Mini LFR - Bitstream Generation » History » Revision 13
Revision 12 (Jean-Christophe Pellion, 02/12/2016 09:54 AM) → Revision 13/16 (Jean-Christophe Pellion, 02/12/2016 09:54 AM)
# Mini LFR - Bitstream Generation # Bitstream Generation Procedure # ------------------------------ ## 1 Generates scripts files ## Clean the project directory, and run the makefile scripts command to generate all project's files. ```bash # clean the project and re-generates the scripts $> make distclean scripts ``` The files MINI\_LFR\_top\_libero.prj should be created. ## 2 Launch Libero IDE ## Open the project MINI\_LFR\_top\_libero.prj with Libero IDE v9.1. !["Libero IDE v9.1"](Capture1.PNG) ### 2.1 Synthesis ### Synthesis tools should be configured to use **Synplify** version **2012-03A-SP1-2**. Launch the synthesis step (You must not add constraint file). In the synplify Pro windows, click on the Run button. The project status obtained should be : !["Synplify Project Status"](Capture2.PNG) > You must verfify the block RAM's usage. The expected value is 100. > > If it's around 60/70, LEON3 processor is not mapped. In this case, you must clean your project and restart the generation procedure. You can close Synplify and return to Libero. If the Sythesis step is green like that : You must activate the option `Detect new files on disk automatically` in the project settings. ![](Capture3.PNG) ![](Capture4.PNG) ### 2.2 Place&Route ### Launch the Place&Route step. You must add the constraint files : * `default.pdc` (Input/Output constraint) * `MINI-LFR_PlaceAndRoute.sdc` (Timing constraint) ![](Capture5.PNG) #### 2.2.1 Compile Step #### ![](Capture6.PNG) Run the Compile step. #### 2.2.2 Layout Step #### ![](Capture7.PNG) Run the Layout step. In the Layout options windows, select Advanced Layout Options : ![](Capture8.PNG) And checked those options : ![](Capture9.PNG) Click Ok and wait... ![](Capture10.PNG) #### 2.2.3 Timing Analyser #### Launch theTiming Analyser. ![](Capture11.PNG) #### 2.2.3.a SpaceWire Output #### You must verify the SpaceWire output timing for the Max and Min delay. ![](Capture12.PNG) ![](Capture19.PNG) The ouput skew is equal to Ouput\_SOut timing - Ouput\_DOut timing. This output skew must be positive. > In this exemple, > > SPW\_NOM skew max = 13.907 - 15.882 = -1.975 ns > > SPW\_NOM skew min = 6.367 - 7.317 = -0.950 ns > > SPW\_RED skew max = 17.937 - 13.510 = 4.427 ns > > SPW\_RED skew min = 8.304 - 6.175 = 2.129 ns > > The SPW\_NOM interface must be modified. In ChipPlanner, we will move element in the SPW\_NOM path to have a positive skew in min and max delay. > ![](Capture13.PNG) > ![](Capture14.PNG) #### 2.2.3.b SpaceWire Input #### You must also verify the SpaceWire input timing. For that, you must add a new set for SPW_INPUT: ![](Capture15.PNG) and configure it like that : you ![](Capture16.PNG) You obtain those timing for min and max delay. ![](Capture17.PNG) ![](Capture18.PNG) You must also add a new set for the FF setup time : ![](Capture20.PNG) ![](Capture21.PNG) In resume, for the input SPW_NOM interface : <table border=1 width=40% align=center> <thead> <tr> <th colspan=2> Signal Type </th> <th> max delay</th> <th>min delay</th> </tr> </thead> <thead> <tr> <th colspan=4 align="center" bgcolor="#C0C0C0"> SPW_NOM_IN </th> </tr> </thead> <tbody> <tr> <td rowspan=4>r_FF</td> <td>Strobe to CLK</td> <td>7.230 ns</td> <td>3.497 ns</td> </tr> <tr> <td>Data to CLK</td> <td>8.046 ns</td> <td>3.807 