Designing Efficient Processors Using Compiler-Directed Optimisations

Abstract

In the quest for greater performance, superscalar processor designers implement large issue queues and register files to take advantage of the out-of-order execution of the architecture. However, there is a trade-off to be made as performance gains are achieved at the cost of increased energy consumption. There comes a point where increasing the size of these structures is too costly in terms of energy. Recently proposed compiler-directed optimisations can be used to reduce this overhead. Conversely, for the same energy consumption, larger issue queues and register files can be used to increase performance. This paper considers the design space of issue queue and register file sizes in processors implementing a combination of issue queue throttling and early register releasing schemes under compiler control. Compared with the best baseline containing 64 issue queue entries and 96 integer registers, our scheme with a configuration of 80 entries and 80 registers can achieve an energydelay-squared (EDD) product of 0.952 without any loss of performance and no increase in energy consumption. The same configuration without compiler optimisations has a EDD product of 1.078, losing 3% performance. Furthermore, this scheme can be applied to a range of baseline processors allowing designers to achieve EDD products as low as 0.880 whilst still maintaining at least the same performance and energy budget