]> Joshua Wise's Git repositories - fpgaboy.git/blame_incremental - GBZ80Core.v
Add an instruction tester to the test ROM.
[fpgaboy.git] / GBZ80Core.v
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CommitLineData
1`define REG_A 0
2`define REG_B 1
3`define REG_C 2
4`define REG_D 3
5`define REG_E 4
6`define REG_F 5
7`define REG_H 6
8`define REG_L 7
9`define REG_SPH 8
10`define REG_SPL 9
11`define REG_PCH 10
12`define REG_PCL 11
13
14`define FLAG_Z 8'b10000000
15`define FLAG_N 8'b01000000
16`define FLAG_H 8'b00100000
17`define FLAG_C 8'b00010000
18
19`define STATE_FETCH 2'h0
20`define STATE_DECODE 2'h1
21`define STATE_EXECUTE 2'h2
22`define STATE_WRITEBACK 2'h3
23
24`define INSN_LD_reg_imm8 8'b00xxx110
25`define INSN_HALT 8'b01110110
26`define INSN_LD_HL_reg 8'b01110xxx
27`define INSN_LD_reg_HL 8'b01xxx110
28`define INSN_LD_reg_reg 8'b01xxxxxx
29`define INSN_LD_reg_imm16 8'b00xx0001
30`define INSN_LD_SP_HL 8'b11111001
31`define INSN_PUSH_reg 8'b11xx0101
32`define INSN_POP_reg 8'b11xx0001
33`define INSN_LDH_AC 8'b111x0010 // Either LDH A,(C) or LDH (C),A
34`define INSN_LDx_AHL 8'b001xx010 // LDD/LDI A,(HL) / (HL),A
35`define INSN_ALU8 8'b10xxxxxx // 10 xxx yyy
36`define INSN_NOP 8'b00000000
37`define INSN_RST 8'b11xxx111
38`define INSN_RET 8'b110x1001 // 1 = RETI, 0 = RET
39`define INSN_CALL 8'b11001101
40`define INSN_JP_imm 8'b11000011
41`define INSN_JPCC_imm 8'b110xx010
42`define INSN_ALU_A 8'b00xxx111
43
44`define INSN_cc_NZ 2'b00
45`define INSN_cc_Z 2'b01
46`define INSN_cc_NC 2'b10
47`define INSN_cc_C 2'b11
48
49`define INSN_reg_A 3'b111
50`define INSN_reg_B 3'b000
51`define INSN_reg_C 3'b001
52`define INSN_reg_D 3'b010
53`define INSN_reg_E 3'b011
54`define INSN_reg_H 3'b100
55`define INSN_reg_L 3'b101
56`define INSN_reg_dHL 3'b110
57`define INSN_reg16_BC 2'b00
58`define INSN_reg16_DE 2'b01
59`define INSN_reg16_HL 2'b10
60`define INSN_reg16_SP 2'b11
61`define INSN_stack_AF 2'b11
62`define INSN_stack_BC 2'b00
63`define INSN_stack_DE 2'b01
64`define INSN_stack_HL 2'b10
65`define INSN_alu_ADD 3'b000
66`define INSN_alu_ADC 3'b001
67`define INSN_alu_SUB 3'b010
68`define INSN_alu_SBC 3'b011
69`define INSN_alu_AND 3'b100
70`define INSN_alu_XOR 3'b101
71`define INSN_alu_OR 3'b110
72`define INSN_alu_CP 3'b111 // Oh lawd, is dat some CP?
