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Need an efficient algorithm solve this kind of complex structure

Problem Statement is :

Given 2 Dimensional array, print output for example

If 4 rows and 6 columns, output would be:

``````        1    2    3    4    5    6
16   17   18   19   20   7
15   24   23   22   21   8
14   13   12   11   10   9
``````

I tried it is looking like square within square but when I attempted this problem, I put so many while and if loops but didn't got exact answer. If row and columns increases how to handle it?

This is not homework. I was learning solving complex structure so I need to understand it by some guidance.

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In five minutes I could come up with at least ten different ways to do that. You should be able to think of at least one way in a half an hour. – Hot Licks Jun 21 '12 at 14:16
(It's a spiral.) – Hot Licks Jun 21 '12 at 14:17
A simple way : initialize an array and go from left to right, filling the cells on the way, until you find a "wall" or a filled cell, then turn and go on. – Denys Séguret Jun 21 '12 at 14:19
Those who put negative vote please take it back . Common guys i want to learn something from here what s the big deal . – Tintin Jun 21 '12 at 14:22
I gave you an idea. Why aren't you coding now ? – Denys Séguret Jun 21 '12 at 14:22

Here is what I came with.

Variables name may be upside/down, lot of thing to enhance, remove, modify but it was fun game.

``````public class Test {
public static void main(String[] args) {
int x = 2;
int y = 2;
int idx = 1;
int[][] array = new int[x][y];
int yUpIdx = y-1;
int yDownIdx = 0;
int xLeftIdx = 0;
int xRightIdx = x-1;

while (idx < x*y) {
for (int i = xLeftIdx; idx <= x*y && i <= xRightIdx; i++) {
array[i][yDownIdx] = idx++;
}
yDownIdx++;
for (int j = yDownIdx; idx <= x*y &&  j <= yUpIdx; j++) {
array[xRightIdx][j] = idx++;
}
xRightIdx--;
for (int i = xRightIdx; idx <= x*y &&  i>=xLeftIdx ; i--) {
array[i][yUpIdx] = idx++;
}
yUpIdx--;
for (int j = yUpIdx; idx <= x*y &&  j>=yDownIdx ; j--) {
array[xLeftIdx][j] = idx++;
}
xLeftIdx++;
}
for (int j = 0; j < y; j++) {
for (int i = 0 ; i < x; i++) {
if ((array[i][j]+"").length() < 2) System.out.print(" ");
System.out.print(array[i][j]+" ");
}
System.out.println("");
}
}
``````
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Nope I won't do anything more ;) A little work can't be bad. You got the drawing. Now take the picture. – Michael Laffargue Jun 21 '12 at 14:48
Really nice . I would work on it – Tintin Jun 21 '12 at 14:50
Thanks dude :) i would see this idea – Tintin Jun 21 '12 at 14:51

It's a square spiral.
You can read a bout it here: http://metacpan.org/pod/Math::PlanePath::SquareSpiral

There's an explanation for the formulas.

-
seriously ? you just need to substract i from N and you get the inverse. – Yochai Timmer Jun 21 '12 at 18:15

Another solution using the same "walk in a spiral" algo:

``````public class SpiralArray {
private int[][] cells;
private int rows;
private int cols;

private enum Direction {
LEFT,
DOWN,
RIGHT,
UP
}

public SpiralArray(int cols, int rows) {
this.cols = cols;
this.rows = rows;
cells = new int[cols][rows];
int count = 0;
Direction direction = Direction.RIGHT;
int x=0, y=0;
while (count++ < cols*rows) {
cells[x][y]=count;
switch (direction) {
case LEFT:
if ((--x<0) || (cells[x][y]>0)) {
y--;
x++;
direction = Direction.UP;
}
break;
case RIGHT:
if ((++x==cols) || (cells[x][y]>0)) {
y++;
x--;
direction = Direction.DOWN;
}
break;
case UP:
if ((--y<0) || (cells[x][y]>0)) {
x++;
y++;
direction = Direction.RIGHT;
}
break;
case DOWN:
if ((++y==rows) || (cells[x][y]>0)) {
x--;
y--;
direction = Direction.LEFT;
}
break;
}
}
}

int get(int i, int j) {
return cells[i][j];
}

@Override
public String toString() {
StringBuffer sb = new StringBuffer();
for (int y=0; y<rows; y++) {
for (int x=0; x<cols; x++) {
sb.append(cells[x][y]).append("\t");
}
sb.append("\n");
}
return sb.toString();
}

public static void main(String[] args) {
System.out.println(new SpiralArray(6, 4));
}

}
``````
-

