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Quite a few more bang files for testing.

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This commit is contained in:
Adam Wick
2011-02-03 20:26:09 -05:00
parent bc435d83f8
commit 17ca2f7899
6 changed files with 396 additions and 20 deletions
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132
bsrc/Control/Monad.bs Normal file
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module Control.Monad
import Data.Number
export class Monad m {
(>>=)(left :: m a, right :: a -> m b) :: m b;
(>>)(left :: m a, right :: m b) :: m b = left >>= (\ _ -> right)
return(a :: a) :: m a;
}
export restrict(Monad m) mapM(f :: a -> m b, ls :: [a]) :: m [b]
{
case ls {
[] -> return([]);
(x:rest) -> return((:) `ap` f x `ap` mapM(f,rest));
}
}
export restrict(Monad m) mapM_(f :: a -> m b, ls :: [a]) :: m ()
{
case ls {
[] -> return ();
(x:rest) -> f(x) >> mapM_(f,rest);
}
export restrict(Monad m) forM(ls :: [a], f :: a -> m b) :: m [b] = mapM(ls, f);
export restrict(Monad m) forM_(ls :: [a], f :: a -> m b) :: m () = mapM_(ls, f);
export restrict(Monad m) sequence(lsM :: [m a]) :: m [a]
{
case lsM {
[] -> return([]);
(x:rest) -> return((:) `ap` x `ap` sequence(rest));
}
export restrict(Monad m) sequence_(lsM :: [m a]) :: m ()
{
case lsM {
[] -> return(());
(x:rest) -> x >> sequence(rest);
}
export restrict(Monad m)
(=<<)(cont :: a -> m b, start :: m a) :: m b
= start >>= cont;
export restrict(Monad m)
(>=>)(left :: a -> m b, right :: b -> m c, x :: a) :: m c
{
step1 = left x
right step1
}
export restrict(Monad m)
(<=<)(right :: b -> m c, left :: a -> m b, x :: a) :: m c
= (>=>)(left,right,x)
export restrict(Monad m) forever(action :: m a) :: m b
= action >> forever(action)
export restrict(Monad m) void(action :: m a) :: m () = action >> return(())
export restrict(Monad m) join(actionM :: m (m a)) :: m a
{
val = actionM;
return(val);
}
export restrict(Monad m) filterM(f :: a -> m Bool, xs :: [a]) :: m [a]
{
case xs {
[] -> return(());
(x:rest) -> if f(x)
then return(x:) `ap` filterM(f,rest)
else filterM(f,rest);
}
}
export restrict(Monad m) foldM(f :: a -> b -> m a, base :: a, xs :: [b]) :: m a
{
case xs {
[] -> return(base);
(x:rest) -> {
newbase = f(base,x);
foldM(f,newbase,rest);
}
}
export restrict(Monad m) foldM_(f :: a -> b -> m a, base :: a, xs :: [b]) ::m ()
{
case xs {
[] -> return(());
(x:rest) -> {
newbase = f(base,x);
foldM_(f,newbase,rest);
}
}
export restrict(Monad m, Unsigned u)
replicateM(count :: u, action :: m a) :: m [a]
{
if count == 0
then return([])
else return( return((:)) `ap` action `ap` replicateM(count-1,action) );
}
export restrict(Monad m, Unsigned u)
replicateM_(count :: u, action :: m a) :: m ()
{
if count == 0
then return(())
else action >> replicateM_(count - 1, action);
}
export restrict(Monad m) ap(mf :: m (a -> b), ma :: m a) :: m b
{
func <- mf
a <- ma
return(func(a));
}
export restrict(Monad m) liftM(f :: a -> b, ma :: m a) :: m b
= return f `ap` ma
export restrict(Monad m) liftM2(f :: a -> b -> c, ma :: m a, mb :: m b) :: m c
= return f `ap` ma `ap` mb
export restrict(Monad m) liftM3(f :: a -> b -> c -> d,
ma :: m a, mb :: m b, mc :: m c)
= return f `ap` ma `ap` mb `ap` mc
export restrict(Monad m) liftM4(f :: a -> b -> c -> d -> e,
ma :: m a, mb :: m b, mc :: m c, md :: m d)
= return f `ap` ma `ap` mb `ap` mc

