An Automated High-Level Design Framework for Partially Reconfigurable FPGAs

Modern field-programmable gate arrays (FPGAs) allow runtime partial reconfiguration (PR) of the FPGA, enabling PR benefits such as runtime adaptability and extensibility, and reduces the application's area requirement. However, PR application development requires non-traditional expertise and lengthy design time effort. Since high-level synthesis (HLS) languages afford fast application development time, these languages are becoming increasingly popular for FPGA application development. However, widely used HLS languages, such as C variants, do not contain PR-specific constructs, thus exploiting PR benefits using an HLS language is a challenging task. To alleviate this challenge, we present an automated high-level design framework -- PaRAT (partial reconfiguration amenability test). PaRAT parses, analyzes, and partitions an application's HLS code to generate the application's PR architectures, which contain the application's runtime modifiable modules and thus, allows the application's runtime reconfiguration. Case study analysis demonstrates PaRAT's ability to quickly and automatically generate PR architectures from an application's HLS code.