1 | \begin{taskinfo} |
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2 | \let\LIP\leader |
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3 | \let\IRISA\enable |
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4 | \let\UBS\enable |
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5 | \let\UPMC\enable |
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6 | \let\TIMA\enable |
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7 | \end{taskinfo} |
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8 | % |
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9 | \begin{objectif} |
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10 | The objective of this task is to convert the input specification of |
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11 | an hardware accelerator, which must be written in a familiar language |
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12 | (C/C++) with as few constraints as possible, into a form suitable for |
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13 | the HLS tools (i.e. HAS back-end tools of the COACH project). If the |
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14 | target is an ASIP, the frontend has to extract |
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15 | patterns from the source code and convert them into the definition |
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16 | of an extensible processor. If the target is a process network, the |
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17 | front end has to distribute the workload and the data sets as fairly |
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18 | as possible, identify communication channels, and output an \xcoach |
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19 | description. |
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20 | \end{objectif} |
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21 | % |
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22 | \begin{workpackage} |
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23 | \subtask This sub-task aims at providing compiler support for custom instructions |
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24 | within the HAS front-end. It will take as input the COACH intermediate |
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25 | representation, and will output an annotated COACH IR containing the custom |
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26 | instructions definitions along with their occurrence in the application. |
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27 | \begin{livrable} |
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28 | \itemV{0}{18}{x}{\Sirisa}{ASIP compilation flow} |
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29 | In this first version of the software, the computations patterns corresponding to |
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30 | custom instructions are specified by the user, and then automatically extracted (when |
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31 | beneficial) from the application intermediate representation. |
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32 | \itemL{18}{24}{x}{\Sirisa}{ASIP compilation flow}{6:9:0} |
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33 | In this second version, the software will also be able to automatically identify |
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34 | interesting pattern candidates in the application code, and use them as custom |
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35 | instructions. |
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36 | \end{livrable} |
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37 | |
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38 | \subtask In this sub-task, we provide micro-architectural template models for the two target |
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39 | processor architectures (NIOS-II and MIPS) supported within the COACH-ASIP design flow. |
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40 | For each processor, we provide a simulation model (System-C) and a synthesizable model (VHDL) |
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41 | of the architecture, along with its architectural extensions |
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42 | \begin{livrable} |
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43 | \itemV{0}{12}{x}{\Sirisa}{SystemC for extensible MIPS } |
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44 | { A SystemC simulation model for a simple extensible MIPS architectural template } |
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45 | \itemL{12}{20}{x}{\Sirisa}{SystemC for extensible MIPS}{2:3:0} |
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46 | {A SystemC simulation model for an extensible MIPS with a tight architectural integration of |
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47 | its instruction set extensions} |
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48 | \itemL{0}{12}{x}{\Sirisa}{SystemC for NIOS processor}{2:0:0} |
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49 | { A SystemC simulation model for an extensible NIOS processor template, the VHDL model being |
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50 | already available from \altera} |
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51 | \itemV{12}{18}{h}{\Sirisa}{VHDL for an extensible MIPS} |
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52 | {A synthesizable VHDL model for a simple extensible MIPS architectural template} |
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53 | \itemL{18}{24}{h}{\Sirisa}{VHDL for extensible MIPS}{9:12:0} |
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54 | {A synthesizable VHDL model for an extensible MIPS with a tight architectural integration of |
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55 | its instruction set extensions} |
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56 | \itemL{24}{36}{d}{\Sirisa}{Evaluation report }{0:0:2} |
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57 | {An evaluation report with quantitative analysis of the performance/area trade-off induced by |
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58 | the different approaches} |
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59 | \end{livrable} |
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60 | |
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61 | \subtask Extraction of parallelism in polyhedral loops and conversion into a process network. |
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62 | |
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63 | \begin{livrable} |
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64 | \itemV{0}{6}{d}{\Slip}{Method, Preliminary Definition} |
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65 | Description and specification of a process construction method for programs with |
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66 | polyhedral loops. |
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67 | \itemL{30}{36}{d}{\Slip}{Process generation method}{10:0:9} |
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68 | Final assessment of the method and improved version of the specification. |
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69 | \itemV{6}{12}{x}{\Slip}{Process construction} |
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70 | Preliminary implementation in the Syntol framework. |
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71 | At this step the software will just implement a single constructor. |
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72 | \itemV{12}{18}{x}{\Slip} {Arrays and FIFO} |
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73 | Implementation of the array contraction and FIFO construction algorithm. |
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74 | Conversion of the input and output to the \xcoach format. |
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75 | \itemV{18}{30}{d+x}{\Slip}{Non-polyhedral extension} |
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76 | Extension of automatic parallelization and array contraction |
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77 | to non-polyhedral loops. Implementation in the Bee framework. |
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78 | \itemL{30}{36}{x}{\Slip} {Process/FIFO construction}{10:20:12} |
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79 | Final release taking into account the feedbacks from the |
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80 | demonstrator \STs. |
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81 | \end{livrable} |
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82 | |
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83 | \end{workpackage} |
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84 | |
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