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So far implicit parameters in Scala do not look good for me -- it is too close to global variables, however since Scala seems like rather strict language I start doubting in my own opinion :-).

Question: could you show a real-life (or close) good example when implicit parameters really work. IOW: something more serious than showPrompt, that would justify such language design.

Or contrary -- could you show reliable language design (can be imaginary) that would make implicit not neccessary. I think that even no mechanism is better than implicits because code is clearer and there is no guessing.

Please note, I am asking about parameters, not implicit functions (conversions)!

Updates

Global variables

Thank you for all great answers. Maybe I clarify my "global variables" objection. Consider such function:

max(x : Int,y : Int) : Int

you call it

max(5,6);

you could (!) do it like this:

max(x:5,y:6);

but in my eyes implicits works like this:

x = 5;
y = 6;
max()

it is not very different from such construct (PHP-like)

max() : Int
{
  global x : Int;
  global y : Int;
  ...
}

Derek's answer

This is great example, however if you can think of as flexible usage of sending message not using implicit please post an counter-example. I am really curious about purity in language design ;-).

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If you make a global implicit (and you can't - the best you can do is a package-scoped implicit) then your statement might hold true, but only if you chose to do such a thing... don't. And, the bottom line is that the flexibility of that API comes from the use of implicits. If you don't use them, you can't get the same flexibility. So you're asking to remove the feature that makes it great, and still make it great. Very odd request. –  Derek Wyatt Mar 2 '12 at 12:04
    
@Derek Wyatt, the last comment is somewhat strange -- don't you seek optimization in life? I do. Now, about global variables -- I am not saying you have to have global variables to use implicits, I say they are similar in usage. Because they are binded by name of the callee, implicitly, and they are taken out of scope of caller, not from actual call. –  greenoldman Mar 2 '12 at 12:21
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6 Answers

up vote 33 down vote accepted

In a sense, yes, implicits represent global state. However, they are not mutable, which is the true problem with global variables -- you don't see people complaining about global constants, do you? In fact, coding standards usually dictate that you transform any constants in your code into constants or enums, which are usually global.

Note also that implicits are not in a flat namespace, which is also a common problem with globals. They are explicitly tied to types and, therefore, to the package hierarchy of those types.

So, take your globals, make them immutable and initialized at the declaration site, and put them on namespaces. Do they still look like globals? Do they still look problematic?

But let's not stop there. Implicits are tied to types, and they are just as much "global" as types are. Does the fact that types are global bother you?

As for use cases, they are many, but we can do a brief review based on their history. Originally, afaik, Scala did not have implicits. What Scala had were view types, a feature many other languages had. We can still see that today whenever you write something like T <% Ordered[T], which means the type T can be viewed as a type Ordered[T]. View types are a way of making automatic casts available on type parameters (generics).

Scala then generalized that feature with implicits. Automatic casts no longer exist, and, instead, you have implicit conversions -- which are just Function1 values and, therefore, can be passed as parameters. From then on, T <% Ordered[T] meant a value for an implicit conversion would be passed as parameter. Since the cast is automatic, the caller of the function is not required to explicitly pass the parameter -- so those parameters became implicit parameters.

Note that there are two concepts -- implicit conversions and implicit parameters -- that are very close, but do not completely overlap.

Anyway, view types became syntactic sugar for implicit conversions being passed implicitly. They would be rewritten like this:

def max[T <% Ordered[T]](a: T, b: T): T = if (a < b) b else a
def max[T](a: T, b: T)(implicit $ev1: Function1[T, Ordered[T]]): T = if ($ev1(a) < b) b else a

The implicit parameters are simply a generalization of that pattern, making it possible to pass any kind of implicit parameters, instead of just Function1. Actual use for them then followed, and syntactic sugar for those uses came latter.

One of the are the Context Bounds, used to implement the type class pattern (pattern because it is not a built-in feature, just a way of using the language that provides similar functionality to Haskell's type class). A context bound is used to provide an adapter that implements a functionality that is inherent in a class, but not declared by it. It offers the benefits of inheritance and interfaces without their drawbacks. For example:

def max[T](a: T, b: T)(implicit $ev1: Ordering[T]): T = if ($ev1.lt(a, b)) b else a
// latter followed by the syntactic sugar
def max[T: Ordering](a: T, b: T): T = if (implicitly[Ordering[T]].lt(a, b)) b else a

You have probably used that already -- there's one common use case that people usually don't notice. It is this:

new Array[Int](size)

That uses a context bound of a class manifests, to enable such array initialization. We can see that with this example:

def f[T](size: Int) = new Array[T](size) // won't compile!

