Abstract

As leakage and other charge storage limitations begin to impair the scalability of DRAM, non-volatile resistive memories are being developed as a potential replacement. Unfortunately, current error correction techniques are poorly suited to this emerging class of memory technologies. Unlike DRAM, PCM and other resistive memories have wear lifetimes, measured in writes, that are sufficiently short to make cell failures common during a system's lifetime. However, resistive memories are much less susceptible to transient faults than DRAM. The Hamming-based ECC codes used in DRAM are designed to handle transient faults with no effective lifetime limits, but ECC codes applied to resistive memories would wear out faster than the cells they are designed to repair. This paper evaluates Error-Correcting Pointers (ECP), a new approach to error correction optimized for memories in which errors are the result of permanent cell failures that occur, and are immediately detectable, at write time. ECP corrects errors by permanently encoding the locations of failed cells into a table and assigning cells to replace them. ECP provides longer lifetimes than previously proposed solutions with equivalent overhead. What's more, as the level of variance in cell lifetimes increases -- a likely consequence of further scalaing -- ECP's margin of improvement over existing schemes increases.