73`define INSN_alu_RLCA 3'b000
74`define INSN_alu_RRCA 3'b001
75`define INSN_alu_RLA 3'b010
76`define INSN_alu_RRA 3'b011
77`define INSN_alu_DAA 3'b100
78`define INSN_alu_CPL 3'b101
79`define INSN_alu_SCF 3'b110
80`define INSN_alu_CCF 3'b111
81
82module GBZ80Core(
83 input clk,
84 output reg [15:0] busaddress, /* BUS_* is latched on STATE_FETCH. */
85 inout [7:0] busdata,
86 output reg buswr, output reg busrd);
87
88 reg [1:0] state = 0; /* State within this bus cycle (see STATE_*). */
89 reg [2:0] cycle = 0; /* Cycle for instructions. */
90
91 reg [7:0] registers[11:0];
92
93 reg [15:0] address; /* Address for the next bus operation. */
94
95 reg [7:0] opcode; /* Opcode from the current machine cycle. */
96
97 reg [7:0] rdata, wdata; /* Read data from this bus cycle, or write data for the next. */
98 reg rd = 1, wr = 0, newcycle = 1;
99
100 reg [7:0] tmp, tmp2; /* Generic temporary regs. */
101
102 reg [7:0] buswdata;
103 assign busdata = buswr ? buswdata : 8'bzzzzzzzz;
104
105 reg ie = 0;
106
107 initial begin
108 registers[ 0] <= 0;
109 registers[ 1] <= 0;
110 registers[ 2] <= 0;
111 registers[ 3] <= 0;
112 registers[ 4] <= 0;
113 registers[ 5] <= 0;
114 registers[ 6] <= 0;
115 registers[ 7] <= 0;
116 registers[ 8] <= 0;
117 registers[ 9] <= 0;
118 registers[10] <= 0;
119 registers[11] <= 0;
120 ie <= 0;
121 rd <= 1;
122 wr <= 0;
123 newcycle <= 1;
124 state <= 0;
125 cycle <= 0;
126 end
127
128 always @(posedge clk)
129 case (state)
130 `STATE_FETCH: begin
131 if (newcycle) begin
132 busaddress <= {registers[`REG_PCH], registers[`REG_PCL]};
133 buswr <= 0;
134 busrd <= 1;
135 end else begin
136 busaddress <= address;
137 buswr <= wr;
138 busrd <= rd;
139 if (wr)
140 buswdata <= wdata;
141 end
142 state <= `STATE_DECODE;
143 end
144 `STATE_DECODE: begin
145 if (newcycle) begin
146 opcode <= busdata;
147 rdata <= busdata;
148 newcycle <= 0;
149 cycle <= 0;
150 end else begin
151 if (rd) rdata <= busdata;
152 cycle <= cycle + 1;
153 end
154 buswr <= 0;
155 busrd <= 0;
156 wr <= 0;
157 rd <= 0;
158 address <= 16'bxxxxxxxxxxxxxxxx; // Make it obvious if something of type has happened.
159 wdata <= 8'bxxxxxxxx;
160 state <= `STATE_EXECUTE;
161 end
162 `STATE_EXECUTE: begin
163`define EXEC_INC_PC \
164 {registers[`REG_PCH], registers[`REG_PCL]} <= {registers[`REG_PCH], registers[`REG_PCL]} + 1
165`define EXEC_NEXTADDR_PCINC \
166 address <= {registers[`REG_PCH], registers[`REG_PCL]} + 1
167`define EXEC_NEWCYCLE \
168 newcycle <= 1; rd <= 1; wr <= 0
169 casex (opcode)
170 `INSN_LD_reg_imm8: begin
171 case (cycle)
172 0: begin
173 `EXEC_INC_PC;
174 `EXEC_NEXTADDR_PCINC;
175 rd <= 1;
176 end
177 1: begin
178 `EXEC_INC_PC;
