# Randomly permute N first elements of a singly linked list

I have to permute N first elements of a singly linked list of length n, randomly. Each element is defined as:

``````typedef struct E_s
{
struct E_s *next;
}E_t;
``````

I have a root element and I can traverse the whole linked list of size n. What is the most efficient technique to permute only N first elements (starting from root) randomly?

So, given a->b->c->d->e->f->...x->y->z I need to make smth. like f->a->e->c->b->...x->y->z

My specific case:

• n-N is about 20% relative to n
• I have limited RAM resources, the best algorithm should make it in place
• I have to do it in a loop, in many iterations, so the speed does matter
• The ideal randomness (uniform distribution) is not required, it's Ok if it's "almost" random
• Before making permutations, I traverse the N elements already (for other needs), so maybe I could use this for permutations as well

UPDATE: I found this paper. It states it presents an algorithm of O(log n) stack space and expected O(n log n) time.

-
std::random_shuffle requires a random access iterator. Iterators for singly-linked lists are not random access. You need to convert to an array first. – Peter Alexander Dec 12 '10 at 12:36
What do you mean by efficient? Is your problem time, space or both? You can traverse a singly linked list by using a fixed amount of memory and reversing pointers to point to the previous element when you move to the next one... – sprite Dec 12 '10 at 12:42
I haven't read the paper, but O(log n) space and O(n log n) time is going to be pretty tough to beat. – NPE Dec 12 '10 at 13:02
Would you link the DOI of the paper? The ScienceDirect link is broken. – Daniel Trebbien Dec 17 '10 at 21:15
@psihodelia: Just to be absolutely clear, you don't care about elements N+1...n at all, right? I'm wondering why you mention the "first N of n" -- do you actually mean you want to randomly select N from the total of n elements, move them to the start and permute that selection? – j_random_hacker Dec 21 '10 at 0:55

I've not tried it, but you could use a "randomized merge-sort".

To be more precise, you randomize the `merge`-routine. You do not merge the two sub-lists systematically, but you do it based on a coin toss (i.e. with probability 0.5 you select the first element of the first sublist, with probability 0.5 you select the first element of the right sublist).

This should run in `O(n log n)` and use `O(1)` space (if properly implemented).

Below you find a sample implementation in C you might adapt to your needs. Note that this implementation uses randomisation at two places: In `splitList` and in `merge`. However, you might choose just one of these two places. I'm not sure if the distribution is random (I'm almost sure it is not), but some test cases yielded decent results.

``````#include <stdio.h>
#include <stdlib.h>

#define N 40

typedef struct _node{
int value;
struct _node *next;
} node;

void splitList(node *x, node **leftList, node **rightList){
int lr=0; // left-right-list-indicator
*leftList = 0;
*rightList = 0;
while (x){
node *xx = x->next;
lr=rand()%2;
if (lr==0){
x->next = *leftList;
*leftList = x;
}
else {
x->next = *rightList;
*rightList = x;
}
x=xx;
lr=(lr+1)%2;
}
}

void merge(node *left, node *right, node **result){
*result = 0;
while (left || right){
if (!left){
node *xx = right;
while (right->next){
right = right->next;
}
right->next = *result;
*result = xx;
return;
}
if (!right){
node *xx = left;
while (left->next){
left = left->next;
}
left->next = *result;
*result = xx;
return;
}
if (rand()%2==0){
node *xx = right->next;
right->next = *result;
*result = right;
right = xx;
}
else {
node *xx = left->next;
left->next = *result;
*result = left;
left = xx;
}
}
}

void mergeRandomize(node **x){
if ((!*x) || !(*x)->next){
return;
}
node *left;
node *right;
splitList(*x, &left, &right);
mergeRandomize(&left);
mergeRandomize(&right);
merge(left, right, &*x);
}

int main(int argc, char *argv[]) {
srand(time(NULL));
int i;
node *x = (node*)malloc(sizeof(node));;
node *root=x;
x->value=0;
for(i=1; i<N; ++i){
node *xx;
xx = (node*)malloc(sizeof(node));
xx->value=i;
xx->next=0;
x->next = xx;
x = xx;
}
x=root;
do {
printf ("%d, ", x->value);
x=x->next;
} while (x);

x = root;
node *left, *right;
mergeRandomize(&x);
if (!x){
printf ("Error.\n");
return -1;
}
printf ("\nNow randomized:\n");
do {
printf ("%d, ", x->value);
x=x->next;
} while (x);
printf ("\n");
return 0;
}
``````
-
+1 for basically the right idea. I expand on this in my answer. Note though, that this uses at least `O(log n)` stack space for recursion. Also, this particular implementation is neither guaranteed to use a finite amount of time nor guaranteed to use a finite amount of space. – Chris Hopman Dec 19 '10 at 8:53
Correct for `O(log n)` stack space. Also correct that is not guaranteed to use a finite amount of time and space (although it is very likely), but you can assure this by removing the randomization from the `splitList` routine, right? – phimuemue Dec 19 '10 at 12:21

