Scala syntax has a lot of symbols. Since these kinds of names are difficult to find using search engines, a comprehensive list of them would be helpful.

What are all of the symbols in Scala, and what does each of them do?

In particular, I'd like to know about ->, ||=, ++=, <=, _._, ::, and :+=.

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I divide the operators, for the purpose of teaching, into four categories:

  • Keywords/reserved symbols
  • Automatically imported methods
  • Common methods
  • Syntactic sugars/composition

It is fortunate, then, that most categories are represented in the question:

->    // Automatically imported method
||=   // Syntactic sugar
++=   // Syntactic sugar/composition or common method
<=    // Common method
_._   // Typo, though it's probably based on Keyword/composition
::    // Common method
:+=   // Common method

The exact meaning of most of these methods depend on the class that is defining them. For example, <= on Int means "less than or equal to". The first one, ->, I'll give as example below. :: is probably the method defined on List (though it could be the object of the same name), and :+= is probably the method defined on various Buffer classes.

So, let's see them.

Keywords/reserved symbols

There are some symbols in Scala that are special. Two of them are considered proper keywords, while others are just "reserved". They are:

// Keywords
<-  // Used on for-comprehensions, to separate pattern from generator
=>  // Used for function types, function literals and import renaming

// Reserved
( )        // Delimit expressions and parameters
[ ]        // Delimit type parameters
{ }        // Delimit blocks
.          // Method call and path separator
// /* */   // Comments
#          // Used in type notations
:          // Type ascription or context bounds
<: >: <%   // Upper, lower and view bounds
<? <!      // Start token for various XML elements
" """      // Strings
'          // Indicate symbols and characters
@          // Annotations and variable binding on pattern matching
`          // Denote constant or enable arbitrary identifiers
,          // Parameter separator
;          // Statement separator
_*         // vararg expansion
_          // Many different meanings

These are all part of the language, and, as such, can be found in any text that properly describe the language, such as Scala Specification(PDF) itself.

The last one, the underscore, deserve a special description, because it is so widely used, and has so many different meanings. Here's a sample:

import scala._    // Wild card -- all of Scala is imported
import scala.{ Predef => _, _ } // Exception, everything except Predef
def f[M[_]]       // Higher kinded type parameter
def f(m: M[_])    // Existential type
_ + _             // Anonymous function placeholder parameter
m _               // Eta expansion of method into method value
m(_)              // Partial function application
_ => 5            // Discarded parameter
case _ =>         // Wild card pattern -- matches anything
f(xs: _*)         // Sequence xs is passed as multiple parameters to f(ys: T*)
case Seq(xs @ _*) // Identifier xs is bound to the whole matched sequence

I probably forgot some other meaning, though.

Automatically imported methods

So, if you did not find the symbol you are looking for in the list above, then it must be a method, or part of one. But, often, you'll see some symbol and the documentation for the class will not have that method. When this happens, either you are looking at a composition of one or more methods with something else, or the method has been imported into scope, or is available through an imported implicit conversion.

These can still be found on ScalaDoc: you just have to know where to look for them. Or, failing that, look at the index (presently broken on 2.9.1, but available on nightly).

Every Scala code has three automatic imports:

// Not necessarily in this order
import _root_.java.lang._      // _root_ denotes an absolute path
import _root_.scala._
import _root_.scala.Predef._

The first two only make classes and singleton objects available. The third one contains all implicit conversions and imported methods, since Predef is an object itself.

Looking inside Predef quickly show some symbols:

class <:<
class =:=
object <%<
object =:=

Any other symbol will be made available through an implicit conversion. Just look at the methods tagged with implicit that receive, as parameter, an object of type that is receiving the method. For example:

"a" -> 1  // Look for an implicit from String, AnyRef, Any or type parameter

In the above case, -> is defined in the class ArrowAssoc through the method any2ArrowAssoc that takes an object of type A, where A is an unbounded type parameter to the same method.

Common methods

So, many symbols are simply methods on a class. For instance, if you do

List(1, 2) ++ List(3, 4)

You'll find the method ++ right on the ScalaDoc for List. However, there's one convention that you must be aware when searching for methods. Methods ending in colon (:) bind to the right instead of the left. In other words, while the above method call is equivalent to:

List(1, 2).++(List(3, 4))

If I had, instead 1 :: List(2, 3), that would be equivalent to:

List(2, 3).::(1)

So you need to look at the type found on the right when looking for methods ending in colon. Consider, for instance:

1 +: List(2, 3) :+ 4

The first method (+:) binds to the right, and is found on List. The second method (:+) is just a normal method, and binds to the left -- again, on List.

