As the following product is a bit unfamiliar to me:
How do we compute the rational cohomology ring $H^*(M;\mathbb{Q})$ of the product of Lie groups: $M=SO(n_1)\times U(n_2)\times SU(n_3)\times (Sp(n_4)\cdot Sp(1))\times Sp(n_5)\times G_2\times Spin(7)\times \left(\frac{SU(n_6+1)}{S(U(1)\times U(n_6))}\right)\times \left(\frac{SO(n_7+1)}{SO(1)\times SO(n_7)}\right)\times \left(\frac{Sp(n_8+1)}{Sp(1)\times Sp(n_8)}\right)\times \left(\frac{F_4}{Spin(9)}\right)?$
Thoughts: Of course, $H^*(M;\mathbb{Q})$ is: $$H^*(M;\mathbb{Q})\cong H^*(SO(n_1);\mathbb{Q})\otimes H^*(U(n_2);\mathbb{Q})\otimes H^*(SU(n_3);\mathbb{Q})\otimes...\otimes H^*(F^4/Spin(9);\mathbb{Q})$$ by the Kunneth formula. This could be possibly simplified by first computing the rationalization $M_\mathbb{Q}$, which would help us in finding the equivariant cohomology ring $H^*_{\mathbb{Q}}(M;\mathbb{Q})=H^*(E\mathbb{Q}\times_{\mathbb{Q}}M;\mathbb{Q})$, noting that the rationalization $M_\mathbb{Q}$ is a product of Eilenberg–MacLane spaces (whose rational cohomology rings are better known-the problem is in finding such a product decomposition).