Convert to an array, use a Fisher-Yates shuffle, and convert back to a list.

-
It is not easy, because I have not too much additional RAM space (embedded platform). And the list is huge. I have to permute N elements, where n-N is small enough relative to n. – psihodelia Dec 12 '10 at 12:41
why do you have such a huge linked list (and singly linked at that)? – Mitch Wheat Dec 12 '10 at 13:59
well in case of a constrained environment, singly makes sense since you have one pointer less. Why using a list when node based containers are memory hogs remains a good question, of course. – Matthieu M. Dec 16 '10 at 18:07

I don't believe there's any efficient way to randomly shuffle singly-linked lists without an intermediate data structure. I'd just read the first N elements into an array, perform a Fisher-Yates shuffle, then reconstruct those first N elements into the singly-linked list.

-
Please read my UPDATE section. It seems there is an efficient algorithm. – psihodelia Dec 12 '10 at 13:00
Note that you don't actually have to put the elements themselves into an array, just the pointers to them. – caf Dec 12 '10 at 13:32
Well, this solution here is good, but for the space restriction. Bellow I have a solution with O(1) additional space, but I am skeptical regarding the runtime being near O(n log n). – sprite Dec 12 '10 at 15:02
@psihodelia: O(n log n) is less efficient than what I have presented. Fisher Yates is only O(n). It uses more memory though. – Peter Alexander Dec 14 '10 at 9:10
@Peter - Wouldn't it be O(N), not O(n)? All that matters is the number of elements being shuffled, not the number of elements in the list. – mbeckish Dec 16 '10 at 16:32

First, get the length of the list and the last element. You say you already do a traversal before randomization, that would be a good time.

Then, turn it into a circular list by linking the first element to the last element. Get four pointers into the list by dividing the size by four and iterating through it for a second pass. (These pointers could also be obtained from the previous pass by incrementing once, twice, and three times per four iterations in the previous traversal.)

For the randomization pass, traverse again and swap pointers 0 and 2 and pointers 1 and 3 with 50% probability. (Do either both swap operations or neither; just one swap will split the list in two.)

Here is some example code. It looks like it could be a little more random, but I suppose a few more passes could do the trick. Anyway, analyzing the algorithm is more difficult than writing it :vP . Apologies for the lack of indentation; I just punched it into ideone in the browser.

