Distributed operating systems

In the past five years, distributed operating systems research has gone through a consolidation phase. On a large number of design issues there is now considerable consensus between different research groups.\ud \ud In this paper, an overview of recent research in distributed systems is given. In turn, the paper discusses overall system structure, protection issues, file system designs, problems and solutions for fault tolerance and a mechanism that is rapidly becoming very important for efficient distributed systems design: hints.\ud \ud An attempt was made to provide sufficient references to interesting research projects for the reader to find material for more detailed study

Acquisition of computer research equipment

Issued as Final report, Project no. G-36-61

Approaches to Distributed UNIX Systems

This paper examines several approaches to developing a distributed version of the UNIX Operating system. Relevant UNIX concepts are introduced and brief overviews of a number of distributed UNIX implementations are provided. The major issues discussed are concurrency and file system architecture: 1. The multiprocessor designs examined have the common problem of implementing critical sections in the kernel; several approaches are studied. 2. The me system architectures studied reflect differing views as to how the UNIX name space should be implemented in a distributed environment, and what the names will refer to; the issue of transparency is central to both, and is examined in some detail

Fault tolerance distributed computing

Issued as Funds expenditure reports [nos. 1-4], Quarterly progress reports [nos. 1-3], and Final report, Project no. G-36-63

Transaction management in mobile multidatabases.

This dissertation studies transaction management in the mobile Multidatabase environment. That is, it studies the management of transactions within the context of the mobile and Multidatabase environments. Two new transaction management techniques for the mobile Multidatabase environment i.e., the PS and Semantic-PS techniques are proposed. These techniques define two now states (Disconnected and Suspended) to address the disconnectivity of the mobile user. A new Partial Global Serialization Graph algorithm is introduced to verify the isolation property of global transactions. This algorithm verifies the serializability of a global transaction by constructing a partial global serialization graph. This algorithm relies on the propagation of (serialization) information to ensure that the partial graph contains sufficient information to verify serializability of global transactions. The unfair treatment of mobile transactions due to their prolonged execution time is minimized through pre-serialization. Pre-serialization allows mobile transactions to establish their serialization order prior to completing their execution.The Internet and advances in wireless communication technology have transformed many facets of the computer environment. Virtual connectivity through the internet has lead to a new genre of software systems, i.e., cooperating autonomous systems---systems that cooperate with each other to provide extended services to the user. Multidatabase systems---a set of databases that cooperate with each other in order to provide a single logical view of the underlying information---is an example of such systems. Advances in wireless communication technology dictate that the services available to the wired user be made available to the mobile user.Finally, analytical evaluation and simulation is carried out to study the performance of these techniques and to compare their performance to that of the Kangaroo [DHB97] technique. Although the PS and Semantic-PS techniques enforce the isolation property, the evaluation results establish that the service time for these techniques in not significantly greater than that of the Kangaroo technique. In addition, the simulation establishes that pre-serialization effectively minimizes the unfair treatment of mobile transactions

A Nested Transaction Mechanism for LOCUS

A working implementation of nested transactions has been produced for LOCUS, an integrated distributed operating system which provides a high degree of network transparency. Several aspects of our mechanism are novel. First, the mechanism allows a transaction to access objects directly without regard to the location of the object. Second, processes running on behalf of a single transaction may be located at many sites. Thus there is no need to invoke a new transaction to perform processing or access objects at a remote site. Third, unlike other environments, LOCUS allows replication of data objects at more than one site in the network, and this capability is incorporated into the transaction mechanism. If the copy of an object that is currently being accessed becomes unavailable, it is possible to continue work by using another one of the replicated copies. Finally, an efficient orphan removal algorithm is presented, and the problem of providing continued operation during network partitions is addressed in detail