Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# Why is (a,b,c,d) not sugar for (a,(b,(c,(d,()))))?

It's clear that any n-tuple can be represented by a bunch of nested 2-tuples. So why are they not the same thing in Haskell? Would this break something?

Making these types equivalent would make writing functions on tuples much easier. For example, instead of defining zip,zip2,zip3,etc., you could define only a single zip function that would work for all tuples.

Of course, you can work with nested 2-tuples, but it is ugly and there is no canonical way to perform the nesting (i.e. should we nest to the left or right?).

-

The type `(a,b,c,d)` has a different performance profile from `(a,(b,(c,(d,()))))`. In general, indexing into an n-tuple takes `O(1)` while indexing into an "hlist" of n nested tuples takes `O(n)`.

That said, you should check out Oleg's classic work on HLists. Using HLists requires extensive, and somewhat sketchy, use of type level programming. Many people find this unacceptable, and it was not available in early Haskell. Probably the best way to represent an HList today is with GADTs and DataKinds

``````data HList ls where
Nil  :: HList '[]
Cons :: x -> HList xs -> HList (x ': xs)
``````

This give canonical nesting, and lets you write functions that work for all instances of this type. You could implement your multi way `zipWith` using the same techniques as used in printf. A more interesting puzzle is to generate the appropriate lenses for this type (hint: use type level naturals and type families for indexing in).

I have considered writing an HList like library that used arrays and `unsafeCoerce` under the hood to get tuple like performance while sticking to a generic interface. I haven't done it, but it should not be overly difficult.

EDIT: the more I think about this the more inclined I am to hack something together when I have the time. The repeated copying problem Andreas Rossberg mentions can probably be eliminated using stream fusion or similar techniques.

-
I had seen Oleg's work, and that's what got me started on this basic idea. The syntax for his library (and all the variants I've seen) are just awful to use in practice though. Also, I didn't realize nested tuples take an O(n) performance hit. Couldn't the unnesting be done by the compiler to generate O(1)? – Mike Izbicki Feb 20 '13 at 7:26
I assumed you were talking about the performance at runtime, not compile time. It makes sense to me that compile time performance for nested tuples would not be as good, but that doesn't seem like a big deal. – Mike Izbicki Feb 20 '13 at 7:30
@MikeIzbicki I was talking about runtime performance. In principle it could probably be inlined into tuples much of the time, but we don't have that kind of compiler machinery currently available. Note that because templates in C++ can be used "unboxed", the C++ implementation of tuples can be fully generic in the way you would like. GHC does not allow you to unbox polymorphic fields, so we can't do this (hence the solution being a library using arrays an unsafe coerce internally). – Philip JF Feb 20 '13 at 9:03
@PhilipJF I've decided to go ahead and make a tuple type using a vector as the base, like you were talking about. I solved the problem of copying the vector every time you do a tuple-cons by making the vector extra large and using a mutable vector. Or at least I think it works so far. It's pretty shoe-string right now, so I'll try to get it into a reasonable condition this coming week and put it on github. – Mike Izbicki Feb 24 '13 at 0:01
For anyone reading this in the future, here's a link to the github prohect: github.com/mikeizbicki/vector-heterogenous#hvector – Mike Izbicki Mar 5 '13 at 17:24

The main problem with this in Haskell would be that a nested tuple allows additional values, due to laziness. For example, the type `(a,(b,())` is inhabited by all `(x,_|_)` or `(x,(y,_|_))`, which is not the case for flat tuples. The existence of these values is not only semantically inconvenient, it also would make tuples much more difficult to optimise.

In a strict language, though, your suggestion is indeed a possibility. But it still introduces a performance pitfall: implementations would still want to flatten tuples. Consequently, in the cases where you actually construct or deconstruct them inductively, they would have to do a lot of repeated copying. When you use really large tuples, that might be a problem.

-
What if we make strictly nested tuples isomorphic to their flattened counterparts, i.e. something like: `(a,!(b,!(c,!()))) ~ (a,b,c)`? Also, couldn't all that copying be done at compile time instead of run time? – Mike Izbicki Feb 20 '13 at 7:41
@MikeIzbicki, AFAICT, there is no such thing as a type `(a,!(...))` in Haskell. You can only annotate the parameters of datatype constructors as strict. Regarding the copying, of course it's not necessary where you write down a tuple literal, but when you construct or deconstruct one inductively, i.e. by recursion over its length, then I see no way avoiding it. – Andreas Rossberg Feb 20 '13 at 8:01
I wonder if there's some way of keeping the current representation of tuples but providing an interface similar to the nested tuples. Basically, have tuples work the same way but also make it easy to write generic code over tuples with things like recursive typeclass instances. – Tikhon Jelvis Feb 20 '13 at 16:30
@AndreasRossberg if the representation consists of, say, a pointer to an array to host a tuple's elements, and a number that is a tuple's known size (`<=` than the actual array size which might be quite larger, or be grown with exponential resizing), the copying would only consist of copying these two fields. The actual array could be then shared, I think. – Will Ness Feb 20 '13 at 17:40
@WillNess, well, sure, but the cost of an extra indirection and extra allocation everywhere is far worse than the problem it would fix. – Andreas Rossberg Feb 20 '13 at 19:01