In Haskell, what is the difference between an
Int and an
Integer? Where is the answer documented?
"Integer" is an arbitrary precision type: it will hold any number no matter how big, up to the limit of your machine's memory…. This means you never have arithmetic overflows. On the other hand it also means your arithmetic is relatively slow. Lisp users may recognise the "bignum" type here.
"Int" is the more common 32 or 64 bit integer. Implementations vary, although it is guaranteed to be at least 30 bits.
Bounded, which means that you can use
maxBound to find out the limits, which are implementation-dependent but guaranteed to hold at least [-229 .. 229-1].
Prelude> (minBound, maxBound) :: (Int, Int) (-9223372036854775808,9223372036854775807)
Integer is arbitrary precision, and not
Prelude> (minBound, maxBound) :: (Integer, Integer) <interactive>:3:2: No instance for (Bounded Integer) arising from a use of `minBound' Possible fix: add an instance declaration for (Bounded Integer) In the expression: minBound In the expression: (minBound, maxBound) :: (Integer, Integer) In an equation for `it': it = (minBound, maxBound) :: (Integer, Integer)
Int is the type of machine integers, with guaranteed range at least -229 to 229 - 1, while Integer is arbitrary precision integers, with range as large as you have memory for.
Int is the C int, which means its values range from -2147483647 to 2147483647, while an Integer range from the whole Z set, that means, it can be arbitrarily large.
$ ghci Prelude> (12345678901234567890 :: Integer, 12345678901234567890 :: Int) (12345678901234567890,-350287150)
Notice the value of the Int literal.
The Prelude defines only the most basic numeric types: fixed sized integers (Int), arbitrary precision integers (Integer), ...
The finite-precision integer type Int covers at least the range [ - 2^29, 2^29 - 1].
from the Haskell report: http://www.haskell.org/onlinereport/basic.html#numbers
Integer is implemented as an
Int# until it gets larger than the maximum value an
Int# can store. At that point, it's a GMP number.
Integer allows for more aggressive optimizations because it is not as constrained by undefined behavior as a result of overflows.
ie, the compiler must assume the expression as written won't ever experience undefined behavior, and that any potential optimizations the compiler introduces won't also introduce new undefined behavior.
or another way
a - (b - c) is algebraically equivalent to
(a + c) - b but the compiler can not do that rearrangement because it is possible that the intermediate value
a + c will overflow with inputs which would not cause an overflow in the original.