Mighty-morphing power-SIMD

Abstract

In modern wireless devices, two broad classes of compute-intensive applications are common: those with high amounts of data-level parallelism, such as signal processing used in wireless baseband applications, and those that have little data-level parallelism, such as encryption. Wide single-instruction multiple-data (SIMD) processors have become popular for providing high performance, yet power efficient data engines for applications with abundant data parallelism. However, the non-data-parallel applications are relegated to a low-performance scalar datapath on these data engines while the SIMD resources are left idle. To accelerate both types of applications, we propose the design of a more flexible SIMD datapath called SIMD-Morph. In SIMD-Morph, code with data-level parallelism can be executed across the lanes in the traditional manner, but the lanes can be morphed into a feed-forward subgraph accelerator to execute scalar applications more efficiently. The morphed SIMD lanes form an accelerator that exploits both instruction-level parallelism as well as operation chaining to improve the performance of scalar code by exploiting the available resources in the SIMD lanes. Experimental results show that the performance impact is a 2.6X improvement for purely non-SIMD applications and a 1.4X improvement for the non-SIMD-ized portions of applications with data parallelism.