The in‐depth understanding of ions' generation and movement inside all‐inorganic perovskite quantum dots (CsPbBr3 QDs), which may lead to a paradigm to break through the conventional von Neumann bottleneck, is strictly limited. Here, it is shown that formation and annihilation of metal conductive filaments and Br− ion vacancy filaments driven by an external electric field and light irradiation can lead to pronounced resistive‐switching effects. Verified by field‐emission scanning electron microscopy as well as energy‐dispersive X‐ray spectroscopy analysis, the resistive switching behavior of CsPbBr3 QD‐based photonic resistive random‐access memory (RRAM) is initiated by the electrochemical metallization and valance change. By coupling CsPbBr3 QD‐based RRAM with a p‐channel transistor, the novel application of an RRAM–gate field‐effect transistor presenting analogous functions of flash memory is further demonstrated. These results may accelerate the technological deployment of all‐inorganic perovskite QD‐based photonic resistive memory for successful logic application. Resistive random‐access memory (RRAM) and RRAM‐functionalized field‐effect transistors (FETs) based on photon tunable CsPbBr3 quantum dots are demonstrated. The formation and annihilation of metal conductive filaments and bromine‐vacancy filaments in CsPbBr3 quantum dot arrays can be realized under an electric field and light irradiation. The devices exhibit multilevel data storage using light tuning, which may accelerate the technological deployment of all‐inorganic perovskite QD‐based photonic memory.