begin() should point to pretty much depends on the order in which you want to traverse your tree. Using the root may be sensible, e.g., for a breadth first walk of the tree. The
end() doesn't really sit on a tree node: this position is accessed and indicates that the end of the sequence is reached. Whether it indicates anything related to the tree somewhat depends on what sort of iteration you want to support: when supporting only forward iteration it can just indicate the end. When also supporting bidirectional iteration, it needs to know how to find the node right before the end.
In any case, the place pointed to isn't really accessed and you need a suitable indicator. For a forward iteration only iterator
end() could just return an iterator pointing to null and when you move on from the last node you just set the iterator's pointer to null as well: equality comparing the two pointers would yield
true, indicating that you have reached the end. When wanting to support bidirectional iteration you'll need some sort of link record which can be used to navigate to the previous node but which doesn't need to store a value.
The ordered associated containers (
std:set<V>, etc.) are internally implemented as some sort of tree (e.g., a Red/Black-tree). The
begin() iterator starts with the left-most node and the
end() iterator refers to the position after the right-most node. The
operator++() just finds the next node to the right of the current:
- if the iterator sits on a node without a right child node, it walks along the chain of parents until it finds a parent reaching its child via the left branch of the tree
- if it sits on a node with a right child node it walks to the child and then down the sequence of left children of this child (if any) to find the left-most child in the right subtree.
Obviously, if you don't walk your tree from left to right but rather, e.g., from top to bottom, you'll need a different algorithm. The easiest approach for me is to draw a tree on a piece of paper and see how to get to the next node.
If you haven't implemented a data structure using your own iterators I'd recommend trying things out on a simple sequential data structure, e.g., a list: There it is pretty obvious how to reach the next node and when the end is reached. Once the general iteration principle is clear, creating a tree is just a matter of getting the navigation right.