Well-performed magnetoresistance (MR) is a significant aim to develop cutting-edge spintronic devices for high-performance read heads of hard disk drives (HDDs), magnetoresistive random access memories (MRAM), magnetic sensors, and magnetic field-effect transistors. The representative device, magnetic tunnel junction (MTJ), possesses a room-temperature MR ratio about 600% in application using a high-quality (100)MgO tunnel barrier. Here, extraordinary MR effects and related phenomena in multiple top-gate-controlled potentials spin-valve built on a lateral two-dimensional (2D) Dirac material, graphene or topological insulator (TI), as a transport channel are studied in this dissertation. The giant MR value up to 104 % in the double-gate graphene-based spin-valve is approximately 15 times higher than the MR of traditional MgO-based MTJs. The result is produced by particular current suppression in the antiparallel (AP) configuration. Such huge AP-mode resistance is due to the modulation of resonance and non-resonance effect in an appropriate energy window. Furthermore, the MR performance is further enhanced by the periodic gate potentials in the graphene-based spin-valve. It is found that the MR value can easily exceed 109 % at room temperature in the 10-cell gate spin-valves, which is quite amazing performance. When the period number decreases to 3, the MR value still retains up to 105 % at room temperature and up to about 1010 % at extremely low temperature in experiments. Through the investigation, the ultra-giant MR is induced by appropriate allowed bands and forbidden bands in the energy window. Needless to say, the MR value is very ordinary (under 100%) while the device setup keeps away from the circumstances described above (resonance point). For TI-based spin-valves, the device reveals interest MR oscillations near the Fermi level of low-energy approximation. The results exhibit that only a few robust bands of high-MR properties are available in practical applications. A MR value higher than 1000% at room temperature is showed in a TI thin-film (TITF) spin valve with a 3-cell segment gate potential. The results reveal a very large resistance difference between the parallel and antiparallel configurations. The MR effect is strongly influenced by the thin-film thickness, the gate potential, the gate size, and the distribution. The research investigates the ultra-giant MR effect and its reason that could be applied to high-efficiency spintronics devices, including novel storage memories, read-head sensors, and spin transistors.