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URL https://opencores.org/ocsvn/mod_sim_exp/mod_sim_exp/trunk

Subversion Repositories mod_sim_exp

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  • This comparison shows the changes necessary to convert path
    /mod_sim_exp/trunk
    from Rev 83 to Rev 84
    Reverse comparison

Rev 83 → Rev 84

/bench/vhdl/mod_sim_exp_core_tb.vhd
77,8 → 77,8
constant C_NR_STAGES_LOW : integer := 32;
constant C_SPLIT_PIPELINE : boolean := true;
constant C_FIFO_DEPTH : integer := 32; -- set to (maximum exponent width)/16
constant C_MEM_STYLE : string := "generic"; -- xil_prim, generic, asym are valid options
constant C_DEVICE : string := "xilinx"; -- xilinx, altera are valid options
constant C_MEM_STYLE : string := "asym"; -- xil_prim, generic, asym are valid options
constant C_FPGA_MAN : string := "xilinx"; -- xilinx, altera are valid options
-- extra calculated constants
constant NR_BITS_LOW : integer := (C_NR_BITS_TOTAL/C_NR_STAGES_TOTAL)*C_NR_STAGES_LOW;
679,7 → 679,7
C_SPLIT_PIPELINE => C_SPLIT_PIPELINE,
C_FIFO_DEPTH => C_FIFO_DEPTH,
C_MEM_STYLE => C_MEM_STYLE, -- xil_prim, generic, asym are valid options
C_DEVICE => C_DEVICE -- xilinx, altera are valid options
C_FPGA_MAN => C_FPGA_MAN -- xilinx, altera are valid options
)
port map(
clk => clk,
704,7 → 704,7
dest_op_single => core_dest_op_single,
p_sel => core_p_sel,
calc_time => calc_time,
modulus_sel => "0"
modulus_sel => '0'
);
 
end test;
/bench/vhdl/axi_tb.vhd
1,10 → 1,48
--------------------------------------------------------------------------------
-- Entity: axi_tb
-- Date:2013-03-26
-- Author: Dinghe
--
-- Description ${cursor}
--------------------------------------------------------------------------------
----------------------------------------------------------------------
---- axi_tb ----
---- ----
---- This file is part of the ----
---- Modular Simultaneous Exponentiation Core project ----
---- http://www.opencores.org/cores/mod_sim_exp/ ----
---- ----
---- Description ----
---- testbench for the AXI-Lite interface, functions are ----
---- provided to read and write data ----
---- writes bus transfers to out/axi_output ----
---- ----
---- Dependencies: ----
---- - mod_sim_exp_core ----
---- ----
---- 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;
25,7 → 63,20
constant C_S_AXI_ADDR_WIDTH : integer := 32;
file output : text open write_mode is "out/axi_output.txt";
 
