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////////////////////////////////////////////////////////////////////// //// //// //// dbg_tb.v //// //// //// //// //// //// This file is part of the SoC/OpenRISC Development Interface //// //// http://www.opencores.org/projects/DebugInterface/ //// //// //// //// Author(s): //// //// Igor Mohor (igorm@opencores.org) //// //// //// //// //// //// All additional information is avaliable in the README.txt //// //// file. //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2000 - 2004 Authors //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source is distributed in the hope that it will be //// //// useful, but WITHOUT ANY WARRANTY; without even the implied //// //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR //// //// PURPOSE. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// // // CVS Revision History // // $Log: not supported by cvs2svn $ // Revision 1.35 2004/01/22 11:07:28 mohor // test stall_test added. // // Revision 1.34 2004/01/20 14:24:08 mohor // Define name changed. // // Revision 1.33 2004/01/20 14:05:26 mohor // Data latching changed when testing WB. // // Revision 1.32 2004/01/20 10:23:21 mohor // More debug data added. // // Revision 1.31 2004/01/20 09:07:44 mohor // CRC generation iand verification in bench changed. // // Revision 1.30 2004/01/20 08:03:35 mohor // IDCODE test improved. // // Revision 1.29 2004/01/19 13:13:18 mohor // Define tap_defines.v added to test bench. // // Revision 1.28 2004/01/19 12:38:10 mohor // Waiting for "ready" improved. // // Revision 1.27 2004/01/17 18:01:31 mohor // New version. // // Revision 1.26 2004/01/17 17:01:25 mohor // Almost finished. // // Revision 1.25 2004/01/16 14:51:24 mohor // cpu registers added. // // Revision 1.24 2004/01/15 10:47:13 mohor // Working. // // Revision 1.23 2004/01/14 22:59:01 mohor // Temp version. // // Revision 1.22 2004/01/13 11:28:30 mohor // tmp version. // // Revision 1.21 2004/01/10 07:50:41 mohor // temp version. // // Revision 1.20 2004/01/09 12:49:23 mohor // tmp version. // // Revision 1.19 2004/01/08 17:53:12 mohor // tmp version. // // Revision 1.18 2004/01/07 11:59:48 mohor // temp4 version. // // Revision 1.17 2004/01/06 17:14:59 mohor // temp3 version. // // Revision 1.16 2004/01/05 12:16:50 mohor // tmp2 version. // // Revision 1.15 2003/12/23 14:26:01 mohor // New version of the debug interface. Not finished, yet. // // Revision 1.14 2003/10/23 16:16:30 mohor // CRC logic changed. // // Revision 1.13 2003/08/28 13:54:33 simons // Three more chains added for cpu debug access. // // Revision 1.12 2002/05/07 14:44:52 mohor // mon_cntl_o signals that controls monitor mux added. // // Revision 1.11 2002/03/12 14:32:26 mohor // Few outputs for boundary scan chain added. // // Revision 1.10 2002/03/08 15:27:08 mohor // Structure changed. Hooks for jtag chain added. // // Revision 1.9 2001/10/19 11:39:20 mohor // dbg_timescale.v changed to timescale.v This is done for the simulation of // few different cores in a single project. // // Revision 1.8 2001/10/17 10:39:17 mohor // bs_chain_o added. // // Revision 1.7 2001/10/16 10:10:18 mohor // Signal names changed to lowercase. // // Revision 1.6 2001/10/15 09:52:50 mohor // Wishbone interface added, few fixes for better performance, // hooks for boundary scan testing added. // // Revision 1.5 2001/09/24 14:06:12 mohor // Changes connected to the OpenRISC access (SPR read, SPR write). // // Revision 1.4 2001/09/20 10:10:29 mohor // Working version. Few bugs fixed, comments added. // // Revision 1.3 2001/09/19 11:54:03 mohor // Minor changes for simulation. // // Revision 1.2 2001/09/18 14:12:43 mohor // Trace fixed. Some registers changed, trace simplified. // // Revision 1.1.1.1 2001/09/13 13:49:19 mohor // Initial official release. // // Revision 1.3 2001/06/01 22:23:40 mohor // This is a backup. It is not a fully working version. Not for use, yet. // // Revision 1.2 2001/05/18 13:10:05 mohor // Headers changed. All additional information is now avaliable in the README.txt file. // // Revision 1.1.1.1 2001/05/18 06:35:15 mohor // Initial release // // `include "timescale.v" `include "tap_defines.v" `include "dbg_defines.v" `include "dbg_wb_defines.v" `include "dbg_cpu_defines.v" // Test bench module dbg_tb; parameter TCLK = 50; // Clock half period (Clok period = 100 ns => 10 MHz) reg tms_pad_i; reg tck_pad_i; reg trst_pad_i; reg tdi_pad_i; wire tdo_pad_o; wire tdo_padoe_o; wire shift_dr_o; wire pause_dr_o; wire update_dr_o; wire capture_dr_o; wire extest_select_o; wire sample_preload_select_o; wire mbist_select_o; wire debug_select_o; // WISHBONE common signals reg wb_rst_i; reg wb_clk_i; // WISHBONE master interface wire [31:0] wb_adr_o; wire [31:0] wb_dat_o; wire [31:0] wb_dat_i; wire