%0 Conference Paper %1 5260570 %A Usui, Takayuki %A Behrends, Reimer %A Evans, Jacob %A Smaragdakis, Yannis %B Parallel Architectures and Compilation Techniques, 2009. PACT '09. 18th International Conference on %D 2009 %K Combination Composition Concurrency Locks Performance Transactions %P 3--14 %R 10.1109/PACT.2009.20 %T Adaptive Locks: Combining Transactions and Locks for Efficient Concurrency %U http://transact09.cs.washington.edu/6_paper.pdf %X Transactional memory is being advanced as an alternative to traditional lock-based synchronization for concurrent programming. Transactional memory simplifies the programming model and maximizes concurrency. At the same time, transactions can suffer from interference that causes them to often abort, from heavy overheads for memory accesses, and from expressiveness limitations (e.g., for I/O operations). In this paper we propose an adaptive locking technique that dynamically observes whether a critical section would be best executed transactionally or while holding a mutex lock. The critical new elements of our approach include the adaptivity logic and cost-benefit analysis, a low overhead implementation of statistics collection and adaptive locking in a full C compiler, and an exposition of the effects on the programming model. In experiments with both micro and macro-benchmarks we found adaptive locks to consistently match or out perform the better of the two component mechanisms (mutexes or transactions). Compared to either mechanism alone, adaptive locks often provide 3-to-10x speedups. Additionally, adaptive locks simplify the programming model by reducing the need for fine-grained locking: with adaptive locks, the programmer can specify coarse-grained locking annotations and often achieve fine-grained locking performance due to the transactional memory mechanisms.

@inproceedings{5260570, abstract = {Transactional memory is being advanced as an alternative to traditional lock-based synchronization for concurrent programming. Transactional memory simplifies the programming model and maximizes concurrency. At the same time, transactions can suffer from interference that causes them to often abort, from heavy overheads for memory accesses, and from expressiveness limitations (e.g., for I/O operations). In this paper we propose an adaptive locking technique that dynamically observes whether a critical section would be best executed transactionally or while holding a mutex lock. The critical new elements of our approach include the adaptivity logic and cost-benefit analysis, a low overhead implementation of statistics collection and adaptive locking in a full C compiler, and an exposition of the effects on the programming model. In experiments with both micro and macro-benchmarks we found adaptive locks to consistently match or out perform the better of the two component mechanisms (mutexes or transactions). Compared to either mechanism alone, adaptive locks often provide 3-to-10x speedups. Additionally, adaptive locks simplify the programming model by reducing the need for fine-grained locking: with adaptive locks, the programmer can specify coarse-grained locking annotations and often achieve fine-grained locking performance due to the transactional memory mechanisms.}, added-at = {2015-02-19T15:57:14.000+0100}, author = {Usui, Takayuki and Behrends, Reimer and Evans, Jacob and Smaragdakis, Yannis}, biburl = {https://www.bibsonomy.org/bibtex/2fc5edb204f0da7b46b964e4a4dbaec10/gron}, booktitle = {Parallel Architectures and Compilation Techniques, 2009. PACT '09. 18th International Conference on}, description = {IEEE Xplore Abstract - Adaptive Locks: Combining Transactions and Locks for Efficient Concurrency}, doi = {10.1109/PACT.2009.20}, interhash = {79a3f1326c5746e79f5248dadf612519}, intrahash = {fc5edb204f0da7b46b964e4a4dbaec10}, issn = {1089-795X}, keywords = {Combination Composition Concurrency Locks Performance Transactions}, month = {Sept}, pages = {3--14}, timestamp = {2015-02-19T15:57:14.000+0100}, title = {Adaptive Locks: Combining Transactions and Locks for Efficient Concurrency}, url = {http://transact09.cs.washington.edu/6_paper.pdf}, year = 2009 }