179 if (opcode[5:3] == `INSN_reg_dHL) begin
180 address <= {registers[`REG_H], registers[`REG_L]};
181 wdata <= rdata;
182 rd <= 0;
183 wr <= 1;
184 end else begin
185 `EXEC_NEWCYCLE;
186 end
187 end
188 2: begin
189 `EXEC_NEWCYCLE;
190 end
191 endcase
192 end
193 `INSN_HALT: begin
194 `EXEC_NEWCYCLE;
195 /* XXX Interrupts needed for HALT. */
196 end
197 `INSN_LD_HL_reg: begin
198 case (cycle)
199 0: begin
200 case (opcode[2:0])
201 `INSN_reg_A: wdata <= registers[`REG_A];
202 `INSN_reg_B: wdata <= registers[`REG_B];
203 `INSN_reg_C: wdata <= registers[`REG_C];
204 `INSN_reg_D: wdata <= registers[`REG_D];
205 `INSN_reg_E: wdata <= registers[`REG_E];
206 `INSN_reg_H: wdata <= registers[`REG_H];
207 `INSN_reg_L: wdata <= registers[`REG_L];
208 endcase
209 address <= {registers[`REG_H], registers[`REG_L]};
210 wr <= 1; rd <= 0;
211 end
212 1: begin
213 `EXEC_INC_PC;
214 `EXEC_NEWCYCLE;
215 end
216 endcase
217 end
218 `INSN_LD_reg_HL: begin
219 case(cycle)
220 0: begin
221 address <= {registers[`REG_H], registers[`REG_L]};
222 rd <= 1;
223 end
224 1: begin
225 tmp <= rdata;
226 `EXEC_INC_PC;
227 `EXEC_NEWCYCLE;
228 end
229 endcase
230 end
231 `INSN_LD_reg_reg: begin
232 `EXEC_INC_PC;
233 `EXEC_NEWCYCLE;
234 case (opcode[2:0])
235 `INSN_reg_A: tmp <= registers[`REG_A];
236 `INSN_reg_B: tmp <= registers[`REG_B];
237 `INSN_reg_C: tmp <= registers[`REG_C];
238 `INSN_reg_D: tmp <= registers[`REG_D];
239 `INSN_reg_E: tmp <= registers[`REG_E];
240 `INSN_reg_H: tmp <= registers[`REG_H];
241 `INSN_reg_L: tmp <= registers[`REG_L];
242 endcase
243 end
244 `INSN_LD_reg_imm16: begin
245 `EXEC_INC_PC;
246 case (cycle)
247 0: begin
248 `EXEC_NEXTADDR_PCINC;
249 rd <= 1;
250 end
251 1: begin
252 `EXEC_NEXTADDR_PCINC;
253 rd <= 1;
254 end
255 2: begin `EXEC_NEWCYCLE; end
256 endcase
257 end
258 `INSN_LD_SP_HL: begin
259 case (cycle)
260 0: begin
261 tmp <= registers[`REG_H];
262 end
263 1: begin
264 `EXEC_NEWCYCLE;
265 `EXEC_INC_PC;
266 tmp <= registers[`REG_L];
267 end
268 endcase
269 end
270 `INSN_PUSH_reg: begin /* PUSH is 16 cycles! */
271 case (cycle)
272 0: begin
273 wr <= 1;
274 address <= {registers[`REG_SPH],registers[`REG_SPL]}-1;
275 case (opcode[5:4])
276 `INSN_stack_AF: wdata <= registers[`REG_A];
277 `INSN_stack_BC: wdata <= registers[`REG_B];
278 `INSN_stack_DE: wdata <= registers[`REG_D];
279 `INSN_stack_HL: wdata <= registers[`REG_H];
280 endcase
281 end
282 1: begin
283 wr <= 1;
284 address <= {registers[`REG_SPH],registers[`REG_SPL]}-1;
285 case (opcode[5:4])
286 `INSN_stack_AF: wdata <= registers[`REG_F];
287 `INSN_stack_BC: wdata <= registers[`REG_C];
288 `INSN_stack_DE: wdata <= registers[`REG_E];
289 `INSN_stack_HL: wdata <= registers[`REG_L];
290 endcase
