fibonacci

2023-03-08 14:44:31 +01:00 · 2023-03-08 14:44:31 +01:00 · 7ad8a8d9ab
commit 7ad8a8d9ab
parent 75ad3b3d06
9 changed files with 188 additions and 0 deletions
--- a/Rapport/Fibonnaci/plot.py
+++ b/Rapport/Fibonnaci/plot.py
@ -0,0 +1,61 @@
 import matplotlib.pyplot as plt
 from sklearn.linear_model import LinearRegression
 import numpy as np
 Y = [1100, 2150, 3200, 4250, 5300, 6350, 7400, 8450, 9500]
 Y2 = [1100, 2150, 3200, 4250, 5300, 6350, 7400, 8450, 9500]
 Y_ARM = [912, 1736 , 2560 , 3352, 4216, 5304 , 5840,  6704, 7464]
 Y_ARMO3 = [173, 329, 480, 633, 789, 945, 1098, 1308, 1406]
 Y_gcc = [2296, 5119, 6715, 9078, 10830, 12541, 15041, 16780, 18883]
 Y_O3 = [165, 287, 380, 559, 900, 901, 776, 1122, 1574]
 f_RISCV1 = 50e6
 f_RISCV2 = 100e6
 f_ARM = 800e6
 f_PC = 2400e6
 X = []
 for i in range(9) :
    Y[i] = (Y[i]*1e9)/f_RISCV1
    Y2[i] = (Y2[i]*1e9)/f_RISCV2
    Y_ARM[i] = (Y_ARM[i]*1e9)/f_ARM
    Y_ARMO3[i] = (Y_ARMO3[i]*1e9)/f_ARM
    Y_gcc[i] = (Y_gcc[i]*1e9)/f_PC
    Y_O3[i] = (Y_O3[i]*1e9)/f_PC
    X.append(50*(1+i))
 plt.scatter(X, Y, color="b", marker="x", label="RISCV 50 MHz")
 plt.scatter(X, Y2, color="g", marker="x", label="RISCV 100 MHz")
 plt.scatter(X, Y_ARM, color="b", label="mesures ARM")
 plt.scatter(X, Y_ARMO3, color="g", label="mesures ARM -O3")
 plt.scatter(X, Y_gcc, color="b",marker="*", label="desktop -O0 2,4Ghz")
 plt.scatter(X, Y_O3, color="g", marker="*",label="desktop -O3 2,4Ghz")
 x = np.array(X).reshape(-1, 1)
 y = np.array(Y).reshape(-1, 1)
 y2 = np.array(Y2).reshape(-1, 1)
 reg = LinearRegression().fit(x, y)
 reg2 = LinearRegression().fit(x, y2)
 print("score obtenu : " + str(reg.score(x, y)))
 print("score obtenu : " + str(reg.score(x, y2)))
 print("attente à zéro : {}".format(reg.intercept_))
 print("attente à zéro : {}".format(reg2.intercept_))
 x_lin = [0, max(X)]
 y_lin = [reg.predict(np.array([0]).reshape(-1, 1)), reg.predict(np.array([x_lin[1]]).reshape(-1, 1))]
 y_lin2 = [reg2.predict(np.array([0]).reshape(-1, 1)), reg2.predict(np.array([x_lin[1]]).reshape(-1, 1))]
 y_lin = [y_lin[0][0][0], y_lin[1][0][0]]
 y_lin2 = [y_lin2[0][0][0], y_lin2[1][0][0]]
 # plt.plot(x_lin, y_lin, color = "r", label="RegLin 50 score : {:.4f}".format(reg.score(x, y)))
 # plt.plot(x_lin, y_lin2, color = "r")
 plt.yscale("log")
 plt.xlim([0, 500])
 plt.ylim([0, 1000000])
 plt.legend()
 plt.title("Temps d'exécution en fonction de n_max")
 plt.ylabel("T (ns)")
 plt.xlabel("N_max")
 plt.show()
 plt.savefig("M2_SETI/A2/fibonacci/linéaire.png")
--- a/Rapport/Fibonnaci/time_exec_fibo.png
+++ b/Rapport/Fibonnaci/time_exec_fibo.png
--- a/fibonacci/main.bin
+++ b/fibonacci/main.bin
--- a/fibonacci/main.c
+++ b/fibonacci/main.c
@ -0,0 +1,108 @@
 // #################################################################################################
 // # << NEORV32 - "Hello World" Demo Program >>                                                    #
 // # ********************************************************************************************* #
 // # BSD 3-Clause License                                                                          #
 // #                                                                                               #
 // # Copyright (c) 2022, Stephan Nolting. All rights reserved.                                     #
 // #                                                                                               #
 // # Redistribution and use in source and binary forms, with or without modification, are          #
 // # permitted provided that the following conditions are met:                                     #
 // #                                                                                               #
 // # 1. Redistributions of source code must retain the above copyright notice, this list of        #
 // #    conditions and the following disclaimer.                                                   #
 // #                                                                                               #
 // # 2. Redistributions in binary form must reproduce the above copyright notice, this list of     #
 // #    conditions and the following disclaimer in the documentation and/or other materials        #
 // #    provided with the distribution.                                                            #
 // #                                                                                               #
 // # 3. Neither the name of the copyright holder nor the names of its contributors may be used to  #
 // #    endorse or promote products derived from this software without specific prior written      #
 // #    permission.                                                                                #
 // #                                                                                               #
 // # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS   #
 // # OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF               #
 // # MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE    #
 // # COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,     #
 // # EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE #
 // # GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED    #
 // # AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING     #
 // # NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED  #
 // # OF THE POSSIBILITY OF SUCH DAMAGE.                                                            #
 // # ********************************************************************************************* #
 // # The NEORV32 Processor - https://github.com/stnolting/neorv32              (c) Stephan Nolting #
 // #################################################################################################
 /**********************************************************************//**
 * @file hello_world/main.c
 * @author Stephan Nolting
 * @brief Classic 'hello world' demo program.
