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[/] [mod_sim_exp/] [trunk/] [bench/] [vhdl/] [multiplier_tb.vhd] - Rev 95
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---------------------------------------------------------------------- ---- multiplier_tb ---- ---- ---- ---- This file is part of the ---- ---- Modular Simultaneous Exponentiation Core project ---- ---- http://www.opencores.org/cores/mod_sim_exp/ ---- ---- ---- ---- Description ---- ---- testbench for the Montgomery multiplier ---- ---- Performs some multiplications to verify the design ---- ---- Takes input parameters from sim_mult_input.txt and writes ---- ---- result and output to sim_mult_output.txt ---- ---- ---- ---- Dependencies: ---- ---- - mont_multiplier ---- ---- ---- ---- Authors: ---- ---- - Geoffrey Ottoy, DraMCo research group ---- ---- - Jonas De Craene, JonasDC@opencores.org ---- ---- ---- ---------------------------------------------------------------------- ---- ---- ---- Copyright (C) 2011 DraMCo research group and OPENCORES.ORG ---- ---- ---- ---- This source file may be used and distributed without ---- ---- restriction provided that this copyright statement is not ---- ---- removed from the file and that any derivative work contains ---- ---- the original copyright notice and the associated disclaimer. ---- ---- ---- ---- This source file is free software; you can redistribute it ---- ---- and/or modify it under the terms of the GNU Lesser General ---- ---- Public License as published by the Free Software Foundation; ---- ---- either version 2.1 of the License, or (at your option) any ---- ---- later version. ---- ---- ---- ---- This source is distributed in the hope that it will be ---- ---- useful, but WITHOUT ANY WARRANTY; without even the implied ---- ---- warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ---- ---- PURPOSE. See the GNU Lesser General Public License for more ---- ---- details. ---- ---- ---- ---- You should have received a copy of the GNU Lesser General ---- ---- Public License along with this source; if not, download it ---- ---- from http://www.opencores.org/lgpl.shtml ---- ---- ---- ---------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; use ieee.std_logic_arith.all; library std; use std.textio.all; library ieee; use ieee.std_logic_textio.all; library mod_sim_exp; use mod_sim_exp.mod_sim_exp_pkg.all; entity multiplier_tb is end multiplier_tb; architecture test of multiplier_tb is constant CLK_PERIOD : time := 10 ns; signal clk : std_logic := '0'; signal reset : std_logic := '1'; file input : text open read_mode is "src/sim_mult_input.txt"; file output : text open write_mode is "out/sim_mult_output.txt"; ------------------------------------------------------------------ -- Core parameters ------------------------------------------------------------------ constant NR_BITS_TOTAL : integer := 1536; constant NR_STAGES_TOTAL : integer := 96; constant NR_STAGES_LOW : integer := 32; constant SPLIT_PIPELINE : boolean := true; -- extra calculated constants constant NR_BITS_LOW : integer := (NR_BITS_TOTAL/NR_STAGES_TOTAL)*NR_STAGES_LOW; constant NR_BITS_HIGH : integer := NR_BITS_TOTAL-NR_BITS_LOW; -- the width of the input operand for the mulitplier test constant TEST_NR_BITS : integer := NR_BITS_LOW; ------------------------------------------------------------------ -- Signals for multiplier core memory space ------------------------------------------------------------------ -- data busses signal xy : std_logic_vector(NR_BITS_TOTAL-1 downto 0); -- x and y operand data bus RAM -> multiplier signal m : std_logic_vector(NR_BITS_TOTAL-1 downto 0); -- modulus data bus RAM -> multiplier signal r : std_logic_vector(NR_BITS_TOTAL-1 downto 0); -- result data bus RAM <- multiplier -- control signals signal p_sel : std_logic_vector(1 downto 0); -- operand selection signal result_dest_op : std_logic_vector(1 downto 0); -- result destination operand signal ready : std_logic; signal start : std_logic; signal load_op : std_logic; signal load_x : std_logic; signal load_m : std_logic; signal load_result : std_logic; begin ------------------------------------------ -- Generate clk ------------------------------------------ clk_process : process begin while (true) loop clk <= '0'; wait for CLK_PERIOD/2; clk <= '1'; wait for CLK_PERIOD/2; end loop; end process; ------------------------------------------ -- Stimulus Process ------------------------------------------ stim_proc : process procedure waitclk(n : natural := 1) is begin for i in 1 to n loop wait until rising_edge(clk); end loop; end waitclk; function ToString(constant Timeval : time) return string is variable StrPtr : line; begin write(StrPtr,Timeval); return StrPtr.all; end ToString; -- variables to read file variable L : line; variable Lw : line; variable x_op : std_logic_vector((NR_BITS_TOTAL-1) downto 0) := (others=>'0'); variable y_op : std_logic_vector((NR_BITS_TOTAL-1) downto 0) := (others=>'0'); variable m_op : std_logic_vector((NR_BITS_TOTAL-1) downto 0) := (others=>'0'); variable result : std_logic_vector((NR_BITS_TOTAL-1) downto 0) := (others=>'0'); variable good_value : boolean; variable param_count : integer := 0; variable timer : time; begin -- initialisation xy <= (others=>'0'); m <= (others=>'0'); start <='0'; reset <= '0'; load_x <= '0'; write(Lw, string'("----- Selecting pipeline: ")); writeline(output, Lw); case (TEST_NR_BITS) is when NR_BITS_TOTAL => p_sel <= "11"; write(Lw, string'(" Full pipeline selected")); when NR_BITS_HIGH => p_sel <= "10"; write(Lw, string'(" Upper pipeline selected")); when NR_BITS_LOW => p_sel <= "01"; write(Lw, string'(" Lower pipeline selected")); when others => write(Lw, string'(" Invallid bitwidth for design")); assert false report "impossible basewidth!" severity failure; end case; writeline(output, Lw); -- Generate active high reset signal reset <= '1'; waitclk(10); reset <= '0'; waitclk(10); while not endfile(input) loop readline(input, L); -- read next line next when L(1)='-'; -- skip comment lines -- read input values case param_count is when 0 => hread(L, x_op(TEST_NR_BITS-1 downto 0), good_value); assert good_value report "Can not read x operand" severity failure; assert false report "Simulating multiplication" severity note; write(Lw, string'("----------------------------------------------")); writeline(output, Lw); write(Lw, string'("-- MULTIPLICATION --")); writeline(output, Lw); write(Lw, string'("----------------------------------------------")); writeline(output, Lw); write(Lw, string'("----- Variables used:")); writeline(output, Lw); write(Lw, string'("x: ")); hwrite(Lw, x_op(TEST_NR_BITS-1 downto 0)); writeline(output, Lw); when 1 => hread(L, y_op(TEST_NR_BITS-1 downto 0), good_value); assert good_value report "Can not read y operand" severity failure; write(Lw, string'("y: ")); hwrite(Lw, y_op(TEST_NR_BITS-1 downto 0)); writeline(output, Lw); when 2 => hread(L, m_op(TEST_NR_BITS-1 downto 0), good_value); assert good_value report "Can not read m operand" severity failure; write(Lw, string'("m: ")); hwrite(Lw, m_op(TEST_NR_BITS-1 downto 0)); writeline(output, Lw); -- load in x xy <= x_op; wait until rising_edge(clk); load_x <='1'; wait until rising_edge(clk); load_x <='0'; -- put y and m on the bus xy <= y_op; m <= m_op; wait until rising_edge(clk); -- start multiplication and wait for result start <= '1'; wait until rising_edge(clk); start <= '0'; wait until ready='1'; wait until rising_edge(clk); writeline(output, Lw); write(Lw, string'(" Computed result: ")); hwrite(Lw, r(TEST_NR_BITS-1 downto 0)); writeline(output, Lw); when 3 => hread(L, result(TEST_NR_BITS-1 downto 0), good_value); assert good_value report "Can not read result" severity failure; write(Lw, string'(" Read result: ")); hwrite(Lw, result(TEST_NR_BITS-1 downto 0)); writeline(output, Lw); if (r(TEST_NR_BITS-1 downto 0) = result(TEST_NR_BITS-1 downto 0)) then write(Lw, string'(" => result is correct!")); writeline(output, Lw); else write(Lw, string'(" => Error: result is incorrect!!!")); writeline(output, Lw); assert false report "result is incorrect!!!" severity error; end if; when others => assert false report "undefined state!" severity failure; end case; if (param_count = 3) then param_count := 0; else param_count := param_count+1; end if; end loop; wait for 1 us; assert false report "End of simulation" severity failure; end process; ------------------------------------------ -- Multiplier instance ------------------------------------------ the_multiplier : mont_multiplier generic map( n => NR_BITS_TOTAL, t => NR_STAGES_TOTAL, tl => NR_STAGES_LOW, split => SPLIT_PIPELINE ) port map( core_clk => clk, xy => xy, m => m, r => r, start => start, reset => reset, p_sel => p_sel, load_x => load_x, ready => ready ); end test;
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