# Split a string to a string of valid words using Dynamic Programming

I need to find a dynamic programming algorithm to solve this problem. I tried but couldn't figure it out. Here is the problem:

You are given a string of n characters s[1...n], which you believe to be a corrupted text document in which all punctuation has vanished (so that it looks something like "itwasthebestoftimes..."). You wish to reconstruct the document using a dictionary, which is available in the form of a Boolean function dict(*) such that, for any string w, dict(w) has value 1 if w is a valid word, and has value 0 otherwise.

1. Give a dynamic programming algorithm that determines whether the string s[*] can be reconstituted as a sequence of valid words. The running time should be at most O(n^2), assuming that each call to dict takes unit time.
2. In the event that the string is valid, make your algorithm output the corresponding sequence of words.
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Is this homework? –  Sjoerd Mar 15 '11 at 11:07
Well, it is an exercise from a textbook. I don't have the solutions to the exercises, and I am not sure how to solve this problem. –  Pet Mar 15 '11 at 11:10
First thing that comes to mind - ambiguity. Suppose your dictionary has words 'was', 'her' and 'washer'. You can just prefer shortest words, though. Wait, no... you can chop part from word and render string invalid - like catch 'auto' from 'automatic'. –  alxx Mar 15 '11 at 11:17
Did you try to search for answer first? There are already few questions about this problem on SO - stackoverflow.com/questions/4755157/split-string-into-words , stackoverflow.com/questions/3553958/… , stackoverflow.com/questions/3466972/… . Some of them mention dynamic programming solutions. –  hoha Mar 15 '11 at 11:38

Let the length of your compacted document be N.

Let b(n) be a boolean: true if the document can be split into words starting from position n in the document.

b(N) is true (since the empty string can be split into 0 words). Given b(N), b(N - 1), ... b(N - k), you can construct b(N - k - 1) by considering all words that start at character N - k - 1. If there's any such word, w, with b(N - k - 1 + len(w)) set, then set b(N - k - 1) to true. If there's no such word, then set b(N - k - 1) to false.

Eventually, you compute b(0) which tells you if the entire document can be split into words.

In pseudo-code:

``````def try_to_split(doc):
N = len(doc)
b = [False] * (N + 1)
b[N] = True
for i in range(N - 1, -1, -1):
for word starting at position i:
if b[i + len(word)]:
b[i] = True
break
return b
``````

There's some tricks you can do to get 'word starting at position i' efficient, but you're asked for an O(N^2) algorithm, so you can just look up every string starting at i in the dictionary.

To generate the words, you can either modify the above algorithm to store the good words, or just generate it like this:

``````def generate_words(doc, b, idx=0):
length = 1
while true:
assert b(idx)
if idx == len(doc): return
word = doc[idx: idx + length]
if word in dictionary and b(idx + length):
output(word)
idx += length
length = 1
``````

Here b is the boolean array generated from the first part of the algorithm.

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Isn't it inefficient if you consider all words that start at character N - k - 1. A better method would be `b[i] = true if there exists i <= j < N such that dict(s[i..j]) and b[j+1..N-1]` –  Minh Pham Mar 7 '13 at 2:12

A dp solution in c++:

``````int main()
{
set<string> dict;
dict.insert("12");
dict.insert("123");
dict.insert("234");
dict.insert("12345");
dict.insert("456");
dict.insert("1234");
dict.insert("567");
dict.insert("123342");
dict.insert("42");
dict.insert("245436564");
dict.insert("12334");

string str = "123456712334245436564";

int size = str.size();
vector<int> dp(size+1, -1);
dp[0] = 0;
vector<string > res(size+1);
for(int i = 0; i < size; ++i)
{
if(dp[i] != -1)
{
for(int j = i+1; j <= size; ++j)
{
const int len = j-i;
string substr = str.substr(i, len);
if(dict.find(substr) != dict.end())
{
string space = i?" ":"";
res[i+len] = res[i] + space + substr;
dp[i+len] = dp[i]+1;
}
}
}
}
cout << *dp.rbegin() << endl;
cout << *res.rbegin() << endl;

return 0;
}
``````
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Why don't you give the description what what you have done and explain why you have done so? –  Minh Pham Mar 7 '13 at 1:57
@tobias could you please explain its algo –  EmptyData May 21 at 3:38
Just some random code doesn't help anyone. You should provide an explanation. –  adijo Jun 13 at 6:05

To formalize what @MinhPham suggested.

This is a dynammic programming solution.

Given a string str, let

b[i] = true if the substring str[0...i] (inclusive) can be split into valid words.

Prepend some starting character to str, say !, to represent the empty word. str = "!" + str

The base case is the empty string, so

b[0] = true.

For the iterative case:

b[j] = true if b[i] == true and str[i..j] is a word for all i < j

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The string s[] can potentially be split into more than one ways. The method below finds the maximum number of words in which we can split s[]. Below is the sketch/pseudocode of the algorithm

bestScore[i] -> Stores the maximum number of words in which the first i characters can be split (it would be MINUS_INFINITY otherwise)

``````for (i = 1 to n){
bestScore[i] = MINUS_INFINITY
for (k = 1 to i-1){
bestScore[i] = Max(bestSCore[i], bestScore[i-k]+ f(i,k))
}
}
``````

Where f(i,k) is defined as:

``````f(i,k) = 1 : if s[i-k+1 to i] is in dictionary
= MINUS_INFINITY : otherwise
``````

bestScore[n] would store the maximum number of words in which s[] can be split (if the value is MINUS_INFINIY, s[] cannot be split)

Clearly the running time is O(n^2)

As this looks like a textbook exercise, I will not write the code to reconstruct the actual split positions.

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The `O(N^2)` Dp is clear but if you know the words of the dictionary, i think you can use some precomputations to get it even faster in `O(N)`. Aho-Corasick

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