VectorBase ADFun<Base>::SparseJacobian( const VectorBase& x )
{ typedef CppAD::vectorBool VectorBool;
size_t m = Range();
size_t n = Domain();
// sparsity pattern for Jacobian
VectorBool p(m * n);
if( n <= m )
{ size_t j, k;
// use forward mode
VectorBool r(n * n);
for(j = 0; j < n; j++)
{ for(k = 0; k < n; k++)
r[j * n + k] = false;
r[j * n + j] = true;
}
p = ForSparseJac(n, r);
}
else
{ size_t i, k;
// use reverse mode
VectorBool s(m * m);
for(i = 0; i < m; i++)
{ for(k = 0; k < m; k++)
s[i * m + k] = false;
s[i * m + i] = true;
}
p = RevSparseJac(m, s);
}
return SparseJacobian(x, p);
}
VectorBase ADFun<Base>::SparseJacobian( const VectorBase& x )
{ typedef CppAD::vectorBool VectorBool;
size_t m = Range();
size_t n = Domain();
// sparsity pattern for Jacobian
VectorBool p(m * n);
// return result
VectorBase jac(m * n);
if( n <= m )
{ size_t j, k;
// use forward mode
VectorBool r(n * n);
for(j = 0; j < n; j++)
{ for(k = 0; k < n; k++)
r[j * n + k] = false;
r[j * n + j] = true;
}
p = ForSparseJac(n, r);
}
else
{ size_t i, k;
// use reverse mode
VectorBool s(m * m);
for(i = 0; i < m; i++)
{ for(k = 0; k < m; k++)
s[i * m + k] = false;
s[i * m + i] = true;
}
p = RevSparseJac(m, s);
}
bool set_type = true; // only used to dispatch compiler to proper case
SparseJacobianCase(set_type, x, p, jac);
return jac;
}
