2d comment Haskell linear algebra libraries that are polymorphic with classes of kind * 2d comment Haskell linear algebra libraries that are polymorphic with classes of kind * Anyway, my reservations about the `* -> *` kind is actually more for conceptual, rather than practical reasons. The real physical space (or, what we think it is) sure has a perfectly fine, even finite, basis. Yet this basis is not given by nature in any way, but chosen completely arbitrary. If you treat it like a free vector space you constantly need to account for this fact and talk about gauge freedom and strange transformation behaviour all the time (indeed, that's a big chunk of the problems physicists are dealing with everydays). 2d comment Haskell linear algebra libraries that are polymorphic with classes of kind * @n.m.: actually, `(x -> a)` is the archetypical free vector space spanned by `a` over the type `x`. (It was a bit stupid what I said above, because the space of all functions e.g. β -> β is of course over-countably infinite-dimensional.) But indeed function spaces are a typical example for spaces where you can't use a basis, for instance the space of continous function has no ("reasonable") basis. 2d comment Haskell linear algebra libraries that are polymorphic with classes of kind * @n.m.: all finite-(or even countably-)dimensional vectorspaces are isomorphic to a free vector space, but a) sometimes it's interesting to work with Hilbert spaces that don't even have a basis b) being isomorphic to something doesn't mean it's a good idea to always exploit it... in Haskell, we don't use tuples all the time either, when it's more descriptive to introduce an isomorphic `data` type! Mar10 revised Haskell linear algebra libraries that are polymorphic with classes of kind * added 78 characters in body Mar10 answered Haskell linear algebra libraries that are polymorphic with classes of kind * Mar9 comment How to best “waste” a roughly specified time by only “burning CPU” with pure functional calculations? The first solution, ahm... no, don't gain much. But I rather like the second approach. Still a bit wordy though, I suppose that would need to go in a library nevertheless. ...And then one might as well take the full unsafe-threaddelay route... Mar9 comment haskell Error,Zipping lists @Ingo: work?? Tell you what, it did try to sleep late this morning... but I woke up and got way to excited about a sudden Haskell idea... Mar9 answered haskell Error,Zipping lists Mar9 comment How to return type of certain typeclass in a function You can not "choose to return some particular type". A function must always return the type declared in its signature, and there are no subtypes. You're abusing type classes here, they're not a replacement for OO classes. Mar9 comment How to best “waste” a roughly specified time by only “burning CPU” with pure functional calculations? I'd prefer it to just "run an empty loop", procedurally speaking. The time should be roughly predictable, but only in orders of magnitude (hardware factors are fine). Mar9 revised How to best “waste” a roughly specified time by only “burning CPU” with pure functional calculations? added 6 characters in body Mar9 asked How to best “waste” a roughly specified time by only “burning CPU” with pure functional calculations? Mar8 comment Has anyone already implemented a size-lazy vector type for Haskell? @JakeMcArthur: request-π-values ... ask-trie ... retrieve-π-values-á-logπ ... pop-π-values-from-initial-list. I do think it should work, with π(π log π) rather than π(π²). But if the OP just needs to "array-ise" a `Int -> a` function, it's definitely preferrable to simply use a trie right away. Mar7 comment Has anyone already implemented a size-lazy vector type for Haskell? @JakeMcArthur: it would be relatively easy to first convert the list to something lazy with π(log π) access, then build the trie from that, to avoid π(π²) build time. Mar7 comment Returning a list element using positions To make this at least somewhat consistent, I'd rather define a new operator e.g. `xs !!! i = xs !! (i `mod` length list)`, to allow negative indices as a special case of "safe indexing by wrap-around". But actually I'd prefer not to have that possibility at all, it's IMO more confusing than helpful. Mar7 comment Returning a list element using positions Yes, perhaps even a bit nicer. Mar7 answered Returning a list element using positions Mar6 comment Is there a name for arrows of the type a -> a (in Haskell notation) in category theory? Note that you seem to confuse OO objects with category-theory objects. "To another object of the same type" doesn't make sense, since the objects of Hask are types. The correct phrasing of your question would simply be "In category theory, in a category π what is the name for a morphism from some object O of π to O itself?" As said by gspr, those are endomorphisms. Mar6 comment Is there a name for arrows of the type a -> a (in Haskell notation) in category theory? @gspr: well, I suppose a polymorphic signature like `β a . a -> a` doesn't even make sense in a general category. In a small category π, this signature means functions from objects of π to endomorphisms of these objects. In Hask, this is certainly not the same as the collection of all endomorphisms, for `id` is indeed the only such polymorphic function you can define (without β).