Precise　light　manipulation　is　of　paramount　importance　in　improving　the　performance　of　semi-transparent　organic　photovoltaics　(STOPVs)　for　their　orientation　toward　building-integrated　photovoltaic　window.　Nevertheless,　one　critically　important　issue　for　the　integration　of　optical　modulation　with　STOPV　devices,　lies　in　the　damage　from　the　harsh　direct　deposition　steps　to　the　intrinsic　properties　and　long-term　durability　of　STOPVs.　Here　a　transferprinting　(TP)　approach,　in　which　photonic　crystals　(PC)　films　are　deposited　onto　a　self-adhesive　and　flexible　matrix　for　their　integration　with　STOPV　devices,　was　first　reported,　enabling　the　resultant　TPPC-STOPV　devices　with　superior　optical-related　multifunction.　In　contrast　to　these　devices　based　on　direct-evaporated　PC　film,　the　non-encapsulated　TPPC-STOPVs　present　an　ultraviolet　blocking　(UVB)　as　high　as　96%,　an　infrared　rejection　(IRR)　of　92%,　an　enhanced　power　conversion　efficiency　(PCE)　by　5%　as　well　as　superior　long-term　durability　as　96%　of　its　initial　PCE.　Their　gifted　superior　UVB　and　IRR　properties　are　individually　on　a　par　with　those　of　the　stat-of-the-art　commercial　optical　films　for　smart　solar　window.　This　transfer-printing　approach　makes　it　possible　to　separate　the　high-energy　fabrication　of　high-quality　contacts　from　target　optoelectronic　devices,　providing　a　wide　range　of　possibilities　for　the　integration　of　high-quality　contacts　with　optoelectronic　devices,　including　organic,　silicon　and　perovskite　optoelectronic　devices,　as　well　as　their　large-area　flexible　integration.