1 | \begin{figure}\leavevmode\center |
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2 | \includegraphics[width=.8\linewidth]{architecture-csg} |
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3 | \caption{\label{archi-csg} software architecture for digital system generation} |
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4 | %\end{figure}\begin{figure}\leavevmode\center |
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5 | \mbox{}\vspace*{1ex}\\ |
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6 | \includegraphics[width=1.0\linewidth]{architecture-hls} |
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7 | \caption{\label{archi-hls} software architecture of hardware accellerator synthesis} |
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8 | %\end{figure}\begin{figure}\leavevmode\center |
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9 | \mbox{}\vspace*{1ex}\\ |
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10 | \includegraphics[width=.8\linewidth]{architecture-hpc} |
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11 | \caption{\label{archi-hpc} software architecture of HPC} |
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12 | \end{figure} |
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13 | %FIXME: la figure ne montre que l'aspect simulation. Intégrer la partie génération (PC API, PCIX, FPGA-IP, bridge vers VCI, SoC API) serait un plus, non ? |
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14 | % |
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15 | Figures~\ref{archi-csg}, \ref{archi-hls} and \ref{archi-hpc} |
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16 | summarize the software architecture of the COACH framework we plan to develop. |
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17 | In figures, the dotted boxes are the softwares or formats that COACH |
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18 | has to provide. |
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19 | \vspace*{.75ex}\par |
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20 | For the system generation presented in figure~\ref{archi-csg}, the conductor |
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21 | is the tool \verb!CSG! (COACH System Generator). Its inputs are a process |
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22 | network describing the application to design and the synthesis parameters. |
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23 | The main parameters are the target hardware architectural template |
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24 | with its instanciation parameters, the hardware/software mapping of the |
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25 | tasks, the FPGA device and design constraints. |
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26 | \verb+CSG+ thus requires an architectural template library, a operating system |
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27 | library, two system hardware component (CPU, memories, BUS...) libraries |
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28 | (one for synthesis, one for simulation). |
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29 | For generating the coprocessor of a task mapped as hardware, \verb+CSG+ |
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30 | controls the HAS tools described below. |
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31 | From these inputs \verb!CSG! can generate the entire system (both software \& |
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32 | hardware) either as a SystemC simulator to prototype and explore quickly the |
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33 | design space or as a bitstream\footnote{COACH generates synthesizable VHDL, and |
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34 | launch the Xilinx or Altera RTL synthesis tools.} directly downloadable on the |
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35 | FPGA device\footnote{Additional partial bitstreams are generated in case of |
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36 | dynamic partial reconfiguration}. |
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37 | \\ |
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38 | %To proove CSG that COACH is open and CSG is really configurable, COACH will |
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39 | %basically support 3 architecture template (the COACH template based on a |
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40 | %MIPS processors and a VCI token ring, the Altera template based on the NIOS |
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41 | %and AVALON bus, the Xilinx template based on the MICROBLAZE and OPB bus) |
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42 | %and 2 operating systems (DNA/OS and MUTEK). Furthermore, thus is enforced |
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43 | %by the \mustbecompleted{FIXME:zied} contribution that consists in |
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44 | %implementing an other hardware target. |
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45 | %\\ |
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46 | %Finally, it is important to notice that this work is a strong |
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47 | %enhancement of the SocLib software. |
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48 | \vspace*{.75ex}\par |
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49 | The software architecture for HAS is presented in figure~\ref{archi-hls}. |
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50 | The input is a single task of the process network. The HAS tools do not work |
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51 | directly on the C++ task description but on an internal format called |
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52 | \xcoach generated by a plugin into the GNU C compiler (GCC). |
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53 | This allows on the one hand to insure that all the tools will |
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54 | accept the same C++ description and on the other hand to make possible |
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55 | their chaining. The front-end tools read a \xcoach description and generate |
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56 | a new \xcoach description that exibits more parallelism or implement |
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57 | specific instructions for ASIP. The back-end tools read a \xcoach |
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58 | description and generate a \xcoachplus description. This is a \xcoach |
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59 | description anotated with hardware information (scheduling, binding) required by |
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60 | the VHDL and systemC drivers. |
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61 | Furthermore, the back-end tools uses a macro-cell library (functional and memory |
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62 | unit). |
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63 | \vspace*{.75ex}\par |
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64 | In addition to digital system design, HPC requires a supplementary |
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65 | partitioning step presented in figure~\ref{archi-hpc}. The designer |
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66 | splits the initial application (tag 1) in two parts: one still on the PC and the |
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67 | other running in a FPGA plugged on the PCI/X PC bus. The two parts exchange data |
