Relativistic programming

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Relativistic programming (RP) is a style of concurrent programming where instead of trying to avoid conflicts between readers and writers (or writers and writers in some cases) the algorithm is designed to tolerate them and get a correct result regardless of the order of events. Also, relativistic programming algorithms are designed to work without the presences of a global order of events. That is, there may be some cases where one thread sees two events in a different order than another thread (hence the term relativistic because in Einstein's theory of special relativity [ citation needed ] the order of events is not always the same to different viewers). This essentially implies working under causal consistency instead of a stronger model.

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Relativistic programming provides advantages in performance compared to other concurrency paradigms because it does not require one thread to wait for another nearly as often. Because of this, forms of it (Read-Copy-Update for instance) are now used extensively in the Linux kernel (over 18,000 times as of April 2021 and has grown from nothing to 11.8% of all locking primitives in just under two decades). [1]

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References

  1. Paul E. McKenney. "RCU Linux Usage". www.rdrop.com. Retrieved 2021-08-28.