Assuming an input text of `N`

characters in length, the minimum number of nodes, including the root node and all leaf nodes, is `N+1`

, the maximum number of nodes, including the root and leaves, is `2N-1`

.

**Proof of minimum:** There must be at least one leaf node for every suffix, and there are `N`

suffixes. There need not be any inner nodes, example: if the text is a sequence of unique symbols, `abc$`

, there are no branches, hence no inner nodes in the resulting suffix tree:

Hence the minimum is `N`

leaves, `0`

inner nodes, and `1`

root node, in sum `N+1`

nodes.

**Proof of maximum:** The number of leaf nodes can never be larger than `N`

, because a leaf node is where a suffix ends, and you can't have more than `N`

distinct suffixes in a string of length `N`

. (In fact, you always have exactly `N`

distinct suffixes, hence `N`

leaf nodes exactly.) The root node is always exactly `1`

, so the question is what is the maximum number of inner nodes. Every inner node introduces a branch in the tree (because inner nodes of a suffix tree have at least 2 children). Each new branch must eventually lead to at least one extra leaf node, so if you have `K`

inner nodes, there must be at least `K+1`

leaf nodes, and the presence of the root node requires at least one additional leaf (unless the tree is empty). But the number of leaf nodes is bounded by `N`

, so the maximum number of inner nodes is bounded by `N-2`

. This yields exactly `N`

leaves, `1`

root, and a maximum of `N-2`

inner nodes, `2N-1`

in total.

To see that this is not only a theoretical upper bound, but some suffix trees actually reach this maximum, consider as an example a string with just one repeated character: 'aaa$'. Confirm that the suffix tree for this has 7 nodes (including root and leaves):

**Summary:** As evident, the only real variable is the number of inner nodes; the number of roots and leaves is constant at `1`

and `N`

for all suffix trees, while the number of inner nodes varies between `0`

and `N-2`

.