Lana Josipović, Axel Marmet, Andrea Guerrieri, P. Ienne
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引用次数: 0
Abstract
To achieve resource-efficient hardware designs, high-level synthesis tools share (i.e., time-multiplex) functional units among operations of the same type. This optimization is typically performed in conjunction with operation scheduling to ensure the best possible unit usage at each point in time. Dataflow circuits have emerged as an alternative HLS approach to efficiently handle irregular and control-dominated code. However, these circuits do not have a predetermined schedule—in its absence, it is challenging to determine which operations can share a functional unit without a performance penalty. More critically, although sharing seems to imply only some trivial circuitry, time-multiplexing units in dataflow circuits may cause deadlock by blocking certain data transfers and preventing operations from executing. In this paper, we present a technique to automatically identify performance-acceptable resource sharing opportunities in dataflow circuits. More importantly, we describe a sharing mechanism which achieves functionally correct and deadlock-free dataflow designs. On a set of benchmarks obtained from C code, we show that our approach effectively implements resource sharing. It results in significant area savings at a minor performance penalty compared to dataflow circuits which do not support this feature (i.e., it achieves a 64%, 2%, and 18% average reduction in DSPs, LUTs, and FFs, respectively, with an average increase in total execution time of only 2%) and matches the sharing capabilities of a state-of-the-art HLS tool.
期刊介绍:
TRETS is the top journal focusing on research in, on, and with reconfigurable systems and on their underlying technology. The scope, rationale, and coverage by other journals are often limited to particular aspects of reconfigurable technology or reconfigurable systems. TRETS is a journal that covers reconfigurability in its own right.
Topics that would be appropriate for TRETS would include all levels of reconfigurable system abstractions and all aspects of reconfigurable technology including platforms, programming environments and application successes that support these systems for computing or other applications.
-The board and systems architectures of a reconfigurable platform.
-Programming environments of reconfigurable systems, especially those designed for use with reconfigurable systems that will lead to increased programmer productivity.
-Languages and compilers for reconfigurable systems.
-Logic synthesis and related tools, as they relate to reconfigurable systems.
-Applications on which success can be demonstrated.
The underlying technology from which reconfigurable systems are developed. (Currently this technology is that of FPGAs, but research on the nature and use of follow-on technologies is appropriate for TRETS.)
In considering whether a paper is suitable for TRETS, the foremost question should be whether reconfigurability has been essential to success. Topics such as architecture, programming languages, compilers, and environments, logic synthesis, and high performance applications are all suitable if the context is appropriate. For example, an architecture for an embedded application that happens to use FPGAs is not necessarily suitable for TRETS, but an architecture using FPGAs for which the reconfigurability of the FPGAs is an inherent part of the specifications (perhaps due to a need for re-use on multiple applications) would be appropriate for TRETS.