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////////////////////////////////////////////////////////////////////////////
////                                                                    ////
//// T6507LP IP Core                                                    ////
////                                                                    ////
//// This file is part of the T6507LP project                           ////
//// http://www.opencores.org/cores/t6507lp/                            ////
////                                                                    ////
//// Description                                                        ////
//// 6507 FSM testbench                                                 ////
////                                                                    ////
//// Author(s):                                                         ////
//// - Gabriel Oshiro Zardo, gabrieloshiro@gmail.com                    ////
//// - Samuel Nascimento Pagliarini (creep), snpagliarini@gmail.com     ////
////                                                                    ////
////////////////////////////////////////////////////////////////////////////
////                                                                    ////
//// Copyright (C) 2001 Authors and OPENCORES.ORG                       ////
////                                                                    ////
//// 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                           ////
////                                                                    ////
////////////////////////////////////////////////////////////////////////////
 
`include "timescale.v"
 
module t6507lp_fsm_tb();
        // mem_rw signals
        localparam MEM_READ = 1'b0;
        localparam MEM_WRITE = 1'b1;
 
        reg clk; // regs are inputs
        reg reset_n;
        reg [7:0] alu_result;
        reg [7:0] alu_status;
        reg [7:0] data_in;
        reg [7:0] alu_x;
        reg [7:0] alu_y;
        wire [12:0] address; // wires are outputs
        wire mem_rw;
        wire [7:0] data_out;
        wire [7:0] alu_opcode;
        wire [7:0] alu_a;
        wire alu_enable;
 
        integer my_i;
 
        `include "t6507lp_package.v"
 
        t6507lp_fsm #(8,13) t6507lp_fsm(
                .clk(clk),
                .reset_n(reset_n),
                .alu_result(alu_result),
                .alu_status(alu_status),
                .data_in(data_in),
                .alu_x(alu_x),
                .alu_y(alu_y),
                .address(address),
                .mem_rw(mem_rw),
                .data_out(data_out),
                .alu_opcode(alu_opcode),
                .alu_a(alu_a),
                .alu_enable(alu_enable)
        );
 
        always #10 clk = ~clk;
 
        reg[7:0] fake_mem[2**13-1:0];
 
        initial begin
                clk = 1'b0;
                reset_n = 1'b0;
                alu_result = 8'h01;
                alu_status = 8'h00;
                alu_x = 8'h07;
                alu_y = 8'h03;
 
                for (my_i=0; my_i < 2**13; my_i= my_i+1) begin
                        $write("\n%d",my_i);
                        fake_mem[my_i]=8'h00;
                end
 
