# Given a file, find the ten most frequently occuring words as efficiently as possible

This is apparently an interview question (found it in a collection of interview questions), but even if it's not it's pretty cool.

We are told to do this efficiently on all complexity measures. I thought of creating a HashMap that maps the words to their frequency. That would be O(n) in time and space complexity, but since there may be lots of words we cannot assume that we can store everything in memory.

I must add that nothing in the question says that the words cannot be stored in memory, but what if that were the case? If that's not the case, then the question does not seem as challenging.

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Something Irrelevant : where did you find the collection of Interview Questions? –  GeorgeAl Dec 21 '10 at 0:20
It's a book that a friend of mine lent me. The following website claims to have collection of Google interview questions though. blog.seattleinterviewcoach.com/2009/02/… –  efficiencyIsBliss Dec 21 '10 at 0:21
Storing them in a hash map is O(n) but that doesn't give you the top 10 without, say, a subsequent O(n log n) sort. –  John Kugelman Dec 21 '10 at 0:22
@Victor We can just keep track of the top ten frequencies, doing only a linear pass. –  efficiencyIsBliss Dec 21 '10 at 0:29
"on all complexity measures"? there's an O(1) space (if "10" is a constant), O(n^2) time algorithm, and an O(n) space and O(n) time algorithm, so which is better on all complexity measures? –  lijie Dec 21 '10 at 0:33

Optimizing for my own time:

``````sort file | uniq -c | sort -nr | head -10
``````

Possibly followed by `awk '{print \$2}'` to eliminate the counts.

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What does this mean? Can anyone explain please? –  P5Coder Jun 2 '14 at 17:19
`sort` groups like words together. `uniq -c` counts each group and prints one line with the count and the group. `sort -nr` sorts `n`umerically (now by count) `r`eversed so the highest count is first. `head -10` prints the top 10. The optional `awk` chops off the counts. –  Ben Jackson Jun 2 '14 at 20:39

I think the trie data structure is a choice.

In the trie, you can record word count in each node representing frequency of word consisting of characters on the path from root to current node.

The time complexity to setup the trie is O(Ln) ~ O(n) (where L is number of characters in the longest word, which we can treat as a constant). To find the top 10 words, we can traversal the trie, which also costs O(n). So it takes O(n) to solve this problem.

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Actually, traversing the trie costs at worst ~O(Lt), where t is the token count which can be no greater than N, and L is as above. It just seems to me that there ought to be a fundamentally faster way to go about this. –  Jake Kurzer Dec 22 '10 at 0:50
@JakeKurzer it is not about to be the fastest in these interviews, but to show the interviewer that you're able to discuss alternatives and trade-offs. –  Thomas Jungblut Jun 13 '13 at 12:45
"Rule of Economy: Programmer time is expensive; conserve it in preference to machine time." - Rob Pike –  darelf Jan 23 '14 at 13:59

Let's say we assign a random prime number to each of the 26 alphabets. Then we scan the file. Whenever we find a word, we calculate its hash value(formula based on the positon & the value of the alphabets making the word). If we find this value in the hash table, then we know for sure that we are not encountering it for the first time and we increment its key value. And maintain a array of maximum 10. But If we encounter a new hash , then we store the file pointer for that hash value, and initialize the key to 0.

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You should add an example –  keyser Oct 11 '12 at 10:55

I have done in C# like this(a sample)

``````int wordFrequency = 10;
string words = "hello how r u u u u  u  u u  u  u u u  u u u u  u u u ? hello there u u u u ! great to c u there. hello .hello hello hello hello hello .hello hello hello hello hello hello ";

var result = (from word in words.Split(new string[] { " " }, StringSplitOptions.RemoveEmptyEntries)
group word by word into g
select new { Word = g.Key, Occurance = g.Count() }).ToList().FindAll(i => i.Occurance >= wordFrequency);
``````
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An complete solution would be something like this:

1. Do an external sort O(N log N)
2. Count the word freq in the file O(N)
3. (An alternate would be the use of a Trie as @Summer_More_More_Tea to count the frequencies, if you can afford that amount of memory) O(k*N) //for the two first steps
4. Use a min-heap:
• Put the first n elements on the heap
• For every word left add it to the heap and delete the new min in heap
• In the end the heap Will contain the n-th most common words O(|words|*log(n))

With the Trie the cost would be O(k*N), because the number of total words generally is bigger than the size of the vocabulary. Finally, since k is smaller for most of the western languages you could assume a linear complexity.

