Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I find that boost::ublas doesn't support element-by-element operations and operations in sequence very well (but the efficiency is pretty high :)) I am trying to

D = A^2 .* B^3 .* C

where A, B, C are all square matrices of the same size, operator ".*" denotes the element-by-element operation and ^ is the power of the matrix. With boost:ublas, I wrote

for (int n=0; n<300; n++)
  for (int k=0; k<300; k++)
    D(n, k) = pow(abs(A(n, k)), 2)*pow(abs(B(n, k)), 3)*C(n, k);

In my program I have many sequent operations like those shown above, anyway I can get the same result but using one line of code instead of loop?

Also, I observe that it seems no valid to assign a constant to all elements of matrix or vector like

boost::numeric::ublas::vector v(100); v = 0.2;

Instead, I have to use a loop to do the assignment again, any better way to save some code? My algorithm is a really long and there are so many tedious operations like those stated above. I tried another numerical library Armadillo, which provides a good way to simply the operations but it currently doesn't suppose sparse matrices (which will spend about 10 times in running my code).

share|improve this question

You can assign constant to a vector or matrix easily enough:

vector<double> v = scalar_vector<double>(100, 0.2);

regular vector (but not c_vector or bounded_vector) even has a constructor:

vector<double> v(100, 0.2);

As for element operations, you can also easily define your own, it' just the boilerplate code, e.g. for absolute power:) :

namespace boost { namespace numeric { namespace ublas {
template<class M, class P>
struct scalar_power:
    public scalar_binary_functor<M, P> {
    typedef typename scalar_binary_functor<M, P>::argument1_type argument1_type;
    typedef typename scalar_binary_functor<M, P>::argument2_type argument2_type;
    typedef typename scalar_binary_functor<M, P>::result_type result_type;

    result_type apply (argument1_type t1, argument2_type t2) {
        return pow(abs(t1), t2);

template<class M, class P>
typename enable_if< is_convertible<P, typename M::value_type>,
typename matrix_binary_scalar2_traits<M, const P, scalar_power<typename M::value_type, P> >::result_type
operator ^ (const matrix_expression<M> &m,
            const P &p) {
    typedef typename matrix_binary_scalar2_traits<M, const P, scalar_power<typename M::value_type, P> >::expression_type expression_type;
    return expression_type (m(), p);

After this your expression becomes:

D = element_prod(A^2, element_prod(B^3, C));
share|improve this answer
That is some template sorcery right there. – sje397 Dec 6 '12 at 11:34

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.