--------------------------------------------------------------------- -- TITLE: Random Access Memory -- AUTHOR: Steve Rhoads (rhoadss@yahoo.com) -- DATE CREATED: 4/21/01 -- FILENAME: ram.vhd -- PROJECT: Plasma CPU core -- COPYRIGHT: Software placed into the public domain by the author. -- Software 'as is' without warranty. Author liable for nothing. -- DESCRIPTION: -- Implements the RAM, reads the executable from either "code.txt", -- or for Altera "code[0-3].hex". -- Modified from "The Designer's Guide to VHDL" by Peter J. Ashenden --------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_misc.all; use ieee.std_logic_arith.all; use ieee.std_logic_unsigned.all; use ieee.std_logic_textio.all; use std.textio.all; use work.mlite_pack.all; entity ram is generic(memory_type : string := "DEFAULT"); port(clk : in std_logic; enable : in std_logic; write_byte_enable : in std_logic_vector(3 downto 0); address : in std_logic_vector(31 downto 2); data_write : in std_logic_vector(31 downto 0); data_read : out std_logic_vector(31 downto 0)); end; --entity ram architecture logic of ram is constant ADDRESS_WIDTH : natural := 13; begin generic_ram: if memory_type /= "ALTERA_LPM" generate begin --Simulate a synchronous RAM ram_proc: process(clk, enable, write_byte_enable, address, data_write) --mem_write, mem_sel variable mem_size : natural := 2 ** ADDRESS_WIDTH; variable data : std_logic_vector(31 downto 0); subtype word is std_logic_vector(data_write'length-1 downto 0); type storage_array is array(natural range 0 to mem_size/4 - 1) of word; variable storage : storage_array; variable index : natural := 0; file load_file : text open read_mode is "code.txt"; variable hex_file_line : line; begin --Load in the ram executable image if index = 0 then while not endfile(load_file) loop --The following two lines had to be commented out for synthesis readline(load_file, hex_file_line); hread(hex_file_line, data); storage(index) := data; index := index + 1; end loop; end if; if rising_edge(clk) then index := conv_integer(address(ADDRESS_WIDTH-1 downto 2)); data := storage(index); if enable = '1' then if write_byte_enable(0) = '1' then data(7 downto 0) := data_write(7 downto 0); end if; if write_byte_enable(1) = '1' then data(15 downto 8) := data_write(15 downto 8); end if; if write_byte_enable(2) = '1' then data(23 downto 16) := data_write(23 downto 16); end if; if write_byte_enable(3) = '1' then data(31 downto 24) := data_write(31 downto 24); end if; end if; if write_byte_enable /= "0000" then storage(index) := data; end if; end if; data_read <= data; end process; end generate; --generic_ram altera_ram: if memory_type = "ALTERA_LPM" generate signal byte_we : std_logic_vector(3 downto 0); begin byte_we <= write_byte_enable when enable = '1' else "0000"; lpm_ram_io_component0 : lpm_ram_dq GENERIC MAP ( intended_device_family => "UNUSED", lpm_width => 8, lpm_widthad => ADDRESS_WIDTH-2, lpm_indata => "REGISTERED", lpm_address_control => "REGISTERED", lpm_outdata => "UNREGISTERED", lpm_file => "code0.hex", use_eab => "ON", lpm_type => "LPM_RAM_DQ") PORT MAP ( data => data_write(31 downto 24), address => address(ADDRESS_WIDTH-1 downto 2), inclock => clk, we => byte_we(3), q => data_read(31 downto 24)); lpm_ram_io_component1 : lpm_ram_dq GENERIC MAP ( intended_device_family => "UNUSED", lpm_width => 8, lpm_widthad => ADDRESS_WIDTH-2, lpm_indata => "REGISTERED", lpm_address_control => "REGISTERED", lpm_outdata => "UNREGISTERED", lpm_file => "code1.hex", use_eab => "ON", lpm_type => "LPM_RAM_DQ") PORT MAP ( data => data_write(23 downto 16), address => address(ADDRESS_WIDTH-1 downto 2), inclock => clk, we => byte_we(2), q => data_read(23 downto 16)); lpm_ram_io_component2 : lpm_ram_dq GENERIC MAP ( intended_device_family => "UNUSED", lpm_width => 8, lpm_widthad => ADDRESS_WIDTH-2, lpm_indata => "REGISTERED", lpm_address_control => "REGISTERED", lpm_outdata => "UNREGISTERED", lpm_file => "code2.hex", use_eab => "ON", lpm_type => "LPM_RAM_DQ") PORT MAP ( data => data_write(15 downto 8), address => address(ADDRESS_WIDTH-1 downto 2), inclock => clk, we => byte_we(1), q => data_read(15 downto 8)); lpm_ram_io_component3 : lpm_ram_dq GENERIC MAP ( intended_device_family => "UNUSED", lpm_width => 8, lpm_widthad => ADDRESS_WIDTH-2, lpm_indata => "REGISTERED", lpm_address_control => "REGISTERED", lpm_outdata => "UNREGISTERED", lpm_file => "code3.hex", use_eab => "ON", lpm_type => "LPM_RAM_DQ") PORT MAP ( data => data_write(7 downto 0), address => address(ADDRESS_WIDTH-1 downto 2), inclock => clk, we => byte_we(0), q => data_read(7 downto 0)); end generate; --altera_ram --For XILINX see ram_xilinx.vhd end; --architecture logic