 **************************************************************************/
 #include <neorv32.h>
 /**********************************************************************//**
 * @name User configuration
 **************************************************************************/
 /**@{*/
 /** UART BAUD rate */
 #define BAUD_RATE 19200
 /**@}*/
 void fibonnaci(uint32_t *n_max, uint32_t *f_n){
  uint32_t max = *n_max;
  uint32_t fn_1 = 0;
  uint32_t fn_copy = 1;
  uint32_t fn_test = 1;
  for(uint32_t i=0; i<max; i++){
    fn_copy = fn_test;
    fn_test = fn_test + fn_1;
    fn_1 = fn_copy;
  }
  *f_n = fn_test;
 }
 /**********************************************************************//**
 * Main function; prints some fancy stuff via UART.
 *
 * @note This program requires the UART interface to be synthesized.
 *
 * @return 0 if execution was successful
 **************************************************************************/
 int main() {
  long Begin_Time, End_Time, User_Time;
  uint32_t n_max, f;
  // capture all exceptions and give debug info via UART
  // this is not required, but keeps us safe
  neorv32_rte_setup();
  // init UART at default baud rate, no parity bits, no HW flow control
  neorv32_uart0_setup(BAUD_RATE, PARITY_NONE, FLOW_CONTROL_NONE);
  // check available hardware extensions and compare with compiler flags
  neorv32_rte_check_isa(0); // silent = 0 -> show message if isa mismatch
  // say hello
  neorv32_uart0_puts("Fibonnacci cycles measure :\n");
  neorv32_uart0_printf("NEORV32: Freq = %u\n",NEORV32_SYSINFO.CLK);
  for(uint8_t i=1; i<10; i++){
    n_max = 50;
    Begin_Time = (long)neorv32_mtime_get_time();
    for(uint32_t j=0; j<2*454546; j++){
      fibonnaci(&n_max, &f);
    }
    End_Time = (long)neorv32_mtime_get_time();
    User_Time = End_Time - Begin_Time;
    neorv32_uart0_printf("NEORV32: mean cycles n_max = %u :      %u\n",n_max, (uint32_t)User_Time);
  }
  neorv32_uart0_puts("end:\n");
  return 0;
 }
--- a/fibonacci/main.c.o
+++ b/fibonacci/main.c.o
--- a/fibonacci/main.elf
+++ b/fibonacci/main.elf
--- a/fibonacci/makefile
+++ b/fibonacci/makefile
@ -0,0 +1,4 @@
 # Modify this variable to fit your NEORV32 setup (neorv32 home folder)
 NEORV32_HOME ?= ../../..
 include $(NEORV32_HOME)/sw/common/common.mk
--- a/fibonacci/neorv32_exe.bin
+++ b/fibonacci/neorv32_exe.bin
--- a/readme.md
+++ b/readme.md
@ -58,7 +58,22 @@ Ext. bus endianness: little
 [ ] XIP
 [ ] ONEWIRE
 ### Clock
 On peut augmenter la fréquence du processeur à l'aide de l'outil PLL Intel FPGA IP que l'on vient monter à 100 MHz. Monter à 200 Mhz indique un timing fail et une Fmax à 130 Mhz.
 Il faut ensuite modifier l'input de clock vers le signal de pll.
 ```
 library pll;
 pll_100: entity pll.pll(rtl) 
 port map(
 	refclk  => clk_i, --  refclk.clk
 	--rst      : in  std_logic := '0'; --   reset.reset
 	outclk_0 => clk_100,        -- outclk0.clk
 	locked   => open        --  locked.export
 );
 ```
 ### Software
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