groovylight/verilog/hub75e.sv

module hub75e (
    input clk,
    input write_trig,
    output reg [2:0] panel_rgb0,
    output reg [2:0] panel_rgb1,
    output reg display_clk = 0,
    output reg out_enable = 1,
    output reg latch = 0,
    output reg done = 0,

    // bram interface (using clk)
    output reg [10:0] pixbuf_addr,
    input [8:0] pixbuf_data
);

  parameter integer ROW_DEPTH = 128, BIT_DEPTH = 8;

  reg [31:0] counter = 0;
  reg [ 3:0] bcm_shift = 7;  // which bit of the colors are we currently exposing.

  localparam integer StateInit = 0;
  localparam integer StateWriteRow = 1;
  localparam integer StateLatchout = 2;
  // the last data that we clock out for the row won't be exposed
  // in the next writerow state because we'll change addresses.
  localparam integer StateFinishExpose = 3;

  reg [7:0] state = StateInit;  // our state


  // initial begin
  //   state <= StateInit;
  //   counter <= 0;
  //   bcm_shift <= 7;
  // end

  // The FSM is a bit confusing since it's optimized for *speed*
  // We can basically display the previous line of data while we write the
  // next one. So instead of having WRITEROW -> LATCH -> EXPOSE
  // like most modules do, we can instead do (WRITEROW + EXPOSE_PREV) -> LATCH
  // There is an edge case for the first/last bits of the color depth.
  // When we start writing a line, we can't flash anything since there's no
  // previous. Likewise, when we end a line, we have to have an extra expose
  // period since there is no next writerow for this address. As a result,
  // we want to go MSB to LSB for our BCM so that the trailing expose time is
  // short!

  wire should_clock, should_expose;
  assign should_clock  = counter < ROW_DEPTH * 2;
  assign should_expose = (counter < (16 << bcm_shift + 1)) && (bcm_shift != 7);

  always_ff @(posedge clk) begin
    counter <= counter + 1;
    case (state)
      StateInit: begin
        bcm_shift <= 7;
        counter <= 0;
        done <= 0;
        pixbuf_addr <= 0;
        // wait for the signal to write out our lines.
        if (write_trig) begin
          state <= StateWriteRow;
        end
      end

      StateWriteRow: begin
        if (should_clock) begin
          // we have data to  clock
          display_clk <= counter[0];
          if (~counter[0]) begin
            // the data from the previous cycle is now ready.
            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
        if (should_expose) begin
          out_enable <= 0;
        end else begin
          out_enable <= 1;
        end
        // if we're done with our data clock out and also done with exposing
        // the previous line, go to the latchout stage.
        if (~should_clock && ~should_expose) begin
          counter <= 0;
          state   <= StateLatchout;
        end
      end

      StateLatchout: begin
        // raise latch high; compute next bcm.
        latch <= 1;
        out_enable <= 1;
        pixbuf_addr <= 0;
        counter <= counter + 1;
        if (counter > 3) begin
          if (bcm_shift == 0) begin
            // we've reached the lsb of this data, go to the next one!
            state <= StateFinishExpose;
            latch <= 0;
          end else begin
            bcm_shift <= bcm_shift - 1;
            state <= StateWriteRow;
            latch <= 0;
          end
        end
      end

      StateFinishExpose: begin
        assert (bcm_shift == 0);
        if (counter < (16 << bcm_shift)) begin
          out_enable <= 0;
        end else begin
          out_enable <= 1;
          state <= StateInit;
          done <= 1;
          // we are done!
        end
      end
      default: begin
          state <= StateInit;
      end
    endcase
  end

endmodule
initial verilog 2024-04-28 21:42:41 +00:00			`module hub75e (`
			`input clk,`
			`input write_trig,`
			`output reg [2:0] panel_rgb0,`
			`output reg [2:0] panel_rgb1,`
			`output reg display_clk = 0,`
			`output reg out_enable = 1,`
			`output reg latch = 0,`
bram stuff 2024-04-29 06:16:36 +00:00			`output reg done = 0,`

			`// bram interface (using clk)`
wip: attempt at integrating, fail 2024-04-30 05:29:41 +00:00			`output reg [10:0] pixbuf_addr,`
			`input [8:0] pixbuf_data`
initial verilog 2024-04-28 21:42:41 +00:00			`);`

