After having looked at the original problem, I think you have misunderstood it.

This question is about an `AND/OR`

tree where the nodes at the **deepest** level are `AND`

nodes. The logical operatives at the other nodes are determined by this factor - we do not know if they are `AND`

or `OR`

nodes initially, we're only given that the nodes at the deepest level are `AND`

nodes - so the nodes at the next higher level are `OR`

nodes, and the next higher level are `AND`

nodes, and so and so on... the logical operatives **interchange** between different depths of the tree. This will become clear if you look at the sample `AND/OR`

tree they have provided.

The way I'd approach this problem is to first figure out the logical connective for the root node. This can be done with a single scan over the expression and keeping track of the number of parentheses. Note that each `()`

corresponds to a new node in the tree (the next level of the tree). For an example, consider the expression:

```
((F(TF))(TF))
```

When you walk across this expression, first we encounter 3 opening parentheses, 2 closing, 1 opening and then finally 2 closing. If you take the maximum number of parentheses that were open at any given time during this walk, it'll be the maximum depth of this `AND/OR`

tree (`3`

in the above example).

So what does this mean? If the depth of the tree is odd, then the root node is an `AND`

node, otherwise the root is an `OR`

node (because the connectives alternate).

Once you know the connective of the root node, you can evaluate this expression using a simple stack based machine. We need to keep in mind that every time we open or close a parentheses, we need to flip the connective. Here's how the above expression gets evaluated:

```
AND |- (•(F(TF))(TF))
```

Notice that the bullet indicates where we are at the expression (like top of the stack). Then we proceed like below:

```
OR |- ((•F(TF))(TF)) // flipped the connective because we jumped a node
OR |- ((F•(TF))(TF)) // nothing to evaluate on the current node, push F
AND |- ((F(•TF))(TF))
AND |- ((F(T•F))(TF))
AND |- ((F(TF•))(TF))
AND |- ((F(F•))(TF)) // Two booleans on top, T AND F = F (reduce)
OR |- ((F(F)•)(TF)) // Jumped out of a node, flip the sign
OR |- ((FF•)(TF)) // Completely evaluated node on top, (F) = F (reduce)
OR |- ((F•)(TF)) // Two booleans on top, F OR F = F (reduce)
AND |- ((F)•(TF))
AND |- (F•(TF))
OR |- (F(•TF))
OR |- (F(T•F))
OR |- (F(TF•))
OR |- (F(T•))
AND |- (F(T)•)
AND |- (FT•)
AND |- (F•)
```

So you get the final answer as `F`

. This has some relation to shift-reduce parsing but the reductions in this case depend on the current depth of the AST we're operating at. I hope you'll be able to translate this idea into code (you'll need a stack and a global variable for keeping track of the current logical operative in force).

Finally, thank you for introducing that site. You might also like this site.