To improve performance and reduce power, processor designers employ advances that shrink feature sizes, lower voltage levels, reduce noise margins, and increase clock rates. However, these advances make processors more susceptible to transient faults that can affect correctness. While reliable systems typically employ hardware techniques to address soft-errors, software techniques can provide a lower-cost and more flexible alternative. This paper presents a novel, software-only, transient-fault-detection technique, called SWIFT. SWIFT efficiently manages redundancy by reclaiming unused instruction-level resources present during the execution of most programs. SWIFT also provides a high level of protection and performance with an enhanced control-flow checking mechanism. We evaluate an implementation of SWIFT on an Itanium 2 which demonstrates exceptional fault coverage with a reasonable performance cost. Compared to the best known single-threaded approach utilizing an ECC memory system, SWIFT demonstrates a 51% average speedup.
Despite the success of instruction-level parallelism (ILP) optimizations in increasing the performance of microprocessors, certain codes remain elusive. In particular, codes containing recursive data structure (RDS) traversal loops have been largely immune to ILP optimizations, due to the fundamental serialization and variable latency of the loop-carried dependence through a pointer-chasing load.To address these and other situations, we introduce decoupled software pipelining (DSWP), a technique that statically splits a single-threaded sequential loop into multiple non-speculative threads, each of which performs useful computation essential for overall program correctness. The resulting threads execute on thread-parallel architectures such as simultaneous multithreaded (SMT) cores or chip multiprocessors (CMP), expose additional instruction level parallelism, and tolerate latency better than the original single-threaded RDS loop. To reduce overhead, these threads communicate using a synchronization array, a dedicated hardware structure for pipelined inter-thread communication. DSWP used in conjunction with the synchronization array achieves an 11% to 76% speedup in the optimized functions on both statically and dynamically scheduled processors.
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