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pustd.pre
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pustd.pre
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-- __________ __________ __________ __________ ________
-- / _______/ / ____ / / _______/ / _______/ / ____ \
-- / / _____ / / / / / /______ / /______ / /___/ /
-- / / /_ / / / / / / _______/ / _______/ / __ __/
-- / /___/ / / /___/ / / / / /______ / / \ \
-- /_________/ /_________/ /__/ /_________/ /__/ \__\
--
-- Functional programming environment, Version 2.28
-- Copyright Mark P Jones 1991-1993.
-- PU Additions
-- Copyright Rusi Mody 1995-2015.
--
-- Standard prelude for use of overloaded values using type classes.
-- Based on the Haskell standard prelude version 1.2.
help = "press :? for a list of commands"
-- Operator precedence table: -----------------------------------------------
infixl 9 !!
infixr 9 ;
infixr 8 ^
infixl 7 *
infix 7 /, `div`, `quot`, `rem`, `mod`
infixl 6 +, -
infix 5 \\
infixr 5 ++, ::
infix 4 ==, /=, <, <=, >=, >
infix 4 `elem`, `notElem`
infixr 3 &&
infixr 2 ||
-- Standard combinators: ----------------------------------------------------
primitive strict "primStrict" : (a -> b) -> a -> b
primitive (.) "primApply" : (a -> b) -> a -> b
const : a -> b -> a
const.k.x = k
id : a -> a
id.x = x
curry : ((a,b) -> c) -> a -> b -> c
curry.f.a.b = f.(a,b)
uncurry : (a -> b -> c) -> (a,b) -> c
uncurry.f.(a,b) = f.a.b
fst : (a,b) -> a
fst.(x,_) = x
snd : (a,b) -> b
snd.(_,y) = y
fst3 : (a,b,c) -> a
fst3.(x,_,_) = x
snd3 : (a,b,c) -> b
snd3.(_,x,_) = x
thd3 : (a,b,c) -> c
thd3.(_,_,x) = x
(;) : (a -> b) -> (b -> c) -> (a -> c)
(g ; f).x = f.(g.x)
flip : (a -> b -> c) -> b -> a -> c
flip.f.x.y = f.y.x
-- Boolean functions: -------------------------------------------------------
(&&), (||) : Bool -> Bool -> Bool
False && x = False
True && x = x
False || x = x
True || x = True
not : Bool -> Bool
not.True = False
not.False = True
and, or : [Bool] -> Bool
and = foldr.(&&).True
or = foldr.(||).False
any, all : (a -> Bool) -> [a] -> Bool
any.p = map.p ; or
all.p = map.p ; and
otherwise : Bool
otherwise = True
-- Character functions: -----------------------------------------------------
primitive ord "primCharToInt" : Char -> Int
primitive chr "primIntToChar" : Int -> Char
isAscii, isControl, isPrint, isSpace : Char -> Bool
isUpper, isLower, isAlpha, isDigit, isAlphanum : Char -> Bool
isAscii.c = ord.c < 128
isControl.c = c < ' ' || c == '\DEL'
isPrint.c = c >= ' ' && c <= '~'
isSpace.c = c == ' ' || c == '\t' || c == '\n' || c == '\r' ||
c == '\f' || c == '\v'
isUpper.c = c >= 'A' && c <= 'Z'
isLower.c = c >= 'a' && c <= 'z'
isAlpha.c = isUpper.c || isLower.c
isDigit.c = c >= '0' && c <= '9'
isAlphanum.c = isAlpha.c || isDigit.c
toUpper, toLower : Char -> Char
toUpper.c
| isLower.c = chr.(ord.c - ord.'a' + ord.'A')
| otherwise = c
toLower.c
| isUpper.c = chr.(ord.c - ord.'A' + ord.'a')
| otherwise = c
minChar, maxChar : Char
minChar = chr.0
maxChar = chr.255
-- Standard type classes: ---------------------------------------------------
class Eq.a where
(==), (/=) : a -> a -> Bool
x /= y = not.(x == y)
class Eq.a => Ord.a where
(<), (<=), (>), (>=) : a -> a -> Bool
max, min : a -> a -> a
x < y = x <= y && x /= y
x >= y = y <= x
x > y = y < x
max.x.y | x >= y = x
| y >= x = y
min.x.y | x <= y = x
| y <= x = y
class Ord.a => Ix.a where
range : (a,a) -> [a]
index : (a,a) -> a -> Int
inRange : (a,a) -> a -> Bool
class Ord.a => Enum.a where
enumFrom : a -> [a] -- [n...]
