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------------------------------------------------------------------------------- -- -- Copyright (C) 2010 -- ASTRON (Netherlands Institute for Radio Astronomy) <http://www.astron.nl/> -- JIVE (Joint Institute for VLBI in Europe) <http://www.jive.nl/> -- P.O.Box 2, 7990 AA Dwingeloo, The Netherlands -- -- This program is free software: you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation, either version 3 of the License, or -- (at your option) any later version. -- -- This program 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 General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program. If not, see <http://www.gnu.org/licenses/>. -- ------------------------------------------------------------------------------- LIBRARY IEEE, common_pkg_lib; USE IEEE.std_logic_1164.ALL; USE IEEE.numeric_std.ALL; USE common_pkg_lib.common_pkg.ALL; USE common_pkg_lib.common_lfsr_sequences_pkg.ALL; USE common_pkg_lib.tb_common_pkg.ALL; USE work.dp_stream_pkg.ALL; PACKAGE tb_dp_pkg IS ------------------------------------------------------------------------------ -- Purpose: -- -- Test bench package for applying stimuli to a streaming data path. The -- input is counter data, the output is verified and an error is reported -- if a counter value is missing or duplicate. -- -- Description: -- -- The test is divided into intervals marked by sync to start a new subtest -- named by state. New subtests can be added by adding an extra sync interval -- and state name to this package. In each subtest the streaming interface -- DUT can be verified for different situations by manipulating: -- . cnt_en : cnt_en not always active when in_ready is asserted -- . out_ready : out_ready not always active -- -- Remarks: -- . See e.g. tb_dp_pipeline.vhd for how to use the procedures. -- . To run all stimuli in Modelsim do: -- > as 10 -- > run 400 us ------------------------------------------------------------------------------ CONSTANT clk_period : TIME := 10 ns; -- 100 MHz CONSTANT c_dp_sync_interval : NATURAL := 3000; CONSTANT c_dp_test_interval : NATURAL := 100; CONSTANT c_dp_nof_toggle : NATURAL := 40; CONSTANT c_dp_nof_both : NATURAL := 50; -- The test bench uses other field widths than the standard t_dp_sosi record field widths, the assumptions are: -- . c_dp_data_w < c_dp_stream_data_w -- . c_dp_data_w > c_dp_stream_empty_w -- . c_dp_data_w > c_dp_stream_channel_w -- . c_dp_data_w > c_dp_stream_error_w CONSTANT c_dp_data_w : NATURAL := c_word_w; -- =32, choose wide enough to avoid out_data wrap around issue for p_verify CONSTANT c_dp_bsn_w : NATURAL := c_dp_data_w; -- c_dp_stream_bsn_w; CONSTANT c_dp_empty_w : NATURAL := c_dp_stream_empty_w; CONSTANT c_dp_channel_w : NATURAL := c_dp_stream_channel_w; CONSTANT c_dp_channel_user_w : NATURAL := c_dp_stream_channel_w/2; -- support some bits for mux input user streams channel widths CONSTANT c_dp_channel_mux_w : NATURAL :=(c_dp_stream_channel_w+1)/2; -- support rest bits for the nof input ports of a mux CONSTANT c_dp_error_w : NATURAL := c_dp_stream_error_w; TYPE t_dp_data_arr IS ARRAY (NATURAL RANGE <>) OF STD_LOGIC_VECTOR(c_dp_data_w-1 DOWNTO 0); -- The state name tells what kind of test is done in the sync interval TYPE t_dp_state_enum IS ( s_idle, s_both_active, s_pull_down_out_ready, s_pull_down_cnt_en, s_toggle_out_ready, s_toggle_cnt_en, s_toggle_both, s_pulse_cnt_en, s_chirp_out_ready, s_random, s_done ); TYPE t_dp_value_enum IS ( e_equal, e_at_least ); -- always active, random or pulse flow control TYPE t_dp_flow_control_enum IS ( e_active, e_random, e_pulse ); TYPE t_dp_flow_control_enum_arr IS ARRAY (NATURAL RANGE <>) OF t_dp_flow_control_enum; CONSTANT c_dp_flow_control_enum_arr : t_dp_flow_control_enum_arr := (e_active, e_random, e_pulse); -- array all possible values that can be iterated over ------------------------------------------------------------------------------ -- Stream source functions ------------------------------------------------------------------------------ -- Block data generator with feedforward throttle control -- !!! old style: sync before sop -- !!! used by tb_dp_packetizing, do not use for new DP components PROCEDURE proc_dp_gen_block_data(CONSTANT c_nof_block_per_sync : IN NATURAL; CONSTANT c_block_size : IN NATURAL; CONSTANT c_gap_size : IN NATURAL; CONSTANT c_throttle_num : IN NATURAL; CONSTANT c_throttle_den : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL sync_nr : INOUT NATURAL; SIGNAL block_nr : INOUT NATURAL; SIGNAL cnt_sync : OUT STD_LOGIC; SIGNAL cnt_val : OUT STD_LOGIC; SIGNAL cnt_dat : INOUT STD_LOGIC_VECTOR); -- Block data generator with ready flow control and symbols counter PROCEDURE proc_dp_gen_block_data(CONSTANT c_ready_latency : IN NATURAL; -- 0, 1 are supported by proc_dp_stream_ready_latency() CONSTANT c_use_data : IN BOOLEAN; -- when TRUE use data field, else use re, im fields, and keep unused fields at 'X' CONSTANT c_data_w : IN NATURAL; -- data width for the data, re and im fields CONSTANT c_symbol_w : IN NATURAL; -- c_data_w/c_symbol_w must be an integer CONSTANT c_symbol_init : IN NATURAL; -- init counter for symbols in data field CONSTANT c_symbol_re_init : IN NATURAL; -- init counter for symbols in re field CONSTANT c_symbol_im_init : IN NATURAL; -- init counter for symbols in im field CONSTANT c_nof_symbols : IN NATURAL; -- nof symbols per frame for the data, re and im fields CONSTANT c_channel : IN NATURAL; -- channel field CONSTANT c_error : IN NATURAL; -- error field CONSTANT c_sync : IN STD_LOGIC; -- when '1' issue sync pulse during this block CONSTANT c_bsn : IN STD_LOGIC_VECTOR; -- bsn field SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi); PROCEDURE proc_dp_gen_block_data(CONSTANT c_data_w : IN NATURAL; -- data width for the data field CONSTANT c_symbol_init : IN NATURAL; -- init counter for the data in the data field CONSTANT c_nof_symbols : IN NATURAL; -- nof symbols per frame for the data fields CONSTANT c_channel : IN NATURAL; -- channel field CONSTANT c_error : IN NATURAL; -- error field CONSTANT c_sync : IN STD_LOGIC; -- when '1' issue sync pulse during this block CONSTANT c_bsn : IN STD_LOGIC_VECTOR; -- bsn field SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi); -- Handle stream ready signal, only support RL=0 or 1. PROCEDURE proc_dp_stream_ready_latency(CONSTANT c_latency : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL ready : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '1' then active output when ready CONSTANT c_sync : IN STD_LOGIC; CONSTANT c_valid : IN STD_LOGIC; CONSTANT c_sop : IN STD_LOGIC; CONSTANT c_eop : IN STD_LOGIC; SIGNAL out_sync : OUT STD_LOGIC; SIGNAL out_valid : OUT STD_LOGIC; SIGNAL out_sop : OUT STD_LOGIC; SIGNAL out_eop : OUT STD_LOGIC); -- Initialize the data per symbol FUNCTION func_dp_data_init(c_data_w, c_symbol_w, init : NATURAL) RETURN STD_LOGIC_VECTOR; -- Increment the data per symbol FUNCTION func_dp_data_incr(c_data_w, c_symbol_w : NATURAL; data : STD_LOGIC_VECTOR) RETURN STD_LOGIC_VECTOR; -- Generate a counter data with valid PROCEDURE proc_dp_gen_data(CONSTANT c_ready_latency : IN NATURAL; -- 0, 1 are supported by proc_dp_stream_ready_latency() CONSTANT c_data_w : IN NATURAL; CONSTANT c_data_init : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi); -- As above but with counter max PROCEDURE proc_dp_gen_data(CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_data_w : IN NATURAL; CONSTANT c_data_init : IN NATURAL; CONSTANT c_data_max : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi); -- Generate a frame with symbols counter PROCEDURE proc_dp_gen_frame(CONSTANT c_ready_latency : IN NATURAL; -- 0, 1 are supported by proc_dp_stream_ready_latency() CONSTANT c_data_w : IN NATURAL; CONSTANT c_symbol_w : IN NATURAL; -- c_data_w/c_symbol_w must be an integer CONSTANT c_symbol_init : IN NATURAL; CONSTANT c_nof_symbols : IN NATURAL; CONSTANT c_bsn : IN NATURAL; CONSTANT c_sync : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi); -- Input data counter PROCEDURE proc_dp_cnt_dat(SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; SIGNAL cnt_dat : INOUT STD_LOGIC_VECTOR); PROCEDURE proc_dp_cnt_dat(SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; SIGNAL cnt_val : INOUT STD_LOGIC; SIGNAL cnt_dat : INOUT STD_LOGIC_VECTOR); -- Transmit data PROCEDURE proc_dp_tx_data(CONSTANT c_ready_latency : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL cnt_val : IN STD_LOGIC; SIGNAL cnt_dat : IN STD_LOGIC_VECTOR; SIGNAL tx_data : INOUT t_dp_data_arr; SIGNAL tx_val : INOUT STD_LOGIC_VECTOR; SIGNAL out_data : OUT STD_LOGIC_VECTOR; SIGNAL out_val : OUT STD_LOGIC); -- Transmit data control (use for sop, eop) PROCEDURE proc_dp_tx_ctrl(CONSTANT c_offset : IN NATURAL; CONSTANT c_period : IN NATURAL; SIGNAL data : IN STD_LOGIC_VECTOR; SIGNAL valid : IN STD_LOGIC; SIGNAL ctrl : OUT STD_LOGIC); -- Define sync interval PROCEDURE proc_dp_sync_interval(SIGNAL clk : IN STD_LOGIC; SIGNAL sync : OUT STD_LOGIC); -- Stimuli for cnt_en PROCEDURE proc_dp_count_en(SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL sync : IN