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cf1ae842 1/*
05c0805b
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2 * MandelFPGA
3 * by Joshua Wise and Chris Lu
4 *
5 * An implementation of a pipelined algorithm to calculate the Mandelbrot set
6 * in real time on an FPGA.
7 */
8
9`define XRES 640
10`define YRES 480
281eac32 11`define WHIRRRRR 27
05c0805b
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12
13module SyncGen(
14 input pixclk,
15 output reg vs, hs,
16 output reg [11:0] xout = `WHIRRRRR, yout = 0,
17 output wire [11:0] xoutreal, youtreal,
18 output reg border);
19
20 reg [11:0] x = 0, y = 0; // Used for generating border and timing.
21 assign xoutreal = x;
22 assign youtreal = y;
23
24 parameter XFPORCH = 16;
25 parameter XSYNC = 96;
26 parameter XBPORCH = 48;
27
28 parameter YFPORCH = 10;
29 parameter YSYNC = 2;
30 parameter YBPORCH = 29;
31
32 always @(posedge pixclk)
33 begin
34 if (x >= (`XRES + XFPORCH + XSYNC + XBPORCH))
35 begin
36 if (y >= (`YRES + YFPORCH + YSYNC + YBPORCH))
37 y <= 0;
38 else
39 y <= y + 1;
40 x <= 0;
41 end else
42 x <= x + 1;
43
44 if (xout >= (`XRES + XFPORCH + XSYNC + XBPORCH))
45 begin
46 if (yout >= (`YRES + YFPORCH + YSYNC + YBPORCH))
47 yout <= 0;
48 else
49 yout <= yout + 1;
50 xout <= 0;
51 end else
52 xout <= xout + 1;
53 hs <= (x >= (`XRES + XFPORCH)) && (x < (`XRES + XFPORCH + XSYNC));
54 vs <= (y >= (`YRES + YFPORCH)) && (y < (`YRES + YFPORCH + YSYNC));
55 border <= (x > `XRES) || (y > `YRES);
56 end
57endmodule
58
59// bits: 1.12
60
61module NaiveMultiplier(
62 input clk,
63 input [12:0] x, y,
64 input xsign, ysign,
65 output reg [12:0] out,
66 output reg sign,
fb8d158b 67 output reg ovf);
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68
69 always @(posedge clk)
70 begin
71 {ovf,out} <=
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72 (((y[12] ? (x ) : 0) +
73 (y[11] ? (x >> 1) : 0) +
74 (y[10] ? (x >> 2) : 0)) +
75 (((y[9] ? (x >> 3) : 0) +
76 (y[8] ? (x >> 4) : 0)) +
ec33b708 77 ((y[7] ? (x >> 5) : 0) +
fb8d158b 78 (y[6] ? (x >> 6) : 0))))+
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79 (((y[5] ? (x >> 7) : 0) +
80 (y[4] ? (x >> 8) : 0) +
81 (y[3] ? (x >> 9) : 0)) +
82 ((y[2] ? (x >> 10): 0) +
83 (y[1] ? (x >> 11): 0) +
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84 (y[0] ? (x >> 12): 0)));
85 sign <= xsign ^ ysign;
86 end
87
88endmodule
89
90module Multiplier(
91 input clk,
92e851e1 92 input [12:0] x, y,
05c0805b 93 input xsign, ysign,
92e851e1 94 output wire [12:0] out,
05c0805b 95 output wire sign,
fb8d158b 96 output wire overflow);
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97
98 NaiveMultiplier nm(clk, x, y, xsign, ysign, out, sign, overflow);
99
100endmodule
101
fb8d158b 102// Yuq.