ns</td> </tr> <tr> <td>Data to D </td> <td>1.700 ns</td> <td>0.692 ns</td> </tr> <tr> <td>D to Q </td> <td>0.888 ns</td> <td>0.413 ns</td> </tr> <tr> <td rowspan=4>nr_FF</td> <td>Strobe to CLK</td> <td>7.315 ns</td> <td>3.543 ns</td> </tr> <tr> <td>Data to CLK</td> <td>8.131 ns</td> <td>3.853 ns</td> </tr> <tr> <td>Data to D </td> <td>1.767 ns</td> <td>0.724 ns</td> </tr> <tr> <td>D to Q </td> <td>0.888 ns</td> <td>0.413 ns</td> </tr> </tbody> <thead> <tr> <th colspan=4 align="center" bgcolor="#C0C0C0"> SPW_RED_IN </th> </tr> </thead> <tbody> <tr> <td rowspan=4>r_FF</td> <td>Strobe to CLK</td> <td>11.601 ns</td> <td>6.217 ns</td> </tr> <tr> <td>Data to CLK</td> <td>12.845 ns</td> <td>5.488 ns</td> </tr> <tr> <td>Data to D </td> <td>2.799 ns</td> <td>1.246 ns</td> </tr> <tr> <td>D to Q </td> <td>0.888 ns</td> <td>0.413 ns</td> </tr> <tr> <td rowspan=4>nr_FF</td> <td>Strobe to CLK</td> <td>11.628 ns</td> <td>6.236 ns</td> </tr> <tr> <td>Data to CLK</td> <td>12.872 ns</td> <td>5.507 ns</td> </tr> <tr> <td>Data to D </td> <td>2.798 ns</td> <td>1.246 ns</td> </tr> <tr> <td>D to Q </td> <td>0.888 ns</td> <td>0.413 ns</td> </tr> </tbody> </table> The input skew is equal to : Time Data to FF + FF Setup Time - min(Time from strobe to CLK; Time from data to CLK). This input skew must be positive. <table border=1 width=40% align=center> <thead> <tr> <th> skew </th> <th colspan=2>max delay</th> <th colspan=2>min delay</th> </tr> </thead> <thead> <tr> <th colspan=5 align="center" bgcolor="#C0C0C0"> SPW_NOM_IN </th> </tr> </thead> <tbody> <tr> <td>skew r_FF</td> <td>4.642 ns</td> <td bgcolor="#00FF00">OK</td> <td>2.392 ns</td> <td bgcolor="#00FF00">OK</td> </tr> <tr> <td>skew nr_FF</td> <td>4.660 ns</td> <td bgcolor="#00FF00">OK</td> <td>2.406 ns</td> <td bgcolor="#00FF00">OK</td> </tr> </tbody> <thead> <tr> <th colspan=5 align="center" bgcolor="#C0C0C0"> SPW_RED_IN </th> </tr> </thead> <tbody> <tr> <td>skew r_FF</td> <td>7.914 ns</td> <td bgcolor="#00FF00">OK</td> <td>3.829 ns</td> <td bgcolor="#00FF00">OK</td> </tr> <tr> <td>skew nr_FF</td> <td>7.942 ns</td> <td bgcolor="#00FF00">OK</td> <td>3.848 ns</td> <td bgcolor="#00FF00">OK</td> </tr> </tbody> </table> In our case, all SPW input skew are positive. If MIN or MAX skew delay are not positive, you must launch the ChipPlanner tool to move r_FF and nr_FF closest to the CLK source and move XOR gate far away from input pads (SIN, DIN), nrFF:D and r_FF:D. You can close the Timing Analyser. #### 2.2.4 Chip Planner #### Launch ChipPlanner to move element in the netlist and try to fit the timing requirements (skew delay for the SPW\_NOM Output interface). ![](Capture22.PNG) In our case, we want to increase SPW\_NOM\ output skew. For that, we must increase Ouput\_SOut timing and reduce the Ouput\_DOut timing. To reduce the output dout delay, we will select the last FF before the SPW\_NOM\_OUTPUT : ![](Capture23.PNG) and move closest to the ouput PAD : ![](Capture24.PNG) To increase the output SOut delay, we will select the last FF before the SPW\_NOM\_OUTPUT : ![](Capture25.PNG) and move far away from the ouput PAD : ![](Capture26.PNG) Now, you can clicked on `Commit and Check` button and close ChipPlanner. You must relaunch the Layout step with those selected options : ![](Capture27.PNG) And finally, checked the timing update with the Timing Analyser. ### 2.2 Bitstream generation ### Click on the Programming File tool. ![](Capture28.PNG) ![](Capture27.PNG) It's done !