In order to realize flexible optical access systems supporting various services in access networks, including passive optical networks (PONs), through agile development, network function virtualization (NFV) is being expanded from upper-layer management and control functions to physical-layer (PHY) functions. We have already demonstrated the real-time software implementation of 10G-EPON PHY on a general-purpose server with graphic processing units (GPUs). However, to realize desirable microservice architectures where functions are independently developed in each environment, function chaining with conventional inter-container communication schemes, such as transmission control protocol (TCP), incurs significant latency that hinders real-time physical-layer processing. In addition, no study has introduced the chaining of software-based PHY functions and upper-layer functions. The 64b/66b control functions are also problematic due to the serial processing, which adds control symbols to each frame that is input. This paper proposes low-latency function chaining in container environments along with parallelized 64b/66b implementation by separating bit shift operations of 2-bit header addition for fully softwarized 10G-EPON. In our inter-container transfer proposal, a shared data region is made available to the appropriate application when a processing completion notification flag is set in inter-container shared memory. A fully containerized optical line terminal (OLT) and optical network units (ONUs) are implemented and connected; throughput and round-trip latency are evaluated using standard Ethernet frames. Evaluation results show that our function chaining method offers low latency independent of transfer size and that our parallelized 64b/66b implementation method is 19 times faster than the conventional approach. Our containerized PON platform achieves round-trip latency of approximately 1 ms and theoretical 10G-EPON throughput performance of 8.7 Gb/s.