With the rapid development of human civilization, greenhouse problem become an important issue of global concern. Converting carbon dioxide into renewable energy resources is an effective way to resolve the detrimental problem. In the present study, we mechanistically examine the reduction reaction of carbon dioxide to carbon monoxide, the fundamental reaction for the converting process, by density functional theory (DFT) calculation. The resolved mechanism indicates that adsorption and the related Gibbs free energy of the two key intermediates COOH* and CO* control the reduction reaction: stronger adsorption of COOH* with lower Gibbs free energy to initiate the CO2 reduction and weaker adsorption of CO* with higher Gibbs free energy to remove the product of CO can essentially promote the reduction reaction. Copper has the advantage for the former adsorption, while gold and silver have those for the later one. Thus, the alloys of CuAu and CuAg are expected to benefit both adsorptions and achieve the best activity for the reduction reaction. The adsorptions on the alloys are affected by the electronic structural and ensemble effects. Accordingly, the best alloy ratios have been rationally determined: CuAu6, AuCu16 and CuAg7 are the optimal Cu-core/Au-shell, Au-core/Cu-shell and Cu-core/Ag-shell catalysts, respectively; among them AuCu16 is the best one.