# Finding all adjacent elements in a 2D array in C

I am working on a project where at one point I am stuck.

My question is for example I have the following 2D array containing 3 different integers.

``````2 2 2 2 1
1 2 2 2 1
3 3 2 3 2
3 1 3 3 1
1 1 2 3 1
1 3 1 3 3
``````

What i want is to find the longest adjacent elements chain of array of any number contained in the array.

Like in the above array the longest chain is of digit 2.

``````2 2 2 2
2 2 2
2
``````

Can anyone just guide me as to what I have to do to achieve this goal ?

Thanks.

-
What have you tried, and how doesn't it work? Also, is the array bounded, toroidal, or spherical? –  Ignacio Vazquez-Abrams Dec 9 '10 at 10:56
Are you writing a minesweeper? :) –  Goran Jovic Dec 9 '10 at 10:57
Do you want the number of the longest chain of adjacent elements (e.g. 8, in your example)? Or do you want their positions in the 2D array? –  Frerich Raabe Dec 9 '10 at 11:39
@Goran I think it is probably something more like Bejeweled :) –  Karl Knechtel Dec 13 '10 at 18:01
Thanks Everybody.. Basically I am Writing the Code for the cpu Player of a puzzle game called bubble breaker and what i want is to delete step by step all the bubbles untill there is no adjacent bubbles. –  devoidfeast Dec 25 '10 at 10:33

Easier to draw than to explain...

``````2 2 2 2 1 => A A A A B => (A: 4, B: 1)
1 2 2 2 1 => C A A A B => (A: 3 + 4, B: 1 + 1, C: 1)
3 3 2 3 2 => D D A E F => (A: 1 + 7, B: 2, C: 1, D: 2, E: 1, F: 1)
3 1 3 3 1 => D G E E G => (A: 8, B: 2, C: 1, D: 2 + 1, E: 2 + 1, F: 1, G: 1)
1 1 2 3 1 => ...
1 3 1 3 3 => ...
``````

update:

And now, with some real code:

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

#define ROWS 6
#define COLS 5

unsigned char eles[ROWS][COLS] = { { 2, 2, 2, 2, 1 },
{ 1, 2, 2, 2, 1 },
{ 3, 3, 2, 3, 2 },
{ 3, 1, 3, 3, 1 },
{ 1, 1, 2, 3, 1 },
{ 1, 3, 1, 3, 3 } };

struct zone {
int acu;
int row, col;
int refs;
};

typedef struct zone zone;

zone *
new_zone(int row, int col) {
zone *z = (zone *)malloc(sizeof(zone));
z->col = col;
z->row = row;
z->refs = 1;
z->acu = 0;
}

void croak (const char *str) {
fprintf(stderr, "error: %s\n", str);
exit(1);
}

void
free_zone(zone *z) {
if (z->refs != 0) croak("free_zone: reference count is not cero");
free(z);
}

zone *
ref_zone(zone *z) {
z->refs++;
return z;
}

void
unref_zone(zone *z) {
z->refs--;
if (!z->refs) free_zone(z);
}

int
main() {
zone *last[COLS];
zone *current[COLS];
zone *best = new_zone(0, 0);
int i, j;
memset(last, 0, sizeof(last));

