input xsign, ysign,
output reg [12:0] out,
output reg sign,
- output reg [1:0] ovf);
+ output reg ovf);
always @(posedge clk)
begin
{ovf,out} <=
(((y[12] ? (x ) : 0) +
(y[11] ? (x >> 1) : 0) +
- (y[10] ? (x >> 2) : 0) +
- (y[9] ? (x >> 3) : 0)) +
- ((y[8] ? (x >> 4) : 0) +
- (y[7] ? (x >> 5) : 0) +
- (y[6] ? (x >> 6) : 0)))+
+ (y[10] ? (x >> 2) : 0)) +
+ (((y[9] ? (x >> 3) : 0) +
+ (y[8] ? (x >> 4) : 0))+
+ ((y[7] ? (x >> 5) : 0) +
+ (y[6] ? (x >> 6) : 0))))+
+
(((y[5] ? (x >> 7) : 0) +
- (y[4] ? (x >> 8) : 0) +
+ (y[4] ? (x >> 8) : 0)+
(y[3] ? (x >> 9) : 0)) +
- ((y[2] ? (x >> 10): 0) +
+ ((y[2] ? (x >> 10): 0) +
(y[1] ? (x >> 11): 0) +
(y[0] ? (x >> 12): 0)));
sign <= xsign ^ ysign;
input xsign, ysign,
output wire [12:0] out,
output wire sign,
- output wire [1:0] overflow);
+ output wire overflow);
NaiveMultiplier nm(clk, x, y, xsign, ysign, out, sign, overflow);
endmodule
+// Yuq.
module MandelUnit(
input clk,
input [12:0] x, y,
output reg [7:0] obail, ocuriter);
wire [14:0] r2, i2, ri, diff;
+ wire [15:0] twocdiff;
wire r2sign, i2sign, risign, dsign;
- wire [16:0] bigsum;
+ wire [15:0] bigsum;
wire bigsum_ovf, rin_ovf, iin_ovf, throwaway;
reg [12:0] xd, yd;
assign ri[0] = 0;
- Multiplier r2m(clk, r[12:0], r[12:0], rsign, rsign, r2[12:0], r2sign, r2[14:13]);
- Multiplier i2m(clk, i[12:0], i[12:0], isign, isign, i2[12:0], i2sign, i2[14:13]);
- Multiplier rim(clk, r[12:0], i[12:0], rsign, isign, ri[13:1], risign, {throwaway,ri[14]});
+ Multiplier r2m(clk, r[12:0], r[12:0], rsign, rsign, r2[12:0], r2sign, r2[13]);
+ Multiplier i2m(clk, i[12:0], i[12:0], isign, isign, i2[12:0], i2sign, i2[13]);
+ Multiplier rim(clk, r[12:0], i[12:0], rsign, isign, ri[13:1], risign, ri[14]);
assign bigsum = r2 + i2;
- assign bigsum_ovf = bigsum[16] | bigsum[15] | bigsum[14];
+ assign bigsum_ovf = bigsum[15] | bigsum[14];
assign rin_ovf = rd;
assign iin_ovf = id;
- assign diff = (r2 > i2) ? r2 - i2 : i2 - r2;
- assign dsign = (r2 > i2) ? 0 : 1;
+ assign twocdiff = r2 - i2;
+ assign diff = twocdiff[15] ? -twocdiff : twocdiff;
+ assign dsign = twocdiff[15];
always @ (posedge clk)
begin
input [2:0] scale,
output reg [2:0] red, green, output reg [1:0] blue);
-`define MAXOUTN 12
+`define MAXOUTN 11
wire [12:0] rx, ry;
wire [13:0] nx, ny;
assign rxsign = nx[13];
assign ry = (ny[13] ? -ny[12:0] : ny[12:0]) << scale;
assign rysign = ny[13];
-
wire [14:0] mr[`MAXOUTN:0], mi[`MAXOUTN:0];
wire mrs[`MAXOUTN:0], mis[`MAXOUTN:0];
wire [7:0] initci, initb;
wire initxs, initys, initrs, initis;
- reg [14:0] loopx, loopy, loopr, loopi;
- reg [7:0] loopci, loopb;
- reg loopxs, loopys, looprs, loopis;
-
- reg state = 0;
+ // Values after the number of iterations denoted by the subscript.