------------------------------------------------------------------
-- Core parameters
------------------------------------------------------------------
constant C_NR_BITS_TOTAL : integer := 1536;
constant C_NR_STAGES_TOTAL : integer := 96;
constant C_NR_STAGES_LOW : integer := 32;
constant C_SPLIT_PIPELINE : boolean := true;
constant C_FIFO_DEPTH : integer := 32; -- set to (maximum exponent width)/16
constant C_MEM_STYLE : string := "generic"; -- xil_prim, generic, asym are valid options
constant C_FPGA_MAN : string := "xilinx"; -- xilinx, altera are valid options
constant C_BASEADDR : std_logic_vector(0 to 31) := x"A0000000";
constant C_HIGHADDR : std_logic_vector(0 to 31) := x"A0007FFF";
-------------------------
-- AXI4lite interface
-------------------------
191,6 → 242,14
axi_read(x"A0005000");
axi_write(x"A0006000", x"EEEEEEEE");
axi_read(x"A0006000");
axi_write(x"A0007000", x"FFFFFFFF");
axi_read(x"A0007000");
axi_write(x"A0008000", x"22222222");
axi_read(x"A0008000");
axi_write(x"A0009000", x"33333333");
axi_read(x"A0009000");
axi_write(x"A000A000", x"44444444");
axi_read(x"A000A000");
waitclk(100);
assert false report "End of simulation" severity failure;
201,10 → 260,17
-------------------------
-- Unit Under Test
-------------------------
uut : entity work.axi_lite_slave
uut : entity work.msec_ipcore_axilite
generic map(
C_BASEADDR => x"A0000000",
C_HIGHADDR => x"A000FFFF"
C_NR_BITS_TOTAL => C_NR_BITS_TOTAL,
C_NR_STAGES_TOTAL => C_NR_STAGES_TOTAL,
C_NR_STAGES_LOW => C_NR_STAGES_LOW,
C_SPLIT_PIPELINE => C_SPLIT_PIPELINE,
C_FIFO_DEPTH => C_FIFO_DEPTH,
C_MEM_STYLE => C_MEM_STYLE, -- xil_prim, generic, asym are valid options
C_FPGA_MAN => C_FPGA_MAN, -- xilinx, altera are valid options
C_BASEADDR => C_BASEADDR,
C_HIGHADDR => C_HIGHADDR
)
port map(
--USER ports
/rtl/vhdl/interface/axi/msec_ipcore_axilite.vhd
0,0 → 1,415
----------------------------------------------------------------------
---- msec_ipcore_axilite ----
---- ----
---- This file is part of the ----
---- Modular Simultaneous Exponentiation Core project ----
---- http://www.opencores.org/cores/mod_sim_exp/ ----
---- ----
---- Description ----
---- AXI-Lite bus interface for the mod_sim_exp_core. Has a ----
---- fixed address decoder, address offsets are: ----
---- ----
---- M : 0xXXXX0000 ----
---- OP0 : 0xXXXX1000 ----
---- OP1 : 0xXXXX2000 ----
---- OP2 : 0xXXXX3000 ----
---- OP3 : 0xXXXX4000 ----
---- FIFO : 0xXXXX5000 ----
---- Control : 0xXXXX6000 ----
---- ----
---- only the XXXX part of the address can be chosen freely ----
---- ----
---- Dependencies: ----
---- - mod_sim_exp_core ----
---- ----
---- 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_arith.all;
use ieee.std_logic_unsigned.all;
 
library mod_sim_exp;
use mod_sim_exp.mod_sim_exp_pkg;
 
------------------------------------------------------------------------------
-- Entity section
------------------------------------------------------------------------------
-- Definition of Generics:
-- C_S_AXI_DATA_WIDTH -- AXI4LITE slave: Data width
-- C_S_AXI_ADDR_WIDTH -- AXI4LITE slave: Address Width
-- C_BASEADDR -- AXI4LITE slave: base address
-- C_HIGHADDR -- AXI4LITE slave: high address
--
-- Definition of Ports:
-- S_AXI_ACLK -- AXI4LITE slave: Clock
-- S_AXI_ARESETN -- AXI4LITE slave: Reset
-- S_AXI_AWADDR -- AXI4LITE slave: Write address
-- S_AXI_AWVALID -- AXI4LITE slave: Write address valid
-- S_AXI_WDATA -- AXI4LITE slave: Write data
-- S_AXI_WSTRB -- AXI4LITE slave: Write strobe
-- S_AXI_WVALID -- AXI4LITE slave: Write data valid
-- S_AXI_BREADY -- AXI4LITE slave: Response ready
-- S_AXI_ARADDR -- AXI4LITE slave: Read address
-- S_AXI_ARVALID -- AXI4LITE slave: Read address valid
-- S_AXI_RREADY -- AXI4LITE slave: Read data ready
-- S_AXI_ARREADY -- AXI4LITE slave: read addres ready
-- S_AXI_RDATA -- AXI4LITE slave: Read data
-- S_AXI_RRESP -- AXI4LITE slave: Read data response
-- S_AXI_RVALID -- AXI4LITE slave: Read data valid
-- S_AXI_WREADY -- AXI4LITE slave: Write data ready
-- S_AXI_BRESP -- AXI4LITE slave: Response
-- S_AXI_BVALID -- AXI4LITE slave: Resonse valid
-- S_AXI_AWREADY -- AXI4LITE slave: Wrte address ready
------------------------------------------------------------------------------
 
