tmeissner
/
verification_ip


								-- Simple wishbone verification IP

								-- For use with GHDL only

								-- Suitable for simulation & formal verification

								-- Copyright 2021 by Torsten Meissner (programming@goodcleanfun.de)


								library ieee;

								use ieee.std_logic_1164.all;

								use ieee.numeric_std.all;


								library wishbone;

								use wishbone.wishbone_pkg.all;


								entity wishbone_vip is

								  generic (

								    MODE     : string  := "CLASSIC";

								    ASSERTS  : boolean := true;

								    COVERAGE : boolean := true

								  );

								  port (

								    -- syscon signals

								    WbSysCon : in t_wb_syscon;

								    -- master signals

								    WbMaster : in t_wb_master;

								    -- slave signals

								    WbSlave  : in t_wb_slave

								  );

								end entity wishbone_vip;


								architecture verification of wishbone_vip is


								  function count_ones (data : in std_logic_vector) return natural is

								    variable v_return : natural := 0;

								  begin

								    for i in data'range loop

								      if (to_x01(data(i)) = '1') then

								        v_return := v_return + 1;

								      end if;

								    end loop;

								    return v_return;

								  end function count_ones;


								  function one_hot (data : in std_logic_vector) return boolean is

								  begin

								    return count_ones(data) = 1;

								  end function one_hot;


								  function one_hot_0 (data : in std_logic_vector) return boolean is

								  begin

								    return count_ones(data) <= 1;

								  end function one_hot_0;


								  alias Clk is WbSysCon.Clk;

								  alias Reset is WbSysCon.Reset;


								  signal s_wb_slave_resp : std_logic_vector(2 downto 0);


								begin


								  s_wb_slave_resp <= WbSlave.Rty & WbSlave.Err & WbSlave.Ack;


								  -- Static interface checks

								  -- Always enabled, regardless of generic ASSERTS setting


								  MODE_a : assert MODE = "CLASSIC"

								    report "ERROR: Unsupported mode"

								    severity failure;


								  DATA_MS_WIDTH_a : assert WbMaster.Dat'length = 8 or WbMaster.Dat'length = 16 or

								                           WbMaster.Dat'length = 32 or WbMaster.Dat'length = 64

								    report "ERROR: Invalid Master Data length"

								    severity failure;


								  DATA_SM_WIDTH_a : assert WbSlave.Dat'length = 8 or WbSlave.Dat'length = 16 or

								                           WbSlave.Dat'length = 32 or WbSlave.Dat'length = 64

								    report "ERROR: Invalid Slave Data length"

								    severity failure;


								  DATA_EQUAL_WIDTH_a : assert WbMaster.Dat'length = WbSlave.Dat'length

								    report "ERROR: Master & Slave Data don't have equal length"

								    severity failure;


								  default clock is rising_edge(Clk);


								  ASSERTS_G : if ASSERTS generate


								    signal s_wb_master : t_wb_master(Adr(WbMaster.Adr'range),

								                                     Dat(WbMaster.Dat'range),

								                                     Sel(WbMaster.Sel'range),

								                                     Tgc(WbMaster.Tgc'range),

								                                     Tga(WbMaster.Tga'range),

								                                     Tgd(WbMaster.Tgd'range));

								    signal s_wb_slave : t_wb_slave(Dat(WbSlave.Dat'range),

								                                   Tgd(WbSlave.Tgd'range));


								  begin


								    -- Create copies of bus signals

								    process (Clk) is

								    begin

								      if rising_edge(Clk) then

								        s_wb_master <= WbMaster;

								        s_wb_slave  <= WbSlave;

								      end if;

								    end process;


								    -- RULE 3.20

								    STB_RESET_a : assert always Reset -> not WbMaster.Stb;

								    CYC_RESET_a : assert always Reset -> not WbMaster.Cyc;


								    -- RULE 3.25

								    STB_CYC_a : assert always WbMaster.Stb -> WbMaster.Cyc;


								    -- RULE 3.45

								    ACK_ERR_RTY_ONEHOT_a : assert always one_hot_0(s_wb_slave_resp);


								    -- RULE 3.50

								    ACK_ERR_RTY_STB_a : assert always or s_wb_slave_resp -> WbMaster.Stb;


								    DAT_STABLE_STB_a : assert always WbMaster.Stb and s_wb_slave_resp = "000" ->

								      next (WbMaster.Dat = s_wb_master.Dat);


								  end generate ASSERTS_G;


								  COVERAGE_G : if COVERAGE generate


								    sequence s_single_read (boolean resp) is {

								      not WbMaster.Cyc;

								      WbMaster.Cyc and not WbMaster.Stb[*];

								      {s_wb_slave_resp = "000"[*]; resp} &&

								      {WbMaster.Cyc and WbMaster.Stb and not WbMaster.We}[+]

								    };


								    sequence s_single_write (boolean resp) is {

								      not WbMaster.Cyc;

								      WbMaster.Cyc and not WbMaster.Stb[*];

								      {s_wb_slave_resp = "000"[*]; resp} &&

								      {WbMaster.Cyc and WbMaster.Stb and WbMaster.We}[+]

								    };


								    SINGLE_READ_ACKED_c : cover s_single_read(WbSlave.Ack)

								      report "Single read with ack finished";


								    SINGLE_READ_ERROR_c : cover s_single_read(WbSlave.Err)

								      report "Single read with error finished";


								    SINGLE_READ_RETRY_c : cover s_single_read(WbSlave.Rty)

								      report "Single read with retry finished";


								    SINGLE_WRITE_ACKED_c : cover s_single_write(WbSlave.Ack)

								      report "Single read with ack finished";


								    SINGLE_WRITE_ERROR_c : cover s_single_write(WbSlave.Err)

								      report "Single read with error finished";


								    SINGLE_WRITE_RETRY_c : cover s_single_write(WbSlave.Rty)

								      report "Single read with retry finished";


								  end generate COVERAGE_G;


								end architecture verification;