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bram stuff

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saji 2024-04-29 01:16:36 -05:00
parent 00ebfa8009
commit 75ef4ad594
3 changed files with 92 additions and 21 deletions
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42
verilog/hub75e.sv
View file

@ -1,14 +1,17 @@
module hub75e ( module hub75e (
input clk, input clk,
input write_trig, input write_trig,
input [1:0][BIT_DEPTH - 1:0] rgb_row[ROW_DEPTH],
output reg [4:0] addr, output reg [4:0] addr,
output reg [2:0] panel_rgb0, output reg [2:0] panel_rgb0,
output reg [2:0] panel_rgb1, output reg [2:0] panel_rgb1,
output reg display_clk = 0, output reg display_clk = 0,
output reg out_enable = 1, output reg out_enable = 1,
output reg latch = 0, output reg latch = 0,
output reg done = 0 output reg done = 0,
// bram interface (using clk)
output reg [8:0] pixbuf_addr,
input [35:0] pixbuf_data
); );
parameter integer ROW_DEPTH = 128, BIT_DEPTH = 8; parameter integer ROW_DEPTH = 128, BIT_DEPTH = 8;
@ -27,8 +30,6 @@ module hub75e (
assign addr = 5'b10101; assign addr = 5'b10101;
assign panel_rgb0 = 3'b101;
assign panel_rgb1 = 3'b010;
// initial begin // initial begin
// state <= StateInit; // state <= StateInit;
@ -55,11 +56,12 @@ module hub75e (
counter <= counter + 1; counter <= counter + 1;
case (state) case (state)
StateInit: begin StateInit: begin
bcm_shift <= 7;
counter <= 0;
done <= 0;
pixbuf_addr <= 0;
// wait for the signal to write out our lines. // wait for the signal to write out our lines.
if (write_trig) begin if (write_trig) begin
bcm_shift <= 7;
counter <= 0;
done <= 0;
state <= StateWriteRow; state <= StateWriteRow;
end end
end end
@ -68,20 +70,31 @@ module hub75e (
if (should_clock) begin if (should_clock) begin
// we have data to clock // we have data to clock
display_clk <= counter[0]; display_clk <= counter[0];
if (counter[0]) begin if (~counter[0]) begin
// load the next pixel data. this is the falling edge since the // the data from the previous cycle is now ready.
// previous value is 1. panel_rgb0 <= {
(pixbuf_data[bcm_shift]),
(pixbuf_data[bcm_shift + 8]),
(pixbuf_data[bcm_shift + 16])
};
panel_rgb1 <= {
(pixbuf_data[bcm_shift]),
(pixbuf_data[bcm_shift + 8]),
(pixbuf_data[bcm_shift + 16])
};
// write it out!
end else begin
// update the bram address so it's ready at the next clock cycle.
pixbuf_addr <= pixbuf_addr + 1;
end end
end end
if (should_expose) begin if (should_expose) begin
// we are still in our expose state, and our bcm shift is not the
// first one, so we should expose.
out_enable <= 0; out_enable <= 0;
end else begin end else begin
out_enable <= 1; out_enable <= 1;
end end
// if we're done with our data clock out and also done with exposing // if we're done with our data clock out and also done with exposing
// the previous frame, go next. // the previous line, go to the latchout stage.
if (~should_clock && ~should_expose) begin if (~should_clock && ~should_expose) begin
counter <= 0; counter <= 0;
state <= StateLatchout; state <= StateLatchout;
@ -92,10 +105,11 @@ module hub75e (
// raise latch high; compute next bcm. // raise latch high; compute next bcm.
latch <= 1; latch <= 1;
out_enable <= 1; out_enable <= 1;
pixbuf_addr <= 0;
counter <= counter + 1; counter <= counter + 1;
if (counter > 3) begin if (counter > 3) begin
if (bcm_shift == 0) begin if (bcm_shift == 0) begin
// done with the line. do the last (short) expose // we've reached the lsb of this data, go to the next one!
state <= StateFinishExpose; state <= StateFinishExpose;
latch <= 0; latch <= 0;
end else begin end else begin

28
verilog/lineram.v Normal file
View file

@ -0,0 +1,28 @@
module lineram #(
parameter DATA_WIDTH = 36,
parameter ADDR_WIDTH = 9
) (
input [DATA_WIDTH - 1:0] din,
input [ADDR_WIDTH - 1:0] addr_w,
output reg [DATA_WIDTH - 1:0] dout,
input [ADDR_WIDTH - 1:0] addr_r,
input write_en,
input read_clk,
input write_clk
);
reg [DATA_WIDTH - 1] ram[2**ADDR_WIDTH];
initial begin
for(int i=0; i < 2**ADDR_WIDTH; i=i+1) begin
ram[i] = 0;
end
end
always @(posedge write_clk) begin
if (write_en) ram[addr_w] <= din;
end
always @(posedge read_clk) begin
dout <= ram[addr_r];
end
endmodule

43
verilog/tb/hub75e_tb.sv
View file

@ -4,8 +4,6 @@ module hub75e_tb;
reg clk; reg clk;
reg write_trig; reg write_trig;
reg [1:0][7:0] rgb_row[128];
wire [4:0] addr_out; wire [4:0] addr_out;
wire [2:0] rgb0; wire [2:0] rgb0;
wire [2:0] rgb1; wire [2:0] rgb1;
@ -15,27 +13,58 @@ module hub75e_tb;
wire done; wire done;
// block ram inputs
reg [35:0] bram_data_in;
reg [8:0] bram_addr_w;
reg bram_write_en;
wire [8:0] bram_addr_r;
wire [35:0] bram_data_out;
lineram bram (
.din(bram_data_in),
.addr_w(bram_addr_w),
.dout(bram_data_out),
.addr_r(bram_addr_r),
.write_en(bram_write_en),
.read_clk(clk),
.write_clk(clk)
);
hub75e dut ( hub75e dut (
.clk(clk), .clk(clk),
.write_trig(write_trig), .write_trig(write_trig),
.rgb_row(rgb_row),
.addr(addr_out), .addr(addr_out),
.panel_rgb0(rgb0), .panel_rgb0(rgb0),
.panel_rgb1(rgb1), .panel_rgb1(rgb1),
.display_clk(display_clk), .display_clk(display_clk),
.out_enable(out_enable), .out_enable(out_enable),
.latch(latch), .latch(latch),
.done(done) .done(done),
.pixbuf_addr(bram_addr_r),
.pixbuf_data(bram_data_out)
); );
always #5 clk = !clk; always #5 clk = !clk;
initial begin initial begin
$dumpfile("wave.vcd"); $dumpfile("wave.vcd");
$dumpvars(0, hub75e_tb); $dumpvars(0, hub75e_tb);
clk = 0; clk <= 0;
write_trig = 1; bram_addr_w <= 0;
bram_write_en <= 1;
repeat (1) @(posedge clk);
for (int i=0; i < 128; i=i+1) begin
bram_data_in <= $urandom % 'hFFFFFF;
bram_addr_w <= i;
repeat (1) @(posedge clk);
end
bram_write_en <= 1;
write_trig <= 1;
repeat (2) @(posedge clk); repeat (2) @(posedge clk);
write_trig = 0; write_trig <= 0;
@(done); @(done);
repeat (20) @(posedge clk); repeat (20) @(posedge clk);