Pipeline frequency boosting: Hiding dual-ported block RAM latency using intentional clock skew

FPGAs are increasingly being used to implement many new applications, including pipelined processor designs. Designers often employ memories to communicate and pass data between these pipeline stages. However, one-cycle communication between sender and receiver is often required. To implement this read-immediately-after-write functionality, bypass registers are needed by most FPGA memory blocks. Read and write latencies to these memories and the bypass can limit clock frequencies, or require extra resources to further pipeline the bypass. Instead of further pipelining the bypass, this paper applies clock skew scheduling to memory write and read ports of a simple bypass circuit. We show that the clock skew provides an improved F_max without requiring the area overhead of the pipelined bypass. Many configurations of pipelined memory systems are implemented, and their speed and area compared to our design. Memory clock skew scheduling yields the best F_max of all techniques which preserve functionality, an improvement of 56% over the baseline clock speed, and 14% over the best conventional design. Furthermore, the suggested technique consumes 46% fewer resources than the next best performing technique.