                fake_mem[0] = ASL_ACC; // testing ACC mode
                fake_mem[1] = ADC_IMM; // testing IMM mode
                fake_mem[2] = 8'h27;
                fake_mem[3] = JMP_ABS; // testing ABS mode, JMP type
                fake_mem[4] = 8'h09;
                fake_mem[5] = 8'h00;
                fake_mem[6] = ASL_ACC; // wont be executed
                fake_mem[7] = ASL_ACC; // wont be executed
                fake_mem[8] = ASL_ACC; // wont be executed
                fake_mem[9] = ASL_ACC; // wont be executed
                fake_mem[10] = LDA_ABS; // testing ABS mode, READ type. A = MEM[0002]. (a=27)
                fake_mem[11] = 8'h02;
                fake_mem[12] = 8'h00;
                fake_mem[13] = ASL_ABS; // testing ABS mode, READ_MODIFY_WRITE type. should overwrite the first ASL_ACC
                fake_mem[14] = 8'h00;
                fake_mem[15] = 8'h00;
                fake_mem[16] = STA_ABS; // testing ABS mode, WRITE type. should write alu_result on MEM[1]
                fake_mem[17] = 8'h01;
                fake_mem[18] = 8'h00;
                fake_mem[19] = LDA_ZPG; // testing ZPG mode, READ type
                fake_mem[20] = 8'h00;
                fake_mem[21] = ASL_ZPG; // testing ZPG mode, READ_MODIFY_WRITE type
                fake_mem[22] = 8'h00;
                fake_mem[23] = STA_ZPG; // testing ZPG mode, WRITE type
                fake_mem[24] = 8'h00;
                fake_mem[25] = LDA_ZPX; // testing ZPX mode, READ type. A = MEM[x+1]
                fake_mem[26] = 8'h01;
                fake_mem[27] = ASL_ZPX; // testing ZPX mode, READ_MODIFY_WRITE type. MEM[x+1] = MEM[x+1] << 1;
                fake_mem[28] = 8'h01;
                fake_mem[29] = STA_ZPX; // testing ZPX mode, WRITE type. MEM[x+2] = A;
                fake_mem[30] = 8'h02;
                fake_mem[31] = LDA_ABX; // testing ABX mode, READ TYPE. No page crossed.
                fake_mem[32] = 8'h0a;
                fake_mem[33] = 8'h00;
                fake_mem[34] = LDA_ABX; // testing ABX mode, READ TYPE. Page crossed.
                fake_mem[35] = 8'hff;
                fake_mem[36] = 8'h00;
                fake_mem[37] = ASL_ABX; // testing ABX mode, READ_MODIFY_WRITE TYPE. No page crossed.
                fake_mem[38] = 8'h01;
                fake_mem[39] = 8'd35;
                fake_mem[40] = ASL_ABX; // testing ABX mode, READ_MODIFY_WRITE TYPE. Page crossed.
                fake_mem[41] = 8'hff;
                fake_mem[42] = 8'h00;
                fake_mem[40] = STA_ABX; // testing ABX mode, WRITE TYPE. No page crossed.
                fake_mem[41] = 8'h04;
                fake_mem[42] = 8'h00;
                fake_mem[43] = STA_ABX; // testing ABX mode, WRITE TYPE. Page crossed.
                fake_mem[44] = 8'hff;
                fake_mem[45] = 8'h00;
                fake_mem[46] = BNE_REL; // testing REL mode, taking a branch, no page crossed.
                fake_mem[47] = 8'h0a;
                fake_mem[58] = BNE_REL; // testing REL mode, taking a branch, page crossed.
                fake_mem[59] = 8'hff;
                fake_mem[60] = 8'hff;
                fake_mem[254] = 8'hff;
