# circular left shift of an array by n positions in java

I am trying to do the circular left shift of an array by n positions using only a single 1D array. I can do it in two arrays, but I haven't figured out how to do it using one. Please give your suggestions

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What have you tried? –  adarshr Aug 9 '12 at 22:44
this is what I have tried –  user1588850 Aug 9 '12 at 22:57
`Collections.rotate(Arrays.asList(array), distance)` –  Louis Wasserman Aug 9 '12 at 23:46

Another alternative would be to wrap up your own structure, which includes the array and the index of virtual zero.

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I do belive that `System.arraycopy` would actually just take all your data from one array, and put it into another one of the same length just shifted.

Anyways thinking about that problem is a quite interesting task. The only Solution i could think about right now is to shit it one by one. Without using another Array it would look like that:

``````for(int i = 0; i < shift;i++)
{
tmp = array[0];
for(int j = 0;j<array.length-1;j++)
array[j]=array[j+1];
array[array.length-1]=tmp;
}
``````

for Arrays greater than 30 items it is but more efficient to use this:

``````for (int i = 0; i < shift; i++) {
tmp = array[0];
System.arraycopy( array, 1, array, 0, array.length - 1 );
array[array.length - 1] = tmp;
}
``````

But for large arrays and great shift that are close to the array size aswell as for short arrays and small shifts this method wins the race:

``````    int[] array2 = new int[shift];
for (int i = 0; i < shift; i++)
{
array2[i] = array[i];
}
System.arraycopy(array, shift, array, 0, array.length - shift);
for (int i = array.length - shift; i < array.length; i++)
{
array[i] = array2[shift + i - array.length];
}
``````

Ive tested that with a few array sizes and shifts Here are the results for

``````    int[] array = new int[100000];
int shift = 99999;
``````

in nanoseconds: 1st method:5663109208 2nd method:4047735536 3rd method:6085690 So you should really use the 3rd method. Hope that helps

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There is actually a clever algorithm for that. We'll use `A` to denote the array, `N` to denote the array size, and `n` to denote the number of positions to shift. After the shift you would like the `i-th` element to move to the `((i + n) mode N)-th` position, the `((i + n) mode N)-th` element to move to the `((i + 2n) mode N)-th` position, and so on.. Hence, we can define the new positions by the following mapping: `f(j) := (j + n) mod N`.

Let us denote`d := gcd(N, n)`. Using number theory it is possible to show that for every one of the integers: `i = 0,...,d - 1`, the function `f` will map `S(i) := { kd + i | k = 0,...,N/d - 1}` bijectively onto itself during the rotation.

Moreover, the values `i, (i + n) mod N, ..., (i + n(N/d - 1)) mod N` cover all of `S(i)`. Note that another way to write these values is: `i, f(i), f(f(i)), ..., f(f(...f(i)...))`.

What this means is that we can rotate all elements in positions `0, d, 2d, ..., (N/d - 1)d` by simply replacing the element at position `n mod N` with the element at position `0`, the element at position `2n mod N` with the element at position `n mod N`, and so on.. until we return to the element in position `0` (which we are assured will happen). Here is a pseudo-code example:

``````temp <- A[0]
j <- N - (n mod N)
while j != 0 do
A[(j + n) mod N] <- A[j];
j <- (j - n) mod N
A[n mod N] <- temp;
``````

This covers the entire set `S(0)`. To cover the rest of the sets, Namely `S(1), ... ,S(d-1)`, we will simply iterate over each set the same way we did for the first:

``````for i <- 0 to d - 1
temp <- A[i]
j <- N - ((n - i) mod N)
while j != i do
A[(j + n) mod N] <- A[j];
j <- (j - n) mod N
A[(i + n) mod N] <- temp;
``````

Note that while we have two nested loops, each element is moved exactly once, and we use `O(1)` space. An exmaple of an implementation in Java:

``````public static int gcd(int a, int b) {
while(b != 0) {
int c = a;
a = b;
b = c % a;
}
return a;
}

public static void shift_array(int[] A, int n) {
int N = A.length;
n %= N;
if(n < 0)
n = N + n;
int d = gcd(N, n);
for(int i = 0; i < d; i++) {
int temp = A[i];
for(int j = i - n + N; j != i; j = (j - n + N) % N)
A[(j + n) % N] = A[j];
A[i + n] = temp;
}
}
``````
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You could shift the data by iterating and copying, this will be O(n). An alternate approach is to create a `List` implementation that wraps your array and exposes it as being circular shifted. This had the advantage that the actual shifting is lazily done when `get` or iteration is performed.

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I would shift it 1 element at a time in place, using a single temporary variable to hold the element while moving elements 1 place along each. I would then repeat this `n` times to achieve `n` shifts.

``````public static void main( String[] args ) {
int[] array = {1,2,3,4,5,6,7,8};
leftShift( array, 3);
System.out.println( Arrays.toString( array));
}

public static void leftShift(int[] array, int n) {
for (int shift = 0; shift < n; shift++) {
int first = array[0];
System.arraycopy( array, 1, array, 0, array.length - 1 );
array[array.length - 1] = first;
}
}
``````

Output:

``````[4, 5, 6, 7, 8, 1, 2, 3]
``````

Not too inefficient, as `System.arraycopy()` is highly optimized.

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``````for (int i = 0; i < n; i++)