All-optical　logic　gates　offer　ultra-fast　speed　information　processing　and　lower　power　consumption　that　still　misses　the　reconfigurability,　remaining　beset　for　high　power　consumption　and　large　space　requirements.　Considering　random　lasers　with　pump-reconstructed　spectra　without　changing　the　structure,　an　optical　platform　for　reconfigurable　logic　gate　operations　is　developed　based　on　random　laser　systems.　By　engineering　the　energy　distribution　of　two　pump　regions,　the　interaction　between　the　two　equivalent　random　laser　systems　is　changed　from　strongly　correlated　to　weakly　correlated,　thereby　realizing　the　transition　from　nonresonant　laser　with　continuous　frequency　distribution　to　resonant　random　laser　with　discrete　frequency　distribution.　By　converting　input　pump　signals　into　output　random　laser　signals,　the　operation　and　facile　reconfiguration　of　four　2-input　logic　gates　(OR,　NOR,　NAND,　and　AND)　in　a　single　disordered　gain　film　is　demonstrated　by　simply　managing　the　correlation　of　the　two　random　laser　regions　through　manipulating　the　energy　distribution　of　the　input　pump.　The　proof-of-concept　of　the　random　laser-based　optical　logic　gates　features　reconfigurability　and　ease　of　operation,　providing　a　promising　method　for　designing　arithmetic　logic　units　for　optical　network　signal　processing　and　optical　computing.