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Generating collaborative systems for digital libraries: A model-driven approach
This is an open access article shared under a Creative Commons Attribution 3.0 Licence (http://creativecommons.org/licenses/by/3.0/). Copyright @ 2010 The Authors.The design and development of a digital library involves different stakeholders, such as: information architects, librarians, and domain experts, who need to agree on a common language to describe, discuss, and negotiate the services the library has to offer. To this end, high-level, language-neutral models have to be devised. Metamodeling techniques favor the definition of domainspecific visual languages through which stakeholders can share their views and directly manipulate representations of the domain entities. This paper describes CRADLE (Cooperative-Relational Approach to Digital Library Environments), a metamodel-based framework and visual language for the definition of notions and services related to the development of digital libraries. A collection of tools allows the automatic generation of several services, defined with the CRADLE visual language, and of the graphical user interfaces providing access to them for the final user. The effectiveness of the approach is illustrated by presenting digital libraries generated with CRADLE, while the CRADLE environment has been evaluated by using the cognitive dimensions framework
Micro Virtual Machines: A Solid Foundation for Managed Language Implementation
Today new programming languages proliferate, but many of them
suffer from
poor performance and inscrutable semantics. We assert that the
root of
many of the performance and semantic problems of today's
languages is
that language implementation is extremely difficult. This
thesis
addresses the fundamental challenges of efficiently developing
high-level
managed languages.
Modern high-level languages provide abstractions over execution,
memory
management and concurrency. It requires enormous intellectual
capability
and engineering effort to properly manage these concerns.
Lacking such
resources, developers usually choose naive implementation
approaches
in the early stages of language design, a strategy which too
often has
long-term consequences, hindering the future development of the
language. Existing language development platforms have failed
to
provide the right level of abstraction, and forced implementers
to
reinvent low-level mechanisms in order to obtain performance.
My thesis is that the introduction of micro virtual machines will
allow
the development of higher-quality, high-performance managed
languages.
The first contribution of this thesis is the design of Mu, with
the
specification of Mu as the main outcome. Mu is
the first micro virtual machine, a robust, performant, and
light-weight
abstraction over just three concerns: execution, concurrency and
garbage
collection. Such a foundation attacks three of the most
fundamental and
challenging issues that face existing language designs and
implementations, leaving the language implementers free to focus
on the
higher levels of their language design.
The second contribution is an in-depth analysis of on-stack
replacement
and its efficient implementation. This low-level mechanism
underpins
run-time feedback-directed optimisation, which is key to the
efficient
implementation of dynamic languages.
The third contribution is demonstrating the viability of Mu
through
RPython, a real-world non-trivial language implementation. We
also did
some preliminary research of GHC as a Mu client.
We have created the Mu specification and its reference
implementation,
both of which are open-source. We show that that Mu's on-stack
replacement API can gracefully support dynamic languages such as
JavaScript, and it is implementable on concrete hardware. Our
RPython
client has been able to translate and execute non-trivial
RPython
programs, and can run the RPySOM interpreter and the core of the
PyPy
interpreter.
With micro virtual machines providing a low-level substrate,
language
developers now have the option to build their next language on a
micro
virtual machine. We believe that the quality of programming
languages
will be improved as a result
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