ConspectusStereochemical control of excited-state asymmetric photoreactions has been one of the most challenging topics of modern photochemistry. The short-lived character of electronically excited photosubstrates and their low activation energy barriers to form both enantiomers are the major obstacles to achieving significant enantioselectivity in excited-state asymmetric photochemistry. Recent research demonstrated that the supramolecular strategy is promising to control the stereochemical outcome of asymmetric photoreaction through relatively strong and long-lasting noncovalent interaction at both ground and excited states. In this methodology, chiral hosts/assemblies provide the chiral environment for photochemically transferring chirality to the complexed photosubstrate in both the ground and the excited states by virtue of relatively strong supramolecular interactions, such as hydrogen bonding, van der Waals, π-π, electrostatic, and hydrophobic interactions. The orientation and conformation of the photosubstrate can be critically manipulated by the supramolecular complexation to ensure the subsequent effective stereoselective photochemical conversion.This Account describes our recent advance in asymmetric photoreactions in supramolecular assemblies. Several chiral photoreactions, including photoisomerization of cycloolefins and photocyclodimerization of anthracene and naphthalene derivatives, have been mediated by various supramolecular hosts, such as cyclodextrin (CD), cucurbituril, pillararene, and chiral polymer. The following advantages of supramolecular asymmetric photochemistry were evidenced: (1) The improvement of stereoselectivity can be enabled by the careful design and fabrication of chiral host molecules. (2) Supramolecular complexation could effectively regulate the orientation and conformation of photosubstrates, thus resulting in novel reaction pathways which create unusual photoproducts that are not achievable through traditional reaction conditions. (3) Asymmetric photoreactions in supramolecular systems showed strong correlations with the external environmental variants, such as temperature, solvent, irradiation wavelength, and pressure, which therefore provide a powerful tool for the regulation of stereoselectivities of excited-state photoreactions. (4) Utilizing supramolecular complexation can dramatically speed up photoreactions, a combination of appropriate photosensitizers/photocatalysts being able to drive catalyzed chiral photoreactions effectively. (5) Photoisomerization in chiral supramolecular systems has been applied to chiroptical molecular devices, which exhibited multiple stimulus-response functions and advanced switching performances. We believe that these concepts, methods, and principles derived therefrom are instructive in designing chiral supramolecular hosts, elucidating the stereodifferentiation mechanisms in the ground and excited states, and analyzing and improving the stereochemical outcomes of a diverse range of supramolecular chiral photoreactions.