Types are both more important and more informative in Haskell than in most other languages. When you don't understand Haskell, a good first step is to think about types. So let's do that. We'll fire up ghci and enter:

```
Prelude> let mult_add d s = d + 10 * s
```

And now ask for its type:

```
Prelude> :t mult_add
mult_add :: Num a => a -> a -> a
```

That is, mult_add takes an `a`

and another `a`

, and returns an `a`

, with the proviso that `a`

is an instance of the `Num`

class (so that you can add and multiply them).

You're asked to use `foldr`

to write this function, so let's look at the type of that:

```
Prelude> :t foldr
foldr :: (a -> b -> b) -> b -> [a] -> b
```

That looks a bit intimidating, so let's break it down. The first part, `(a -> b -> b)`

tells us that `foldr`

needs a function of two variables, `a`

and `b`

. Well, we have one of those already - it's `mult_add`

. So what happens if we feed in `mult_add`

as the first argument to `foldr`

?

```
Prelude> :t foldr mult_add
foldr mult_add :: Num b => b -> [b] -> b
```

Okay! We now have a function that takes a `b`

and a `[b]`

(a list of `b`

s) and returns a `b`

. The function you're trying to write needs to return `0`

when it's given the empty list, so let's try feeding it the empty list, with a few different values for the remaining argument:

```
Prelude> foldr mult_add 10 []
10
Prelude> foldr mult_add 5 []
5
```

Hey, that's interesting. If we feed it the number `x`

and the empty list, it just returns `x`

(**Note:** this is always true for `foldr`

. If we give it the initial value `x`

and the empty list `[]`

, it will return `x`

, no matter what function we use in place of `mult_add`

.)

So let's try feeding it `0`

as the second argument:

```
Prelude> foldr mult_add 0 []
0
```

That seems to work. Now how about if we feed it the list `[1,2,3,4]`

instead of the empty list?

```
Prelude> foldr mult_add 0 [1,2,3,4]
4321
```

Nice! So it seems to work. Now the question is, **why** does it work? The trick to understanding `foldr`

is that `foldr f x xs`

inserts the function `f`

between every element of `xs`

, and additionally puts `x`

at the end of the list, and collects everything from the right (that's why it's called a **right** fold). So, for example:

```
foldr f 0 [1,2,3] = 1 `f` (2 `f` (3 `f` 0))
```

where the backticks indicate that we're using the function in its infix form (so its first argument is the one on the left, and the second argument is the one on the right). In your example you have `f = mult_add`

, which multiplies its second argument by 10 and adds it to the first argument:

```
d `mult_add` s = d + 10 * s
```

so you have

```
foldr mult_add 0 [1,2,3] = 1 `mult_add` (2 `mult_add` (3 `mult_add 0))
= 1 `mult_add` (2 `mult_add` 3)
= 1 `mult_add` 32
= 321
```

which does what you expect. To make sure you understand this, work out what would happen if you defined `mult_add`

the other way around, i.e.

```
mult_add d s = 10 * d + s
```

`mult_add`

is a helper function. Its definition is given as`mult_add d s = d + 10*s`

. You should use that for`form_number_back`

. – Daniel Fischer Jun 11 '12 at 22:53`1982 = 2 * 1 + 8 * 10 + 9 * 100 + 1 * 1000 = 2 + 10 * (8 + 10 * (9 + 10 * (1 + 10 * (0))))`

. – Daniel Wagner Jun 11 '12 at 23:17`mult_add`

in a source file, load it, and ask ghci what the type of`foldr mult_add`

is,`:t foldr mult_add`

. – Daniel Fischer Jun 11 '12 at 23:19`foldr`

requires that you pass a function, initial value, and the list. – sdcvvc Jun 12 '12 at 0:13