wb_cyc_o; wire wb_stb_o; wire [3:0] wb_sel_o; wire wb_we_o; wire wb_ack_i; wire wb_cab_o; wire wb_err_i; wire [2:0] wb_cti_o; wire [1:0] wb_bte_o; // CPU signals wire cpu_clk_i; wire [31:0] cpu_addr_o; wire [31:0] cpu_data_i; wire [31:0] cpu_data_o; wire cpu_bp_i; wire cpu_stall_o; wire cpu_stall_all_o; wire cpu_stb_o; wire [`CPU_NUM -1:0] cpu_sel_o; wire cpu_we_o; wire cpu_ack_i; wire cpu_rst_o; // Text used for easier debugging reg [199:0] test_text; reg [2:0] last_wb_cmd; reg [199:0] last_wb_cmd_text; reg [31:0] wb_data [0:4095]; // Data that is written to (read from) wishbone is stored here. wire tdo_o; wire debug_tdi_i; wire bs_chain_tdi_i; wire mbist_tdi_i; reg test_enabled; reg [31:0] result; reg [31:0] in_data_le, in_data_be; reg [31:0] id; wire crc_match_in; reg [31:0] crc_in; reg [31:0] crc_out; wire tdo; assign tdo = tdo_padoe_o? tdo_pad_o : 1'hz; // Connecting TAP module tap_top i_tap_top ( .tms_pad_i (tms_pad_i), .tck_pad_i (tck_pad_i), .trst_pad_i (!trst_pad_i), .tdi_pad_i (tdi_pad_i), .tdo_pad_o (tdo_pad_o), .tdo_padoe_o (tdo_padoe_o), // TAP states .shift_dr_o (shift_dr_o), .pause_dr_o (pause_dr_o), .update_dr_o (update_dr_o), .capture_dr_o (capture_dr_o), // Select signals for boundary scan or mbist .extest_select_o (extest_select_o), .sample_preload_select_o(sample_preload_select_o), .mbist_select_o (mbist_select_o), .debug_select_o (debug_select_o), // TDO signal that is connected to TDI of sub-modules. .tdo_o (tdo_o), // TDI signals from sub-modules .debug_tdi_i (debug_tdi_i), // from debug module .bs_chain_tdi_i (bs_chain_tdi_i), // from Boundary Scan Chain .mbist_tdi_i (mbist_tdi_i) // from Mbist Chain ); // Connecting debug top module dbg_top i_dbg_top ( .tck_i (tck_pad_i), .tdi_i (tdo_o), .tdo_o (debug_tdi_i), // TAP states .shift_dr_i (shift_dr_o), .pause_dr_i (pause_dr_o), .update_dr_i (update_dr_o), // Instructions .debug_select_i (debug_select_o), // WISHBONE common signals .wb_rst_i (wb_rst_i), .wb_clk_i (wb_clk_i), // WISHBONE master interface .wb_adr_o (wb_adr_o), .wb_dat_o (wb_dat_o), .wb_dat_i (wb_dat_i), .wb_cyc_o (wb_cyc_o), .wb_stb_o (wb_stb_o), .wb_sel_o (wb_sel_o), .wb_we_o (wb_we_o), .wb_ack_i (wb_ack_i), .wb_cab_o (wb_cab_o), .wb_err_i (wb_err_i), .wb_cti_o (wb_cti_o), .wb_bte_o (wb_bte_o), // CPU signals .cpu_clk_i (cpu_clk_i), .cpu_addr_o (cpu_addr_o), .cpu_data_i (cpu_data_i), .cpu_data_o (cpu_data_o), .cpu_bp_i (cpu_bp_i), .cpu_stall_o (cpu_stall_o), .cpu_stall_all_o (cpu_stall_all_o), .cpu_stb_o (cpu_stb_o), .cpu_sel_o (cpu_sel_o), .cpu_we_o (cpu_we_o), .cpu_ack_i (cpu_ack_i), .cpu_rst_o (cpu_rst_o) ); wb_slave_behavioral wb_slave ( .CLK_I (wb_clk_i), .RST_I (wb_rst_i), .ACK_O (wb_ack_i), .ADR_I (wb_adr_o), .CYC_I (wb_cyc_o), .DAT_O (wb_dat_i), .DAT_I (wb_dat_o), .ERR_O (wb_err_i), .RTY_O (), // NOT USED for now! .SEL_I (wb_sel_o), .STB_I (wb_stb_o), .WE_I (wb_we_o), .CAB_I (1'b0) ); cpu_behavioral i_cpu_behavioral ( // CPU signals .cpu_rst_i (wb_rst_i), .cpu_clk_o (cpu_clk_i), .cpu_addr_i (cpu_addr_o), .cpu_data_o (cpu_data_i), .cpu_data_i (cpu_data_o), .cpu_bp_o (cpu_bp_i), .cpu_stall_i (cpu_stall_o), .cpu_stall_all_i (cpu_stall_all_o), .cpu_stb_i (cpu_stb_o), .cpu_sel_i (cpu_sel_o), .cpu_we_i (cpu_we_o), .cpu_ack_o (cpu_ack_i), .cpu_rst_o (cpu_rst_o) ); // Initial values initial begin trst_pad_i = 1'b1; tms_pad_i = 1'hz; tck_pad_i = 1'hz; tdi_pad_i = 1'hz; #100; trst_pad_i = 1'b0; #100; trst_pad_i = 1'b1; end initial begin test_enabled = 1'b0; wb_rst_i = 1'b0; #1000; wb_rst_i = 1'b1; #1000; wb_rst_i = 1'b0; // Initial values for wishbone slave model wb_slave.cycle_response(`ACK_RESPONSE, 9'h55, 8'h2); // (`ACK_RESPONSE, wbs_waits, wbs_retries); #1 test_enabled<=#1 1'b1; end initial begin wb_clk_i = 1'b0; forever #5 wb_clk_i = ~wb_clk_i; end always @ (posedge test_enabled) begin $display("//////////////////////////////////////////////////////////////////"); $display("// //"); $display("// (%0t) dbg_tb starting //", $time); $display("// //"); $display("//////////////////////////////////////////////////////////////////"); initialize_memory(32'h12340000, 32'h00100000); // Initialize 0x100000 bytes starting from address 0x12340000 reset_tap; #500; goto_run_test_idle; // Test stall signal stall_test; // Testing read and write to internal registers #10000; set_instruction(`IDCODE); read_id_code(id); $display("\tRead ID = 0x%0x", id); $display("\tExpected ID = 0x%0x", `IDCODE_VALUE); set_instruction(`DEBUG); #10000; chain_select(`WISHBONE_DEBUG_CHAIN, 1'b0); // {chain, gen_crc_err} // #10000; // xxx(4'b1001, 32'he579b242); #10000; // debug_wishbone(`WB_READ8, 1'b0, 32'h12345678, 16'h4, 1'b0, "abc 1"); // {command, ready, addr, length, gen_crc_err, text} // debug_wishbone(`WB_READ8, 1'b0, 32'h12345679, 16'h4, 1'b0, "abc 2"); // {command, ready, addr, length, gen_crc_err, text} // debug_wishbone(`WB_READ8, 