for (j = 0; j < ROWS; j++) {
for (i = 0; i < COLS; i++) {
unsigned int ele = eles[j][i];
zone *z;
/* printf("analyzing ele: %d at row %d, col: %d\n", ele, j, i); */
if (i && (ele == eles[j][i-1])) {
/* printf("  equal to left element\n"); */
z = ref_zone(current[i-1]);
if (j && (ele == eles[j-1][i])) {
zone *z1 = last[i];
/* printf("  equal to upper element\n"); */
if (z != z1) {
int k;
/* printf("  collapsing zone %p\n", z1); */
z->acu += z1->acu;
for (k = 0; k < COLS; k++) {
if (last[k] == z1) {
last[k] = ref_zone(z);
unref_zone(z1);
}
}
for (k = 0; k < i; k++) {
if (current[k] == z1) {
current[k] = ref_zone(z);
unref_zone(z1);
}
}
}
}
}
else if (j && (ele == eles[j-1][i])) {
/* printf("  equal to upper element\n"); */
z = ref_zone(last[i]);
}
else {
/* printf("  new element\n"); */
z = new_zone(j, i);
}
z->acu++;
current[i] = z;
/* printf("  element zone: %p\n", z); */
}
for (i = 0; i < COLS; i++) {
if (j) unref_zone(last[i]);
last[i] = current[i];
if (best->acu < current[i]->acu) {
unref_zone(best);
best = ref_zone(current[i]);
/* printf("best zone changed to %p at row; %d, col: %d, acu: %d\n", best, best->row, best->col, best->acu); */
}
}
}
printf("best zone is at row: %d, col: %d, ele: %d, size: %d\n", best->row, best->col, eles[best->row][best->col], best->acu);
}
``````
-
How does this help? Note that you still have to determine whether two `2` are adjacent or not. In the third row, you assign the letter `A` for the first `2` and the letter `F` for the second `2` in the same row. –  Frerich Raabe Dec 9 '10 at 11:21
Thanks Salva... –  devoidfeast Dec 10 '10 at 13:13

Suppose your matrix is a graph, and the elements are vertices. Two vertices are connected if they are adjacent and have the same value. If you perform any search in that graph, be it Breadth-First Search or Depth-First Search, you'll get exactly what you want. HTH

-
1. define another 2d array of the same size, initialize all cells to 0
2. set maxval to 0
3. if helper array is full of 1's go to 5, otherwise find a cell with 0 and do:
3.1 change value of the cell to 1
3.2 set a counter to 1
3.3 check all adjacent cells, if they're 0 in the helper array and the same value as current cell in the input array then counter++ and go to 2.1 with new coordinates.
4. maxval = max(maxval,counter), go to 3
5. return maxval

steps 3.1-3.3 should be implemented as a recursive function which takes coordinate and both arrays as arguments and returns 1+the sum of the returned values from the recursive calls.

-

You could treat this like a picture in a paint application. Perform a flood-fill on each element in your 2D array (unless its filled already by something else) and keep track how many pixels you filled in each step.

If your array is declared like

``````int elements[5][5];
``````

Then introduce a second array which tells whether you filled an element already (if you like, use a different type like `bool` if thats's okay in your C program):

``````int pixelFilled[5][5];
memset( pixelFilled, 0, sizeof( pixelFilled ) );
``````

Next, write a recursive function which performs a flood fill and returns the numbers of elements which were filled (I'm writing this from the top of my head, no guarantee whatsoever that this function works as it is):

``````int floodFill( int x, int y ) {
int filledPixels = 0;
if ( !pixelFilled[x][y] ) {
++filledPixels;
pixelFilled[x][y] = 1;
}
if ( x < 4 && elements[x+1][y] == elements[x][y])
filledPixels += floodFill( x + 1, y );
if ( x > 0 && elements[x-1][y] == elements[x][y] )
filledPixels += floodFill( x - 1, y );
if ( y < 4  && elements[x][y+1] == elements[x][y])
filledPixels += floodFill( x, y + 1 );
if ( y > 0  && elements[x][y-1] == elements[x][y])
filledPixels += floodFill( x, y - 1 );
return filledPixels;
}
``````

Finally, iterate over your array and try to fill it completely. Keep track of the largest filled array:

