We introduce the concept of smart radio environments, currently extensively studied for wireless communication in metasurface-programmable meter-scaled environments (e.g., inside rooms), on the chip scale. Wired intra-chip communication for information exchange between cores increasingly becomes a computation-speed-bottleneck for modern multi-core chips. Wireless intra-chip links with millimeter waves are a candidate technology to address this challenge, but they currently face their own problems: the on-chip propagation environment can be highly reverberant due to the metallic chip enclosure but transceiver modules must be kept simple (on/off keying) such that long channel impulse responses (CIRs) slow down the communication rate. Here, we overcome this problem by endowing the on-chip propagation environment with in situ programmability, allowing us to shape the CIR at will, and to impose, for instance, a pulse-like CIR despite the strong multi-path environment. Using full-wave simulations, we design a programmable metasurface suitable for integration in the on-chip environment ("on-chip reconfigurable intelligent surface"), and we demonstrate that the spatial control offered by the metasurface allows us to shape the CIR profile. We envision (i) dynamic multi-channel CIR shaping adapted to on-chip traffic patterns, (ii) analog wave-based over-the-air computing inside the chip enclosure, and (iii) the application of the explored concepts to off-chip communication inside racks, inside the chassis of personal computers, etc.