+ reg [14:0] stagex [2:1], stagey [2:1], stager [2:1], stagei [2:1];
+ reg [7:0] stageci [2:1], stageb [2:1];
+ reg stagexs [2:1], stageys [2:1], stagers [2:1], stageis [2:1];
- // On pixclk = 1,
- // A new value to be loaded comes in, and a value in need of loopback comes out.
- // On pixclk = 0,
- // A new value in need of loopback comes in, and a completed value comes out.
+ reg [2:0] state = 3'b001; // One-hot encoded state.
- assign initx = state ? rx : loopx;
- assign inity = state ? ry : loopy;
- assign initr = state ? rx : loopr;
- assign initi = state ? ry : loopi;
- assign initxs = state ? rxsign : loopxs;
- assign initys = state ? rysign : loopys;
- assign initrs = state ? rxsign : looprs;
- assign initis = state ? rysign : loopis;
- assign initb = state ? 8'b11111111 : loopb;
- assign initci = state ? 8'b00000000 : loopci;
+ assign initx = (state[0]) ? rx :
+ (state[1]) ? stagex[1] :
+ (state[2]) ? stagex[2] : 0;
+ assign inity = (state[0]) ? ry :
+ (state[1]) ? stagey[1] :
+ (state[2]) ? stagey[2] : 0;
+ assign initr = (state[0]) ? rx :
+ (state[1]) ? stager[1] :
+ (state[2]) ? stager[2] : 0;
+ assign initi = (state[0]) ? ry :
+ (state[1]) ? stagei[1] :
+ (state[2]) ? stagei[2] : 0;
+ assign initxs = (state[0]) ? rxsign :
+ (state[1]) ? stagexs[1] :
+ (state[2]) ? stagexs[2] : 0;
+ assign initys = (state[0]) ? rysign :
+ (state[1]) ? stageys[1] :
+ (state[2]) ? stageys[2] : 0;
+ assign initrs = (state[0]) ? rxsign :
+ (state[1]) ? stagers[1] :
+ (state[2]) ? stagers[2] : 0;
+ assign initis = (state[0]) ? rysign :
+ (state[1]) ? stageis[1] :
+ (state[2]) ? stageis[2] : 0;
+ assign initb = (state[0]) ? 8'b11111111 :
+ (state[1]) ? stageb[1] :
+ (state[2]) ? stageb[2] : 0;
+ assign initci = (state[0]) ? 8'b00000000 :
+ (state[1]) ? stageci[1] :
+ (state[2]) ? stageci[2] : 0;
reg [7:0] out;
- reg pixclksync;
+
+ // We detect when the state should be poked by a high negedge followed
+ // by a high posedge -- if that happens, then we're guaranteed that the
+ // state following the current state will be 3'b100.
+ reg lastneg;
always @(negedge mclk)
- pixclksync <= ~pixclk;
+ lastneg <= pixclk;
always @(posedge mclk)
begin
- if (!state) begin
- out <= ~mb[`MAXOUTN] + colorofs;
- end else begin
+ if (lastneg && pixclk) // If a pixclk has happened, the state should be reset.
+ state <= 3'b100;
+ else // Otherwise, just poke it forward.
