Dependent method types, which used to be an experimental feature before, has now been enabled by default in the trunk, and apparently this seems to have created some excitement in the Scala community.

At first look, it's not immediately obvious what this could be useful for. Heiko Seeberger posted a simple example of dependent method types here, which as can be seen in the comment there can easily be reproduced with type parameters on methods. So that wasn't a very compelling example. (I might be missing something obvious. Please correct me if so.)

What are some practical and useful examples of use cases for dependent method types where they are clearly advantageous over the alternatives?

What interesting things can we do with them that weren't possible/easy before?

What do they buy us over the existing type system features?

Also, are dependent method types analogous to or drawing inspiration from any features found in the type systems of other advanced typed languages such as Haskell, OCaml?

  • You may be interested in perusing haskell.org/haskellwiki/Dependent_type
    – Dan Burton
    Oct 22, 2011 at 19:09
  • Thanks for the link, Dan! I am aware of dependent types in general, but the concept of dependent method types is relatively new to me. Oct 22, 2011 at 19:54
  • It seems to me that "dependent method types" are simply types which are dependent on one or more of a method's input types (including the type of the object upon which the method is invoked); nothing crazy there beyond the general idea of dependent types. Perhaps I'm missing something?
    – Dan Burton
    Oct 22, 2011 at 20:43
  • No, you didn't, but apparently I did. :-) I didn't see the link between the two before. It's crystal clear now though. Oct 22, 2011 at 20:45

4 Answers 4


More or less any use of member (ie. nested) types can give rise to a need for dependent method types. In particular, I maintain that without dependent method types the classic cake pattern is closer to being an anti-pattern.

So what's the problem? Nested types in Scala are dependent on their enclosing instance. Consequently, in the absence of dependent method types, attempts to use them outside of that instance can be frustratingly difficult. This can turn designs which initially seem elegant and appealing into monstrosities which are nightmarishly rigid and difficult to refactor.

I'll illustrate that with an exercise I give during my Advanced Scala training course,

trait ResourceManager {
  type Resource <: BasicResource
  trait BasicResource {
    def hash : String
    def duplicates(r : Resource) : Boolean
  def create : Resource

  // Test methods: exercise is to move them outside ResourceManager
  def testHash(r : Resource) = assert(r.hash == "9e47088d")  
  def testDuplicates(r : Resource) = assert(r.duplicates(r))

trait FileManager extends ResourceManager {
  type Resource <: File
  trait File extends BasicResource {
    def local : Boolean
  override def create : Resource

class NetworkFileManager extends FileManager {
  type Resource = RemoteFile
  class RemoteFile extends File {
    def local = false
    def hash = "9e47088d"
    def duplicates(r : Resource) = (local == r.local) && (hash == r.hash)
  override def create : Resource = new RemoteFile

It's an example of the classic cake pattern: we have a family of abstractions which are gradually refined through a heirarchy (ResourceManager/Resource are refined by FileManager/File which are in turn refined by NetworkFileManager/RemoteFile). It's a toy example, but the pattern is real: it's used throughout the Scala compiler and was used extensively in the Scala Eclipse plugin.

Here's an example of the abstraction in use,

val nfm = new NetworkFileManager
val rf : nfm.Resource = nfm.create

Note that the path dependency means that the compiler will guarantee that the testHash and testDuplicates methods on NetworkFileManager can only be called with arguments which correspond to it, ie. it's own RemoteFiles, and nothing else.

That's undeniably a desirable property, but suppose we wanted to move this test code to a different source file? With dependent method types it's trivially easy to redefine those methods outside the ResourceManager hierarchy,

def testHash4(rm : ResourceManager)(r : rm.Resource) = 
  assert(r.hash == "9e47088d")

def testDuplicates4(rm : ResourceManager)(r : rm.Resource) = 

Note the uses of dependent method types here: the type of the second argument (rm.Resource) depends on the value of the first argument (rm).

It is possible to do this without dependent method types, but it's extremely awkward and the mechanism is quite unintuitive: I've been teaching this course for nearly two years now, and in that time, noone has come up with a working solution unprompted.

Try it for yourself ...

// Reimplement the testHash and testDuplicates methods outside
// the ResourceManager hierarchy without using dependent method types
def testHash        // TODO ... 
def testDuplicates  // TODO ...


After a short while struggling with it you'll probably discover why I (or maybe it was David MacIver, we can't remember which of us coined the term) call this the Bakery of Doom.

Edit: consensus is that Bakery of Doom was David MacIver's coinage ...

For the bonus: Scala's form of dependent types in general (and dependent method types as a part of it) was inspired by the programming language Beta ... they arise naturally from Beta's consistent nesting semantics. I don't know of any other even faintly mainstream programming language which has dependent types in this form. Languages like Coq, Cayenne, Epigram and Agda have a different form of dependent typing which is in some ways more general, but which differs significantly by being part of type systems which, unlike Scala, don't have subtyping.