291 end
292 2: begin /* Twiddle thumbs. */ end
293 3: begin
294 `EXEC_NEWCYCLE;
295 `EXEC_INC_PC;
296 end
297 endcase
298 end
299 `INSN_POP_reg: begin /* POP is 12 cycles! */
300 case (cycle)
301 0: begin
302 rd <= 1;
303 address <= {registers[`REG_SPH],registers[`REG_SPL]};
304 end
305 1: begin
306 rd <= 1;
307 address <= {registers[`REG_SPH],registers[`REG_SPL]};
308 end
309 2: begin
310 `EXEC_NEWCYCLE;
311 `EXEC_INC_PC;
312 end
313 endcase
314 end
315 `INSN_LDH_AC: begin
316 case (cycle)
317 0: begin
318 address <= {8'hFF,registers[`REG_C]};
319 if (opcode[4]) begin // LD A,(C)
320 rd <= 1;
321 end else begin
322 wr <= 1;
323 wdata <= registers[`REG_A];
324 end
325 end
326 1: begin
327 `EXEC_NEWCYCLE;
328 `EXEC_INC_PC;
329 end
330 endcase
331 end
332 `INSN_LDx_AHL: begin
333 case (cycle)
334 0: begin
335 address <= {registers[`REG_H],registers[`REG_L]};
336 if (opcode[3]) begin // LDx A, (HL)
337 rd <= 1;
338 end else begin
339 wr <= 1;
340 wdata <= registers[`REG_A];
341 end
342 end
343 1: begin
344 `EXEC_NEWCYCLE;
345 `EXEC_INC_PC;
346 end
347 endcase
348 end
349 `INSN_ALU8: begin
350 if ((opcode[2:0] == `INSN_reg_dHL) && (cycle == 0)) begin
351 // fffffffff fuck your shit, read from (HL) :(
352 rd <= 1;
353 address <= {registers[`REG_H], registers[`REG_L]};
354 end else begin
355 `EXEC_NEWCYCLE;
356 `EXEC_INC_PC;
357 case (opcode[2:0])
358 `INSN_reg_A: tmp <= registers[`REG_A];
359 `INSN_reg_B: tmp <= registers[`REG_B];
360 `INSN_reg_C: tmp <= registers[`REG_C];
361 `INSN_reg_D: tmp <= registers[`REG_D];
362 `INSN_reg_E: tmp <= registers[`REG_E];
363 `INSN_reg_H: tmp <= registers[`REG_H];
364 `INSN_reg_L: tmp <= registers[`REG_L];
365 `INSN_reg_dHL: tmp <= rdata;
366 endcase
367 end
368 end
369 `INSN_ALU_A: begin
370 `EXEC_NEWCYCLE;
371 `EXEC_INC_PC;
372 end
373 `INSN_NOP: begin
374 `EXEC_NEWCYCLE;
375 `EXEC_INC_PC;
376 end
377 `INSN_RST: begin
378 case (cycle)
379 0: begin
380 `EXEC_INC_PC; // This goes FIRST in RST
381 end
382 1: begin
383 wr <= 1;
384 address <= {registers[`REG_SPH],registers[`REG_SPL]}-1;
385 wdata <= registers[`REG_PCH];
386 end
387 2: begin
388 wr <= 1;
389 address <= {registers[`REG_SPH],registers[`REG_SPL]}-2;
390 wdata <= registers[`REG_PCL];
391 end
392 3: begin
393 `EXEC_NEWCYCLE;
394 {registers[`REG_PCH],registers[`REG_PCL]} <=
395 {10'b0,opcode[5:3],3'b0};
396 end
397 endcase
398 end
399 `INSN_RET: begin
400 case (cycle)
401 0: begin
402 rd <= 1;
403 address <= {registers[`REG_SPH],registers[`REG_SPL]};
404 end
405 1: begin
406 rd <= 1;
407 address <= {registers[`REG_SPH],registers[`REG_SPL]} + 1;
408 end
409 2: begin /* twiddle thumbs */ end
410 3: begin
411 `EXEC_NEWCYCLE;
412 // do NOT increment PC!