+ case(state)
+ 3'b001: state <= 3'b010;
+ 3'b010: state <= 3'b100;
+ 3'b100: state <= 3'b001;
+ endcase
+
+ // Data output handling
+ if (state[0]) begin
{red, green, blue} <= {out[0],out[3],out[6],out[1],out[4],out[7],out[2],out[5]};
- loopx <= xprop[`MAXOUTN];
- loopy <= yprop[`MAXOUTN];
- loopr <= mr[`MAXOUTN];
- loopi <= mi[`MAXOUTN];
- loopxs <= xsprop[`MAXOUTN];
- loopys <= ysprop[`MAXOUTN];
- looprs <= mrs[`MAXOUTN];
- loopis <= mis[`MAXOUTN];
- loopb <= mb[`MAXOUTN];
- loopci <= curiter[`MAXOUTN];
end
- state <= ~pixclksync;
+ if (state[1]) begin
+ out <= ~mb[`MAXOUTN] + colorofs;
+ end
+
+ if (state[0]) begin // PnR0 in, PnR2 out
+ stagex[2] <= xprop[`MAXOUTN];
+ stagey[2] <= yprop[`MAXOUTN];
+ stager[2] <= mr[`MAXOUTN];
+ stagei[2] <= mi[`MAXOUTN];
+ stagexs[2] <= xsprop[`MAXOUTN];
+ stageys[2] <= ysprop[`MAXOUTN];
+ stagers[2] <= mrs[`MAXOUTN];
+ stageis[2] <= mis[`MAXOUTN];
+ stageb[2] <= mb[`MAXOUTN];
+ stageci[2] <= curiter[`MAXOUTN];
+ end
+
+ if (state[2]) begin // PnR2 in, PnR1 out
+ stagex[1] <= xprop[`MAXOUTN];
+ stagey[1] <= yprop[`MAXOUTN];
+ stager[1] <= mr[`MAXOUTN];
+ stagei[1] <= mi[`MAXOUTN];
+ stagexs[1] <= xsprop[`MAXOUTN];
+ stageys[1] <= ysprop[`MAXOUTN];
+ stagers[1] <= mrs[`MAXOUTN];
+ stageis[1] <= mis[`MAXOUTN];
+ stageb[1] <= mb[`MAXOUTN];
+ stageci[1] <= curiter[`MAXOUTN];
+ end
end
MandelUnit mu0(
MandelUnit mub(mclk,
xprop[10], yprop[10], xsprop[10], ysprop[10], mr[10], mi[10], mrs[10], mis[10], mb[10], curiter[10],
xprop[11], yprop[11], xsprop[11], ysprop[11], mr[11], mi[11], mrs[11], mis[11], mb[11], curiter[11]);
- MandelUnit muc(mclk,
- xprop[11], yprop[11], xsprop[11], ysprop[11], mr[11], mi[11], mrs[11], mis[11], mb[11], curiter[11],
- xprop[12], yprop[12], xsprop[12], ysprop[12], mr[12], mi[12], mrs[12], mis[12], mb[12], curiter[12]);
endmodule
input left, right, up, down, rst, cycle, logooff,
input [2:0] scale);
+
+ wire pixclk, mclk, gclk2, clk;
+ wire dcm1ok, dcm2ok;
+ assign dcmok = dcm1ok && dcm2ok;
+
+ IBUFG typeA(.O(clk), .I(gclk));
+
+ pixDCM dcm( // CLKIN is 50MHz xtal, CLKFX_OUT is 25MHz
+ .CLKIN_IN(clk),
+ .CLKFX_OUT(pixclk),
+ .LOCKED_OUT(dcm1ok)
+ );
+
+ mandelDCM dcm2(
+ .CLKIN_IN(clk),
+ .CLKFX_OUT(mclk),
+ .LOCKED_OUT(dcm2ok)
+ );
+
wire border;
- wire pixclk;
- wire [7:0] zero = 8'b0;
- wire clk;
wire [11:0] x, y;
reg [13:0] xofs = -`XRES/2, yofs = -`YRES/2;
reg [5:0] slowctr = 0;
wire [2:0] mandelr, mandelg, logor, logog;
wire [1:0] mandelb, logob;
- pixDCM dcm( // CLKIN is 50MHz xtal, CLKFX_OUT is 25MHz
- .CLKIN_IN(gclk),
- .CLKFX_OUT(pixclk),
- .CLKIN_IBUFG_OUT(clk),
- .LOCKED_OUT(dcmok)
- );
+
SyncGen sync(pixclk, vs, hs, x, y, realx, realy, border);
- Mandelbrot mandel(clk, pixclk, x, y, xofs, yofs, cycle ? colorcycle : 0, scale, mandelr, mandelg, mandelb);
+ Mandelbrot mandel(mclk, pixclk, x, y, xofs, yofs, cycle ? colorcycle : 0, scale, mandelr, mandelg, mandelb);
Logo logo(pixclk, realx, realy, logoenb, logor, logog, logob);
assign {red,green,blue} =