I'd probably create an NxM integer array, initialized to zero. Set `nextNumber` to 1, `position` to 0,0, and `direction` to `left-to-right`. Check the `position` for being outside the array, and check the cell at `position` for zero. If `position` is OK and the cell is zero store `nextNumber` there and increment `nextNumber`. Then, based on `direction`, increment `position`.

If the cell at `position` is non-zero, or one of the indices of `position` is < 0 or >= the array size, you need to change direction. First back up `position` by 1, using the existing direction. Then pick a new `direction` that is 90 degrees from the current value, increment `position`, and try again.

When you can't go any direction you're done -- print the array.

(Probably a few boundary conditions I mishandled above, but that's one basic algorithm.)

(Hint: Write a subroutine to increment/decrement `position` based on `direction`.)

-

I hope this idea can get you started:

``````void solve2DArray(bool[][] 2DArray, int i, int j, int numMoves)
{
2DArray[i][j] = true;   // Mark current position as visited
// Perhaps a print statement here
if(right is not visited and can move right)
// move right
else if(down is not visited and can move down)
// move down
// ...
// ...
}
``````
-

I guess you can just create a worm that travels through your array:

``````public class Worm {
public static void main(String[] args) {
int[][] outArray = runWormRun(6, 4);
printArray(outArray);
}

private static void printArray(int[][] outArray) {
for (int j = 0; j < outArray[0].length; j++) {
for (int i = 0; i < outArray.length; i++) {
System.out.print(String.format("%02d ", outArray[i][j]));
}
System.out.println();
}
}

private static int[][] runWormRun(int w, int h) {
int[][] output = new int[w][h];

int counter = 0;
int wormX = 0, wormY = 0;
int minX = 0, maxX = w - 1, minY = 0, maxY = h - 1;
int dirX = 0, dirY = 1;
while (counter < w * h) {
output[wormX][wormY] = ++counter;
// let the worm walk
wormX += dirX;
wormY += dirY;
// update direction of worm for next iteration
if ((dirX != 0 && dirY != 1) && wormX == minX && wormY == minY) { // upper left border (and not yet rotated correctly
dirX = 0; dirY = 1; minY++;
}
if ((dirX != -1 && dirY != 0) && wormX == maxX && wormY == minY) { // upper right border
dirX = -1; dirY = 0; maxX--;
}
if ((dirX != 0 && dirY != -1) && wormX == maxX && wormY == maxY) { // lower right border
dirX = 0; dirY = -1; maxY--;
}
if ((dirX != 1 && dirY != 0) && wormX == minX && wormY == maxY) { // lower left border
dirX = 1; dirY = 0; minX++;
}
}
return output;
}
}
``````

And yes, my worm travels in the other direction, because I want you to think a bit too and understand, what I was doing. Because I think that this is homework. (If that's true, would you please consider adding the "homework" tag to your question?)

EDIT: Ooops, does not exactly, what it should do. No time now, will look into that in the evening.