STD_LOGIC; SIGNAL lfsr : INOUT STD_LOGIC_VECTOR; SIGNAL state : OUT t_dp_state_enum; SIGNAL done : OUT STD_LOGIC; SIGNAL tb_end : OUT STD_LOGIC; SIGNAL cnt_en : OUT STD_LOGIC); ------------------------------------------------------------------------------ -- Stream sink functions ------------------------------------------------------------------------------ -- Stimuli for out_ready PROCEDURE proc_dp_out_ready(SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL sync : IN STD_LOGIC; SIGNAL lfsr : INOUT STD_LOGIC_VECTOR; SIGNAL out_ready : OUT STD_LOGIC); -- DUT output verify enable PROCEDURE proc_dp_verify_en(CONSTANT c_delay : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL sync : IN STD_LOGIC; SIGNAL verify_en : OUT STD_LOGIC); PROCEDURE proc_dp_verify_en(CONSTANT c_continuous : IN BOOLEAN; SIGNAL clk : IN STD_LOGIC; SIGNAL valid : IN STD_LOGIC; SIGNAL sop : IN STD_LOGIC; SIGNAL eop : IN STD_LOGIC; SIGNAL verify_en : OUT STD_LOGIC); -- Run and verify for some cycles PROCEDURE proc_dp_verify_run_some_cycles(CONSTANT nof_pre_clk : IN NATURAL; CONSTANT nof_verify_clk : IN NATURAL; CONSTANT nof_post_clk : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : OUT STD_LOGIC); -- Verify the expected value PROCEDURE proc_dp_verify_value(CONSTANT c_str : IN STRING; CONSTANT mode : IN t_dp_value_enum; SIGNAL clk : IN STD_LOGIC; SIGNAL en : IN STD_LOGIC; SIGNAL exp : IN STD_LOGIC_VECTOR; SIGNAL res : IN STD_LOGIC_VECTOR); PROCEDURE proc_dp_verify_value(CONSTANT mode : IN t_dp_value_enum; SIGNAL clk : IN STD_LOGIC; SIGNAL en : IN STD_LOGIC; SIGNAL exp : IN STD_LOGIC_VECTOR; SIGNAL res : IN STD_LOGIC_VECTOR); PROCEDURE proc_dp_verify_value(CONSTANT c_str : IN STRING; SIGNAL clk : IN STD_LOGIC; SIGNAL en : IN STD_LOGIC; SIGNAL exp : IN STD_LOGIC; SIGNAL res : IN STD_LOGIC); -- Verify output global and local BSN -- . incrementing or replicated global BSN -- . incrementing local BSN that starts at 1 PROCEDURE proc_dp_verify_bsn(CONSTANT c_use_local_bsn : IN BOOLEAN; -- use local BSN or only use global BSN CONSTANT c_global_bsn_increment : IN POSITIVE; -- increment per global BSN CONSTANT c_nof_replicated_global_bsn : IN POSITIVE; -- number of replicated global BSN CONSTANT c_block_per_sync : IN POSITIVE; -- of sop/eop blocks per sync interval SIGNAL clk : IN STD_LOGIC; SIGNAL out_sync : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_bsn : IN STD_LOGIC_VECTOR; SIGNAL verify_en : INOUT STD_LOGIC; -- initialize '0', becomes '1' when bsn verification starts SIGNAL cnt_replicated_global_bsn : INOUT NATURAL; SIGNAL prev_out_bsn_global : INOUT STD_LOGIC_VECTOR; SIGNAL prev_out_bsn_local : INOUT STD_LOGIC_VECTOR); -- Verify incrementing data -- . wrap at c_out_data_max when >0, else no wrap when c_out_data_max=0 -- . default increment by +1, but also allow an increment by +c_out_data_gap PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_out_data_max : IN UNSIGNED; CONSTANT c_out_data_gap : IN UNSIGNED; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR); -- Verify the DUT incrementing output data that wraps in range 0 ... c_out_data_max PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_out_data_max : IN UNSIGNED; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR); -- Verify the DUT incrementing output data, fixed increment +1 PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_ready_latency : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; -- by using sop or eop proc_dp_verify_data() can also be used to verify other SOSI fields like bsn, error, channel, empty SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR); -- Verify incrementing data with RL > 0 or no flow control, support wrap at maximum and increment gap PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_out_data_max : IN UNSIGNED; CONSTANT c_out_data_gap : IN UNSIGNED; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR); PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_out_data_max : IN NATURAL; CONSTANT c_out_data_gap : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR); PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_out_data_max : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR); -- Verify incrementing data with RL > 0 or no flow control, fixed increment +1 PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR); -- Verify the DUT output symbols PROCEDURE proc_dp_verify_symbols(CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_data_w : IN NATURAL; CONSTANT c_symbol_w : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL out_empty : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR); -- Verify the DUT output data with empty PROCEDURE proc_dp_verify_data_empty(CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_last_word : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL out_eop_1 : INOUT STD_LOGIC; SIGNAL out_eop_2 : INOUT STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL out_data_1 : INOUT STD_LOGIC_VECTOR; SIGNAL out_data_2 : INOUT STD_LOGIC_VECTOR; SIGNAL out_data_3 : INOUT STD_LOGIC_VECTOR; SIGNAL out_empty : IN STD_LOGIC_VECTOR; SIGNAL out_empty_1 : INOUT STD_LOGIC_VECTOR); PROCEDURE proc_dp_verify_other_sosi(CONSTANT c_str : IN STRING; CONSTANT c_exp_data : IN STD_LOGIC_VECTOR; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL res_data : IN STD_LOGIC_VECTOR); PROCEDURE proc_dp_verify_valid(CONSTANT c_ready_latency : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL prev_out_ready : INOUT STD_LOGIC_VECTOR; SIGNAL out_val : IN STD_LOGIC); PROCEDURE proc_dp_verify_valid(SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL prev_out_ready : INOUT STD_LOGIC; SIGNAL out_val : IN STD_LOGIC); -- Verify the DUT output sync PROCEDURE proc_dp_verify_sync(CONSTANT c_sync_period : IN NATURAL; CONSTANT c_sync_offset : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL sync : IN STD_LOGIC; SIGNAL sop : IN STD_LOGIC; SIGNAL bsn : IN STD_LOGIC_VECTOR); -- Verify the DUT output sop and eop PROCEDURE proc_dp_verify_sop_and_eop(CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_verify_valid : IN BOOLEAN; SIGNAL clk : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL hold_sop : INOUT STD_LOGIC); PROCEDURE proc_dp_verify_sop_and_eop(CONSTANT c_ready_latency : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL hold_sop : INOUT STD_LOGIC); PROCEDURE proc_dp_verify_sop_and_eop(SIGNAL clk : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL hold_sop : INOUT STD_LOGIC); PROCEDURE proc_dp_verify_block_size(CONSTANT c_ready_latency : IN NATURAL; SIGNAL alt_size : IN NATURAL; -- alternative size (eg. use exp_size'last_value) SIGNAL exp_size : IN NATURAL; -- expected size SIGNAL clk : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL cnt_size : INOUT NATURAL); PROCEDURE proc_dp_verify_block_size(CONSTANT c_ready_latency : IN NATURAL; SIGNAL exp_size : IN NATURAL; -- expected size SIGNAL clk : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL cnt_size : INOUT NATURAL); PROCEDURE proc_dp_verify_block_size(SIGNAL alt_size : IN NATURAL; -- alternative size (eg. use exp_size'last_value) SIGNAL exp_size : IN NATURAL; -- expected size SIGNAL clk : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL cnt_size : INOUT NATURAL); PROCEDURE proc_dp_verify_block_size(SIGNAL exp_size : IN NATURAL; -- expected size SIGNAL clk : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL cnt_size : INOUT NATURAL); -- Verify the DUT output invalid between frames PROCEDURE proc_dp_verify_gap_invalid(SIGNAL clk : IN STD_LOGIC; SIGNAL in_val : IN STD_LOGIC; SIGNAL in_sop : IN STD_LOGIC; SIGNAL in_eop : IN STD_LOGIC; SIGNAL out_gap : INOUT STD_LOGIC); -- declare initial gap signal = '1' -- Verify the DUT output control (use for sop, eop) PROCEDURE proc_dp_verify_ctrl(CONSTANT c_offset : IN NATURAL; CONSTANT c_period : IN NATURAL; CONSTANT c_str : IN STRING; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL data : IN STD_LOGIC_VECTOR; SIGNAL valid : IN STD_LOGIC; SIGNAL ctrl : IN STD_LOGIC); -- Wait for stream valid PROCEDURE proc_dp_stream_valid(SIGNAL clk : IN STD_LOGIC; SIGNAL in_valid : IN STD_LOGIC); -- Wait for stream valid AND sop PROCEDURE proc_dp_stream_valid_sop(SIGNAL clk : IN STD_LOGIC; SIGNAL in_valid : IN STD_LOGIC; SIGNAL in_sop : IN STD_LOGIC); -- Wait for stream valid AND eop PROCEDURE proc_dp_stream_valid_eop(SIGNAL clk : IN STD_LOGIC; SIGNAL in_valid : IN STD_LOGIC; SIGNAL in_eop : IN STD_LOGIC); END tb_dp_pkg; PACKAGE BODY tb_dp_pkg IS ------------------------------------------------------------------------------ -- PROCEDURE: Block data generator with feedforward throttle control ------------------------------------------------------------------------------ PROCEDURE proc_dp_gen_block_data(CONSTANT c_nof_block_per_sync : IN NATURAL; CONSTANT c_block_size : IN NATURAL; CONSTANT c_gap_size : IN NATURAL; CONSTANT c_throttle_num : IN NATURAL; CONSTANT c_throttle_den : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL sync_nr : INOUT NATURAL; SIGNAL block_nr : INOUT NATURAL; SIGNAL cnt_sync : OUT STD_LOGIC; SIGNAL cnt_val : OUT STD_LOGIC; SIGNAL cnt_dat : INOUT STD_LOGIC_VECTOR) IS CONSTANT c_start_delay : NATURAL := 10; VARIABLE v_throttle : NATURAL; BEGIN sync_nr <= 0; block_nr <= 0; cnt_sync <= '0'; cnt_val <= '0'; cnt_dat <= (cnt_dat'RANGE=>'1'); -- -1, so first valid cnt_dat starts at 0 -- allow some clock cycles before start after rst release WAIT UNTIL rst='0'; FOR I IN 0 TO c_start_delay-1 LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- output first sync cnt_sync <= '1'; WAIT UNTIL rising_edge(clk); cnt_sync <= '0'; FOR I IN 1 TO c_gap_size-1 LOOP WAIT UNTIL rising_edge(clk); END LOOP; WHILE TRUE LOOP -- output block IF c_throttle_num >= c_throttle_den THEN -- no need to throttle, so cnt_val active during whole data block FOR I IN 0 TO c_block_size-1 LOOP cnt_val <= '1'; cnt_dat <= INCR_UVEC(cnt_dat, 1); WAIT UNTIL rising_edge(clk); END LOOP; ELSE -- throttle cnt_val, so c_throttle_num active cnt_val cycles per c_throttle_den cycles FOR I IN 0 TO c_block_size/c_throttle_num-1 LOOP FOR J IN 0 TO c_throttle_num-1 LOOP cnt_val <= '1'; cnt_dat <= INCR_UVEC(cnt_dat, 1); WAIT UNTIL rising_edge(clk); END LOOP; FOR J IN 0 TO c_throttle_den-c_throttle_num-1 LOOP cnt_val <= '0'; WAIT UNTIL rising_edge(clk); END LOOP; END LOOP; END IF; cnt_val <= '0'; -- output sync for next block at first sample of gap IF block_nr>0 AND ((block_nr + 1) MOD c_nof_block_per_sync)=0 THEN cnt_sync <= '1'; sync_nr <= sync_nr+1; END IF; WAIT UNTIL rising_edge(clk); -- output rest of the gap cnt_sync <= '0'; FOR I IN 1 TO c_gap_size-1 LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- next block block_nr <= block_nr+1; END LOOP; END proc_dp_gen_block_data; ------------------------------------------------------------------------------ -- PROCEDURE: Block data generator with ready flow control and symbols counter -- . dependent on in_en and src_in.ready -- . optional sync pulse at end of frame ------------------------------------------------------------------------------ PROCEDURE proc_dp_gen_block_data(CONSTANT c_ready_latency : IN NATURAL; -- 0, 1 are supported by proc_dp_stream_ready_latency() CONSTANT c_use_data : IN BOOLEAN; -- when TRUE use data field, else use re, im fields, and keep unused fields at 'X' CONSTANT c_data_w : IN NATURAL; -- data width for the data, re and im fields CONSTANT c_symbol_w : IN NATURAL; -- c_data_w/c_symbol_w must be an integer CONSTANT c_symbol_init : IN NATURAL; -- init counter for symbols in data field CONSTANT c_symbol_re_init : IN NATURAL; -- init counter for symbols in re field CONSTANT c_symbol_im_init : IN NATURAL; -- init counter for symbols in im field CONSTANT c_nof_symbols : IN NATURAL; -- nof symbols per frame for the data, re and im fields CONSTANT c_channel : IN NATURAL; -- channel field CONSTANT c_error : IN NATURAL; -- error field CONSTANT c_sync : IN STD_LOGIC; -- when '1' issue sync pulse during this block CONSTANT c_bsn : IN STD_LOGIC_VECTOR; -- bsn field SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi) IS CONSTANT c_nof_symbols_per_data : NATURAL := c_data_w/c_symbol_w; CONSTANT c_div : NATURAL := c_nof_symbols / c_nof_symbols_per_data; CONSTANT c_mod : NATURAL := c_nof_symbols MOD c_nof_symbols_per_data; CONSTANT c_empty : NATURAL := sel_a_b(c_mod, c_nof_symbols_per_data - c_mod, 0); CONSTANT c_nof_data : NATURAL := sel_a_b(c_mod, 1, 0) + c_div; VARIABLE v_data : STD_LOGIC_VECTOR(c_data_w-1 DOWNTO 0):= func_dp_data_init(c_data_w, c_symbol_w, c_symbol_init); VARIABLE v_re : STD_LOGIC_VECTOR(c_data_w-1 DOWNTO 0):= func_dp_data_init(c_data_w, c_symbol_w, c_symbol_re_init); VARIABLE v_im : STD_LOGIC_VECTOR(c_data_w-1 DOWNTO 0):= func_dp_data_init(c_data_w, c_symbol_w, c_symbol_im_init); BEGIN src_out <= c_dp_sosi_rst; IF src_in.xon='1' THEN -- Generate this block src_out.bsn <= RESIZE_DP_BSN(c_bsn); src_out.empty <= TO_DP_EMPTY(c_empty); src_out.channel <= TO_DP_CHANNEL(c_channel); src_out.err <= TO_DP_ERROR(c_error); IF c_use_data=TRUE THEN src_out.data <= RESIZE_DP_DATA(v_data); END IF; IF c_use_data=FALSE THEN src_out.re <= RESIZE_DP_DSP_DATA(v_re); END IF; IF c_use_data=FALSE THEN src_out.im <= RESIZE_DP_DSP_DATA(v_im); END IF; IF c_nof_data>1 THEN -- . sop proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, c_sync, '1', '1', '0', src_out.sync, src_out.valid, src_out.sop, src_out.eop); -- . valid FOR I IN 1 TO c_nof_data-2 LOOP v_data := func_dp_data_incr(c_data_w, c_symbol_w, v_data); v_re := func_dp_data_incr(c_data_w, c_symbol_w, v_re); v_im := func_dp_data_incr(c_data_w, c_symbol_w, v_im); IF c_use_data=TRUE THEN src_out.data <= RESIZE_DP_DATA(v_data); END IF; IF c_use_data=FALSE THEN src_out.re <= RESIZE_DP_DSP_DATA(v_re); END IF; IF c_use_data=FALSE THEN src_out.im <= RESIZE_DP_DSP_DATA(v_im); END IF; proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, '0', '1', '0', '0', src_out.sync, src_out.valid, src_out.sop, src_out.eop); END LOOP; -- . eop v_data := func_dp_data_incr(c_data_w, c_symbol_w, v_data); v_re := func_dp_data_incr(c_data_w, c_symbol_w, v_re); v_im := func_dp_data_incr(c_data_w, c_symbol_w, v_im); IF c_use_data=TRUE THEN src_out.data <= RESIZE_DP_DATA(v_data); END IF; IF c_use_data=FALSE THEN src_out.re <= RESIZE_DP_DSP_DATA(v_re); END IF; IF c_use_data=FALSE THEN src_out.im <= RESIZE_DP_DSP_DATA(v_im); END IF; proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, '0', '1', '0', '1', src_out.sync, src_out.valid, src_out.sop, src_out.eop); ELSE -- . sop and eop, frame has only one word proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, c_sync, '1', '1', '1', src_out.sync, src_out.valid, src_out.sop, src_out.eop); END IF; ELSE -- Skip this block proc_common_wait_some_cycles(clk, c_nof_data); END IF; END proc_dp_gen_block_data; PROCEDURE proc_dp_gen_block_data(CONSTANT c_data_w : IN NATURAL; -- data width for the data field CONSTANT c_symbol_init : IN NATURAL; -- init counter for the data in the data field CONSTANT c_nof_symbols : IN NATURAL; -- nof symbols per frame for the data fields CONSTANT c_channel : IN NATURAL; -- channel field CONSTANT c_error : IN NATURAL; -- error field CONSTANT c_sync : IN STD_LOGIC; -- when '1' issue sync pulse during this block CONSTANT c_bsn : IN STD_LOGIC_VECTOR; -- bsn field SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi) IS BEGIN proc_dp_gen_block_data(1, TRUE, c_data_w, c_data_w, c_symbol_init, 0, 0, c_nof_symbols, c_channel, c_error, c_sync, c_bsn, clk, in_en, src_in, src_out); END proc_dp_gen_block_data; ------------------------------------------------------------------------------ -- PROCEDURE: Handle stream ready signal -- . output active when src_in is ready and in_en='1' -- . only support RL=0 or 1, support for RL>1 requires keeping previous ready information in a STD_LOGIC_VECTOR(RL-1 DOWNTO 0). ------------------------------------------------------------------------------ PROCEDURE proc_dp_stream_ready_latency(CONSTANT c_latency : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL ready : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; CONSTANT c_sync : IN STD_LOGIC; CONSTANT c_valid : IN STD_LOGIC; CONSTANT c_sop : IN STD_LOGIC; CONSTANT c_eop : IN STD_LOGIC; SIGNAL out_sync : OUT STD_LOGIC; SIGNAL out_valid : OUT STD_LOGIC; SIGNAL out_sop : OUT STD_LOGIC; SIGNAL out_eop : OUT STD_LOGIC) IS BEGIN -- Default no output out_sync <= '0'; out_valid <= '0'; out_sop <= '0'; out_eop <= '0'; -- Skip cycles until in_en='1' WHILE in_en='0' LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- Active output when ready -- . RL = 0 IF c_latency=0 THEN -- show the available output until acknowledge out_sync <= c_sync; out_valid <= c_valid; out_sop <= c_sop; out_eop <= c_eop; WAIT UNTIL rising_edge(clk); WHILE ready /= '1' LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- ready has acknowledged the valid output END IF; -- . RL = 1 IF c_latency=1 THEN -- no valid output until request WHILE ready /= '1' LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- ready has requested this valid output out_sync <= c_sync; out_valid <= c_valid; out_sop <= c_sop; out_eop <= c_eop; WAIT UNTIL rising_edge(clk); END IF; -- Return with no active output out_sync <= '0'; out_valid <= '0'; out_sop <= '0'; out_eop <= '0'; END proc_dp_stream_ready_latency; ------------------------------------------------------------------------------ -- FUNCTION: Initialize the data per symbol -- . use big endian -- . if c_data_w=32, c_symbol_w=8, init=3 then return 0x03040506 ------------------------------------------------------------------------------ FUNCTION func_dp_data_init(c_data_w, c_symbol_w, init : NATURAL) RETURN STD_LOGIC_VECTOR IS CONSTANT c_nof_symbols_per_data : NATURAL := c_data_w/c_symbol_w; VARIABLE v_data : STD_LOGIC_VECTOR(c_data_w-1 DOWNTO 0); VARIABLE v_sym : STD_LOGIC_VECTOR(c_symbol_w-1 DOWNTO 0); BEGIN v_data := (OTHERS=>'0'); v_sym := TO_UVEC(init, c_symbol_w); FOR I IN c_nof_symbols_per_data-1 DOWNTO 0 LOOP v_data((I+1)*c_symbol_w-1 DOWNTO I*c_symbol_w) := v_sym; v_sym := INCR_UVEC(v_sym, 1); END LOOP; RETURN v_data; END func_dp_data_init; ------------------------------------------------------------------------------ -- FUNCTION: Increment the data per symbol -- . use big endian -- . if c_data_w=32, c_symbol_w=8 