			`parameter integer ROW_DEPTH = 128, BIT_DEPTH = 8;`

			`reg [31:0] counter = 0;`
			`reg [ 3:0] bcm_shift = 7; // which bit of the colors are we currently exposing.`

			`localparam integer StateInit = 0;`
			`localparam integer StateWriteRow = 1;`
			`localparam integer StateLatchout = 2;`
			`// the last data that we clock out for the row won't be exposed`
			`// in the next writerow state because we'll change addresses.`
			`localparam integer StateFinishExpose = 3;`

			`reg [7:0] state = StateInit; // our state`



			`// initial begin`
			`// state <= StateInit;`
			`// counter <= 0;`
			`// bcm_shift <= 7;`
			`// end`

			`// The FSM is a bit confusing since it's optimized for speed`
			`// We can basically display the previous line of data while we write the`
			`// next one. So instead of having WRITEROW -> LATCH -> EXPOSE`
			`// like most modules do, we can instead do (WRITEROW + EXPOSE_PREV) -> LATCH`
			`// There is an edge case for the first/last bits of the color depth.`
			`// When we start writing a line, we can't flash anything since there's no`
			`// previous. Likewise, when we end a line, we have to have an extra expose`
			`// period since there is no next writerow for this address. As a result,`
			`// we want to go MSB to LSB for our BCM so that the trailing expose time is`
			`// short!`

			`wire should_clock, should_expose;`
			`assign should_clock = counter < ROW_DEPTH * 2;`
			`assign should_expose = (counter < (16 << bcm_shift + 1)) && (bcm_shift != 7);`

			`always_ff @(posedge clk) begin`
			`counter <= counter + 1;`
			`case (state)`
			`StateInit: begin`
bram stuff 2024-04-29 06:16:36 +00:00			`bcm_shift <= 7;`
			`counter <= 0;`
			`done <= 0;`
			`pixbuf_addr <= 0;`
initial verilog 2024-04-28 21:42:41 +00:00			`// wait for the signal to write out our lines.`
			`if (write_trig) begin`
			`state <= StateWriteRow;`
			`end`
			`end`

			`StateWriteRow: begin`
			`if (should_clock) begin`
			`// we have data to clock`
			`display_clk <= counter[0];`
bram stuff 2024-04-29 06:16:36 +00:00			`if (~counter[0]) begin`
			`// the data from the previous cycle is now ready.`
			`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;`
initial verilog 2024-04-28 21:42:41 +00:00			`end`
			`end`
			`if (should_expose) begin`
			`out_enable <= 0;`
			`end else begin`
			`out_enable <= 1;`
			`end`
			`// if we're done with our data clock out and also done with exposing`
bram stuff 2024-04-29 06:16:36 +00:00			`// the previous line, go to the latchout stage.`
initial verilog 2024-04-28 21:42:41 +00:00			`if (~should_clock && ~should_expose) begin`
			`counter <= 0;`
			`state <= StateLatchout;`
			`end`
			`end`

			`StateLatchout: begin`
			`// raise latch high; compute next bcm.`
			`latch <= 1;`
			`out_enable <= 1;`
bram stuff 2024-04-29 06:16:36 +00:00			`pixbuf_addr <= 0;`
initial verilog 2024-04-28 21:42:41 +00:00			`counter <= counter + 1;`
			`if (counter > 3) begin`
			`if (bcm_shift == 0) begin`
bram stuff 2024-04-29 06:16:36 +00:00			`// we've reached the lsb of this data, go to the next one!`
initial verilog 2024-04-28 21:42:41 +00:00			`state <= StateFinishExpose;`
			`latch <= 0;`
			`end else begin`
			`bcm_shift <= bcm_shift - 1;`
			`state <= StateWriteRow;`
			`latch <= 0;`
			`end`
			`end`
			`end`

			`StateFinishExpose: begin`
			`assert (bcm_shift == 0);`
			`if (counter < (16 << bcm_shift)) begin`
			`out_enable <= 0;`
			`end else begin`
			`out_enable <= 1;`
			`state <= StateInit;`
			`done <= 1;`
			`// we are done!`
			`end`
			`end`
			`default: begin`
wip: attempt at integrating, fail 2024-04-30 05:29:41 +00:00			`state <= StateInit;`
initial verilog 2024-04-28 21:42:41 +00:00			`end`
			`endcase`
			`end`

			`endmodule`