**You forgot:**

```
1 3 4
2 5 6
```

**Code in c#:**

```
static int N = 5;
static int M = 5;
static int[,] Number;
static int[] NumbersInRow;
static int Put(int n)
{
if (n > N * M)
{
// If output of each solution is desired
//for (int y = 0; y < N; y++)
//{
// for (int x = 0; x < M; x++)
// Console.Write(Number[y, x] + "\t");
// Console.WriteLine();
//}
//Console.WriteLine();
return 1;
}
int sum = 0;
int numbersInLastRow = int.MaxValue;
int currentRow = 0;
while (currentRow < N)
{
int numbersInCurrentRow = NumbersInRow[currentRow];
if (numbersInCurrentRow < numbersInLastRow && numbersInCurrentRow < M)
{
Number[currentRow, NumbersInRow[currentRow]] = n;
NumbersInRow[currentRow]++;
sum += Put(n + 1);
NumbersInRow[currentRow]--;
Number[currentRow, NumbersInRow[currentRow]] = 0;
}
numbersInLastRow = NumbersInRow[currentRow];
currentRow++;
}
return sum;
}
static void Main(string[] args)
{
Number = new int[N, M];
NumbersInRow = new int[N];
Console.WriteLine(Put(1));
Console.ReadLine();
}
```

**Explanation:**

Place numbers on the board in order, starting with 1. When there are multiple correct placements for a number, split recursively and count all the solutions.

How do we know which are the correct placements for a number without trying every possible placement / using backtracking? **A number can be put in the first empty position of any non-full row whose previous row has more numbers in it, assuming the "-1th" row has an infinite number of numbers in it.** That's it. This way we never make a wrong move.

Note that this is symmetric - just like you can always put the next number into the first row if it isn't full, you can also put it into the first column.

The number of solutions grows extremely quickly:

```
2x2 - 2
3x3 - 42
4x4 - 24024
5x5 - 701149020
```