## 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)