413 end
414 endcase
415 end
416 `INSN_CALL: begin
417 case (cycle)
418 0: begin
419 `EXEC_INC_PC;
420 `EXEC_NEXTADDR_PCINC;
421 rd <= 1;
422 end
423 1: begin
424 `EXEC_INC_PC;
425 `EXEC_NEXTADDR_PCINC;
426 rd <= 1;
427 end
428 2: begin
429 `EXEC_INC_PC;
430 end
431 3: begin
432 address <= {registers[`REG_SPH],registers[`REG_SPL]} - 1;
433 wdata <= registers[`REG_PCH];
434 wr <= 1;
435 end
436 4: begin
437 address <= {registers[`REG_SPH],registers[`REG_SPL]} - 2;
438 wdata <= registers[`REG_PCL];
439 wr <= 1;
440 end
441 5: begin
442 `EXEC_NEWCYCLE; /* do NOT increment the PC */
443 end
444 endcase
445 end
446 `INSN_JP_imm,`INSN_JPCC_imm: begin
447 case (cycle)
448 0: begin
449 `EXEC_INC_PC;
450 `EXEC_NEXTADDR_PCINC;
451 rd <= 1;
452 end
453 1: begin
454 `EXEC_INC_PC;
455 `EXEC_NEXTADDR_PCINC;
456 rd <= 1;
457 end
458 2: begin
459 `EXEC_INC_PC;
460 if (!opcode[0]) begin // i.e., JP cc,nn
461 /* We need to check the condition code to bail out. */
462 case (opcode[4:3])
463 `INSN_cc_NZ: if (registers[`REG_F][7]) begin `EXEC_NEWCYCLE; end
464 `INSN_cc_Z: if (~registers[`REG_F][7]) begin `EXEC_NEWCYCLE; end
465 `INSN_cc_NC: if (registers[`REG_F][4]) begin `EXEC_NEWCYCLE; end
466 `INSN_cc_C: if (~registers[`REG_F][4]) begin `EXEC_NEWCYCLE; end
467 endcase
468 end
469 end
470 3: begin
471 `EXEC_NEWCYCLE;
472 end
473 endcase
474 end
475 default:
476 $stop;
477 endcase
478 state <= `STATE_WRITEBACK;
479 end
480 `STATE_WRITEBACK: begin
481 casex (opcode)
482 `INSN_LD_reg_imm8:
483 case (cycle)
484 0: begin end
485 1: case (opcode[5:3])
486 `INSN_reg_A: begin registers[`REG_A] <= rdata; end
487 `INSN_reg_B: begin registers[`REG_B] <= rdata; end
488 `INSN_reg_C: begin registers[`REG_C] <= rdata; end
489 `INSN_reg_D: begin registers[`REG_D] <= rdata; end
490 `INSN_reg_E: begin registers[`REG_E] <= rdata; end
491 `INSN_reg_H: begin registers[`REG_H] <= rdata; end
492 `INSN_reg_L: begin registers[`REG_L] <= rdata; end
493 `INSN_reg_dHL: begin /* Go off to cycle 2 */ end
494 endcase
495 2: begin end
496 endcase
497 `INSN_HALT: begin
498 /* Nothing needs happen here. */
499 /* XXX Interrupts needed for HALT. */
500 end
501 `INSN_LD_HL_reg: begin
502 /* Nothing of interest here */
503 end
504 `INSN_LD_reg_HL: begin
505 case (cycle)
506 0: begin end
507 1: begin
508 case (opcode[5:3])
509 `INSN_reg_A: registers[`REG_A] <= tmp;
510 `INSN_reg_B: registers[`REG_B] <= tmp;
511 `INSN_reg_C: registers[`REG_C] <= tmp;
512 `INSN_reg_D: registers[`REG_D] <= tmp;
513 `INSN_reg_E: registers[`REG_E] <= tmp;
514 `INSN_reg_H: registers[`REG_H] <= tmp;
515 `INSN_reg_L: registers[`REG_L] <= tmp;
516 endcase
517 end
518 endcase
519 end
520 `INSN_LD_reg_reg: begin
521 case (opcode[5:3])
522 `INSN_reg_A: registers[`REG_A] <= tmp;
523 `INSN_reg_B: registers[`REG_B] <= tmp;