                fake_mem[256] = 8'h55; // PCL fetched from here when executing RTS_IMP
                fake_mem[257] = 8'h01;    // PCH fetched from here when executing RTS_IMP
                fake_mem[264] = 8'd340;
                fake_mem[315] = BEQ_REL; // testing REL mode, not taking a branch, page would have crossed.
                fake_mem[316] = 8'hff;
                fake_mem[317] = BEQ_REL; // testing REL mode, not taking a branch, page would not have crossed.
                fake_mem[318] = 8'h00;
                fake_mem[319] = LDA_IDX; // testing IDX mode READ TYPE, no page crossed;
                fake_mem[320] = 8'h0a;
                fake_mem[321] = LDA_IDX; // testing IDX mode READ TYPE, page crossed; this will actually do A = MEM[6] because there is no carry
                fake_mem[322] = 8'hff;
                //fake_mem[319] = SLO_IDX; // testing IDX mode READ_MODIFY_WRITE TYPE
                //fake_mem[320] = 8'h0a;   // all of read modify write instructions are not documented therefore will not be simulated
                fake_mem[323] = STA_IDX; // testing IDX mode WRITE TYPE, page crossed being ignored
                fake_mem[324] = 8'hff;
                fake_mem[325] = STA_IDX; // testing IDX mode WRITE TYPE, page not crossed;
                fake_mem[326] = 8'h00;
                fake_mem[327] = LDA_IDY; // testing IDY mode READ TYPE, page not crossed;
                fake_mem[328] = 8'h00;
                fake_mem[329] = LDA_IDY; // testing IDY mode READ TYPE, page not crossed but pointer overflowed.
                fake_mem[330] = 8'hff;
                /* testing IDY mode READ TYPE, page crossed.
                   address may assume a invalid value when page is crossed but it is fixed on the next cycle when the true read occurs.
                   this is probably not an issue */
                fake_mem[331] = LDA_IDY;
                fake_mem[332] = 8'hfe;
                fake_mem[333] = STA_IDY; // testing IDY mode WRITE TYPE, page crossed;
                fake_mem[334] = 8'h00;
                fake_mem[335] = STA_IDY; // testing IDY mode WRITE TYPE, page not crossed;
                fake_mem[336] = 8'h0e;
                fake_mem[337] = INX_IMP;
                //fake_mem[338] = JMP_IND; // testing absolute indirect addressing. page crossed when updating pointer.
                //fake_mem[339] = 8'hff; 
                //fake_mem[340] = 8'h00; 
                //fake_mem[337] = JMP_IND; // testing absolute indirect addressing. no page crossed when updating pointer.
                //fake_mem[338] = 8'h3b;   // these are commented cause they will actually jump
                //fake_mem[339] = 8'h00;
                //fake_mem[338] = BRK_IMP;
                //fake_mem[339] = RTI_IMP;
                //fake_mem[340] = RTS_IMP;
                // 341 is skipped due to RTS internal functionality
                //fake_mem[342] = PHA_IMP;      
                //fake_mem[343] = PHP_IMP;      
                //fake_mem[344] = PLA_IMP;      
                //fake_mem[345] = PLP_IMP;
                fake_mem[338] = JSR_ABS;
                fake_mem[339] = 8'h01;
                fake_mem[340] = 8'h01;
 
