I am trying to solve this problem but I can't find a solution:

A board consisting of squares arranged into N rows and M columns is given. A tiling of this board is a pattern of tiles that covers it. A tiling is interesting if:

```
only tiles of size 1x1 and/or 2x2 are used;
each tile of size 1x1 covers exactly one whole square;
each tile of size 2x2 covers exactly four whole squares;
each square of the board is covered by exactly one tile.
```

For example, the following images show a few interesting tilings of a board of size 4 rows and 3 columns: http://dabi.altervista.org/images/task.img.4x3_tilings_example.gif

Two interesting tilings of a board are different if there exists at least one square on the board that is covered with a tile of size 1x1 in one tiling and with a tile of size 2x2 in the other. For example, all tilings shown in the images above are different.

Write a function

```
int count_tilings(int N, int M);
```

that, given two integers N and M, returns the remainder modulo 10,000,007 of the number of different interesting tilings of a board of size N rows and M columns.

Assume that:

```
N is an integer within the range [1..1,000,000];
M is an integer within the range [1..7].
```

For example, given N = 4 and M = 3, the function should return 11, because there are 11 different interesting tilings of a board of size 4 rows and 3 columns:

http://dabi.altervista.org/images/task.img.4x3_tilings_all.gif

for (4,3) the result is 11, for (6,5) the result is 1213. I tried the following but it doesn't work:

```
static public int count_tilings ( int N,int M ) {
int result=1;
if ((N==1)||(M==1)) return 1;
result=result+(N-1)*(M-1);
int max_tiling= (int) ((int)(Math.ceil(N/2))*(Math.ceil(M/2)));
System.out.println(max_tiling);
for (int i=2; i<=(max_tiling);i++){
if (N>=2*i){
int n=i+(N-i);
int k=i;
//System.out.println("M-1->"+(M-1) +"i->"+i);
System.out.println("(M-1)^i)->"+(Math.pow((M-1),i)));
System.out.println( "n="+n+ " k="+k);
System.out.println(combinations(n, k));
if (N-i*2>0){
result+= Math.pow((M-1),i)*combinations(n, k);
}else{
result+= Math.pow((M-1),i);
}
}
if (M>=2*i){
int n=i+(M-i);
int k=i;
System.out.println("(N-1)^i)->"+(Math.pow((N-1),i)));
System.out.println( "n="+n+ " k="+k);
System.out.println(combinations(n, k));
if (M-i*2>0){
result+= Math.pow((N-1),i)*combinations(n, k);
}else{
result+= Math.pow((N-1),i);
}
}
}
return result;
}
static long combinations(int n, int k) {
/*binomial coefficient*/
long coeff = 1;
for (int i = n - k + 1; i <= n; i++) {
coeff *= i;
}
for (int i = 1; i <= k; i++) {
coeff /= i;
}
return coeff;
}
```