Let's draw it. First I'll use a small circle for the empty tree and a circle for data at a node, with two branches for the subtrees. `left`

and `right`

will also themselves be trees.

OK, let's take the code line by line and unpack the case statement into pattern matching at the top level, because

```
function x y = case (x,y) of
(0,1) -> this
(1,10) -> that
```

can be written

```
function 0 1 = this
function 1 10 = that
```

# gurgle Empty_Tree Empty_Tree = True

Noting much to learn here - it's yes if they're both empty. OK.

# gurgle Empty_Tree _ = False

This means we get stuff like

Because it gives `False`

no matter what the second argument is. We've already eliminated the case that the second argument is `Empty_Tree`

in the last line, so the second argument has to be non-empty to give False here.

The next line is very like it, only the other way round:

# gurgle _ Empty_Tree = False

Again, stuff like this

is getting a No for an answer. I'm beginning to suspect once I've read these two lines it's checking that there's something the same with the shape of the two trees.

# Recursive case

## gurgle x y = gurgle (left_tree x) (right_tree y) && gurgle (right_tree x) (left_tree y)

This is the most interesting one. Notice the swap-sides thing it's doing. It's not just checking that the subtrees of both are the same, it's comparing right with left.

Also notice it's ignoring the value at the node - that's why I got rid of the numbers in this example.

# What do we need to make it True?

To make it true we need the shape on the left of one to match the shape of the right of the other:

# What's your point?

The recursive case says the left of one must match the right of the other. The trees have to be mirror images of each other when you ignore the values.

# What's going on in the pattern match?

The recursive case in the original said

```
(Node _ left_a right_a, Node _ left_b right_b) -> gurgle left_a right_b
&& gurgle right_a left_b
```

Let's colour that code in to match the diagrams above:

Colouring it in is a good visual clue for what's going on, since the names `left_a`

etc on the left don't mean anything special, they're just there to refer to bits of the tree.

Which bits?

This is there to match up with the definition of Node:

The first (grey) bit is the element. `element`

is now a function from tree nodes to values.

The second (pale brown) bit is the left subtree, `left_tree`

. It could be large and complex, or just an `Empty_Tree`

. (It can be any Tree.)

The third (pale orange) bit is the right subtree, `right_tree`

. They match up with my diagrams like this:

I've not put any details in the coloured box - it could be any tree, big or small.

When your original code put this on the left hand side

it was giving names to the subtrees, so that it could refer to them directly, rather than using the `left-tree`

and `right_tree`

functions.

`element`

is never matched on). However, I think there's more mirroring going on... – Koterpillar Jun 9 '13 at 23:50