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Input: A positive integer K and a big text. The text can actually be viewed as word sequence. So we don't have to worry about how to break down it into word sequence.
Output: The most frequent K words in the text.

My thinking is like this.

  1. use a Hash table to record all words' frequency while traverse the whole word sequence. In this phase, the key is "word" and the value is "word-frequency". This takes O(n) time.

  2. sort the (word, word-frequency) pair; and the key is "word-frequency". This takes O(n*lg(n)) time with normal sorting algorithm.

  3. After sorting, we just take the first K words. This takes O(K) time.

To summarize, the total time is O(n+nlg(n)+K), Since K is surely smaller than N, so it is actually O(nlg(n)).

We can improve this. Actually, we just want top K words. Other words' frequency is not concern for us. So, we can use "partial Heap sorting". For step 2) and 3), we don't just do sorting. Instead, we change it to be

2') build a heap of (word, word-frequency) pair with "word-frequency" as key. It takes O(n) time to build a heap;

3') extract top K words from the heap. Each extraction is O(lg(n)). So, total time is O(k*lg(n)).

To summarize, this solution cost time O(n+k*lg(n)).

This is just my thought. I haven't find out way to improve step 1).
I Hope some Information Retrieval experts can shed more light on this question.

share|improve this question
    
Would you use merge sort or quicksort for the O(n*logn) sort? – committedandroider Feb 27 '15 at 18:15
    
For practical uses, Aaron Maenpaa's answer of counting on a sample is best. It's not like the most frequent words will hide from your sample. For you complexity geeks, it's O(1) since the size of the sample is fixed. You don't get the exact counts, but you're not asking for them either. – Nikana Reklawyks May 5 '15 at 22:00
    
If what you want is a review of your complexity analysis, then I'd better mention: if n is the number of words in your text and m is the number of different words (types, we call them), step 1 is O(n), but step 2 is O(m.lg(m)), and m << n (you may have billions words and not reach a million types, try it out). So even with a dummy algorithm, it's still O(n + m lg(m)) = O(n). – Nikana Reklawyks May 5 '15 at 22:40

15 Answers 15

This can be done in O(n) time

Solution 1:

Steps:

  1. Count words and hash it, which will end up in the structure like this

    var hash = {
      "I" : 13,
      "like" : 3,
      "meow" : 3,
      "geek" : 3,
      "burger" : 2,
      "cat" : 1,
      "foo" : 100,
      ...
      ...
    
  2. Traverse through the hash and find the most frequently used word (in this case "foo" 100), then create the array of that size

  3. Then we can traverse the hash again and use the number of occurrences of words as array index, if there is nothing in the index, create an array else append it in the array. Then we end up with an array like:

      0   1      2            3                100
    [[ ],[ ],[burger],[like, meow, geek],[]...[foo]]
    
  4. Then just traverse the array from the end, and collect the k words.

Solution 2:

Steps:

  1. Same as above
  2. Use min heap and keep the size of min heap to k, and for each word in the hash we compare the occurrences of words with the min, 1) if it's greater than the min value, remove the min (if the size of the min heap is equal to k) and insert the number in the min heap. 2) rest simple conditions.
  3. After traversing through the array, we just convert the min heap to array and return the array.
share|improve this answer
6  
Your solution (1) is an O(n) bucket sort replacing a standard O(n lg n) comparison sort. Your approach requires additional space for the bucket structure, but comparison sorts can be done in place. Your solution (2) runs in time O(n lg k) -- that is, O(n) to iterate over all words and O(lg k) to add each one into the heap. – stackoverflowuser2010 Sep 29 '14 at 4:29
1  
The first solution does require more space, but it is important to emphasize that it is in fact O(n) in time. 1: Hash frequencies keyed by word, O(n); 2: Traverse frequency hash, create second hash keyed by frequency. This is O(n) to traverse the hash and O(1) to add a word to the list of words at that frequency. 3: Traverse hash down from max frequency until you hit k. At most, O(n). Total = 3 * O(n) = O(n). – BringMyCakeBack Nov 5 '14 at 1:01
1  
Typically when counting words, your number of buckets in solution 1 is widely overestimated (because the number one most frequent word is so much more frequent than the second and third best), so your array is sparse and inefficient. – Nikana Reklawyks May 5 '15 at 22:03

You're not going to get generally better runtime than the solution you've described. You have to do at least O(n) work to evaluate all the words, and then O(k) extra work to find the top k terms.

