The existing transceiver design in amplify-and-forward (AF) multiple-input multiple-output (MIMO) relay systems often assume the perfect channel state information (CSI) is available. In practice, the perfect CSI is not attainable and the robust design with considering imperfect CSI is applied. In this paper, we propose a robust transceiver design for the system with Tomlinson-Harashima (TH) precoder, a linear relay precoder and a minimum-mean-square (MMSE) receiver. Since two precoders and the imperfect CSI are involved, the robust design problem is difficult. To overcome the difficulty, we additionally cascade a unitary precoder after the TH precoder. The unitary precoder can not only simply the optimization problem but improve the performance of the system. With the precoders, we use the primal decomposition to divide the original optimization problem into a subproblem and a master problem. The subproblem can be solved and the two-precoder problem can be reduced to the problem composed of single relay precoder. However, the master problem is still difficult to solve. We then proposed a lower bound for the cost function and transfer the master problem to a convex optimization problem. A closed-form solution can then be obtained by Karush-Kuhn-Tucker (KKT) conditions. Simulations show the that the proposed transceiver design have better performance than existing linear transceiver with either perfect/imperfect CSI.