Miniphases: Compilation using Modular and Efficient Tree Transformations

Production compilers commonly perform dozens of transformations on an intermediate representation. Running those transformations in separate passes harms performance. One approach to recover performance is to combine transformations by hand in order to reduce number of passes. Such an approach harms modularity, and thus makes it hard to maintain and evolve a compiler over the long term, and makes reasoning about performance harder. This paper describes a methodology that allows a compiler writer to define multiple transformations separately, but fuse them into a single traversal of the intermediate representation when the compiler runs. This approach has been implemented in a compiler for the Scala language. Our performance evaluation indicates that this approach reduces the running time of tree transformations by 35% and shows that this is due to improved cache friendliness. At the same time, the approach improves total memory consumption by reducing the object tenuring rate by 50%. This approach enables compiler writers to write transformations that are both modular and fast at the same time.

Design and implementation of an optimizing type-centric compiler for a high-level language

Dmytro Petrashko

Production compilers for programming languages face multiple requirements. They should be correct, as we rely on them to produce code. They should be fast, in order to provide a good developer experience. They should also be easy to maintain and evolve. This thesis shows how an expressive high level type system can be used to simplify the development of a compiler and demonstrates this on a compiler for Scala. First, it shows how expressive types of high level languages can be used to build internal data structures that provide a statically checked API, ensuring that important properties hold at compile time. Second, we also show how high level language features can be used to abstract the components of a compiler. We demonstrate this by introducing a type-safe layer on top of the bytecode emission phase. This makes it possible to abstract away the implementation details of the compiler frontend and run the same bytecode emission phase in two different Scala compilers. Third, it presents MiniPhases, a novel way to organize transformation passes in a compiler. MiniPhases impose constraints on the organization of passes that are beneficial for maintainability, performance, and testability. We include a detailed performance evaluation of MiniPhases which indicates that their speedup is due to improved cache friendliness and to a lower rate of promotions of objects into the old generations of garbage collectors. Finally, we demonstrate how the expressive type system of the language being compiled can be used for static analysis. We present a novel call graph construction algorithm which uses the typing context for context sensitivity. The resulting algorithm is both substantially faster and more precise than existing alternatives. We demonstrate the applicability of this analysis by extending common subexpression elimination to idempotent expression elimination.

EPFL2017

Cross-Platform Language Design

Sébastien Jean R Doeraene

Programming languages are increasingly compiled to multiple runtimes, each featuring their own rich structures such as their object model. Furthermore, they need to interact with other languages targeting said runtimes. A language targeting only one runtime can be designed to tailor its semantics to those of that runtime, for easy interoperability with other languages. However, in a language targeting multiple runtimes with differing semantics, it is difficult to cater to each of them while retaining a common behavior across runtimes. We call \emph{cross-platform language} a language that aims at being both \emph{portable} across platforms and \emph{interoperable} with each target platform. Portability is the ability for a program or a library to cross-compile for multiple platforms, and behave the same way on all of them. Interoperability is the ability to communicate with other languages on the same platform. While many cross-compiling languages focus on one of these two properties---only adding support for the other one as an afterthought---, languages that are designed from the ground up to support both are rare. In this thesis, we present the design of Scala.js, the dialect of Scala targeting the JavaScript platform, which turned Scala into a cross-platform language. On the one hand, Scala programs can be cross-compiled for the JVM and JavaScript with portable semantics. On the other hand, whereas Scala/JVM interoperates with Java, Scala.js interoperates with JavaScript, allowing to use any JavaScript library. Along the dissertation, we give insights that can be transferred to the design of other cross-platform languages, although with a bias towards those targeting the JVM and JavaScript. The first and most obvious challenge is to reconcile the static nature of Scala's object model with JavaScript's dynamic one. Besides the ability to mutate a class hierarchy at run-time in JavaScript, there are fundamental differences between the two models, in particular the difference between compile-time overloading and run-time overloading. We discuss how such semantic mismatches can live in harmony within the language. The second challenge is to obtain good performance from a language where interoperability with a dynamic and unknown part of the program is pervasive. To that end, we design and specify an intermediate representation (IR) with first-class support for dynamically typed interoperability features in addition to statically typed JVM-style operations. Despite its tight integration with the open world of JavaScript, most of the IR can be considered as a closed world where advanced whole-program optimizations can be performed. The performance of the overall system is evaluated and shown to be competitive with hand-written JavaScript, and even with Scala/JVM in some cases.

EPFL2018

Cross-Platform Language Design

Sébastien Jean R Doeraene

EPFL2018

Design and implementation of an optimizing type-centric compiler for a high-level language

Dmytro Petrashko

EPFL2017