Consider a cube $\Omega = [-1,1]^d$, and complex bounded periodic functions $g \in L^\infty_{\text{per}}(\Omega)$ such that $\int_\Omega g = 0$. For each $g$, define $f_g$ to be the unique function such that $\int_\Omega f_g = 0$ and
 \begin{align*}
	  \Delta f_g = g.
 \end{align*}
 Can we prove that $f_g \in L^\infty_{\text{per}}(\Omega)$ and
 \begin{align*}
	  \|f_g\|_{L^\infty_{\rm per}} \le c \|g\|_{L^\infty_{\rm per}}
 \end{align*}
 where $c$ does not depend on $g$ ?