You can to write it like this:

def f[T: ClassManifest](size: Int) = new Array[T](size)

On the standard library, the context bounds most used are:

Manifest      // Provides reflection on a type
ClassManifest // Provides reflection on a type after erasure
Ordering      // Total ordering of elements
Numeric       // Basic arithmetic of elements
CanBuildFrom  // Collection creation

The latter three are mostly used with collections, with methods such as max, sum and map. One library that makes extensive use of context bounds is Scalaz.

Another common usage is to decrease boiler-plate on operations that must share a common parameter. For example, transactions:

def withTransaction(f: Transaction => Unit) = {
  val txn = new Transaction

  try { f(txn); txn.commit() }
  catch { case ex => txn.rollback(); throw ex }
}

withTransaction { txn =>
  op1(data)(txn)
  op2(data)(txn)
  op3(data)(txn)
}

Which is then simplified like this:

withTransaction { implicit txn =>
  op1(data)
  op2(data)
  op3(data)
}

This pattern is used with transactional memory, and I think (but I'm not sure) that the Scala I/O library uses it as well.

The third common usage I can think of is making proofs about the types that are being passed, which makes it possible to detect at compile time things that would, otherwise, result in run time exceptions. For example, see this definition on Option:

def flatten[B](implicit ev: A <:< Option[B]): Option[B]

That makes this possible:

scala> Option(Option(2)).flatten // compiles
res0: Option[Int] = Some(2)

scala> Option(2).flatten // does not compile!
<console>:8: error: Cannot prove that Int <:< Option[B].
              Option(2).flatten // does not compile!
                        ^

One library that makes extensive use of that feature is Shapeless.

I don't think the example of the Akka library fits in any of these four categories, but that's the whole point of generic features: people can use it in all sorts of way, instead of ways prescribed by the language designer.

If you like being prescribed to (like, say, Python does), then Scala is just not for you.

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2  
That book you are writing should be definitively in English! :-) Thank you for great post. –  greenoldman Mar 3 '12 at 10:41
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Sure. Akka's got a great example of it with respect to its Actors. When you're inside an Actor's receive method, you might want to send a message to another Actor. When you do this, Akka will bundle (by default) the current Actor as the sender of the message, like this:

trait ScalaActorRef { this: ActorRef =>
  ...

  def !(message: Any)(implicit sender: ActorRef = null): Unit

  ...
}

The sender is implicit. In the Actor there is a definition that looks like:

trait Actor {
  ...

  implicit val self = context.self

  ...
}

This creates the implicit value within the scope of your own code, and it allows you to do easy things like this:

someOtherActor ! SomeMessage

Now, you can do this as well, if you like:

someOtherActor.!(SomeMessage)(self)

or

someOtherActor.!(SomeMessage)(null)

or

someOtherActor.!(SomeMessage)(anotherActorAltogether)

But normally you don't. You just keep the natural usage that's made possible by the implicit value definition in the Actor trait. There are about a million other examples. The collection classes are a huge one. Try wandering around any non-trivial Scala library and you'll find a truckload.

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I think this is an even better example than Traversable.max type classes and the like. –  Debilski Mar 2 '12 at 9:54
    
This is a good example. To some degree I think implicit variables are a way to AVOID global variables and "god singletons" (in lack of a better word) but still keep your code more readable as you don't have to explicitly pass some basic plumbing (the above mentioned singletons). And then again you still can pass them explicitly in for example while testing. So I think in many cases they allow for looser coupling and cleaner code. –  vertti Mar 2 '12 at 9:57
    
@vertti, not exactly. I think the way C++ works is better here -- i.e. parameters per entire class and/or default arguments. For me idea that function sucks in an argument taken from somewhere by itself is very strange. –  greenoldman Mar 2 '12 at 11:26
1  
@Derek Wyatt, you are taking this too personally. "works better here" -- I hope I made myself clear what my metrics are, they are not the same as yours, so my "better" is not the same as your "better". You are glad you have implicits, I don't -- your example is great as mind-puzzle (and I am thankful for that) how to tackle the problem from another perspective. That's my POV, so please spare me the advices "learn the language you're coding in" (true, but not very polite -- patronizing is not welcome it any discussion). –  greenoldman Mar 2 '12 at 12:32
1  
@macias Oh crap! I'm really sorry, but my comment way up there should have read... I'm NOT patronizing you... I'm really not. Ugh... sorry about that. –  Derek Wyatt Mar 2 '12 at 19:07
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One example would be the comparison operations on Traversable[A]. E.g. max or sort:

def max[B >: A](implicit cmp: Ordering[B]) : A

These can only be sensibly defined when there is an operation < on A. So, without implicits we’d have to supply the context Ordering[B] every time we’d like to use this function. (Or give up type static checking inside max and risk a runtime cast error.)

If however, an implicit comparison type class is in scope, e.g. some Ordering[Int], we can just use it right away or simply change the comparison method by supplying some other value for the implicit parameter.

