AbstractThe linear lambda calculus, where variables are restricted to occur in terms exactly once, has a very weak expressive power: in particular, all functions terminate in linear time. In this paper we consider a simple extension with natural numbers and a restricted iterator: only closed linear functions can be iterated. We show properties of this linear version of Gödel’s Tusing a closed reduction strategy, and study the class of functions that can be represented. Surprisingly, this linear calculus offers a huge increase in expressive power over previous linear versions of T, which are ‘closed at construction’ rather than ‘closed at reduction’. We show that a linear Twith closed reduction is as powerful as T
AbstractCombinatory logic claims to do the same work as λ-calculus but with a simpler language and a...
This article provides a survey of key papers that characterise computable functions, but also provid...
AbstractWe present an extension of the lambda-calculus with differential constructions. We state and...
The linear lambda calculus, where variables are restricted to occur in terms exactly once, has a ver...
AbstractThe linear lambda calculus, where variables are restricted to occur in terms exactly once, h...
The linear lambda calculus is very weak in terms of expressive power: in particular, all functions t...
Gödel’s System T is an extremely powerful calculus: essentially anything that we want to compute ca...
System is a linear λ-calculus with numbers and an iterator, which, although imposing linearity rest...
AbstractSystem L is a linear version of Gödel's System T, where the λ-calculus is replaced with a li...
System L is a linear λ-calculus with numbers and an iterator, which, although imposing linearity res...
We present a separated-linear lambda calculus based on a refinement of linear logic which allo...
AbstractA subsystem of linear logic, elementary linear logic, is defined and shown to represent exac...
International audienceIn this paper, we present the lambda-mu-and-or-calculus which at the typed lev...
We provide a computational definition of the notions of vector space andbilinear functions. We use t...
AbstractStarting from Girard’s seminal paper on light linear logic (LLL), a number of works investig...
AbstractCombinatory logic claims to do the same work as λ-calculus but with a simpler language and a...
This article provides a survey of key papers that characterise computable functions, but also provid...
AbstractWe present an extension of the lambda-calculus with differential constructions. We state and...
The linear lambda calculus, where variables are restricted to occur in terms exactly once, has a ver...
AbstractThe linear lambda calculus, where variables are restricted to occur in terms exactly once, h...
The linear lambda calculus is very weak in terms of expressive power: in particular, all functions t...
Gödel’s System T is an extremely powerful calculus: essentially anything that we want to compute ca...
System is a linear λ-calculus with numbers and an iterator, which, although imposing linearity rest...
AbstractSystem L is a linear version of Gödel's System T, where the λ-calculus is replaced with a li...
System L is a linear λ-calculus with numbers and an iterator, which, although imposing linearity res...
We present a separated-linear lambda calculus based on a refinement of linear logic which allo...
AbstractA subsystem of linear logic, elementary linear logic, is defined and shown to represent exac...
International audienceIn this paper, we present the lambda-mu-and-or-calculus which at the typed lev...
We provide a computational definition of the notions of vector space andbilinear functions. We use t...
AbstractStarting from Girard’s seminal paper on light linear logic (LLL), a number of works investig...
AbstractCombinatory logic claims to do the same work as λ-calculus but with a simpler language and a...
This article provides a survey of key papers that characterise computable functions, but also provid...
AbstractWe present an extension of the lambda-calculus with differential constructions. We state and...