1. M. Voelter, J. Siegmund, T. Berger, B. Kolb.
Towards User-Friendly Projectional Editors (2014)
Proc. of the 7th Intl. Conf. on Software Language Engineering (SLE 2014), 20 pages, 2014
1. Markus Voelter
Generic Tools, Specific Languages (PhD thesis; 2014)
Generic Tools, Specific Languages (GTSL) is an approach for developing tools and applications in a way that supports easier and more meaningful adaptation to specific domains. To achieve this goal, GTSL generalizes programming language IDEs to domains traditionally not addressed by languages and IDEs. At its core, GTSL represents applications as documents/programs/models expressed with suitable languages. Application functionality is provided through an IDE that is aware of the languages and their semantics. The IDE provides editing support, and also directly integrates domain-specific analyses and execution services. Applications and their languages can be adapted to increasingly specific domains using language engineering; this includes developing incremental extensions to existing languages or creating additional, tightly integrated languages. Language workbenches act as the foundation on which such applications are built.
Get the book - http://voelter.de/books/
2. The MPS Language Workbench Volume I (as written on the main MPS page)
3. Federico Tomassetti
Polyglot software development (PhD thesis; 2014)
In the first part of this dissertation we study the adoption of modeling and domain specific languages. On the basis of an industrial survey we individuate a list of benefits attainable through these languages, how frequently they can be reached and which techniques permit to improve the chances to obtain a particular benefit. In the same way we study also the common problems which either prevent or hinder the adoption of these languages. We then analyze the processes through which these languages are employed, studying the relative frequency of the usage of the different techniques and the factors influencing it. Finally we present two case-studies performed in a small and in a very large company, with the intent of presenting the peculiarities of the adoption in different contexts.
4. M. Voelter, B. Kolb, J. Warmer
Projecting a Modular Future (Journal Paper, peer-reviewed, 2014)
IEEE Software, Volume & Issue still to be determined
4. Manuele Simi, Fabien Campagne
Composable languages for bioinformatics: the NYoSh experiment (Paper, 2013)
Language WorkBenches (LWBs) are software engineering tools that help domain experts develop solutions to various classes of problems. Some of these tools focus on non-technical users and provide languages to help organize knowledge while other workbenches provide means to create new programming languages. A key advantage of language workbenches is that they support the seamless composition of independently developed languages. This capability is useful when developing programs that can benefit from different levels of abstraction. We reasoned that language workbenches could be useful to develop bioinformatics software solutions. In order to evaluate the potential of language workbenches in bioinformatics, we tested a prominent workbench by developing an alternative to shell scripting. To illustrate what LWBs and Language Composition can bring to bioinformatics, we report on our design and development of NYoSh (Not Your ordinary Shell).
5. Václav Pech, Alexander Shatalin, Markus Voelter
JetBrains MPS as a Tool for Extending Java (Paper, 2013)
PDF - publish the pppj.pdf file attached to this document at jetbrains.com and link to it from here
JetBrains MPS is an integrated environment for language engineering. It allows language designers to define new programming languages, both general-purpose and domain-specific, either as standalone entities or as modular extensions of already existing ones. Since MPS leverages the concept of projectional editing, non-textual and non-parseable syntactic forms are possible, including tables or mathematical symbols. This tool paper introduces MPS and shows how its novel approach can be applied to Java development. Special attention will be paid to the ability to modularize and compose languages.
6. M. Voelter, D. Ratiu, B. Kolb, B. Schaetz, mbeddr
Instantiating a Language Workbench in the Embedded Systems Domain (2013)
Journal of Automated Software Engineering, September 2013, Volume 20, Issue 3, pp 339-390, 51 pages, 2013
6. DSL Engineering (as written on the main MPS page)
7. M. Voelter, D. Ratiu, B. Kolb, B. Schaetz.
mbeddr: an Extensible C-based Programming Language and IDE for Embedded Systems (2013)
Proc. of the 3rd annual conference on Systems, programming, and applications: software for humanity (SPLASH), ACM, pp 121-140, 20 pages, 2013
8. M. Voelter.
Language and IDE Modularization and Composition with MPS (2013)
International Summer School on Generative and Transformational Techniques in Software Engineering, GTTSE 2011, LNCS 7680, pp 383-430, 47 pages, 2013
7. Tomáš Fechtner
MPS-based Domain-specific Languages for real time Java development (Diploma thesis, 2012)
The Real-time Specification of Java (RTSJ) is an intention to introduce Java as a language for developing real-time system. However, the complexity of their development and a non-trivial programming model of RTSJ with its manual memory management often lead to programming errors. To mitigate the development of RTSJ systems it would be beneficial to provide an internal domain-specific language (DSL) extending the Java language which would allow to develop the systems in more intuitive and safer way. However, it is needed to find compromise between solution’s power and level of usability, because this two attributes go often against each other. One possible way of DSLs creation concerns the Meta-Programming System (MPS). It allows to develop new domain- specific languages and corresponding projectional editors enabling different views on code. This thesis proposes a design and implementation of the DSL on the top of the MPS platform and corresponding code generator enabling development of RTSJ systems. Furthermore, the thesis provides a simple case-study to evaluate a proposed DSL. Additionally, the thesis assesses the suitability of MPS as a DSL-development platform.
8. Markus Voelter, Eelco Visser.
Product Line Engineering with Projectional Language Workbenches (Paper, 2010)
This paper investigates the application of domainspecific languages in product line engineering (PLE). We start by analyzing the limits of expressivity of feature models. Feature models correspond to context-free grammars without recursion, which prevents the expression of multiple instances and references. We then show how domain-specific languages (DSLs) can serve as a middle ground between feature modeling and programming. They can be used in cases where feature models are too limited, while keeping the separation between problem space and solution space provided by feature models. We then categorize useful combinations between configuration with feature model and construction with DSLs and provide an integration of DSLs into the conceptual framework of PLE. Finally we show how use of a consistent, unified formalism for models, code, and configuration can yield important benefits for managing variability and traceability. We illustrate the concepts with several examples from industrial case studies.
9. Markus Voelter
Embedded Software Development with Projectional Language Workbenches (Paper, 2010)
This paper describes a novel approach to embedded software development. Instead of using a combination of C code and modeling tools, we propose an approach where modeling and programming is unified using projectional language workbenches. These allow the incremental, domain-specific extension of C and a seamless integration between the various concerns of an embedded system. The paper does not propose specific extensions to C in the hope that everybody will use them; rather, the paper illustrates the benefits of domain specific extension using projectional editors. In the paper we describe the problems with the traditional approach to embedded software development and how the proposed approach can solve them. The main part of the paper describes our modular embedded language, a proof-of-concept implementation of the approach based on JetBrains MPS. We implemented a set of language extensions for embedded programming, such as state machines, tasks, type system extensions as well as a domain specific language (DSL) for robot control. The language modules are seamlessly integrated, leading to a very efficient way for implementing embedded software.
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