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I have read that with a statically typed language like Scala or Haskell there is no way to create or provide a Lisp apply function:

(apply #'+ (list 1 2 3)) => 6

or maybe

(apply #'list '(list :foo 1 2 "bar")) => (:FOO 1 2 "bar")
(apply #'nth (list 1 '(1 2 3))) => 2

Is this a truth?

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C# is static and has a function called Invoke that is like apply. –  Gabe Sep 12 '10 at 3:08
IIRC, C# does that using dynamics, which means that it'll generate glue code that checks all the I/O types before passing them. –  Eli Barzilay Sep 12 '10 at 3:17
@sreservoir: In the general case, static typechecking is equivalent to solving the Halting Problem and thus undecidable. This means that there exist programs which are type-safe but not type-checkable. Put another way: any statically typed language will prevent you from writing certain perfectly type-safe programs. This is basically undisputed even by the most hardcore static typing fanbois. There is, however, a disagreement between proponents of static and dynamic typing about whether or not this class contains any useful programs. This basically asks whether apply is such a program. –  Jörg W Mittag Sep 12 '10 at 4:08
In particular, apply and eval (especially a metarcicular eval) are some of the programs that are often claimed by proponents of dynamic typing to be impossible to implement in statically typed languages. At least in practically existing ones. For example, if you look at the source code for Haskell's dynApply in the Data.Dynamic module, which is probably the closest thing to Scheme's apply, you will find that it uses the unsafeCoerce function, which is basically the same as an unrestricted unsafe cast in C, and thus explicitly and deliberately circumvents the type system. –  Jörg W Mittag Sep 12 '10 at 4:15
@Jörg W Mittag: Speaking as a "hardcore static typing fanboi" (C# and Java don't really count as statically typed languages BTW), I pretty much agree. There are workarounds, but there's basically no way to make a proper, first-class eval without circumventing the type system somehow. In fact, if you plug all the holes and take static typing to its logical conclusion, it's provably impossible to write an interpreter for a language in itself at all. Having used Scheme and Ruby before moving to Haskell, I do miss this sort of thing sometimes... –  C. A. McCann Sep 12 '10 at 5:16

12 Answers 12

up vote 9 down vote accepted

A full APPLY is difficult in a static language.

In Lisp APPLY applies a function to a list of arguments. Both the function and the list of arguments are arguments to APPLY.

  • APPLY can use any function. That means that this could be any result type and any argument types.

  • APPLY takes arbitrary arguments in arbitrary length (in Common Lisp the length is restricted by an implementation specific constant value) with arbitrary and possibly different types.

  • APPLY returns any type of value that is returned by the function it got as an argument.

How would one type check that without subverting a static type system?


(apply #'+ '(1 1.4))   ; the result is a float.

(apply #'open (list "/tmp/foo" :direction :input))
; the result is an I/O stream

(apply #'open (list name :direction direction))
; the result is also an I/O stream

(apply some-function some-arguments)
; the result is whatever the function bound to some-function returns

(apply (read) (read))
; neither the actual function nor the arguments are known before runtime.
; READ can return anything

Interaction example:

CL-USER 49 > (apply (READ) (READ))                        ; call APPLY
open                                                      ; enter the symbol OPEN
("/tmp/foo" :direction :input :if-does-not-exist :create) ; enter a list
#<STREAM::LATIN-1-FILE-STREAM /tmp/foo>                   ; the result

Now an example with the function REMOVE. We are going to remove the character a from a list of different things.

CL-USER 50 > (apply (READ) (READ))
(#\a (1 "a" #\a 12.3 :foo))
(1 "a" 12.3 :FOO)

Note that you also can apply apply itself, since apply is a function.

CL-USER 56 > (apply #'apply '(+ (1 2 3)))

There is also a slight complication because the function APPLY takes an arbitrary number of arguments, where only the last argument needs to be a list:

CL-USER 57 > (apply #'open
                    '(:if-does-not-exist :create))

How to deal with that?

  • relax static type checking rules

  • restrict APPLY

One or both of above will have to be done in a typical statically type checked programming language. Neither will give you a fully statically checked and fully flexible APPLY.

