论文信息 - GA-MAP: An Error Tolerant Address Mapping Method in Data Center Networks Based on Improved Genetic Algorithm

GA-MAP: An Error Tolerant Address Mapping Method in Data Center Networks Based on Improved Genetic Algorithm

Address configuration is a key problem in data center networks. The core issue of automatic address configuration is assigning logical addresses to the physical network according to a blueprint, namely logical-to-device ID mapping, which can be formulated as a graph isomorphic problem and is hard. Recently years, some work has been proposed for this problem, such as DAC and ETAC. DAC adopts a sub-graph isomorphic algorithm. By leveraging the structure characteristic of data center network, DAC can finish the mapping process quickly when there is no malfunction. However, in the presence of any malfunctions, DAC need human effort to correct these malfunctions and thus is time-consuming. ETAC improves on DAC and can finish mapping even in the presence of malfunctions. However, ETAC also suffers from some robustness and efficiency problems. In this paper, we present GA-MAP, a data center networks address mapping algorithm based on genetic algorithm. By intelligently leveraging the structure characteristic of data center networks and the global search characteristic of genetic algorithm, GA-MAP can solve the address mapping problem quickly. Moreover, GA-MAP can even finish address mapping when physical network involved in malfunctions, making it more robust than ETAC. We evaluate GA-MAP via extensive simulation in several of aspects, including computation time, error-tolerance, convergence characteristic and the influence of population size. The simulation results demonstrate that GA-MAP is effective for data center addresses mapping. key words: data center networks, address mapping, graph isomorphic, genetic algorithm

[1] Xingyu Ma,et al. Error Tolerant Address Configuration for Data Center Networks with Malfunctioning Devices , 2012, 2012 IEEE 32nd International Conference on Distributed Computing Systems.

[2] Haitao Wu,et al. BCube: a high performance, server-centric network architecture for modular data centers , 2009, SIGCOMM '09.

[3] D. West. Introduction to Graph Theory , 1995 .

[4] Lei Shi,et al. Dcell: a scalable and fault-tolerant network structure for data centers , 2008, SIGCOMM '08.

[5] C. Wills. Principles of Population Genetics, 4th edition , 2007 .

[6] Hans-Paul Schwefel,et al. Evolution and optimum seeking , 1995, Sixth-generation computer technology series.

[7] Amin Vahdat,et al. A scalable, commodity data center network architecture , 2008, SIGCOMM '08.

[8] Ralph E. Droms,et al. Dynamic Host Configuration Protocol , 1993, RFC.

[9] Amin Vahdat,et al. PortLand: a scalable fault-tolerant layer 2 data center network fabric , 2009, SIGCOMM '09.

[10] Haitao Wu,et al. Generic and automatic address configuration for data center networks , 2010, SIGCOMM 2010.

[11] Bin Liu,et al. Automatically configuring the network layer of data centers for cloud computing , 2011, IBM J. Res. Dev..

[12] Stuart Cheshire,et al. Dynamic Configuration of IPv4 Link-Local Addresses , 2005, RFC.

[13] Dorothea Heiss-Czedik,et al. An Introduction to Genetic Algorithms. , 1997, Artificial Life.