11
bsrc/Data/Bool.bs Normal file
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module Data.Bool
datatype Bool = True | False;
export (&)(x :: Bool, y :: Bool) :: Bool = prim%and;
export (|)(x :: Bool, y :: Bool) :: Bool = prim%or;
export (^)(x :: Bool, y :: Bool) :: Bool = prim%xor;
export (not)(x :: Bool) :: Bool = prim%not;
export otherwise :: Bool = True;

45
bsrc/Data/List.bs
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@@ -7,42 +7,49 @@ export datatype List a =
export (++)(a :: [a], b :: [a]) :: [a]
{
case a of
[] -> b
(af:ar) -> case b of
[] -> a
_ -> af:(ar ++ b)
case a {
[] -> b;
(af:ar) ->
case b {
[] -> a;
_ -> af:(ar ++ b);
}
}
};
export null(ls :: [a]) :: Bool
{
case ls of
[] -> True
_ -> False
case ls {
[] -> True;
_ -> False;
}
};
export length(ls :: [a]) :: Int
{
case ls of
[] -> 0
_:rest -> length(rest)
case ls {
[] -> 0;
(_:rest) -> 1 + length(rest);
}
};
export reverse(ls :: [a]) :: [a]
{
helper(xs,acc) = {
case xs of
[] -> acc
(a:rest) -> helper(rest, (a:acc))
let helper(xs,acc) = {
case xs {
[] -> acc;
(a:rest) -> helper(rest, (a:acc));
}
};
helper(ls, []);
};
export restrict(Eq a) find(f :: a -> Bool, ls :: [a]) :: Maybe a
{
case ls of
[] -> False
(a:_) | f a -> a
(_:rest) -> find(f, rest)
case ls {
[] -> False;
(a:_) | f(a) -> a;
(_:rest) -> find(f, rest);
}
};

93
bsrc/Data/Number.bs Normal file
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module Data.Number
import Data.Object
export restrict(Eq a) Num a {
(+)(x :: a, y :: a) :: a;
(*)(x :: a, y :: a) :: a;
(-)(x :: a, y :: a) :: a;
};
export restrict(Num a) Signed a {
negate(x :: a) :: a;
abs(x :: a) :: a;
signum(x :: a) :: a;
};
export restrict(Num a) Unsigned a {
};
export class Bounded a {
minBound :: a;
maxBound :: a;
};
export datatype Ordering = Before | Equal | After;
export class restrict(Eq a) Ord a {
compare(_ :: a, _ :: a) :: Ordering;
(<)(x :: a, y :: b) :: Bool
{
case compare(x,y) {
Before -> True;
_ -> False;
}
}
(>)(x :: a, y :: b) :: Bool
{
case compare(x,y) {
After -> True;
_ -> False;
}
}
(<=)(x :: a, y :: b) :: Bool
{
case compare(x,y) {
After -> False;
_ -> True;
}
}
(>=)(x :: a, y :: b) :: Bool
{
case compare(x,y) {
Before -> False;
_ -> True;
}
}
max(x :: a, y :: b) :: a
{
case compare(x,y) {
Before -> y;
_ -> x;
}
}
min(x :: a, y :: b) :: b
{
case compare(x,y) {
After -> y;
_ -> x;
}
}
export class Enum a {
succ(a) :: a;
pred(a) :: a;
toEnum(Integer) :: a;
fromEnum(a) :: Integer;
enumFromTo(a, a) :: [a];
enumFromThenTo(a, a, a) :: [a];
}
export restrict(Ord a, Num a)
createEnum(s :: a, e :: a, m :: a) :: [a] = s : createEnum(s + m, e, m);
export restrict(Ord a, Num a)
diff(x :: a, y :: a) :: a = if x > y then x - y else y - x;