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@FUZxxl: How so, your post is full of restrictions and the 'does not auto-infer types' relaxes static typing. –  Rainer Joswig Sep 12 '10 at 6:12
@Eli Barzilay, a typical use case of APPLY is to use it with variable length argument lists and arguments of different types. If such a use case can not be replicated using APPLY in a statically typed language, then it is not the APPLY that Lisp provides. The OP asked about a Lisp apply function. If one restricts APPLY to what the statically typed language allows, then it covers only simple uses of APPLY, but is not a Lisp apply, which the OP was asking about. –  Rainer Joswig Sep 12 '10 at 8:17
Following this line, you're reducing the answer to a trivial "no", for reasons that are unrelated to apply, and with that you completely ignore an interesting problem that points at a real deficiency of popular type systems. –  Eli Barzilay Sep 12 '10 at 8:23
@Eli Barzilay, the reasons are not unrelated to APPLY. APPLY is used for certain types of use cases in Lisp. I describe some of the capabilities, to make sure that the OP understands that APPLY is not a case of REDUCE, but used for much more in Lisp. That these use cases of APPLY are hard to replicate in a statically typed language is not my problem. –  Rainer Joswig Sep 12 '10 at 8:55
@Eli Barzilay. From your answer: 'uniform' lists with 'limited types' or 'lists' with statically known length. Doesn't sound like Lisp's APPLY, which has neither of these restrictions. Using APPLY with uniform lists sounds mostly useless to me, especially since the main use case can be provided via REDUCE. Using APPLY with lists of a static length also sounds strange. –  Rainer Joswig Sep 13 '10 at 21:48

It is perfectly possible in a statically typed language. The whole java.lang.reflect thingy is about doing that. Of course, using reflection gives you as much type safety as you have with Lisp. On the other hand, while I do not know if there are statically typed languages supporting such feature, it seems to me it could be done.

Let me show how I figure Scala could be extended to support it. First, let's see a simpler example:

def apply[T, R](f: (T*) => R)(args: T*) = f(args: _*)

This is real Scala code, and it works, but it won't work for any function which receives arbitrary types. For one thing, the notation T* will return a Seq[T], which is a homegenously-typed sequence. However, there are heterogeneously-typed sequences, such as the HList.

So, first, let's try to use HList here:

def apply[T <: HList, R](f: (T) => R)(args: T) = f(args)

That's still working Scala, but we put a big restriction on f by saying it must receive an HList, instead of an arbitrary number of parameters. Let's say we use @ to make the conversion from heterogeneous parameters to HList, the same way * converts from homogeneous parameters to Seq:

def apply[T, R](f: (T@) => R)(args: T@) = f(args: _@)

We aren't talking about real-life Scala anymore, but an hypothetical improvement to it. This looks reasonably to me, except that T is supposed to be one type by the type parameter notation. We could, perhaps, just extend it the same way:

def apply[T@, R](f: (T@) => R)(args: T@) = f(args: _@)

To me, it looks like that could work, though that may be naivety on my part.

Let's consider an alternate solution, one depending on unification of parameter lists and tuples. Let's say Scala had finally unified parameter list and tuples, and that all tuples were subclass to an abstract class Tuple. Then we could write this:

def apply[T <: Tuple, R](f: (T) => R)(args: T) = f(args)

There. Making an abstract class Tuple would be trivial, and the tuple/parameter list unification is not a far-fetched idea.

share|improve this answer
+1, Great answer (as usual :) –  missingfaktor Sep 12 '10 at 19:20
Using any form of reflection is cheating the solution, since it "gives you as much type safety as you have with Lisp". A proper solution would be a typed apply -- much like $ being close to a statically typed version of funcall. –  Eli Barzilay Sep 13 '10 at 2:28
@Eli Only the first paragraph talks about a solution with reflection. All the rest is plain static typing. –  Daniel C. Sobral Sep 13 '10 at 15:48
Daniel: Indeed, you're not talking about reflection; but you're imaginary "Let's say we use @ to make the conversion from heterogeneous parameters to HList" is exactly the problem here! You can't just switch from a type to a sequence of types without some serious support from the language: an hlist is still a value in the language, and without apply a sequence of function argument is not something in the language. It's a second class concept that you can't access directly. As for the question if it could work, of course it can -- I've pointed at Typed Racket... (It's just hard.) –  Eli Barzilay Sep 19 '10 at 20:17
(I should have added that: yes, it's possible, just not done for pretty much all statically typed languages (including Scala) -- with Typed Racket being an obvious exception.) –  Eli Barzilay Sep 19 '10 at 20:55

The reason you can't do that in most statically typed languages is that they almost all choose to have a list type that is restricted to uniform lists. Typed Racket is an example for a language that can talk about lists that are not uniformly typed (eg, it has a Listof for uniform lists, and List for a list with a statically known length that can be non-uniform) -- but still it assigns a limited type (with uniform lists) for Racket's apply, since the real type is extremely difficult to encode.

