A molecular machine, or nanomachine, refers to any nano-sized system that produces quasi-mechanical movements (output) in response to a specific stimuli (input). Nano-engineering is today a rapidly growing, innovative field of science and technology. The 2016 Nobel Prize in Chemistry recompensing the chemical research effort in this area confirmed that engineering of the nano-machines is not any more an object of science-fiction stories. We are at the advent of new engineering methodology, in which the nano-systems can be numerically designed and chemically synthesized. In order to construct a complex machine, several challenging problems must be solved. First, a number of pre-assembled building blocks have to be prepared, as the function of the device is intended to be a consequence of their assembly. Furthermore, to obtain a predetermined function of the machine, this assembly should provide a possibility to precisely controlled translational and rotational movements of the machine components, stimulated by an inflow of external energy. The machine also needs an interface with its environment. Ultimately, it should be able to overcome thermal fluctuation (Brownian motion) that influences its mechanical action, and to operate out of equilibrium in dissipative systems, when controlled and driven by an external fueling, by light or other energy source. Starting from Richard Feynman prediction from 1984 that it would be possible to build machines with nanometric dimensions we show how the notion of the nano-machine has evolved during the last century. In 1983 chemists succeeded to produce molecular chains, catenanes, in which ring-shaped molecules were linked together by mechanical bonds, but the interlocked molecules did not form any intermolecular, strong covalent bonds. The catenanes were not only a new class of macromolecules: they also represented the first step towards creating a molecular machine. Then, in 1994 a rotaxane, a ring-shaped molecule that is mechanically attached to an axle has been created. The first molecular motor was proposed in 1999. Since then the rotaxane has been used to construct numerous molecular machines, including a molecular elevator, which can raise itself 0.7 nanometers above a surface, and an artificial muscle (2000), that is able to bend a very thin gold lamina. Many new ideas have been published and many new systems have been already synthesized. This presentation will be focused on the nanomachines in which the light is used as a photonic factor actuating and allowing control of the nano-machines movements.