module Data.Array.Knead.Index.Linear.Int (
Single(..),
Int(Int), cons, decons,
) where
import qualified Data.Array.Knead.Expression as Expr
import qualified LLVM.Extra.Multi.Value as MultiValue
import qualified LLVM.Extra.Arithmetic as A
import Data.Word (Word32, )
import Prelude hiding (Int, head, tail, )
newtype Int = Int Word32
cons :: (Expr.Value val) => val Word32 -> val Int
cons = Expr.lift1 $ \(MultiValue.Cons x) -> MultiValue.Cons x
decons :: (Expr.Value val) => val Int -> val Word32
decons = Expr.lift1 $ \(MultiValue.Cons x) -> MultiValue.Cons x
class Single ix where
switchSingle :: f Int -> f ix
instance Single Int where
switchSingle x = x
instance MultiValue.C Int where
type Repr f Int = f Word32
cons (Int x) = MultiValue.consPrimitive x
undef = MultiValue.undefPrimitive
zero = MultiValue.zeroPrimitive
phis = MultiValue.phisPrimitive
addPhis = MultiValue.addPhisPrimitive
instance MultiValue.Additive Int where
add = MultiValue.liftM2 A.add
sub = MultiValue.liftM2 A.sub
neg = MultiValue.liftM A.neg
instance MultiValue.PseudoRing Int where
mul = MultiValue.liftM2 A.mul
instance MultiValue.Real Int where
min = MultiValue.liftM2 A.min
max = MultiValue.liftM2 A.max
abs = MultiValue.liftM A.abs
signum = MultiValue.liftM A.signum
instance MultiValue.IntegerConstant Int where
fromInteger' = cons . A.fromInteger'
instance MultiValue.Comparison Int where
cmp mode = MultiValue.liftM2 $ A.cmp mode