2D materials have captured the attention of researchers due to their unique properties and the ability to produce high-quality material by simple exfoliation from bulk precursors in solution. To realize the vision of cheap and ubiquitous, liquid-deposited electronics, a suitable assembly method has to be devised that retains the 2D morphology and supports complicated device geometries. We here demonstrate a new method of depositing 2D materials into complex circuits directly from solution without the need for post-deposition patterning. By confining a liquid droplet in two dimensions, a continuous liquid film is produced whose extents are determined by the competition of Young-Laplace equation, gravity and capillary force. The confinement produces a preferential direction of evaporative liquid loss on the top of the droplet and results in receding 2D film. Such a receding motion of liquid produces a flow that brings solute to the edge, resulting in deposition of the dispersed 2D material in a well-defined region. The resulting 1D patterns exhibit a microscopic width and good uniformity over millimeter-scale and lend themselves to electrical devices. We demonstrate the formation of complex electrical circuits through when using graphene and transistors formed from graphene/MoS2.