106
bsrc/Data/Number/Machine.bs Normal file
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module Data.Number.Machine
type Int = prim%Int;
type Word = prim%Word;
export instance Eq Int {
(==)(x,y) = prim%inteq(x,y);
(/=)(x,y) = prim%intneq(x,y);
}
export instance Eq Word {
(==)(x,y) = prim%wordeq(x,y);
(/=)(x,y) = prim%wordneq(x,y);
}
export instance Num Int {
(+)(x,y) = prim%intplus(x,y);
(-)(x,y) = prim%intminus(x,y);
(*)(x,y) = prim%intmult(x,y);
}
export instance Num Word {
(+)(x,y) = prim%wordplus(x,y);
(-)(x,y) = prim%wordminus(x,y);
(*)(x,y) = prim%wordmult(x,y);
}
export instance Signed Int {
negate = prim%intnegate;
abs = prim%intabs;
signum(x) = case x {
_ | x < 0 -> -1;
| x == 0 -> 0;
| otherwise -> 1;
}
}
export instance Unsigned Word;
export instance Bounded Int {
minBound = prim%intminbound;
maxBound = prim%intmaxbound;
}
export instance Bounded Word {
minBound = 0;
maxBound = prim%wordmaxbound;
}
export instance Ord Int {
compare(x,y) = if x == y
then Equal
else if x < y
then Before
else After
(<) = prim%intlt
(<=) = prim%intlte
(>) = prim%intgt
(>=) = prim%intgte
max(x,y) = if x > y then x else y;
min(x,y) = if x < y then x else y;
}
export instance Ord Word {
compare(x,y) = if x == y
then Equal
else if x < y
then Before
else After
(<) = prim%wordlt
(<=) = prim%wordlte
(>) = prim%wordgt
(>=) = prim%wordgte
max(x,y) = if x > y then x else y;
min(x,y) = if x < y then x else y;
}
export instance Enum Int {
succ(x) = x + 1;
pred(x) = x - 1;
toEnum(x) = if x > safeConvert(maxBound :: Int)
then maxBound
else if x < safeConvert(minBound :: Int)
then minBound
else unsafeConvert(x)
fromEnum(x) = safeConvert(x)
enumFromTo(x,y) = if x > y then createEnum(x,y,-1) else createEnum(x,y,1);
enumFromThenTo(x,y) = let direction = if x > y then -1 else 1
amt = diff x y
in createEnum(x,y,amt * direction)
}
export instance Enum Word {
succ(x) = x + 1;
pred(x) = x - 1;
toEnum(x) = if x > safeConvert(maxBound :: Word)
then maxBound
else if x < safeConvert(minBound :: Word)
then minBound
else unsafeConvert(x)
fromEnum(x) = safeConvert(x)
enumFromTo(x,y) = if x > y then createEnum(x,y,-1) else createEnum(x,y,1);
enumFromThenTo(x,y) = let direction = if x > y then -1 else 1
amt = diff x y
in createEnum(x,y,amt * direction)
}

27
bsrc/Data/Object.bs Normal file
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module Data.Object
import Data.Bool;
export eq(x :: a, y :: a) :: Bool = prim%eq(x,y);
class Eq a {
(==)(x :: a, y :: a) :: Bool = not (x /= y);
(/=)(x :: a, y :: a) :: Bool = not (x == y);
}
instance Eq () {
(==)(x,y) = True;
(/=)(x,y) = False;
}
instance Eq Bool {
(/=)(x,y) = x ^ y;
}
class SafelyConvertable a b {
safeConvert :: a -> b;
}
class UnsafelyConvertable a b {
unsafeConvert :: a -> b;
}