Machine-dependent software

Porting is the process of converting an application from one architecture to another.[2] Software languages such as Java are designed so that applications can migrate across architectures without source code modifications. The term is applied when programming/equipment is changed to make it usable in a different architecture.

Code that does not operate properly on a specific system must be ported to another system.

Porting effort depends upon a few variables, including the degree to which the first environment (the source stage) varies from the new environment (the objective stage) and the experience of the creators in knowing platform-specific programming dialects.[3]

Many languages offer a machine independent intermediate code that can be processed by platform-specific interpreters to address incompatibilities.[4] The transitional representation characterises a virtual machine that can execute all modules written in the intermediate dialect. The intermediate code guidelines are interpreted into distinct machine code arrangements by a code generator to make executable code. The intermediate code may also be executed directly without static conversion into platform-specific code.[5]

• Port the translator. This can be coded in portable code.
• Adapt the source code to the new machine.
• Execute the adjusted source utilizing the translator with the code generator source as data. This will produce the machine code for the code generator.

Some application software is restricted to certain platforms.[6] Those who want an application to work on a non-native computer, port the app to a new platform.

• Virtual machine
• Java (programming language)
• Hardware-dependent software

• Agrawala, A. K., & Rauscher, T. G., 2014, Foundations of microprogramming: architecture, software, and applications, Academic press
• Huang, J., Li, Y. F., & Xie, M., 2015, An empirical analysis of data preprocessing for machine learning-based software cost estimation, Information and Software Technology, 67, 108-127
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• Lin, S. W., & Ying, K. C., 2014, ABC-based manufacturing scheduling for unrelated parallel machines with machine-dependent and job sequence-dependent setup times, Computers & Operations Research, 51, 172-181
• Mathur, R., Miles, S., & Du, M., 2015, Adaptive Automation: Leveraging Machine Learning to Support Uninterrupted Automated Testing of Software Applications, arXiv preprint arXiv:1508.00671
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• Röhrich, T., & Welfonder, E., 2014, Machine Independent Software Wiring and Programming of Distributed Digital Control Systems, In Digital Computer Applications to Process Control: Proceedings of the 7th IFAC/IFIP/IMACS Conference, Vienna, Austria, 17–20 September 1985 (p. 247), Elsevier
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• Yin, Y., Liu, M., Hao, J., & Zhou, M., 2012, Sin