General information
Organisation
The French Alternative Energies and Atomic Energy Commission (CEA) is a key player in research, development and innovation in four main areas :
• defence and security,
• nuclear energy (fission and fusion),
• technological research for industry,
• fundamental research in the physical sciences and life sciences.
Drawing on its widely acknowledged expertise, and thanks to its 16000 technicians, engineers, researchers and staff, the CEA actively participates in collaborative projects with a large number of academic and industrial partners.
The CEA is established in ten centers spread throughout France
Reference
2024-31188
Division description
The CEA (French Commission for Atomic and Renewable Energy) is a public research institute. It plays an important role in the research, development and innovation community. The CEA has four missions: security and defense, nuclear energy (fission and fusion), technology research for industry and fundamental research. With 16 000 employees, including technicians, engineers, researchers and support personnel, the CEA is involved in numerous research projects in collaboration with both academic and industrial partners.
Description de l'unité
In the section of the CEA focused on technology research for industry, the LIST institute is focused on intelligent digital systems. This institute has a culture of innovation and has as a mission to transfer these technologies to industrial partners. The DSCIN division specializes in complex digital and embedded systems for Artificial Intelligence (AI), High-Performance Computing (HPC) and Cyber security applications.
The focus of the LECA laboratory is the design of flexible on-chip architectures which provide high performance, energy efficiency and security. The emphasis is on secure embedded systems and AI accelerators (DNNs/CNNs). This lab is located in the Paris region (Palaiseau).
Position description
Category
Electronics components and equipments
Contract
Fixed-term contract
Job title
PhD Position in AI-Assisted Generation of High-Level Models and Simulators for Hardware Design
Socio-professional category
Non Cadre
Contract duration (months)
36
Job description
Simulation tools are essential for the design and validation of digital circuits. They use different levels of abstraction to facilitate hardware/software co-design and co-validation. Architecture simulators, called Instruction Set Simulators (ISSs), provide high-level abstraction for fast functional verification and early design space exploration, while Register Transfer Level (RTL) simulators provide detailed circuit-level implementation for accurate analysis but with longer simulation times.
Faced with accelerated development schedules together with tool and resource constraints, hardware designers often start with RTL development and defer the construction of an ISS. However, as the design process progresses, the need to create ISSs becomes apparent, particularly for tasks such as software validation and design space exploration of next-generation hardware.
Creating ISSs manually presents significant challenges, as it is both time-consuming and error-prone. Further complexity is introduced by the need to ensure equivalence between ISS and RTL. There is therefore an urgent need for innovative methods to automate the generation of an ISS when the RTL is available.
The generation process of an ISS consists mainly of extracting architectural states and deriving instruction execution functions [1, 2]. An ISS is then constructed by seamlessly integrating the architectural states and the instruction execution functions, ensuring an accurate representation of the hardware's functional behaviour.
The goal of the thesis is to design a methodology implemented in a tool that takes low-level RTL models as input and automatically generates an ISS by exploiting recent advances in machine learning (ML) such as Graph Neural Networks [3], and compilation flows such as MLIR [4], in the field of electronic design automation (EDA). The expected result is a complete flow for the automatic generation of ISS from RTL, ensuring by construction the semantic consistency between the two levels.
The results of this thesis will be the subject of presentations at international conferences and in scientific journals.
References
[1] Zeng, Yu, Aarti Gupta, and Sharad Malik. "Generating architecture-level abstractions from RTL designs for processors and accelerators part I: Determining architectural state variables." ICCAD, 2021.
[2] Zeng, Yu, Aarti Gupta, and Sharad Malik. "Automatic generation of architecture-level models from RTL designs for processors and accelerators." DATE, 2022.
[3] Chowdhury, Subhajit Dutta, Kaixin Yang, and Pierluigi Nuzzo. "ReIGNN: State register identification using graph neural networks for circuit reverse engineering." ICCAD, 2021.
[4] Lattner, Chris, et al. "MLIR: Scaling compiler infrastructure for domain specific computation." CGO, 2021.
Applicant Profile
- Master's degree in Computer Science/Electronics.
- Good experience/knowledge in Machine Learning.
- Experience/knowledge in digital electronics design.
- Excellent programming skills in Python and C++. Proficiency in VHDL and/or Verilog programming will be a plus.
- Good analytical and experimental skills will be highly valued.
In accordance with the commitments made by the CEA in favor of the integration of people with disabilities, this job is open to everyone.
Position location
Site
Saclay
Job location
France, Ile-de-France, Essonne (91)
Location
Palaiseau
Requester
Position start date
01/10/2024