Execute SNUSP/Haskell: Difference between revisions
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{{implementation|SNUSP}}{{collection|RCSNUSP}} |
{{implementation|SNUSP}}{{collection|RCSNUSP}} |
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This implementation supports commands from all the three SNUSP variants, as described on the [[eso:SNUSP|Esolang SNUSP page]]. |
This [[Haskell]] implementation supports commands from all the three SNUSP variants, as described on the [[eso:SNUSP|Esolang SNUSP page]]. |
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Threads and 2D-data makes a purely functional implementation difficult, so most of the code works in the IO-Monad. There is an immutable array ''c'' for the code, a global mutable hashtable ''d'' for the data, and each thread has an instruction pointer ''ip'', a memory pointer ''mp'', and a call stack ''stack''. |
Threads and 2D-data makes a purely functional implementation difficult, so most of the code works in the IO-Monad. There is an immutable array ''c'' for the code, a global mutable hashtable ''d'' for the data, and each thread has an instruction pointer ''ip'', a memory pointer ''mp'', and a call stack ''stack''. |
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The Haskell code starts with lots of imports: |
The Haskell code starts with lots of imports: |
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<lang haskell> |
<lang haskell>import System.Environment |
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import System.Environment |
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import System.IO |
import System.IO |
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import System.Random |
import System.Random |
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import Data.Array |
import Data.Array |
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import qualified Data.HashTable as H |
import qualified Data.HashTable as H</lang> |
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</lang> |
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Use a list as an index into an array: |
Use a list as an index into an array: |
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<lang haskell> |
<lang haskell>type Index = [Int] |
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type Index = [Int] |
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instance Ix a => Ix [a] where |
instance Ix a => Ix [a] where |
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inRange ([],[]) [] = True |
inRange ([],[]) [] = True |
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inRange (l:ls, u:us) (i:is) = inRange (l,u) i && inRange (ls,us) is |
inRange (l:ls, u:us) (i:is) = inRange (l,u) i && inRange (ls,us) is |
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rangeSize (ls,us) = product $ map rangeSize $ zip ls us |
rangeSize (ls,us) = product $ map rangeSize $ zip ls us</lang> |
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</lang> |
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or into an hashtable (the hash function could probably be improved): |
or into an hashtable (the hash function could probably be improved): |
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<lang haskell> |
<lang haskell>cmpList :: Index -> Index -> Bool |
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cmpList :: Index -> Index -> Bool |
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cmpList [] [] = True |
cmpList [] [] = True |
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cmpList (x:xs) [] = x == 0 && cmpList xs [] |
cmpList (x:xs) [] = x == 0 && cmpList xs [] |
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combine :: Int -> Int -> Int |
combine :: Int -> Int -> Int |
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combine x 0 = x |
combine x 0 = x |
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combine x y = z * (z+1) `div` 2 + x where z = x + y |
combine x y = z * (z+1) `div` 2 + x where z = x + y</lang> |
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</lang> |
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Here it's important that index lists with trailing zeroes are treated just like this list without the zeroes, so we can handle any number of dimensions. We want the same flexibility when adding index lists: |
Here it's important that index lists with trailing zeroes are treated just like this list without the zeroes, so we can handle any number of dimensions. We want the same flexibility when adding index lists: |
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<lang haskell> |
<lang haskell>(<+>) :: Index -> Index -> Index |
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(<+>) :: Index -> Index -> Index |
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[] <+> ys = ys |
[] <+> ys = ys |
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xs <+> [] = xs |
xs <+> [] = xs |
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(x:xs) <+> (y:ys) = (x+y) : (xs <+> ys) |
(x:xs) <+> (y:ys) = (x+y) : (xs <+> ys)</lang> |
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</lang> |
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Some helper functions: |
Some helper functions: |
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| ⚫ | |||
<lang haskell> |
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| ⚫ | |||
modify d t f = do |
modify d t f = do |
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toChar = chr . fromInteger |
toChar = chr . fromInteger |
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fromChar = toInteger . ord |
fromChar = toInteger . ord</lang> |
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</lang> |
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Now, the commands. Given a thread, return a list of threads valid after one simulation step. In that way, ''exec'' can handle forks and thread termination on errors. |
Now, the commands. Given a thread, return a list of threads valid after one simulation step. In that way, ''exec'' can handle forks and thread termination on errors. |
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<lang haskell> |
<lang haskell>-- Core SNUSP |
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-- Core SNUSP |
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exec '+' d t = modify d t (+1) |
exec '+' d t = modify d t (+1) |
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-- NOOP |
-- NOOP |
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exec _ d t = return [t] |
exec _ d t = return [t]</lang> |
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</lang> |