entity msec_ipcore_axilite is
generic(
-- Multiplier parameters
C_NR_BITS_TOTAL : integer := 1536;
C_NR_STAGES_TOTAL : integer := 96;
C_NR_STAGES_LOW : integer := 32;
C_SPLIT_PIPELINE : boolean := true;
C_FIFO_DEPTH : integer := 32;
C_MEM_STYLE : string := "xil_prim"; -- xil_prim, generic, asym are valid options
C_FPGA_MAN : string := "xilinx"; -- xilinx, altera are valid options
-- Bus protocol parameters
C_S_AXI_DATA_WIDTH : integer := 32;
C_S_AXI_ADDR_WIDTH : integer := 32;
C_BASEADDR : std_logic_vector := X"FFFFFFFF";
C_HIGHADDR : std_logic_vector := X"00000000"
);
port(
--USER ports
calc_time : out std_logic;
IntrEvent : out std_logic;
-------------------------
-- AXI4lite interface
-------------------------
--- Global signals
S_AXI_ACLK : in std_logic;
S_AXI_ARESETN : in std_logic;
--- Write address channel
S_AXI_AWADDR : in std_logic_vector(C_S_AXI_ADDR_WIDTH-1 downto 0);
S_AXI_AWVALID : in std_logic;
S_AXI_AWREADY : out std_logic;
--- Write data channel
S_AXI_WDATA : in std_logic_vector(C_S_AXI_DATA_WIDTH-1 downto 0);
S_AXI_WVALID : in std_logic;
S_AXI_WREADY : out std_logic;
S_AXI_WSTRB : in std_logic_vector((C_S_AXI_DATA_WIDTH/8)-1 downto 0);
--- Write response channel
S_AXI_BVALID : out std_logic;
S_AXI_BREADY : in std_logic;
S_AXI_BRESP : out std_logic_vector(1 downto 0);
--- Read address channel
S_AXI_ARADDR : in std_logic_vector(C_S_AXI_ADDR_WIDTH-1 downto 0);
S_AXI_ARVALID : in std_logic;
S_AXI_ARREADY : out std_logic;
--- Read data channel
S_AXI_RDATA : out std_logic_vector(C_S_AXI_DATA_WIDTH-1 downto 0);
S_AXI_RVALID : out std_logic;
S_AXI_RREADY : in std_logic;
S_AXI_RRESP : out std_logic_vector(1 downto 0)
);
 
attribute MAX_FANOUT : string;
attribute SIGIS : string;
attribute MAX_FANOUT of S_AXI_ACLK : signal is "10000";
attribute MAX_FANOUT of S_AXI_ARESETN : signal is "10000";
attribute SIGIS of S_AXI_ACLK : signal is "Clk";
attribute SIGIS of S_AXI_ARESETN : signal is "Rst";
end entity msec_ipcore_axilite;
 
------------------------------------------------------------------------------
-- Architecture section
------------------------------------------------------------------------------
 
architecture IMP of msec_ipcore_axilite is
type axi_states is (addr_wait, read_state, write_state, response_state);
signal state : axi_states;
signal address : std_logic_vector(C_S_AXI_ADDR_WIDTH-1 downto 0);
signal reset : std_logic;
signal S_AXI_BVALID_i : std_logic;
-- selection signals
signal cs_array : std_logic_vector(6 downto 0);
signal slv_reg_selected : std_logic;
signal op_mem_selected : std_logic;
signal op_sel : std_logic_vector(1 downto 0);
signal MNO_sel : std_logic;
 
-- slave register signals
signal slv_reg : std_logic_vector(C_S_AXI_DATA_WIDTH-1 downto 0);
signal slv_reg_write_enable : std_logic;
signal load_flags : std_logic;
-- core interface signeals
signal write_enable : std_logic;
signal core_write_enable : std_logic;
signal core_fifo_push : std_logic;
signal core_data_out : std_logic_vector(31 downto 0);
signal core_rw_address : std_logic_vector(8 downto 0);
------------------------------------------------------------------
-- Signals for multiplier core interrupt
------------------------------------------------------------------
signal core_interrupt : std_logic;
signal core_fifo_full : std_logic;
signal core_fifo_nopush : std_logic;
signal core_ready : std_logic;
signal core_mem_collision : std_logic;
 
