How do Hamilton's equations deal with non-conservative forces?

1. If a variational formulation of Lagrange equations exists (e.g. because of the existence of a generalized velocity-dependent potential $U(q,dot{q},t)$ for the forces in the problem), then we can in principle derive a Hamiltonian formulation via a Legendre transformation in the standard manner.

2. If no variational Lagrangian formulation exists for Lagrange equations $$begin{align}frac{d}{dt}frac{partial L}{partial dot{q}^j}-frac{partial L}{partial q^j}~=~&Q_j, cr j~in~& {1,ldots, n}, end{align}tag{L}$$ but the Lagrangian $L$ is regular/non-degenerate, then we may still derive a Hamiltonian $H$ via a Legendre transformation. However Hamilton's equations get modified $$begin{align} dot{q}^j~=~frac{partial H}{partial p_j}, & qquad dot{p}_j+frac{partial H}{partial q^j}~=~Q_j, cr j~in~&{1,ldots, n}. end{align}tag{H}$$ So there is no conventional Hamiltonian formulation. Nevertheless, several unconventional approaches exist, cf. this related Phys.SE post.

Lorentz force is an example of non-conservative conservative force that is discussed in pretty much any theoretical mechanics textbook. The Lagrangian is: $$L = frac{m}{2}dot{mathbf{r}}cdotdot{mathbf{r}} + q mathbf{A}(mathbf{r})cdotdot{mathbf{r}} - qphi(mathbf{r}),$$ from which the momentum, the Hamiltonian, and the Hamilton equations follow as usual.