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103module MandelUnit(
104 input clk,
105 input [12:0] x, y,
106 input xsign, ysign,
92e851e1 107 input [14:0] r, i,
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108 input rsign, isign,
109 input [7:0] ibail, icuriter,
110 output reg [12:0] xout, yout,
111 output reg xsout, ysout,
92e851e1 112 output reg [14:0] rout, iout,
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113 output reg rsout, isout,
114 output reg [7:0] obail, ocuriter);
115
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116 wire [13:0] r2, i2;
117 wire [14:0] ri, diff;
9032b2b5 118 wire [15:0] twocdiff;
05c0805b 119 wire r2sign, i2sign, risign, dsign;
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120 wire [13:0] bigsum;
121 wire bigsum_ovf;
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122
123 reg [12:0] xd, yd;
2afeab21 124 reg ineedbaild;
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125 reg xsd, ysd;
126 reg [7:0] ibaild, curiterd;
127
128 assign ri[0] = 0;
129
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130 Multiplier r2m(clk, r[12:0], r[12:0], rsign, rsign, r2[12:0], r2sign, r2[13]);
131 Multiplier i2m(clk, i[12:0], i[12:0], isign, isign, i2[12:0], i2sign, i2[13]);
132 Multiplier rim(clk, r[12:0], i[12:0], rsign, isign, ri[13:1], risign, ri[14]);
05c0805b 133
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134 //assign bigsum = r2[12:0] + i2[12:0];
135 //wire shnasto = bigsum[13];
136 wire shnasto = // o shi
137 ((r[12] & i[12]) |
138 ((r[12] ^ i[12]) &
139 ((r[11] & i[11]) |
140 ((r[11] ^ i[11]) &
141 ((r[10] & i[10]) |
142 ((r[10] ^ i[10]) &
143 ((r[ 9] & i[ 9]) |
144 ((r[ 9] ^ i[ 9]) &
145 ((r[ 8] & i[ 8]) |
146 ((r[ 8] ^ i[ 8]) &
147 ((r[ 7] & i[ 7]) |
148 ((r[ 7] ^ i[ 7]) &
149 ((r[ 6] & i[ 6]) |
150 ((r[ 6] ^ i[ 6]) &
151 ((r[ 5] & i[ 5]) |
152 ((r[ 5] ^ i[ 5]) &
153 ((r[ 4] & i[ 4]) |
154 ((r[ 4] ^ i[ 4]) &
155 ((r[ 3] & i[ 3]) |
156 ((r[ 3] ^ i[ 3]) &
157 ((r[ 2] & i[ 2]) |
158 ((r[ 2] ^ i[ 2]) &
159 ((r[ 1] & i[ 1]) |
160 ((r[ 1] ^ i[ 1]) &
161 (r[ 0] & i[ 0])
162 ))))))))))))))))))))))));
163 assign bigsum_ovf = shnasto | r2[13] | i2[13];
2afeab21 164
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165 assign twocdiff = r2 - i2;
166 assign diff = twocdiff[15] ? -twocdiff : twocdiff;
167 assign dsign = twocdiff[15];
2afeab21
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168
169 wire [15:0] twocrout = xd - diff;
170 wire [15:0] twociout = yd - ri;
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171
172 always @ (posedge clk)
173 begin
174 xd <= x;
175 yd <= y;
176 xsd <= xsign;
177 ysd <= ysign;
178 xout <= xd;
179 yout <= yd;
180 xsout <= xsd;
181 ysout <= ysd;
182 ibaild <= ibail;
183 curiterd <= icuriter;
2afeab21 184 ineedbaild <= r[13] | r[14] | i[13] | i[14];
05c0805b 185
2afeab21 186 // r^2 - i^2 + x
05c0805b 187 if (xsd ^ dsign) begin
2afeab21
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188 if (twocrout[15]) begin // diff > xd
189 rout <= -twocrout;
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190 rsout <= dsign;
191 end else begin
2afeab21 192 rout <= twocrout;
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193 rsout <= xsd;
194 end
195 end else begin
196 rout <= diff + xd;
2afeab21 197 rsout <= xsd; // xsd == dsign
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198 end
199
2afeab21 200 // 2 * r * i + y
05c0805b 201 if (ysd ^ risign) begin
2afeab21
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202 if (twociout[15]) begin // ri > yd
203 iout <= -twociout;
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204 isout <= risign;
205 end else begin
2afeab21 206 iout <= twociout;
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207 isout <= ysd;
208 end
209 end else begin
210 iout <= ri + yd;
211 isout <= ysd;
212 end
213
214 // If we haven't bailed out, and we meet any of the bailout conditions,
215 // bail out now. Otherwise, leave the bailout at whatever it was before.