http://ideone.com/9I7mx

``````#include <iostream>
#include <cstdlib>
#include <ctime>
using namespace std;

struct list_node {
int v;
list_node *n;
list_node( int inv, list_node *inn )
: v( inv ), n( inn) {}
};

int main() {
srand( time(0) );

// initialize the list and 4 pointers at even intervals
list_node *n_first = new list_node( 0, 0 ), *n = n_first;
list_node *p[4];
p[0] = n_first;
for ( int i = 1; i < 20; ++ i ) {
n = new list_node( i, n );
if ( i % (20/4) == 0 ) p[ i / (20/4) ] = n;
}
// intervals must be coprime to list length!
p[2] = p[2]->n;
p[3] = p[3]->n;
// turn it into a circular list
n_first->n = n;

// swap the pointers around to reshape the circular list
// one swap cuts a circular list in two, or joins two circular lists
// so perform one cut and one join, effectively reordering elements.
for ( int i = 0; i < 20; ++ i ) {
list_node *p_old[4];
copy( p, p + 4, p_old );
p[0] = p[0]->n;
p[1] = p[1]->n;
p[2] = p[2]->n;
p[3] = p[3]->n;
if ( rand() % 2 ) {
swap( p_old[0]->n, p_old[2]->n );
swap( p_old[1]->n, p_old[3]->n );
}
}

// you might want to turn it back into a NULL-terminated list

// print results
for ( int i = 0; i < 20; ++ i ) {
cout << n->v << ", ";
n = n->n;
}
cout << '\n';
}
``````
-

For the case when N is really big (so it doesn't fit your memory), you can do the following (a sort of Knuth's 3.4.2P):

1. j = N
2. k = random between 1 and j
3. traverse the input list, find k-th item and output it; remove the said item from the sequence (or mark it somehow so that you won't consider it at the next traversal)
5. output the rest of the list

Beware that this is O(N^2), unless you can ensure random access in the step 3.

In case the N is relatively small, so that N items fit into the memory, just load them into array and shuffle, like @Mitch proposes.

-

If you know both N and n, I think you can do it simply. It's fully random, too. You only iterate through the whole list once, and through the randomized part each time you add a node. I think that's O(n+NlogN) or O(n+N^2). I'm not sure. It's based upon updating the conditional probability that a node is selected for the random portion given what happened to previous nodes.

1. Determine the probability that a certain node will be selected for the random portion given what happened to previous nodes (p=(N-size)/(n-position) where size is number of nodes previously chosen and position is number of nodes previously considered)
2. If node is not selected for random part, move to step 4. If node is selected for the random part, randomly choose place in random part based upon the size so far (place=(random between 0 and 1) * size, size is again number of previous nodes).
3. Place the node where it needs to go, update the pointers. Increment size. Change to looking at the node that previously pointed at what you were just looking at and moved.
4. Increment position, look at the next node.

I don't know C, but I can give you the pseudocode. In this, I refer to the permutation as the first elements that are randomized.

``````integer size=0;         //size of permutation
integer position=0      //number of nodes you've traversed so far
Node    current_node=head           //Starting at head, you'll move this down the list to check each node, whether you put it in the list.
Node    previous=head               //stores the previous node for changing pointers.  starts at head to avoid asking for the next field on a null node

While ((size not equal to N) or (current_node is not null)){            //iterating through the list until the permutation is full.  We should never pass the end of list, but just in case, I include that condition)

pperm=(N-size)/(n-position)          //probability that a selected node will be in the permutation.
if ([generate a random decimal between 0 and 1] < pperm)    //this decides whether or not the current node will go in the permutation

if (j is not equal to 0){   //in case we are at start of list, there's no need to change the list

pfirst=1/(size+1)       //probability that, if you select a node to be in the permutation, that it will be first.  Since the permutation has
//zero elements at start, adding an element will make it the initial node of a permutation and percent chance=1.
integer place_in_permutation = round down([generate a random decimal between 0 and 1]/pfirst)   //place in the permutation.  note that the head =0.
previous.next=current_node.next

if(place_in_permutation==0){            //if placing current node first, must change the head

}
else{
for (counter starts at zero. counter is less than place_in_permutation-1.  Each iteration, increment counter){

counter=counter.next
}   //at this time, temp should point to the node right before the insertion spot
current_node.next=temp.next
temp.next=current_node
}
current_node=previous
}
size++              //since we add one to the permutation, increase the size of the permutation
}
j++;
previous=current_node
current_node=current_node.next
``````

}

You could probably increase the efficiency if you held on to the most recently added node in case you had to add one to the right of it.

-

If both the following conditions are true:

• you have plenty of program memory (many embedded hardwares execute directly from flash);

Then you can choose a sufficiently large set of specific permutations, defined at programming time, write a code to write the code that implements each, and then iterate over them at runtime.

