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1`timescale 1ns / 1ps
2
3module SimROM(
4 input [15:0] address,
5 inout [7:0] data,
6 input clk,
7 input wr, rd);
8
9 reg rdlatch = 0;
10 reg [7:0] odata;
11
12 reg [7:0] rom [32767:0];
13 initial $readmemh("rom.hex", rom);
14
15 wire decode = address[15:13] == 0;
16 always @(posedge clk) begin
17 rdlatch <= rd && decode;
18 odata <= rom[address[10:0]];
19 end
20 assign data = rdlatch ? odata : 8'bzzzzzzzz;
21endmodule
22
23module BootstrapROM(
24 input [15:0] address,
25 inout [7:0] data,
26 input clk,
27 input wr, rd);
28
29 reg rdlatch = 0;
30 reg [7:0] addrlatch = 0;
31 reg romno = 0, romnotmp = 0;
32 reg [7:0] brom0 [255:0];
33 reg [7:0] brom1 [255:0];
34
35 initial $readmemh("fpgaboot.hex", brom0);
36 initial $readmemh("gbboot.hex", brom1);
37
38`ifdef isim
39 initial romno <= 1;
40`endif
41
42 wire decode = address[15:8] == 0;
43 wire [7:0] odata = (romno == 0) ? brom0[addrlatch] : brom1[addrlatch];
44 always @(posedge clk) begin
45 rdlatch <= rd && decode;
46 addrlatch <= address[7:0];
47 if (wr && decode) romnotmp <= data[0];
48 if (rd && address == 16'h0000) romno <= romnotmp; /* Latch when the program restarts. */
49 end
50 assign data = rdlatch ? odata : 8'bzzzzzzzz;
51endmodule
52
53module MiniRAM(
54 input [15:0] address,
55 inout [7:0] data,
56 input clk,
57 input wr, rd);
58
59 reg [7:0] ram [127:0];
60
61 wire decode = (address >= 16'hFF80) && (address <= 16'hFFFE);
62 reg rdlatch = 0;
63 reg [7:0] odata;
64 assign data = rdlatch ? odata : 8'bzzzzzzzz;
65
66 always @(posedge clk)
67 begin
68 rdlatch <= rd && decode;
69 if (decode) // This has to go this way. The only way XST knows how to do
70 begin // block ram is chip select, write enable, and always
71 if (wr) // reading. "else if rd" does not cut it ...
72 ram[address[6:0]] <= data;
73 odata <= ram[address[6:0]];
74 end
75 end
76endmodule
77
78module CellularRAM(
79 input clk,
80 input [15:0] address,
81 inout [7:0] data,
82 input wr, rd,
83 output wire cr_nADV, cr_nCE, cr_nOE, cr_nWE, cr_CRE, cr_nLB, cr_nUB, cr_CLK,
84 output wire st_nCE, st_nRST,
85 output wire [22:0] cr_A,
86 inout [15:0] cr_DQ);
87
88 parameter ADDR_PROGADDRH = 16'hFF60;
89 parameter ADDR_PROGADDRM = 16'hFF61;
90 parameter ADDR_PROGADDRL = 16'hFF62;
91 parameter ADDR_PROGDATA = 16'hFF63;
92 parameter ADDR_PROGFLASH = 16'hFF65;
93 parameter ADDR_MBC = 16'hFF64;
94
95 reg rdlatch = 0, wrlatch = 0;
96 reg [15:0] addrlatch = 0;
97 reg [7:0] datalatch = 0;
98
99 reg [7:0] progaddrh, progaddrm, progaddrl;
100
101 reg [22:0] progaddr;
102
103 reg [7:0] mbc_emul = 8'b00000101; // High bit is whether we're poking flash
104 // low 7 bits are the MBC that we are emulating
105
106 assign cr_nADV = 0; /* Addresses are always valid! :D */
107 assign cr_nCE = ~(addrlatch != ADDR_PROGFLASH); /* The chip is enabled */
108 assign cr_nLB = 0; /* Lower byte is enabled */
109 assign cr_nUB = 0; /* Upper byte is enabled */
110 assign cr_CRE = 0; /* Data writes, not config */
111 assign cr_CLK = 0; /* Clock? I think not! */