then 0x00010203 returns 0x04050607 -- . the actual data'LENGTH must be >= c_data_w, unused bits become 0 -- . c_data_w/c_symbol_w must be an integer ------------------------------------------------------------------------------ FUNCTION func_dp_data_incr(c_data_w, c_symbol_w : NATURAL; data : STD_LOGIC_VECTOR) RETURN STD_LOGIC_VECTOR IS CONSTANT c_nof_symbols_per_data : NATURAL := c_data_w/c_symbol_w; VARIABLE v_data : STD_LOGIC_VECTOR(data'LENGTH-1 DOWNTO 0); VARIABLE v_sym : STD_LOGIC_VECTOR(c_symbol_w-1 DOWNTO 0); BEGIN v_data := (OTHERS=>'0'); v_sym := data(c_symbol_w-1 DOWNTO 0); FOR I IN c_nof_symbols_per_data-1 DOWNTO 0 LOOP v_sym := INCR_UVEC(v_sym, 1); v_data((I+1)*c_symbol_w-1 DOWNTO I*c_symbol_w) := v_sym; END LOOP; RETURN v_data; END func_dp_data_incr; ------------------------------------------------------------------------------ -- PROCEDURE: Generate counter data with valid -- . Output counter data dependent on in_en and src_in.ready ------------------------------------------------------------------------------ PROCEDURE proc_dp_gen_data(CONSTANT c_ready_latency : IN NATURAL; -- 0, 1 are supported by proc_dp_stream_ready_latency() CONSTANT c_data_w : IN NATURAL; CONSTANT c_data_init : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi) IS VARIABLE v_data : STD_LOGIC_VECTOR(c_data_w-1 DOWNTO 0):= TO_UVEC(c_data_init, c_data_w); BEGIN src_out <= c_dp_sosi_rst; src_out.data <= RESIZE_DP_DATA(v_data); IF rst='0' THEN WAIT UNTIL rising_edge(clk); WHILE TRUE LOOP src_out.data <= RESIZE_DP_DATA(v_data); proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, '0', '1', '0', '0', src_out.sync, src_out.valid, src_out.sop, src_out.eop); v_data := INCR_UVEC(v_data, 1); END LOOP; END IF; END proc_dp_gen_data; ------------------------------------------------------------------------------ -- PROCEDURE: Generate counter data with valid -- . Output counter data dependent on in_en and src_in.ready -- . with maximum count value ------------------------------------------------------------------------------ PROCEDURE proc_dp_gen_data(CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_data_w : IN NATURAL; CONSTANT c_data_init : IN NATURAL; CONSTANT c_data_max : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi) IS VARIABLE v_cnt : STD_LOGIC_VECTOR(c_data_w-1 DOWNTO 0):= TO_UVEC(c_data_init, c_data_w); BEGIN src_out <= c_dp_sosi_rst; src_out.data <= RESIZE_DP_DATA(v_cnt); IF rst='0' THEN WAIT UNTIL rising_edge(clk); WHILE TRUE LOOP src_out.data <= RESIZE_DP_DATA(v_cnt); proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, '0', '1', '0', '0', src_out.sync, src_out.valid, src_out.sop, src_out.eop); IF TO_UINT(v_cnt)=c_data_max THEN v_cnt := TO_UVEC(c_data_init, c_data_w); ELSE v_cnt := INCR_UVEC(v_cnt, 1); END IF; END LOOP; END IF; END proc_dp_gen_data; ------------------------------------------------------------------------------ -- PROCEDURE: Generate a frame with symbols counter -- . dependent on in_en and src_in.ready ------------------------------------------------------------------------------ PROCEDURE proc_dp_gen_frame(CONSTANT c_ready_latency : IN NATURAL; -- 0, 1 are supported by proc_dp_stream_ready_latency() CONSTANT c_data_w : IN NATURAL; CONSTANT c_symbol_w : IN NATURAL; -- c_data_w/c_symbol_w must be an integer CONSTANT c_symbol_init : IN NATURAL; CONSTANT c_nof_symbols : IN NATURAL; CONSTANT c_bsn : IN NATURAL; CONSTANT c_sync : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; -- when '0' then no valid output even when src_in is ready SIGNAL src_in : IN t_dp_siso; SIGNAL src_out : OUT t_dp_sosi) IS CONSTANT c_nof_symbols_per_data : NATURAL := c_data_w/c_symbol_w; CONSTANT c_div : NATURAL := c_nof_symbols / c_nof_symbols_per_data; CONSTANT c_mod : NATURAL := c_nof_symbols MOD c_nof_symbols_per_data; CONSTANT c_empty : NATURAL := sel_a_b(c_mod, c_nof_symbols_per_data - c_mod, 0); CONSTANT c_nof_data : NATURAL := sel_a_b(c_mod, 1, 0) + c_div; VARIABLE v_data : STD_LOGIC_VECTOR(c_data_w-1 DOWNTO 0):= func_dp_data_init(c_data_w, c_symbol_w, c_symbol_init); BEGIN src_out <= c_dp_sosi_rst; src_out.bsn <= TO_DP_BSN(c_bsn); src_out.empty <= TO_DP_EMPTY(c_empty); src_out.data <= RESIZE_DP_DATA(v_data); IF c_nof_data>1 THEN -- . sop proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, c_sync, '1', '1', '0', src_out.sync, src_out.valid, src_out.sop, src_out.eop); -- . valid FOR I IN 1 TO c_nof_data-2 LOOP v_data := func_dp_data_incr(c_data_w, c_symbol_w, v_data); src_out.data <= RESIZE_DP_DATA(v_data); proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, '0', '1', '0', '0', src_out.sync, src_out.valid, src_out.sop, src_out.eop); END LOOP; -- . eop v_data := func_dp_data_incr(c_data_w, c_symbol_w, v_data); src_out.data <= RESIZE_DP_DATA(v_data); proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, '0', '1', '0', '1', src_out.sync, src_out.valid, src_out.sop, src_out.eop); ELSE -- . sop and eop, frame has only one word proc_dp_stream_ready_latency(c_ready_latency, clk, src_in.ready, in_en, c_sync, '1', '1', '1', src_out.sync, src_out.valid, src_out.sop, src_out.eop); END IF; src_out.sync <= '0'; src_out.valid <= '0'; src_out.sop <= '0'; src_out.eop <= '0'; END proc_dp_gen_frame; ------------------------------------------------------------------------------ -- PROCEDURE: Input data counter ------------------------------------------------------------------------------ PROCEDURE proc_dp_cnt_dat(SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; SIGNAL cnt_dat : INOUT STD_LOGIC_VECTOR) IS BEGIN IF rst='1' THEN cnt_dat <= (cnt_dat'RANGE=>'0'); ELSIF rising_edge(clk) THEN IF in_en='1' THEN cnt_dat <= STD_LOGIC_VECTOR(UNSIGNED(cnt_dat)+1); END IF; END IF; END proc_dp_cnt_dat; PROCEDURE proc_dp_cnt_dat(SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL in_en : IN STD_LOGIC; SIGNAL cnt_val : INOUT STD_LOGIC; SIGNAL cnt_dat : INOUT STD_LOGIC_VECTOR) IS BEGIN IF rst='1' THEN cnt_val <= '0'; cnt_dat <= (cnt_dat'RANGE=>'0'); ELSIF rising_edge(clk) THEN cnt_val <= '0'; IF in_en='1' THEN cnt_val <= '1'; cnt_dat <= STD_LOGIC_VECTOR(UNSIGNED(cnt_dat)+1); END IF; END IF; END proc_dp_cnt_dat; ------------------------------------------------------------------------------ -- PROCEDURE: Transmit data ------------------------------------------------------------------------------ PROCEDURE proc_dp_tx_data(CONSTANT c_ready_latency : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL cnt_val : IN STD_LOGIC; SIGNAL cnt_dat : IN STD_LOGIC_VECTOR; SIGNAL tx_data : INOUT t_dp_data_arr; SIGNAL tx_val : INOUT STD_LOGIC_VECTOR; SIGNAL out_data : OUT STD_LOGIC_VECTOR; SIGNAL out_val : OUT STD_LOGIC) IS CONSTANT c_void : NATURAL := sel_a_b(c_ready_latency, 1, 0); -- used to avoid empty range VHDL warnings when c_ready_latency=0 BEGIN -- TX data array for output ready latency [c_ready_latency], index [0] for zero latency combinatorial tx_data(0) <= cnt_dat; tx_val( 0) <= cnt_val; IF rst='1' THEN tx_data(1 TO c_ready_latency+c_void) <= (1 TO c_ready_latency+c_void=>(OTHERS=>'0')); tx_val( 1 TO c_ready_latency+c_void) <= (1 TO c_ready_latency+c_void=>'0'); ELSIF rising_edge(clk) THEN tx_data(1 TO c_ready_latency+c_void) <= tx_data(0 TO c_ready_latency+c_void-1); tx_val( 1 TO c_ready_latency+c_void) <= tx_val( 0 TO c_ready_latency+c_void-1); END IF; out_data <= tx_data(c_ready_latency); out_val <= tx_val(c_ready_latency); END proc_dp_tx_data; ------------------------------------------------------------------------------ -- PROCEDURE: Transmit data control (use for sop, eop) ------------------------------------------------------------------------------ PROCEDURE proc_dp_tx_ctrl(CONSTANT c_offset : IN NATURAL; CONSTANT c_period : IN NATURAL; SIGNAL data : IN STD_LOGIC_VECTOR; SIGNAL valid : IN STD_LOGIC; SIGNAL ctrl : OUT STD_LOGIC) IS VARIABLE v_data : INTEGER; BEGIN v_data := TO_UINT(data); ctrl <= '0'; IF valid='1' AND ((v_data-c_offset) MOD c_period)=0 THEN ctrl <= '1'; END IF; END proc_dp_tx_ctrl; ------------------------------------------------------------------------------ -- PROCEDURE: Define test sync interval ------------------------------------------------------------------------------ PROCEDURE proc_dp_sync_interval(SIGNAL clk : IN STD_LOGIC; SIGNAL sync : OUT STD_LOGIC) IS BEGIN sync <= '0'; FOR I IN 1 TO c_dp_sync_interval-1 LOOP WAIT UNTIL rising_edge(clk); END LOOP; sync <= '1'; WAIT UNTIL rising_edge(clk); END proc_dp_sync_interval; ------------------------------------------------------------------------------ -- PROCEDURE: Stimuli for cnt_en ------------------------------------------------------------------------------ PROCEDURE proc_dp_count_en(SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL sync : IN STD_LOGIC; SIGNAL lfsr : INOUT STD_LOGIC_VECTOR; SIGNAL state : OUT t_dp_state_enum; SIGNAL done : OUT STD_LOGIC; SIGNAL tb_end : OUT STD_LOGIC; SIGNAL cnt_en : OUT STD_LOGIC) IS BEGIN -- The counter operates at zero latency state <= s_idle; done <= '0'; tb_end <= '0'; cnt_en <= '0'; WAIT UNTIL rst='0'; WAIT UNTIL rising_edge(clk); -- The cnt_val may be asserted for every active in_ready, but als support -- cnt_val not