Use lists efficiently (easy)
A simple method of making it more idiomatic is to reverse stack
(this makes it a little more like a true stack), which allows you to use pattern matching and makes the code more efficient since attaching/reading at the head of list is an O(1)
operation, while doing so at the end is O(n)
i.e.:
solveRPN :: (Read a, Integral a) => [String] -> [String] -> a
solveRPN [] (x:[]) = read x
solveRPN [] (x:y:xs) = solveRPN (y:x:[]) xs -- push them on backwards
solveRPN stack@(s1:s2:rest) (x:xs) -- pattern match on stack with length >= 2
| isOperator x =
let z = calcFunction x s2 s1
in solveRPN rest (z:xs)
| otherwise = solveRPN (x:stack) xs
solveRPN stack (x:xs) -- last case: list with a single element
| isOperator x = error "Stack too small"
| otherwise = solveRPN (x:stack) xs
Use the typesystem (important!)
You are using strings to encapsulate the two possible types on the input stack: operations and numbers, which allows for invalid input, idiomatic Haskell will leverage the type system so that a function always has a defined result (i.e. so that all functions are total).
It better is to use an ADT (algebraic data type) to encapsulate the possible operations and Either
to distinguish between operations and literals in a type-safe way:
data Operation = Plus | Minus | Times | Divide
-- conversion function
readStackVar :: (Read a) => String -> Either Operation a
readStackVar "+" = Left Plus
readStackVar "-" = Left Minux
readStackVar "*" = Left Times
readStackVar "/" = Left Divide
readStackVar other = Right . read $ other
This allows you to write isOperator
nicely (although it's actually unnecessary now):
isOperator :: Either Operation a -> Bool
isOperator (Left _) = False
isOperator _ = True
calcFunction
is now typesafe (note the type doesn't have the Either
) and there is no possibility of an unrecognised operation:
calcFunction :: (Integral a) => Operation -> a -> a -> a
calcFunction Plus = (+)
calcFunction Minus = (-)
calcFunction Times = (*)
calcFunction Divide = div -- integral division
Using these we can rewrite solveRPN
(notice that we've avoided having to pass an empty list to solveRPN
by using the where clause):
solveRPN :: (Read a, Integral a) => [Either Operation a] -> a
solveRPN xs = go [] xs
where
go :: (Read a, Integral a) => [a] -> [Either Operation a] -> a
go [] [] = error "Empty"
go (x:xs) [] = x -- finished all the input
go [] (x:y:xs) = go (y:x:[]) xs -- start the stack in reverse order
go (s1:s2:rest) ((Left op):xs) = go ((calcFunction op s1 s2) : rest) xs -- operation
go stack ((Right x):xs) = go (x:stack) xs -- literal
Notice that I've been able to use pattern matching on the Left
and Right
of Either
to distinguish between operations and literals. (An additional thing we could (and should) do is make solveRPN
return Maybe a
so that errors can be indicated by returning Nothing
and success by returning Just x
.)
This is used like:
solveRPN . map readStackVar . words $ "1 2 + 3 *"
(Warning: I haven't actually tested this, so there may be typos and small logic errors)