 
 
                fake_mem[8190] = 8'h53; // this is the reset vector
                fake_mem[8191] = 8'h01;
                @(negedge clk) // will wait for next negative edge of the clock (t=20)
                reset_n=1'b1;
 
 
                #4000;
                $finish; // to shut down the simulation
        end //initial
 
        always @(clk) begin
                if (mem_rw == MEM_READ) begin // MEM_READ
                        data_in <= fake_mem[address];
                        $write("\nreading from mem position %h: %h", address, fake_mem[address]);
                end
                else begin // MEM_WRITE
                        fake_mem[address] <= data_out;
                        $write("\nreading from mem position %h: %h", address, fake_mem[address]);
                end
        end
 
endmodule

Line No.	Rev	Author	Line
1	67	creep	`////////////////////////////////////////////////////////////////////////////`
2			`//// ////`
3			`//// T6507LP IP Core ////`
4			`//// ////`
5			`//// This file is part of the T6507LP project ////`
6			`//// http://www.opencores.org/cores/t6507lp/ ////`
7			`//// ////`
8			`//// Description ////`
9	98	creep	`//// 6507 FSM testbench ////`
10	67	creep	`//// ////`
11			`//// Author(s): ////`
12			`//// - Gabriel Oshiro Zardo, gabrieloshiro@gmail.com ////`
13			`//// - Samuel Nascimento Pagliarini (creep), snpagliarini@gmail.com ////`
14			`//// ////`
15			`////////////////////////////////////////////////////////////////////////////`
16			`//// ////`
17			`//// Copyright (C) 2001 Authors and OPENCORES.ORG ////`
18			`//// ////`
19			`//// This source file may be used and distributed without ////`
20			`//// restriction provided that this copyright statement is not ////`
21			`//// removed from the file and that any derivative work contains ////`
22			`//// the original copyright notice and the associated disclaimer. ////`
23			`//// ////`
24			`//// This source file is free software; you can redistribute it ////`
25			`//// and/or modify it under the terms of the GNU Lesser General ////`
26			`//// Public License as published by the Free Software Foundation; ////`
27			`//// either version 2.1 of the License, or (at your option) any ////`
28			`//// later version. ////`
29			`//// ////`
30			`//// This source is distributed in the hope that it will be ////`
31			`//// useful, but WITHOUT ANY WARRANTY; without even the implied ////`
32			`//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////`
33			`//// PURPOSE. See the GNU Lesser General Public License for more ////`
34			`//// details. ////`
35			`//// ////`
36			`//// You should have received a copy of the GNU Lesser General ////`
37			`//// Public License along with this source; if not, download it ////`
38			`//// from http://www.opencores.org/lgpl.shtml ////`
39			`//// ////`
40			`////////////////////////////////////////////////////////////////////////////`
41
42	112	creep	`include "timescale.v"
43	67	creep
44			`module t6507lp_fsm_tb();`
45	115	creep	`// mem_rw signals`
46			`localparam MEM_READ = 1'b0;`
47			`localparam MEM_WRITE = 1'b1;`
48
49	117	creep	`reg clk; // regs are inputs`
50	71	creep	`reg reset_n;`
51	67	creep	`reg [7:0] alu_result;`
52			`reg [7:0] alu_status;`
53			`reg [7:0] data_in;`
54	86	creep	`reg [7:0] alu_x;`
55			`reg [7:0] alu_y;`
56	117	creep	`wire [12:0] address; // wires are outputs`
57	115	creep	`wire mem_rw;`
58	67	creep	`wire [7:0] data_out;`
59			`wire [7:0] alu_opcode;`
60			`wire [7:0] alu_a;`
61			`wire alu_enable;`
62
63	111	creep	`integer my_i;`
64	95	creep
65	146	creep	`include "t6507lp_package.v"
66	67	creep
67	117	creep	`t6507lp_fsm #(8,13) t6507lp_fsm(`
68	116	creep	`.clk(clk),`
69			`.reset_n(reset_n),`