112
113 assign st_nRST = 1; /* Keep the strataflash out of reset. */
114 assign st_nCE = ~(addrlatch == ADDR_PROGFLASH);
115
116 wire decode = (addrlatch[15:14] == 2'b00) /* extrom */ || (addrlatch[15:13] == 3'b101) /* extram */ || (addrlatch == ADDR_PROGDATA) || (addrlatch == ADDR_PROGFLASH);
117
118 reg [3:0] rambank = 0;
119 reg [8:0] rombank = 1;
120
121 assign cr_nOE = decode ? ~rdlatch : 1;
122 assign cr_nWE = (decode && ((addrlatch == ADDR_PROGDATA) || (addrlatch == ADDR_PROGFLASH) || (mbc_emul[6:0] == 0) || (addrlatch[15:13] == 3'b101))) ? ~wrlatch : 1;
123
124 assign cr_DQ = (~cr_nOE) ? 16'bzzzzzzzzzzzzzzzz : {8'b0, datalatch};
125 assign cr_A = (addrlatch[15:14] == 2'b00) ? /* extrom, home bank */ {9'b0,addrlatch[13:0]} :
126 (addrlatch[15:14] == 2'b01) ? /* extrom, paged bank */ {rombank, addrlatch[13:0]} :
127 (addrlatch[15:13] == 3'b101) ? /* extram */ {1'b1, 5'b0, rambank, addrlatch[12:0]} :
128 ((addrlatch == ADDR_PROGDATA) || (addrlatch == ADDR_PROGFLASH)) ? progaddr :
129 23'b0;
130
131 always @(posedge clk) begin
132 case (address)
133 ADDR_PROGADDRH: if (wr) progaddrh <= data;
134 ADDR_PROGADDRM: if (wr) progaddrm <= data;
135 ADDR_PROGADDRL: if (wr) progaddrl <= data;
136 ADDR_PROGDATA: if (rd || wr) begin
137 progaddr <= {progaddrh[6:0], progaddrm[7:0], progaddrl[7:0]};
138 {progaddrh[6:0], progaddrm[7:0], progaddrl[7:0]} <= {progaddrh[6:0], progaddrm[7:0], progaddrl[7:0]} + 23'b1;
139 end
140 ADDR_PROGFLASH: if (rd || wr) begin
141 progaddr <= {progaddrh[6:0], progaddrm[7:0], progaddrl[7:0]};
142 {progaddrh[6:0], progaddrm[7:0], progaddrl[7:0]} <= {progaddrh[6:0], progaddrm[7:0], progaddrl[7:0]} + 23'b1;
143 end
144 ADDR_MBC: begin
145 mbc_emul <= data;
146 rambank <= 0;
147 rombank <= 1;
148 end
149 endcase
150
151 if (mbc_emul[6:0] == 5) begin
152 if ((address[15:12] == 4'h2) && wr)
153 rombank <= {rombank[8], data};
154 else if ((address[15:12] == 4'h3) && wr)
155 rombank <= {data[0], rombank[7:0]};
156 else if ((address[15:12] == 4'h4) && wr)
157 rambank <= data[3:0];
158 end
159
160 rdlatch <= rd;
161 wrlatch <= wr;
162 addrlatch <= address;
163 datalatch <= data;
164 end
165
166 assign data = (rdlatch && decode) ?
167 (addrlatch == ADDR_PROGADDRH) ? progaddrh :
168 (addrlatch == ADDR_PROGADDRM) ? progaddrm :
169 (addrlatch == ADDR_PROGADDRL) ? progaddrl :
170 cr_DQ
171 : 8'bzzzzzzzz;
172endmodule
173
174module InternalRAM(
175 input [15:0] address,
176 inout [7:0] data,
177 input clk,
178 input wr, rd);
179
180 // synthesis attribute ram_style of ram is block
181 reg [7:0] ram [8191:0];
182
183 wire decode = (address >= 16'hC000) && (address <= 16'hFDFF); /* This includes echo RAM. */
184 reg [7:0] odata;
185 reg rdlatch = 0;
186 assign data = rdlatch ? odata : 8'bzzzzzzzz;
187
188 always @(posedge clk)
189 begin
190 rdlatch <= rd && decode;
191 if (decode) // This has to go this way. The only way XST knows how to do
192 begin // block ram is chip select, write enable, and always
193 if (wr) // reading. "else if rd" does not cut it ...