If your problem set is really big, you can use a distributed solution such as map/reduce. Have n map workers count frequencies on 1/nth of the text each, and for each word, send it to one of m reducer workers calculated based on the hash of the word. The reducers then sum the counts. Merge sort over the reducers' outputs will give you the most popular words in order of popularity.

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A small variation on your solution yields an O(n) algorithm if we don't care about ranking the top K, and a O(n+k*lg(k)) solution if we do. I believe both of these bounds are optimal within a constant factor.

The optimization here comes again after we run through the list, inserting into the hash table. We can use the median of medians algorithm to select the Kth largest element in the list. This algorithm is provably O(n).

After selecting the Kth smallest element, we partition the list around that element just as in quicksort. This is obviously also O(n). Anything on the "left" side of the pivot is in our group of K elements, so we're done (we can simply throw away everything else as we go along).

So this strategy is:

  1. Go through each word and insert it into a hash table: O(n)
  2. Select the Kth smallest element: O(n)
  3. Partition around that element: O(n)

If you want to rank the K elements, simply sort them with any efficient comparison sort in O(k * lg(k)) time, yielding a total run time of O(n+k * lg(k)).

The O(n) time bound is optimal within a constant factor because we must examine each word at least once.

The O(n + k * lg(k)) time bound is also optimal because there is no comparison-based way to sort k elements in less than k * lg(k) time.

share|improve this answer
    
When we select the Kth smallest element, what gets selected is the Kth smallest hash-key. It is not necessary that there are exactly K words in the left partition of Step 3. – Prakash Murali May 20 '12 at 15:10
2  
You will not be able to run "medians of medians" on the hash table as it does swaps. You would have to copy the data from the hash table to an temp array. So, O(n) storage will be reqd. – user674669 Feb 20 '13 at 17:08
    
I don't understand how can you select the Kth smallest element in O(n) ? – Michael Ho Chum Mar 16 '15 at 16:18
    
Check this out for the algorithm for finding Kth smallest element in O(n) - wikiwand.com/en/Median_of_medians – Piyush Feb 2 at 14:19

If your "big word list" is big enough, you can simply sample and get estimates. Otherwise, I like hash aggregation.

Edit:

By sample I mean choose some subset of pages and calculate the most frequent word in those pages. Provided you select the pages in a reasonable way and select a statistically significant sample, your estimates of the most frequent words should be reasonable.

This approach is really only reasonable if you have so much data that processing it all is just kind of silly. If you only have a few megs, you should be able to tear through the data and calculate an exact answer without breaking a sweat rather than bothering to calculate an estimate.

share|improve this answer
    
Sometimes you have to do this many times over, for example if you're trying to get the list of frequent words per website, or per subject. In that case, "without breaking a sweat" doesn't really cut it. You still need to find a way to do it in as efficiently as possible. – itsadok Sep 16 '09 at 8:31
    
+1 for a practical answer that doesn't adress the irrelevant complexity issues. @itsadok: For each run: if it's big enough, sample it ; if it's not, then gaining a log factor is irrelevant. – Nikana Reklawyks May 5 '15 at 22:09

You can cut down the time further by partitioning using the first letter of words, then partitioning the largest multi-word set using the next character until you have k single-word sets. You would use a sortof 256-way tree with lists of partial/complete words at the leafs. You would need to be very careful to not cause string copies everywhere.

This algorithm is O(m), where m is the number of characters. It avoids that dependence on k, which is very nice for large k [by the way your posted running time is wrong, it should be O(n*lg(k)), and I'm not sure what that is in terms of m].

