This paper describes ongoing work aimed at the construction of formal cost models and analyses to yield verifiable guarantees of resource usage in the context of real-time embedded systems. Our work is conducted in terms of the domain-specific language Hume, a language that combines functional programming for computations with finitestate automata for specifying reactive systems. We outline an approach in which high-level information derived from source-code analysis can be combined with worst-case execution time information obtained from high quality abstract interpretation of low-level binary code
Advanced design techniques of safety-critical applications use specialized development model-based m...
Embedded real-time software systems (ESS) play an important role in almost every aspect of our daily...
International audienceThe worst case execution time (WCET) analysis allows to determine an upper bou...
This paper describes ongoing work aimed at the construction of formal cost models and analyses that ...
In order to safely construct time-critical systems, it is necessary to ensure that responses are pro...
Purpose: To construct an effective Worst-Case Execution Time analysis based on a formal semantics fo...
This chapter describes Hume: a functionally-based language for programming with bounded resource usa...
Advanced design techniques of safety-critical applications use specialized development model based m...
Our research focuses on formally bounded WCET analysis, where we aim to provide absolute guarantees ...
International audienceCritical embedded systems are generally composed of repetitive tasks that must...
Real-Time embedded systems must enforce strict timing constraints. In this context, achieving precis...
Our research focuses on formally bounded WCET analysis, where we aim to provide ab-solute guarantees...
In this article we give an overview of the Worst-Case Execution Time (WCET) analysis research perfor...
In a real-time system, it is crucial to ensure that all tasks of the system hold their deadlines. A ...
The scheduling of real-time systems requires knowing the Worst Case Execution Time (WCET) of their t...
Advanced design techniques of safety-critical applications use specialized development model-based m...
Embedded real-time software systems (ESS) play an important role in almost every aspect of our daily...
International audienceThe worst case execution time (WCET) analysis allows to determine an upper bou...
This paper describes ongoing work aimed at the construction of formal cost models and analyses that ...
In order to safely construct time-critical systems, it is necessary to ensure that responses are pro...
Purpose: To construct an effective Worst-Case Execution Time analysis based on a formal semantics fo...
This chapter describes Hume: a functionally-based language for programming with bounded resource usa...
Advanced design techniques of safety-critical applications use specialized development model based m...
Our research focuses on formally bounded WCET analysis, where we aim to provide absolute guarantees ...
International audienceCritical embedded systems are generally composed of repetitive tasks that must...
Real-Time embedded systems must enforce strict timing constraints. In this context, achieving precis...
Our research focuses on formally bounded WCET analysis, where we aim to provide ab-solute guarantees...
In this article we give an overview of the Worst-Case Execution Time (WCET) analysis research perfor...
In a real-time system, it is crucial to ensure that all tasks of the system hold their deadlines. A ...
The scheduling of real-time systems requires knowing the Worst Case Execution Time (WCET) of their t...
Advanced design techniques of safety-critical applications use specialized development model-based m...
Embedded real-time software systems (ESS) play an important role in almost every aspect of our daily...
International audienceThe worst case execution time (WCET) analysis allows to determine an upper bou...