2afeab21 216 if ((ibaild == 255) && (bigsum_ovf | ineedbaild))
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217 obail <= curiterd;
218 else
219 obail <= ibaild;
220 ocuriter <= curiterd + 8'b1;
221 end
222
223endmodule
224
225module Mandelbrot(
226 input mclk,
227 input pixclk,
228 input [11:0] x, y,
92e851e1 229 input [13:0] xofs, yofs,
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230 input [7:0] colorofs,
231 input [2:0] scale,
232 output reg [2:0] red, green, output reg [1:0] blue);
281eac32 233
534b3903 234`define MAXOUTN 11
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235
236 wire [12:0] rx, ry;
237 wire [13:0] nx, ny;
238 wire rxsign, rysign;
239
240 assign nx = x + xofs;
241 assign ny = y + yofs;
242 assign rx = (nx[13] ? -nx[12:0] : nx[12:0]) << scale;
243 assign rxsign = nx[13];
244 assign ry = (ny[13] ? -ny[12:0] : ny[12:0]) << scale;
245 assign rysign = ny[13];
05c0805b 246
281eac32
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247 wire [14:0] mr[`MAXOUTN:0], mi[`MAXOUTN:0];
248 wire mrs[`MAXOUTN:0], mis[`MAXOUTN:0];
249 wire [7:0] mb[`MAXOUTN:0];
250 wire [12:0] xprop[`MAXOUTN:0], yprop[`MAXOUTN:0];
251 wire xsprop[`MAXOUTN:0], ysprop[`MAXOUTN:0];
252 wire [7:0] curiter[`MAXOUTN:0];
05c0805b 253
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254 reg [14:0] initx, inity, initr, initi;
255 reg [7:0] initci, initb;
256 reg initxs, initys, initrs, initis;
05c0805b 257
534b3903
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258 // Values after the number of iterations denoted by the subscript.
259 reg [14:0] stagex [2:1], stagey [2:1], stager [2:1], stagei [2:1];
260 reg [7:0] stageci [2:1], stageb [2:1];
261 reg stagexs [2:1], stageys [2:1], stagers [2:1], stageis [2:1];
05c0805b 262
534b3903 263 reg [2:0] state = 3'b001; // One-hot encoded state.
05c0805b 264
79af494a
JW
265 // States are advanced one from what they should be, so that they'll
266 // get there on the _next_ mclk.
267 always @(posedge mclk)
268 begin
269 initx <= (state[2]) ? rx :
270 (state[0]) ? stagex[1] :
271 (state[1]) ? stagex[2] : 0;
272 inity <= (state[2]) ? ry :
273 (state[0]) ? stagey[1] :
274 (state[1]) ? stagey[2] : 0;
275 initr <= (state[2]) ? rx :
276 (state[0]) ? stager[1] :
277 (state[1]) ? stager[2] : 0;
278 initi <= (state[2]) ? ry :
279 (state[0]) ? stagei[1] :
280 (state[1]) ? stagei[2] : 0;
281 initxs <= (state[2]) ? rxsign :
282 (state[0]) ? stagexs[1] :
283 (state[1]) ? stagexs[2] : 0;
284 initys <= (state[2]) ? rysign :
285 (state[0]) ? stageys[1] :
286 (state[1]) ? stageys[2] : 0;
287 initrs <= (state[2]) ? rxsign :
288 (state[0]) ? stagers[1] :
289 (state[1]) ? stagers[2] : 0;
290 initis <= (state[2]) ? rysign :
291 (state[0]) ? stageis[1] :
292 (state[1]) ? stageis[2] : 0;
293 initb <= (state[2]) ? 8'b11111111 :
294 (state[0]) ? stageb[1] :
295 (state[1]) ? stageb[2] : 0;
296 initci <= (state[2]) ? 8'b00000000 :
297 (state[0]) ? stageci[1] :
298 (state[1]) ? stageci[2] : 0;
299 end
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300
301 reg [7:0] out;
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302
303 // We detect when the state should be poked by a high negedge followed
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304 // by a high posedge -- if that happens, then we're guaranteed that the
305 // state following the current state will be 3'b100.
