguity and overlap errors when you call foo. The biggest stumbling block here is that fundeps don't interact with type variables the way you might expect them to--instance selection doesn't really look for solutions, it just blindly ...

12

Section 7.6.3.2 of the GHC manual [1] tells us that the coverage condition is: The Coverage Condition. For each functional dependency, tvsleft -> tvsright, of the class, every type variable in S(tvsright) must appear in S(tvsleft), where S is the substitution mapping each type variable in the class declaration to the corresponding type in the instance ...

10

Okay, first of all: The reason the compiler complains about the fundeps conflicting is... because they do conflict. There's really no way around that, as such--the conflict is inherent in what you're trying to do. The first type parameter is the "input", and you're essentially pattern matching on it for specific types, with overlapping giving default ...

10

A candidate key is a minimal superkey. In other words, there are no superflous attributes in the key. The first step to finding a candidate key, is to find all the superkeys. For those unfamiliar, a super key is a set of attributes whose closure is the set of all atributes. In other words, a super key is a set of attributes you can start from, and ...

9

You could do something like this, but it doesn't give you the functional dependency. class TimeUnit a where toSeconds :: a -> Int fromSeconds :: Int -> a instance TimeUnit (Time Second) where toSeconds = id; fromSeconds = id instance TimeUnit (Time Minute) where toSeconds = (* 60); fromSeconds = (`quot` 60) class TimeAdd a b c where add ...

9

is it possible to get some more verbose information on how Haskell works with instances? Some of these combinations seem impossible. Even just a link to a document explaining the mechanism would be appreciated How Haskell works with instances is very simple. You're dealing with multiple experimental language extensions provided by GHC, so the primary ...

8

It's perfectly fine to write code not using functional dependencies, it's just a pain to use since the inference sucks. Basically without FDs, the function get :: MonadState m s => m s will have to figure out m and s independently. Usually m is quite easily inferred, but often s would require an explicit annotation. Moreover, this is much more general ...

7

It could probably be argued that TH is more appropriate in cases like this. That said, I'll do it with types anyhow. The problem here is that everything is too discrete. You can't iterate through the prefixes to find the right one, and you're not expressing the transitivity of the ordering you want. We can solve it by either route. For a recursive ...

7

A functional dependency defines a functional relationship between attributes. For example: PersonId functionally determines BirthDate (normally written as PersonId -> BirthDate). Another way of saying this is: There is exactly one Birth Date for any given given any instance of a person. Note that the converse may or may not be true. Many people may have ...

6

I thought this explains it fairly well. So basically if you have an FD relation of a -> b all it means is for type-class instance there can only be one 'b' with any 'a' so Int Int but you can't have Int Float as well. That's what they mean when it's said that 'b' is uniquely determined from 'a'. This extends to any number of type paramters. The reason why it ...

6

The problem is that a literal number has a polymorphic type. It is not obvious to the typechecker that both literals should have the same type (Int). If you use something that is not polymorphic for your tuples, your code should work. Consider these examples: *Main> two (3,4) <interactive>:1:1: No instance for (Pair (t0, t1) a0) arising ...

6

The way I would do this at the type level is to map the phantom types to type level natural numbers and use a "minimum" operation to find the correct return type and then let instance resolution do the job from there on. I'll be using type families here, but it can probably be done with functional dependencies if you prefer those. {-# LANGUAGE ...

6

There's no big reason to stay away from UndecidableInstances. The worst that can happen is that the type checker starts looping (and tells you about it, I think). You can make the coverage condition more and more clever, but it will never do everything you could want since that's undecidable.

6

Pull neg and zero out into a superclass that only uses the one type: class Zero a where neg :: a -> a zero :: a class Zero a => Add a b c | a b -> c where (~+) :: a -> b -> c (~-) :: a -> b -> c The point is that your way, zero :: Int could be the zero from Add Int Int Int, or the zero from Add Int Double Double, and ...

6

You can make the functional dependency "circular": class Class a b c | a->b, b->c, c->a where getB :: a -> b getC :: b -> c so any one type parameter can be deduced from any of the others. But I'm not sure if you really want this; why not have just a type class with one fundep and one method, and make two instances of it (instance ...

5

A procedure that is a little more formal. Take an FD, e.g. (example 2), AB -> CD. Augment this using trivial FDs until you have ALL the attributes on the RHS. You lack ABE on the RHS, so you must augment using the trivial FD ABE -> ABE to obtain ABE -> ABCDE. That tells you that ABE is a superkey, because knowing the values in a certain row for ABE will ...

5

The second one's a bit simpler, so taking it first . . . you know that B must be in any key, because it's not on any right-hand side. (That is, even if you have the values of ACDE, you couldn't infer the value of B.) Similarly for E; so, any key must include BE. But BE is by itself a sufficient key, because E gives you A (hence BE â†’ ABE) and AB gives you CD ...

5

You might want to look into repa, which offers n-dimensional arrays which encode their shape (dimensions) into the type; you can code generic operations that work on arrays of any shape with it. I think you could avoid a typeclass entirely by constructing the array with backpermute or fromFunction and translating the indices (it's more efficient than it ...

5

If you want a type function, use Type Families - that's what they're for. Type Families are easy and do what you expect. Often the reason that the compiler didn't infer your type is that you specified a functional dependency (logical relationship) rather than a function (calculating tool). Using fundeps is notoriously counter-intuitive, partly because ...

4

As Manuel Chakravarty explains, type functions and functional dependencies have roughly the same expressiveness, you can translate one formulation into the other. They only begin to differ when you look at interaction with other language extensions like GADTs or UndecidableInstances. I gather that type families are currently favored for implementation in GHC ...

4

The way you have defined the Lit constructor will prevent you from projecting out the value it contains, regardless of how you define the projection function. Let's look at the constructor's type: Lit :: Prim l => l -> E The type variable l appears in the parameters, but not the return type. That means that when you construct a Lit, you put in a ...

4

At a glance . . . custName -> custNo model -> make outletLoc -> outletNo carReg, custNo -> hireDate carReg, custName -> hireDate And I'm sure there are others. The sample data isn't representative, and that's a problem when you try to determine functional dependencies from data. Let's say your sample data had only one row. carReg ...

4

Don't use fundeps, they are too much pain. Use associated types. class (Eq (Vertex g), Eq (Edge g)) => Graph g where type Edge g :: * type Vertex g :: * edges :: g -> [Edge g] src :: g -> Edge g -> Vertex g dst :: g -> Edge g -> Vertex g vertices :: g -> [Vertex g] vertices g = nub \$ map (src g) (edges g) ++ map ...

4

It's a very bad error message. The cause is due to a type mismatch in State. Your code is trying to mix [M.Map Ident Type] and [[M.Map Ident Type]]. If you manually inline the emptyIdents call into scopeEnter it looks like this: scopeEnter :: Typer () scopeEnter = modify \$ \ids -> [] : ids ... which doesn't make much sense for [M.Map Ident Type]. ...

4

No, but as F is not in any of the FD:s then it has to be a member of every candidate key. Also, A->BCD, BC->DE, B->D, D->A give us A+ (the cover of A) = ABCDE B+ = ABCDE C+ = C D+ = ABCDE so the E+ = E F+ = F. The combinations giving ABCDEF are AF BF DF and hence the candidate keys are {AF, BF, DF} and every enhancement of any of those three ...

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