------------------------------------------------------------------
-- Signals for multiplier core control
------------------------------------------------------------------
signal core_start : std_logic;
signal core_exp_m : std_logic;
signal core_p_sel : std_logic_vector(1 downto 0);
signal core_dest_op_single : std_logic_vector(1 downto 0);
signal core_x_sel_single : std_logic_vector(1 downto 0);
signal core_y_sel_single : std_logic_vector(1 downto 0);
signal core_flags : std_logic_vector(15 downto 0);
signal core_modulus_sel : std_logic;
begin
-- unused signals
S_AXI_BRESP <= "00";
S_AXI_RRESP <= "00";
-- axi-lite slave state machine
axi_slave_states : process (S_AXI_ACLK)
begin
if rising_edge(S_AXI_ACLK) then
if S_AXI_ARESETN='0' then -- slave reset state
S_AXI_RVALID <= '0';
S_AXI_BVALID_i <= '0';
S_AXI_ARREADY <= '0';
S_AXI_WREADY <= '0';
S_AXI_AWREADY <= '0';
state <= addr_wait;
address <= (others=>'0');
write_enable <= '0';
else
case state is
when addr_wait =>
-- wait for a read or write address and latch it in
if S_AXI_ARVALID = '1' then -- read
state <= read_state;
address <= S_AXI_ARADDR;
S_AXI_ARREADY <= '1';
elsif (S_AXI_AWVALID = '1' and S_AXI_WVALID = '1') then -- write
state <= write_state;
address <= S_AXI_AWADDR;
else
state <= addr_wait;
end if;
when read_state =>
-- place correct data on bus and generate valid pulse
S_AXI_ARREADY <= '0';
S_AXI_RVALID <= '1';
state <= response_state;
when write_state =>
-- generate a write pulse
S_AXI_AWREADY <= '1';
write_enable <= '1';
S_AXI_WREADY <= '1';
state <= response_state;
when response_state =>
write_enable <= '0';
S_AXI_AWREADY <= '0';
S_AXI_WREADY <= '0';
S_AXI_BVALID_i <= '1';
-- wait for response from master
if (S_AXI_RREADY = '1') or (S_AXI_BVALID_i = '1' and S_AXI_BREADY = '1') then
S_AXI_RVALID <= '0';
S_AXI_BVALID_i <= '0';
state <= addr_wait;
else
state <= response_state;
end if;
end case;
end if;
end if;
end process;
S_AXI_BVALID <= S_AXI_BVALID_i;
 
