Copyright | (c) The University of Glasgow 2009 |
---|---|
License | see libraries/ghc-prim/LICENSE |
Maintainer | cvs-ghc@haskell.org |
Stability | internal |
Portability | non-portable (GHC Extensions) |
Safe Haskell | Safe-Inferred |
Language | Haskell2010 |
GHC type definitions. Use GHC.Exts from the base package instead of importing this module directly.
Synopsis
- data Bool
- data Char = C# Char#
- data Int = I# Int#
- data Word = W# Word#
- data Float = F# Float#
- data Double = D# Double#
- data Ordering
- newtype IO a = IO (State# RealWorld -> (# State# RealWorld, a #))
- isTrue# :: Int# -> Bool
- data SPEC
- data Nat
- data Symbol
- type family Any :: k where ...
- class a ~~ b
- class Coercible (a :: k) (b :: k)
- data TYPE (a :: RuntimeRep)
- data RuntimeRep
- type Type = TYPE 'LiftedRep
- data Constraint
- data VecCount
- data VecElem
- data Module = Module TrName TrName
- data TrName
- data TyCon = TyCon Word# Word# Module TrName Int# KindRep
- data TypeLitSort
- data KindRep
- type KindBndr = Int
- data Multiplicity
- type family MultMul (a :: Multiplicity) (b :: Multiplicity) :: Multiplicity where ...
Documentation
The character type Char
is an enumeration whose values represent
Unicode (or equivalently ISO/IEC 10646) code points (i.e. characters, see
http://www.unicode.org/ for details). This set extends the ISO 8859-1
(Latin-1) character set (the first 256 characters), which is itself an extension
of the ASCII character set (the first 128 characters). A character literal in
Haskell has type Char
.
To convert a Char
to or from the corresponding Int
value defined
by Unicode, use toEnum
and fromEnum
from the
Enum
class respectively (or equivalently ord
and
chr
).
A fixed-precision integer type with at least the range [-2^29 .. 2^29-1]
.
The exact range for a given implementation can be determined by using
minBound
and maxBound
from the Bounded
class.
Single-precision floating point numbers. It is desirable that this type be at least equal in range and precision to the IEEE single-precision type.
Instances
Eq Float # | Note that due to the presence of
Also note that
|
Ord Float # | Note that due to the presence of
Also note that, due to the same,
|
Defined in GHC.Classes |
Double-precision floating point numbers. It is desirable that this type be at least equal in range and precision to the IEEE double-precision type.
Instances
Eq Double # | Note that due to the presence of
Also note that
|
Ord Double # | Note that due to the presence of
Also note that, due to the same,
|
Defined in GHC.Classes |
Instances
Eq Ordering # | |
Ord Ordering # | |
Defined in GHC.Classes |
A value of type
is a computation which, when performed,
does some I/O before returning a value of type IO
aa
.
There is really only one way to "perform" an I/O action: bind it to
Main.main
in your program. When your program is run, the I/O will
be performed. It isn't possible to perform I/O from an arbitrary
function, unless that function is itself in the IO
monad and called
at some point, directly or indirectly, from Main.main
.
IO
is a monad, so IO
actions can be combined using either the do-notation
or the >>
and >>=
operations from the Monad
class.
isTrue# :: Int# -> Bool Source #
Alias for tagToEnum#
. Returns True if its parameter is 1# and False
if it is 0#.
SPEC
is used by GHC in the SpecConstr
pass in order to inform
the compiler when to be particularly aggressive. In particular, it
tells GHC to specialize regardless of size or the number of
specializations. However, not all loops fall into this category.
Libraries can specify this by using SPEC
data type to inform which
loops should be aggressively specialized.
(Kind) This is the kind of type-level symbols. Declared here because class IP needs it
type family Any :: k where ... Source #
The type constructor Any
is type to which you can unsafely coerce any
lifted type, and back. More concretely, for a lifted type t
and
value x :: t
, -- unsafeCoerce (unsafeCoerce x :: Any) :: t
is equivalent
to x
.
Lifted, heterogeneous equality. By lifted, we mean that it
can be bogus (deferred type error). By heterogeneous, the two
types a
and b
might have different kinds. Because ~~
can
appear unexpectedly in error messages to users who do not care
about the difference between heterogeneous equality ~~
and
homogeneous equality ~
, this is printed as ~
unless
-fprint-equality-relations
is set.
In 0.7.0
, the fixity was set to infix 4
to match the fixity of :~~:
.
class Coercible (a :: k) (b :: k) Source #
Coercible
is a two-parameter class that has instances for types a
and b
if
the compiler can infer that they have the same representation. This class
does not have regular instances; instead they are created on-the-fly during
type-checking. Trying to manually declare an instance of Coercible
is an error.
Nevertheless one can pretend that the following three kinds of instances exist. First, as a trivial base-case:
instance Coercible a a
Furthermore, for every type constructor there is
an instance that allows to coerce under the type constructor. For
example, let D
be a prototypical type constructor (data
or
newtype
) with three type arguments, which have roles nominal
,
representational
resp. phantom
. Then there is an instance of
the form
instance Coercible b b' => Coercible (D a b c) (D a b' c')
Note that the nominal
type arguments are equal, the
representational
type arguments can differ, but need to have a
Coercible
instance themself, and the phantom
type arguments can be
changed arbitrarily.
The third kind of instance exists for every newtype NT = MkNT T
and
comes in two variants, namely
instance Coercible a T => Coercible a NT
instance Coercible T b => Coercible NT b
This instance is only usable if the constructor MkNT
is in scope.
If, as a library author of a type constructor like Set a
, you
want to prevent a user of your module to write
coerce :: Set T -> Set NT
,
you need to set the role of Set
's type parameter to nominal
,
by writing
type role Set nominal
For more details about this feature, please refer to Safe Coercions by Joachim Breitner, Richard A. Eisenberg, Simon Peyton Jones and Stephanie Weirich.
Since: ghc-prim-4.7.0.0
data TYPE (a :: RuntimeRep) Source #
data RuntimeRep Source #
GHC maintains a property that the kind of all inhabited types
(as distinct from type constructors or type-level data) tells us
the runtime representation of values of that type. This datatype
encodes the choice of runtime value.
Note that TYPE
is parameterised by RuntimeRep
; this is precisely
what we mean by the fact that a type's kind encodes the runtime
representation.
For boxed values (that is, values that are represented by a pointer), a further distinction is made, between lifted types (that contain ⊥), and unlifted ones (that don't).
VecRep VecCount VecElem | a SIMD vector type |
TupleRep [RuntimeRep] | An unboxed tuple of the given reps |
SumRep [RuntimeRep] | An unboxed sum of the given reps |
LiftedRep | lifted; represented by a pointer |
UnliftedRep | unlifted; represented by a pointer |
IntRep | signed, word-sized value |
Int8Rep | signed, 8-bit value |
Int16Rep | signed, 16-bit value |
Int32Rep | signed, 32-bit value |
Int64Rep | signed, 64-bit value (on 32-bit only) |
WordRep | unsigned, word-sized value |
Word8Rep | unsigned, 8-bit value |
Word16Rep | unsigned, 16-bit value |
Word32Rep | unsigned, 32-bit value |
Word64Rep | unsigned, 64-bit value (on 32-bit only) |
AddrRep | A pointer, but not to a Haskell value |
FloatRep | a 32-bit floating point number |
DoubleRep | a 64-bit floating point number |
data Constraint Source #
The kind of constraints, like Show a
Element of a SIMD vector type
Runtime type representation
The representation produced by GHC for conjuring up the kind of a
TypeRep
.
Multiplicity Types
data Multiplicity Source #