524 `INSN_reg_C: registers[`REG_C] <= tmp;
525 `INSN_reg_D: registers[`REG_D] <= tmp;
526 `INSN_reg_E: registers[`REG_E] <= tmp;
527 `INSN_reg_H: registers[`REG_H] <= tmp;
528 `INSN_reg_L: registers[`REG_L] <= tmp;
529 endcase
530 end
531 `INSN_LD_reg_imm16: begin
532 case (cycle)
533 0: begin /* */ end
534 1: begin
535 case (opcode[5:4])
536 `INSN_reg16_BC: registers[`REG_C] <= rdata;
537 `INSN_reg16_DE: registers[`REG_E] <= rdata;
538 `INSN_reg16_HL: registers[`REG_L] <= rdata;
539 `INSN_reg16_SP: registers[`REG_SPL] <= rdata;
540 endcase
541 end
542 2: begin
543 case (opcode[5:4])
544 `INSN_reg16_BC: registers[`REG_B] <= rdata;
545 `INSN_reg16_DE: registers[`REG_D] <= rdata;
546 `INSN_reg16_HL: registers[`REG_H] <= rdata;
547 `INSN_reg16_SP: registers[`REG_SPH] <= rdata;
548 endcase
549 end
550 endcase
551 end
552 `INSN_LD_SP_HL: begin
553 case (cycle)
554 0: registers[`REG_SPH] <= tmp;
555 1: registers[`REG_SPL] <= tmp;
556 endcase
557 end
558 `INSN_PUSH_reg: begin /* PUSH is 16 cycles! */
559 case (cycle)
560 0: {registers[`REG_SPH],registers[`REG_SPL]} <=
561 {registers[`REG_SPH],registers[`REG_SPL]} - 1;
562 1: {registers[`REG_SPH],registers[`REG_SPL]} <=
563 {registers[`REG_SPH],registers[`REG_SPL]} - 1;
564 2: begin /* type F */ end
565 3: begin /* type F */ end
566 endcase
567 end
568 `INSN_POP_reg: begin /* POP is 12 cycles! */
569 case (cycle)
570 0: {registers[`REG_SPH],registers[`REG_SPL]} <=
571 {registers[`REG_SPH],registers[`REG_SPL]} + 1;
572 1: begin
573 case (opcode[5:4])
574 `INSN_stack_AF: registers[`REG_F] <= rdata;
575 `INSN_stack_BC: registers[`REG_C] <= rdata;
576 `INSN_stack_DE: registers[`REG_E] <= rdata;
577 `INSN_stack_HL: registers[`REG_L] <= rdata;
578 endcase
579 {registers[`REG_SPH],registers[`REG_SPL]} <=
580 {registers[`REG_SPH],registers[`REG_SPL]} + 1;
581 end
582 2: begin
583 case (opcode[5:4])
584 `INSN_stack_AF: registers[`REG_A] <= rdata;
585 `INSN_stack_BC: registers[`REG_B] <= rdata;
586 `INSN_stack_DE: registers[`REG_D] <= rdata;
587 `INSN_stack_HL: registers[`REG_H] <= rdata;
588 endcase
589 end
590 endcase
591 end
592 `INSN_LDH_AC: begin
593 case (cycle)
594 0: begin /* Type F */ end
595 1: if (opcode[4])
596 registers[`REG_A] <= rdata;
597 endcase
598 end
599 `INSN_LDx_AHL: begin
600 case (cycle)
601 0: begin /* Type F */ end
602 1: begin
603 if (opcode[3])
604 registers[`REG_A] <= rdata;
605 {registers[`REG_H],registers[`REG_L]} <=
606 opcode[4] ? // if set, LDD, else LDI
607 ({registers[`REG_H],registers[`REG_L]} - 1) :
608 ({registers[`REG_H],registers[`REG_L]} + 1);
609 end
610 endcase
611 end
612 `INSN_ALU8: begin
613 if ((opcode[2:0] == `INSN_reg_dHL) && (cycle == 0)) begin
614 /* Sit on our asses. */
615 end else begin /* Actually do the computation! */
616 case (opcode[5:3])
