Răzvan Nane scite author profile

Abstract-High-level synthesis (HLS) is increasingly popular for the design of high-performance and energy-efficient heterogeneous systems, shortening time-to-market and addressing today's system complexity. HLS allows designers to work at a higher-level of abstraction by using a software program to specify the hardware functionality. Additionally, HLS is particularly interesting for designing FPGA circuits, where hardware implementations can be easily refined and replaced in the target device. Recent years have seen much activity in the HLS research community, with a plethora of HLS tool offerings, from both industry and academia. All these tools may have different input languages, perform different internal optimizations, and produce results of different quality, even for the very same input description. Hence, it is challenging to compare their performance and understand which is the best for the hardware to be implemented. We present a comprehensive analysis of recent HLS tools, as well as overview the areas of active interest in the HLS research community. We also present a first-published methodology to evaluate different HLS tools. We use our methodology to compare one commercial and three academic tools on a common set of C benchmarks, aiming at performing an in-depth evaluation in terms of performance and use of resources.

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OpenQL: A Portable Quantum Programming Framework for Quantum Accelerators

Khammassi

Ashraf

Someren

et al. 2021

J. Emerg. Technol. Comput. Syst.

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With the potential of quantum algorithms to solve intractable classical problems, quantum computing is rapidly evolving, and more algorithms are being developed and optimized. Expressing these quantum algorithms using a high-level language and making them executable on a quantum processor while abstracting away hardware details is a challenging task. First, a quantum programming language should provide an intuitive programming interface to describe those algorithms. Then a compiler has to transform the program into a quantum circuit, optimize it, and map it to the target quantum processor respecting the hardware constraints such as the supported quantum operations, the qubit connectivity, and the control electronics limitations. In this article, we propose a quantum programming framework named OpenQL, which includes a high-level quantum programming language and its associated quantum compiler. We present the programming interface of OpenQL, we describe the different layers of the compiler and how we can provide portability over different qubit technologies. Our experiments show that OpenQL allows the execution of the same high-level algorithm on two different qubit technologies, namely superconducting qubits and Si-Spin qubits. Besides the executable code, OpenQL also produces an intermediate quantum assembly code, which is technology independent and can be simulated using the QX simulator.

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DWARV 2.0: A CoSy-based C-to-VHDL hardware compiler

Nane

Sima

Olivier

et al. 2012

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On the Implementation of Computation-in-Memory Parallel Adder

Nguyen

Xie

Taouil

et al. 2017

IEEE Trans. VLSI Syst.

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Controlling a complete hardware synthesis toolchain with LARA aspects

Cardoso

Carvalho

Coutinho

et al. 2013

Microprocessors and Microsystems

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Răzvan Nane

A Survey and Evaluation of FPGA High-Level Synthesis Tools

OpenQL: A Portable Quantum Programming Framework for Quantum Accelerators

DWARV 2.0: A CoSy-based C-to-VHDL hardware compiler

On the Implementation of Computation-in-Memory Parallel Adder

Controlling a complete hardware synthesis toolchain with LARA aspects

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