Let $\mathcal P$ be the set of probability densities on $[0,1]$ with mean $1/2$, i.e. $p\in \mathcal P$ iff
$$\int_0^1 p(x)dx=1,\quad \int_0^1 xp(x)dx=\frac{1}{2}\quad \mbox{and}\quad p(x)\ge 0, ~~\forall x\in [0,1].$$
How to solve the minimization problem below ?
$$\min_{p\in\mathcal P}~ \left\{V(p) ~:=~ \int_0^1 \log\big(p(x)\big)p(x)dx + \int_0^1 \big(x\log(x)+(1-x)\log(1-x)\big)p(x)dx\right\}.$$
As in the comment by leo monsaingeon, let $$p_*(x):=e^{h(x)}/c,$$ where $h(x):=-x\ln x-(1-x)\ln(1-x)$ and $c:=\int_0^1 e^{h(x)}\,dx$, so that $p$ is a pdf on $(0,1)$ with mean $1/2$, and $$V(p)=\int_0^1(p(x)\ln p(x)-h(x)p(x))\,dx.$$
For any pdf $q$ on $(0,1)$ with $V(q)<\infty$, the directional derivative of $V$ at $p_*$ in the direction of $q-p_*$ is $$\begin{aligned} &\frac d{dt}\,V(p_*+t(q-p_*))\Big|_{t=0} \\ &=\int_0^1 (1+\ln p_*(x)-h(x))(q(x)-p_*(x))\,dx \\ &=\int_0^1 (1+h(x)-\ln c-h(x))(q(x)-p_*(x))\,dx=0, \end{aligned}$$ since $q$ and $p_*$ are pdf's on $(0,1)$.
The crucial point is that the function $V$ is convex (since $u\ln u$ is convex in $u\ge0$, with $0\ln0:=0$). So, $p_*$ is indeed a minimizer of $V$.
