You have got some suggestions for a cleaner way to write the `insert`

function, but so far nobody has told you what went wrong with your implementation, so let me start with that:

```
data ArbolBinario a = Node a (ArbolBinario a) (ArbolBinario a) | EmptyNode
deriving(Show)
insert(x) EmptyNode= insert(tail x) (Node (head x) EmptyNode EmptyNode)
insert(x) (Node e izq der)
|x == [] = EmptyNode
|head x == e = (Node e izq der)
|head x < e = (Node e (insert x izq) der)
|head x > e = (Node e izq (insert x der))
```

For brevity, I use a shorter list and abbreviate `EmptyNode`

to `E`

.

```
insert [1,2] E
~> insert [2] (Node 1 E E)
-- 2 > 1, so the last clause, head x > e, is used
~> Node 1 E (insert [2] E)
-- insertion in empty tree, first equation is used
~> Node 1 E (insert [] (Node 2 E E))
-- Now the first clause of the second equation is used
~> Node 1 E (E)
```

When all elements have been inserted and you reach the end of the list, instead of doing nothing, you delete the node. The minimal change to fix this would be changing the first clause of the second equation for `insert`

to

```
|x == [] = Node e izq der
```

That would however still leave one failure case (which you already have),

```
insert [] EmptyNode = insert (tail []) (Node (head []) EmptyNode EmptyNode)
```

will cause `*** Exception: Prelude.tail: empty list`

.

Apart from being the cause of the abovementioned error, the use of `head`

and `tail`

here is also highly unidiomatic. The usual way to define such a function would be to pattern-match on the list. Also unidiomatic is your check for an empty list, `x == []`

, the idiomatic way is to use `null x`

for that. In this case, the other guards require the element type to be an instance of `Ord`

, so there is no semantic change, but in general, `x == []`

imposes an `Eq`

constraint on the element type, while `null x`

works with arbitrary types.

Finally, although you think your guards `head x == e`

, `head x < e`

, `head x > e`

cover all possibilities (for valid `Ord`

instances, they do - excepting floating point types, where a `NaN`

is neither equal to nor smaller than nor larger than any value, but whether these `Ord`

instances are valid is a matter of debate), the compiler can't be sure of that, and will (when asked to warn about such things, which it usually should be, always compile with `-Wall`

) warn about non-exhaustive patterns in the definition of `insert`

. To cover all cases in a way that the compiler knows all cases are covered, the last guard should have an `otherwise`

condition.

Bringing your code into a more idiomatic shape (and fixing the outstanding `insert [] EmptyNode`

bug) results in

```
insert :: Ord a => [a] -> ArbolBinario a -> ArbolBinario a
insert [] t = t -- if there's nothing to insert, don't change anything
insert (x:xs) EmptyNode = insert xs (Node x EmptyNode EmptyNode)
-- Using as-patterns, `l` is the entire list, `x` its head, `t` the entire tree
insert l@(x:_) t@(Node e izq der)
| x == e = t
| x < e = Node e (insert l izq) der
| otherwise = Node e izq (insert l der)
```

Now we can look for further problems. One probably unintended aspect of `insert`

is that if the head of the list of elements to be inserted is already in the tree, the entire list is thrown away and the tree completely unchanged, so e.g.

```
insert [1 .. 10] (Node 1 EmptyNode EmptyNode) = Node 1 EmptyNode EmptyNode
```

The usual way to handle such things is to only drop the head of the list and still insert the remaining elements. That would be achieved by changing the last equation of the definition to

```
insert l@(x:xs) t@(Node e izq der)
| x == e = insert xs t
| x < e = Node e (insert l izq) der
| otherwise = Node e izq (insert l der)
```

More probably unintended aspects are

`insert xs EmptyNode`

always produces a tree in which every node has only one (or none, for the lowest) nonempty subtree, i.e. the constructed tree is basically a list.
the clauses in the last equation of the definition strongly suggest that the tree should be a binary search tree, but that property is not maintained by the definition. e.g.

```
insert [1,10] (Node 3 (Node 2 E E) (Node 7 E E))
~> Node 3 (insert [1,10] (Node 2 E E)) (Node 7 E E)
~> Node 3 (Node 2 (insert [1,10] E) E) (Node 7 E E)
~> Node 3 (Node 2 (insert [10] (Node 1 E E)) E) (Node 7 E E)
~> Node 3 (Node 2 (Node 1 E (Node 10 E E)) E) (Node 7 E E)
3
/ \
/ \
2 7
/
/
1
\
\
10
```

The best way to solve these problems is, as OJ. suggested before, to separate out the case of inserting a single element into a tree

```
insertOne :: Ord a => a -> ArbolBinario a -> ArbolBinario a
insertOne x EmptyNode = Node x EmptyNode EmptyNode
insertOne x t@(Node e izq der)
| x == e = t
| x < e = Node e (insertOne x izq) der
| otherwise = Node e izq (insertOne x der)
```

and use that to insert each element from the list, finding its position from the top:

```
insertList :: Ord a => [a] -> ArbolBinario a -> ArbolBinario a
insertList [] t = t
insertList (x:xs) t = insertList xs (insertOne x t)
-- Alternative way:
-- insertList (x:xs) t = insertOne x (insertList xs t)
```

These patterns of computation are so common that they have been captured in functions defined in the `Prelude`

:

```
insertList xs t = foldl (flip insertOne) t xs
-- or, for the alternative way:
-- insertList xs t = foldr insertOne t xs
```

As you can see, with the natural argument order of `insertOne`

, for the left fold, we need to apply the `flip`

combinator to swap its argument order, which hints at the fact that the natural fold operation for lists is the right fold, `foldr`

.

However, since `insertOne`

needs to know its tree argument before it can do anything, it's not a function tailor-made to be used in right folds, using it in a left fold can be more efficient (but to actually have an efficiency gain, one would have to use a strict left fold `foldl'`

, available from `Data.List`

, and a stricter version of `insertOne`

).