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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?

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1  
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

4 Answers 4

up vote 4 down vote accepted

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.

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1  
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
1  
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)

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4  
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
1  
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
3  
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.

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+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.

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