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You could make a time/space tradeoff and go `O(n^2)` for time and `O(1)` for (memory) space by counting how many times a word occurs each time you encounter it in a linear pass of the data. If the count is above the top 10 found so far, then keep the word and the count, otherwise ignore it.

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You'll have to keep every word, otherwise every time you see a word not in the top 10 you'll think it's the first time you saw it. –  Kirk Broadhurst Dec 21 '10 at 0:50
But thinking that is OK, because it's still `O(n^2)`. The only time it's an issue is when it is a word in the top 10 (because you might keep the same word 10 times), but we do keep those words, so it's not a big issue. Thinking it's the first time every time does not mean we "have to keep every word". As I said above, you count "each time you encounter it." Not as time efficient of course, but OP wants space efficiency. –  user470379 Dec 21 '10 at 0:57
Consider a file in which the second half of the file in the same word, repeated. If you process the file linearly, once you get to the sceond half you will already have your 'top 10' words that you've kept. You'll see this word, and count '1'. Not in the top 10, don't keep it; move to the next word. See it again - I haven't 'kept' it, so I haven't counted it, so count '1'. Not in the top 10, don't keep it; move to the next word. Repeat. Can you explain what I'm missing? –  Kirk Broadhurst Dec 21 '10 at 1:11
@Kirk The algorithm you describe is only `O(n)` time-wise (or maybe `O(n log n)`?). I'm suggesting an `O(n^2)` algorithm where you "count how many times a word occurs each time you encounter it" -- in other words, for each word in text, compare each word in text and count the number of times the two are the same. As far as code goes, it would look like `for(i=0; i < num_words; ++i) { for (j=0; j < num_words; ++j) { if (words[i] == words[j]) ++count; }` plus some code at the end to process whether the count is in the top 10 or not and if the word has already been included in the top 10. –  user470379 Dec 21 '10 at 1:18
Aha! Understood. –  Kirk Broadhurst Dec 21 '10 at 1:27

Says building a Hash and sorting the values is best. I'm inclined to agree. http://www.allinterview.com/showanswers/56657.html

Here is a Bash implementation that does something similar...I think http://www.commandlinefu.com/commands/view/5994/computes-the-most-frequent-used-words-of-a-text-file

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Depending on the size of the input data, it may or may not be a good idea to keep a HashMap. Say for instance, our hash-map is too big to fit into main memory. This can cause a very high number of memory transfers as most hash-map implementations need random access and would not be very good on the cache.

In such cases sorting the input data would be a better solution.

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I think this is a typical application of counting sort since the sum of occurrences of each word is equal to the total number of words. A hash table with a counting sort should do the job in a time proportional to the number of words.

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Cycle through the string of words and store each in a dictionary(using python) and number of times they occur as the value.

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A Python dictionary is a HashMap, so that's pretty much what I proposed. –  efficiencyIsBliss Dec 21 '10 at 0:35

If the word list will not fit in memory, you can split the file until it will. Generate a histogram of each part (either sequentially or in parallel), and merge the results (the details of which may be a bit fiddly if you want guaranteed correctness for all inputs, but should not compromise the O(n) effort, or the O(n/k) time for k tasks).

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A Radix tree or one of it's variations will generally allow you to save storage space by collapsing common sequences.
Building it will take O(nk) - where k is "the maximum length of all strings in the set".

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step 1 : If the file is very large and can't be sorted in memory you can split it into chunks that can be sorted in memory.

step 2 : For each sorted chunk compute sorted pairs of (words, nr_occurrence), at his point you can renounce to the chunks because you need only the sorted pairs.

step 3 : Iterate over the chunks and sort the chunks and always keep the top ten appearances.

Example:

Step 1:

a b a ab abb a a b b c c ab ab

split into :

chunk 1: a b a ab
chunk 2: abb a a b b
chunk 3: c c ab ab

Step 2:

chunk 1: a2, b1, ab1 chunk 2: a2, b2, abb1
chunk 3: c2, ab2

Step 3(merge the chunks and keep the top ten appearances):

a4 b3 ab3 c2 abb1

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``````    int k = 0;
int n = i;
int j;
string[] stringList = h.Split(" ".ToCharArray(),
StringSplitOptions.RemoveEmptyEntries);
int m = stringList.Count();
for (j = 0; j < m; j++)
{
int c = 0;
for (k = 0; k < m; k++)
{
if (string.Compare(stringList[j], stringList[k]) == 0)
{
c = c + 1;
}
}
}
``````
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Not sure your code solves desired problem - case where words aren't stored in memory –  Petro Korienev Jul 20 '14 at 11:19