**Hash-table**

The simplest (although not particularly efficient) approach is simple recursion.

For each cell, recursively look around, keeping track of the current word and, at each step, checking whether the current word is contained in the hash table.

```
set up hash table with all words
for each cell c
findWords(c, c.value)
findWords(cell c, string current)
if current.length > longestWord
return
if hashTable.contains(current)
output current
for each neighbour n of c
findWords(n, current + c.value)
```

Now, to make this more efficient, we can essentially simulate a trie.

We'll put all prefixes of every word into the hash table, so for `"johnny"`

, you'd have `"j"`

, `"jo"`

, `"joh"`

, `"john"`

, `"johnn"`

and `"johnny"`

in the hash table.

We can just have a flag in the hash table to indicate whether or not the given entry is a valid word. So, for the above, only `"johnny"`

would have this flag.

```
set up hash table with all words, but also all prefixes of words
for each cell c
findWords(c, c.value)
findWords(cell c, string current)
if hashTable.contains(current)
if isValidWord(current)
output current
for each neighbour n of c
findWords(n, current + c.value)
```

**Trie**

A trie seems like a better data structure for this problem.

First, construct the trie with all the words. Then, for each position on the grid, check whether there's an edge from the root for its value. If there is, recursively check each of it's neighbours, checking whether there's an edge for that value, and checking it's neighbours, and so on.

The pseudo-code is something like this:

```
set up trie with all words
for each cell c
if root.hasChild(c.value)
findWords(root.getChild(c.value), c)
findWords(node n, cell c)
if n.isValidWord
output n.getWord
for each neighbour ne of c
if n.hasChild(ne.value)
findWords(n.getChild(ne.value), ne)
```