PhD ThesisMost modern platforms offer ample potention for parallel execution of concurrent programs yet concurrency control is required to exploit parallelism while maintaining program correctness. Pessimistic con-
currency control featuring blocking synchronization and mutual ex-
clusion, has given way to transactional memory, which allows the
composition of concurrent code in a manner more intuitive for the
application programmer. An important component in any transactional memory technique however is the policy for resolving conflicts
on shared data, commonly referred to as the contention management
policy.
In this thesis, a Universal Construction is described which provides
contention management for software transactional memory. The technique differs from existing approaches given that multiple execution
paths are explored speculatively and in parallel. In the resolution of
conflicts by state space exploration, we demonstrate that both concur-
rent conflicts and semantic conflicts can be solved, promoting multi-
threaded program progression.
We de ne a model of computation called Many Systems, which defines the execution of concurrent threads as a state space management
problem. An implementation is then presented based on concepts
from the model, and we extend the implementation to incorporate
nested transactions. Results are provided which compare the performance of our approach with an established contention management
policy, under varying degrees of concurrent and semantic conflicts. Finally, we provide performance results from a number of search strategies, when nested transactions are introduced