I don't know Lightyear, but I had some success porting Parsec to Idris:

```
module Parser
data Parser : Type -> Type where
P : (String -> List (a, String)) -> Parser a
unP : Parser a -> String -> List (a, String)
unP (P f) = f
total stripPrefix : (Eq a) => List a -> List a -> Maybe (List a)
stripPrefix [] ys = Just ys
stripPrefix (x::xs) (y::ys) = if (x == y) then stripPrefix xs ys else Nothing
stripPrefix _ _ = Nothing
total token : String -> Parser ()
token tk = P $ \s => case stripPrefix (unpack tk) (unpack s) of
Just s' => [((), pack s')]
Nothing => []
total skip : Parser ()
skip = P $ \s => case unpack s of
[] => []
(_::s') => [((), pack s')]
instance Functor Parser where
map f p = P $ \s => map (\(x, s') => (f x, s')) (unP p s)
instance Applicative Parser where
pure x = P $ \s => [(x, s)]
(P pf) <*> (P px) = P $ \s => concat (map (\(f, s') => map (\(x, s'') => (f x, s'')) (px s')) (pf s))
instance Alternative Parser where
empty = P $ \s => []
(P p1) <|> (P p2) = P $ \s => case p1 s of
[] => p2 s
results => results
instance Monad Parser where
px >>= f = P $ \s => concat (map (\(x, s') => unP (f x) s') (unP px s))
total runParser : Parser a -> String -> Maybe a
runParser (P p) s = case p s of
[(x, "")] => Just x
_ => Nothing
```

This allows a straight copy-paste implementation of `chainl`

:

```
chainl1 : Parser a -> Parser (a -> a -> a) -> Parser a
chainl1 p op = p >>= rest
where
rest x = do { f <- op; y <- p; rest $ f x y } <|> return x
chainl : Parser a -> Parser (a -> a -> a) -> a -> Parser a
chainl p op x = chainl1 p op <|> return x
```

We can then take a straight transliteration of the expression parser from the `chainl`

docs (I'm too lazy to implement a proper `integer`

parser so we'll just use unary):

```
parens : Parser a -> Parser a
parens p = token "(" *> p <* token ")"
symbol : String -> Parser ()
symbol = token
integer : Parser Nat
integer = P $ \s => case unpack s of
('Z'::s') => [(Z, pack s')]
('S'::s') => map (\(n, s'') => (S n, s'')) $ unP integer (pack s')
_ => []
mutual
expr : Parser Nat
expr = term `chainl1` addop
term : Parser Nat
term = factor `chainl1` mulop
factor : Parser Nat
factor = parens expr <|> integer
mulop : Parser (Nat -> Nat -> Nat)
mulop = (symbol "*" *> pure (*)) <|>
(symbol "/" *> pure div)
addop : Parser (Nat -> Nat -> Nat)
addop = (symbol "+" *> pure (+)) <|>
(symbol "-" *> pure (-))
```

Now, if you try this:

```
main : IO ()
main = do
s <- getLine
printLn $ runParser expr s
```

then it will have the same divergant behaviour that you've observed. However, we can make two small changes:

Introduce a lazy alternative combinator:

```
orElse : Parser a -> Lazy (Parser a) -> Parser a
orElse p1 p2 = P $ \s => case unP p1 s of
[] => unP p2 s
results => results
```

Make sure the recursive part of `factor`

, i.e. the `parens expr`

part, is in this lazy position, by flipping the two alternatives:

```
factor = integer `orElse` parens expr
```

This then works as expected:

```
13:06:07 [cactus@galaxy brainfuck]$ idris Expr.idr -o Expr
13:06:27 [cactus@galaxy brainfuck]$ echo "SZ+(SSZ*SSSZ)" | ./Expr
Just 7
```

`A ::= Aa | b`

you can use the equivalent grammar:`A' ::= bA'' A'' ::= aA'' | ""`

(you can do this even with more productions and if the recursion is indirect, although it becomes too long for a comment.`chainl`

.