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In Scala and Haskell, those are called Tuples. They encode their length and the type of each element. –  MJP Sep 12 '10 at 13:01
In addition to Tuples, there are HLists (heterogenous lists). Like Tuples, they encode length and type of arguments. Unlike Tuples, they don't require a new type constructor for each arity, and support operations like typed concatenate. A good bit tougher to use than tuples, but they really show off what is possible with modern typeful programming. homepages.cwi.nl/~ralf/HList –  Dave Griffith Sep 12 '10 at 14:37
@MJP Tuples are not the same thing. An HList would be more like it -- an arbitrary-length data structure that is fully typed at each member. And there exist such for Scala and Haskell, by the way. –  Daniel C. Sobral Sep 12 '10 at 15:40
MJP: no, tuples are not really the same as what I'm talking about, and trying to reify them as argument lists in Haskell can be confusing since Haskell has only unary functions. I don't know anything specific about HLists, but it sounds much closer to what I'm talking about. –  Eli Barzilay Sep 13 '10 at 2:26
Eli Barzilay: HList is a library for working with lists containing values of arbitrary types. The "type" of an HList is also a list, holding the types for each item. Basically equivalent to right-nested 2-tuples with () as the empty list. Deep wizardry is used to create functions working on arbitrary HLists, but to do much of anything useful all the types must still be known at compile-time. –  C. A. McCann Sep 13 '10 at 13:27

It's trivial in Scala:

Welcome to Scala version 2.8.0.final ...

scala> val li1 = List(1, 2, 3)
li1: List[Int] = List(1, 2, 3)

scala> li1.reduceLeft(_ + _)
res1: Int = 6

OK, typeless:

scala> def m1(args: Any*): Any = args.length
m1: (args: Any*)Any

scala> val f1 = m1 _
f1: (Any*) => Any = <function1>

scala> def apply(f: (Any*) => Any, args: Any*) = f(args: _*)
apply: (f: (Any*) => Any,args: Any*)Any

scala> apply(f1, "we", "don't", "need", "no", "stinkin'", "types")
res0: Any = 6

Perhaps I mixed up funcall and apply, so:

scala> def funcall(f: (Any*) => Any, args: Any*) = f(args: _*)
funcall: (f: (Any*) => Any,args: Any*)Any

scala> def apply(f: (Any*) => Any, args: List[Any]) = f(args: _*)
apply: (f: (Any*) => Any,args: List[Any])Any

scala> apply(f1, List("we", "don't", "need", "no", "stinkin'", "types"))
res0: Any = 6

scala> funcall(f1, "we", "don't", "need", "no", "stinkin'", "types")
res1: Any = 6
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No, these reduce, fold, and friends are not apply. –  Eli Barzilay Sep 12 '10 at 2:48
I guess I need to see a definition of what you want rather than just examples. But I think it's a near certainty that whatever it is you want to do, it can be done in a reasonable fashion in Scala. –  Randall Schulz Sep 12 '10 at 3:52
The definition of apply in CL is simply "This applies function to a list of arguments.", and in R5RS it's defined as "Calls proc with the elements of the list [...] as the actual arguments. (In any case, I highly doubt your "near certainty".) –  Eli Barzilay Sep 12 '10 at 4:17
@Randall Schulz: That's not really fair--it's not about "type errors at runtime", it's about first-class metaprogramming. This is absolutely reasonable and useful and awesome and really tough to get right in a statically typed language. In an ideal world, I'd be able to check at compile-time not only that my program is well-typed, but that my meta-programming will itself only generate well-typed programs at run time. This is a hard problem, but not impossible! –  C. A. McCann Sep 12 '10 at 5:26
@Randall Sure it could be possible, if the language provided compile-time support for type lists. Then we could write something like this: def apply[@T, R](f: (@T => R), args: @T*): R = f(args: _*), where @T stands for a list of types, and args was something like an HList. –  Daniel C. Sobral Sep 12 '10 at 15:45

In Haskell, there is no datatype for multi-types lists, although I believe, that you can hack something like this together whith the mysterious Typeable typeclass. As I see, you're looking for a function, which takes a function, a which contains exactly the same amount of values as needed by the function and returns the result.