asserted for every asserted in_ready. ---------------------------------------------------------------------------- -- Interval 1 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_both_active; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 2 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_pull_down_out_ready; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 3 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_pull_down_cnt_en; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 1 cycle cnt_en <= '0'; WAIT UNTIL rising_edge(clk); cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 2 cycle cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 3 cycle cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 4 cycle cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 5 cycle cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 6 cycle cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 7 cycle cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 4 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_toggle_out_ready; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 5 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_toggle_cnt_en; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 1-1 toggle cnt_en <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); cnt_en <= '0'; WAIT UNTIL rising_edge(clk); cnt_en <= '1'; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 1-2 toggle cnt_en <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 2-1 toggle cnt_en <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '0'; WAIT UNTIL rising_edge(clk); cnt_en <= '1'; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 2-2 toggle cnt_en <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 1-3 toggle cnt_en <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 3-1 toggle cnt_en <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '0'; WAIT UNTIL rising_edge(clk); cnt_en <= '1'; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 2-3 toggle cnt_en <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 3-2 toggle cnt_en <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); cnt_en <= '1'; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 6 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_toggle_both; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; FOR I IN 1 TO c_dp_nof_both LOOP cnt_en <= '0'; FOR J IN 1 TO I LOOP WAIT UNTIL rising_edge(clk); END LOOP; cnt_en <= '1'; FOR J IN I TO c_dp_nof_both LOOP WAIT UNTIL rising_edge(clk); END LOOP; END LOOP; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 7 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_pulse_cnt_en; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; FOR I IN 1 TO 15 LOOP FOR J IN 1 TO 15 LOOP cnt_en <= '0'; FOR K IN 1 TO I LOOP WAIT UNTIL rising_edge(clk); END LOOP; cnt_en <= '1'; WAIT UNTIL rising_edge(clk); END LOOP; FOR J IN 1 TO 20 LOOP WAIT UNTIL rising_edge(clk); END LOOP; END LOOP; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 8 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_chirp_out_ready; cnt_en <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 9 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_random; cnt_en <= '1'; FOR I IN 0 TO c_dp_sync_interval - c_dp_test_interval LOOP lfsr <= func_common_random(lfsr); cnt_en <= lfsr(lfsr'HIGH); WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Done ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; state <= s_done; WAIT UNTIL rising_edge(clk); cnt_en <= '0'; -- pulse done FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; done <= '1'; WAIT UNTIL rising_edge(clk); done <= '0'; ---------------------------------------------------------------------------- -- Testbench end ---------------------------------------------------------------------------- -- set tb_end WAIT UNTIL sync='1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; tb_end <= '1'; WAIT; END proc_dp_count_en; ------------------------------------------------------------------------------ -- PROCEDURE: Stimuli for out_ready ------------------------------------------------------------------------------ PROCEDURE proc_dp_out_ready(SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL sync : IN STD_LOGIC; SIGNAL lfsr : INOUT STD_LOGIC_VECTOR; SIGNAL out_ready : OUT STD_LOGIC) IS BEGIN out_ready <= '0'; WAIT UNTIL rst='0'; WAIT UNTIL rising_edge(clk); ---------------------------------------------------------------------------- -- Interval 1 : Assert both cnt_en and out_ready ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 2 : Make out_ready low for 1 or more cycles ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 1 cycle out_ready <= '0'; WAIT UNTIL rising_edge(clk); out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 2 cycle out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 3 cycle out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 4 cycle out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 5 cycle out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 6 cycle out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 7 cycle out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 3 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 4 : Toggle out_ready for 1 or more cycles ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 1-1 toggle out_ready <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); out_ready <= '0'; WAIT UNTIL rising_edge(clk); out_ready <= '1'; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 1-2 toggle out_ready <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 2-1 toggle out_ready <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '0'; WAIT UNTIL rising_edge(clk); out_ready <= '1'; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 2-2 toggle out_ready <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 1-3 toggle out_ready <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 3-1 toggle out_ready <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '0'; WAIT UNTIL rising_edge(clk); out_ready <= '1'; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 2-3 toggle out_ready <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . 3-2 toggle out_ready <= '0'; FOR I IN 1 TO c_dp_nof_toggle LOOP WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL rising_edge(clk); out_ready <= '1'; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 5 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 6 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; FOR I IN 1 TO c_dp_nof_both LOOP out_ready <= '0'; FOR J IN I TO c_dp_nof_both LOOP WAIT UNTIL rising_edge(clk); END LOOP; out_ready <= '1'; FOR J IN 1 TO I LOOP WAIT UNTIL rising_edge(clk); END LOOP; END LOOP; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 7 ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 8 : Chirp out_ready ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; -- . slow toggle out_ready <= '0'; FOR I IN 0 TO c_dp_nof_toggle LOOP out_ready <= '0'; FOR J IN 0 TO I LOOP WAIT UNTIL rising_edge(clk); END LOOP; out_ready <= '1'; FOR J IN 0 TO I LOOP WAIT UNTIL rising_edge(clk); END LOOP; END LOOP; out_ready <= '1'; FOR I IN 0 TO c_dp_test_interval LOOP WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Interval 9 : Random ---------------------------------------------------------------------------- WAIT UNTIL sync='1'; out_ready <= '1'; FOR I IN 0 TO c_dp_sync_interval - c_dp_test_interval LOOP lfsr <= func_common_random(lfsr); out_ready <= lfsr(lfsr'HIGH); WAIT UNTIL rising_edge(clk); END LOOP; ---------------------------------------------------------------------------- -- Done ---------------------------------------------------------------------------- WAIT; END proc_dp_out_ready; ------------------------------------------------------------------------------ -- PROCEDURE: DUT output verify enable ------------------------------------------------------------------------------ -- Fixed delay until verify_en active PROCEDURE proc_dp_verify_en(CONSTANT c_delay : IN NATURAL; SIGNAL rst : IN STD_LOGIC; SIGNAL clk : IN STD_LOGIC; SIGNAL sync : IN STD_LOGIC; SIGNAL verify_en : OUT STD_LOGIC) IS BEGIN verify_en <= '0'; WAIT UNTIL rst='0'; WAIT UNTIL rising_edge(clk); WAIT UNTIL sync='1'; -- Use c_delay delay before enabling the p_verify. FOR I IN 0 TO c_delay LOOP WAIT UNTIL rising_edge(clk); END LOOP; verify_en <= '1'; WAIT; END proc_dp_verify_en; -- Dynamicly depend on first valid data to make verify_en active PROCEDURE proc_dp_verify_en(CONSTANT c_continuous : IN BOOLEAN; SIGNAL clk : IN STD_LOGIC; SIGNAL valid : IN STD_LOGIC; SIGNAL sop : IN STD_LOGIC; SIGNAL eop : IN STD_LOGIC; SIGNAL verify_en : OUT STD_LOGIC) IS BEGIN IF rising_edge(clk) THEN IF c_continuous=TRUE THEN -- Verify across frames (so enable data verify after the first data has been output) IF valid='1' THEN verify_en <= '1'; END IF; ELSE -- Verify only per frame (so re-enable data verify after the every sop) IF eop='1' THEN verify_en <= '0'; ELSIF sop='1' THEN verify_en <= '1'; END IF; END IF; END IF; END proc_dp_verify_en; -- Run and verify for some cycles PROCEDURE