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68 | through communication primitives (tag 2) implemented in a library. |
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69 | The relevance of the partitioning is evaluated through a |
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70 | simulator. Once the partitioning is validated, the design of the FPGA part |
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71 | is done through \verb!CSG! (figure~\ref{archi-csg}). |
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72 | |
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73 | |
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74 | \vspace*{.75ex}\par |
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75 | \mustbecompleted{FIXME == MODIFICATION DE LA FIGURE} |
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76 | The project is split into 8 tasks numbered from 0 to 7. |
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77 | The first task (task 0) is the project management, the last one (task 7) is |
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78 | the dissemination the other task are listed below: |
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79 | \begin{enumerate} |
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80 | \item\textbf{\Backbone:} This task tackles the fundamental points of the |
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81 | project such as the defintion of the COACH inputs and outputs, |
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82 | the internal formats (e.g. \xcoach), the architectural templates and |
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83 | the design flow. |
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84 | \item\textbf{System generation:} This task addresses the prototyping and |
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85 | the generation of digital system. Apart from HAS that belong to the task 3 |
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86 | and 4, its components are those presented figure~\ref{archi-csg} |
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87 | (e.g. \verb!CSG!, operating systems). |
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88 | \item\textbf{HAS front-end:} This task mainly focusses on four functionalities: |
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89 | optimization of the memory usage, parallelism enhancement through loop |
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90 | transformations, coarse grain parallelization and ASIP generation. |
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91 | \item\textbf{HAS back-end:} This task groups two functionalities: |
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92 | High-Level Synthesis of data dominated description and HLS of control |
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93 | dominated description. |
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94 | This task contains also the development of a frequency adaptator |
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95 | that will allow the coprocessors to respect the processor \& the bus |
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96 | frequency. |
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97 | \item\textbf{Communication between PC \& FPGA-SoC:} |
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98 | This task pools the features dedicated to HPC. The main are the |
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99 | partitioning validation (see figure~\ref{archi-hpc}), the sytem drivers for |
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100 | both PC and FPGA-SoC sides, the hardware communication components and |
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101 | support for dynamic partial reconfiguration. |
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102 | \item\textbf{Demonstrators:} |
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103 | This task groups the demonstrators of the COACH project. |
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104 | \mustbecompleted{FIXME} |
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105 | \end{enumerate} |
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106 | % |
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107 | \begin{figure}\leavevmode\center |
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108 | %\includegraphics[width=.4\linewidth]{dependence-task} |
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109 | \includegraphics[width=0.70\linewidth]{dependence-task-h} |
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110 | \caption{\label{dependence-task}Task dependencies} |
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111 | \end{figure} |
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112 | Figure~\ref{dependence-task} presents the dependencies between the tasks. |
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113 | "$task-N \longrightarrow task-M$" means that $task-N$ requires $task-M$ |
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114 | to work and be demonstrated. The more bold is the arrow, the more important is |
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115 | the dependency. |
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116 | The graph shows: |
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117 | \begin{itemize} |
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118 | \item Even that $T3$ and $T4$ functionalities are complementary, their |
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119 | developments are independent (thanks to \xcoach internal format). |
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120 | \item $T2$ depends slightly from $T3$ and $T4$. Indeed, $T2$ may works |
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121 | without $T3$ and $T4$ if we limit to digital systems without hardware |
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122 | accellerators. |
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123 | \item $T5$ strongly depends on $T2$ but, $T2$ does not depend at all on |
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124 | $T5$. So demonstrators ($T6$) of embedded system would not be impacted if |
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125 | $T5$ would fail. |
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126 | \item $T1$ drives all the tasks ($T2$, $T3$, $T4$, $T5$) at the heart of |
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127 | the COACH project. |
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128 | \item $T7$ and $T0$ respectively depends on and impacts all the other tasks. |
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129 | \end{itemize} |
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130 | This organisation offers enough robustness to insure the success of the |
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131 | project except for the specification task $T1$. |
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132 | |
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133 | The only critical task in this chart is T1. \label{xcoach-problem} |
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134 | However, the partners met |
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135 | 10 times (a one day meeting per month) during the last year to prepare the |
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136 | specification and the project proposal. This gives us a degree of confidence |
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137 | that T1 will be completed in time. |
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