194 ram[address[12:0]] <= data;
195 odata <= ram[address[12:0]];
196 end
197 end
198endmodule
199
200module Switches(
201 input [15:0] address,
202 inout [7:0] data,
203 input clk,
204 input wr, rd,
205 input [7:0] switches,
206 output reg [7:0] ledout = 0);
207
208 wire decode = address == 16'hFF51;
209 reg [7:0] odata;
210 reg rdlatch = 0;
211 assign data = rdlatch ? odata : 8'bzzzzzzzz;
212
213 always @(posedge clk)
214 begin
215 rdlatch <= rd && decode;
216 if (decode && rd)
217 odata <= switches;
218 else if (decode && wr)
219 ledout <= data;
220 end
221endmodule
222
223`ifdef isim
224module Dumpable(input [2:0] r, g, input [1:0] b, input hs, vs, vgaclk);
225endmodule
226`endif
227
228module CoreTop(
229`ifdef isim
230 output reg vgaclk = 0,
231 output reg clk = 0,
232`else
233 input xtal,
234 input [7:0] switches,
235 input [3:0] buttons,
236 output wire [7:0] leds,
237 output serio,
238 input serin,
239 output wire [3:0] digits,
240 output wire [7:0] seven,
241 output wire cr_nADV, cr_nCE, cr_nOE, cr_nWE, cr_CRE, cr_nLB, cr_nUB, cr_CLK, st_nCE, st_nRST,
242 output wire [22:0] cr_A,
243 inout [15:0] cr_DQ,
244 input ps2c, ps2d,
245 output txp, txm,
246 input rxp, rxm,
247`endif
248 output wire hs, vs,
249 output wire [2:0] r, g,
250 output wire [1:0] b,
251 output wire soundl, soundr);
252
253`ifdef isim
254 always #62 clk <= ~clk;
255 always #100 vgaclk <= ~vgaclk;
256
257 Dumpable dump(r,g,b,hs,vs,vgaclk);
258
259 wire [7:0] leds;
260 wire serio;
261 wire serin = 1;
262 wire [3:0] digits;
263 wire [7:0] seven;
264 wire [7:0] switches = 8'b0;
265 wire [3:0] buttons = 4'b0;
266`else
267 wire xtalb, clk, vgaclk, ethclk;
268 IBUFG iclkbuf(.O(xtalb), .I(xtal));
269 CPUDCM cpudcm (.CLKIN_IN(xtalb), .CLKFX_OUT(clk));
270 pixDCM pixdcm (.CLKIN_IN(xtalb), .CLKFX_OUT(vgaclk));
271 ethDCM ethdcm (.CLKIN_IN(xtalb), .CLKFX_OUT(ethclk));
272 wire [7:0] ps2buttons;
273`endif
274
275 wire [15:0] addr [1:0];
276 wire [7:0] data [1:0];
277 wire wr [1:0], rd [1:0];
278
279 wire irq, tmrirq, lcdcirq, vblankirq, btnirq;
280 wire [7:0] jaddr;
281 wire [1:0] state;
282 wire ack;
283
284 GBZ80Core core(
285 .clk(clk),
286 .bus0address(addr[0]),
287 .bus0data(data[0]),
288 .bus0wr(wr[0]),
289 .bus0rd(rd[0]),
290 .bus1address(addr[1]),
291 .bus1data(data[1]),
292 .bus1wr(wr[1]),
293 .bus1rd(rd[1]),
294 .irq(irq),
295 .irqack(ack),
296 .jaddr(jaddr),
297 .state(state));
298
299 BootstrapROM brom(
300 .address(addr[1]),
301 .data(data[1]),
302 .clk(clk),
303 .wr(wr[1]),
304 .rd(rd[1]));
305
306`ifdef isim
307 SimROM rom(
308 .address(addr[0]),
309 .data(data[0]),
310 .clk(clk),
311 .wr(wr[0]),
312 .rd(rd[0]));
313`else
314 CellularRAM cellram(
315 .address(addr[0]),
316 .data(data[0]),
317 .clk(clk),
318 .wr(wr[0]),
319 .rd(rd[0]),
320 .cr_nADV(cr_nADV),
321 .cr_nCE(cr_nCE),
322 .cr_nOE(cr_nOE),
323 .cr_nWE(cr_nWE),
324 .cr_CRE(cr_CRE),
325 .cr_nLB(cr_nLB),
