Proteus: Achieving High-Performance Processing-Using-DRAM via Dynamic Precision Bit-Serial Arithmetic

Processing-using-DRAM (PUD) is a paradigm where the analog operational properties of DRAM structures are used to perform bulk logic operations. While PUD promises high throughput at low energy and area cost, we uncover three limitations of existing PUD approaches that lead to significant inefficiencies: (i) static data representation, i.e., 2's complement with fixed bit-precision, leading to unnecessary computation over useless (i.e., inconsequential) data; (ii) support for only throughput-oriented execution, where the high latency of individual PUD operations can only be hidden in the presence of bulk data-level parallelism; and (iii) high latency for high-precision (e.g., 32-bit) operations. To address these issues, we propose Proteus, which builds on two key ideas. First, Proteus parallelizes the execution of independent primitives in a PUD operation by leveraging DRAM's internal parallelism. Second, Proteus reduces the bit-precision for PUD operations by leveraging narrow values (i.e., values with many leading zeros). We compare Proteus to different state-of-the-art computing platforms (CPU, GPU, and the SIMDRAM PUD architecture) for twelve real-world applications. Using a single DRAM bank, Proteus provides (i) 17x, 7.3x, and 10.2x the performance per mm2; and (ii) 90.3x, 21x, and 8.1x lower energy consumption than that of the CPU, GPU, and SIMDRAM, respectively, on average across twelve real-world applications. Proteus incurs low area cost on top of a DRAM chip (1.6%) and CPU die (0.03%).