Internal modules are generally modules that expose the internals of a package, that break package encapsulation.
ByteString as an example: When you normally use
ByteStrings, they are used as opaque data types; a
ByteString value is atomic, and its representation is uninteresting. All of the functions in
Data.ByteString take values of
ByteString, and never raw
Ptr CChars or something.
This is a good thing; it means that the
ByteString authors managed to make the representation abstract enough that all the details about the
ByteString can be hidden completely from the user. Such a design leads to encapsulation of functionality.
Internal modules are for people that wish to work with the internals of an encapsulated concept, to widen the encapsulation.
For example, you might want to make a new
BitString data type, and you want users to be able to convert a
ByteString into a
BitString without copying any memory. In order to do this, you can't use opaque
ByteStrings, because that doesn't give you access to the memory that represents the
ByteString. You need access to the raw memory pointer to the byte data. This is what the
Internal module for
You should then make your
BitString data type encapsulated as well, thus widening the encapsulation without breaking it. You are then free to provide your own
BitString.Internal module, exposing the innards of your data type, for users that might want to inspect its representation in turn.
If someone does not provide an
Internal module (or similar), you can't gain access to the module's internal representation, and the user writing e.g.
BitString is forced to (ab)use things like
unsafeCoerce to cast memory pointers, and things get ugly.
The definitions that should be put in an
Internal module are the actual data declarations for your data types:
module Bla.Internal where
data Bla = Blu Int | Bli String
module Bla (Bla, makeBla) where -- ONLY export the Bla type, not the constructors
makeBla :: String -> Bla -- Some function only dealing with the opaque type
makeBla = undefined