enumFromThen : a -> a -> [a] -- [n,m...]
enumFromTo : a -> a -> [a] -- [n...m]
enumFromThenTo : a -> a -> a -> [a] -- [n,n'...m]
enumFromTo.n.m = takeWhile.(m >=).(enumFrom.n)
enumFromThenTo.n.n'.m = takeWhile.((if n' >= n then (>=) else (<=)).m).
(enumFromThen.n.n')
class (Eq.a, Text.a) => Num.a where -- simplified numeric class
(+), (-), (*), (/) : a -> a -> a
negate : a -> a
fromInteger : Int -> a
-- Type class instances: ----------------------------------------------------
primitive primEqInt "primEqInt",
primLeInt "primLeInt" : Int -> Int -> Bool
primitive primPlusInt "primPlusInt",
primMinusInt "primMinusInt",
primDivInt "primDivInt",
primMulInt "primMulInt" : Int -> Int -> Int
primitive primNegInt "primNegInt" : Int -> Int
instance Eq.() where () == () = True
instance Ord.() where () <= () = True
instance Eq.Int where (==) = primEqInt
instance Ord.Int where (<=) = primLeInt
instance Ix.Int where
range.(m,n) = [m...n]
index.(m,n).i = i - m
inRange.(m,n).i = m <= i && i <= n
instance Enum.Int where
enumFrom.n = iterate.(1 +).n
enumFromThen.n.m = iterate.((m - n) +).n
instance Num.Int where
(+) = primPlusInt
(-) = primMinusInt
(*) = primMulInt
(/) = primDivInt
negate = primNegInt
fromInteger.x = x
{- PC version off -}
primitive primEqFloat "primEqFloat",
primLeFloat "primLeFloat" : Float -> Float -> Bool
primitive primPlusFloat "primPlusFloat",
primMinusFloat "primMinusFloat",
primDivFloat "primDivFloat",
primMulFloat "primMulFloat" : Float -> Float -> Float
primitive primNegFloat "primNegFloat" : Float -> Float
primitive primIntToFloat "primIntToFloat" : Int -> Float
instance Eq.Float where (==) = primEqFloat
instance Ord.Float where (<=) = primLeFloat
instance Enum.Float where
enumFrom.n = iterate.(1.0 +).n
enumFromThen.n.m = iterate.((m - n) +).n
instance Num.Float where
(+) = primPlusFloat
(-) = primMinusFloat
(*) = primMulFloat
(/) = primDivFloat
negate = primNegFloat
fromInteger = primIntToFloat
primitive sin "primSinFloat", asin "primAsinFloat",
cos "primCosFloat", acos "primAcosFloat",
tan "primTanFloat", atan "primAtanFloat",
log "primLogFloat", log10 "primLog10Float",
exp "primExpFloat", sqrt "primSqrtFloat" : Float -> Float
primitive atan2 "primAtan2Float" : Float -> Float -> Float
primitive truncate "primFloatToInt" : Float -> Int
pi : Float
pi = 3.1415926535
{- PC version on -}
primitive primEqChar "primEqChar",
primLeChar "primLeChar" : Char -> Char -> Bool
instance Eq.Char where (==) = primEqChar -- c == d = ord c == ord d
instance Ord.Char where (<=) = primLeChar -- c <= d = ord c <= ord d
instance Ix.Char where
range.(c,c') = [c...c']
index.(c,c').ci = ord.ci - ord.c
inRange.(c,c').ci = ord.c <= i && i <= ord.c' where i = ord.ci
instance Enum.Char where
enumFrom.c = map.chr.[ord.c ... ord.maxChar]
enumFromThen.c.c' = map.chr.[ord.c, ord.c' ... ord.lastChar]
where lastChar = if c' < c then minChar else maxChar
instance Eq.a => Eq.[a] where
[] == [] = True
[] == (y::ys) = False
(x::xs) == [] = False
(x::xs) == (y::ys) = x == y && xs == ys
instance Ord.a => Ord.[a] where
[] <= _ = True
(_::_) <= [] = False
(x::xs) <= (y::ys) = x < y || x == y && xs <= ys
instance (Eq.a, Eq.b) => Eq.(a,b) where
(x,y) == (u,v) = x==u && y==v
instance (Ord.a, Ord.b) => Ord.(a,b) where
(x,y) <= (u,v) = x<u || (x==u && y<=v)
instance Eq.Bool where
True == True = True
False == False = True
_ == _ = False