-

Indices in algorithm are 1 based.

1. Initialize lastR = -1
2. If N <= 1 go to step 6.
3. Randomize number r between 1 and N.
4. if r != N

4.1 Traverse the list to item r and its predecessor.

``````If lastR != -1
If r == lastR, your pointer for the of the r'th item predecessor is still there.
If r < lastR, traverse to it from the beginning of the list.
If r > lastR, traverse to it from the predecessor of the lastR'th item.
``````

4.2 remove the r'th item from the list into a result list as the tail.

4.3 lastR = r

5. Decrease N by one and go to step 2.
6. link the tail of the result list to the head of the remaining input list. You now have the original list with the first N items permutated.

Since you do not have random access, this will reduce the traversing time you will need within the list (I assume that by half, so asymptotically, you won't gain anything).

-
Running time of this is O(N^2). – Chris Hopman Dec 19 '10 at 8:08
I know... I didn't say it's linear. It is only slightly better statistically as it will run in about half time. Still O(N^2). – sprite Feb 9 '11 at 14:21

O(NlogN) easy to implement solution that does not require extra storage:

Say you want to randomize L:

1. is L has 1 or 0 elements you are done

2. create two empty lists L1 and L2

3. loop over L destructively moving its elements to L1 or L2 choosing between the two at random.

4. repeat the process for L1 and L2 (recurse!)

5. join L1 and L2 into L3

6. return L3

Update

At step 3, L should be divided into equal sized (+-1) lists L1 and L2 in order to guaranty best case complexity (N*log N). That can be done adjusting the probability of one element going into L1 or L2 dynamically:

``````p(insert element into L1) = (1/2 * len0(L) - len(L1)) / len(L)
``````

where

``````len(M) is the current number of elements in list M
len0(L) is the number of elements there was in L at the beginning of step 3
``````
-
This uses expected O(log(N)) worst-case O(N) stack space from the recursion. – Chris Hopman Dec 19 '10 at 8:03
In practice, worst-case O(N) memory usage (and O(N*N) complexity) will never happen with common pseudo-number generators. – salva Dec 19 '10 at 10:08
The point was more that the claim that it does not require extra storage is wrong. In fact it recurses at least log(n) times and so requires at least some constant factor of log(n) extra storage. – Chris Hopman Dec 19 '10 at 10:46
@Chris Hopman: oh, well, you are right but log(N) is so insignificant when talking about memory that I usually disregard it. Anyway, the algorithm can be converted to an iterative form with real O(1) memory usage. – salva Dec 19 '10 at 11:10
@Chris Hopman: see my other post in this same thread for the iterative version with complexity O(NlogN) and memory O(1). – salva Dec 20 '10 at 11:38

There is an algorithm takes `O(sqrt(N))` space and `O(N)` time, for a singly linked list.

It does not generate a uniform distribution over all permutation sequence, but it can gives good permutation that is not easily distinguishable. The basic idea is similar to permute a matrix by rows and columns as described below.

## Algorithm

Let the size of the elements to be `N`, and `m = floor(sqrt(N))`. Assuming a "square matrix" `N = m*m` will make this method much clear.

1. In the first pass, you should store the pointers of elements that is separated by every `m` elements as `p_0, p_1, p_2, ..., p_m`. That is, `p_0->next->...->next(m times) == p_1` should be true.

2. Permute each row

• For i = 0 to m do:
• Index all elements between `p_i->next` to `p_(i+1)->next` in the link list by an array of size `O(m)`
• Shuffle this array using standard method
• Relink the elements using this shuffled array
3. Permute each column.

• Initialize an array `A` to store pointers `p_0, ..., p_m`. It is used to traverse the columns
• For i = 0 to m do
• Index all elements pointed `A[0], A[1], ..., A[m-1]` in the link list by an array of size `m`
• Shuffle this array
• Relink the elements using this shuffled array
• Advance the pointer to next column `A[i] := A[i]->next`

Note that `p_0` is an element point to the first element and the `p_m` point to the last element. Also, if `N != m*m`, you may use `m+1` separation for some `p_i` instead. Now you get a "matrix" such that the `p_i` point to the start of each row.