326 .cr_nUB(cr_nUB),
327 .cr_CLK(cr_CLK),
328 .cr_A(cr_A),
329 .cr_DQ(cr_DQ),
330 .st_nCE(st_nCE),
331 .st_nRST(st_nRST));
332`endif
333
334 wire lcdhs, lcdvs, lcdclk;
335 wire [2:0] lcdr, lcdg;
336 wire [1:0] lcdb;
337
338 LCDC lcdc(
339 .clk(clk),
340 .addr(addr[0]),
341 .data(data[0]),
342 .wr(wr[0]),
343 .rd(rd[0]),
344 .lcdcirq(lcdcirq),
345 .vblankirq(vblankirq),
346 .lcdclk(lcdclk),
347 .lcdhs(lcdhs),
348 .lcdvs(lcdvs),
349 .lcdr(lcdr),
350 .lcdg(lcdg),
351 .lcdb(lcdb));
352
353 Framebuffer fb(
354 .lcdclk(lcdclk),
355 .lcdhs(lcdhs),
356 .lcdvs(lcdvs),
357 .lcdr(lcdr),
358 .lcdg(lcdg),
359 .lcdb(lcdb),
360 .vgaclk(vgaclk),
361 .vgahs(hs),
362 .vgavs(vs),
363 .vgar(r),
364 .vgag(g),
365 .vgab(b));
366
367 wire [7:0] sleds;
368`ifdef isim
369 assign leds = sleds;
370`else
371 assign leds = sleds | ps2buttons;
372`endif
373 Switches sw(
374 .clk(clk),
375 .address(addr[0]),
376 .data(data[0]),
377 .wr(wr[0]),
378 .rd(rd[0]),
379 .ledout(sleds),
380 .switches(switches)
381 );
382
383`ifdef isim
384`else
385 PS2Button ps2(
386 .clk(clk),
387 .inclk(ps2c),
388 .indata(ps2d),
389 .buttons(ps2buttons)
390 );
391`endif
392
393 Buttons ass(
394 .core_clk(clk),
395 .addr(addr[0]),
396 .data(data[0]),
397 .wr(wr[0]),
398 .rd(rd[0]),
399 .int(btnirq),
400 `ifdef isim
401 .buttons(switches)
402 `else
403 .buttons(ps2buttons)
404 `endif
405 );
406
407 AddrMon amon(
408 .clk(clk),
409 .addr(addr[0]),
410 .digit(digits),
411 .out(seven),
412 .freeze(buttons[0]),
413 .periods(
414 (state == 2'b00) ? 4'b0010 :
415 (state == 2'b01) ? 4'b0001 :
416 (state == 2'b10) ? 4'b1000 :
417 4'b0100) );
418
419 UART nouart ( /* no u */
420 .clk(clk),
421 .addr(addr[0]),
422 .data(data[0]),
423 .wr(wr[0]),
424 .rd(rd[0]),
425 .serial(serio),
426 .serialrx(serin)
427 );
428
429 InternalRAM ram(
430 .clk(clk),
431 .address(addr[0]),
432 .data(data[0]),
433 .wr(wr[0]),
434 .rd(rd[0])
435 );
436
437 MiniRAM mram(
438 .clk(clk),
439 .address(addr[1]),
440 .data(data[1]),
441 .wr(wr[1]),
442 .rd(rd[1])
443 );
444
445 Timer tmr(
446 .clk(clk),
447 .addr(addr[0]),
448 .data(data[0]),
449 .wr(wr[0]),
450 .rd(rd[0]),
451 .irq(tmrirq)
452 );
453
454 Interrupt intr(
455 .clk(clk),
456 .addr(addr[0]),
457 .data(data[0]),
458 .wr(wr[0]),
459 .rd(rd[0]),
460 .vblank(vblankirq),
461 .lcdc(lcdcirq),
462 .tovf(tmrirq),
463 .serial(1'b0),
464 .buttons(btnirq),
465 .master(irq),
466 .ack(ack),
467 .jaddr(jaddr));
468
469 Soundcore sound(
470 .core_clk(clk),
471 .addr(addr[0]),
472 .data(data[0]),
473 .rd(rd[0]),
474 .wr(wr[0]),
475 .snd_data_l(soundl),
476 .snd_data_r(soundr));
477
478`ifdef isim
479`else
480 Ethernet eth(
481 .clk(clk),
482 .wr(wr[0]),
483 .rd(rd[0]),
484 .addr(addr[0]),
485 .data(data[0]),
486 .ethclk(ethclk),
487 .rxclk(xtalb),
488 .txp(txp),
489 .txm(txm),
490 .rxp(rxp),
491 .rxm(rxm));
492`endif
493endmodule
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