instance Ord.Bool where
False <= x = True
True <= x = x
-- Standard numerical functions: --------------------------------------------
primitive div "primDivInt",
quot "primQuotInt",
rem "primRemInt",
mod "primModInt" : Int -> Int -> Int
subtract : Num.a => a -> a -> a
subtract = flip.(-)
even, odd : Int -> Bool
even.x = x `rem` 2 == 0
odd = even ; not
gcd : Int -> Int -> Int
gcd.x.y = gcd'.(abs.x).(abs.y)
where gcd'.x.0= x
gcd'.x.y= gcd'.y.(x `rem` y)
lcm : Int -> Int -> Int
lcm._.0 = 0
lcm.0._ = 0
lcm.x.y = abs.((x `quot` gcd.x.y) * y)
(^) : Num.a => a -> Int -> a
x ^ 0 = fromInteger.1
x ^ (n+1) = f.x.n.x
where f._.0.y = y
f.x.n.y = g.x.n where
g.x.n | even.n = g.(x*x).(n`quot`2)
| otherwise = f.x.(n-1).(x*y)
abs : (Num.a, Ord.a) => a -> a
abs.x | x>=fromInteger.0 = x
| otherwise = -x
signum : (Num.a, Ord.a) => a -> Int
signum.x
| x==fromInteger.0 = 0
| x> fromInteger.0 = 1
| otherwise = -1
sum, product : Num.a => [a] -> a
sum = foldl'.(+).(fromInteger.0)
product = foldl'.(*).(fromInteger.1)
sums, products : Num.a => [a] -> [a]
sums = scanl.(+).(fromInteger.0)
products = scanl.(*).(fromInteger.1)
-- Standard list processing functions: --------------------------------------
head : [a] -> a
head.(x::_) = x
last : [a] -> a
last.[x] = x
last.(_::xs) = last.xs
tail : [a] -> [a]
tail.(_::xs) = xs
init : [a] -> [a]
init.[x] = []
init.(x::xs) = x :: init.xs
(++) : [a] -> [a] -> [a] -- append lists. Associative with
[] ++ ys = ys
(x::xs) ++ ys = x :: (xs ++ ys)
genericLength : Num.a => [b] -> a
genericLength = foldl'.(\n _ -> n + fromInteger.1).(fromInteger.0)
length : [a] -> Int -- calculate length of list
length = foldl'.(\n _ -> n + 1).0
(!!) : [a] -> Int -> a -- xs!!n selects the nth element of
(x::_) !! 0 = x -- the list xs (first element xs!!0)
(_::xs) !! (n+1) = xs !! n -- for any n < length xs.
iterate : (a -> a) -> a -> [a] -- generate the infinite list
iterate.f.x = x :: iterate.f.(f.x) -- [x, f.x, f.(f.x), ...
repeat : a -> [a] -- generate the infinite list
repeat.x = xs where xs = x::xs -- [x, x, x, x, ...
cycle : [a] -> [a] -- generate the infinite list
cycle.xs = xs' where xs'=xs++xs'-- xs ++ xs ++ xs ++ ...
copy : Int -> a -> [a] -- make list of n copies of x
copy.n.x = take.n.xs where xs = x::xs
nub : Eq.a => [a] -> [a] -- remove duplicates from list
nub.[] = []
nub.(x::xs) = x :: nub.(filter.(x /=).xs)
reverse : [a] -> [a] -- reverse elements of list
reverse = foldl.(flip.(::)).[]
elem, notElem : Eq.a => a -> [a] -> Bool
elem = (==) ; any -- test for membership in list
notElem = (/=) ; all -- test for non-membership
maximum, minimum : Ord.a => [a] -> a
maximum = foldl1.max -- max element in non-empty list
minimum = foldl1.min -- min element in non-empty list
concat : [[a]] -> [a] -- concatenate list of lists
concat = foldr.(++).[]
transpose : [[a]] -> [[a]] -- transpose list of lists
transpose = foldr.(\xs xss -> zipWith.(::).xs.(xss ++ repeat.[])).[]
-- null provides a simple and efficient way of determining whether a given
-- list is empty, without using (==) and hence avoiding a constraint of the
-- form Eq [a].
null : [a] -> Bool
null.[] = True
null.(_::_) = False
-- (\\) is used to remove the first occurrence of each element in the second
-- list from the first list. It is a kind of inverse of (++) in the sense
-- that (xs ++ ys) \\ xs = ys for any finite list xs of proper values xs.