-- place correct data on the read bus
S_AXI_RDATA <= slv_reg when (slv_reg_selected='1') else
core_data_out;
-- SLAVE REG MAPPING
-- core control signals
core_p_sel <= slv_reg(31 downto 30);
core_dest_op_single <= slv_reg(29 downto 28);
core_x_sel_single <= slv_reg(27 downto 26);
core_y_sel_single <= slv_reg(25 downto 24);
core_start <= slv_reg(23);
core_exp_m <= slv_reg(22);
core_modulus_sel <= slv_reg(21);
reset <= (not S_AXI_ARESETN) or slv_reg(20);
-- implement slave register
SLAVE_REG_WRITE_PROC : process( S_AXI_ACLK ) is
begin
if rising_edge(S_AXI_ACLK) then
if S_AXI_ARESETN = '0' then
slv_reg <= (others => '0');
elsif load_flags = '1' then
slv_reg <= slv_reg(31 downto 16) & core_flags;
else
if (slv_reg_write_enable='1') then
slv_reg <= S_AXI_WDATA(31 downto 0);
end if;
end if;
end if;
end process SLAVE_REG_WRITE_PROC;
-- interrupt and flags
core_interrupt <= core_ready or core_mem_collision or core_fifo_full or core_fifo_nopush;
IntrEvent <= core_interrupt;
FLAGS_CNTRL_PROC : process(S_AXI_ACLK, S_AXI_ARESETN) is
begin
if S_AXI_ARESETN = '0' then
core_flags <= (others => '0');
load_flags <= '0';
elsif rising_edge(S_AXI_ACLK) then
if core_start = '1' then
core_flags <= (others => '0');
else
if core_ready = '1' then
core_flags(15) <= '1';
else
core_flags(15) <= core_flags(15);
end if;
if core_mem_collision = '1' then
core_flags(14) <= '1';
else
core_flags(14) <= core_flags(14);
end if;
if core_fifo_full = '1' then
core_flags(13) <= '1';
else
core_flags(13) <= core_flags(13);
end if;
if core_fifo_nopush = '1' then
core_flags(12) <= '1';
else
core_flags(12) <= core_flags(12);
end if;
end if;
load_flags <= core_interrupt;
end if;
end process FLAGS_CNTRL_PROC;
-- adress decoder
with address(14 downto 12) select
cs_array <= "0000001" when "000", -- M
"0000010" when "001", -- OP0
"0000100" when "010", -- OP1
"0001000" when "011", -- OP2
"0010000" when "100", -- OP3
"0100000" when "101", -- FIFO
"1000000" when "110", -- user reg space
"0000000" when others;
slv_reg_selected <= cs_array(6);
slv_reg_write_enable <= write_enable and slv_reg_selected;
-- high if memory space is selected
op_mem_selected <= cs_array(0) or cs_array(1) or cs_array(2) or cs_array(3) or cs_array(4);
-- operand memory singals
MNO_sel <= cs_array(0);
with cs_array(4 downto 1) select
op_sel <= "00" when "0001",
"01" when "0010",
"10" when "0100",
"11" when "1000",
"00" when others;
core_rw_address <= MNO_sel & op_sel & address(7 downto 2);
core_write_enable <= write_enable and op_mem_selected;
-- FIFO signals
core_fifo_push <= write_enable and cs_array(5);
------------------------------------------
-- Exponentiation core instance
------------------------------------------
msec: entity mod_sim_exp.mod_sim_exp_core
generic map(
C_NR_BITS_TOTAL => C_NR_BITS_TOTAL,
C_NR_STAGES_TOTAL => C_NR_STAGES_TOTAL,
C_NR_STAGES_LOW => C_NR_STAGES_LOW,
C_SPLIT_PIPELINE => C_SPLIT_PIPELINE,
C_FIFO_DEPTH => C_FIFO_DEPTH,
C_MEM_STYLE => C_MEM_STYLE,
C_FPGA_MAN => C_FPGA_MAN
)
port map(
clk => S_AXI_ACLK,
reset => reset,
-- operand memory interface (plb shared memory)
write_enable => core_write_enable,
data_in => S_AXI_WDATA(31 downto 0),
rw_address => core_rw_address,
data_out => core_data_out,
collision => core_mem_collision,
-- op_sel fifo interface
fifo_din => S_AXI_WDATA(31 downto 0),
fifo_push => core_fifo_push,
fifo_full => core_fifo_full,
fifo_nopush => core_fifo_nopush,
-- ctrl signals
start => core_start,
exp_m => core_exp_m,
ready => core_ready,
x_sel_single => core_x_sel_single,
y_sel_single => core_y_sel_single,
dest_op_single => core_dest_op_single,
p_sel => core_p_sel,
calc_time => calc_time,
modulus_sel => core_modulus_sel
);
end IMP;
/rtl/vhdl/interface/plb/mod_sim_exp_IPcore.vhd
164,7 → 164,7
C_SPLIT_PIPELINE : boolean := true;
C_FIFO_DEPTH : integer := 32;
C_MEM_STYLE : string := "xil_prim"; -- xil_prim, generic, asym are valid options
C_DEVICE : string := "xilinx"; -- xilinx, altera are valid options
C_FPGA_MAN : string := "xilinx"; -- xilinx, altera are valid options
-- ADD USER GENERICS ABOVE THIS LINE ---------------
 
-- DO NOT EDIT BELOW THIS LINE ---------------------
582,7 → 582,7
C_SPLIT_PIPELINE => C_SPLIT_PIPELINE,
C_FIFO_DEPTH => C_FIFO_DEPTH,
C_MEM_STYLE => C_MEM_STYLE,
C_DEVICE => C_DEVICE,
C_FPGA_MAN => C_FPGA_MAN,
-- MAP USER GENERICS ABOVE THIS LINE ---------------
 
C_SLV_AWIDTH => USER_SLV_AWIDTH,
/rtl/vhdl/interface/plb/user_logic.vhd
102,7 → 102,7
C_SPLIT_PIPELINE : boolean := true;
C_FIFO_DEPTH : integer := 32;
C_MEM_STYLE : string := "xil_prim"; -- xil_prim, generic, asym are valid options
C_DEVICE : string := "xilinx"; -- xilinx, altera are valid options
C_FPGA_MAN : string := "xilinx"; -- xilinx, altera are valid options
-- ADD USER GENERICS ABOVE THIS LINE ---------------
 
