1 | % les objectifs scientifiques/techniques du projet. |
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2 | The objectives of COACH project are to develop a complete framework to HPC |
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3 | (accelerating solutions for existing software applications) and embedded |
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4 | applications (implementing an application on a low power standalone |
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5 | device). The design steps are presented figure~\ref{coach-flow}. |
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6 | \begin{figure}[hbtp]\leavevmode\center |
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7 | \includegraphics[width=.8\linewidth]{flow} |
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8 | \caption{\label{coach-flow} COACH flow} |
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9 | \end{figure} |
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10 | \begin{description} |
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11 | \item[HPC setup] Here the user splits the application into 2 parts: the host application |
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12 | which remains on PC and the SoC application which migrates on SoC. |
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13 | The framework provides a simulation model allowing to evaluate the partitioning. |
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14 | \item[SoC design] In this phase, |
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15 | The user can obtain simulators at different abstraction levels of the SoC by giving to COACH framework |
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16 | a SoC description. |
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17 | This description consists of a process network corresponding to the SoC application, |
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18 | an OS, an instance of a generic hardware platform |
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19 | and a mapping of processes on the platform components. The supported mapping are |
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20 | software (the process runs on a SoC processor), |
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21 | XXXpeci (the process runs on a SoC processor enhanced with dedicated instructions), |
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22 | and hardware (the process runs into a coprocessor generated by HLS and plugged on the SoC bus). |
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23 | \item[Application compilation] Once SoC description is validated, COACH generates automatically |
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24 | an FPGA bitstream containing the hardware platform with SoC application software and |
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25 | an executable containing the host application. The user can launch the application by |
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26 | loading the bitstream on FPGA and running the executable on PC. |
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27 | \end{description} |
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28 | |
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29 | % l'avancee scientifique attendue. Preciser l'originalite et le caractere |
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30 | % ambitieux du projet. |
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31 | The main scientific contribution of the project is to unify various synthesis techniques |
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32 | (same input and output formats) allowing the user to swap without engineering effort |
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33 | from one to an other and even to chain them, for example, to run polyedric transformation |
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34 | before synthesis. |
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35 | Another advantage of this framework is to provide different abstraction levels from |
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36 | a single description. |
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37 | Finally, this description is device family independent and its hardware implementation |
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38 | is automatically generated. |
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39 | |
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40 | % Detailler les verrous scientifiques et techniques a lever par la realisation du projet. |
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41 | System design is a very complicated task and in this project we try to simplify it |
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42 | as much as possible. For this purpose we have to deal with the following scientific |
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43 | and technological barriers. |
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44 | \begin{itemize} |
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45 | \item The main problem in HPC is the communication between the PC and the SoC. |
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46 | This problem has 2 aspects. The first one is the efficiency. The second is to |
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47 | eliminate enginnering effort to implement it at different abstract levels. |
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48 | \item COACH design flow has a top-down approach. In the such case, |
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49 | the required performance of a coprocessor (run frequency, maximum cycles for |
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50 | a given computation, power consumption, etc) are imposed by the other system |
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51 | components. The challenge is to allow user to control accurately the synthesis |
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52 | process. For instance, the run frequency must not be a result of the RTL synthesis |
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53 | but a strict synthesis constraint. |
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54 | \item HLS tools are sensitive to the style in which the algorithm is written. |
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55 | In addition, they are are not integrated into an architecture and system |
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56 | exploration tool. |
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57 | Consequently, engineering work is required to swap from a tool to another, |
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58 | to integrate the resulting simulation model to an architectural exploration tool |
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59 | and to synthesize the generated RTL description. |
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60 | %CA Additionnal preprocessing, source-level transformations, are thus |
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61 | %CA required to improve the process. |
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62 | %CA Particularly, this includes parallelism exposure and efficient memory mapping. |
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63 | \item Most HLS tools translate a sequential algorithm into a coprocessor |
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64 | containing a single data-path and finite state machine (FSM). In this way, |
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65 | only the fine grained parallelism is exploited (ILP parallelism). |
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66 | The challenge is to identify the coarse grained parallelism and to generate, |
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67 | from a sequential algorithm, coprocessor containing multiple communicating |
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68 | tasks (data-paths and FSMs). |
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69 | \end{itemize} |
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70 | |
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71 | %Presenter les resultats escomptes en proposant si possible des criteres de reussite |
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72 | %et d'evaluation adaptes au type de projet, permettant d'evaluer les resultats en |
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73 | %fin de projet. |
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74 | The main result is the framework. It is composed concretely of: |
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75 | 2 HPC communication shemes with their implementation, |
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76 | 5 HLS tools (control dominated HLS, data dominated HLS, Coarse grained HLS, |
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77 | Memory optimisation HLS and ASIP), |
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78 | 3 systemC based virtual prototyping environment extended with synthesizable |
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79 | RTL IP cores (generic, ALTERA/NIOS/AVALON, XILINX/MICROBLAZE/OPB), |
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80 | one design space exploration tool, |
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81 | one operating system (OS). |
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82 | \\ |
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83 | The framework fonctionality will be demonstrated with XXX-EXAMPLE1, XXX-EXAMPLE2 |
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84 | and XXX-EXAMPLE3 on 4 archictures (generic/XILINX, generic/ALTERA, |
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85 | proprietary/XILINX, proprietary/ALTERA). |
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86 | |
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