(\\) : Eq.a => [a] -> [a] -> [a]
(\\) = foldl.del
where [] `del` _ = []
(x::xs) `del` y
| x == y = xs
| otherwise = x :: xs `del` y
-- map f xs applies the function f to each element of the list xs returning
-- the corresponding list of results. filter p xs returns the sublist of xs
-- containing those elements which satisfy the predicate p.
map : (a -> b) -> [a] -> [b]
map.f.[] = []
map.f.(x::xs) = f.x :: map.f.xs
filter : (a -> Bool) -> [a] -> [a]
filter._.[] = []
filter.p.(x::xs)
| p.x = x :: xs'
| otherwise = xs'
where xs' = filter.p.xs
-- Fold primitives: The foldl and scanl functions, variants foldl1 and
-- scanl1 for non-empty lists, and strict variants foldl' scanl' describe
-- common patterns of recursion over lists. Informally:
--
-- foldl f a [x1, x2, ..., xn] = f (...(f (f a x1) x2)...) xn
-- = (...((a `f` x1) `f` x2)...) `f` xn
-- etc...
--
-- The functions foldr, scanr and variants foldr1, scanr1 are duals of these
-- functions:
-- e.g. foldr f a xs = foldl (flip f) a (reverse xs) for finite lists xs.
foldl : (a -> b -> a) -> a -> [b] -> a
foldl.f.z.[] = z
foldl.f.z.(x::xs) = foldl.f.(f.z.x).xs
foldl1 : (a -> a -> a) -> [a] -> a
foldl1.f.(x::xs) = foldl.f.x.xs
foldl' : (a -> b -> a) -> a -> [b] -> a
foldl'.f.a.[] = a
foldl'.f.a.(x::xs) = strict.(foldl'.f).(f.a.x).xs
scanl : (a -> b -> a) -> a -> [b] -> [a]
scanl.f.q.xs = q :: (case xs of
[] -> []
x::xs -> scanl.f.(f.q.x).xs)
scanl1 : (a -> a -> a) -> [a] -> [a]
scanl1.f.(x::xs) = scanl.f.x.xs
scanl' : (a -> b -> a) -> a -> [b] -> [a]
scanl'.f.q.xs = q :: (case xs of
[] -> []
x::xs -> strict.(scanl'.f).(f.q.x).xs)
foldr : (a -> b -> b) -> b -> [a] -> b
foldr.f.z.[] = z
foldr.f.z.(x::xs) = f.x.(foldr.f.z.xs)
foldr1 : (a -> a -> a) -> [a] -> a
foldr1.f.[x] = x
foldr1.f.(x::xs) = f.x.(foldr1.f.xs)
scanr : (a -> b -> b) -> b -> [a] -> [b]
scanr.f.q0.[] = [q0]
scanr.f.q0.(x::xs) = f.x.q :: qs
where qs@(q::_) = scanr.f.q0.xs
scanr1 : (a -> a -> a) -> [a] -> [a]
scanr1.f.[x] = [x]
scanr1.f.(x::xs) = f.x.q :: qs
where qs@(q::_) = scanr1.f.xs
-- List breaking functions:
--
-- take n xs returns the first n elements of xs
-- drop n xs returns the remaining elements of xs
-- splitAt n xs = (take n xs, drop n xs)
--
-- takeWhile p xs returns the longest initial segment of xs whose
-- elements satisfy p
-- dropWhile p xs returns the remaining portion of the list
-- span p xs = (takeWhile p xs, dropWhile p xs)
--
-- takeUntil p xs returns the list of elements upto and including the
-- first element of xs which satisfies p
take : Int -> [a] -> [a]
take.0._ = []
take._.[] = []
take.(n + 1).(x::xs) = x :: take.n.xs
drop : Int -> [a] -> [a]
drop.0.xs = xs
drop._.[] = []
drop.(n + 1).(_::xs) = drop.n.xs
splitAt : Int -> [a] -> ([a], [a])
splitAt.0.xs = ([],xs)
splitAt._.[] = ([],[])
splitAt.(n + 1).(x::xs) = (x::xs', xs'') where (xs', xs'') = splitAt.n.xs
