Transactional actors in cooperative information systems

Abstract

Transaction management in advanced distributed information systems is a very important issue under research scrutiny with many technical and open problems. Most of the research and development activities use conventional database technology to address this important issue. The transaction model presented in this thesis combines attractive properties of the actor model of computation with advanced database transaction concepts in an object-oriented environment to address transactional necessities of cooperative information systems. The novel notion of transaction tree in our model includes subtransactions as well as a rich collection of decision making, chronological ordering, and communication and synchronization constructs for them. Advanced concepts such as blocking/ non_blocking synchronization, vital and non_vital subtransactions , contingency transactions, temporal and value dependencies, and delegation are supported. Compensatable subtransactions are distinguished and early commit is accomplished in order to release resources and facilitate cooperative as well as longduration transactions. Automatic cancel procedures are provided to logically undo the effects of such commits if the global transaction fails. The complexity and semantics-orientation of advanced database applications is our main motivation to design and implement a high-level scripting language for the proposed transaction model. Database programming can gain in performance and problem-orientation if the semantic dependencies between transactions can be expressed directly. Simple and flexible mechanisms are provided for advanced users to query the databases, program their transactions accordingly, and accept weak forms of semantic coherence that allows for more concurrency. The transaction model is grafted onto the concurrent obj ect-oriented programming language Sather developed at UC Berkeley which has a nice high-level syntax, supports advanced obj ect-oriented concepts, and aims toward performance and reusability. W have augmented the language with distributed programming facilities and various types of message passing routines as well as advanced transactions management constructs . The thesis is organized in three parts. The first part introduces the problem, reviews state of the art, and presents the transaction model. The second part describes the scripting language and talks about implementation details. The third part presents the formal semantics of the transaction model using mathematical notations and concludes the thesis.