[16] | 1 | % les objectifs globaux, |
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[89] | 2 | The market of digital systems is about 4,600 M\$ today and is estimated to |
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[68] | 3 | 5,600 M\$ in 2012. However the ever growing applications complexity involves |
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[97] | 4 | integration of heterogeneous technologies and requires the design of |
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[49] | 5 | complex Multi-Processors System on Chip (MPSoC). |
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[99] | 6 | \\ |
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[97] | 7 | During the last decade, the design of ASICs (Application Specific |
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[49] | 8 | Integrated Circuits) appeared to be more and more reserved to high volume markets, because |
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| 9 | the design and fabrication costs of such components exploded, due to increasing NRE (Non |
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| 10 | Recurring-Engineering) costs. |
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[97] | 11 | Fortunately, FPGA (Field Programmable Gate Array) components, such as the |
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[49] | 12 | Virtex5 family from \xilinx or the Stratix4 family from \altera, can nowadays |
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[97] | 13 | implement a complete MPSoC with multiple processors and several dedicated |
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[81] | 14 | coprocessors for a few keuros per device. |
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[49] | 15 | In addition, Electronic System Level (ESL) design methodologies (Virtual Prototyping, |
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| 16 | Co-design, High-Level Synthesis...) are now mature and allow the automation of |
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| 17 | a system level design flow that targets FPGA devices. |
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| 18 | We believe that coupling FPGA technologies and ESL methodologies |
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| 19 | will allow both SMEs (Small and Medium Enterprise) and |
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| 20 | major companies to design innovative devices and to enter new, low and |
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| 21 | medium volume markets. |
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[99] | 22 | \parlf |
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[49] | 23 | The objective of COACH is to provide an integrated design flow, based on the |
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| 24 | SoCLib infrastructure~\cite{soclib}, and optimized for the design of |
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[97] | 25 | multi-processors digital systems targeting FPGA devices. |
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[81] | 26 | Such digital systems are generally integrated |
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| 27 | into one or several chips, and there are two types of applications: |
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[97] | 28 | They can be embedded (autonomous) applications |
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| 29 | such as personal digital assistants (PDA), ambiant computing components, |
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[49] | 30 | or wireless sensor networks (WSN) |
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| 31 | They can also be extension boards connected to a PC to accelerate a specific computation, |
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| 32 | as in High-Performance Computing (HPC) or High-Speed Signal Processing (HSSP). |
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[99] | 33 | \parlf |
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[25] | 34 | %verrous scientifiques et techniques |
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[97] | 35 | The COACH environment will integrate several hardware and software technologies: |
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[49] | 36 | \begin{description} |
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[100] | 37 | \item[Design Space Exploration:] |
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[49] | 38 | The COACH environment will support design space exploration to help the |
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| 39 | system designer to select and parameterize the target architecture, and to |
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| 40 | define the proper hardware/software partitioning of the application. |
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| 41 | For each point in the design space, metrics such as throughput, latency, power |
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| 42 | consumption, silicon area, memory allocation and data locality will be provided. |
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| 43 | These criteria will be evaluated by using the SoCLib virtual prototyping infrastructure |
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| 44 | and high-level estimation methodologies. |
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[100] | 45 | \item[Hardware Accelerators Synthesis (HAS):] |
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[49] | 46 | COACH will allow the automatic generation of hardware accelerators when required. |
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| 47 | Hence, High-Level Synthesis (HLS) tools, Application Specific Instruction Processor |
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| 48 | (ASIP) design environment and source-level transformation tools (loop transformations |
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| 49 | and memory optimisation) will be provided. |
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| 50 | This will allow further exploration of the micro-architectural design space. |
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| 51 | HLS tools are sensitive to the coding style of the input specification and the domain |
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| 52 | they target (control vs. data dominated). |
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| 53 | The HLS tools of COACH will support a common language and coding style to avoid |
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| 54 | re-engineering by the designer. |
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[100] | 55 | \item[Platform based design:] |
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[52] | 56 | COACH will handle both \altera and \xilinx FPGA devices. |
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[49] | 57 | COACH will define architectural templates that can be customized by adding |
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| 58 | dedicated coprocessors and ASIPs and by fixing template parameters such as |
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[97] | 59 | the number of embedded processors or the number of sizes of embedde memory banks, |
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| 60 | or the embedded the operating system. |
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[49] | 61 | Basically, the 3 following architectural templates will be provided: |
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| 62 | \begin{enumerate} |
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| 63 | \item A Neutral architectural template based on the SoCLib IP core library and the |
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| 64 | VCI/OCP communication infrastructure. |
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| 65 | \item An \altera architectural template based on the \altera IP core library and the |
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| 66 | AVALON system bus. |
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[99] | 67 | \item A \xilinx architectural template based on the Xlinx IP core library and the PLB |
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[49] | 68 | system bus. |
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| 69 | \end{enumerate} |
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| 70 | Moreover, the specification of the application will be independant of both the |
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| 71 | architectural template and the target FPGA device. |
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[100] | 72 | \item[Hardware/Software communication middleware:] |
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[134] | 73 | COACH will implement an homogeneous HW/SW communication infrastructure and |
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[97] | 74 | communication APIs (Application Programming Interface), that will be used for |
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| 75 | communications between software tasks running on embedded processors and |