1'b0, 32'h1234567a, 16'h4, 1'b0, "abc 3"); // {command, ready, addr, length, gen_crc_err, text} // // debug_wishbone(`WB_READ16, 1'b0, 32'h12345678, 16'h4, 1'b0, "abc 4"); // {command, ready, addr, length, gen_crc_err, text} // debug_wishbone(`WB_READ16, 1'b0, 32'h1234567a, 16'h4, 1'b0, "abc 5"); // {command, ready, addr, length, gen_crc_err, text} // debug_wishbone(`WB_READ32, 1'b0, 32'h12345678, 16'h4, 1'b0, "read32 1"); // {command, ready, addr, length, gen_crc_err, text} // // debug_wishbone(`WB_READ16, 1'b0, 32'h12345679, 16'h4, 1'b0, "abc 6"); // {command, ready, addr, length, gen_crc_err, text} #10000; // xxx(4'b1001, 32'he579b242); debug_wishbone(`WB_READ32, 1'b1, 32'h12345678, 16'h4, 1'b0, "read32 2"); // {command, ready, addr, length, gen_crc_err, text} #10000; wb_slave.cycle_response(`ACK_RESPONSE, 9'h55, 8'h2); // (`ACK_RESPONSE, wbs_waits, wbs_retries); debug_wishbone(`WB_READ32, 1'b1, 32'h12346668, 16'h4, 1'b0, "read32 3"); // {command, ready, addr, length, gen_crc_err, text} #10000; wb_slave.cycle_response(`ERR_RESPONSE, 9'h03, 8'h2); // (`ERR_RESPONSE, wbs_waits, wbs_retries); debug_wishbone(`WB_READ32, 1'b1, 32'h12346668, 16'h4, 1'b0, "read32 4"); // {command, ready, addr, length, gen_crc_err, text} #10000; debug_wishbone(`WB_STATUS, 1'b0, 32'h0, 16'h0, 1'b0, "status 1"); // {command, ready, addr, length, gen_crc_err, text} #10000; debug_wishbone(`WB_STATUS, 1'b0, 32'h0, 16'h0, 1'b0, "status 2"); // {command, ready, addr, length, gen_crc_err, text} #10000; wb_slave.cycle_response(`ACK_RESPONSE, 9'h012, 8'h2); // (`ACK_RESPONSE, wbs_waits, wbs_retries); debug_wishbone(`WB_READ32, 1'b1, 32'h12347778, 16'hc, 1'b0, "read32 5"); // {command, ready, addr, length, gen_crc_err, text} #10000; debug_wishbone(`WB_WRITE32, 1'b0, 32'h12346668, 16'h8, 1'b0, "wr32 len8"); // {command, ready, addr, length, gen_crc_err, text} #10000; debug_wishbone(`WB_WRITE16, 1'b0, 32'h12344446, 16'h8, 1'b0, "wr16 len8"); // {command, ready, addr, length, gen_crc_err, text} #10000; debug_wishbone(`WB_WRITE8, 1'b0, 32'h1234010e, 16'h8, 1'b0, "wr8 len8"); // {command, ready, addr, length, gen_crc_err, text} #10000; debug_wishbone(`WB_GO, 1'b0, 32'h0, 16'h0, 1'b0, "go 1"); // {command, ready, addr, length, gen_crc_err, text} #10000; debug_wishbone(`WB_READ32, 1'b1, 32'h12340100, 16'hc, 1'b0, "read32 6"); // {command, ready, addr, length, gen_crc_err, text} // debug_wishbone(`WB_READ32, 1'b1, 32'h12340100, 16'hfffc, 1'b0, "read32 6"); // {command, ready, addr, length, gen_crc_err, text} #10000; // debug_wishbone(`WB_READ16, 1'b1, 32'h12340102, 16'he, 1'b0, "read16 7"); // {command, ready, addr, length, gen_crc_err, text} // debug_wishbone(`WB_READ16, 1'b1, 32'h12340102, 16'hfffe, 1'b0, "read16 7"); // {command, ready, addr, length, gen_crc_err, text} #10000; // debug_wishbone(`WB_READ8, 1'b1, 32'h12348804, 16'h6, 1'b0, "read8 8"); // {command, ready, addr, length, gen_crc_err, text} // debug_wishbone(`WB_READ8, 1'b1, 32'h12348804, 16'hfffc, 1'b0, "read8 8"); // {command, ready, addr, length, gen_crc_err, text} #10000; debug_wishbone(`WB_GO, 1'b0, 32'h0, 16'h0, 1'b0, "go 2"); // {command, ready, addr, length, gen_crc_err, text} #10000; chain_select(`CPU_DEBUG_CHAIN, 1'b0); // {chain, gen_crc_err} // Select cpu0 #10000; debug_cpu(`CPU_WRITE_REG, `CPU_SEL_ADR, 32'h0, 1'b0, result, "select cpu 0"); // {command, addr, data, gen_crc_err, result, text} #10000; debug_cpu(`CPU_GO, 32'h0, 32'h1, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} // Read register #10000; debug_cpu(`CPU_READ_REG, `CPU_SEL_ADR, 32'h0, 1'b0, result, "cpu_read_reg"); // {command, addr, data, gen_crc_err, result, text} #10000; debug_cpu(`CPU_GO, 32'h0, 32'hff, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} // Stall cpu0 #10000; debug_cpu(`CPU_WRITE_REG, `CPU_OP_ADR, 32'h0, 1'b0, result, "stall cpu0"); // {command, addr, data, gen_crc_err, result, text} #10000; debug_cpu(`CPU_GO, 32'h0, 32'h1, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} // write to cpu 32-bit #10000; debug_cpu(`CPU_WRITE32, 32'h32323232, 32'h0, 1'b0, result, "cpu_write_32"); // {command, addr, data, gen_crc_err, result, text} #10000; debug_cpu(`CPU_GO, 32'h0, 32'hdeadbeef, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} // read from cpu 32-bit #10000; debug_cpu(`CPU_READ32, 32'h32323232, 32'h0, 1'b0, result, "cpu_read_32"); // {command, addr, data, gen_crc_err, result, text} #10000; debug_cpu(`CPU_GO, 32'h0, 32'hdeadbeef, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} // write to cpu 8-bit #10000; debug_cpu(`CPU_WRITE8, 32'h08080808, 32'h0, 1'b0, result, "cpu_write_8"); // {command, addr, data, gen_crc_err, result, text} #10000; debug_cpu(`CPU_GO, 32'h0, 32'hdeadbeef, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} // read