I saw this snippet at the devlog of omegagb:

data ExecutionAST result where
  Return :: result -> ExecutionAST result
  Bind :: (ExecutionAST oldres) -> (oldres -> ExecutionAST result) ->
          ExecutionAST result
  WriteRegister :: M_Register -> Word8 -> ExecutionAST ()
  ReadRegister :: M_Register -> ExecutionAST Word8
  WriteRegister2 :: M_Register2 -> Word16 -> ExecutionAST ()
  ReadRegister2 :: M_Register2 -> ExecutionAST Word16
  WriteMemory :: Word16 -> Word8 -> ExecutionAST ()
  ReadMemory :: Word16 -> ExecutionAST Word8

What does the data ... where mean? I thought the keyword data is used to define a new type.


It defines a new type, the syntax is called generalized algebraic data type.

It is more general than the normal syntax. You can write any normal type definition (ADT) using GADTs:

data E a = A a | B Integer

can be written as:

data E a where
  A :: a -> E a
  B :: Integer -> E a

But you can also restrict what is on right hand side:

data E a where
  A :: a -> E a
  B :: Integer -> E a
  C :: Bool -> E Bool

which is not possible with a normal ADT declaration.

For more, check Haskell wiki or this video.

The reason is type safety. ExecutionAST t is supposed to be type of statements returning t. If you write a normal ADT

data ExecutionAST result = Return result 
                         | WriteRegister M_Register Word8
                         | ReadRegister M_Register
                         | ReadMemory Word16
                         | WriteMemory Word16
                         | ...

then ReadMemory 5 will be a polymorphic value of type ExecutionAST t, instead of monomorphic ExecutionAST Word8, and this will type check:

x :: M_Register2
x = ...

a = Bind (ReadMemory 1) (WriteRegister2 x)

That statement should read memory from location 1 and write to register x. However, reading from memory gives 8-bit words, and writing to x requires 16-bit words. By using a GADT, you can be sure this won't compile. Compile-time errors are better than run-time errors.

GADTs also include existential types. If you tried to write bind this way:

data ExecutionAST result = ... 
                           | Bind (ExecutionAST oldres)
                                  (oldres -> ExecutionAST result)

then it won't compile since "oldres" is not in scope, you have to write:

data ExecutionAST result = ...
                           | forall oldres. Bind (ExecutionAST oldres)
                                                 (oldres -> ExecutionAST result)

If you are confused, check the linked video for simpler, related example.

| improve this answer | |
  • Can some one explain to me, why GADT is needed here? – wliao Nov 24 '11 at 7:27
  • @wliao: Added an explanation. – sdcvvc Nov 24 '11 at 11:59
  • I find your explanation is better than the video clip. Thanks. – wliao Nov 24 '11 at 13:18

Note that it is also possible to put class constraints:

data E a where
  A :: Eq b => b -> E b
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  • 10
    And more importantly, unlike in regular data declarations, this actually causes the instance dictionary to be stored in the type, allowing you to recover it through pattern matching, just like with existential types. – hammar Nov 23 '11 at 17:10
  • 2
    @hammar I don't understand what your comment imply. I don't understand this wording (with my rephrasing) 'to recover the instance dictionary through pattern matching because it is stored in the type'. When I pattern match, I deconstruct according the shape of the structure, and I don't see how this translates to a "instance dictionary", and why it is different that it is store in the type. What should I read/learn to understand the sense of this ? – Stephane Rolland Jun 17 '18 at 19:06

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