takeWhile : (a -> Bool) -> [a] -> [a]
takeWhile.p.[] = []
takeWhile.p.(x::xs)
| p.x = x :: takeWhile.p.xs
| otherwise = []
takeUntil : (a -> Bool) -> [a] -> [a]
takeUntil.p.[] = []
takeUntil.p.(x::xs)
| p.x = [x]
| otherwise = x :: takeUntil.p.xs
dropWhile : (a -> Bool) -> [a] -> [a]
dropWhile.p.[] = []
dropWhile.p.xs@(x::xs')
| p.x = dropWhile.p.xs'
| otherwise = xs
span, break : (a -> Bool) -> [a] -> ([a],[a])
span.p.[] = ([],[])
span.p.xs@(x::xs')
| p.x = let (ys,zs) = span.p.xs' in (x::ys, zs)
| otherwise = ([],xs)
break.p = span.(p ; not)
-- Text processing:
-- lines s returns the list of lines in the string s.
-- words s returns the list of words in the string s.
-- unlines ls joins the list of lines ls into a single string
-- with lines separated by newline characters.
-- unwords ws joins the list of words ws into a single string
-- with words separated by spaces.
lines : String -> [String]
lines."" = []
lines.s = l :: (if null.s' then [] else lines.(tail.s'))
where (l,s') = break.('\n' ==).s
words : String -> [String]
words.s = case dropWhile.isSpace.s of
"" -> []
s' -> w :: words.s''
where (w,s'') = break.isSpace.s'
unlines : [String] -> String
unlines = map.(\l -> l ++ "\n") ; concat
unwords : [String] -> String
unwords.[] = []
unwords.ws = foldr1.(\w s -> w ++ ' ' :: s).ws
-- Merging and sorting lists:
merge : Ord.a => [a] -> [a] -> [a]
merge.[].ys = ys
merge.xs.[] = xs
merge.(x::xs).(y::ys)
| x <= y = x :: merge.xs.(y::ys)
| otherwise = y :: merge.(x::xs).ys
sort : Ord.a => [a] -> [a]
sort = foldr.insert.[]
insert : Ord.a => a -> [a] -> [a]
insert.x.[] = [x]
insert.x.(y::ys)
| x <= y = x::y::ys
| otherwise = y::insert.x.ys
qsort : Ord.a => [a] -> [a]
qsort.[] = []
qsort.(x::xs) = qsort.[ u | u<-xs, u < x ] ++
[ x ] ++
qsort.[ u | u<-xs, u>=x ]
-- zip and zipWith families of functions:
zip : [a] -> [b] -> [(a,b)]
zip = zipWith.(\a b -> (a,b))
zip3 : [a] -> [b] -> [c] -> [(a,b,c)]
zip3 = zipWith3.(\a b c -> (a,b,c))
zip4 : [a] -> [b] -> [c] -> [d] -> [(a,b,c,d)]
zip4 = zipWith4.(\a b c d -> (a,b,c,d))
zip5 : [a] -> [b] -> [c] -> [d] -> [e] -> [(a,b,c,d,e)]
zip5 = zipWith5.(\a b c d e -> (a,b,c,d,e))
zip6 : [a] -> [b] -> [c] -> [d] -> [e] -> [f] -> [(a,b,c,d,e,f)]
zip6 = zipWith6.(\a b c d e f -> (a,b,c,d,e,f))
zip7 : [a] -> [b] -> [c] -> [d] -> [e] -> [f] -> [g] -> [(a,b,c,d,e,f,g)]
zip7 = zipWith7.(\a b c d e f g -> (a,b,c,d,e,f,g))
zipWith : (a->b->c) -> [a]->[b]->[c]
zipWith.z.(a::as).(b::bs) = z.a.b :: zipWith.z.as.bs
zipWith._._._ = []
zipWith3 : (a->b->c->d) -> [a]->[b]->[c]->[d]
zipWith3.z.(a::as).(b::bs).(c::cs) = z.a.b.c :: zipWith3.z.as.bs.cs
zipWith3._._._._ = []
zipWith4 : (a->b->c->d->e) -> [a]->[b]->[c]->[d]->[e]
zipWith4.z.(a::as).(b::bs).(c::cs).(d::ds)
= z.a.b.c.d :: zipWith4.z.as.bs.cs.ds
zipWith4._._._._._ = []
