It will be backtrack the most efficient solution for generation, however as there are many approaches to that I propose the following algorithm (it is in pseudo C++)

```
int mat[n][m] = {-1}; // initialize all cells with -1
int sortedArray[n * m]; // the sorted array of all numbers, increasing order
void generateAllSolutions(set<pair<int, int> > front, int depth) {
if (depth == n * m) {
printMatrix();
return;
}
for (pair<int, int> cell : front) {
mat[cell.first][cell.second] = sortedArray[depth];
newFront = front;
newFront.remove(cell);
if (cell.first < n - 1 &&
(cell.second == 0 || mat[cell.first + 1][cell.second - 1] != -1)) {
newFront.add(<cell.first + 1, cell.second>);
}
if (cell.second < m - 1 &&
(cell.first == 0 || mat[cell.first - 1][cell.second + 1] != -1))
newFront.add(<cell.first, cell.second + 1>);
}
generateAllSolutions(newFront, depth + 1);
mat[cell.first][cell.second] = -1; // backing the track
}
}
void solve() {
set<pair<int, int> > front = {<0, 0>}; // front initialized to upper left cell
generateAllSolutions(front, 0);
}
```

What I am doing with that is keeping a 'front' of all the cells that are possible candidates for the next smallest number. These are basically all the cells that have their upper and left neighbours already filled in with smaller numbers.

Because the algorithm I propose can be optimised to use operations of the magnitude of the number of all cells in all solutions, this should be optimal possible solution performance-wise for your task.

I wonder if there is any clever solution if you aim only at counting all possible solutions (I can immediately device a solution of magnitude O(min(m^{n}, n^{m}))