# Given a position in matrix [i, j], find the block it belongs to

Well, I am dealing with sudoku solving algorithm and generation but stuck at rather simple task. I have made the check, whether a number is really fit in the position row-wise and column-wise. But what it is driving me mad is block check, ie, whether the number is really fit in the 3x3 block.

It must be simple enough but I can't really arrive at the solution. In short, I want to know the 3x3 block to which a position in matrix belongs. Here are some of the assert cases. The block no, row no and col no indexing starts from 0.

``````assert("x( 0, 8 ) === 2");
assert("x( 8, 8 ) === 8");
assert("x( 3, 3 ) === 4");
assert("x( 3, 7 ) === 5");
assert("x( 7, 1 ) === 6");
``````

`x( i , j )` returns the block number where `i` = row and `j` = col.

-

Isn't it just:

``````block = 3 * (i / 3) + (j / 3)
``````

(assumes integer operations).

I would code a check, something like this (in pseudo C++)

``````// row = row to check
// col = column to check
// checkNum = number we are thinking of inserting
bool check(int row, int col, int checkNum)
{
int blockRow = 3 * (row/3);
int blockCol = 3 * (col/3);
for(int i = 0 ; i < 9 ; i++)
{
if(grid[row][i] == checkNum) return false; // number exists in the row.
if(grid[i][col] == checkNum) return false; // number exists in the col.
if(grid[blockRow + i/3][blockCol + i%3] == checkNum) return false; // number exists in the block.
}
return true;
}
``````
-
:|. (Poker Face). –  Shubham Dec 24 '12 at 16:09

Here is a sudoku solver in javascript. Taken from DSSudokuSolver, that I created. The CleanElements function does something similar to what you are asking for.

``````CleanElements = function(comp_ary, Qsudoku){
for(i=0; i<9; i++){
for(j=0; j<9; j++){
/*if(Qsudoku[i][j] != ""){
comp_ary[i][j]=[];
}*/
for(k=0; k<9; k++){
i_index = comp_ary[i][k].indexOf(Qsudoku[i][j]);
if(i_index != -1){
comp_ary[i][k].splice(i_index, 1);
}
j_index = comp_ary[k][j].indexOf(Qsudoku[i][j]);
if(j_index != -1){
comp_ary[k][j].splice(j_index, 1);
}
}
if(i < 3){
i_min = 0;
i_max = 2;
}
else if(i < 6){
i_min = 3;
i_max = 5;
}
else{
i_min = 6;
i_max = 8;
}

if(j < 3){
j_min = 0;
j_max = 2;
}
else if(j < 6){
j_min = 3;
j_max = 5;
}
else{
j_min = 6;
j_max = 8;
}

for(i_box=i_min; i_box<=i_max; i_box++){
for(j_box=j_min; j_box<=j_max; j_box++){
index = comp_ary[i_box][j_box].indexOf(Qsudoku[i][j]);
if(index != -1){
comp_ary[i_box][j_box].splice(index, 1);
}
}
}
}
}
return comp_ary;
}

FindElements = function(comp_ary, Qsudoku){
for(i=0; i<9; i++){
for(j=0; j<9; j++){
if(comp_ary[i][j].length == 1){
if (Qsudoku[i][j] == ""){
Qsudoku[i][j] = comp_ary[i][j][0];
comp_ary[i][j] = [];
}
}
}
}
return Qsudoku;
}

IsThereNullElement = function(Qsudoku){
for(i=0; i<9; i++){
for(j=0; j<9; j++){
if(Qsudoku[i][j] == ""){
return false;
}
}
}
return true;
}

InitEmptyArray = function(){
empty_ary = Array();
for(i=0; i<9; i++){
empty_ary[i] = Array();
for(j=0; j<9; j++){
empty_ary[i][j] = Array();
for(k=0; k<9; k++){
empty_ary[i][j][k] = (k+1).toString();
}
}
}
return empty_ary;
}

DSSolve = function(Qsudoku){
comp_ary = InitEmptyArray(); //Complementary Array
window.comp_ary_old = comp_ary;
IterationMax = 5000;

while(true){
IterationMax -= 1;
comp_ary = CleanElements(comp_ary, Qsudoku);
console.log(comp_ary);

if(window.comp_ary_old == comp_ary){
//implement this.
}
else{
window.comp_ary_old = comp_ary;
}

Qsudoku = FindElements(comp_ary, Qsudoku);
//console.log(Qsudoku);

if(IsThereNullElement(Qsudoku)){
return Qsudoku;
}

if(IterationMax == 0){
return null;
}
}
}
``````
-