QUIC-FEC: Bringing the benefits of Forward Erasure Correction to QUIC
Title | QUIC-FEC: Bringing the benefits of Forward Erasure Correction to QUIC |
Publication Type | Conference Paper |
Year of Publication | 2019 |
Authors | Michel, François, De Coninck, Quentin, Bonaventure, Olivier |
Conference Name | 2019 IFIP Networking Conference (IFIP Networking) |
Publisher | IEEE |
ISBN Number | 978-3-903176-16-4 |
Keywords | composability, computer network reliability, computer network security, Convolutional codes, convolutional RLC error-correcting codes, error correction codes, Forward Erasure Correction, forward error correction, IETF, in-flight communications, interference (signal), Internet, loss-based congestion, Metrics, pubcrawl, QUIC, QUIC specification, QUIC-FEC, quick UDP Internet connections, Reed-Solomon codes, resilience, Resiliency, TCP/TLS/HTTP/2 stack, telecommunication congestion control, transport protocols, user datagram protocol, XOR codes |
Abstract | Originally implemented by Google, QUIC gathers a growing interest by providing, on top of UDP, the same service as the classical TCP/TLS/HTTP/2 stack. The IETF will finalise the QUIC specification in 2019. A key feature of QUIC is that almost all its packets, including most of its headers, are fully encrypted. This prevents eavesdropping and interferences caused by middleboxes. Thanks to this feature and its clean design, QUIC is easier to extend than TCP. In this paper, we revisit the reliable transmission mechanisms that are included in QUIC. More specifically, we design, implement and evaluate Forward Erasure Correction (FEC) extensions to QUIC. These extensions are mainly intended for high-delays and lossy communications such as In-Flight Communications. Our design includes a generic FEC frame and our implementation supports the XOR, Reed-Solomon and Convolutional RLC error-correcting codes. We also conservatively avoid hindering the loss-based congestion signal by distinguishing the packets that have been received from the packets that have been recovered by the FEC. We evaluate its performance by applying an experimental design covering a wide range of delay and packet loss conditions with reproducible experiments. These confirm that our modular design allows the protocol to adapt to the network conditions. For long data transfers or when the loss rate and delay are small, the FEC overhead negatively impacts the download completion time. However, with high packet loss rates and long delays or smaller files, FEC allows drastically reducing the download completion time by avoiding costly retransmission timeouts. These results show that there is a need to use FEC adaptively to the network conditions. |
URL | https://ieeexplore.ieee.org/document/8816838 |
DOI | 10.23919/IFIPNetworking.2019.8816838 |
Citation Key | michel_quic-fec_2019 |
- Metrics
- XOR codes
- user datagram protocol
- transport protocols
- telecommunication congestion control
- TCP/TLS/HTTP/2 stack
- Resiliency
- resilience
- Reed-Solomon codes
- quick UDP Internet connections
- QUIC-FEC
- QUIC specification
- QUIC
- pubcrawl
- composability
- loss-based congestion
- internet
- interference (signal)
- in-flight communications
- IETF
- forward error correction
- Forward Erasure Correction
- error correction codes
- convolutional RLC error-correcting codes
- Convolutional codes
- computer network security
- computer network reliability