The reason that you get that particular error message is that the variable
multi is type
int *, and not
int **. Your function treats it as an
int ** by dereferencing it twice in
*(*(multi + i ) + j)
Break the expression down:
*(multi + i) dereferences the pointer
multi is type
int *, this is fine. The resulting type is
*( ... + j) attempts to dereference
... + j. The problem is that
... is type
... + j is type
int. Your cannot dereference an
int (it's an integral type, not a pointer).
multi to be type
int **, and pass in an actual
multi as an
int * and use single-index addressing
Solution 1 only works if you allocate an array of
int * and then fill it to point to arrays of
int. It will not work if you declare a multidimensional array in C (i.e.,
int myarray). In C, a declared multidimensional array is kept in contiguous memory, and this information is lost if you pass it to a function as a pointer-to-a-pointer.
The second solution is to choose either row-major or column-major indexing, and the pass in the relevant sizes. You should probably be doing this anyway. If you choose row-major indexing (rows are contiguous in memory), an M x N matrix
multi is addressed as
multi[i + M*j]
If you choose column-major indexing (columns are contiguous in memory), the same matrix is addressed as
multi[N*i + j]
This solution will work for statically-declared multidimensional arrays in C, and allows you to dynamically allocate a multidimensional array in C with minimal overhead.
Also, be aware that statically-declared multidimensional arrays in C uses column-major indexing when they're accessed as
mat[i][j]. However, if you're doing serious matrix work, there are good reasons to prefer row-major indexing. Finally, Fortran uses row-major indexing, and if your code needs to interface with Fortran (as numerical code often does), you should probably prefer row-major indexing.