If you run both algorithms side by side you will get what I'm pretty sure is an asymptotically optimal O(min(m, n*lg(k))) algorithm, but mine should be faster on average because it doesn't involve hashing or sorting.

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7  
What you're describing is called a 'trie'. – Nick Johnson Oct 9 '08 at 7:53
    
Hi Strilanc. Can you explain the process of partition in details? – Morgan Cheng Oct 9 '08 at 11:39
1  
how does this not involve sorting?? once you have the trie, how do you pluck out the k words with the largest frequencies. doesnt make any sense – ordinary Nov 12 '13 at 7:38

You have a bug in your description: Counting takes O(n) time, but sorting takes O(m*lg(m)), where m is the number of unique words. This is usually much smaller than the total number of words, so probably should just optimize how the hash is built.

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Your problem is same as this- http://www.geeksforgeeks.org/find-the-k-most-frequent-words-from-a-file/

Use Trie and min heap to efficieinty solve it.

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If what you're after is the list of k most frequent words in your text for any practical k and for any natural langage, then the complexity of your algorithm is not relevant.

Just sample, say, a few million words from your text, process that with any algorithm in a matter of seconds, and the most frequent counts will be very accurate.

As a side note, the complexity of the dummy algorithm (1. count all 2. sort the counts 3. take the best) is O(n+m*log(m)), where m is the number of different words in your text. log(m) is much smaller than (n/m), so it remains O(n).

Practically, the long step is counting.

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Suppose we have a word sequence "ad" "ad" "boy" "big" "bad" "com" "come" "cold". And K=2. as you mentioned "partitioning using the first letter of words", we got ("ad", "ad") ("boy", "big", "bad") ("com" "come" "cold") "then partitioning the largest multi-word set using the next character until you have k single-word sets." it will partition ("boy", "big", "bad") ("com" "come" "cold"), the first partition ("ad", "ad") is missed, while "ad" is actually the most frequent word.

Perhaps I misunderstand your point. Can you please detail your process about partition?

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I believe this problem can be solved by an O(n) algorithm. We could make the sorting on the fly. In other words, the sorting in that case is a sub-problem of the traditional sorting problem since only one counter gets incremented by one every time we access the hash table. Initially, the list is sorted since all counters are zero. As we keep incrementing counters in the hash table, we bookkeep another array of hash values ordered by frequency as follows. Every time we increment a counter, we check its index in the ranked array and check if its count exceeds its predecessor in the list. If so, we swap these two elements. As such we obtain a solution that is at most O(n) where n is the number of words in the original text.

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This is generally a good direction - but it has a flaw. when the count is increased, we won't be just checking "its predecessor", but we'll need to check the "predecessors". for example, there is a big chance that the array will be [4,3,1,1,1,1,1,1,1,1,1] - the 1's can be as many - that will make it less efficient since we'll have to look back through all the predecessors to find the proper one to swap. – Shawn Oct 19 '13 at 0:02
    
Wouldn't this in fact be way worse than O(n)? More like O(n^2) as it is essentially a rather inefficient sort? – dcarr622 Oct 22 '13 at 11:53
    
Hi Shawn. Yes, I agree with you. But I suspect that the problem you mentioned is fundamental to the problem. In fact, if instead of keeping just a sorted array of values, we could go ahead an keep an array of (value, index) pairs, where the index points to the first occurrence of the repeated element, the problem should be solvable in O(n) time. For example, [4,3,1,1,1,1,1,1,1,1,1] will look like [(4,0), (3,1), (1,2), (1,2), (1,2, ..., (1,2)]; the indices start from 0. – Aly Farahat Dec 20 '13 at 19:11

I was struggling with this as well and get inspired by @aly. Instead of sorting afterwards, we can just maintain a presorted list of words (List<Set<String>>) and the word will be in the set at position X where X is the current count of the word. In generally, here's how it works:

  1. for each word, store it as part of map of it's occurrence: Map<String, Integer>.
  2. then, based on the count, remove it from the previous count set, and add it into the new count set.

The drawback of this is the list maybe big - can be optimized by using a TreeMap<Integer, Set<String>> - but this will add some overhead. Ultimately we can use a mix of HashMap or our own data structure.

