There are a number of things going on here.
Numeric literals in Haskell are polymorphic; the type of the literal 5
really is Num a => a
. It can belong to any type that adheres to the Num
type class.
Addition is part of the Num
type class, so an addition of two numeric literals is still Num a => a
.
Interactive evaluation in ghci is very similar to evaluating actions in the IO monad. When you enter a bare expression, ghci acts as if you ran something like the following:
main = do
let it = 5 + 5
print it
It's not exactly like that, though, because in a program like that, inference would work over the entire do
expression body to find a specific type. When you enter a single line, it has to infer a type and compile something with only the context available as of the end of the line you entered. So the print
doesn't affect the type inferred for the let-binding, as it's not something you entered.
There's nothing in that program that would constrain it
to a particular instance of Num
or Show
; this means that it
is still a polymorphic value. Specifically, GHC compiles values with type class constraints to functions that accept a type class dictionary that provides the instance implementations required to meet the constraint. So, although it
looks like a monomorphic value, it is actually represented by GHC as a function. This was surprising to enough people that the dreaded "Monomorphism Restriction" was invented to prevent this kind of surprise. It disallows pattern bindings (such as this one) where an identifier is bound to a polymorphic type.
The Monomorphism Restriction is off by default in GHC now, and it has been off by default in GHCi since version 7.8.
See the GHC manual for more info.
Haskell provides a special bit of magic for polymorphic numbers; each module can make a default declaration that provides type defaulting rules for polymorphic numbers. At your ghci prompt, the defaulting rules made ghci choose 'Int' when it was forced to provide instance dictionaries to show it
in order to get to an IO action value.
Here's the relevant section in the Haskell 98 Report.
To sum it up: it
was bound to the expression 5 + 5
, which has type Num a => a
because that's the more general inferred type based on the polymorphic numeric literals.
Polymorphic values are represented as functions waiting for a typeclass dictionary. So evaluating it
at a particular instance doesn't force it to become monomorphic.
However, Haskell's type default rules allow it to pick a particular type when you implicitly print it
as part of the ghci interaction. It picks Int
and so it chooses the Int
type class instance dictionaries for Show
and Num
when forced to by print it
.
I hope that makes it somewhat less confusing!
By the way, here is an example of how you can get the same behavior outside of ghci by explicitly requesting the polymorphic let-binding. Without the type signature in this context, it will infer a monomorphic type for foo
and give a type error.
main = do
let foo :: Num a => a
foo = 5 + 5
let bar = 8 :: Double
let baz = 9 :: Int
print (foo + bar)
print (foo + baz)
This will compile and run, printing the following:
18.0
19
UPDATE:
Looking at the Real World Haskell example and the comment thread, some people included different ghci logs along with their ghc versions. Using that information, I looked at ghc release notes and found that starting in version 7.8, the Monomorphism Restriction was disabled in ghci by default.
If you run the following command, you'll re-enable the Monomorphism Restriction and in order to be friendly, ghci will default the binding to Integer rather than giving you either an error or a polymorphic binding:
Prelude> :set -XMonomorphismRestriction
Prelude> 5 + 5
10
Prelude> :t it
it :: Integer
Prelude>
(Bool, t, [Char], t1, [Bool])
can't make sense to you if you do not understand the first part. If it actually makes sense to you, what aret
andt2
?