from cpu 8-bit #10000; debug_cpu(`CPU_READ8, 32'h08080808, 32'h0, 1'b0, result, "cpu_read_8"); // {command, addr, data, gen_crc_err, result, text} #10000; debug_cpu(`CPU_GO, 32'h0, 32'hdeadbeef, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} #5000 gen_clk(1); // One extra TCLK for debugging purposes $display("\n\nSimulation end."); #1000 $stop; end task stall_test; integer i; begin test_text = "stall_test"; $display("\n\n(%0t) stall_test started", $time); // Set bp_i active for 1 clock cycle and check is stall is set or not check_stall(0); // Should not be set at the beginning @ (posedge wb_clk_i); #1 dbg_tb.i_cpu_behavioral.cpu_bp_o = 1'b1; #1 check_stall(1); // set? @ (posedge wb_clk_i); #1 dbg_tb.i_cpu_behavioral.cpu_bp_o = 1'b0; #1 check_stall(1); // set? gen_clk(1); #1 check_stall(1); // set? // Unstall with register set_instruction(`DEBUG); chain_select(`CPU_DEBUG_CHAIN, 1'b0); // {chain, gen_crc_err} #1 check_stall(1); // set? debug_cpu(`CPU_WRITE_REG, `CPU_OP_ADR, 32'h0, 1'b0, result, "clr unstall"); // {command, addr, data, gen_crc_err, result, text} #1 check_stall(1); // set? debug_cpu(`CPU_GO, 32'h0, 32'h0, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} #1 check_stall(0); // reset? // Set stall with register debug_cpu(`CPU_WRITE_REG, `CPU_OP_ADR, 32'h0, 1'b0, result, "clr stall"); // {command, addr, data, gen_crc_err, result, text} #1 check_stall(0); // reset? debug_cpu(`CPU_GO, 32'h0, 32'h1, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} #1 check_stall(1); // set? // Unstall with register debug_cpu(`CPU_WRITE_REG, `CPU_OP_ADR, 32'h0, 1'b0, result, "clr unstall"); // {command, addr, data, gen_crc_err, result, text} #1 check_stall(1); // set? debug_cpu(`CPU_GO, 32'h0, 32'h0, 1'b0, result, "go cpu"); // {command, addr, data, gen_crc_err, result, text} #1 check_stall(0); // reset? $display("\n\n(%0t) stall_test passed\n\n", $time); end endtask // stall_test task check_stall; input should_be_set; begin if (should_be_set && (!cpu_stall_o)) begin $display ("\t\t(%0t) ERROR: cpu_stall_o is not set but should be.", $time); $stop; end if ((!should_be_set) && cpu_stall_o) begin $display ("\t\t(%0t) ERROR: cpu_stall_o set but shouldn't be.", $time); $stop; end end endtask // check_stall task initialize_memory; input [31:0] start_addr; input [31:0] length; integer i; reg [31:0] addr; begin for (i=0; i<length; i=i+4) // This data will be return from wb slave begin addr = start_addr + i; wb_slave.wr_mem(addr, {addr[7:0], addr[7:0]+2'd1, addr[7:0]+2'd2, addr[7:0]+2'd3}, 4'hf); // adr, data, sel end for (i=0; i<4096; i=i+1) // This data will be written to wb slave begin wb_data[i] <= {i[7:0], i[7:0]+2'd1, i[7:0]+2'd2, i[7:0]+2'd3}; end end endtask // Generation of the TCLK signal task gen_clk; input [7:0] num; integer i; begin for(i=0; i<num; i=i+1) begin #TCLK tck_pad_i<=1; #TCLK tck_pad_i<=0; end end endtask // TAP reset task reset_tap; begin $display("(%0t) Task reset_tap", $time); tms_pad_i<=#1 1'b1; gen_clk(5); end endtask // Goes to RunTestIdle state task goto_run_test_idle; begin $display("(%0t) Task goto_run_test_idle", $time); tms_pad_i<=#1 1'b0; gen_clk(1); end endtask // sets the instruction to the IR register and goes to the RunTestIdle state task set_instruction; input [3:0] instr; integer i; begin case (instr) `EXTEST : $display("(%0t) Task set_instruction (EXTEST)", $time); `SAMPLE_PRELOAD : $display("(%0t) Task set_instruction (SAMPLE_PRELOAD)", $time); `IDCODE : $display("(%0t) Task set_instruction (IDCODE)", $time); `DEBUG : $display("(%0t) Task set_instruction (DEBUG)", $time); `MBIST : $display("(%0t) Task set_instruction (MBIST)", $time); `BYPASS : $display("(%0t) Task set_instruction (BYPASS)", $time); default begin $display("(%0t) Task set_instruction (Unsupported instruction !!!)", $time); $display("\tERROR: Unsupported instruction !!!", $time); $stop; end endcase tms_pad_i<=#1 1; gen_clk(2); tms_pad_i<=#1 0; gen_clk(2); // we are in shiftIR for(i=0; i<`IR_LENGTH-1; i=i+1) begin tdi_pad_i<=#1 instr[i]; gen_clk(1); end tdi_pad_i<=#1 instr[i]; // last shift tms_pad_i<=#1 1; // going out of shiftIR gen_clk(1); tdi_pad_i<=#1 'hz; // tri-state gen_clk(1); tms_pad_i<=#1 0; gen_clk(1); // we are in RunTestIdle end endtask // Reads the ID code task read_id_code; output [31:0] code; reg [31:0] code; begin $display("(%0t) Task read_id_code", $time); tms_pad_i<=#1 1; gen_clk(1); tms_pad_i<=#1 0; gen_clk(2); // we are in shiftDR tdi_pad_i<=#1 0; gen_clk(31); tms_pad_i<=#1 1; // going out of shiftIR gen_clk(1); code = in_data_le; tdi_pad_i<=#1 'hz; // tri-state gen_clk(1); tms_pad_i<=#1 0; gen_clk(1); // we are in RunTestIdle end endtask // sets the selected scan chain and goes to the RunTestIdle state task chain_select; input [3:0] data; input gen_crc_err; integer