Hamiltonian vector fields of homogeneous polynomials in two variables

Let $g:\mathbb{R}^2\to\mathbb{R}$ be a homogeneous polynomial of degree $p>1$, $G=(-g'_{y}, g'_{x})$ be its Hamiltonian vector field, and $G_t$ be the local flow generated by $G$. Denote by $E(G,O)$ the space of germs of $C^{\infty}$ diffeomorphisms $(\mathbb{R}^2,O)\to(\mathbb{R}^2,O)$ that preserve orbits of $G$. Let also $E_{\mathrm{id}}(G,O)$ be the identity component of $E(G,O)$ with respect to $C^1$-topology. Suppose that $g$ has no multiple prime factors. Then we prove that for every $h\in E_{\mathrm{id}}(G,O)$ there exists a germ of a smooth function $\alpha:\mathbb{R}^2\to\mathbb{R}$ at $O$ such that $h(z)=G_{\alpha(z)}(z)$.