# Radix Sort base 256 Performance

I'm trying to implement Radix sort with base 256 using Lists. The sort works fine but it takes to long to sort big arrays, in addition the complexity should be linear, O(n), but i'm not getting that result as i'm timing the sort in the output. Here is my code:

Insert Function:

``````//insert to the back of the list element pointed to by x
void insert(Item * ls, Item * x)
{
x->prev = ls->prev;
ls->prev->next=x;
x->next=ls;
ls->prev=x;
}
``````

Delete Function:

``````//delete link in list whose address is x
void delete_x(Item * x)
{
x->prev->next = x->next;
x->next->prev = x->prev;
delete [] x;
}
``````

Radix_Sort Function:

``````void radix_sort_256(unsigned int *arr,unsigned int length)
//Radix sort implementation with base 256
{

int num_of_digits=0,count=0,radix_num=0;
unsigned int base=0,largest=0;

Item List [256];             //Creating 256 Nodes ( Base 256 )
for(int j=0; j<256;j++)      // Sentinel Init for each Node
{
List[j].key=0;
List[j].next=&List[j];
List[j].prev=&List[j];
}

for(unsigned int i=0; i<length ; i++)     //Finding the largest number in the array
{
if(arr[i]>largest)
largest = arr[i];
}

while(largest != 0 )        //Finding the total number of digits in the bigest number( "largest" ) of the array.
{
num_of_digits++;
largest = largest >> 8;
}
for(int i=0; i<num_of_digits; i++)
{
Item *node;
for(unsigned int j=0; j<length; j++)
{
node = new Item;                      //Creating a new node(Total 256 nodes) and inserting numbers from the array to each node
node->next = NULL;                    // with his own index.
node->prev = NULL;
node->key = arr[j];
radix_num = ( arr[j] >> (8*i) ) & 0xFF;
insert(&List[radix_num],node);
}

for(int m=0 ; m<256 ; m++)              //checking the list for keys // if key found inserting it to the array in the original order
{
while( List[m].next != &List[m] )
{
arr[count]=List[m].next->key;
delete_x(List[m].next);             //deleting the Item after the insertion
count++;
}
}
count=0;
}
}
``````

Main:

``````void main()
{
Random r;
int start,end;
srand((unsigned)time(NULL));

// Seting up dinamic array in growing sizes,
//  filling the arrayes with random
for(unsigned int i=10000 ; i <= 1280000; i*=2)
{
// numbers from [0 to 2147483646] calling the radix
//  sort function and timing the results
unsigned int *arr = new unsigned int [i];
for(int j=0 ; j<i ; j++)
{
arr[j] = r.Next()-1;
}
start = clock();
radix_sort_256(arr,i);
end = clock();
cout<<i;
cout<<"               "<<end-start;
if(Sort_check(arr,i))
cout<<"\t\tArray is sorted"<<endl;
else
cout<<"\t\tArray not sorted"<<endl;

delete [] arr;
}
}
``````

Can anyone see, maybe i'm doing some unnecessary actions that take great deal of time to execute?

-
Did you try to use profiler? – Denis Ermolin Nov 27 '12 at 7:35
Actually i haven't, i'll try that. – OlejkaKL Nov 27 '12 at 7:41
Looks linear to me: It's very slow, of course, but it's certainly linear. – tmyklebu Nov 27 '12 at 8:06
That is my point, you think it's alright that it is so slow? I'm sorting some large numbers after all.. – OlejkaKL Nov 27 '12 at 8:13
The non-standard `void main` prevents this code from compiling with e.g. g++. It is more to write than `int main`. Why did you choose that? – Cheers and hth. - Alf Nov 27 '12 at 8:14

## 1 Answer

Complexity is a difficult beast to master, because it is polymorphic.

When we speak about the complexity of an algorithm, we generally simplify it and express it according to what we think being the bottleneck operation.

For example, when evaluating sorting algorithms, the complexity is expressed as the number of comparisons; however, should your memory be a tape1 instead of RAM, the true bottleneck is the memory access and therefore a quicksort O(N log N) ends up being slower than a bubblesort O(N ** 2).

Here, your algorithm may be optimal, its implementation seems lacking: there is a lot of memory allocation/deallocation going on, for example. Therefore, it may well be that you did not identified the bottleneck operation correctly, and that all talk of linear complexity are moot since you are not measuring the right things.

1 because tapes take a time to move from one cell to another proportional to the distance between those cells, and thus a quicksort algorithms that keep jumping around memory ends up doing a lot of back and forth whilst a bubble sort algorithm just runs the length of the tape N times (max).

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