i; begin case (data) `CPU_DEBUG_CHAIN : $display("(%0t) Task chain_select (CPU_DEBUG_CHAIN, gen_crc_err=%0d)", $time, gen_crc_err); `WISHBONE_DEBUG_CHAIN : $display("(%0t) Task chain_select (WISHBONE_DEBUG_CHAIN, gen_crc_err=%0d)", $time, gen_crc_err); default : $display("(%0t) Task chain_select (ERROR!!! Unknown chain selected)", $time); endcase tms_pad_i<=#1 1; gen_clk(1); tms_pad_i<=#1 0; gen_clk(2); // we are in shiftDR crc_out = 32'hffffffff; // Initialize outgoing CRC tdi_pad_i<=#1 1'b1; // chain_select bit calculate_crc(1'b1); gen_clk(1); for(i=0; i<`CHAIN_ID_LENGTH; i=i+1) begin tdi_pad_i<=#1 data[i]; calculate_crc(data[i]); gen_clk(1); end for(i=31; i>=0; i=i-1) begin if (gen_crc_err & (i==0)) // Generate crc error at last crc bit tdi_pad_i<=#1 ~crc_out[i]; // error crc else tdi_pad_i<=#1 crc_out[i]; // ok crc gen_clk(1); end tdi_pad_i<=#1 'hz; // tri-state crc_in = 32'hffffffff; // Initialize incoming CRC gen_clk(`STATUS_LEN); // Generating 4 clocks to read out status. for(i=0; i<`CRC_LEN -1; i=i+1) gen_clk(1); tms_pad_i<=#1 1; gen_clk(1); // to exit1_dr if (~crc_match_in) begin $display("(%0t) Incoming CRC failed !!!", $time); $stop; end tms_pad_i<=#1 1; gen_clk(1); // to update_dr tms_pad_i<=#1 0; gen_clk(1); // to run_test_idle end endtask // chain_select task debug_wishbone; input [2:0] command; input ready; input [31:0] addr; input [15:0] length; input gen_crc_err; input [99:0] text; integer i; begin $write("(%0t) Task debug_wishbone: ", $time); test_text = text; case (command) `WB_STATUS : begin $display("wb_status (gen_crc_err=%0d (%0s))", gen_crc_err, text); debug_wishbone_status(command, gen_crc_err); last_wb_cmd = `WB_STATUS; last_wb_cmd_text = "WB_STATUS"; end `WB_READ8 : begin $display("wb_read8 (adr=0x%0x, length=0x%0x, gen_crc_err=%0d (%0s))", addr, length, gen_crc_err, text); debug_wishbone_set_addr(command, addr, length, gen_crc_err); last_wb_cmd = `WB_READ8; last_wb_cmd_text = "WB_READ8"; end `WB_READ16 : begin $display("wb_read16 (adr=0x%0x, length=0x%0x, gen_crc_err=%0d (%0s))", addr, length, gen_crc_err, text); debug_wishbone_set_addr(command, addr, length, gen_crc_err); last_wb_cmd = `WB_READ16; last_wb_cmd_text = "WB_READ16"; end `WB_READ32 : begin $display("wb_read32 (adr=0x%0x, length=0x%0x, gen_crc_err=%0d (%0s))", addr, length, gen_crc_err, text); debug_wishbone_set_addr(command, addr, length, gen_crc_err); last_wb_cmd = `WB_READ32; last_wb_cmd_text = "WB_READ32"; end `WB_WRITE8 : begin $display("wb_write8 (adr=0x%0x, length=0x%0x, gen_crc_err=%0d (%0s))", addr, length, gen_crc_err, text); debug_wishbone_set_addr(command, addr, length, gen_crc_err); last_wb_cmd = `WB_WRITE8; last_wb_cmd_text = "WB_WRITE8"; end `WB_WRITE16 : begin $display("wb_write16 (adr=0x%0x, length=0x%0x, gen_crc_err=%0d (%0s))", addr, length, gen_crc_err, text); debug_wishbone_set_addr(command, addr, length, gen_crc_err); last_wb_cmd = `WB_WRITE16; last_wb_cmd_text = "WB_WRITE16"; end `WB_WRITE32 : begin $display("wb_write32 (adr=0x%0x, length=0x%0x, gen_crc_err=%0d (%0s))", addr, length, gen_crc_err, text); debug_wishbone_set_addr(command, addr, length, gen_crc_err); last_wb_cmd = `WB_WRITE32; last_wb_cmd_text = "WB_WRITE32"; end `WB_GO : begin $display("wb_go, ready=%0d, gen_crc_err=%0d (%0s))", ready, gen_crc_err, text); debug_wishbone_go(command, ready, gen_crc_err); // $display("wb_go_tmp, gen_crc_err=0x%0x (%0s))", gen_crc_err, text); // debug_wishbone_go_tmp(command, crc); last_wb_cmd = `WB_GO; last_wb_cmd_text = "WB_GO"; end endcase end endtask // debug_wishbone task debug_wishbone_set_addr; input [2:0] command; input [31:0] addr; input [15:0] length; input gen_crc_err; integer i; begin $display("(%0t) Task debug_wishbone_set_addr: ", $time); tms_pad_i<=#1 1; gen_clk(1); tms_pad_i<=#1 0; gen_clk(2); // we are in shiftDR crc_out = 32'hffffffff; // Initialize outgoing CRC tdi_pad_i<=#1 1'b0; // chain_select bit = 0 calculate_crc(1'b0); gen_clk(1); for(i=2; i>=0; i=i-1) begin tdi_pad_i<=#1 command[i]; // command calculate_crc(command[i]); gen_clk(1); end for(i=31; i>=0; i=i-1) // address begin tdi_pad_i<=#1 addr[i]; calculate_crc(addr[i]); gen_clk(1); end for(i=15; i>=0; i=i-1) // length begin tdi_pad_i<=#1 length[i]; calculate_crc(length[i]); gen_clk(1); end for(i=31; i>=0; i=i-1) begin if (gen_crc_err & (i==0)) // Generate crc error at last crc bit tdi_pad_i<=#1 ~crc_out[i]; // error crc else tdi_pad_i<=#1 crc_out[i]; // ok crc gen_clk(1); end tdi_pad_i<=#1 'hz; crc_in = 32'hffffffff; // Initialize incoming CRC gen_clk(`STATUS_LEN); // Generating 4 clocks to read out status. for(i=0; i<`CRC_LEN -1; i=i+1) // Getting in the CRC begin gen_clk(1); end tms_pad_i<=#1 1; gen_clk(1); // to exit1_dr if (~crc_match_in) begin $display("(%0t) Incoming CRC failed !!!", $time); $stop; end tms_pad_i<=#1 