proc_dp_verify_run_some_cycles(CONSTANT nof_pre_clk : IN NATURAL; CONSTANT nof_verify_clk : IN NATURAL; CONSTANT nof_post_clk : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : OUT STD_LOGIC) IS BEGIN proc_common_wait_some_cycles(clk, nof_pre_clk); verify_en <= '1'; proc_common_wait_some_cycles(clk, nof_verify_clk); verify_en <= '0'; proc_common_wait_some_cycles(clk, nof_post_clk); END proc_dp_verify_run_some_cycles; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the expected value ------------------------------------------------------------------------------ -- e.g. to check that a test has ran at all PROCEDURE proc_dp_verify_value(CONSTANT c_str : IN STRING; CONSTANT mode : IN t_dp_value_enum; SIGNAL clk : IN STD_LOGIC; SIGNAL en : IN STD_LOGIC; SIGNAL exp : IN STD_LOGIC_VECTOR; SIGNAL res : IN STD_LOGIC_VECTOR) IS BEGIN IF rising_edge(clk) THEN IF en='1' THEN IF mode = e_equal AND UNSIGNED(res) /= UNSIGNED(exp) THEN REPORT "DP : Wrong " & c_str & " result value" SEVERITY ERROR; END IF; IF mode = e_at_least AND UNSIGNED(res) < UNSIGNED(exp) THEN REPORT "DP : Wrong " & c_str & " result value too small" SEVERITY ERROR; END IF; END IF; END IF; END proc_dp_verify_value; PROCEDURE proc_dp_verify_value(CONSTANT mode : IN t_dp_value_enum; SIGNAL clk : IN STD_LOGIC; SIGNAL en : IN STD_LOGIC; SIGNAL exp : IN STD_LOGIC_VECTOR; SIGNAL res : IN STD_LOGIC_VECTOR) IS BEGIN proc_dp_verify_value("", mode, clk, en, exp, res); END proc_dp_verify_value; PROCEDURE proc_dp_verify_value(CONSTANT c_str : IN STRING; SIGNAL clk : IN STD_LOGIC; SIGNAL en : IN STD_LOGIC; SIGNAL exp : IN STD_LOGIC; SIGNAL res : IN STD_LOGIC) IS BEGIN IF rising_edge(clk) THEN IF en='1' THEN IF res /= exp THEN REPORT "DP : Wrong " & c_str & " result value" SEVERITY ERROR; END IF; END IF; END IF; END proc_dp_verify_value; ------------------------------------------------------------------------------ -- PROCEDURE: Verify output global and local BSN ------------------------------------------------------------------------------ -- Verify BSN: -- . incrementing or replicated global BSN -- . incrementing local BSN that starts at 1 -- -- _ _ _ _ -- sync __| |____________| |____________| |____________| |____________ -- _ _ _ _ _ _ _ _ _ _ _ _ -- sop __| |__| |__| |__| |__| |__| |__| |__| |__| |__| |__| |__| |__ c_block_per_sync = 3 -- -- c_use_local_bsn = FALSE: -- c_nof_replicated_global_bsn = 1 -- bsn 3 4 5 6 7 8 9 10 11 12 13 14 c_global_bsn_increment = 1 -- bsn 3 5 7 9 11 13 15 17 19 21 22 23 c_global_bsn_increment = 2 -- -- c_use_local_bsn = TRUE: -- -- global bsn 3 4 5 6 c_global_bsn_increment = 1, c_nof_replicated_global_bsn = 1 -- global bsn 3 6 9 12 c_global_bsn_increment = 3, c_nof_replicated_global_bsn = 1 -- global bsn 3 3 9 9 c_global_bsn_increment = 6, c_nof_replicated_global_bsn = 2 -- local bsn - 1 2 - 1 2 - 1 2 - 1 2 range 1:c_block_per_sync-1 -- -- The verify_en should initially be set to '0' and gets enabled when -- sufficient BSN history is available to do the verification. -- PROCEDURE proc_dp_verify_bsn(CONSTANT c_use_local_bsn : IN BOOLEAN; -- use local BSN or only use global BSN CONSTANT c_global_bsn_increment : IN POSITIVE; -- increment per global BSN CONSTANT c_nof_replicated_global_bsn : IN POSITIVE; -- number of replicated global BSN CONSTANT c_block_per_sync : IN POSITIVE; -- of sop/eop blocks per sync interval SIGNAL clk : IN STD_LOGIC; SIGNAL out_sync : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_bsn : IN STD_LOGIC_VECTOR; SIGNAL verify_en : INOUT STD_LOGIC; -- initialize '0', becomes '1' when bsn verification starts SIGNAL cnt_replicated_global_bsn : INOUT NATURAL; SIGNAL prev_out_bsn_global : INOUT STD_LOGIC_VECTOR; SIGNAL prev_out_bsn_local : INOUT STD_LOGIC_VECTOR) IS BEGIN IF rising_edge(clk) THEN -- out_sop must be active, because only then out_bsn will differ from the previous out_bsn IF out_sop='1' THEN IF c_use_local_bsn=FALSE THEN ------------------------------------------------------------------ -- Only use global BSN ------------------------------------------------------------------ prev_out_bsn_global <= out_bsn; -- verify IF out_sync='1' THEN verify_en <= '1'; END IF; IF verify_en='1' THEN ASSERT UNSIGNED(out_bsn) = UNSIGNED(prev_out_bsn_global)+c_global_bsn_increment REPORT "DP : Wrong BSN increment" SEVERITY ERROR; END IF; ELSE ------------------------------------------------------------------ -- Use global and local BSN ------------------------------------------------------------------ IF out_sync='1' THEN prev_out_bsn_global <= out_bsn; IF UNSIGNED(out_bsn) /= UNSIGNED(prev_out_bsn_global) THEN verify_en <= '1'; -- wait until after last replicated global bsn cnt_replicated_global_bsn <= 0; ELSE cnt_replicated_global_bsn <= cnt_replicated_global_bsn + 1; END IF; prev_out_bsn_local <= TO_UVEC(0, prev_out_bsn_global'LENGTH); ELSE prev_out_bsn_local <= out_bsn; END IF; -- verify IF verify_en='1' THEN IF out_sync='1' THEN IF UNSIGNED(out_bsn) /= UNSIGNED(prev_out_bsn_global) THEN ASSERT cnt_replicated_global_bsn=c_nof_replicated_global_bsn-1 REPORT "DP : Wrong number of replicated global BSN" SEVERITY ERROR; ASSERT UNSIGNED(out_bsn)=UNSIGNED(prev_out_bsn_global)+c_global_bsn_increment REPORT "DP : Wrong global BSN increment" SEVERITY ERROR; ELSE ASSERT UNSIGNED(out_bsn)=UNSIGNED(prev_out_bsn_global) REPORT "DP : Wrong replicated global BSN" SEVERITY ERROR; END IF; ASSERT UNSIGNED(prev_out_bsn_local)=c_block_per_sync-1 REPORT "DP : Wrong last local BSN in sync interval" SEVERITY ERROR; ELSE ASSERT UNSIGNED(out_bsn)=UNSIGNED(prev_out_bsn_local)+1 REPORT "DP : Wrong local BSN increment" SEVERITY ERROR; END IF; END IF; END IF; END IF; END IF; END proc_dp_verify_bsn; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the DUT output data ------------------------------------------------------------------------------ -- Verify incrementing data -- . wrap at c_out_data_max when >0, else no wrap when c_out_data_max=0 -- . default increment by 1, but also allow an increment by c_out_data_gap PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_out_data_max : IN UNSIGNED; CONSTANT c_out_data_gap : IN UNSIGNED; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; -- only needed when c_ready_latency = 0 SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR) IS BEGIN IF rising_edge(clk) THEN -- out_val must be active, because only the out_data will it differ from the previous out_data IF out_val='1' THEN -- for ready_latency > 0 out_val indicates new data -- for ready_latency = 0 out_val only indicates new data when it is confirmed by out_ready IF c_ready_latency/=0 OR (c_ready_latency=0 AND out_ready='1') THEN IF c_out_data_max=0 THEN prev_out_data <= out_data; -- no wrap detection ELSIF UNSIGNED(out_data)<c_out_data_max THEN prev_out_data <= out_data; -- no wrap ELSE prev_out_data <= TO_SVEC(-1, prev_out_data'LENGTH); -- do wrap END IF; IF verify_en='1' THEN IF UNSIGNED(out_data) /= UNSIGNED(prev_out_data)+1 AND -- check increment +1 UNSIGNED(out_data) /= UNSIGNED(prev_out_data)+c_out_data_gap AND -- increment +c_out_data_gap UNSIGNED(out_data) /= UNSIGNED(prev_out_data)+c_out_data_gap-c_out_data_max THEN -- increment +c_out_data_gap wrapped REPORT "DP : Wrong out_data " & c_str & " count" SEVERITY ERROR; END IF; END IF; END IF; END IF; END IF; END proc_dp_verify_data; -- Verify incrementing data that wraps in range 0 ... c_out_data_max PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_out_data_max : IN UNSIGNED; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR) IS BEGIN proc_dp_verify_data(c_str, c_ready_latency, c_out_data_max, TO_UNSIGNED(1,1), clk, verify_en, out_ready, out_val, out_data, prev_out_data); END proc_dp_verify_data; -- Verify incrementing data PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_ready_latency : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR) IS BEGIN proc_dp_verify_data(c_str, c_ready_latency, TO_UNSIGNED(0,1), TO_UNSIGNED(1,1), clk, verify_en, out_ready, out_val, out_data, prev_out_data); END proc_dp_verify_data; -- Verify incrementing data with RL > 0 or no flow control PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_out_data_max : IN UNSIGNED; CONSTANT c_out_data_gap : IN UNSIGNED; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR) IS BEGIN -- Use out_val as void signal to pass on to unused out_ready, because a signal input can not connect a constant or variable proc_dp_verify_data(c_str, 1, c_out_data_max, c_out_data_gap, clk, verify_en, out_val, out_val, out_data, prev_out_data); END proc_dp_verify_data; PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_out_data_max : IN NATURAL; CONSTANT c_out_data_gap : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR) IS CONSTANT c_data_w : NATURAL := out_data'LENGTH; BEGIN proc_dp_verify_data(c_str, TO_UNSIGNED(c_out_data_max, c_data_w), TO_UNSIGNED(c_out_data_gap, c_data_w), clk, verify_en, out_val, out_data, prev_out_data); END proc_dp_verify_data; PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; CONSTANT c_out_data_max : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR) IS CONSTANT c_data_w : NATURAL := out_data'LENGTH; BEGIN