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| 76 | dedicated hardware coprocessors, |
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[49] | 77 | \end{description} |
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| 78 | The COACH design flow will be dedicated to system designers, and will as |
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| 79 | much as possible hide the hardware characteristics to the end user. |
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| 80 | %From the end user point of view, the specification of the application will be |
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| 81 | %independant from both the architectural template and from the selected FPGA |
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| 82 | %family. |
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[99] | 83 | \parlf |
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[16] | 84 | % le programme de travail |
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[49] | 85 | %The COACH project targets fundamental issues related to design methodologies for |
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| 86 | %digital systems by providing estimation, exploration and design tools targeting both |
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| 87 | %performance and power optimization at all the abstraction levels of the flow (system, |
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| 88 | %architecture, algorithm and logic). |
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| 89 | To reach this ambitious goal, the project will rely on the experience and the |
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| 90 | complementariness of partners in the following domains: |
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| 91 | Operating system and communication middleware (\tima, \upmc), |
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| 92 | MPSoC architectures (\tima, \ubs, \upmc), |
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| 93 | ASIP architectures (\irisa), |
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[97] | 94 | High Level Synthesis (\tima, \ubs, \upmc), and compilation (\lip). |
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[49] | 95 | \\ |
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| 96 | The COACH project does not start from scratch. |
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| 97 | It stronly relies on SoCLib virtual prototyping platform~\cite{soclib} for prototyping, |
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[100] | 98 | |
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[134] | 99 | (DSX, component library), operating systems (MUTEKH, DNA/OS). |
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[49] | 100 | It also leverages on several existing technologies: |
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| 101 | on the GAUT~\cite{gaut08} and UGH~\cite{ugh08} tools for HLS, |
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| 102 | on the ROMA~\cite{roma} project for ASIP, |
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[87] | 103 | on the SYNTOL~\cite{syntol} and BEE~\cite{bee} tools for source-level analysis and transformations |
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[49] | 104 | and on the \xilinx and \altera IP core libraries. |
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| 105 | Finally it will use the \xilinx and \altera RTL tools to generate the FPGA configuration |
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| 106 | bitstreams. |
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[99] | 107 | \parlf |
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[49] | 108 | The COACH proposal has been prepared during one year by a technical working group |
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[97] | 109 | involving the 5 academic partners (one monthly meeting from january 2009 to february |
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| 110 | 2010). The objective was to analyse the issues of integrating |
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| 111 | and enhancing the existing tools and tecnnologies into a unique framework. |
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| 112 | Most of the general software architecture of the proposed design flow (including the |
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| 113 | exchange format specification) has been define by this working group. |
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[49] | 114 | Because the SocLib platform is the base of this project, it may be described as an |
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| 115 | extension of the SoCLib platform. |
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[97] | 116 | %The main development steps of the COACH project are: |
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| 117 | %\begin{enumerate} |
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| 118 | % \item Definition of the end user inputs: |
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| 119 | % The coarse grain parallelism of the application will be described as a communicating |
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| 120 | % task graph, each task being described in C language. |
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| 121 | % Similarly the architectural templates with their parameters and the design constraints |
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| 122 | % will be specified. |
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| 123 | % \item Definition of an internal format for representing task. |
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| 124 | % \item Development of the GCC pluggin for generating the internal format of a |
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| 125 | % C task. |
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| 126 | % \item Adaptation of the existing HAS tools (BEE, SYNTOL, UGH, GAUT) to read and write |
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| 127 | % the internal format. This will allow to swap from one tool to another one, and to |
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| 128 | % chain them if necessary. |
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| 129 | % \item Modification of the DSX tool (Design Space eXplorer) of the SocLib |
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| 130 | % platform to generate the bitstream for the various FPGA families and architectural |
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| 131 | % templates. |
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| 132 | % \item Development of new tools such as ASIP compiler, HPC design environment and |
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| 133 | % dynamic reconfiguration of FPGA devices. |
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| 134 | %\end{enumerate} |
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[99] | 135 | \parlf |
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[97] | 136 | Two major FPGA companies are involved in the project : \xilinx will contribute |
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| 137 | as a contractual partner providing documentation and manpower; \altera will contribute as a supporter, |
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[99] | 138 | providing documentation and development boards. These two companies are strongly motivated |
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[97] | 139 | to help the COACH project to generate efficient bitsream for both FPGA families. |
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[49] | 140 | The role of the industrial partners \bull, \thales, \navtel and \zied is to provide |
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| 141 | real use cases to benchmark the COACH design environment. |
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[99] | 142 | \parlf |
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[49] | 143 | Following the general policy of the SoCLib platform, the COACH project will be an open |
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| 144 | infrastructure, available in the framework of the SoCLib server. |
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| 145 | The architectural templates, and the COACH software tools will be distributed under the |
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| 146 | GPL license. The VHDL synthesizable models for the neutral architectural template (SoCLib |
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[97] | 147 | IP core library) will be freely available for non commercial use. For industrial exploitation |
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| 148 | the technology providers are ready to propose commercial licenses, directly to the end user, |
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| 149 | or through a third party. |
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[25] | 150 | |
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