  • 2
    It was David MacIver who coined the term, but in any case, it's quite descriptive. This is a fantastic explanation of why dependent method types are so exciting. Nice work! Oct 22, 2011 at 19:03
  • It came up initially in conversation between the two of us on #scala quite some time ago ... like I said I can't remember which of us it was who said it first. Oct 22, 2011 at 19:09
  • Seems my memory was playing tricks on me ... consensus is it was David MacIver's coinage. Oct 23, 2011 at 0:50
  • Yeah, I wasn't there (on #scala) at the time, but Jorge was and that's where I was getting my information. Oct 26, 2011 at 15:20
  • Utilizing abstract type member refinement I was able to implement the testHash4 function fairly painlessly. def testHash4[R <: ResourceManager#BasicResource](rm: ResourceManager { type Resource = R }, r: R) = assert(r.hash == "9e47088d") I suppose this can be considered another form of dependent types, though. Jan 10, 2015 at 6:56
trait Graph {
  type Node
  type Edge
  def end1(e: Edge): Node
  def end2(e: Edge): Node
  def nodes: Set[Node]
  def edges: Set[Edge]

Somewhere else we can statically guarantee that we aren't mixing up nodes from two different graphs, e.g.:

def shortestPath(g: Graph)(n1: g.Node, n2: g.Node) = ... 

Of course, this already worked if defined inside Graph, but say we can't modify Graph and are writing a "pimp my library" extension for it.

About the second question: types enabled by this feature are far weaker than complete dependent types (See Dependently Typed Programming in Agda for a flavor of that.) I don't think I've seen an analogy before.


This new feature is needed when concrete abstract type members are used instead of type parameters. When type parameters are used, the family polymorphism type dependency can be expressed in the latest and some older versions of Scala, as in the following simplified example.

trait C[A]
def f[M](a: C[M], b: M) = b
class C1 extends C[Int]
class C2 extends C[String]

f(new C1, 0)
res0: Int = 0
f(new C2, "")
res1: java.lang.String = 
f(new C1, "")
error: type mismatch;
 found   : C1
 required: C[Any]
       f(new C1, "")
  • This is unrelated. With type members you can use refinements for the same result: trait C {type A}; def f[M](a: C { type A = M}, b: M) = 0;class CI extends C{type A=Int};class CS extends C{type A=String} etc.
    – nafg
    Oct 7, 2013 at 23:26
  • In any case this has nothing to do with dependent method types. Take for instance Alexey's example (stackoverflow.com/a/7860821/333643). Using your approach (including the refinement version I commented) does not achieve the goal. It will ensure that n1.Node =:= n2.Node, but it won't ensure they are both in the same graph. IIUC DMT does ensure this.
    – nafg
    Oct 7, 2013 at 23:31
  • @nafg Thanks for pointing that out. I've added the word concrete to make it clear I wasn't referring to the refinement case for type members. As far as I can see, this is still a valid use-case for dependent method types in spite of your point (which I was aware of) that they can have more power in other use cases. Or did I miss the fundamental essence of your second comment? Nov 1, 2013 at 11:39

I'm developing a model for the interoption of a form of declarative programming with environmental state. The details aren't relevant here (e.g. details about callbacks and conceptual similarity to the Actor model combined with a Serializer).

The relevant issue is state values are stored in a hash map and referenced by a hash key value. Functions input immutable arguments that are values from the environment, may call other such functions, and write state to the environment. But functions are not allowed to read values from the environment (so the internal code of the function is not dependent on the order of state changes and thus remains declarative in that sense). How to type this in Scala?

The environment class must have an overloaded method which inputs such a function to call, and inputs the hash keys of the arguments of the function. Thus this method can call the function with the necessary values from the hash map, without providing public read access to the values (thus as required, denying functions the ability to read values from the environment).

But if these hash keys are strings or integer hash values, the static typing of the hash map element type subsumes to Any or AnyRef (hash map code not shown below), and thus a run-time mismatch could occur, i.e. it would be possible to put any type of value in a hash map for a given hash key.

trait Env {
  def callit[A](func: Env => Any => A, arg1key: String): A
  def callit[A](func: Env => Any => Any => A, arg1key: String, arg2key: String): A

Although I didn't test the following, in theory I can get the hash keys from class names at runtime employing classOf, so a hash key is a class name instead of a string (using Scala's backticks to embed a string in a class name).

trait DependentHashKey {
  type ValueType
trait `the hash key string` extends DependentHashKey {
  type ValueType <: SomeType

So static type safety is achieved.

def callit[A](arg1key: DependentHashKey)(func: Env => arg1key.ValueType => A): A
  • When we need to pass the argument keys around in a single value, I didn't test, but assume we can use a Tuple, e.g. for the 2 argument overload def callit[A](argkeys: Tuple[DependentHashKey,DependentHashKey])(func: Env => argkeys._0.ValueType => argkeys._1.ValueType => A): A. We wouldn't use a collection of argument keys, because the element types would be subsumed (unknown at compile-time) in the type of collection. Feb 8, 2012 at 3:46
  • "the static typing of the hash map element type subsumes to Any or AnyRef" - I don't follow. When you say element type do you mean key type or value type (i.e. first or second type argument to HashMap)? And why would it get subsumed? May 12, 2012 at 14:45
  • @RobinGreen The type of the values in the hash table. Afair, subsumed because you can't put more than one type in a collection in Scala unless you subsume to their common supertype, because Scala doesn't have a union (disjunction) type. See my Q&A on subsumption in Scala. May 19, 2012 at 0:26

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.