251788d8 306 reg lastneg;
265061f2 307 always @(negedge mclk)
251788d8 308 lastneg <= pixclk;
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309
310 always @(posedge mclk)
311 begin
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312 if (lastneg && pixclk) // If a pixclk has happened, the state should be reset.
313 state <= 3'b100;
314 else // Otherwise, just poke it forward.
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315 case(state)
316 3'b001: state <= 3'b010;
317 3'b010: state <= 3'b100;
318 3'b100: state <= 3'b001;
319 endcase
251788d8 320
534b3903
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321 // Data output handling
322 if (state[0]) begin
05c0805b 323 {red, green, blue} <= {out[0],out[3],out[6],out[1],out[4],out[7],out[2],out[5]};
05c0805b 324 end
3068fa61 325 if (state[1]) begin
534b3903
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326 out <= ~mb[`MAXOUTN] + colorofs;
327 end
328
3068fa61 329 if (state[0]) begin // PnR0 in, PnR2 out
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330 stagex[2] <= xprop[`MAXOUTN];
331 stagey[2] <= yprop[`MAXOUTN];
332 stager[2] <= mr[`MAXOUTN];
333 stagei[2] <= mi[`MAXOUTN];
334 stagexs[2] <= xsprop[`MAXOUTN];
335 stageys[2] <= ysprop[`MAXOUTN];
336 stagers[2] <= mrs[`MAXOUTN];
337 stageis[2] <= mis[`MAXOUTN];
338 stageb[2] <= mb[`MAXOUTN];
339 stageci[2] <= curiter[`MAXOUTN];
340 end
341
3068fa61 342 if (state[2]) begin // PnR2 in, PnR1 out
534b3903
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343 stagex[1] <= xprop[`MAXOUTN];
344 stagey[1] <= yprop[`MAXOUTN];
345 stager[1] <= mr[`MAXOUTN];
346 stagei[1] <= mi[`MAXOUTN];
347 stagexs[1] <= xsprop[`MAXOUTN];
348 stageys[1] <= ysprop[`MAXOUTN];
349 stagers[1] <= mrs[`MAXOUTN];
350 stageis[1] <= mis[`MAXOUTN];
351 stageb[1] <= mb[`MAXOUTN];
352 stageci[1] <= curiter[`MAXOUTN];
353 end
05c0805b
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354 end
355
356 MandelUnit mu0(
357 mclk,
358 initx, inity, initxs, initys,
359 initr, initi, initrs, initis,
360 initb, initci,
361 xprop[0], yprop[0], xsprop[0], ysprop[0],
362 mr[0], mi[0], mrs[0], mis[0],
363 mb[0], curiter[0]);
e03ccef9
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364
365`define MAKE_UNIT(name, num) \
366 MandelUnit name(mclk, \
367 xprop[(num)], yprop[(num)], xsprop[(num)], ysprop[(num)], mr[(num)], mi[(num)], mrs[(num)], mis[(num)], mb[(num)], curiter[(num)], \
368 xprop[(num)+1], yprop[(num)+1], xsprop[(num)+1], ysprop[(num)+1], mr[(num)+1], mi[(num)+1], mrs[(num)+1], mis[(num)+1], mb[(num)+1], curiter[(num)+1])
05c0805b 369
e03ccef9
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370 `MAKE_UNIT(mu1, 0);
371 `MAKE_UNIT(mu2, 1);
372 `MAKE_UNIT(mu3, 2);
373 `MAKE_UNIT(mu4, 3);
374 `MAKE_UNIT(mu5, 4);
375 `MAKE_UNIT(mu6, 5);
376 `MAKE_UNIT(mu7, 6);
