1 research outputs found
Dynamic deployment of web services on the internet or grid
PhD ThesisThis thesis focuses on the area of dynamic Web Service deployment for grid and
Internet applications. It presents a new Dynamic Service Oriented Architecture
(DynaSOAr) that enables the deployment of Web Services at run-time in response to
consumer requests.
The service-oriented approach to grid and Internet computing is centred on two
parties: the service provider and the service consumer. This thesis investigates the
introduction of mobility into this service-oriented approach allowing for better use of
resources and improved quality of service. To this end, it examines the role of the
service provider and makes the case for a clear separation of its concerns into two
distinct roles: that of a Web Service Provider, whose responsibility is to receive and
direct consumer requests and supply service implementations, and a Host Provider,
whose role is to deploy services and process consumers' requests on available
resources. This separation of concerns breaks the implicit bond between a published
Web Service endpoint (network address) and the resource upon which the service is
deployed. It also allows the architecture to respond dynamically to changes in service
demand and the quality of service requirements. Clearly defined interfaces for each
role are presented, which form the infrastructure of DynaSOAr. The approach taken
is wholly based on Web Services.
The dynamic deployment of service code between separate roles, potentially running
in different administrative domains, raises a number of security issues which are
addressed. A DynaSOAr service invocation involves three parties: the requesting
Consumer, a Web Service Provider and a Host Provider; this tripartite relationship
requires a security model that allows the concerns of each party to be enforced for a
given invocation. This thesis, therefore, presents a Tripartite Security Model and an
architecture that allows the representation, propagation and enforcement of three
separate sets of constraints.
A prototype implementation of DynaSOAr is used to evaluate the claims made, and
the results show that a significant benefit in terms of round-trip execution time for
data-intensive applications is achieved. Additional benefits in terms of parallel
deployments to satisfy multiple concurrent requests are also shown