1; gen_clk(1); // to update_dr tms_pad_i<=#1 0; gen_clk(1); // to run_test_idle end endtask // debug_wishbone_set_addr task debug_wishbone_status; input [2:0] command; input gen_crc_err; integer i; begin $display("(%0t) Task debug_wishbone_status: ", $time); tms_pad_i<=#1 1; gen_clk(1); tms_pad_i<=#1 0; gen_clk(2); // we are in shiftDR crc_out = 32'hffffffff; // Initialize outgoing CRC tdi_pad_i<=#1 1'b0; // chain_select bit = 0 calculate_crc(1'b0); gen_clk(1); for(i=2; i>=0; i=i-1) begin tdi_pad_i<=#1 command[i]; // command calculate_crc(command[i]); gen_clk(1); end for(i=31; i>=0; i=i-1) begin if (gen_crc_err & (i==0)) // Generate crc error at last crc bit tdi_pad_i<=#1 ~crc_out[i]; // error crc else tdi_pad_i<=#1 crc_out[i]; // ok crc gen_clk(1); end tdi_pad_i<=#1 1'hz; crc_in = 32'hffffffff; // Initialize incoming CRC gen_clk(`STATUS_LEN); // Generating 4 clocks to read out status. for(i=0; i<`CRC_LEN -1; i=i+1) // Getting in the CRC begin gen_clk(1); end tms_pad_i<=#1 1; gen_clk(1); // to exit1_dr if (~crc_match_in) begin $display("(%0t) Incoming CRC failed !!!", $time); $stop; end tms_pad_i<=#1 1; gen_clk(1); // to update_dr tms_pad_i<=#1 0; gen_clk(1); // to run_test_idle end endtask // debug_wishbone_status task debug_wishbone_go; input [2:0] command; input wait_for_wb_ready; input gen_crc_err; integer i; reg [4:0] bit_pointer; integer word_pointer; reg [31:0] tmp_data; begin $display("(%0t) Task debug_wishbone_go (previous command was %0s): ", $time, last_wb_cmd_text); word_pointer = 0; tms_pad_i<=#1 1; gen_clk(1); tms_pad_i<=#1 0; gen_clk(2); // we are in shiftDR crc_out = 32'hffffffff; // Initialize outgoing CRC tdi_pad_i<=#1 1'b0; // chain_select bit = 0 calculate_crc(1'b0); gen_clk(1); for(i=2; i>=0; i=i-1) begin tdi_pad_i<=#1 command[i]; // command calculate_crc(command[i]); gen_clk(1); end if ((last_wb_cmd == `WB_WRITE8) | (last_wb_cmd == `WB_WRITE16) | (last_wb_cmd == `WB_WRITE32)) // When WB_WRITEx was previously activated, data needs to be shifted. begin for (i=0; i<(dbg_tb.i_dbg_top.i_dbg_wb.len << 3); i=i+1) begin tmp_data = wb_data[word_pointer]; if ((!(i%32)) && (i>0)) begin word_pointer = word_pointer + 1; end bit_pointer = 31-i[4:0]; tdi_pad_i<=#1 tmp_data[bit_pointer]; calculate_crc(tmp_data[bit_pointer]); gen_clk(1); end end for(i=31; i>=1; i=i-1) begin tdi_pad_i<=#1 crc_out[i]; gen_clk(1); end if (gen_crc_err) // Generate crc error at last crc bit tdi_pad_i<=#1 ~crc_out[0]; // error crc else tdi_pad_i<=#1 crc_out[0]; // ok crc if (wait_for_wb_ready) begin tms_pad_i<=#1 1; gen_clk(1); // to exit1_dr. Last CRC is shifted on this clk tms_pad_i<=#1 0; gen_clk(1); // to pause_dr #2; // wait a bit for tdo to activate while (tdo) // waiting for wb to send "ready" begin gen_clk(1); // staying in pause_dr end tms_pad_i<=#1 1; gen_clk(1); // to exit2_dr tms_pad_i<=#1 0; gen_clk(1); // to shift_dr end else begin gen_clk(1); // Last CRC is shifted on this clk end tdi_pad_i<=#1 1'hz; crc_in = 32'hffffffff; // Initialize incoming CRC if ((last_wb_cmd == `WB_READ8) | (last_wb_cmd == `WB_READ16) | (last_wb_cmd == `WB_READ32)) // When WB_READx was previously activated, data needs to be shifted. begin $display("\t\tGenerating %0d clocks to read %0d data bytes.", dbg_tb.i_dbg_top.i_dbg_wb.data_cnt_limit, dbg_tb.i_dbg_top.i_dbg_wb.data_cnt_limit>>3); word_pointer = 0; // Reset pointer for (i=0; i<(dbg_tb.i_dbg_top.i_dbg_wb.data_cnt_limit); i=i+1) begin gen_clk(1); if (i[4:0] == 31) // Latching data begin wb_data[word_pointer] = in_data_be; $display("\t\tin_data_be = 0x%x", in_data_be); word_pointer = word_pointer + 1; end end end gen_clk(`STATUS_LEN); // Generating 4 clocks to read out status. for(i=0; i<`CRC_LEN -1; i=i+1) // Getting in the CRC begin gen_clk(1); end tms_pad_i<=#1 1; gen_clk(1); // to exit1_dr if (~crc_match_in) begin $display("(%0t) Incoming CRC failed !!!", $time); $stop; end tms_pad_i<=#1 1; gen_clk(1); // to update_dr tms_pad_i<=#1 0; gen_clk(1); // to run_test_idle end endtask // debug_wishbone_go task debug_cpu; input [2:0] command; input [31:0] addr; input [31:0] data; input gen_crc_err; output [31:0] result; input [199:0] text; integer i; begin $write("(%0t) Task debug_cpu: ", $time); test_text = text; case (command) // `WB_STATUS : // begin // $display("wb_status (gen_crc_err=%0d (%0s))", gen_crc_err, text); // debug_wishbone_status(command, gen_crc_err); // last_wb_cmd = `WB_STATUS; last_wb_cmd_text = "WB_STATUS"; // end `CPU_READ_REG : begin $display("cpu_read_reg (adr=0x%0x, gen_crc_err=%0d (%0s))", addr, gen_crc_err, text); debug_cpu_set_addr(command, addr, gen_crc_err); last_wb_cmd = `CPU_READ_REG; last_wb_cmd_text = "CPU_READ_REG"; end `CPU_WRITE_REG : begin $display("cpu_write_reg (adr=0x%0x, gen_crc_err=%0d (%0s))", addr, gen_crc_err, text); debug_cpu_set_addr(command, addr, gen_crc_err); last_wb_cmd = `CPU_WRITE_REG; last_wb_cmd_text = "CPU_WRITE_REG"; end `CPU_READ8 : begin $display("cpu_read8 (adr=0x%0x, gen_crc_err=%0d (%0s))", addr, gen_crc_err, text); debug_cpu_set_addr(command, addr, gen_crc_err); last_wb_cmd = `CPU_READ8; last_wb_cmd_text = "CPU_READ8"; end `CPU_READ32 : begin $display("cpu_read32 (adr=0x%0x, gen_crc_err=%0d (%0s))", addr, gen_crc_err, text); debug_cpu_set_addr(command, addr, gen_crc_err); last_wb_cmd = `CPU_READ32; last_wb_cmd_text = "CPU_READ32"; end `CPU_WRITE8 : begin $display("cpu_write8 (adr=0x%0x, gen_crc_err=%0d (%0s))", addr, gen_crc_err, text); debug_cpu_set_addr(command, addr, gen_crc_err); last_wb_cmd = `CPU_WRITE8; last_wb_cmd_text = "CPU_WRITE8"; end `CPU_WRITE32 : begin $display("cpu_write32 (adr=0x%0x, gen_crc_err=%0d (%0s))", addr, gen_crc_err, text); debug_cpu_set_addr(command, addr, gen_crc_err); last_wb_cmd = `CPU_WRITE32; last_wb_cmd_text = "CPU_WRITE32"; end `CPU_GO : begin $display("cpu_go, data = 0x%0x, gen_crc_err=%0d (%0s))", data, gen_crc_err, text); debug_cpu_go(command, data, gen_crc_err); last_wb_cmd = `CPU_GO; last_wb_cmd_text = "CPU_GO"; end default : begin $display("\t\tERROR: Non-existing command while debugging %0s", gen_crc_err, text); $stop; end endcase end endtask // debug_cpu task debug_cpu_set_addr; input [2:0] command; input [31:0] addr; input gen_crc_err; integer i; begin $display("(%0t) Task debug_cpu_set_addr: ", $time); tms_pad_i<=#1 1; gen_clk(1); tms_pad_i<=#1 0; gen_clk(2); // we are in shiftDR crc_out = 32'hffffffff; // Initialize outgoing CRC tdi_pad_i<=#1 1'b0; // chain_select bit = 0 calculate_crc(1'b0); gen_clk(1); for(i=2; i>=0; i=i-1) begin tdi_pad_i<=#1 command[i]; // command calculate_crc(command[i]); gen_clk(1); end for(i=31; i>=0; i=i-1) // address begin tdi_pad_i<=#1 addr[i]; calculate_crc(addr[i]); gen_clk(1); end for(i=31; i>=0; i=i-1) begin if (gen_crc_err & (i==0)) // Generate crc error at last crc bit tdi_pad_i<=#1 ~crc_out[i]; // error crc else tdi_pad_i<=#1 crc_out[i]; // ok crc gen_clk(1); end tdi_pad_i<=#1 'hz; crc_in = 32'hffffffff; // Initialize incoming CRC gen_clk(`STATUS_LEN); // Generating 4 clocks to read out status. for(i=0; i<`CRC_LEN -1; i=i+1) // Getting in the CRC begin gen_clk(1); end tms_pad_i<=#1 1; gen_clk(1); // to exit1_dr if (~crc_match_in) begin $display("(%0t) Incoming CRC failed !!!", $time); $stop; end tms_pad_i<=#1 1; gen_clk(1); // to update_dr tms_pad_i<=#1 0; gen_clk(1); // to run_test_idle end endtask // debug_cpu_set_addr task debug_cpu_go; input [2:0] command; input [31:0] data; input gen_crc_err; integer i, len; begin $display("(%0t) Task debug_cpu_go (previous command was %0s): ", $time, last_wb_cmd_text); tms_pad_i<=#1 1; gen_clk(1); tms_pad_i<=#1 0; gen_clk(2); // we are in shiftDR crc_out = 32'hffffffff; // Initialize outgoing CRC tdi_pad_i<=#1 1'b0; // chain_select bit = 0 calculate_crc(1'b0); gen_clk(1); for(i=2; i>=0; i=i-1) begin tdi_pad_i<=#1 command[i]; // command calculate_crc(command[i]); gen_clk(1); end if (last_wb_cmd == `CPU_WRITE32) begin len = 31; $display("\t\tdata = 0x%x", data); end else if ((last_wb_cmd == `CPU_WRITE8) | (last_wb_cmd == `CPU_WRITE_REG)) begin len = 7; $display("\t\tdata = 0x%x", data[7:0]); end else len = 0; if (len>0) // When CPU_WRITEx was previously activated, data needs to be shifted. begin for (i=len; i>=0; i=i-1) begin tdi_pad_i<=#1 data[i]; calculate_crc(data[i]); gen_clk(1); end end for(i=31; i>=0; i=i-1) begin if (gen_crc_err & (i==0)) // Generate crc error at last crc bit tdi_pad_i<=#1 ~crc_out[i]; // error crc else tdi_pad_i<=#1 crc_out[i]; // ok crc gen_clk(1); end tdi_pad_i<=#1 1'hz; crc_in = 32'hffffffff; // Initialize incoming CRC if (last_wb_cmd == `CPU_READ32) len = 32; else if ((last_wb_cmd == `CPU_READ8) | (last_wb_cmd == `CPU_READ_REG)) len = 8; else len = 0; if (len>0) // When CPU_READx was previously activated, data needs to be shifted. begin $display("\t\tGenerating %0d clocks to read out the data.", len); for (i=0; i<len; i=i+1) gen_clk(1); end gen_clk(`STATUS_LEN); // Generating 4 clocks to read out status. for(i=0; i<`CRC_LEN -1; i=i+1) // Getting in the CRC begin gen_clk(1); end tms_pad_i<=#1 1; gen_clk(1); // to exit1_dr if (~crc_match_in) begin $display("(%0t) Incoming CRC failed !!!", $time); $stop; end tms_pad_i<=#1 1; gen_clk(1); // to update_dr tms_pad_i<=#1 0; gen_clk(1); // to run_test_idle end endtask // debug_cpu_go always @ (posedge tck_pad_i) begin in_data_be[31:1] <= #1 in_data_be[30:0]; in_data_be[0] <= #1 tdo; in_data_le[31] <= #1 tdo; in_data_le[30:0] <= #1 in_data_le[31:1]; end // Calculating outgoing CRC task calculate_crc; input data; begin crc_out[0] <= #1 data ^ crc_out[31]; crc_out[1] <= #1 data ^ crc_out[0] ^ crc_out[31]; crc_out[2] <= #1 data ^ crc_out[1] ^ crc_out[31]; crc_out[3] <= #1 crc_out[2]; crc_out[4] <= #1 data ^ crc_out[3] ^ crc_out[31]; crc_out[5] <= #1 data ^ crc_out[4] ^ crc_out[31]; crc_out[6] <= #1 crc_out[5]; crc_out[7] <= #1 data ^ crc_out[6] ^ crc_out[31]; crc_out[8] <= #1 data ^ crc_out[7] ^ crc_out[31]; crc_out[9] <= #1 crc_out[8]; crc_out[10] <= #1 data ^ crc_out[9] ^ crc_out[31]; crc_out[11] <= #1 data ^ crc_out[10] ^ crc_out[31]; crc_out[12] <= #1 data ^ crc_out[11] ^ crc_out[31]; crc_out[13] <= #1 crc_out[12]; crc_out[14] <= #1 crc_out[13]; crc_out[15] <= #1 crc_out[14]; crc_out[16] <= #1 data ^ crc_out[15] ^ crc_out[31]; crc_out[17] <= #1 crc_out[16]; crc_out[18] <= #1 crc_out[17]; crc_out[19] <= #1 crc_out[18]; crc_out[20] <= #1 crc_out[19]; crc_out[21] <= #1 crc_out[20]; crc_out[22] <= #1 data ^ crc_out[21] ^ crc_out[31]; crc_out[23] <= #1 data ^ crc_out[22] ^ crc_out[31]; crc_out[24] <= #1 crc_out[23]; crc_out[25] <= #1 crc_out[24]; crc_out[26] <= #1 data ^ crc_out[25] ^ crc_out[31]; crc_out[27] <= #1 crc_out[26]; crc_out[28] <= #1 crc_out[27]; crc_out[29] <= #1 crc_out[28]; crc_out[30] <= #1 crc_out[29]; crc_out[31] <= #1 crc_out[30]; end endtask // calculate_crc // Calculating and checking input CRC always @(posedge tck_pad_i) begin crc_in[0] <= #1 tdo ^ crc_in[31]; crc_in[1] <= #1 tdo ^ crc_in[0] ^ crc_in[31]; crc_in[2] <= #1 tdo ^ crc_in[1] ^ crc_in[31]; crc_in[3] <= #1 crc_in[2]; crc_in[4] <= #1 tdo ^ crc_in[3] ^ crc_in[31]; crc_in[5] <= #1 tdo ^ crc_in[4] ^ crc_in[31]; crc_in[6] <= #1 crc_in[5]; crc_in[7] <= #1 tdo ^ crc_in[6] ^ crc_in[31]; crc_in[8] <= #1 tdo ^ crc_in[7] ^ crc_in[31]; crc_in[9] <= #1 crc_in[8]; crc_in[10] <= #1 tdo ^ crc_in[9] ^ crc_in[31]; crc_in[11] <= #1 tdo ^ crc_in[10] ^ crc_in[31]; crc_in[12] <= #1 tdo ^ crc_in[11] ^ crc_in[31]; crc_in[13] <= #1 crc_in[12]; crc_in[14] <= #1 crc_in[13]; crc_in[15] <= #1 crc_in[14]; crc_in[16] <= #1 tdo ^ crc_in[15] ^ crc_in[31]; crc_in[17] <= #1 crc_in[16]; crc_in[18] <= #1 crc_in[17]; crc_in[19] <= #1 crc_in[18]; crc_in[20] <= #1 crc_in[19]; crc_in[21] <= #1 crc_in[20]; crc_in[22] <= #1 tdo ^ crc_in[21] ^ crc_in[31]; crc_in[23] <= #1 tdo ^ crc_in[22] ^ crc_in[31]; crc_in[24] <= #1 crc_in[23]; crc_in[25] <= #1 crc_in[24]; crc_in[26] <= #1 tdo ^ crc_in[25] ^ crc_in[31]; crc_in[27] <= #1 crc_in[26]; crc_in[28] <= #1 crc_in[27]; crc_in[29] <= #1 crc_in[28]; crc_in[30] <= #1 crc_in[29]; crc_in[31] <= #1 crc_in[30]; end assign crc_match_in = crc_in == 32'h0; /********************************************************************************** * * * Printing the information to the screen * * * **********************************************************************************/ always @ (posedge tck_pad_i) begin if(dbg_tb.i_tap_top.update_ir) case(dbg_tb.i_tap_top.jtag_ir[`IR_LENGTH-1:0]) `EXTEST : $display("\tInstruction EXTEST entered"); `SAMPLE_PRELOAD : $display("\tInstruction SAMPLE_PRELOAD entered"); `IDCODE : $display("\tInstruction IDCODE entered"); `MBIST : $display("\tInstruction MBIST entered"); `DEBUG : $display("\tInstruction DEBUG entered"); `BYPASS : $display("\tInstruction BYPASS entered"); default : $display("\n\tInstruction not valid. Instruction BYPASS activated !!!"); endcase end // We never use following states: exit2_ir, exit2_dr, pause_ir or pause_dr always @ (posedge tck_pad_i) begin if(dbg_tb.i_tap_top.pause_ir | dbg_tb.i_tap_top.exit2_ir) begin $display("\n(%0t) ERROR: State pause_ir or exit2_ir detected.", $time); $display("(%0t) Simulation stopped !!!", $time); $stop; end end // Detecting CRC error always @ (posedge dbg_tb.i_dbg_top.i_dbg_wb.crc_cnt_end or posedge dbg_tb.i_dbg_top.chain_latch_en or posedge dbg_tb.i_dbg_top.i_dbg_cpu.crc_cnt_end) begin #2; if (~dbg_tb.i_dbg_top.crc_match) begin $display("\t\tCRC ERROR !!!"); $stop; end end // Detecting errors in counters always @ (dbg_tb.i_dbg_top.i_dbg_wb.cmd_cnt or dbg_tb.i_dbg_top.i_dbg_wb.cmd_cnt_end or dbg_tb.i_dbg_top.i_dbg_wb.addr_len_cnt or dbg_tb.i_dbg_top.i_dbg_wb.addr_len_cnt_end or dbg_tb.i_dbg_top.i_dbg_wb.data_cnt or dbg_tb.i_dbg_top.i_dbg_wb.data_cnt_end or dbg_tb.i_dbg_top.i_dbg_wb.cmd_cnt_en or dbg_tb.i_dbg_top.i_dbg_wb.addr_len_cnt_en or dbg_tb.i_dbg_top.i_dbg_wb.data_cnt_en or dbg_tb.i_dbg_top.i_dbg_wb.crc_cnt_en or dbg_tb.i_dbg_top.i_dbg_wb.status_cnt1 //dbg_tb.i_dbg_top.i_dbg_wb.status_cnt2 or //dbg_tb.i_dbg_top.i_dbg_wb.status_cnt3 or //dbg_tb.i_dbg_top.i_dbg_wb.status_cnt4 // dbg_tb.i_dbg_top.i_dbg_wb. or ) begin if ((~dbg_tb.i_dbg_top.i_dbg_wb.cmd_cnt_end) & ( dbg_tb.i_dbg_top.i_dbg_wb.addr_len_cnt_en | dbg_tb.i_dbg_top.i_dbg_wb.data_cnt_en | dbg_tb.i_dbg_top.i_dbg_wb.crc_cnt_en | dbg_tb.i_dbg_top.i_dbg_wb.status_cnt1 ) ) begin $display("\n\n\t\t(%0t) ERROR in counters !!!", $time); #10000; $stop; end end endmodule // dbg_tb
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