Library of reusable VHDL components
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library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;
--+ including vhdl 2008 libraries
--+ These lines can be commented out when using
--+ a simulator with built-in VHDL 2008 support
--library ieee_proposed;
-- use ieee_proposed.standard_additions.all;
-- use ieee_proposed.std_logic_1164_additions.all;
-- use ieee_proposed.numeric_std_additions.all;
library osvvm;
use osvvm.RandomPkg.all;
library libvhdl;
use libvhdl.AssertP.all;
use libvhdl.SimP.all;
use libvhdl.QueueP.all;
use libvhdl.UtilsP.all;
entity SimT is
end entity SimT;
architecture sim of SimT is
--* testbench global clock period
constant C_PERIOD : time := 5 ns;
--* SPI data transfer data width
constant C_DATA_WIDTH : natural := 8;
signal s_tests_done : boolean_vector(0 to 1) := (others => false);
signal s_clk : std_logic := '0';
signal s_sclk : std_logic;
signal s_ste : std_logic;
signal s_mosi : std_logic;
signal s_miso : std_logic;
shared variable sv_mosi_queue : t_list_queue;
shared variable sv_miso_queue : t_list_queue;
begin
s_clk <= not(s_clk) after C_PERIOD when not(and_reduce(s_tests_done)) else '0';
QueueInitP : process is
begin
sv_mosi_queue.init(32);
sv_miso_queue.init(32);
wait;
end process QueueInitP;
SimTestP : process is
variable v_time : time;
begin
wait until s_clk = '1';
v_time := now;
wait_cycles(s_clk, 10);
assert (now - v_time) = C_PERIOD * 20
severity failure;
s_tests_done(0) <= true;
report "INFO: wait_cycles() procedure tests finished successfully";
wait;
end process SimTestP;
-- Unit test of spi master procedure, checks all combinations
-- of cpol & cpha against spi slave procedure
SpiMasterP : process is
variable v_send_data : std_logic_vector(C_DATA_WIDTH-1 downto 0) := (others => '0');
variable v_receive_data : std_logic_vector(C_DATA_WIDTH-1 downto 0) := (others => '0');
variable v_queue_data : std_logic_vector(C_DATA_WIDTH-1 downto 0) := (others => '0');
variable v_random : RandomPType;
begin
v_random.InitSeed(v_random'instance_name);
for direction in 0 to 1 loop
for mode in 0 to 3 loop
for i in 0 to 255 loop
v_send_data := v_random.RandSlv(C_DATA_WIDTH);
sv_mosi_queue.push(v_send_data);
spi_master (data_in => v_send_data,
data_out => v_receive_data,
sclk => s_sclk,
ste => s_ste,
mosi => s_mosi,
miso => s_miso,
dir => direction,
cpol => mode / 2,
cpha => mode mod 2,
period => 1 us
);
sv_miso_queue.pop(v_queue_data);
assert_equal(v_receive_data, v_queue_data);
end loop;
end loop;
end loop;
wait;
end process SpiMasterP;
-- Unit test of spi slave procedure, checks all combinations
-- of cpol & cpha against spi master procedure
SpiSlaveP : process is
variable v_send_data : std_logic_vector(C_DATA_WIDTH-1 downto 0) := (others => '0');
variable v_receive_data : std_logic_vector(C_DATA_WIDTH-1 downto 0) := (others => '0');
variable v_queue_data : std_logic_vector(C_DATA_WIDTH-1 downto 0) := (others => '0');
variable v_random : RandomPType;
begin
v_random.InitSeed(v_random'instance_name);
for direction in 0 to 1 loop
for mode in 0 to 3 loop
for i in 0 to 255 loop
v_send_data := v_random.RandSlv(C_DATA_WIDTH);
sv_miso_queue.push(v_send_data);
spi_slave (data_in => v_send_data,
data_out => v_receive_data,
sclk => s_sclk,
ste => s_ste,
mosi => s_mosi,
miso => s_miso,
dir => direction,
cpol => mode / 2,
cpha => mode mod 2
);
sv_mosi_queue.pop(v_queue_data);
assert_equal(v_receive_data, v_queue_data);
end loop;
end loop;
end loop;
report "INFO: All tests of valid spi_master() & spi_slave() combinations finished successfully";
s_tests_done(1) <= true;
wait;
end process SpiSlaveP;
end architecture sim;