The NLopt objective function looks like this:

``````double myfunc(const std::vector<double> &x, std::vector<double> &grad, void *my_func_data)
``````

x is the data being optimized, grad is a vector of gradients, and my_func_data holds additional data.

I am interested in supplying Armadillo matrices A and B to void *my_func_data.

I fiddled with Armadillo's member functions

``````mat A(5,5);
mat B(5,5);
double* A_mem = A.memptr();
double* B_mem = B.memptr();
``````

which gives me a pointers to the matrices A and B. I was thinking of defining another pointer to these pointers:

``````double** CombineMat;
int* Arow = A.n_rows; int* Acols = A.n_cols; //obtain dimensions of A
int* Brows = B.n_rows; int* Bcols = B.n_cols; // dim(B)
CombineMat[0] = A_mem; CombineMat[1] = Arows; CombineMat[2] = Acols;
CombineMat[3] = B_mem; CombineMat[4] = Brows; CombineMat[5] = Bcols;
``````

and then passing *CombineMat as my_func_data.

1. Is this the way to do it? It seems clumsy...
2. Once CombineMat is passed, how do re-cast the void type into something usable when I'm inside myfunc?

I answered my own question with help from here.

``````mat A(2,2);
A << 1 << 2 << endr << 3 << 4;

mat B(2,2);
B << 5 << 6 << endr << 7 << 8;

mat C[2];
C[0] = A;
C[1] = B;

opt.set_min_objective(myfunc, &C);
``````

Once inside myfunc, the data in C can be converted back to Armadillo matrices like this:

``````mat* pC = (mat*)(my_func_data);
mat A = pC[0];
mat B = pC[1];
``````
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You can also use Armadillo's Cube class ("3D matrix", or 3-rd order tensor).

Each slice in a cube is just a matrix. For example:

``````cube X(4,5,2);

mat A(4,5);
mat B(4,5);

X.slice(0) = A;  // set the individual slices
X.slice(1) = B;

mat& C = X.slice(1); // get the reference to a matrix stored in a cube
``````
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