Syntactic sugars/composition

So, here's a few syntactic sugars that may hide a method:

class Example(arr: Array[Int] = Array.fill(5)(0)) {
  def apply(n: Int) = arr(n)
  def update(n: Int, v: Int) = arr(n) = v
  def a = arr(0); def a_=(v: Int) = arr(0) = v
  def b = arr(1); def b_=(v: Int) = arr(1) = v
  def c = arr(2); def c_=(v: Int) = arr(2) = v
  def d = arr(3); def d_=(v: Int) = arr(3) = v
  def e = arr(4); def e_=(v: Int) = arr(4) = v
  def +(v: Int) = new Example(arr map (_ + v))
  def unapply(n: Int) = if (arr.indices contains n) Some(arr(n)) else None

val Ex = new Example // or var for the last example
println(Ex(0))  // calls apply(0)
Ex(0) = 2       // calls update(0, 2)
Ex.b = 3        // calls b_=(3)
// This requires Ex to be a "val"
val Ex(c) = 2   // calls unapply(2) and assigns result to c
// This requires Ex to be a "var"
Ex += 1         // substituted for Ex = Ex + 1

The last one is interesting, because any symbolic method can be combined to form an assignment-like method that way.

And, of course, there's various combinations that can appear in code:

(_+_) // An expression, or parameter, that is an anonymous function with
      // two parameters, used exactly where the underscores appear, and
      // which calls the "+" method on the first parameter passing the
      // second parameter as argument.
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  • 1
    Did you mean val c = ex(2) instead of val ex(c) = 2? – Mike Stay Mar 7 '14 at 14:32
  • 3
    @MikeStay No, I did mean val ex(c) = 2. – Daniel C. Sobral Mar 7 '14 at 16:43
  • Oh, it's using pattern matching syntax. Thanks. – Mike Stay Mar 7 '14 at 20:25
  • => also confers 'call by name' status when used between : and type as in y: => Int' – Stephen W. Wright Nov 15 '14 at 18:15
  • 1
    Maybe one should also mention the :/ and :\ really unintuitive operators. So map.foldLeft( initialVal) is the same as ( initialVal :/ map ) - :\ is foldRight instead. – Mr MT Oct 26 '16 at 18:07

One (good, IMO) difference between Scala and other languages is that it lets you name your methods with almost any character.

What you enumerate is not "punctuation" but plain and simple methods, and as such their behavior vary from one object to the other (though there are some conventions).

For example, check the Scaladoc documentation for List, and you'll see some of the methods you mentioned here.

Some things to keep in mind:

  • Most of the times the A operator+equal B combination translates to A = A operator B, like in the ||= or ++= examples.

  • Methods that end in : are right associative, this means that A :: B is actually B.::(A).

You'll find most answers by browsing the Scala documentation. Keeping a reference here would duplicate efforts, and it would fall behind quickly :)

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You can group those first according to some criteria. In this post I will just explain the underscore character and the right-arrow.

_._ contains a period. A period in Scala always indicates a method call. So left of the period you have the receiver, and right of it the message (method name). Now _ is a special symbol in Scala. There are several posts about it, for example this blog entry all use cases. Here it is an anonymous function short cut, that is it a shortcut for a function that takes one argument and invokes the method _ on it. Now _ is not a valid method, so most certainly you were seeing _._1 or something similar, that is, invoking method _._1 on the function argument. _1 to _22 are the methods of tuples which extract a particular element of a tuple. Example:

val tup = ("Hallo", 33)
tup._1 // extracts "Hallo"
tup._2 // extracts 33

Now lets assume a use case for the function application shortcut. Given a map which maps integers to strings:

val coll = Map(1 -> "Eins", 2 -> "Zwei", 3 -> "Drei")

Wooop, there is already another occurrence of a strange punctuation. The hyphen and greater-than characters, which resemble a right-hand arrow, is an operator which produces a Tuple2. So there is no difference in the outcome of writing either (1, "Eins") or 1 -> "Eins", only that the latter is easier to read, especially in a list of tuples like the map example. The -> is no magic, it is, like a few other operators, available because you have all implicit conversions in object scala.Predef in scope. The conversion which takes place here is

implicit def any2ArrowAssoc [A] (x: A): ArrowAssoc[A] 

Where ArrowAssoc has the -> method which creates the Tuple2. Thus 1 -> "Eins" is actual the call Predef.any2ArrowAssoc(1).->("Eins"). Ok. Now back to the original question with the underscore character:

// lets create a sequence from the map by returning the
// values in reverse.
coll.map(_._2.reverse) // yields List(sniE, iewZ, ierD)

The underscore here shortens the following equivalent code:

coll.map(tup => tup._2.reverse)

Note that the map method of a Map passes in the tuple of key and value to the function argument. Since we are only interested in the values (the strings), we extract them with the _2 method on the tuple.