zipWith5 : (a->b->c->d->e->f) -> [a]->[b]->[c]->[d]->[e]->[f]
zipWith5.z.(a::as).(b::bs).(c::cs).(d::ds).(e::es)
= z.a.b.c.d.e :: zipWith5.z.as.bs.cs.ds.es
zipWith5._._._._._._ = []
zipWith6 : (a->b->c->d->e->f->g)
-> [a]->[b]->[c]->[d]->[e]->[f]->[g]
zipWith6.z.(a :: as).(b :: bs).(c :: cs).(d :: ds).(e :: es).(f :: fs)
= z.a.b.c.d.e.f :: zipWith6.z.as.bs.cs.ds.es.fs
zipWith6._._._._._._._ = []
zipWith7 : (a->b->c->d->e->f->g->h)
-> [a]->[b]->[c]->[d]->[e]->[f]->[g]->[h]
zipWith7.z.(a::as).(b::bs).(c::cs).(d::ds).(e::es).(f::fs).(g::gs)
= z.a.b.c.d.e.f.g :: zipWith7.z.as.bs.cs.ds.es.fs.gs
zipWith7._._._._._._._._ = []
unzip : [(a,b)] -> ([a],[b])
unzip = foldr.(\(a,b) ~(as,bs) -> (a::as, b::bs)).([],[])
-- Formatted output: --------------------------------------------------------
primitive primPrint "primPrint" : Int -> a -> String -> String
show' : a -> String
show'.x = primPrint.0.x.[]
cjustify, ljustify, rjustify : Int -> String -> String
cjustify.n.s = space.halfm ++ s ++ space.(m - halfm)
where m = n - length.s
halfm = m `div` 2
ljustify.n.s = s ++ space.(n - length.s)
rjustify.n.s = space.(n - length.s) ++ s
space : Int -> String
space.n = copy.n.' '
layn : [String] -> String
layn = lay.1 where lay._.[] = []
lay.n.(x::xs) = rjustify.4.(show.n) ++ ") "
++ x ++ "\n" ++ lay.(n+1).xs
-- Miscellaneous: -----------------------------------------------------------
until : (a -> Bool) -> (a -> a) -> a -> a
until.p.f.x
| p.x = x
| otherwise = until.p.f.(f.x)
until' : (a -> Bool) -> (a -> a) -> a -> [a]
until'.p.f = iterate.f ; takeUntil.p
primitive error "primError" : String -> a
undefined : a
undefined | False = undefined
asTypeOf : a -> a -> a
x `asTypeOf` _ = x
-- A trimmed down version of the Haskell Text class: ------------------------
type ShowS = String -> String
class Text.a where
showsPrec : Int -> a -> ShowS
showList : [a] -> ShowS
showsPrec = primPrint
showList.[] = showString."[]"
showList.(x::xs) = showl.xs ; shows.x ; showChar.'['
where showl.[] = showChar.']'
showl.(x::xs) = showl.xs ; shows.x ; showChar.','
shows : Text.a => a -> ShowS
shows = showsPrec.0
show : Text.a => a -> String
show.x = shows.x.""
showChar : Char -> ShowS
showChar = (::)
showString : String -> ShowS
showString = (++)
instance Text.() where
showsPrec.d.() = showString."()"
instance Text.Bool where
showsPrec.d.True = showString."True"
showsPrec.d.False = showString."False"
primitive primShowsInt "primShowsInt" : Int -> Int -> String -> String
instance Text.Int where showsPrec = primShowsInt
{- PC version off -}
primitive primShowsFloat "primShowsFloat" : Int -> Float -> String -> String
instance Text.Float where showsPrec = primShowsFloat
{- PC version on -}
instance Text.Char where
showsPrec.p.c = showString.[q, c, q] where q = '\''
showList.cs = showl.cs ; showChar.'"'
where showl."" = showChar.'"'
