Your language, about what you thought the program should *do*, suggests to me that you need help to escape from the trap of imperative thinking. Let me try to offer some help, based on thinking about what things *are*, not what things *do*.

For `findpath (Leaf y) x`

, you're heading in the right direction. You just need to give `if`

a lowercase `i`

, and think about what the correct `Path`

to a `Leaf`

must be.

Now, let's think about the other possibility. You know more than that it's some `t`

. You know that you're really trying to figure out what

```
findpath (Node l r) x
```

is (what it `=`

, indeed), because that's the other possibility for a `BTree`

. Think of splitting the problem by asking "Is this `BTree`

a `(Leaf y)`

or a `(Node l r)`

?" as one conceptual step of program design. Now, in order to figure out what the above left-hand side equals, you're entitled to some recursively computed information, namely what

```
findpath l x
```

and

```
findpath r x
```

are. If you know `Path`

information for both `l`

and `r`

, can you say what the `Path`

for the whole `Node l r`

is? Let me rephrase that question by writing it in Haskell:

```
findpath :: Eq a => BTree a -> a -> Path
findpath (Leaf y) x = if y==x then ??? else Nothing
findpath (Node l r) x = nodepath (findpath l x) (findpath r x) where
nodepath :: Path -> Path -> Path
nodepath ???
```

I have expressed my question by introducing a *helper function* `nodepath`

which takes as arguments the recursively computed information. Now you can try to implement `nodepath`

by pattern matching on those two paths for the left and right subtrees, respectively. If you know whether they are `(Just p)`

or `Nothing`

, then you should be able to say what the path for the whole node must be.

Lesson one, the useful thoughts are of the form: "If this is like such-and-such, then that must be so-and-so.". Being, not doing.

Lesson two, the basic method of programming over a datatype is: split into constructor cases (`Leaf`

versus `Node`

, `Just`

versus `Nothing`

); collect useful information from any substructures by recursive calls; say what the value for the whole structure must be.

If you follow my advice and figure out what `nodepath`

should be, you may find that it's simple enough not to merit being a separate named definition. In that case, just replace the `nodepath`

call with its meaning and cut out the `where`

-clause. But it's good to start by introducing `nodepath`

, as it expresses a useful conceptual step towards solving the problem.

`findpath`

type indicates that it returns`[Dir]`

, which is not a type that accepts the value`Nothing`

. The question suggests that`findpath`

should return`Path`

, which is`Maybe [Dir]`

, allowing for the possibility of failure. I wonder also whether the type should be`findpath :: Eq a => BTree a -> a -> Path`

which would allow you to test whether the value you seek is equal to a value stored at a leaf of the tree. – pigworker Nov 11 '12 at 11:17