Single-chip heterogeneous multiprocessors (SCHMs) are arising to meet the computational demands of portable and handheld devices. These computing systems are not fully custom designs traditionally targeted by the design automation community, general-purpose designs traditionally targeted by the computer architecture community, nor pure embedded designs traditionally targeted by the real-time community. An entirely new design philosophy will be needed for this hybrid class of computing. The programming of the device will be drawn from a narrower set of applications with execution that persists in the system over a longer period of time than for general-purpose programming. However, the devices will still be programmable, not only at the level of the individual processing element, but across multiple processing elements and even the entire chip. The design of other programmable single chip computers has enjoyed an era where the design tradeoffs could be captured in simulators such as SimpleScalar and performance could be evaluated to the SPEC benchmarks. Motivated by this, we describe new benchmark-based design strategies for SCHMs which we refer to as scenario-oriented design. We include an example and results.Index Terms-Benchmarking, design methodology, heterogeneous multiprocessor, modeling, scenario-oriented design, systemon-chip (SOC).
As System On a Chip (SoC) designs become more like Programmable Heterogeneous Multiprocessors (PHMs), the highest levels of design will place emphasis on the custom design of elements that were traditionally associated with systems in the large. We motivate how schedulers that make dynamic, datadependent decisions at run-time will be key design elements in PHM SoCs. Starting from a fundamental model, the role schedulers play in PHMs is developed. Model-based scheduling is introduced as an approach to designing schedulers that optimize a PHM's performance. Due to the complexity of the PHM design space, convergence on optimal design requires high-level modeling and simulation. In model-based scheduling, high-level models of scheduling decisions result in actual design elements that appear in real systems. Experiments for a simple two-processor PHM that does a mix of image and text compression are included. Results show the effectiveness of model-based scheduling.
Emerging single-chip heterogeneous multiprocessors feature hundreds of design elements contending for shared resources, making it difficult to isolate performance impacts of individual design changes. This work is the first to parameterize shared resource accesses in the form of access attributes, summarizing the impact of shared resource contention on system performance, analogous to the way RTL parameters summarize more detailed transistor models. The intuition behind access attributes is that much application and architecture dependent contention information is known during detailed cycle-accurate simulations, and would be useful to inform a higher level model. The detailed contention information is sampled from a short cycle-accurate simulation, "training" a high-level statistical regression model of contention. This contention model can then be used in simulation to estimate the impact of shared resource accesses at a high level of abstraction, enabling the designers to explore contention-related performance impacts of design decisions. Using the access attribute-based contention models resulted in speedups of 40X over cycle-accurate simulation, with average simulation errors of less than 1% with 95% confidence intervals of about ±3%.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.