-
OP states it is not homework in the question. – Chris Dargis Jun 21 '12 at 14:46
@VanDarg What else would that be... :D – brimborium Jun 21 '12 at 14:48

Another take:

``````public class Test {
enum Dir {
R(0,1), L(0,-1), D(1,0), U(-1,0);
public final int rowd, cold;
private Dir(int rowd, int cold) { this.rowd = rowd; this.cold = cold; }
public Dir next() { return values()[(ordinal()+1) % values().length]; }
}
static final int rows = 4, cols = 6;
static final int[][] grid = new int[rows][cols];
static int row, col = -1, step;

public static void main(String[] args) {
Dir dir = Dir.R;
moving: while (true) {
for (int i = 0; i < Dir.values().length; i++, dir = dir.next())
if (move(dir)) continue moving;
break;
}
for (int[] row : grid) System.out.println(Arrays.toString(row));
}
static boolean move(Dir dir) {
final int newRow = row+dir.rowd, newCol = col+dir.cold;
if (newRow >= 0 && newRow < rows && newCol >= 0 && newCol < cols
&& grid[newRow][newCol] == 0)
{
row = newRow; col = newCol; grid[row][col] = ++step; return true;
}
return false;
}
}
``````
-

Square Spiral

Here is a compact solution in a single function that performs optimally (it only visits each location in the array exactly once):

``````static int anMoveXDir[] = { 1, 0, -1,  0 };
static int anMoveYDir[] = { 0, 1,  0, -1 };

static void DoSpiral(int *panGrid, int nWidth, int nHeight)
{
int nSideSel, nSideIdx, nMoveDir, nXPosn, nYPosn, nCounter;
int anSideLen[2];

anSideLen[0] = nWidth;
anSideLen[1] = nHeight - 1;

nMoveDir = 0;     /* start off at (0, 0) in array, */
nXPosn   = 0;     /* facing east, and count from 1 */
nYPosn   = 0;
nCounter = 1;

for (nSideSel = 0; anSideLen[nSideSel & 1]; anSideLen[nSideSel++ & 1]--)
for (nSideIdx = anSideLen[nSideSel & 1]; nSideIdx; nSideIdx--)
{
panGrid[(nYPosn * nWidth) + nXPosn] = nCounter++;

if (nSideIdx == 1)
nMoveDir = (nMoveDir + 1) & 3;

nXPosn += anMoveXDir[nMoveDir];
nYPosn += anMoveYDir[nMoveDir];
}
}
``````

This algorithm works on the simple rule that given a rectangular or square array of width `x` and height `y`, then the walking the array to create a Square Spiral can be done using the following number of steps:

``````x + (y - 1) + (x - 1) + (y - 2) + (x - 2) + (y - 3) + (x - 3) + ... + 0
``````

The function above simply follows the above sequence. It starts at the top-left of the array facing east, walks `x` steps, turns right 90 degrees, walks `(y - 1)` steps, turns right 90 degress, walks `(x - 1)` steps, etc. etc. until either `x` or `y` is zero, whichever comes first.

You can test the function above by inserting it into the test program below:

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

#define GRID_WIDTH    7
#define GRID_HEIGHT  11

void main()
{
int nXPosn, nYPosn;
int anGrid[GRID_WIDTH * GRID_HEIGHT];
int *pnValue;

DoSpiral(anGrid, GRID_WIDTH, GRID_HEIGHT);

for (pnValue = anGrid, nYPosn = 0; nYPosn < GRID_HEIGHT; nYPosn++, printf("\n"))
for (nXPosn = 0; nXPosn < GRID_WIDTH; printf("%4i", *pnValue++), nXPosn++);
}
``````

The output will be as follows (for a 7x11 grid as indicated in the above program):

`````` 1   2   3   4   5   6   7
32  33  34  35  36  37   8
31  56  57  58  59  38   9
30  55  72  73  60  39  10
29  54  71  74  61  40  11
28  53  70  75  62  41  12
27  52  69  76  63  42  13
26  51  68  77  64  43  14
25  50  67  66  65  44  15
24  49  48  47  46  45  16
23  22  21  20  19  18  17
``````
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