**The number of unique elements, m, needed to be represented in an n by n symmetric matrix:**

With the main diagonal

`m = (n*(n + 1))/2`

Without the diagonal (for symmetric matrix as the OP describes, main diagonal is needed, but just for good measure...)

`m = (n*(n - 1))/2`

.

Not dividing by 2 until the last operation is important if integer arithmetic with truncation is used.

You also need to do some arithmetic to find the index, i, in the allocated memory corresponding to row x and column y in the diagonal matrix.

**Index in allocated memory, i, of row x and column y in upper diagonal matrix:**

With the diagonal

```
i = (y*(2*n - y + 1))/2 + (x - y - 1)
```

Without the diagonal

```
i = (y*(2*n - y - 1))/2 + (x - y -1)
```

For a lower diagonal matrix flip x and y in the equations. For a symmetric matrix just choose either x>=y or y>=x internally and have member functions flip as needed.