Generally, for tail-recursive functions, you need an accumulator argument -- with purity, the result could otherwise only depend on the base case reached. So you would need a helper function taking also an accumulator argument, and call that with an initial value for the accumulator,

```
hexToInteger :: String -> Integer
hexToInteger string = hexToIntegerHelper initialAccumulator string
```

and you must find out

- what initial value you should pass for the accumulator
- how the accumulator has to be updated in each step.

For example, a tail-recursive implementation of `reverse`

is

```
reverse :: [a] -> [a]
reverse xs = reverseHelper [] xs
reverseHelper :: [a] -> [a] -> [a]
reverseHelper accumulator [] = accumulator
reverseHelper accumulator (x:xs) = reverseHelper (x:accumulator) xs
```

and a tail-recursive factorial (fudging the case of a negative argument)

```
factorial :: Integer -> Integer
factorial n = factorialHelper 1 n
factorialHelper :: Integer -> Integer -> Integer
factorialHelper accumulator n
| n < 2 = accumulator
| otherwise = factorialHelper (n*accumulator) (n-1)
```

So you can see the general structure of `hexToIntegerHelper`

,

```
hexToIntegerHelper :: Integer -> String -> Integer
hexToIntegerHelper accumulator "" = accumulator
hexToIntegerHelper accumulator (d:ds) = hexToIntegerHelper (newAccumulatorFrom accumulator d) ds
```

and the question is how the new accumulator is to be computed from the old one and the hexadecimal digit (and what the initial accumulator should be).

For the updating of the accumulator,

```
digitToInt :: Char -> Int
```

from `Data.Char`

could be useful, that handles all hexadecimal digits. But, it doesn't return the desired type, so you'd need to use a `fromIntegral`

or a `toInteger`

to convert the `Int`

to `Integer`

.