# How to break down a given text into words from the dictionary?

This is an interview question. Suppose you have a string `text` and a `dictionary` (a set of strings). How do you break down `text` into substrings such that each substring is found in the `dictionary`.

For example you can break down `"thisisatext"` into `["this", "is", "a", "text"]` using `/usr/share/dict/words`.

I believe backtracking can solve this problem (in pseudo-Java):

```void solve(String s, Set<String> dict, List<String> solution) {
if (s.length == 0)
return
for each prefix of s found in dict
solve(s without prefix, dict, solution + prefix)
}

List<String> solution = new List<String>()
solve(text, dict, solution)
```

Does it make sense? Would you optimize the step of searching the prefixes in the dictionary? What data structures would you recommend?

-
Correct me if I am wrong, but your solution is non polynomial. It is possible to solve this in at most O(n^2) using trie and DP (It is actually O(k) where k is the length of the longest word in the dictionary) . Let me know if you need the answer. –  ElKamina Jan 9 '12 at 21:05
@ElKamina Thanks. I would like to hear the DP solution –  Michael Jan 9 '12 at 22:38

This solution assumes the existence of Trie data structure for the dictionary. Further, for each node in Trie, assumes the following functions:

1. node.IsWord() : Returns true if the path to that node is a word
2. node.IsChild(char x): Returns true if there exists a child with label x
3. node.GetChild(char x): Returns the child node with label x
``````Function annotate( String str, int start, int end, int root[], TrieNode node):
i = start
while i<=end:
if node.IsChild ( str[i]):
node = node.GetChild( str[i] )
if node.IsWord():
root[i+1] = start
i+=1
else:
break;

end = len(str)-1
root = [-1 for i in range(len(str)+1)]
for start= 0:end:
if start = 0 or root[start]>=0:
annotate(str, start, end, root, trieRoot)

index  0  1  2  3  4  5  6  7  8  9  10  11
str:   t  h  i  s  i  s  a  t  e  x  t
root: -1 -1 -1 -1  0 -1  4  6 -1  6 -1   7
``````

I will leave the part for you to list the words that make up the string by reverse traversing the root.

Time complexity is O(nk) where n is the length of the string and k is the length of the longest word in the dictionary.

PS: I am assuming following words in the dictionary: this, is, a, text, ate.

-
Doesn't root need to be an array of lists? Otherwise you'll lose multiple paths through the string that converge at the same place –  Timothy Jones Jan 9 '12 at 23:56
Otherwise, nice solution :) –  Timothy Jones Jan 9 '12 at 23:56
@TimothyJones I thought the poster wanted one solution, not all solutions. You are right, by having a list you get to print all the word combinations that form the string. –  ElKamina Jan 9 '12 at 23:59
It might also be worth adding the time complexity to your answer - I think it's O(n.k), where n is the size of the text, and k is the longest word in the dictionary. (plus whatever it takes to read the final path - in the non-multiple path version I think it's O(m), where m is the number of words in the result). –  Timothy Jones Jan 10 '12 at 11:11
Can you please tell me what this step done is root = [-1 for i in range(len(str)+1)]. –  devnull Aug 27 '12 at 20:29

Approach 1- Trie looks to be a close fit here. Generate trie of the words in english dictionary. This trie building is one time cost. After trie is built then your `string` can be easily compared letter by letter. if at any point you encounter a leaf in the trie you can assume you found a word, add this to a list & move on with your traversal. Do the traversal till you have reached the end of your `string`. The list is output.

Time Complexity - O(1) + O(x). Trie comparisons happen in constant time + length of your string.

Space Complexity - O(n). Size of your dictionary.

Approach 2 - I have heard of Suffix Trees, never used them but it might be useful here.

Approach 3 - is more pedantic & a lousy alternative. you have already suggested this.

You could try the other way around. Run through the `dict` is check for sub-string match. Here I am assuming the keys in `dict` are the `words` of the english dictionary `/usr/share/dict/words`. So psuedo code looks something like this -

``````(list) splitIntoWords(String str, dict d)
{
words = []
for (word in d)
{
if word in str
words.append(word);
}
return words;
}
``````

Complexity - O(n) running through entire dict + O(1) for substring match.

Space - worst case O(n) if `len(words) == len(dict)`

-
You still have to deal with backtracking, right? If your dictionary contains both "the" and "these", then the inputs "thesebugs" and "thesets" will cause problems. –  Adrian McCarthy Jan 9 '12 at 21:11
This seems to only find those words that occur in the string. There is an additional condition in the problem - the words must cover the whole string without overlapping. –  Rafał Dowgird Jan 9 '12 at 22:23
I don't think that O(1) lookup is correct for a trie. –  Timothy Jones Jan 9 '12 at 23:51

There is a very thorough writeup for the solution to this problem in this blog post.

The basic idea is just to memoize the function you've written and you'll have an O(n^2) time, O(n) space algorithm.

-
+1 Nice answer with additional commentary on several approaches and how a variety of candidates respond. As the blogger states, if someone can't do a competent job on this toy problem, they'd have a very hard time in large scale information retrieval and NLP. –  Iterator Jan 10 '12 at 5:01

You can solve this problem using Dynamic Programming and Hashing.

Calculate the hash of every word in the dictionary. Use the hash function you like the most. I would use something like (a1 * B ^ (n - 1) + a2 * B ^ (n - 2) + ... + an * B ^ 0) % P, where a1a2...an is a string, n is the length of the string, B is the base of the polynomial and P is a large prime number. If you have the hash value of a string a1a2...an you can calculate the hash value of the string a1a2...ana(n+1) in constant time: (hashValue(a1a2...an) * B + a(n+1)) % P.

The complexity of this part is O(N * M), where N is the number of words in the dictionary and M is the length of the longest word in the dictionary.

Then, use a DP function like this:

``````   bool vis[LENGHT_OF_STRING];
bool go(char str[], int length, int position)
{
int i;

// You found a set of words that can solve your task.
if (position == length) {
return true;
}

// You already have visited this position. You haven't had luck before, and obviously you won't have luck this time.
if (vis[position]) {
return false;
}
// Mark this position as visited.
vis[position] = true;

// A possible improvement is to stop this loop when the length of substring(position, i) is greater than the length of the longest word in the dictionary.
for (i = position; position < length; i++) {
// Calculate the hash value of the substring str(position, i);
if (hashValue is in dict) {
// You can partition the substring str(i + 1, length) in a set of words in the dictionary.
if (go(i + 1)) {
// Use the corresponding word for hashValue in the given position and return true because you found a partition for the substring str(position, length).
return true;
}
}
}

return false;
}
``````

The complexity of this algorithm is O(N * M), where N is the length of the string and M is the length of the longest word in the dictionary or O(N ^ 2), depending if you coded the improvement or not.

So the total complexity of the algorithm will be: O(N1 * M) + O(N2 * M) (or O(N2 ^ 2)), where N1 is the number of words in the dictionary, M is the length of the longest word in the dictionary and N2 is the lenght of the string).

If you can't think of a nice hash function (where there are not any collision), other possible solution is to use Tries or a Patricia trie (if the size of the normal trie is very large) (I couldn't post links for these topics because my reputation is not high enough to post more than 2 links). But in you use this, the complexity of your algorithm will be O(N * M) * O(Time needed to find a word in the trie), where N is the length of the string and M is the length of the longest word in the dictionary.

I hope it helps, and I apologize for my poor english.

-