-- DO NOT EDIT BELOW THIS LINE ---------------------
408,7 → 408,7
C_SPLIT_PIPELINE => C_SPLIT_PIPELINE,
C_FIFO_DEPTH => C_FIFO_DEPTH,
C_MEM_STYLE => C_MEM_STYLE,
C_DEVICE => C_DEVICE
C_FPGA_MAN => C_FPGA_MAN
)
port map(
clk => Bus2IP_Clk,
/rtl/vhdl/core/mod_sim_exp_pkg.vhd
932,7 → 932,7
C_SPLIT_PIPELINE : boolean := true;
C_FIFO_DEPTH : integer := 32;
C_MEM_STYLE : string := "generic"; -- xil_prim, generic, asym are valid options
C_DEVICE : string := "xilinx" -- xilinx, altera are valid options
C_FPGA_MAN : string := "xilinx" -- xilinx, altera are valid options
);
port(
clk : in std_logic;
/rtl/vhdl/core/mod_sim_exp_core.vhd
67,7 → 67,7
C_SPLIT_PIPELINE : boolean := true;
C_FIFO_DEPTH : integer := 32;
C_MEM_STYLE : string := "asym"; -- xil_prim, generic, asym are valid options
C_DEVICE : string := "xilinx" -- xilinx, altera are valid options
C_FPGA_MAN : string := "xilinx" -- xilinx, altera are valid options
);
port(
clk : in std_logic;
122,7 → 122,12
signal fifo_nopop : std_logic;
signal fifo_dout : std_logic_vector(31 downto 0);
begin
 
-- check the parameters
assert (C_MEM_STYLE="xil_prim" or C_MEM_STYLE="generic" or C_MEM_STYLE="asym")
report "C_MEM_STYLE incorrect!, it must be one of these: xil_prim, generic or asym" severity failure;
assert (C_FPGA_MAN="xilinx" or C_FPGA_MAN="altera")
report "C_FPGA_MAN incorrect!, it must be one of these: xilinx or altera" severity failure;
-- The actual multiplier
the_multiplier : mont_multiplier
generic map(
150,7 → 155,7
nr_op => nr_op,
nr_m => nr_m,
mem_style => C_MEM_STYLE,
device => C_DEVICE
device => C_FPGA_MAN
)
port map(
data_in => data_in,
/sim/Makefile
6,52 → 6,59
##
# avs_aes hdl files
##
CORE_SRC =$(HDL_DIR)/core/std_functions.vhd \
$(HDL_DIR)/core/mod_sim_exp_pkg.vhd \
$(HDL_DIR)/ram/dpram_generic.vhd \
$(HDL_DIR)/ram/tdpram_generic.vhd \
$(HDL_DIR)/ram/dpram_asym.vhd \
$(HDL_DIR)/ram/dpramblock_asym.vhd \
$(HDL_DIR)/core/modulus_ram_asym.vhd \
$(HDL_DIR)/ram/tdpram_asym.vhd \
$(HDL_DIR)/ram/tdpramblock_asym.vhd \
$(HDL_DIR)/core/operand_ram_asym.vhd \
$(HDL_DIR)/core/fifo_generic.vhd \
$(HDL_DIR)/core/modulus_ram_gen.vhd \
$(HDL_DIR)/core/operand_ram_gen.vhd \
$(HDL_DIR)/core/adder_block.vhd \
$(HDL_DIR)/core/autorun_cntrl.vhd \
$(HDL_DIR)/core/cell_1b_adder.vhd \
$(HDL_DIR)/core/cell_1b_mux.vhd \
$(HDL_DIR)/core/cell_1b.vhd \
$(HDL_DIR)/core/counter_sync.vhd \
$(HDL_DIR)/core/d_flip_flop.vhd \
$(HDL_DIR)/core/fifo_primitive.vhd \
$(HDL_DIR)/core/modulus_ram.vhd \
$(HDL_DIR)/core/mont_ctrl.vhd \
$(HDL_DIR)/core/mod_sim_exp_core.vhd \
$(HDL_DIR)/core/operand_dp.vhd \
$(HDL_DIR)/core/operand_mem.vhd \
$(HDL_DIR)/core/operand_ram.vhd \
$(HDL_DIR)/core/operands_sp.vhd \
$(HDL_DIR)/core/register_1b.vhd \
$(HDL_DIR)/core/register_n.vhd \
$(HDL_DIR)/core/standard_cell_block.vhd \
$(HDL_DIR)/core/stepping_logic.vhd \
$(HDL_DIR)/core/x_shift_reg.vhd \
$(HDL_DIR)/core/sys_stage.vhd \
$(HDL_DIR)/core/sys_last_cell_logic.vhd \
$(HDL_DIR)/core/sys_first_cell_logic.vhd \
$(HDL_DIR)/core/sys_pipeline.vhd \
$(HDL_DIR)/core/mont_multiplier.vhd \
CORE_SRC =$(HDL_DIR)core/std_functions.vhd \
$(HDL_DIR)core/mod_sim_exp_pkg.vhd \
$(HDL_DIR)ram/dpram_generic.vhd \
$(HDL_DIR)ram/tdpram_generic.vhd \
$(HDL_DIR)ram/dpram_asym.vhd \
$(HDL_DIR)ram/dpramblock_asym.vhd \
$(HDL_DIR)core/modulus_ram_asym.vhd \
$(HDL_DIR)ram/tdpram_asym.vhd \
$(HDL_DIR)ram/tdpramblock_asym.vhd \
$(HDL_DIR)core/operand_ram_asym.vhd \
$(HDL_DIR)core/fifo_generic.vhd \
$(HDL_DIR)core/modulus_ram_gen.vhd \
$(HDL_DIR)core/operand_ram_gen.vhd \
$(HDL_DIR)core/adder_block.vhd \
$(HDL_DIR)core/autorun_cntrl.vhd \
$(HDL_DIR)core/cell_1b_adder.vhd \
$(HDL_DIR)core/cell_1b_mux.vhd \
$(HDL_DIR)core/cell_1b.vhd \
$(HDL_DIR)core/counter_sync.vhd \
$(HDL_DIR)core/d_flip_flop.vhd \
$(HDL_DIR)core/fifo_primitive.vhd \
$(HDL_DIR)core/modulus_ram.vhd \
$(HDL_DIR)core/mont_ctrl.vhd \
$(HDL_DIR)core/mod_sim_exp_core.vhd \
$(HDL_DIR)core/operand_dp.vhd \
$(HDL_DIR)core/operand_mem.vhd \
$(HDL_DIR)core/operand_ram.vhd \
$(HDL_DIR)core/operands_sp.vhd \
$(HDL_DIR)core/register_1b.vhd \
$(HDL_DIR)core/register_n.vhd \
$(HDL_DIR)core/standard_cell_block.vhd \
$(HDL_DIR)core/stepping_logic.vhd \
$(HDL_DIR)core/x_shift_reg.vhd \
$(HDL_DIR)core/sys_stage.vhd \
$(HDL_DIR)core/sys_last_cell_logic.vhd \
$(HDL_DIR)core/sys_first_cell_logic.vhd \
$(HDL_DIR)core/sys_pipeline.vhd \
$(HDL_DIR)core/mont_multiplier.vhd \
 
