# faster string sorting with long common prefix?

I have a set of strings. 90% of them are URLs start with `"http://www."`. I want to sort them alphabetically.

Currently I use C++ std::sort(). but std::sort is a variant of quick-sort based on comparison, and comparing two strings with long common prefix is not effecient. However (I think) a radix-sort won't work either, since most strings are put in the same bucket because of long common prefix.

Is there any better algorithm than normal quick-sort/radix-sort for this problem?

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Would it be possible to remove the prefix before sorting? –  Kyle Strand Apr 26 '13 at 22:19
There might be some added efficiency with a radix tree. –  Hot Licks Apr 27 '13 at 3:32

Common Prefixes seem to naturally imply that a trie data structure could be useful. So the idea is to build a trie of all the words and then sort each node. The ordering should be that the children of a particular node reside in a list and are sorted. This can be done easily since at a particular node we need only sort the children, so naturally a recursive solution reveals itself. See this for more inspiration: http://goanna.cs.rmit.edu.au/~jz/fulltext/acsc03sz.pdf

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I wonder split a string into tree nodes would really help. tree nodes make much more non-continuous access. I don't mean to avoid the O(nlogn*LEN) worst case. I believe quick-sort still faster than a tree-based solution. –  richselian Apr 26 '13 at 23:00

I would suspect that the processing time you spend trying to exploit common prefixes on the order of 10 characters per URL doesn't even pay for itself when you consider the average length of URLs.

Just try a completely standard sort. If that's not fast enough, look at parallelizing or distributing a completely standard sort. It's a straightforward approach that will work.

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Processing a fixed number of prefixes is an O(N) process; sorting in O(N logN) requires O(N logN) comparisons. For sufficiently large N this is certainly a good idea, but the question is how large must N be to reach break-even –  Pieter Geerkens Apr 26 '13 at 23:41
"Processing prefixes is an O(N) process" - Is it? It depends on what processing you're doing. While you may be right that theoretically there could be a lower complexity doing something more clever, I was giving practical advice. For example: theoretically, Radix sort is O(N) (easily less than 100 valid URL characters), so why look elsewhere? –  Timothy Shields Apr 26 '13 at 23:49

Create two groups: the ones with the prefix and the ones without. For the first set remove the prefix, sort and add the prefix back. For the second set just sort. After that divide the second set into before prefix and after prefix. Now concatenate the three lists (list_2_before, list_1, list_2_after).

Instead of removing and adding prefix for the first list, you can write your own custom code that would start comparing after the prefix (i.e. ignore the prefix part while comparing).

Addendum: If you have multiple common prefixes you can use them further to speed up. It is better to create a shallow tree with very common prefixes and join them.

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This will help improve performance. but URLs can be devided into smaller groups like `http://www.google.com/xxxx` or `http://yahoo.com/xxxx`. can we improve it further? –  richselian Apr 26 '13 at 22:51
You can improve further as long as number of prefixes in manageable. For a more general case I recommend using a very shallow tree structure (eg. a pruned trie ) to keep track of various prefixes. –  ElKamina Apr 26 '13 at 23:35
You could replace the prefix with a single assigned character, but you'd have trouble maintaining the true sort order of the non-prefixed strings (which would presumably have a "no prefix" assigned character). Is it important to actually be sorted alphabetically? –  Hot Licks Apr 27 '13 at 3:35

If you figure out the minimum and maximum values in the vector before you start quicksorting, then you always know the range of values for each call to partition(), since the partition value is either the minimum or the maximum (or at least close to the minimum/maximum) of each subrange and the containing partition's minimum and maximum are the other end of each subrange.

If the minimum and the maximum of a subrange share a common prefix, then you can do all of the partition comparisons starting from the character position following the common prefix. As the quicksort progresses, the ranges get smaller and smaller so their common prefixes should get longer and longer, and ignoring them for the comparisons will save more and more time. How much, I don't know; you'd have to benchmark this to see if it actually helps.

In any event, the additional overhead is fairly small; one pass through the vector to find the minim and maximum string, costing 1.5 comparisons per string (*), and then one check for each partition to find the maximum shared prefix for the partition; the check is equivalent to a comparison, and it can start from the maximum shared prefix of the containing prefix, so it's not even a full string comparison.