70			`.alu_result(alu_result),`
71			`.alu_status(alu_status),`
72			`.data_in(data_in),`
73	117	creep	`.alu_x(alu_x),`
74			`.alu_y(alu_y),`
75	116	creep	`.address(address),`
76			`.mem_rw(mem_rw),`
77			`.data_out(data_out),`
78			`.alu_opcode(alu_opcode),`
79			`.alu_a(alu_a),`
80	117	creep	`.alu_enable(alu_enable)`
81	116	creep	`);`
82	67	creep
83	71	creep	`always #10 clk = ~clk;`
84	67	creep
85	95	creep	`reg[7:0] fake_mem[2**13-1:0];`
86	71	creep
87	67	creep	`initial begin`
88	117	creep	`clk = 1'b0;`
89	71	creep	`reset_n = 1'b0;`
90			`alu_result = 8'h01;`
91	94	creep	`alu_status = 8'h00;`
92	86	creep	`alu_x = 8'h07;`
93			`alu_y = 8'h03;`
94	95	creep
95	111	creep	`for (my_i=0; my_i < 2**13; my_i= my_i+1) begin`
96			`$write("\n%d",my_i);`
97			`fake_mem[my_i]=8'h00;`
98	95	creep	`end`
99	67	creep
100	71	creep	`fake_mem[0] = ASL_ACC; // testing ACC mode`
101			`fake_mem[1] = ADC_IMM; // testing IMM mode`
102			`fake_mem[2] = 8'h27;`
103			`fake_mem[3] = JMP_ABS; // testing ABS mode, JMP type`
104			`fake_mem[4] = 8'h09;`
105			`fake_mem[5] = 8'h00;`
106			`fake_mem[6] = ASL_ACC; // wont be executed`
107			`fake_mem[7] = ASL_ACC; // wont be executed`
108			`fake_mem[8] = ASL_ACC; // wont be executed`
109			`fake_mem[9] = ASL_ACC; // wont be executed`
110			`fake_mem[10] = LDA_ABS; // testing ABS mode, READ type. A = MEM[0002]. (a=27)`
111			`fake_mem[11] = 8'h02;`
112			`fake_mem[12] = 8'h00;`
113			`fake_mem[13] = ASL_ABS; // testing ABS mode, READ_MODIFY_WRITE type. should overwrite the first ASL_ACC`
114	76	creep	`fake_mem[14] = 8'h00;`
115	71	creep	`fake_mem[15] = 8'h00;`
116	76	creep	`fake_mem[16] = STA_ABS; // testing ABS mode, WRITE type. should write alu_result on MEM[1]`
117			`fake_mem[17] = 8'h01;`
118			`fake_mem[18] = 8'h00;`
119			`fake_mem[19] = LDA_ZPG; // testing ZPG mode, READ type`
120			`fake_mem[20] = 8'h00;`
121	78	creep	`fake_mem[21] = ASL_ZPG; // testing ZPG mode, READ_MODIFY_WRITE type`
122			`fake_mem[22] = 8'h00;`
123			`fake_mem[23] = STA_ZPG; // testing ZPG mode, WRITE type`
124			`fake_mem[24] = 8'h00;`
125	86	creep	`fake_mem[25] = LDA_ZPX; // testing ZPX mode, READ type. A = MEM[x+1]`
126			`fake_mem[26] = 8'h01;`
127			`fake_mem[27] = ASL_ZPX; // testing ZPX mode, READ_MODIFY_WRITE type. MEM[x+1] = MEM[x+1] << 1;`
128			`fake_mem[28] = 8'h01;`
129			`fake_mem[29] = STA_ZPX; // testing ZPX mode, WRITE type. MEM[x+2] = A;`
130			`fake_mem[30] = 8'h02;`
131	87	creep	`fake_mem[31] = LDA_ABX; // testing ABX mode, READ TYPE. No page crossed.`
132			`fake_mem[32] = 8'h0a;`
133			`fake_mem[33] = 8'h00;`
134	88	creep	`fake_mem[34] = LDA_ABX; // testing ABX mode, READ TYPE. Page crossed.`
135			`fake_mem[35] = 8'hff;`
136			`fake_mem[36] = 8'h00;`
137	89	creep	`fake_mem[37] = ASL_ABX; // testing ABX mode, READ_MODIFY_WRITE TYPE. No page crossed.`
138			`fake_mem[38] = 8'h01;`
139	96	creep	`fake_mem[39] = 8'd35;`
140	91	creep	`fake_mem[40] = ASL_ABX; // testing ABX mode, READ_MODIFY_WRITE TYPE. Page crossed.`
141			`fake_mem[41] = 8'hff;`
142			`fake_mem[42] = 8'h00;`
143	92	creep	`fake_mem[40] = STA_ABX; // testing ABX mode, WRITE TYPE. No page crossed.`
144			`fake_mem[41] = 8'h04;`
145			`fake_mem[42] = 8'h00;`
146	94	creep	`fake_mem[43] = STA_ABX; // testing ABX mode, WRITE TYPE. Page crossed.`
147			`fake_mem[44] = 8'hff;`
148			`fake_mem[45] = 8'h00;`
149			`fake_mem[46] = BNE_REL; // testing REL mode, taking a branch, no page crossed.`
150			`fake_mem[47] = 8'h0a;`
151			`fake_mem[58] = BNE_REL; // testing REL mode, taking a branch, page crossed.`
152			`fake_mem[59] = 8'hff;`
153	101	creep	`fake_mem[60] = 8'hff;`
154	96	creep	`fake_mem[254] = 8'hff;`
155	110	creep	`fake_mem[256] = 8'h55; // PCL fetched from here when executing RTS_IMP`
