Some problems:

`x == 0`

or `x == 1`

, but `x`

is a `Char`

, so you mean `x == '0'`

.

You write `(xs:x)`

. There's no pattern for matching at the end of a list. Perhaps use a helper function that reverses the list first.

`[xs]`

has one element, and will never be `""`

. Use a base case instead.

Pattern matching is more helpful than equality checking.

`**`

is for floating point powers, `^`

is for integer powers

You often use `[xs]`

where you mean `xs`

. You don't need to put square brackets to make a list.

Here's a rewrite that works:

```
negbin_dezi1 :: NegaBinary -> Integer
negbin_dezi1 xs = negbin (reverse xs) 0
negbin [] _ = 0
negbin (x:xs) n
| x == '0' = negbin xs (n+1)
| x == '1' = (-2)^n + (negbin xs (n+1))
```

It would be nicer to use pattern matching:

```
negbin_dezi2 :: NegaBinary -> Integer
negbin_dezi2 xs = negbin (reverse xs) 0 where
negbin [] _ = 0
negbin ('0':xs) n = negbin xs (n+1)
negbin ('1':xs) n = (-2)^n + negbin xs (n+1)
```

But maybe it would be nicer to convert '0' to 0 and '1' to 1 and just multiply by that:

```
val :: Char -> Int
val '0' = 0
val '1' = 1
negbin_dezi3 :: NegaBinary -> Integer
negbin_dezi3 xs = negbin (reverse xs) 0 where
negbin [] _ = 0
negbin (x:xs) n = val x * (-2)^n + negbin xs (n+1)
```

I'd not write it that way, though:

A completely different approach is to think about the whole thing at once.

```
"10010" -rev> [0,1,0,0,1] -means> [ 0, 1, 0, 0, 1 ]
[(-2)^0, (-2)^1, (-2)^2, (-2)^3, (-2)^4]
```

so let's make both lists

```
powers = [(-2)^n | n <- [0..]]
coefficients = reverse.map val $ xs
```

and multiply them

```
zipWith (*) powers coefficients
```

then add up, giving:

```
negbin_dezi4 xs = sum $ zipWith (*) powers coefficients
where powers = [(-2)^n | n <- [0..]]
coefficients = reverse.map val $ xs
```

You could rewrite `powers`

as `map ((-2)^) [0..]`

,

or even nicer: `powers = 1:map ((-2)*) powers`

.

(It's nicer because it reuses previous calculations and is pleasantly clean.)