For me, this looks very familiar to haskells uncurryfunction, just that it takes a tuple instead of a list. The difference is, that a tuple has always the same count of elements (so (1,2) and (1,2,3) are of different types (!)) and there contents can be arbitrary typed.

The uncurry function has this definition:

uncurry :: (a -> b -> c) -> (a,b) -> c
uncurry f (a,b) = f a b

What you need is some kind of uncurry which is overloaded in a way to provide an arbitrary number of params. I think of something like this:

{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE UndecidableInstances #-}

class MyApply f t r where
  myApply :: f -> t -> r

instance MyApply (a -> b -> c) (a,b) c where
  myApply f (a,b) = f a b

instance MyApply (a -> b -> c -> d) (a,b,c) d where
  myApply f (a,b,c) = f a b c

-- and so on

But this only works, if ALL types involved are known to the compiler. Sadly, adding a fundep causes the compiler to refuse compilation. As I'm not a haskell guru, maybe domeone else knows, howto fix this. Sadly, I don't know how to archieve this easier.

Résumee: apply is not very easy in Haskell, although possible. I guess, you'll never need it.

Edit I have a better idea now, give me ten minutes and I present you something whithout these problems.

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FUZxxl: for this to work, you'll need an infinite definition. –  Eli Barzilay Sep 12 '10 at 3:41
Yes. I saw some definition whithout infiniteness, but I forgot where. Let me look for it. –  FUZxxl Sep 12 '10 at 3:45
And I also know, it's a duplicate. –  FUZxxl Sep 12 '10 at 3:46
I tried for half an hour to make this user-friendly. The idea is to write a generalized flatTuple function of the type flatTuple :: (a, b...) -> (a,(b,...)) and apply the elements to the function recursivly. But by some reason, the type system is not happy with my idea sniff –  FUZxxl Sep 12 '10 at 4:34

It is possible to write apply in a statically-typed language, as long as functions are typed a particular way. In most languages, functions have individual parameters terminated either by a rejection (i.e. no variadic invocation), or a typed accept (i.e. variadic invocation possible, but only when all further parameters are of type T). Here's how you might model this in Scala:

trait TypeList[T]
case object Reject extends TypeList[Reject]
case class Accept[T](xs: List[T]) extends TypeList[Accept[T]]
case class Cons[T, U](head: T, tail: U) extends TypeList[Cons[T, U]]

Note that this doesn't enforce well-formedness (though type bounds do exist for that, I believe), but you get the idea. Then you have apply defined like this:

apply[T, U]: (TypeList[T], (T => U)) => U

Your functions, then, are defined in terms of type list things:

def f (x: Int, y: Int): Int = x + y


def f (t: TypeList[Cons[Int, Cons[Int, Reject]]]): Int = t.head + t.tail.head

And variadic functions like this:

def sum (xs: Int*): Int = xs.foldLeft(0)(_ + _)

become this:

def sum (t: TypeList[Accept[Int]]): Int = t.xs.foldLeft(0)(_ + _)

The only problem with all of this is that in Scala (and in most other static languages), types aren't first-class enough to define the isomorphisms between any cons-style structure and a fixed-length tuple. Because most static languages don't represent functions in terms of recursive types, you don't have the flexibility to do things like this transparently. (Macros would change this, of course, as well as encouraging a reasonable representation of function types in the first place. However, using apply negatively impacts performance for obvious reasons.)

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try folds. they're probably similar to what you want. just write a special case of it.

haskell: foldr1 (+) [0..3] => 6

incidentally, foldr1 is functionally equivalent to foldr with the accumulator initialized as the element of the list.

there are all sorts of folds. they all technically do the same thing, though in different ways, and might do their arguments in different orders. foldr is just one of the simpler ones.

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BTW, foldl is prefereable in most cases. –  FUZxxl Sep 12 '10 at 2:44
The apply function only calls the function once, with the supplied list as its arguments. The OP's example doesn't fold the list 1,2,3 with the add function, it calls the add function once with the list 1,2,3 and the add function does the looping itself. –  Gabe Sep 12 '10 at 3:01
Folds, of any sort, are unrelated to apply. –  Eli Barzilay Sep 12 '10 at 3:04
and, of course, I just realized I completely missed the point of apply. –  sreservoir Sep 12 '10 at 3:12
@Brian Campbell: you're obviously right; but if all we care about is this specific example, then there's a whole bunch of ways it can be implemented without apply. For example -- "6" works fine too, and it's a much shorter program, even. –  Eli Barzilay Sep 12 '10 at 3:20

On this page, I read that "Apply is just like funcall, except that its final argument should be a list; the elements of that list are treated as if they were additional arguments to a funcall."

