# How does Haskell actually define the + function?

While reading Real world Haskell I came up with this note:

``````ghci> :info (+)
class (Eq a, Show a) => Num a where
(+) :: a -> a -> a
...
-- Defined in GHC.Num
infixl 6 +
``````

But how can Haskell define `+` as a non-native function? At some level you have to say that `2 + 3` will become assembler i.e. machine code.

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I understand this question as 'How can I define + as a non-native function without using assembly primitives at some level?'. Another possible variant is 'How actual Haskell implementation define +?'. Please edit your question to clarify which answer(s) you want. –  nponeccop Nov 18 '11 at 14:13

The `+` function is overloaded and for some types, like `Int` and `Double` the definition of `+` is something like

``````instance Num Int where
x + y = primAddInt x y
``````

where `primAddInt` is a function the compiler knows about and will generate machine code for.

The details of how this looks and works depends on the Haskell implementation you're looking at.

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In GHC, the corresponding function is `+# :: Int# -> Int# -> Int#`. Thus, the implementation is something like `I# a + I# b = I# (a +# b)` –  FUZxxl Nov 18 '11 at 16:40

It is in fact possible to define numbers without ANY native primitives. There are many ways, but the simplest is:

``````data Peano = Z | S Peano
``````

Then you can define `instance Num` for this type using pattern-matching. The second common representation of numbers is so called Church encoding using only functions (all numbers will be represented by some obscure functions, and + will 'add' two functions together to form third one).

Very interesting encodings are possible indeed. For example, you can represent arbitrary precision reals in [0,1) using sequences of bits:

``````data RealReal = RealReal Bool RealReal | RealEnd
``````

In GHC of course it is defined in a machine-specific way by using either primitives or FFI.

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That definition of `RealReal` is not very good if you want computable arithmetic. –  augustss Nov 18 '11 at 16:38
Where do you see problems? As long as we don't pattern match digits they are not computed. –  nponeccop Nov 18 '11 at 17:13
If you never plan to use any of the bits then you don't have to represent them at all. :) –  augustss Nov 18 '11 at 17:17
Assuming you are going to look at some initial segment of the bits then you run into trouble definition addition, because you cannot bound the lookahead to determine the carry. E.g., 0.010101... + 0.0010101... What's the first after the .? You would have to look infinitely far to determine it. Which means addition cannot produce even a single bit of the result. –  augustss Nov 18 '11 at 17:20
@nponeccop Streams of bits are a particular kind of Cauchy sequences, but they are unfortunately not closed under, for example, addition, as demonstrated by augustss above. –  Daniel Wagner Nov 18 '11 at 19:04