377 `MAKE_UNIT(mu8, 7);
378 `MAKE_UNIT(mu9, 8);
379 `MAKE_UNIT(mua, 9);
380 `MAKE_UNIT(mub, 10);
05c0805b
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381endmodule
382
383module Logo(
384 input pixclk,
385 input [11:0] x, y,
386 output wire enb,
387 output wire [2:0] red, green, output wire [1:0] blue);
388
389 reg [1:0] logo[8191:0];
390 initial $readmemb("logo.readmemb", logo);
391
392 assign enb = (x < 96) && (y < 64);
393 wire [12:0] addr = {y[5:0], x[6:0]};
394 wire [1:0] data = logo[addr];
395 assign {red, green, blue} =
396 (data == 2'b00) ? 8'b00000000 :
397 ((data == 2'b01) ? 8'b00011100 :
398 ((data == 2'b10) ? 8'b11100000 :
399 8'b11111111));
400endmodule
401
402module MandelTop(
403 input gclk, output wire dcmok,
404 output wire vs, hs,
405 output wire [2:0] red, green, output [1:0] blue,
406 input left, right, up, down, rst, cycle, logooff,
407 input [2:0] scale);
408
11cc2d9b 409 wire pixclk, mclk, clk;
534b3903 410 wire dcm1ok, dcm2ok;
c3ed4329 411 assign dcmok = dcm1ok && dcm2ok;
265061f2 412
e03ccef9 413 IBUFG iclkbuf(.O(clk), .I(gclk));
534b3903 414
c3ed4329
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415 pixDCM dcm( // CLKIN is 50MHz xtal, CLKFX_OUT is 25MHz
416 .CLKIN_IN(clk),
417 .CLKFX_OUT(pixclk),
418 .LOCKED_OUT(dcm1ok)
419 );
534b3903 420
c3ed4329
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421 mandelDCM dcm2(
422 .CLKIN_IN(clk),
423 .CLKFX_OUT(mclk),
424 .LOCKED_OUT(dcm2ok)
425 );
534b3903 426
05c0805b 427 wire border;
05c0805b 428 wire [11:0] x, y;
92e851e1 429 reg [13:0] xofs = -`XRES/2, yofs = -`YRES/2;
05c0805b
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430 reg [5:0] slowctr = 0;
431 reg [7:0] colorcycle = 0;
432 wire [11:0] realx, realy;
433
434 wire logoenb;
435 wire [2:0] mandelr, mandelg, logor, logog;
436 wire [1:0] mandelb, logob;
437
05c0805b 438 SyncGen sync(pixclk, vs, hs, x, y, realx, realy, border);
534b3903 439 Mandelbrot mandel(mclk, pixclk, x, y, xofs, yofs, cycle ? colorcycle : 0, scale, mandelr, mandelg, mandelb);
05c0805b
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440 Logo logo(pixclk, realx, realy, logoenb, logor, logog, logob);
441
442 assign {red,green,blue} =
443 border ? 8'b00000000 :
444 (!logooff && logoenb) ? {logor, logog, logob} : {mandelr, mandelg, mandelb};
445
446 always @(posedge vs)
447 begin
448 if (rst)
449 begin
450 xofs <= -`XRES/2;
451 yofs <= -`YRES/2;
452 colorcycle <= 0;
453 end else begin
454 if (up) yofs <= yofs + 1;
455 else if (down) yofs <= yofs - 1;
456
457 if (left) xofs <= xofs + 1;
458 else if (right) xofs <= xofs - 1;
459
460 if (slowctr == 0)
461 colorcycle <= colorcycle + 1;
462 end
463
464 if (slowctr == 12)
465 slowctr <= 0;
466 else
467 slowctr <= slowctr + 1;
468 end
469endmodule
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