In Scala, functions can have varargs (variadic arguments), like the newer versions of Java. You can convert a list (or any Iterable object) into more vararg parameters using the notation :_* Example:

//The asterisk after the type signifies variadic arguments
def someFunctionWithVarargs(varargs: Int*) = //blah blah blah...

val list = List(1, 2, 3, 4)
//equivalent to
someFunctionWithVarargs(1, 2, 3, 4)

In fact, even Java can do this. Java varargs can be passed either as a sequence of arguments or as an array. All you'd have to do is convert your Java List to an array to do the same thing.

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The main point of apply is that the function that is being applied doesn't need to change. –  Eli Barzilay Sep 12 '10 at 3:03
What? Where did I change a function? –  MJP Sep 12 '10 at 3:07
You've defined it with varargs:. OTOH, apply can be used with anything (even +, as the question shows). –  Eli Barzilay Sep 12 '10 at 3:12
On the contrary, Lisp's + is defined with varargs. In Lisp, you can say (+ 1 2 3 4). –  MJP Sep 12 '10 at 3:28
MJP: that's right, but that's just one example. apply can work with any lisp function, including ones that are not variable arity. (I just edited it and added such an example.) –  Eli Barzilay Sep 12 '10 at 3:43

The benefit of a static language is that it would prevent you to apply a function to the arguments of incorrect types, so I think it's natural that it would be harder to do.

Given a list of arguments and a function, in Scala, a tuple would best capture the data since it can store values of different types. With that in mind tupled has some resemblance to apply:

scala> val args = (1, "a")
args: (Int, java.lang.String) = (1,a)

scala> val f = (i:Int, s:String) => s + i
f: (Int, String) => java.lang.String = <function2>

scala> f.tupled(args)
res0: java.lang.String = a1

For function of one argument, there is actually apply:

scala> val g = (i:Int) => i + 1
g: (Int) => Int = <function1>

scala> g.apply(2)
res11: Int = 3

I think if you think as apply as the mechanism to apply a first class function to its arguments, then the concept is there in Scala. But I suspect that apply in lisp is more powerful.

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For Haskell, to do it dynamically, see Data.Dynamic, and dynApp in particular: http://www.haskell.org/ghc/docs/6.12.1/html/libraries/base/Data-Dynamic.html

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See his dynamic thing for haskell, in C, void function pointers can be casted to other types, but you'd have to specify the type to cast it to. (I think, haven't done function pointers in a while)

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A list in Haskell can only store values of one type, so you couldn't do funny stuff like (apply substring ["Foo",2,3]). Neither does Haskell have variadic functions, so (+) can only ever take two arguments.

There is a $ function in Haskell:

($)                     :: (a -> b) -> a -> b
f $ x                   =  f x

But that's only really useful because it has very low precedence, or as passing around HOFs.

I imagine you might be able to do something like this using tuple types and fundeps though?

class Apply f tt vt | f -> tt, f -> vt where
  apply :: f -> tt -> vt

instance Apply (a -> r) a r where
  apply f t = f t

instance Apply (a1 -> a2 -> r) (a1,a2) r where
  apply f (t1,t2) = f t1 t2

instance Apply (a1 -> a2 -> a3 -> r) (a1,a2,a3) r where
  apply f (t1,t2,t3) = f t1 t2 t3

I guess that's a sort of 'uncurryN', isn't it?

Edit: this doesn't actually compile; superseded by @FUZxxl's answer.

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Nevermind; that doesn't work, I guess because they're overlapping. So I guess you'd need to do apply1 f t = f t, apply2 f (t1,t2) = f t1 t2, and so on... –  Amos Robinson Sep 12 '10 at 2:42
Variadic functions: Yes, we can! stackoverflow.com/questions/3467279/… –  FUZxxl Sep 12 '10 at 2:44
Haskell's $ is not a form of an apply function -- it is more like funcall, except limited to one argument which makes it useless in Lisp. (But the one-argument limitation is obviously not a problem in Haskell.) –  Eli Barzilay Sep 12 '10 at 2:46
BTW, your won't compile, I tested. See my answer –  FUZxxl Sep 12 '10 at 3:45

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