[1] ITU-D ICT. Measuring digital development:facts and figures[R/OL]. Geneva:ITU, 2020:1-19(2020-06-10)[2021-01-05]. https://www.itu.int/en/ITU-D/Statistics/Documents/facts/FactsFigures2020.pdf. [2] Clement J. Number of worldwide Internet hosts in the domain name system from 1993 to 2019[R/OL]. Hamburg:Statista, 2020:1-10(2020-05-15)[2021-01-05]. https://www.statista.com/statistics/264473/number-of-internet-hosts-in-the-domain-name-system/. [3] Ibhaze A E, Okoyeigbo O, Samson U A, et al. Performance evaluation of IPv6 and IPv4 for future technologies[C]//Future of Information and Communication Conference. Cham:Springer, 2020:15-22. [4] Li Junfeng, Li Dan, Huang Yukai, et al. Quick NAT:high performance NAT system on commodity platforms[C]//International Symposium on Local and Metropolitan Area Networks (LANMAN). Osaka:IEEE, 2017:1-2. [5] Pickard J, Mark A, Dale D. IPv6 diffusion milestones:assessing the quantity and quality of adoption[J]. Journal of International Technology and Information Management, 2019, 28(1):2-28. [6] Miano S, Bertrone M, Risso F, et al. Securing Linux with a faster and scalable iptables[J]. ACM SIGCOMM Computer Communication Review, 2019, 49(3):2-17. [7] 王程, 徐玭, 张素兵, 等. 基于Linux系统的LEO卫星动态路由协议研究与实现[J]. 北京邮电大学学报, 2020, 43(2):94-102. Wang Cheng, Xu Pin, Zhang Subing, et al. Research and implementation of dynamic routing protocol for LEO satellites based on Linux system[J]. Journal of Beijing University of Posts and Telecommunications, 2020, 43(2):94-102. [8] Yang Mingming, Wang Zheng. Study and implementation of algorithm to dynamic improvement of performance of netfilter[J]. Computer Technology and Development, 2010, 20(4):163-166. [9] Ntop. PF_RING:high-speed packet capture, filtering and analysis[R/OL]. Pisa:Ntop, 2020:1-1(2020-04-25)[2021-01-05]. https://www.ntop.org/products/packet-capture/pf_ring. [10] Han S, Jang K, Park K, et al. PacketShader:a GPU-accelerated software router[J]. ACM SIGCOMM Computer Communication Review, 2010, 40(4):195-206. [11] Bonelli N, Di P A, Giordano S, et al. On multi-gigabit packet capturing with multi-core commodity hardware[C]//International Conference on Passive and Active Network Measurement. Vienna:Springer, 2012:64-73. [12] Zhang Tianzhu, Linguaglossa L, Gallo M, et al. FloWatcher-DPDK:lightweight line-rate flow-level monitoring in software[J]. IEEE Transactions on Network and Service Management, 2019, 16(3):1143-1156. [13] Chandrababu S, Bahulekar C, Yadav R, et al. Hardware-assisted flow monitoring for high speed networks[C]//10th International Conference on Computing, Communication and Networking Technologies (ICCCNT). Kanpur:IEEE, 2019:1-5. [14] Dally W, Turakhia Y, Han Song. Domain-specific hardware accelerators[J]. Communications of the ACM, 2020, 63(7):48-57. [15] Owaida M, Alonso G, Fogliarini L, et al. Lowering the latency of data processing pipelines through FPGA based hardware acceleration[J]. Proceedings of the VLDB Endowment, 2019, 13(1):71-85. [16] Wada R, Yamasaki N. Fast interrupt handling scheme by using interrupt wake-up mechanism[C]//Seventh International Symposium on Computing and Networking Workshops (CANDARW). Nagasaki:IEEE, 2019:109-114. [17] Zhang Wei, Liu Guyue, Zhang Wenhui, et al. OpenNetVM:a platform for high performance network service chains[C]//Workshop on Hot Topics in Middleboxes and Network Function Virtualization. Florianopolis:ACM, 2016:26-31. [18] Li Junfeng, Li Dan, Wu Wenfei, et al. Sphinx:a transport protocol for high-speed and lossy mobile networks[C]//38th International Performance Computing and Communications Conference (IPCCC). London:IEEE, 2019:1-8. [19] Wu Wenqing, Feng Xiao, Zhang Wenli, et al. MCC:a predictable and scalable massive client load generator[C]//International Symposium on Benchmarking, Measuring and Optimization. Denver:Springer, 2019:319-331. |