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[/] [forwardcom/] [trunk/] [lcd.sv] - Rev 6
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//////////////////////////////////////////////////////////////////////////////////
// Engineer: Agner Fog
//
// Create Date: 2020-06-22
// Last modified: 2020-06-29
// Module Name: decoder
// Project Name: ForwardCom soft core
// Target Devices: Artix 7
// Tool Versions: Vivado v. 2020.1
// License: CERN-OHL-W v. 2 or later
// Description: Driver for LCD displays
// Two LCD displays with each 4 lines x 20 characters
//////////////////////////////////////////////////////////////////////////////////
`include "defines.vh"
module lcd
#(parameter numrows = 8, // number of lines of combined displays (2 - 8)
parameter numcolumns = 20, // number of characters per line
parameter rows_per_display = 4) // number of rows per display unit
(input clock, // system clock 100 MHz
input reset, // reset and clear
input [4:0] x, // column number (0 = left)
input [2:0] y, // row number (0 = top)
input [7:0] text[0:numcolumns-1], // text for one line
input [4:0] text_length, // length of text
input start, // start writing
input eol, // pad with spaces until end of line
output reg lcd_rs, // LCD RS pin
output reg [1:0] lcd_e, // enable pins for two LCD displays
output reg [3:0] lcd_data, // LCD data, 4 bit bus
output reg ready // finished writing. ready for next line
);
localparam count_bits = 14; // number of bits in clock divider counter
localparam count_max = (2**count_bits)-1;// maximum count
logic [7:0] rowaddress; // command for setting row address
reg [count_bits-1:0] counter = 0; // clock divider
reg [7:0] delay; // delay counter
reg [3:0] state = 0; // state machine for initialization
// 0 - 9: initialization sequence
// 10 - 11: set x,y position
// 12 - 13: write characters
// 15: finished
reg [7:0] text_buffer [0:numcolumns-1]; // copy of input text
reg [4:0] column; // text column
reg [2:0] row; // text row
reg [4:0] text_count; // count down characters in text
reg eol_save; // copy of eol
/* initialization sequence:
The display can receive data in 4-bit or 8-bit mode. We are using 4-bit mode,
sending 4 bits at a time, with only the upper four bits connected.
First, we send 8'H3x three times to get into 8-bit mode. Then 8'H2x to get
into 4-bit mode. The remaining numbers are 8-bit pairs:
8'H28: multi-line mode (the first needs a long delay)
8'H01: reset (needs long delay)
8'H0C: display on, no cursor, no blink
//8'H06 forward direction
*/
reg [3:0] initialization_sequence [10] = {3, 3, 3, 2, 2, 8, 0, 1, 0, 12 };
always_comb begin
// command to set row address
if (rows_per_display == 4) begin
case (row[1:0]) // 4 lines per display
0: rowaddress = 8'H80 + column;
1: rowaddress = 8'HC0 + column;
2: rowaddress = 8'H80 + numcolumns + column;
3: rowaddress = 8'HC0 + numcolumns + column;
endcase
end else begin
case (row[0]) // 2 lines per display
0: rowaddress = 8'H80 + column;
1: rowaddress = 8'HC0 + column;
endcase
end
end
always_ff @(posedge clock) begin
lcd_e <= 0;
if (reset) begin
// reset
counter <= 0;
delay <= 8'H80;
state <= 0;
end else if (start && state == 15) begin
// write command received
text_buffer <= text;
column <= x;
row <= y;
text_count <= text_length;
eol_save <= eol;
counter <= 0;
state <= 10;
end else begin
if (state < 10) begin
// initialization sequence
lcd_rs <= 0;
if (delay > 0) begin
if (counter == count_max) delay <= delay - 1;
end else begin
lcd_data <= initialization_sequence[state];
lcd_e[0] <= counter[count_bits-1:count_bits-2] == 2'b01; // generate pulse for display unit 0
lcd_e[1] <= counter[count_bits-1:count_bits-2] == 2'b01; // generate pulse for display unit 1
if (counter == count_max) begin
if (state == 9) state <= 15; // finished
else state <= state + 1; // next state
delay <= 8'H10;
end
end
end else if (state < 12) begin
// set (x,y) position
lcd_rs <= 0;
if (delay > 0) begin
if (counter == count_max) delay <= delay - 1;
end else begin
lcd_data <= ~state[0] ? rowaddress[7:4] : rowaddress[3:0];
if (row < rows_per_display)
lcd_e[0] <= counter[count_bits-1:count_bits-2] == 2'b01; // generate pulse
else lcd_e[1] <= counter[count_bits-1:count_bits-2] == 2'b01; // generate pulse
if (counter == count_max) begin
state <= state + 1;
delay <= 8'H10;
end
end
end else if (state < 15) begin
// write characters
lcd_rs <= 1;
if (delay > 0) begin
if (counter == count_max) delay <= delay - 1;
end else begin
if (text_count > 0) begin
// write character
lcd_data <= ~state[0] ? text_buffer[0][7:4] : text_buffer[0][3:0];
if (row < rows_per_display)
lcd_e[0] <= counter[count_bits-1:count_bits-2] == 2'b01; // generate pulse
else lcd_e[1] <= counter[count_bits-1:count_bits-2] == 2'b01; // generate pulse
end else if (eol_save) begin
lcd_data <= ~state[0] ? 2 : 0; // write space
if (row < rows_per_display)
lcd_e[0] <= counter[count_bits-1:count_bits-2] == 2'b01; // generate pulse
else lcd_e[1] <= counter[count_bits-1:count_bits-2] == 2'b01; // generate pulse
end
if (counter == count_max) begin
if (state[0]) begin
column <= column + 1; // count up column index
if (text_count != 0) text_count <= text_count - 1; // count down number of characters
for (int i = 0; i < numcolumns-1; i++) begin
text_buffer[i] <= text_buffer[i+1]; // shift down to get next character
end
end
if (state[0] && (column == numcolumns-1 || (text_count == 0 && !eol_save))) begin
state <= 15; // finished
end else begin
state[0] <= ~state[0];
end
// delay <= 8'H01;
end
end
end else begin
// state = 15. finished
lcd_e <= 0;
end
end
if (state == 15) ready <= 1;
else ready <= 0;
end
endmodule
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