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It seems Radix sort has a very good average case performance, i.e. O(kN): http://en.wikipedia.org/wiki/Radix_sort

but it seems most people still are using Quick Sort, don't they?

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Most people use a sort routine provided by their preferred framework without even caring about the algorithm. –  Doc Brown Nov 10 '10 at 17:05
Radix sort is not good with different kind of data, but when you want to sort unsigned int and you want are doing the sort on a multi-core processor like GPU, radix sort is faster. –  tintin Oct 12 at 2:51

8 Answers 8

up vote 3 down vote accepted

Quick sort has an average of O(N logN), but it also has a worst case of O(N^2), so even due in most practical cases it wont get to N^2, there is always the risk that the input will be in "bad order" for you. This risk doesn't exist in radix sort. I think this gives a great advantage to radix sort.

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It's unlikely to be the main advantage. Other comparison-based sorts (like heapsort or mergesort) do not have such a bad worst-case behavior as quicksort's. –  Eldritch Conundrum Dec 19 '13 at 19:13

Radix sort is harder to generalize than most other sorting algorithms. It requires fixed size keys, and some standard way of breaking the keys into pieces. Thus it never finds its way into libraries.

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Edited according to your comments:

  • Radix sort only applies to integers, fixed size strings, floating points and to "less than", "greater than" or "lexicographic order" comparison predicates, whereas comparison sorts can accommodate different orders.
  • k can be greater than log N.
  • Quick sort can be done in place, radix sort becomes less efficient.
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"Quick sort can be done in place" - so can binary radix sort, although that increases the likelihood that k is greater than log N. –  Steve Jessop Nov 10 '10 at 17:00
Your first point is not quite correct - Radix sort can easily be applied to fixed length strings. And the comparison predicate is required no matter which sort algorithm you use. –  Mark Ransom Nov 10 '10 at 17:10
"Radix sort only applies to integers": Why? I always thought if you sort by the exponent bits and the mantissa bits in the right order, you can use it to sort floating points number, too. And in theory, you could use it on strings, only k will almost always be greater than log N then. –  nikie Nov 10 '10 at 17:12
@j_random_hacker: Technically storing an index into an array of length N takes log(N) bits, so I don't think any sorting algorithm can be implemented without extra space ;-) –  nikie Nov 10 '10 at 20:37
@j_random_hacker: this is where practicality runs up against theory and both lose. If you're assuming a fixed upper limit on the size of the input array (so that an index can be held in O(1) space), then you break the theoretical model of a limit at infinity, so it's just a question of what you salvage. If you're saying that log(n) is "really" constant, you could just as well say that log^2(n) is "really" constant. In practice, I've written a quicksort (for production) that used, instead of the call stack, a fixed-size array on the stack to store the "todo list". 240 bytes or whatever. –  Steve Jessop Nov 11 '10 at 12:17

Unless you have a huge list or extremely small keys, log(N) is usually smaller than k, it is rarely much higher. So choosing a general-purpose sorting algorithm with O(N log N) average case performance isn't neccesarily worse than using radix sort.

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This is not true for all cases. k needn't be a bit count, it could be a byte count for example - if you're sorting 4-byte integers, N would need to be smaller than 16 for log N to be less than 4. –  Mark Ransom Nov 11 '10 at 3:40

when n > 128, we should use RadixSort

when sort int32s, I choose radix 256, so k = log(256, 2^32) = 4, which is significant smaller than log(2, n)

and in my test, radix sort is 7 times faster than quicksort in the best case.

public class RadixSort {
    private static final int radix=256, shifts[]={8,16,24}, mask=radix-1;
    private final int bar[]=new int[radix];
    private int s[] = new int[65536];//不使用额外的数组t,提高cpu的cache命中率

    public void ensureSort(int len){
        if(s.length < len)
            s = new int[len];

    public void sort(int[] a){
        int n=a.length;
        for(int i=0;i<radix;i++)bar[i]=0;
        for(int i=0;i<n;i++)bar[a[i]&mask]++;//bar存放了桶内元素数量
        for(int i=1;i<radix;i++)bar[i]+=bar[i-1];//bar存放了桶内的各个元素在排序结果中的最大下标+1
        for(int i=0;i<n;i++)s[--bar[a[i]&mask]]=a[i];//对桶内元素,在bar中找到下标x=bar[slot]-1, 另s[x]=a[i](同时--bar[slot]将下标前移,供桶内其它元素使用)

        for(int i=0;i<radix;i++)bar[i]=0;
        for(int i=0;i<n;i++)bar[(s[i]>>8)&mask]++;
        for(int i=1;i<radix;i++)bar[i]+=bar[i-1];
        for(int i=n-1;i>=0;i--)a[--bar[(s[i]>>8)&mask]]=s[i];//同一个桶内的元素,低位已排序,而放入t中时是从t的大下标向小下标放入的,所以应该逆序遍历s[i]来保证原有的顺序不变

        for(int i=0;i<radix;i++)bar[i]=0;
        for(int i=0;i<n;i++)bar[(a[i]>>16)&mask]++;
        for(int i=1;i<radix;i++)bar[i]+=bar[i-1];
        for(int i=n-1;i>=0;i--)s[--bar[(a[i]>>16)&mask]]=a[i];//同一个桶内的元素,低位已排序,而放入t中时是从t的大下标向小下标放入的,所以应该逆序遍历s[i]来保证原有的顺序不变

        for(int i=0;i<radix;i++)bar[i]=0;
        for(int i=0;i<n;i++)bar[(s[i]>>24)&mask]++;
        for(int i=129;i<radix;i++)bar[i]+=bar[i-1];//bar[128~255]是负数,比正数小
        bar[0] += bar[255];
        for(int i=1;i<128;i++)bar[i]+=bar[i-1];     
        for(int i=n-1;i>=0;i--)a[--bar[(s[i]>>24)&mask]]=s[i];//同一个桶内的元素,低位已排序,而放入t中时是从t的大下标向小下标放入的,所以应该逆序遍历s[i]来保证原有的顺序不变      
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Wouldnt radix-256 need 256 times memory of the size of original array? –  huseyin tugrul buyukisik Feb 16 at 14:55

Radix sort takes O(k*n) time. But you have to ask what is K. K is the "number of digits" (a bit simplistic but basically something like that).

So, how many digits do you have? Quite answer, more than log(n) (log using the "digit size" as base) which makes the Radix algorithm O(n log n).

Why is that? If you have less than log(n) digits, then you have less than n possible numbers. Hence you can simply use "count sort" which takes O(n) time (just count how many of each number you have). So I assume you have more than k>log(n) digits...

That's why people don't use Radix sort that much. Although there are cases where it's worthwhile using it, in most cases quick sort is much better.

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k = "length of the longest value in Array to be sorted"

n = "length of the array"

O(k*n) = "worst case running"

k * n = n^2 (if k = n)

so when using Radix sort make sure "the longest integer is shorter than the array size" or vice versa. Then you going to beat Quicksort!

The drawback is: Most of the time you cannot assure how big integers become, but if you have a fixed range of numbers radix sort should be the way to go.

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The other answers here are horrible, they don't give examples of when when radix sort is actually used.

An example is when creating a "suffix array" using the skew DC3 algorithm (Kärkkäinen-Sanders-Burkhardtz). The algorithm is only linear-time if the sorting algorithm is linear-time, and radix sort is necessary and useful here because the keys are short (3-tuples).

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