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The scheduler manages a list ''ts'' of active threads, and a list ''ks'' of threads waiting for input. If there are no more threads in either list, stop. If input is available, one blocked thread is executed. If no input is available and all threads are blocked, we block the interpreter, too (so the OS can do something else). Otherwise, try to execute one of the unblocked threads, first checking if it's still inside the code array. |
The scheduler manages a list ''ts'' of active threads, and a list ''ks'' of threads waiting for input. If there are no more threads in either list, stop. If input is available, one blocked thread is executed. If no input is available and all threads are blocked, we block the interpreter, too (so the OS can do something else). Otherwise, try to execute one of the unblocked threads, first checking if it's still inside the code array. |
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<lang haskell> |
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run c d = schedule [thread] [] False where |
run c d = schedule [thread] [] False where |
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| x == ',' = return ([],[t]) |
| x == ',' = return ([],[t]) |
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| otherwise = exec' x d t |
| otherwise = exec' x d t |
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where x = c ! (ip t) |
where x = c ! (ip t)</lang> |
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</lang> |
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Finally, routines to run code from a string or a file, and the main program. |
Finally, routines to run code from a string or a file, and the main program. |
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<lang haskell> |
<lang haskell>runString y s = do |
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runString y s = do |
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d <- H.new cmpList hashList |
d <- H.new cmpList hashList |
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let x = length s `div` y |
let x = length s `div` y |
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hSetBuffering stdin NoBuffering |
hSetBuffering stdin NoBuffering |
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[s] <- getArgs |
[s] <- getArgs |
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runFile s |
runFile s</lang> |
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</lang> |
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== Extension == |
== Extension == |
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To demonstrate the ease of introducing even more dimensions, let's implement commands ( and ) to move the data pointer along the z-axis, and a command ^ to rotate the IP direction around the (1,1,1) axis (i.e., left becomes up, up becomes "farther" on the z-axis, "farther" becomes left, etc.). |
To demonstrate the ease of introducing even more dimensions, let's implement commands ( and ) to move the data pointer along the z-axis, and a command ^ to rotate the IP direction around the (1,1,1) axis (i.e., left becomes up, up becomes "farther" on the z-axis, "farther" becomes left, etc.). |
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<lang haskell> |
<lang haskell>exec '(' d t = moveMp d t [0,0,-1] |
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exec '(' d t = moveMp d t [0,0,-1] |
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exec ')' d t = moveMp d t [0,0, 1] |
exec ')' d t = moveMp d t [0,0, 1] |
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exec '^' d t = return [t {dir=(d3:d1:d2:ds)}] where d1:d2:d3:ds = dir t <+> [0,0,0] |
exec '^' d t = return [t {dir=(d3:d1:d2:ds)}] where d1:d2:d3:ds = dir t <+> [0,0,0]</lang> |
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</lang> |
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Revision as of 20:59, 30 December 2009
This Haskell implementation supports commands from all the three SNUSP variants, as described on the Esolang SNUSP page.
Threads and 2D-data makes a purely functional implementation difficult, so most of the code works in the IO-Monad. There is an immutable array c for the code, a global mutable hashtable d for the data, and each thread has an instruction pointer ip, a memory pointer mp, and a call stack stack.
Design decisions (not covered by SNUSP specification):
- Decrementing a zero memory cell sets it to zero.
- The data area is infinite.
- Threads block during read if no input is available, while other threads continue (as one of the examples requires).
- As the SNUSP variants differ in the number of dimensions in data and code, make it easy to add even more dimensions.
The interpreter has been tested with the echo, thread, multiplication and multi-digit print examples.
The Haskell code starts with lots of imports:
<lang haskell>import System.Environment import System.IO import System.Random
import Control.Monad
import Data.Char import Data.List import Data.Maybe import Data.Array
import qualified Data.HashTable as H</lang>
Use a list as an index into an array:
<lang haskell>type Index = [Int]
instance Ix a => Ix [a] where
index ([],[]) [] = 0
index (l:ls, u:us) (i:is) = index (l,u) i +
index (ls,us) is * rangeSize (l,u)
range ([],[]) = [[]]
range (l:ls, u:us) = [i:is | is <- range (ls,us), i <- range (l,u)]
inRange ([],[]) [] = True
inRange (l:ls, u:us) (i:is) = inRange (l,u) i && inRange (ls,us) is
rangeSize (ls,us) = product $ map rangeSize $ zip ls us</lang>
or into an hashtable (the hash function could probably be improved):
<lang haskell>cmpList :: Index -> Index -> Bool cmpList [] [] = True cmpList (x:xs) [] = x == 0 && cmpList xs [] cmpList [] (y:ys) = y == 0 && cmpList [] ys cmpList (x:xs) (y:ys) = x == y && cmpList xs ys
hashList xs = H.hashInt $ foldr combine 0 xs
combine :: Int -> Int -> Int combine x 0 = x combine x y = z * (z+1) `div` 2 + x where z = x + y</lang>
Here it's important that index lists with trailing zeroes are treated just like this list without the zeroes, so we can handle any number of dimensions. We want the same flexibility when adding index lists:
<lang haskell>(<+>) :: Index -> Index -> Index [] <+> ys = ys xs <+> [] = xs (x:xs) <+> (y:ys) = (x+y) : (xs <+> ys)</lang>
Some helper functions:
<lang haskell>data Thread a = T {mp::a, ip::a, dir::a, stack::[(a,a)]} deriving Show
modify d t f = do
let i = mp t x <- H.lookup d i let x' = fromMaybe 0 x H.delete d i H.insert d i (f x') -- H.update return [t]
moveMp d t delta = return [t {mp=(mp t) <+> delta}]
readMp d t = H.lookup d (mp t) >>= return . fromMaybe 0
step t = t {ip=(ip t) <+> (dir t)}
dec :: Integer -> Integer dec 0 = 0 dec x = x-1
toChar = chr . fromInteger fromChar = toInteger . ord</lang>
Now, the commands. Given a thread, return a list of threads valid after one simulation step. In that way, exec can handle forks and thread termination on errors.