``````int thisArea = 0;
int largestArea = 0;
int x, y;
for ( y = 0; y < 5; ++y ) {
for ( x = 0; x < 5; ++x ) {
thisArea = floodFill( x, y );
if (thisArea > largestArea ) {
largestArea = thisArea;
}
}
}
``````

Now, `largestArea` should contain the size of the longest chain of adjacent elements.

-
Hmmmmm... It seems you are going to flood fill also starting from "pixel" that have already been flood filled starting from a contiguous "pixel" of same value. Extremely inefficient. BTW, for this kind of problems I usually remove the boundary checks (e.g. `x < 4`) by copying the input array in a bigger array with a frame of zeros, that will make the general condition `elements[x+1][y] == elements[x][y]` fail at the edge of the "image". –  Antonio Dec 11 '13 at 23:22
You probably just miss an `else return 0` at the beginning of the `floodFill` function. In fact without that you enter an infinite recursion :-) –  Antonio Dec 11 '13 at 23:28

I love this kind of problems :-) so here it is my answer. As said by Frerich Raabe, this can be solved with a floodFill function. For example, `opencv` library would provide such a function off the shelf.

Please forgive me if in the following code you'll find traces of C++, in case they should be simple to be replaced.

``````typedef struct Point {
int x;
int y;
} Point;

int areaOfBiggestContiguousRegion(int* mat,int nRows, int nCols) {
int maxArea = 0;
int currValue, queueSize, queueIndex;
int* aux;
Point queue[1000]; //Stores the points I need to label
Point newPoint, currentPoint;
int x,y,x2,y2;
//Code: allocate support array aux of same size of mat
//Code: fill aux of zeros

for (y = 0; y < nRows; y++)
for (x = 0; x < nCols; x++)
if (aux[y * nCols + x] == 0) {//I find a pixel not yet labeled, my seed for the next flood fill
queueIndex = 0; //Contains the index to the next element in the queue
queueSize = 0;

currValue = mat[y * nCols + x]; //The "color" of the current spot
aux[y * nCols + x] = 1;
newPoint.x = x;
newPoint.y = y;
queue[queueSize] = newPoint;
queueSize++;

while(queueIndex != queueSize) {
currPoint = queue[queueIndex];
queueIndex++;

//Look left, right, up, down

x2 = currPoint.x - 1;
y2 = currPoint.y;
//Some copy & paste, sorry I have been too long on C++ to remember correctly about C functions
if (x2 >= 0 && aux[y2 * nCols + x2] == 0 && mat[y2 * nCols + x2] == currValue) {
aux[y2 * nCols + x2] = 1;
newPoint.x = x2;
newPoint.y = y2;
queue[queueSize] = newPoint;
queueSize++;
}

x2 = currPoint.x + 1;
y2 = currPoint.y;
//Some copy & paste, sorry I have been too long on C++ to remember correctly about C functions
if (x2 < nCols && aux[y2 * nCols + x2] == 0 && mat[y2 * nCols + x2] == currValue) {
aux[y2 * nCols + x2] = 1;
newPoint.x = x2;
newPoint.y = y2;
queue[queueSize] = newPoint;
queueSize++;
}

x2 = currPoint.x;
y2 = currPoint.y - 1;
//Some copy & paste, sorry I have been too long on C++ to remember correctly about C functions
if (y2 >= 0 && aux[y2 * nCols + x2] == 0 && mat[y2 * nCols + x2] == currValue) {
aux[y2 * nCols + x2] = 1;
newPoint.x = x2;
newPoint.y = y2;
queue[queueSize] = newPoint;
queueSize++;
}

x2 = currPoint.x;
y2 = currPoint.y + 1;
//Some copy & paste, sorry I have been too long on C++ to remember correctly about C functions
if (y2 < nRows && aux[y2 * nCols + x2] == 0 && mat[y2 * nCols + x2] == currValue) {
aux[y2 * nCols + x2] = 1;
newPoint.x = x2;
newPoint.y = y2;
queue[queueSize] = newPoint;
queueSize++;
}
} //while

if (queueSize > maxArea)
maxArea = queueSize; //If necessary we could store other details like currentValue
}//if (aux...

return maxArea;
}
``````

Note: In C++ using std containers and a constructor for `Point` it becomes much more compact

-