I'm currently trying to use odeint and Eigen3 to integrate an nBody system (target is a library providing advanced routines for use in planet formation, such as mixed variable symplectic or Chambers hybrid variation of MVS). While experimenting with different steppers I found that when using normal steppers the state_type `std::vector<Eigen::Vector3d>`

works fine, but with controlled steppers (such as `burlisch_stoer`

) compilation fails, the first error message being:

```
/usr/include/boost/numeric/odeint/stepper/controlled_runge_kutta.hpp:87:40: error: cannot convert ‘boost::numeric::odeint::norm_result_type<std::vector<Eigen::Matrix<double, 3, 1> >, void>::type {aka Eigen::Matrix<double, 3, 1>}’ to ‘boost::numeric::odeint::default_error_checker<double, boost::numeric::odeint::range_algebra, boost::numeric::odeint::default_operations>::value_type {aka double}’ in return
return algebra.norm_inf( x_err );
```

Does this mean that the norm_result_type is deduced incorrectly? What does this norm do exactly? Should it be the highest value_type found in x_err?

and the second:

```
/usr/include/boost/numeric/odeint/algebra/range_algebra.hpp:132:89: error: call of overloaded ‘Matrix(int)’ is ambiguous
static_cast< typename norm_result_type<S>::type >( 0 ) );
```

Do I have to provide my own algebra to use it this way? I would rather not switch to a `std::vector<double>`

or an Eigen::VectorNd, as having the coordinates grouped is very beneficial to the readability of the right hand sides of the ODEs.

Here is the a reduced example of the code I used.

```
#include "boost/numeric/odeint.hpp"
#include "boost/numeric/odeint/external/eigen/eigen.hpp"
#include "Eigen/Core"
using namespace boost::numeric::odeint;
typedef std::vector<Eigen::Vector3d> state_type;
struct f
{
void operator ()(const state_type& state, state_type& change, const double /*time*/)
{
};
};
int main()
{
// Using this compiles
typedef euler <state_type> stepper_euler;
// Using this does not compile
typedef bulirsch_stoer <state_type> stepper_burlisch;
state_type x;
integrate_const(
stepper_burlisch(),
f(),
x,
0.0,
1.0,
0.1
);
return 0;
}
```

Headmyshoulders solution worked. I have created a algebra inheriting from the `range_algebra`

:

```
class custom_algebra : public boost::numeric::odeint::range_algebra {
public:
template< typename S >
static double norm_inf( const S &s )
{
double norm = 0;
for (const auto& inner : s){
const double tmp = inner.maxCoeff();
if (tmp > norm)
norm = tmp;
}
return norm;
}
} ;
```

I think it should be possible to create such an algebra generically using both `range_algebra`

and `vector_space_algebra`

, but i haven't tried yet.