617 `INSN_alu_ADD: begin
618 registers[`REG_A] <=
619 registers[`REG_A] + tmp;
620 registers[`REG_F] <=
621 { /* Z */ ((registers[`REG_A] + tmp) == 0) ? 1'b1 : 1'b0,
622 /* N */ 1'b0,
623 /* H */ (({1'b0,registers[`REG_A][3:0]} + {1'b0,tmp[3:0]}) >> 4 == 1) ? 1'b1 : 1'b0,
624 /* C */ (({1'b0,registers[`REG_A]} + {1'b0,tmp}) >> 8 == 1) ? 1'b1 : 1'b0,
625 registers[`REG_F][3:0]
626 };
627 end
628 `INSN_alu_ADC: begin
629 registers[`REG_A] <=
630 registers[`REG_A] + tmp + {7'b0,registers[`REG_F][4]};
631 registers[`REG_F] <=
632 { /* Z */ ((registers[`REG_A] + tmp + {7'b0,registers[`REG_F][4]}) == 0) ? 1'b1 : 1'b0,
633 /* N */ 1'b0,
634 /* H */ (({1'b0,registers[`REG_A][3:0]} + {1'b0,tmp[3:0]} + {4'b0,registers[`REG_F][4]}) >> 4 == 1) ? 1'b1 : 1'b0,
635 /* C */ (({1'b0,registers[`REG_A]} + {1'b0,tmp} + {8'b0,registers[`REG_F][4]}) >> 8 == 1) ? 1'b1 : 1'b0,
636 registers[`REG_F][3:0]
637 };
638 end
639 `INSN_alu_SUB: begin
640 registers[`REG_A] <=
641 registers[`REG_A] - tmp;
642 registers[`REG_F] <=
643 { /* Z */ ((registers[`REG_A] - tmp) == 0) ? 1'b1 : 1'b0,
644 /* N */ 1'b1,
645 /* H */ (({1'b0,registers[`REG_A][3:0]} - {1'b0,tmp[3:0]}) >> 4 == 1) ? 1'b1 : 1'b0,
646 /* C */ (({1'b0,registers[`REG_A]} - {1'b0,tmp}) >> 8 == 1) ? 1'b1 : 1'b0,
647 registers[`REG_F][3:0]
648 };
649 end
650 `INSN_alu_SBC: begin
651 registers[`REG_A] <=
652 registers[`REG_A] - (tmp + {7'b0,registers[`REG_F][4]});
653 registers[`REG_F] <=
654 { /* Z */ ((registers[`REG_A] - (tmp + {7'b0,registers[`REG_F][4]})) == 0) ? 1'b1 : 1'b0,
655 /* N */ 1'b1,
656 /* H */ (({1'b0,registers[`REG_A][3:0]} - ({1'b0,tmp[3:0]} + {4'b0,registers[`REG_F][4]})) >> 4 == 1) ? 1'b1 : 1'b0,
657 /* C */ (({1'b0,registers[`REG_A]} - ({1'b0,tmp} + {8'b0,registers[`REG_F][4]})) >> 8 == 1) ? 1'b1 : 1'b0,
658 registers[`REG_F][3:0]
659 };
660 end
661 `INSN_alu_AND: begin
662 registers[`REG_A] <=
663 registers[`REG_A] & tmp;
664 registers[`REG_F] <=
665 { /* Z */ ((registers[`REG_A] & tmp) == 0) ? 1'b1 : 1'b0,
666 3'b010,
667 registers[`REG_F][3:0]
668 };
669 end
670 `INSN_alu_OR: begin
671 registers[`REG_A] <=
672 registers[`REG_A] | tmp;
673 registers[`REG_F] <=
674 { /* Z */ ((registers[`REG_A] | tmp) == 0) ? 1'b1 : 1'b0,
675 3'b000,
676 registers[`REG_F][3:0]
677 };
678 end
679 `INSN_alu_XOR: begin
680 registers[`REG_A] <=
681 registers[`REG_A] ^ tmp;
682 registers[`REG_F] <=
683 { /* Z */ ((registers[`REG_A] ^ tmp) == 0) ? 1'b1 : 1'b0,
684 3'b000,
685 registers[`REG_F][3:0]
686 };
687 end
688 `INSN_alu_CP: begin
689 registers[`REG_F] <=
690 { /* Z */ ((registers[`REG_A] - tmp) == 0) ? 1'b1 : 1'b0,
691 /* N */ 1'b1,
692 /* H */ (({1'b0,registers[`REG_A][3:0]} - {1'b0,tmp[3:0]}) >> 4 == 1) ? 1'b1 : 1'b0,
693 /* C */ (({1'b0,registers[`REG_A]} - {1'b0,tmp}) >> 8 == 1) ? 1'b1 : 1'b0,