• The min/max algorithm: Scan the vector two elements at a time. For each pair, first compare them with each other, then compare the smaller one with the running minimum and the larger one with the running maximum. Result: three comparisons for two elements, or 1.5 comparisons per element.
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This is a little hard to follow, but I believe it's the best answer. The kernel of the idea, to me, is that once you have partitioned the list more than once, you can find the common prefixes of the adjacent partition elements, and know that the elements in between share that prefix. –  Joel Nelson Apr 27 '13 at 4:02

At last I found a Ternary Quick Sort works well. I found the algorithm at www.larsson.dogma.net/qsufsort.c.

Here is my modified implementation, with similar interface to std::sort. It's about 40% faster than std::sort on my machine and dataset.

``````#include <iterator>

template<class RandIt> static inline void multiway_qsort(RandIt beg, RandIt end, size_t depth = 0, size_t step_len = 6) {
if(beg + 1 >= end) {
return;
}

struct { /* implement bounded comparing */
inline int operator() (
const typename std::iterator_traits<RandIt>::value_type& a,
const typename std::iterator_traits<RandIt>::value_type& b, size_t depth, size_t step_len) {

for(size_t i = 0; i < step_len; i++) {
if(a[depth + i] == b[depth + i] && a[depth + i] == 0) return 0;
if(a[depth + i] <  b[depth + i]) return +1;
if(a[depth + i] >  b[depth + i]) return -1;
}
return 0;
}
} bounded_cmp;

RandIt i = beg;
RandIt j = beg + std::distance(beg, end) / 2;
RandIt k = end - 1;

typename std::iterator_traits<RandIt>::value_type key = ( /* median of l,m,r */
bounded_cmp(*i, *j, depth, step_len) > 0 ?
(bounded_cmp(*i, *k, depth, step_len) > 0 ? (bounded_cmp(*j, *k, depth, step_len) > 0 ? *j : *k) : *i) :
(bounded_cmp(*i, *k, depth, step_len) < 0 ? (bounded_cmp(*j, *k, depth, step_len) < 0 ? *j : *k) : *i));

/* 3-way partition */
for(j = i; j <= k; ++j) {
switch(bounded_cmp(*j, key, depth, step_len)) {
case +1: std::iter_swap(i, j); ++i;      break;
case -1: std::iter_swap(k, j); --k; --j; break;
}
}
++k;

if(beg + 1 < i) multiway_qsort(beg, i, depth, step_len); /* recursively sort [x > pivot] subset */
if(end + 1 > k) multiway_qsort(k, end, depth, step_len); /* recursively sort [x < pivot] subset */

/* recursively sort [x == pivot] subset with higher depth */
if(i < k && (*i)[depth] != 0) {
multiway_qsort(i, k, depth + step_len, step_len);
}
return;
}
``````
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I like it! I hadn't heard about this before. How does it help with the prefix issue though? –  anil Apr 28 '13 at 6:13
@tigger in normal quick-sort, it takes O(nlogn * L) time, where L is the average common prefix length. in ternary quick-sort we take O(n) for partition and move to higher depth, moving takes O(L) times. so the worst performance is O(n * L). –  richselian Apr 28 '13 at 9:44
@richselian I think something is wrong with your big O analysis. The left and right partitions are sorted as in quicksort, since 'depth' has not increased. Elements in the middle partition can be considered as quicksort run on shorter strings, which we see can be compared more quickly in practice, but the compare time is considered constant anyway, unless we want to introduce a term for average string length. –  Joel Nelson Apr 29 '13 at 17:47
@JoelNelson, You can get a strict provement at larsson.dogma.net/ssrev-tr.pdf. This algorithm is part of Jesper Larsson's qsufsort. –  richselian Apr 30 '13 at 6:14
@richselian Thanks. The way I read it, it says it's O(n logn). O(n * L) is clearly better than O(n logn), so it would be quite something if O(n * L) was really the worst case. +1 for a highlighting a very cool algorithm. It may well be the fastest general-purpose sort in this scenario. 40% improvement doesn't point to an asymptotic improvement though. –  Joel Nelson Apr 30 '13 at 17:38
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