# Longest common prefix for n string

Given n string of max length m. How can we find the longest common prefix shared by at least two strings among them?

Example: ['flower', 'flow', 'hello', 'fleet']

I was thinking of building a Trie for all the string and then checking the deepest node (satisfies longest) that branches out to two/more substrings (satisfies commonality). This takes O(n*m) time and space. Is there a better way to do this

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@Mark I believe this example would be `flow`. Judging by the context of the proposed solution, it only has to be common to at least 2, not to all. I agree some clarification from OP is necessary here. –  corsiKa Dec 20 '11 at 16:12
a string may start without 'fl'. 'hello' was put to prove a point that it could be any strings where in 1 string need not have any common prefix with the others –  shreyasva Dec 20 '11 at 16:19

there is an `O(|S|*n)` solution to this problem, using a trie. [`n` is the number of strings, `S` is the longest string]

``````(1) put all strings in a trie
(2) do a DFS in the trie, until you find the first vertex with more then 1 "edge".
(3) the path from the root to the node you found at (2) is the longest commin prefix.
``````

There is no possible faster solution then it [in terms of big O notation], at the worst case, all your strings are identical - and you need to read all of them to know it.

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That is the method I was thinking as well and outlined in the problem. I agree with the lower bound of time as we have to read every string once. Space complexity is still O(n*m), can we do better? –  shreyasva Dec 20 '11 at 16:25
@shreyasva: refresh your page, I added a sentence explaining why this problem is `Omega(n*m)`, so no solution can do better then `O(n*m)` –  amit Dec 20 '11 at 16:26
I didn't understand the DFS solution. Can you give an example? –  Dejel May 4 '13 at 20:32
can't we just go from left to right checking if the character at position X is the same for all the strings, remove the string for which this is not met and iterate like this until we go to the end of the shortest string or we have only 1 string in our array of strings. We just need to remember the last longest prefix. Same time complexity but no need for a trie. –  Mateusz Dymczyk May 29 '13 at 12:24

I would sort them, which you can do in `n lg n` time. Then any strings with common prefixes will be right next to eachother. In fact you should be able to keep a pointer of which index you're currently looking at and work your way down for a pretty speedy computation.

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sorting would take nmlog(nm) because comparison in the worst case takes O(m) –  shreyasva Dec 20 '11 at 16:20
actually it makes it `O(m*nlog(n))` and not `O(nmlog(nm))`, because as you said: comparison takes `O(m)`, and there are `O(nlogn)` of those, resulting in total `O(mnlog(n))` –  amit Dec 20 '11 at 16:29
In the worst case, yes that's true. However that worst case only applies when the strings themselves are very, very similar, which means there would be much less swapping. I haven't done the math on it, and it is conceivable that a contrived case would cause it to degrade, but it still seems like the best option, especially considering space. –  corsiKa Dec 20 '11 at 17:43
Also, the notion of `m` is only important when `m` is significantly close to or greater than `n`. A typical `m` will be 12 or less for standard English words, and if we consider non-coined, non-technical words, we're looking at 33 (antidisestablishmentarianistically). So it has an impact if your `n` is, let's say, 100 or less, but if that's the case your entire operation is small and `O` doesn't apply. `O` notation is for asymptotic evaluation. –  corsiKa Feb 13 at 20:52

Why to use trie(which takes O(mn) time and O(mn) space, just use the basic brute force way. first loop, find the shortest string as minStr, which takes o(n) time, second loop, compare one by one with this minStr, and keep an variable which indicates the rightmost index of minStr, this loop takes O(mn) where m is the shortest length of all strings. The code is like below,

``````public String longestCommonPrefix(String[] strs) {
if(strs.length==0) return "";
String minStr=strs[0];

for(int i=1;i<strs.length;i++){
if(strs[i].length()<minStr.length())
minStr=strs[i];
}
int end=minStr.length();
for(int i=0;i<strs.length;i++){
int j;
for( j=0;j<end;j++){
if(minStr.charAt(j)!=strs[i].charAt(j))
break;
}
if(j<end)
end=j;
}
return minStr.substring(0,end);
}
``````
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You can, with one pass, bucket every string based on its first letter.

With another pass you can sort each bucket based on its second later. (This is known as radix sort, which is `O(n*m)`, and `O(n)` with each pass.) This gives you a baseline prefix of 2.

You can safely remove from your dataset any elements that do not have a prefix of 2.

You can continue the radix sort, removing elements without a shared prefix of `p`, as `p` approaches `m`.

This will give you the same `O(n*m)` time that the trie approach does, but will always be faster than the trie since the trie must look at every character in every string (as it enters the structure), while this approach is only guaranteed to look at 2 characters per string, at which point it culls much of the dataset.

The worst case is still that every string is identical, which is why it shares the same big O notation, but will be faster in all cases as is guaranteed to use less comparisons since on any "non-worst-case" there are characters that never need to be visited.

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