proc_dp_verify_data(c_str, TO_UNSIGNED(c_out_data_max, c_data_w), TO_UNSIGNED(1, 1), clk, verify_en, out_val, out_data, prev_out_data); END proc_dp_verify_data; PROCEDURE proc_dp_verify_data(CONSTANT c_str : IN STRING; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR) IS BEGIN -- Use out_val as void signal to pass on to unused out_ready, because a signal input can not connect a constant or variable proc_dp_verify_data(c_str, 1, TO_UNSIGNED(0,1), TO_UNSIGNED(1,1), clk, verify_en, out_val, out_val, out_data, prev_out_data); END proc_dp_verify_data; ------------------------------------------------------------------------------ -- PROCEDURE: Verify incrementing symbols in data -- . for c_data_w = c_symbol_w proc_dp_verify_symbols() = proc_dp_verify_data() ------------------------------------------------------------------------------ PROCEDURE proc_dp_verify_symbols(CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_data_w : IN NATURAL; CONSTANT c_symbol_w : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL out_empty : IN STD_LOGIC_VECTOR; SIGNAL prev_out_data : INOUT STD_LOGIC_VECTOR) IS CONSTANT c_nof_symbols_per_data : NATURAL := c_data_w/c_symbol_w; -- must be an integer CONSTANT c_empty_w : NATURAL := ceil_log2(c_nof_symbols_per_data); VARIABLE v_data : STD_LOGIC_VECTOR(c_data_w-1 DOWNTO 0); VARIABLE v_symbol : STD_LOGIC_VECTOR(c_symbol_w-1 DOWNTO 0); VARIABLE v_empty : NATURAL; BEGIN IF rising_edge(clk) THEN -- out_val must be active, because only the out_data will it differ from the previous out_data IF out_val='1' THEN -- for ready_latency > 0 out_val indicates new data -- for ready_latency = 0 out_val only indicates new data when it is confirmed by out_ready IF c_ready_latency/=0 OR (c_ready_latency=0 AND out_ready='1') THEN prev_out_data <= out_data; IF verify_en='1' THEN v_data := prev_out_data(c_data_w-1 DOWNTO 0); FOR I IN 0 TO c_nof_symbols_per_data-1 LOOP v_data((I+1)*c_symbol_w-1 DOWNTO I*c_symbol_w) := INCR_UVEC(v_data((I+1)*c_symbol_w-1 DOWNTO I*c_symbol_w), c_nof_symbols_per_data); -- increment each symbol END LOOP; IF out_eop='0' THEN IF UNSIGNED(out_data) /= UNSIGNED(v_data) THEN REPORT "DP : Wrong out_data symbols count" SEVERITY ERROR; END IF; ELSE v_empty := TO_UINT(out_empty(c_empty_w-1 DOWNTO 0)); IF UNSIGNED(out_data(c_data_w-1 DOWNTO v_empty*c_symbol_w)) /= UNSIGNED(v_data(c_data_w-1 DOWNTO v_empty*c_symbol_w)) THEN REPORT "DP : Wrong out_data symbols count at eop" SEVERITY ERROR; END IF; IF v_empty>0 THEN -- adjust prev_out_data for potentially undefined empty symbols in out_data v_symbol := v_data((v_empty+1)*c_symbol_w-1 DOWNTO v_empty*c_symbol_w); -- last valid symbol FOR I IN 0 TO c_nof_symbols_per_data-1 LOOP v_data((I+1)*c_symbol_w-1 DOWNTO I*c_symbol_w) := v_symbol; -- put the last valid symbol at the end of the v_data v_symbol := INCR_UVEC(v_symbol, -1); -- decrement each symbol towards the beginning of v_data END LOOP; prev_out_data <= v_data; END IF; END IF; END IF; END IF; END IF; END IF; END proc_dp_verify_symbols; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the DUT output data with empty -- . account for stream empty -- . support last word replace (e.g. by a CRC instead of the count, or use -- c_last_word=out_data for no replace) ------------------------------------------------------------------------------ PROCEDURE proc_dp_verify_data_empty(CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_last_word : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL out_eop_1 : INOUT STD_LOGIC; SIGNAL out_eop_2 : INOUT STD_LOGIC; SIGNAL out_data : IN STD_LOGIC_VECTOR; SIGNAL out_data_1 : INOUT STD_LOGIC_VECTOR; SIGNAL out_data_2 : INOUT STD_LOGIC_VECTOR; SIGNAL out_data_3 : INOUT STD_LOGIC_VECTOR; SIGNAL out_empty : IN STD_LOGIC_VECTOR; SIGNAL out_empty_1 : INOUT STD_LOGIC_VECTOR) IS VARIABLE v_last_word : STD_LOGIC_VECTOR(out_data'RANGE); VARIABLE v_ref_data : STD_LOGIC_VECTOR(out_data'RANGE); VARIABLE v_empty_data : STD_LOGIC_VECTOR(out_data'RANGE); BEGIN IF rising_edge(clk) THEN -- out_val must be active, because only then out_data will differ from the previous out_data IF out_val='1' THEN -- for ready_latency > 0 out_val indicates new data -- for ready_latency = 0 out_val only indicates new data when it is confirmed by out_ready IF c_ready_latency/=0 OR (c_ready_latency=0 AND out_ready='1') THEN -- default expected data out_data_1 <= out_data; out_data_2 <= out_data_1; out_data_3 <= out_data_2; out_empty_1 <= out_empty; out_eop_1 <= out_eop; out_eop_2 <= out_eop_1; IF verify_en='1' THEN -- assume sufficient valid cycles between eop and sop, so no need to check for out_sop with regard to eop empty IF out_eop='0' AND out_eop_1='0' AND out_eop_2='0'THEN -- verify out_data from eop-n to eop-2 and from eop+1 to eop+n, n>2 v_ref_data := INCR_UVEC(out_data_2, 1); IF UNSIGNED(out_data_1) /= UNSIGNED(v_ref_data) THEN REPORT "DP : Wrong out_data count" SEVERITY ERROR; END IF; ELSE -- the empty and crc replace affect data at eop_1 and eop, so need to check data from eop-2 to eop-1 to eop to eop+1 v_last_word := TO_UVEC(c_last_word, out_data'LENGTH); IF out_eop='1' THEN -- verify out_data at eop CASE TO_INTEGER(UNSIGNED(out_empty)) IS WHEN 0 => v_empty_data := v_last_word; WHEN 1 => v_empty_data := v_last_word(3*c_byte_w-1 DOWNTO 0) & c_slv0(1*c_byte_w-1 DOWNTO 0); WHEN 2 => v_empty_data := v_last_word(2*c_byte_w-1 DOWNTO 0) & c_slv0(2*c_byte_w-1 DOWNTO 0); WHEN 3 => v_empty_data := v_last_word(1*c_byte_w-1 DOWNTO 0) & c_slv0(3*c_byte_w-1 DOWNTO 0); WHEN OTHERS => NULL; END CASE; IF UNSIGNED(out_data) /= UNSIGNED(v_empty_data) THEN REPORT "DP : Wrong out_data count at eop" SEVERITY ERROR; END IF; ELSIF out_eop_1='1' THEN -- verify out_data from eop-2 to eop-1 v_ref_data := INCR_UVEC(out_data_3, 1); CASE TO_INTEGER(UNSIGNED(out_empty_1)) IS WHEN 0 => v_empty_data := v_ref_data; WHEN 1 => v_empty_data := v_ref_data(4*c_byte_w-1 DOWNTO 1*c_byte_w) & v_last_word(4*c_byte_w-1 DOWNTO 3*c_byte_w); WHEN 2 => v_empty_data := v_ref_data(4*c_byte_w-1 DOWNTO 2*c_byte_w) & v_last_word(4*c_byte_w-1 DOWNTO 2*c_byte_w); WHEN 3 => v_empty_data := v_ref_data(4*c_byte_w-1 DOWNTO 3*c_byte_w) & v_last_word(4*c_byte_w-1 DOWNTO 1*c_byte_w); WHEN OTHERS => NULL; END CASE; IF UNSIGNED(out_data_2) /= UNSIGNED(v_empty_data) THEN REPORT "DP : Wrong out_data count at eop-1" SEVERITY ERROR; END IF; -- verify out_data from eop-2 to eop+1 v_ref_data := INCR_UVEC(out_data_3, 3); IF UNSIGNED(out_data) /= UNSIGNED(v_ref_data) THEN REPORT "DP : Wrong out_data count at eop+1" SEVERITY ERROR; END IF; END IF; END IF; END IF; END IF; END IF; END IF; END proc_dp_verify_data_empty; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the DUT output other SOSI data -- . Suited to verify the empty, error, channel fields assuming that these -- are treated in the same way in parallel to the SOSI data. ------------------------------------------------------------------------------ PROCEDURE proc_dp_verify_other_sosi(CONSTANT c_str : IN STRING; CONSTANT c_exp_data : IN STD_LOGIC_VECTOR; -- use constant to support assignment via FUNCTION return value SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL res_data : IN STD_LOGIC_VECTOR) IS BEGIN IF rising_edge(clk) THEN IF verify_en='1' THEN IF c_str="bsn" THEN IF UNSIGNED(c_exp_data(c_dp_bsn_w-1 DOWNTO 0))/=UNSIGNED(res_data(c_dp_bsn_w-1 DOWNTO 0)) THEN REPORT "DP : Wrong sosi.bsn value" SEVERITY ERROR; END IF; ELSIF c_str="empty" THEN IF UNSIGNED(c_exp_data(c_dp_empty_w-1 DOWNTO 0))/=UNSIGNED(res_data(c_dp_empty_w-1 DOWNTO 0)) THEN REPORT "DP : Wrong sosi.empty value" SEVERITY ERROR; END IF; ELSIF c_str="channel" THEN IF UNSIGNED(c_exp_data(c_dp_channel_user_w-1 DOWNTO 0))/=UNSIGNED(res_data(c_dp_channel_user_w-1 DOWNTO 0)) THEN REPORT "DP : Wrong sosi.channel value" SEVERITY ERROR; END IF; ELSIF c_str="error" THEN IF UNSIGNED(c_exp_data(c_dp_error_w-1 DOWNTO 0))/=UNSIGNED(res_data(c_dp_error_w-1 DOWNTO 0)) THEN REPORT "DP : Wrong sosi.error value" SEVERITY ERROR; END IF; ELSE REPORT "proc_dp_verify_other_sosi : Unknown sosi." & c_str & "field" SEVERITY FAILURE; END IF; END IF; END IF; END proc_dp_verify_other_sosi; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the DUT output valid ------------------------------------------------------------------------------ PROCEDURE proc_dp_verify_valid(CONSTANT c_ready_latency : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL prev_out_ready : INOUT STD_LOGIC_VECTOR; SIGNAL out_val : IN STD_LOGIC) IS BEGIN IF rising_edge(clk) THEN -- for ready_latency > 0 out_val may only be asserted after out_ready -- for ready_latency = 0 out_val may always be asserted prev_out_ready <= (prev_out_ready'RANGE=>'0'); IF c_ready_latency/=0 THEN IF c_ready_latency=1 THEN prev_out_ready(0) <= out_ready; ELSE prev_out_ready <= out_ready & prev_out_ready(0 TO c_ready_latency-1); END IF; IF verify_en='1' AND out_val='1' THEN IF prev_out_ready(c_ready_latency-1)/='1' THEN REPORT "DP : Wrong ready latency between out_ready and out_val" SEVERITY ERROR; END IF; END IF; END IF; END IF; END proc_dp_verify_valid; PROCEDURE proc_dp_verify_valid(SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL prev_out_ready : INOUT STD_LOGIC; SIGNAL out_val : IN STD_LOGIC) IS BEGIN -- Can not reuse: -- proc_dp_verify_valid(1, clk, verify_en, out_ready, prev_out_ready, out_val); -- because prev_out_ready needs to map from STD_LOGIC to STD_LOGIC_VECTOR. Therefore copy paste code for RL=1: IF rising_edge(clk) THEN -- for ready_latency = 1 out_val may only be asserted after out_ready prev_out_ready <= out_ready; IF verify_en='1' AND out_val='1' THEN IF prev_out_ready/='1' THEN REPORT "DP : Wrong ready latency between out_ready and out_val" SEVERITY ERROR; END IF; END IF; END IF; END proc_dp_verify_valid; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the DUT output sync -- . sync is defined such that it can only be active at sop -- . assume that the sync occures priodically at bsn MOD c_sync_period = c_sync_offset ------------------------------------------------------------------------------ PROCEDURE proc_dp_verify_sync(CONSTANT c_sync_period : IN NATURAL; -- BSN sync period CONSTANT c_sync_offset : IN NATURAL; -- BSN sync offset SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL sync : IN STD_LOGIC; SIGNAL sop : IN STD_LOGIC; SIGNAL bsn : IN STD_LOGIC_VECTOR) IS CONSTANT c_bsn_w : NATURAL := sel_a_b(bsn'LENGTH>31, 31, bsn'LENGTH); -- use maximally 31 bit of BSN slv to allow calculations with integers VARIABLE v_expected_sync : BOOLEAN; BEGIN IF rising_edge(clk) THEN IF verify_en='1' THEN v_expected_sync := (TO_UINT(bsn(c_bsn_w-1 DOWNTO 0))-c_sync_offset) MOD c_sync_period = 0; -- Check for unexpected sync IF sync='1' THEN ASSERT v_expected_sync = TRUE REPORT "Error: Unexpected sync at BSN" SEVERITY ERROR; ASSERT sop = '1' REPORT "Error: Unexpected sync at inactive sop" SEVERITY ERROR; END IF; -- Check for missing sync IF sop='1' AND v_expected_sync=TRUE THEN ASSERT sync = '1' REPORT "Error: Missing sync" SEVERITY ERROR; END IF; END IF; END IF; END proc_dp_verify_sync; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the DUT output sop and eop ------------------------------------------------------------------------------ -- sop and eop in pairs, valid during packet and invalid between packets PROCEDURE proc_dp_verify_sop_and_eop(CONSTANT c_ready_latency : IN NATURAL; CONSTANT c_verify_valid : IN BOOLEAN; SIGNAL clk : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL hold_sop : INOUT STD_LOGIC) IS BEGIN IF rising_edge(clk) THEN IF out_val='0' THEN IF out_sop='1' THEN REPORT "DP : Wrong active sop during invalid" SEVERITY ERROR; END IF; IF out_eop='1' THEN REPORT "DP : Wrong active eop during invalid" SEVERITY ERROR; END IF; ELSE -- for ready_latency > 0 out_val indicates new data -- for ready_latency = 0 out_val only indicates new data when it is confirmed by out_ready IF c_ready_latency/=0 OR (c_ready_latency=0 AND out_ready='1') THEN IF out_sop='1' THEN hold_sop <= '1'; IF hold_sop='1' THEN REPORT "DP : Unexpected sop without eop" SEVERITY ERROR; END IF; END IF; IF out_eop='1' THEN hold_sop <= '0'; IF hold_sop='0' AND out_sop='0' THEN REPORT "DP : Unexpected eop without sop" SEVERITY ERROR; END IF; END IF; -- out_val='1' IF c_verify_valid=TRUE AND out_sop='0' AND hold_sop='0' THEN REPORT "DP : Unexpected valid in gap between eop and sop" SEVERITY ERROR; END IF; END IF; END IF; END IF; END proc_dp_verify_sop_and_eop; PROCEDURE proc_dp_verify_sop_and_eop(CONSTANT c_ready_latency : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL hold_sop : INOUT STD_LOGIC) IS BEGIN proc_dp_verify_sop_and_eop(c_ready_latency, TRUE, clk, out_ready, out_val, out_sop, out_eop, hold_sop); END proc_dp_verify_sop_and_eop; PROCEDURE proc_dp_verify_sop_and_eop(SIGNAL clk : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL hold_sop : INOUT STD_LOGIC) IS BEGIN -- Use out_val as void signal to pass on to unused out_ready, because a signal input can not connect a constant or variable proc_dp_verify_sop_and_eop(1, TRUE, clk, out_val, out_val, out_sop, out_eop, hold_sop); END proc_dp_verify_sop_and_eop; PROCEDURE proc_dp_verify_block_size(CONSTANT c_ready_latency : IN NATURAL; SIGNAL alt_size : IN NATURAL; -- alternative size SIGNAL exp_size : IN NATURAL; -- expected size SIGNAL clk : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL cnt_size : INOUT NATURAL) IS BEGIN IF rising_edge(clk) THEN IF out_val='1' THEN -- for ready_latency > 0 out_val indicates new data -- for ready_latency = 0 out_val only indicates new data when it is confirmed by out_ready IF c_ready_latency/=0 OR (c_ready_latency=0 AND out_ready='1') THEN IF out_sop='1' THEN cnt_size <= 1; ELSIF out_eop='1' THEN cnt_size <= 0; IF cnt_size/=alt_size-1 AND cnt_size/=exp_size-1 THEN REPORT "DP : Unexpected block size" SEVERITY ERROR; END IF; ELSE cnt_size <= cnt_size+1; END IF; END IF; END IF; END IF; END proc_dp_verify_block_size; PROCEDURE proc_dp_verify_block_size(CONSTANT c_ready_latency : IN NATURAL; SIGNAL exp_size : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL out_ready : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL cnt_size : INOUT NATURAL) IS BEGIN proc_dp_verify_block_size(c_ready_latency, exp_size, exp_size, clk, out_ready, out_val, out_sop, out_eop, cnt_size); END proc_dp_verify_block_size; PROCEDURE proc_dp_verify_block_size(SIGNAL alt_size : IN NATURAL; -- alternative size SIGNAL exp_size : IN NATURAL; -- expected size SIGNAL clk : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL cnt_size : INOUT NATURAL) IS BEGIN -- Use out_val as void signal to pass on to unused out_ready, because a signal input can not connect a constant or variable proc_dp_verify_block_size(1, alt_size, exp_size, clk, out_val, out_val, out_sop, out_eop, cnt_size); END proc_dp_verify_block_size; PROCEDURE proc_dp_verify_block_size(SIGNAL exp_size : IN NATURAL; SIGNAL clk : IN STD_LOGIC; SIGNAL out_val : IN STD_LOGIC; SIGNAL out_sop : IN STD_LOGIC; SIGNAL out_eop : IN STD_LOGIC; SIGNAL cnt_size : INOUT NATURAL) IS BEGIN -- Use out_val as void signal to pass on to unused out_ready, because a signal input can not connect a constant or variable proc_dp_verify_block_size(1, exp_size, exp_size, clk, out_val, out_val, out_sop, out_eop, cnt_size); END proc_dp_verify_block_size; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the DUT output invalid between frames ------------------------------------------------------------------------------ PROCEDURE proc_dp_verify_gap_invalid(SIGNAL clk : IN STD_LOGIC; SIGNAL in_val : IN STD_LOGIC; SIGNAL in_sop : IN STD_LOGIC; SIGNAL in_eop : IN STD_LOGIC; SIGNAL out_gap : INOUT STD_LOGIC) IS BEGIN IF rising_edge(clk) THEN IF in_eop='1' THEN out_gap <= '1'; ELSIF in_sop='1' THEN out_gap <= '0'; ELSIF in_val='1' AND out_gap='1' THEN REPORT "DP : Wrong valid in gap between eop and sop" SEVERITY ERROR; END IF; END IF; END proc_dp_verify_gap_invalid; ------------------------------------------------------------------------------ -- PROCEDURE: Verify the DUT output control (use for sop, eop) ------------------------------------------------------------------------------ PROCEDURE proc_dp_verify_ctrl(CONSTANT c_offset : IN NATURAL; CONSTANT c_period : IN NATURAL; CONSTANT c_str : IN STRING; SIGNAL clk : IN STD_LOGIC; SIGNAL verify_en : IN STD_LOGIC; SIGNAL data : IN STD_LOGIC_VECTOR; SIGNAL valid : IN STD_LOGIC; SIGNAL ctrl : IN STD_LOGIC) IS VARIABLE v_data : INTEGER; BEGIN IF rising_edge(clk) THEN IF verify_en='1' THEN v_data := TO_UINT(data); IF ((v_data-c_offset) MOD c_period)=0 THEN IF valid='1' AND ctrl/='1' THEN REPORT "DP : Wrong data control, missing " & c_str SEVERITY ERROR; END IF; ELSE IF ctrl='1' THEN REPORT "DP : Wrong data control, unexpected " & c_str SEVERITY ERROR; END IF; END IF; END IF; END IF; END proc_dp_verify_ctrl; ------------------------------------------------------------------------------ -- PROCEDURE: Wait for stream valid ------------------------------------------------------------------------------ PROCEDURE proc_dp_stream_valid(SIGNAL clk : IN STD_LOGIC; SIGNAL in_valid : IN STD_LOGIC) IS BEGIN WAIT UNTIL rising_edge(clk); WHILE in_valid /= '1' LOOP WAIT UNTIL rising_edge(clk); END LOOP; END proc_dp_stream_valid; ------------------------------------------------------------------------------ -- PROCEDURE: Wait for stream valid AND sop ------------------------------------------------------------------------------ PROCEDURE proc_dp_stream_valid_sop(SIGNAL clk : IN STD_LOGIC; SIGNAL in_valid : IN STD_LOGIC; SIGNAL in_sop : IN STD_LOGIC) IS BEGIN WAIT UNTIL rising_edge(clk); WHILE in_valid /= '1' AND in_sop /= '1' LOOP WAIT UNTIL rising_edge(clk); END LOOP; END proc_dp_stream_valid_sop; ------------------------------------------------------------------------------ -- PROCEDURE: Wait for stream valid AND eop ------------------------------------------------------------------------------ PROCEDURE proc_dp_stream_valid_eop(SIGNAL clk : IN STD_LOGIC; SIGNAL in_valid : IN STD_LOGIC; SIGNAL in_eop : IN STD_LOGIC) IS BEGIN WAIT UNTIL rising_edge(clk); WHILE in_valid /= '1' AND in_eop /= '1' LOOP WAIT UNTIL rising_edge(clk); END LOOP; END proc_dp_stream_valid_eop; END tb_dp_pkg;
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