Overview of Hydra: a concurrent language for synchronous digital circuit design

Hydra is a computer hardware description language that integrates several kinds of software tool (simulation, netlist generation and timing analysis) within a single circuit specification. The design language is inherently concurrent, and it offers black box abstraction and general design patterns that simplify the design of circuits with regular structure. Hydra specifications are concise, allowing the complete design of a computer system as a digital circuit within a few pages. This paper discusses the motivations behind Hydra, and illustrates the system with a significant portion of the design of a basic RISC processor

The Challenges of Hardware Synthesis from C-like Languages

The relentless increase in the complexity of integrated circuits we can fabricate imposes a continuing need for ways to describe complex hardware succinctly. Because of their ubiquity and flexibility, many have proposed to use the C and C++ languages as specification languages for digital hardware. Yet, tools based on this idea have seen little commercial interest. In this paper, I argue that C/C++ is a poor choice for specifying hardware for synthesis and suggest a set of criteria that the next successful hardware description language should have

The SANDRA project: cooperative architecture/compiler technology for embedded real-time streaming applications

The convergence of digital television, Internet access, gaming, and digital media capture and playback stresses the importance of high-quality and high-performance video and graphics processing. The SANDRA project, a collaboration between Philips Research and INRIA, develops a consistent and efficient system design approach for regular, real-time constrained stream processing. The project aims at providing a system template with its associated compiler chain and application development framework, enabling an early validation of both the functional and the non-functional requirements of the application at every system design stage

A Survey and Evaluation of FPGA High-Level Synthesis Tools

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 field-programmable gate array 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 the use of resources

A Behavioral Design Flow for Synthesis and Optimization of Asynchronous Systems

Asynchronous or clockless design is believed to hold the promise of alleviating many of the challenges currently facing microelectronic design. Distributing a high-speed clock signal across an entire chip is an increasing challenge, particularly as the number of transistors on chip continues to rise. With increasing heterogeneity in massively multi- core processors, the top-level system integration is already elastic in nature. Future computing technologies (e.g., nano, quantum, etc.) are expected to have unpredictable timing as well. Therefore, asynchronous design techniques are gaining relevance in mainstream design. Unfortunately, the field of asynchronous design lacks mature design tools for creating large-scale, high-performance or energy-efficient systems. This thesis attempts to fill the void by contributing a set of design methods and automated tools for synthesizing asynchronous systems from high-level specifications. In particular, this thesis provides methods and tools for: (i) generating high-speed pipelined implementations from behavioral specifications, (ii) sharing and scheduling resources to conserve area while providing high performance, and (iii) incorporating energy and power considerations into high-level design. These methods are incorporated into a comprehensive design flow that provides a choice of synthesis paths to the designer, and a mechanism to explore the spectrum between them. The first path specifically targets the highest-performance implementations using data-driven pipelined circuits. The second path provides an alternative approach that targets low-area implementations, providing for optimal resource sharing and optimal scheduling techniques to achieve performance targets. Finally, the third path through the design flow allows the entire spectrum between the two extremes to be explored. In particular, it is a hybrid approach that preserves a pipelined architecture but still allows sharing of resources. By varying performance targets, a wide range of designs can be realized. A variety of metrics are incorporated as constraints or cost functions: area, latency, cycle time, energy consumption, and peak power. Experimental results demonstrate the capability of the proposed design flow to quickly produce optimized specifications. By automating synthesis and optimization, this thesis shows that the designer effort necessary to produce a high-quality solution can be significantly reduced. It is hoped that this work provides a path towards more mature automation and design tools for asynchronous design

A visual programming model to implement coarse-grained DSP applications on parallel and heterogeneous clusters

International audienceThe digital signal processing (DSP) applications are one of the biggest consumers of computing. They process a big data volume which is represented with a high accuracy. They use complex algorithms, and must satisfy a time constraints in most of cases. In the other hand, it's necessary today to use parallel and heterogeneous architectures in order to speedup the processing, where the best examples are the su-percomputers "Tianhe-2" and "Titan" from the top500 ranking. These architectures could contain several connected nodes, where each node includes a number of generalist processor (multi-core) and a number of accelerators (many-core) to finally allows several levels of parallelism. However, for DSP programmers, it's still complicated to exploit all these parallelism levels to reach good performance for their applications. They have to design their implementation to take advantage of all heteroge-neous computing units, taking into account the architecture specifici-ties of each of them: communication model, memory management, data management, jobs scheduling and synchronization . . . etc. In the present work, we characterize DSP applications, and based on their distinctive-ness, we propose a high level visual programming model and an execution model in order to drop down their implementations and in the same time make desirable performances