156			`fake_mem[257] = 8'h01; // PCH fetched from here when executing RTS_IMP`
157	107	creep	`fake_mem[264] = 8'd340;`
158	94	creep	`fake_mem[315] = BEQ_REL; // testing REL mode, not taking a branch, page would have crossed.`
159			`fake_mem[316] = 8'hff;`
160			`fake_mem[317] = BEQ_REL; // testing REL mode, not taking a branch, page would not have crossed.`
161	95	creep	`fake_mem[318] = 8'h00;`
162			`fake_mem[319] = LDA_IDX; // testing IDX mode READ TYPE, no page crossed;`
163			`fake_mem[320] = 8'h0a;`
164			`fake_mem[321] = LDA_IDX; // testing IDX mode READ TYPE, page crossed; this will actually do A = MEM[6] because there is no carry`
165			`fake_mem[322] = 8'hff;`
166			`//fake_mem[319] = SLO_IDX; // testing IDX mode READ_MODIFY_WRITE TYPE`
167			`//fake_mem[320] = 8'h0a; // all of read modify write instructions are not documented therefore will not be simulated`
168			`fake_mem[323] = STA_IDX; // testing IDX mode WRITE TYPE, page crossed being ignored`
169			`fake_mem[324] = 8'hff;`
170			`fake_mem[325] = STA_IDX; // testing IDX mode WRITE TYPE, page not crossed;`
171	96	creep	`fake_mem[326] = 8'h00;`
172			`fake_mem[327] = LDA_IDY; // testing IDY mode READ TYPE, page not crossed;`
173			`fake_mem[328] = 8'h00;`
174			`fake_mem[329] = LDA_IDY; // testing IDY mode READ TYPE, page not crossed but pointer overflowed.`
175			`fake_mem[330] = 8'hff;`
176			`/* testing IDY mode READ TYPE, page crossed.`
177			`address may assume a invalid value when page is crossed but it is fixed on the next cycle when the true read occurs.`
178			`this is probably not an issue */`
179			`fake_mem[331] = LDA_IDY;`
180	100	creep	`fake_mem[332] = 8'hfe;`
181	101	creep	`fake_mem[333] = STA_IDY; // testing IDY mode WRITE TYPE, page crossed;`
182			`fake_mem[334] = 8'h00;`
183			`fake_mem[335] = STA_IDY; // testing IDY mode WRITE TYPE, page not crossed;`
184	102	creep	`fake_mem[336] = 8'h0e;`
185			`fake_mem[337] = INX_IMP;`
186	104	creep	`//fake_mem[338] = JMP_IND; // testing absolute indirect addressing. page crossed when updating pointer.`
187			`//fake_mem[339] = 8'hff;`
188			`//fake_mem[340] = 8'h00;`
189	101	creep	`//fake_mem[337] = JMP_IND; // testing absolute indirect addressing. no page crossed when updating pointer.`
190	104	creep	`//fake_mem[338] = 8'h3b; // these are commented cause they will actually jump`
191			`//fake_mem[339] = 8'h00;`
192	110	creep	`//fake_mem[338] = BRK_IMP;`
193			`//fake_mem[339] = RTI_IMP;`
194			`//fake_mem[340] = RTS_IMP;`
195	107	creep	`// 341 is skipped due to RTS internal functionality`
196	110	creep	`//fake_mem[342] = PHA_IMP;`
197			`//fake_mem[343] = PHP_IMP;`
198			`//fake_mem[344] = PLA_IMP;`
199			`//fake_mem[345] = PLP_IMP;`
200			`fake_mem[338] = JSR_ABS;`
201			`fake_mem[339] = 8'h01;`
202			`fake_mem[340] = 8'h01;`
203
204	100	creep
205
206	104	creep	`fake_mem[8190] = 8'h53; // this is the reset vector`
207			`fake_mem[8191] = 8'h01;`
208	71	creep	`@(negedge clk) // will wait for next negative edge of the clock (t=20)`
209			`reset_n=1'b1;`
210
211	67	creep
212	102	creep	`#4000;`
213	67	creep	`$finish; // to shut down the simulation`
214			`end //initial`
215
216	71	creep	`always @(clk) begin`
217	115	creep	`if (mem_rw == MEM_READ) begin // MEM_READ`
218	71	creep	`data_in <= fake_mem[address];`
219			`$write("\nreading from mem position %h: %h", address, fake_mem[address]);`
220			`end`
221	115	creep	`else begin // MEM_WRITE`
222	71	creep	`fake_mem[address] <= data_out;`
223			`$write("\nreading from mem position %h: %h", address, fake_mem[address]);`
224			`end`
225			`end`
226	67	creep
227			`endmodule`

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[/] [t6507lp/] [trunk/] [rtl/] [verilog/] [t6507lp_fsm_tb.v] - Blame information for rev 146