<lang haskell>-- Core SNUSP
exec '+' d t = modify d t (+1) exec '-' d t = modify d t (dec) exec '<' d t = moveMp d t [-1] exec '>' d t = moveMp d t [ 1] exec ',' d t = getChar >>= modify d t . const . fromChar exec '.' d t = readMp d t >>= putChar . toChar >> return [t] exec '\\' d t = return [t {dir=( d2: d1:ds)}] where d1:d2:ds = dir t <+> [0,0] exec '/' d t = return [t {dir=(-d2: -d1:ds)}] where d1:d2:ds = dir t <+> [0,0] exec '!' d t = return [step t] exec '?' d t = readMp d t >>= \x -> return [if x == 0 then step t else t]
-- Modular SNUSP
exec '@' d t = return [t {stack=(ip t, dir t):(stack t)}] exec '#' d T{stack=[]} = return [] exec '#' d t@T{stack=(ip,dir):s} = return [step $ t {ip=ip, dir=dir, stack=s}]
-- Bloated SNUSP
exec ':' d t = moveMp d t [0,-1] exec ';' d t = moveMp d t [0, 1] exec '&' d t = return [step t, t {stack=[]}] exec '%' d t = readMp d t >>= \x -> randomRIO (0,x) >>= modify d t . const
-- NOOP
exec _ d t = return [t]</lang>
The scheduler manages a list ts of active threads, and a list ks of threads waiting for input. If there are no more threads in either list, stop. If input is available, one blocked thread is executed. If no input is available and all threads are blocked, we block the interpreter, too (so the OS can do something else). Otherwise, try to execute one of the unblocked threads, first checking if it's still inside the code array.
<lang haskell>start c = maybe (fst $ bounds $ c) fst $ find (\(_,x) -> x == '$') $ assocs c
run c d = schedule [thread] [] False where
thread = T {mp=[1,1], ip=start c, dir=[1], stack=[]}
exec' x d t = exec x d t >>= \ts -> return (ts,[])
schedule' ts ks (ts',ks') = hReady stdin >>= schedule (ts++ts') (ks++ks')
schedule [] [] _ = return ()
schedule [] ks False = hLookAhead stdin >> schedule' [] ks ([],[])
schedule ts (k:ks) True = exec' ',' d k >>= schedule' ts ks
schedule (t:ts) ks _ = check (step t) >>= schedule' ts ks
check t
| not $ bounds c `inRange` (ip t) = return ([],[])
| x == ',' = return ([],[t])
| otherwise = exec' x d t
where x = c ! (ip t)</lang>
Finally, routines to run code from a string or a file, and the main program.
<lang haskell>runString y s = do
d <- H.new cmpList hashList let x = length s `div` y run (listArray ([1,1],[x,y]) s) d
runFile name = do
s <- readFile name d <- H.new cmpList hashList let l = lines s let y = length l let x = maximum $ map length $ l let m = [([i,j],c) | (j,v) <- zip [1..] l, (i,c) <- zip [1..] v] let c = listArray ([1,1],[x,y]) (repeat ' ') // m run c d
main = do
hSetBuffering stdin NoBuffering [s] <- getArgs runFile s</lang>
Extension
To demonstrate the ease of introducing even more dimensions, let's implement commands ( and ) to move the data pointer along the z-axis, and a command ^ to rotate the IP direction around the (1,1,1) axis (i.e., left becomes up, up becomes "farther" on the z-axis, "farther" becomes left, etc.).
<lang haskell>exec '(' d t = moveMp d t [0,0,-1] exec ')' d t = moveMp d t [0,0, 1] exec '^' d t = return [t {dir=(d3:d1:d2:ds)}] where d1:d2:d3:ds = dir t <+> [0,0,0]</lang>