The code

public class WordFrequencyCounter {
    private static final int WORD_SEPARATOR_MAX = 32; // UNICODE 0000-001F: control chars
    Map<String, MutableCounter> counters = new HashMap<String, MutableCounter>();
    List<Set<String>> reverseCounters = new ArrayList<Set<String>>();

    private static class MutableCounter {
        int i = 1;
    }

    public List<String> countMostFrequentWords(String text, int max) {
        int lastPosition = 0;
        int length = text.length();
        for (int i = 0; i < length; i++) {
            char c = text.charAt(i);
            if (c <= WORD_SEPARATOR_MAX) {
                if (i != lastPosition) {
                    String word = text.substring(lastPosition, i);
                    MutableCounter counter = counters.get(word);
                    if (counter == null) {
                        counter = new MutableCounter();
                        counters.put(word, counter);
                    } else {
                        Set<String> strings = reverseCounters.get(counter.i);
                        strings.remove(word);
                        counter.i ++;
                    }
                    addToReverseLookup(counter.i, word);
                }
                lastPosition = i + 1;
            }
        }

        List<String> ret = new ArrayList<String>();
        int count = 0;
        for (int i = reverseCounters.size() - 1; i >= 0; i--) {
            Set<String> strings = reverseCounters.get(i);
            for (String s : strings) {
                ret.add(s);
                System.out.print(s + ":" + i);
                count++;
                if (count == max) break;
            }
            if (count == max) break;
        }
        return ret;
    }

    private void addToReverseLookup(int count, String word) {
        while (count >= reverseCounters.size()) {
            reverseCounters.add(new HashSet<String>());
        }
        Set<String> strings = reverseCounters.get(count);
        strings.add(word);
    }

}
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I just find out the other solution for this problem. But I am not sure it is right. Solution:

  1. Use a Hash table to record all words' frequency T(n) = O(n)
  2. Choose first k elements of hash table, and restore them in one buffer (whose space = k). T(n) = O(k)
  3. Each time, firstly we need find the current min element of the buffer, and just compare the min element of the buffer with the (n - k) elements of hash table one by one. If the element of hash table is greater than this min element of buffer, then drop the current buffer's min, and add the element of the hash table. So each time we find the min one in the buffer need T(n) = O(k), and traverse the whole hash table need T(n) = O(n - k). So the whole time complexity for this process is T(n) = O((n-k) * k).
  4. After traverse the whole hash table, the result is in this buffer.
  5. The whole time complexity: T(n) = O(n) + O(k) + O(kn - k^2) = O(kn + n - k^2 + k). Since, k is really smaller than n in general. So for this solution, the time complexity is T(n) = O(kn). That is linear time, when k is really small. Is it right? I am really not sure.
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Try to think of special data structure to approach this kind of problems. In this case special kind of tree like trie to store strings in specific way, very efficient. Or second way to build your own solution like counting words. I guess this TB of data would be in English then we do have around 600,000 words in general so it'll be possible to store only those words and counting which strings would be repeated + this solution will need regex to eliminate some special characters. First solution will be faster, I'm pretty sure.

http://en.wikipedia.org/wiki/Trie

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This is an interesting idea to search and I could find this paper related to Top-K https://icmi.cs.ucsb.edu/research/tech_reports/reports/2005-23.pdf

Also there is an implementation of it here.

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Simplest code to get the occurrence of most frequently used word.

 function strOccurence(str){
    var arr = str.split(" ");
    var length = arr.length,temp = {},max; 
    while(length--){
    if(temp[arr[length]] == undefined && arr[length].trim().length > 0)
    {
        temp[arr[length]] = 1;
    }
    else if(arr[length].trim().length > 0)
    {
        temp[arr[length]] = temp[arr[length]] + 1;

    }
}
    console.log(temp);
    var max = [];
    for(i in temp)
    {
        max[temp[i]] = i;
    }
    console.log(max[max.length])
   //if you want second highest
   console.log(max[max.length - 2])
}
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