 
##
# Testbench HDL file
# Testbench HDL files
##
TB_SRC_DIR = ../bench/vhdl/
TB_SRC = $(TB_SRC_DIR)mod_sim_exp_core_tb.vhd
TB_SRC = $(TB_SRC_DIR)mod_sim_exp_core_tb.vhd \
$(TB_SRC_DIR)msec_axi_tb.vhd
 
##
# Interface HDL files
##
IF_SRC_DIR = ../rtl/vhdl/interface/
IF_SRC = $(IF_SRC_DIR)axi/msec_ipcore_axilite.vhd
 
#######################################
all: mod_sim_exp
 
64,7 → 71,7
work_lib:
vlib work
 
libs: mod_sim_exp work_lib
libs: mod_sim_exp_lib work_lib
 
mod_sim_exp_com: mod_sim_exp_lib
#echo --
75,9 → 82,18
 
mod_sim_exp_tb: work_lib
#echo --
#echo building Modular Exponentiation Core Testbench
#echo building Modular Exponentiation Core Testbenches
#echo --
vcom $(VCOMOPS) -work work $(TB_SRC)
 
msec_if: work_lib
#echo --
#echo building Modular Exponentiation Core Interface
#echo --
vcom $(VCOMOPS) -work work $(IF_SRC)
 
mod_sim_exp: mod_sim_exp_com mod_sim_exp_tb
vsim -c -do mod_sim_exp.do -lib work mod_sim_exp_core_tb
 
mod_sim_exp_axi: mod_sim_exp_com msec_if mod_sim_exp_tb
vsim -c -do mod_sim_exp.do -lib work msec_axi_tb

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