This is topological sorting on a directed acyclic graph. You need to first build the graph: vertices are letters, and there's an edge if one is lexicographically less than the other. The topological order then gives you the answer.

A contradiction is when the directed graph is not acyclic. Uniqueness is determined by whether or not a Hamiltonian path exists, which is testable in polynomial time.

### Building the graph

You do this by comparing each two consecutive "words" from the dictionary. Let's say you have these two words appearing one after another:

```
x156@
x1$#2z
```

Then you find the longest common prefix, `x1`

in this case, and check the immediately following characters after this prefix. In this case,, we have `5`

and `$`

. Since the words appear in this order in the dictionary, we can determine that `5`

must be lexicographically smaller than `$`

.

Similarly, given the following words (appearing one after another in the dictionary)

```
jhdsgf
19846
19846adlk
```

We can tell that `'j' < '1'`

from the first pair (where the longest common prefix is the empty string). The second pair doesn't tell us anything useful (since one is a prefix of another, so there are no characters to compare).

Now suppose later we see the following:

```
oi1019823
oij(*#@&$
```

Then we've found a contradiction, because this pair says that `'1' < 'j'`

.

### The topological sort

There are two traditional ways to do topological sorting. Algorithmically simpler is the depth-first search approach, where there's an edge from `x`

to `y`

if `y < x`

.

The pseudocode of the algorithm is given in Wikipedia:

```
L ← Empty list that will contain the sorted nodes
S ← Set of all nodes with no incoming edges
function visit(node n)
if n has not been visited yet then
mark n as visited
for each node m with an edge from n to m do
visit(m)
add n to L
for each node n in S do
visit(n)
```

Upon conclusion of the above algorithm, the list `L`

would contain the vertices in topological order.

### Checking uniqueness

The following is a quote from Wikipedia:

If a topological sort has the property that all pairs of consecutive vertices in the sorted order are connected by edges, then these edges form a directed Hamiltonian path in the DAG. If a Hamiltonian path exists, the topological sort order is unique; no other order respects the edges of the path. Conversely, if a topological sort does not form a Hamiltonian path, the DAG will have two or more valid topological orderings, for in this case it is always possible to form a second valid ordering by swapping two consecutive vertices that are not connected by an edge to each other. Therefore, it is possible to test in polynomial time whether a unique ordering exists, and whether a Hamiltonian path exists.

Thus, to check if the order is unique or not, you simply check if all two consecutive vertices in `L`

(from the above algorithm) are connected by direct edges. If they are, then the order is unique.

### Complexity analysis

Once the graph is built, topological sort is `O(|V|+|E|)`

. Uniqueness check is `O(|V| edgeTest)`

, where `edgeTest`

is the complexity of testing whether two vertices are connected by an edge. With an adjacency matrix, this is `O(1)`

.

Building the graph requires only a single linear scan of the dictionary. If there are `W`

words, then it's `O(W cmp)`

, where `cmp`

is the complexity of comparing two words. You always compare two subsequent words, so you can do all sorts of optimizations if necessary, but otherwise a naive comparison is `O(L)`

where `L`

is the length of the words.

You may also shortcircuit reading the dictionary once you've determined that you have enough information about the alphabet, etc, but even a naive building step would take `O(WL)`

, which is the size of the dictionary.