Of course, implicits may be shadowed and thus there may be situations in which the actual implicit which is in scope is not clear enough. For simple uses of max or sort it might indeed be sufficient to have a fixed ordering trait on Int and use some syntax to check whether this trait is available. But this would mean that there could be no add-on traits and every piece of code would have to use the traits which were originally defined.

Addition:
Response to the global variable comparison.

I think you’re correct that in a code snipped like

implicit val num = 2
implicit val item = "Orange"
def shopping(implicit num: Int, item: String) = {
  "I’m buying "+num+" "+item+(if(num==1) "." else "s.")
}

scala> shopping
res: java.lang.String = I’m buying 2 Oranges.

it may smell of rotten and evil global variables. The crucial point, however, is that there may be only one implicit variable per type in scope. Your example with two Ints is not going to work.

Also, this means that practically, implicit variables are employed only when there is a not necessarily unique yet distinct primary instance for a type. The self reference of an actor is a good example for such a thing. The type class example is another example. There may be dozens of algebraic comparisons for any type but there is one which is special. (On another level, the actual line number in the code itself might also make for a good implicit variable as long as it uses a very distinctive type.)

You normally don’t use implicits for everyday types. And with specialised types (like Ordering[Int]) there is not too much risk in shadowing them.

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Thank you, however this is actually counterexample -- this should be a "trait" of the collection instance. And then you could use max() which would use ordering of the collection or max(comparer) which would use custom one. –  greenoldman Mar 2 '12 at 11:22
2  
Sure, this would be possible. But it would also mean that one could not add another trait to, e.g. Int or any other pre-defined type whenever needed. (An oft-cited example is that of a semi group which might not be an original trait on Int, nor on String – and neither would it be possible to add this trait in a fixed form.) The problem is: There is no way to generalise a type over all possible traits. These is always code (type annotations) which have to be given ad-hoc or you lose type-safety. Implicit variables just reduce the boilerplate code for this. –  Debilski Mar 2 '12 at 11:39
    
Not Int's given collection of Int's, like List or Array. If you assume the elements are comparable and you write such implicit as above you could as well, define the order at the top of the class (like in C++). In C++ the namespace is not polluted with arbitrary names like "cmp" here, because you pass the value. –  greenoldman Mar 2 '12 at 11:51
    
Thank you for that addition, I cannot upvote you more, sorry :-) –  greenoldman Mar 2 '12 at 12:26
    
No problem with me. :) –  Debilski Mar 2 '12 at 12:53
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Implicit parameters are heavily used in the collection API. Many functions get an implicit CanBuildFrom, which ensures that you get the 'best' result collection implementation.

Without implicits you would either pass such a thing all the time, which would make normal usage cumbersome. Or use less specialized collections which would be annoying because it would mean you loose performance/power.

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Another good general usage of implicit parameters is to make the return type of a method depend on the type of some of the parameters passed to it. A good example, mentioned by Jens, is the collections framework, and methods like map, whose full signature usually is:

def map[B, That](f: (A) ⇒ B)(implicit bf: CanBuildFrom[GenSeq[A], B, That]): That

Note that the return type That is determined by the best fitting CanBuildFrom that the compiler can find.

For another example of this, see that answer. There, the return type of the method Arithmetic.apply is determined according to a certain implicit parameter type (BiConverter).

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Maybe I miss something. You cannot guess here for type That, so you have to specify it, right? Wouldn't it be the same, if you omit type That, and simply convert the result by hand: map(it => it.foo).toBar() instead of map[B,List[Bars]](it => it.foo) ? –  greenoldman Mar 2 '12 at 11:47
    
@macias: The latter one doesn't create an intermediate collection. When you call toBar explicitly, first a Foo must created which is then converted to a Bar. When there is a type parameter a Bar can created directly. –  sschaef Mar 2 '12 at 12:24
3  
@macias: If you convert it by hand, you’re doing it in a second step, afterwards. You may get a List in return and then need to traverse it again just to get a Set. By using the implicit ‘annotation’, it is possible for the map method to avoid initialising and populating the wrong collection in the first place. –  Debilski Mar 2 '12 at 12:27
1  
@macias: you don't have to spell out the type parameters to the map method - they can be inferred. val lf: List[Foo] = …; val sb: Set[Bar] = lf map (_.toBar) //no intermediate List[Bar] –  romusz Mar 3 '12 at 5:02
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It's easy, just remember:

  • to declare the variable to be passed in as implicit too
  • to declare all the implicit params after the non-implicit params in a separate ()

e.g.

def myFunction(): Int = {
  implicit val y: Int = 33
  implicit val z: Double = 3.3

  functionWithImplicit("foo") // calls functionWithImplicit("foo")(y, z)
}

def functionWithImplicit(foo: String)(implicit x: Int, d: Double) = // blar blar
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