The compilation of synchronous block diagrams into sequential imperative code has been addressed in the early eighties and can now be considered as folklore. However, separate, or modular, code generation, though largely used in existing compilers and particularly in industrial ones, has never been precisely described or entirely formalized. Such a formalization is now fundamental in the long-term goal to develop a mathematically certified compiler for a synchronous language as well as in simplifying existing implementations. This article presents in full detail the modular compilation of synchronous block diagrams into sequential code. We consider a first-order functional language reminiscent of LUSTRE, which it extends with a general n-ary merge operator, a reset construct, and a richer notion of clocks. The clocks are used to express activation of computations in the program and are specifically taken into account during the compilation process to produce efficient imperative code. We introduce a generic machine-based intermediate language to represent transition functions, and we present a concise clock-directed translation from the source to this intermediate language. We address the target code generation phase by describing a translation from the intermediate language to JAVA and C.
Algebraic effects and handlers have received a lot of attention recently, both from the theoretical point of view and in practical language design. This stems from the fact that algebraic effects give the programmer unprecedented freedom to define, combine, and interpret computational effects. This plenty-of-rope, however, demands not only a deep understanding of the underlying semantics, but also access to practical means of reasoning about effectful code, including correctness and program equivalence. In this paper we tackle this problem by constructing a step-indexed relational interpretation of a call-by-value calculus with algebraic effect handlers and a row-based polymorphic type-and-effect system. Our calculus, while striving for simplicity, enjoys desirable theoretical properties, and is close to the cores of programming languages with algebraic effects used in the wild, while the logical relation we build for it can be used to reason about non-trivial properties, such as contextual equivalence and contextual approximation of programs. Our development has been fully formalised in the Coq proof assistant.
Handlers of algebraic effects aspire to be a practical and robust programming construct that allows one to define, use, and combine different computational effects. Interestingly, a critical problem that still bars the way to their popular adoption is how to combine different uses of the same effect in a program, particularly in a language with a static type-and-effect system. For example, it is rudimentary to define the "mutable memory cellž effect as a pair of operations, put and get, together with a handler, but it is far from obvious how to use this effect a number of times to operate a number of memory cells in a single context. In this paper, we propose a solution based on lexically scoped effects in which each use (an "instancež) of an effect can be singled out by name, bound by an enclosing handler and tracked in the type of the expression. Such a setting proves to be delicate with respect to the choice of semantics, as it depends on the explosive mixture of effects, polymorphism, and reduction under binders. Hence, we devise a novel approach to Kripke-style logical relations that can deal with open terms, which allows us to prove the desired properties of our calculus. We formalise our core results in Coq, and introduce an experimental surface-level programming language to show that our approach is applicable in practice.
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