## Analysis and randomness

1. Space complexity: This algorithm need `O(m)` space to store the start of row. `O(m)` space to store the array and `O(m)` space to store the extra pointer during column permutation. Hence, time complexity is ~ O(3*sqrt(N)). For `N = 1000000`, it is around 3000 entries and 12 kB memory.

2. Time complexity: It is obviously `O(N)`. It either walk through the "matrix" row by row or column by column

3. Randomness: The first thing to note is that each element can go to anywhere in the matrix by row and column permutation. It is very important that elements can go to anywhere in the linked list. Second, though it does not generate all permutation sequence, it does generate part of them. To find the number of permutation, we assume `N=m*m`, each row permutation has `m!` and there is m row, so we have `(m!)^m`. If column permutation is also include, it is exactly equal to `(m!)^(2*m)`, so it is almost impossible to get the same sequence.

It is highly recommended to repeat the second and third step by at least one more time to get an more random sequence. Because it can suppress almost all the row and column correlation to its original location. It is also important when your list is not "square". Depends on your need, you may want to use even more repetition. The more repetition you use, the more permutation it can be and the more random it is. I remember that it is possible to generate uniform distribution for `N=9` and I guess that it is possible to prove that as repetition tends to infinity, it is the same as the true uniform distribution.

Edit: The time and space complexity is tight bound and is almost the same in any situation. I think this space consumption can satisfy your need. If you have any doubt, you may try it in a small list and I think you will find it useful.

-

The list randomizer below has complexity O(N*log N) and O(1) memory usage.

It is based on the recursive algorithm described on my other post modified to be iterative instead of recursive in order to eliminate the O(logN) memory usage.

``````#include <stdlib.h>
#include <stdio.h>
#include <string.h>

typedef struct node {
struct node *next;
char *str;
} node;

unsigned int
next_power_of_two(unsigned int v) {
v--;
v |= v >> 1;
v |= v >> 2;
v |= v >> 4;
v |= v >> 8;
v |= v >> 16;
return v + 1;
}

void
dump_list(node *l) {
printf("list:");
for (; l; l = l->next) printf(" %s", l->str);
printf("\n");
}

node *
array_to_list(unsigned int len, char *str[]) {
unsigned int i;
node *list;
node **last = &list;
for (i = 0; i < len; i++) {
node *n = malloc(sizeof(node));
n->str = str[i];
*last = n;
last = &n->next;
}
*last = NULL;
return list;
}

node **
reorder_list(node **last, unsigned int po2, unsigned int len) {
node *l = *last;
node **last_a = last;
node *b = NULL;
node **last_b = &b;
unsigned int len_a = 0;
unsigned int i;
for (i = len; i; i--) {
double pa = (1.0 + RAND_MAX) * (po2 - len_a) / i;
unsigned int r = rand();
if (r < pa) {
*last_a = l;
last_a = &l->next;
len_a++;
}
else {
*last_b = l;
last_b = &l->next;
}
l = l->next;
}
*last_b = l;
*last_a = b;
return last_b;
}

unsigned int
min(unsigned int a, unsigned int b) {
return (a > b ? b : a);
}

randomize_list(node **l, unsigned int len) {
unsigned int po2 = next_power_of_two(len);
for (; po2 > 1; po2 >>= 1) {
unsigned int j;
node **last = l;
for (j = 0; j < len; j += po2)
last = reorder_list(last, po2 >> 1, min(po2, len - j));
}
}

int
main(int len, char *str[]) {
if (len > 1) {
node *l;
len--; str++; /* skip program name */
l = array_to_list(len, str);
randomize_list(&l, len);
dump_list(l);
}
return 0;
}

/* try as:   a.out list of words foo bar doz li 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14
*/
``````

Note that this version of the algorithm is completely cache unfriendly, the recursive version would probably perform much better!

-