694 registers[`REG_F][3:0]
695 };
696 end
697 default:
698 $stop;
699 endcase
700 end
701 end
702 `INSN_ALU_A: begin
703 case(opcode[5:3])
704 `INSN_alu_RLCA: begin
705 registers[`REG_A] <= {registers[`REG_A][6:0],registers[`REG_A][7]};
706 registers[`REG_F] <= {registers[`REG_F][7:5],registers[`REG_A][7],registers[`REG_F][3:0]};
707 end
708 `INSN_alu_RRCA: begin
709 registers[`REG_A] <= {registers[`REG_A][0],registers[`REG_A][7:1]};
710 registers[`REG_F] <= {registers[`REG_F][7:5],registers[`REG_A][0],registers[`REG_F][3:0]};
711 end
712 `INSN_alu_RLA: begin
713 registers[`REG_A] <= {registers[`REG_A][6:0],registers[`REG_F][4]};
714 registers[`REG_F] <= {registers[`REG_F][7:5],registers[`REG_A][7],registers[`REG_F][3:0]};
715 end
716 `INSN_alu_RRA: begin
717 registers[`REG_A] <= {registers[`REG_A][4],registers[`REG_A][7:1]};
718 registers[`REG_F] <= {registers[`REG_F][7:5],registers[`REG_A][0],registers[`REG_F][3:0]};
719 end
720 `INSN_alu_CPL: begin
721 registers[`REG_A] <= ~registers[`REG_A];
722 registers[`REG_F] <= {registers[`REG_F][7],1'b1,1'b1,registers[`REG_F][4:0]};
723 end
724 `INSN_alu_SCF: begin
725 registers[`REG_F] <= {registers[`REG_F][7:5],1,registers[`REG_F][3:0]};
726 end
727 `INSN_alu_CCF: begin
728 registers[`REG_F] <= {registers[`REG_F][7:5],~registers[`REG_F][4],registers[`REG_F][3:0]};
729 end
730 endcase
731 end
732 `INSN_NOP: begin /* NOP! */ end
733 `INSN_RST: begin
734 case (cycle)
735 0: begin /* type F */ end
736 1: begin /* type F */ end
737 2: begin /* type F */ end
738 3: {registers[`REG_SPH],registers[`REG_SPL]} <=
739 {registers[`REG_SPH],registers[`REG_SPL]}-2;
740 endcase
741 end
742 `INSN_RET: begin
743 case (cycle)
744 0: begin /* type F */ end
745 1: registers[`REG_PCL] <= rdata;
746 2: registers[`REG_PCH] <= rdata;
747 3: begin
748 {registers[`REG_SPH],registers[`REG_SPL]} <=
749 {registers[`REG_SPH],registers[`REG_SPL]} + 2;
750 if (opcode[4]) /* RETI */
751 ie <= 1;
752 end
753 endcase
754 end
755 `INSN_CALL: begin
756 case (cycle)
757 0: begin /* type F */ end
758 1: tmp <= rdata; // tmp contains newpcl
759 2: tmp2 <= rdata; // tmp2 contains newpch
760 3: begin /* type F */ end
761 4: registers[`REG_PCH] <= tmp2;
762 5: begin
763 {registers[`REG_SPH],registers[`REG_SPL]} <=
764 {registers[`REG_SPH],registers[`REG_SPL]} - 2;
765 registers[`REG_PCL] <= tmp;
766 end
767 endcase
768 end
769 `INSN_JP_imm,`INSN_JPCC_imm: begin
770 case (cycle)
771 0: begin /* type F */ end
772 1: tmp <= rdata; // tmp contains newpcl
773 2: tmp2 <= rdata; // tmp2 contains newpch
774 3: {registers[`REG_PCH],registers[`REG_PCL]} <=
775 {tmp2,tmp};
776 endcase
777 end
778 default:
779 $stop;
780 endcase
781 state <= `STATE_FETCH;
782 end
783 endcase
784endmodule
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