showl.('"'::cs) = showl.cs ; showString."\\\""
showl.(c :: cs) = showl.cs ; showChar.c
-- Haskell has showLitChar c . showl cs
instance Text.a => Text.[a] where
showsPrec.p = showList
instance (Text.a, Text.b) => Text.(a,b) where
showsPrec.p.(x,y) = showChar.')' ; shows.y ; showChar.',' ; shows.x ;
showChar.'(' ; showsPrec.p.(x,y)
-- I/O functions and definitions: -------------------------------------------
stdin = "stdin"
stdout = "stdout"
stderr = "stderr"
stdecho = "stdecho"
{- The Dialogue, Request, Response and IOError datatypes are now builtin:
data Request = -- file system requests:
ReadFile.String
|WriteFile.String.String
|AppendFile.String.String
-- channel system requests:
|ReadChan.String.
|AppendChan.String.String
-- environment requests:
|Echo.Bool
|GetArgs
|GetProgName
|GetEnv.String
data Response = Success
| Str. String
| Failure.IOError
| StrList.[String]
data IOError = WriteError.String
| ReadError.String
| SearchError.String
| FormatError.String
| OtherError.String
type Dialogue = [Response] -> [Request]
-}
type SuccCont = Dialogue
type StrCont = String -> Dialogue
type StrListCont = [String] -> Dialogue
type FailCont = IOError -> Dialogue
done : Dialogue
readFile : String -> FailCont -> StrCont -> Dialogue
writeFile : String -> String -> FailCont -> SuccCont -> Dialogue
appendFile : String -> String -> FailCont -> SuccCont -> Dialogue
readChan : String -> FailCont -> StrCont -> Dialogue
appendChan : String -> String -> FailCont -> SuccCont -> Dialogue
echo : Bool -> FailCont -> SuccCont -> Dialogue
getArgs : FailCont -> StrListCont -> Dialogue
getProgName : FailCont -> StrCont -> Dialogue
getEnv : String -> FailCont -> StrCont -> Dialogue
done.resps = []
readFile.name.fail.succ.resps = (ReadFile.name) ::
strDispatch.fail.succ.resps
writeFile.name.contents.fail.succ.resps =
(WriteFile.name.contents) :: succDispatch.fail.succ.resps
appendFile.name.contents.fail.succ.resps =
(AppendFile.name.contents) :: succDispatch.fail.succ.resps
readChan.name.fail.succ.resps = ReadChan.name :: strDispatch.fail.succ.resps
appendChan.name.contents.fail.succ.resps = AppendChan.name.contents ::
succDispatch.fail.succ.resps
echo.bool.fail.succ.resps = Echo.bool :: succDispatch.fail.succ.resps
getArgs.fail.succ.resps = GetArgs :: strListDispatch.fail.succ.resps
getProgName.fail.succ.resps = GetProgName :: strDispatch.fail.succ.resps
getEnv.name.fail.succ.resps = GetEnv.name :: strDispatch.fail.succ.resps
strDispatch.fail.succ.(resp::resps) =
case resp of Str.val -> succ.val.resps
Failure.msg -> fail.msg.resps
succDispatch.fail.succ.(resp::resps) =
case resp of Success -> succ.resps
Failure.msg -> fail.msg.resps
strListDispatch.fail.succ.(resp::resps) =
case resp of StrList.val -> succ.val.resps
Failure.msg -> fail.msg.resps
abort : FailCont
abort.err = done
exit : FailCont
exit.err = appendChan.stderr.msg.abort.done
where msg = case err of ReadError.s -> s
WriteError.s -> s
SearchError.s -> s
FormatError.s -> s
OtherError.s -> s
print : Text.a => a -> Dialogue
print.x = appendChan.stdout.(show.x).exit.done
prints : Text.a => a -> String -> Dialogue
prints.x.s = appendChan.stdout.(shows.x.s).exit.done
interact : (String -> String) -> Dialogue
interact.f = readChan.stdin.exit.
(\x -> appendChan.stdout.(f.x).exit.done)
run : (String -> String) -> Dialogue
run.f = echo.False.exit.(interact.f)
primitive primFopen "primFopen" : String -> a -> (String -> a) -> a
openfile : String -> String
openfile.f = primFopen.f.(error.("can't open file " ++ f)).id
-- End of Gofer standard prelude: --------------------------------------------