Onsager's relations allow one to express the second law of thermodynamics in terms of the underlying associated currents. These relations, however, are usually valid only close to equilibrium. Using a quantum phase space formulation of the second law, we show that open bosonic Gaussian systems also obey a set of Onsager relations, valid arbitrarily far from equilibrium. These relations, however, are found to be given by a more complex nonlinear function, which reduces to the usual quadratic form close to equilibrium. This nonlinearity implies that in Gaussian models far from equilibrium, there exists a fundamental asymmetry between entropy flow from the system to the bath and vice versa. The ramifications of this for applications in driven-dissipative quantum optical setups are also discussed. (AU)