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  • +1 I was having trouble trying to understand the -> method but your sentence "So there is no difference in the outcome of writing either (1, "Eins") or 1 -> "Eins"" helped me comprehend the syntax and its usage. – Jesse Webb Jun 26 '13 at 21:18
  • fyi your blog entry link is dead – still_learning Apr 17 at 20:44

As an addition to brilliant answers of Daniel and 0__, I have to say that Scala understands Unicode analogs for some of the symbols, so instead of

for (n <- 1 to 10) n % 2 match {
  case 0 => println("even")
  case 1 => println("odd")

one may write

for (n ← 1 to 10) n % 2 match {
  case 0 ⇒ println("even")
  case 1 ⇒ println("odd")
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Regarding :: there is another Stackoverflow entry which covers the :: case. In short, it is used to construct Lists by 'consing' a head element and a tail list. It is both a class which represents a cons'ed list and which can be used as an extractor, but most commonly it is a method on a list. As Pablo Fernandez points out, since it ends in a colon, it is right associative, meaning the receiver of the method call is to the right, and the argument to the left of the operator. That way you can elegantly express the consing as prepending a new head element to an existing list:

val x = 2 :: 3 :: Nil  // same result as List(2, 3)
val y = 1 :: x         // yields List(1, 2, 3)

This is equivalent to

val x = Nil.::(3).::(2) // successively prepend 3 and 2 to an empty list
val y = x.::(1)         // then prepend 1

The use as extractor object is as follows:

def extract(l: List[Int]) = l match {
   case Nil          => "empty"
   case head :: Nil  => "exactly one element (" + head + ")"
   case head :: tail => "more than one element"

extract(Nil)          // yields "empty"
extract(List(1))      // yields "exactly one element (1)"
extract(List(2, 3))   // yields "more than one element"

This looks like an operator here, but it is really just another (more readable) way of writing

def extract2(l: List[Int]) = l match {
   case Nil            => "empty"
   case ::(head, Nil)  => "exactly one element (" + head + ")"
   case ::(head, tail) => "more than one element"

You can read more about extractors in this post.

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<= is just like you would "read" it: 'less than or equals'. So it's a mathematical operator, in the list of < (is less than?), > (is greater than?), == (equals?), != (is not equal?), <= (is less than or equal?), and >= (is greater than or equal?).

This must not be confused with => which is kind of a double right-hand arrow, used to separate the argument list from the body of a function and to separate the testing condition in pattern matching (a case block) from the body executed when a match occurs. You can see example of this in my previous two answers. First, the function use:

coll.map(tup => tup._2.reverse)

which is already abbreviated as the types are omitted. The follow function would be

// function arguments         function body
(tup: Tuple2[Int, String]) => tup._2.reverse

and the pattern matching use:

def extract2(l: List[Int]) = l match {
   // if l matches Nil    return "empty"
   case Nil            => "empty"
   // etc.
   case ::(head, Nil)  => "exactly one element (" + head + ")"
   // etc.
   case ::(head, tail) => "more than one element"
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  • 4
    Avoiding this confusion is why I decided to start using the unicode characters for right double arrow (\U21D2), the single right "maps" arrow (\U2192), and the left single "in" arrow (\U2190). Scala supports this but I was a little skeptical until I tried it for a while. Just look up how to bind these code points to a convenient key combination on your system. It was really easy on OS X. – Connor Doyle Oct 25 '11 at 14:36

I consider a modern IDE to be critical for understanding large scala projects. Since these operators are also methods, in intellij idea I just control-click or control-b into the definitions.

You can control-click right into a cons operator (::) and end up at the scala javadoc saying "Adds an element at the beginning of this list." In user-defined operators, this becomes even more critical, since they could be defined in hard-to-find implicits... your IDE knows where the implicit was defined.

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Just adding to the other excellent answers. Scala offers two often criticized symbolic operators, /: (foldLeft) and :\ (foldRight) operators, the first being right-associative. So the following three statements are the equivalent:

( 1 to 100 ).foldLeft( 0, _+_ )
( 1 to 100 )./:( 0 )( _+_ )
( 0 /: ( 1 to 100 ) )( _+_ )

As are these three:

( 1 to 100 ).foldRight( 0, _+_ )
( 1 to 100 ).:\( 0 )( _+_ )
( ( 1 to 100 ) :\ 0 )( _+_ )
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Scala inherits most of Java's arithmetic operators. This includes bitwise-or | (single pipe character), bitwise-and &, bitwise-exclusive-or ^, as well as logical (boolean) or || (two pipe characters) and logical-and &&. Interestingly, you can use the single character operators on boolean, so the java'ish logical operators are totally redundant:

true && true   // valid
true & true    // valid as well

3 & 4          // bitwise-and (011 & 100 yields 000)
3 && 4         // not valid

As pointed out in another post, calls ending in an equals sign =, are resolved (if a method with that name does not exist!) by a reassignment:

var x = 3
x += 1         // `+=` is not a method in `int`, Scala makes it `x = x + 1`

This 'double-check' makes it possible, to easily exchange a mutable for an immutable collection:

val m = collection.mutable.Set("Hallo")   // `m` a val, but holds mutable coll
var i = collection.immutable.Set("Hallo") // `i` is a var, but holds immutable coll

m += "Welt" // destructive call m.+=("Welt")
i += "Welt" // re-assignment i = i + "Welt" (creates a new immutable Set)
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  • 4
    P.S. There is a difference between using the single vs. double character operators on booleans—the former is eager (all terms are evaluated), the latter terminates early if the resulting boolean is known: true | { println( "Icke" ); true } ⇒ prints! true || { println( "Icke" ); true } ⇒ does not print! – 0__ Sep 22 '12 at 17:00

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