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uart_tx.sv
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uart_tx.sv
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`timescale 1ns/100ps
// ============================================================================= //
// Designer: Jose Iuri B. de Brito - [email protected] // //
// //
// Design Name: UART Transmitter //
// Module Name: uart_tx //
// //
// ============================================================================= //
// This file contains the UART Transmitter. This transmitter is able
// to transmit 8 bits of serial data, one start bit, one stop bit,
// and no parity bit. When transmit is complete o_Tx_done will be
// driven high for one clock cycle.
//
// Set Parameter CLKS_PER_BIT as follows:
// CLKS_PER_BIT = (Frequency of i_Clock)/(Frequency of UART)
// Example: 25 MHz Clock, 115200 baud UART
// (25000000)/(115200) = 217
module uart_tx
#(parameter CLKS_PER_BIT = 217)
(
input logic i_Clock,
input logic rst,
input logic i_RTS,
input logic empty,
input logic rd_valid,
input logic [7:0] i_TX_Byte,
output logic o_TX_Active,
output logic o_TX_Serial,
output logic o_TX_Done
);
parameter IDLE = 3'b000;
parameter TX_START_BIT = 3'b001;
parameter TX_DATA_BITS = 3'b010;
parameter TX_STOP_BIT = 3'b011;
parameter CLEANUP = 3'b100;
logic [2:0] r_SM_Main;
logic [7:0] r_Clock_Count;
logic [2:0] r_Bit_Index;
logic [7:0] r_TX_Data;
logic r_TX_Done;
logic r_TX_Active;
always_ff @(posedge i_Clock or negedge rst)
begin
if (!rst)
begin
r_SM_Main <= 0;
r_Clock_Count <= 0;
r_Bit_Index <= 0;
r_TX_Data <= 0;
r_TX_Done <= 0;
r_TX_Active <= 0;
end
else
begin
case (r_SM_Main)
IDLE :
begin
o_TX_Serial <= 1'b1; // Drive Line High for Idle
r_TX_Done <= 1'b0;
r_Clock_Count <= 0;
r_Bit_Index <= 0;
if(!empty)
begin
if (i_RTS == 1'b1 && rd_valid)
begin
r_TX_Active <= 1'b1;
r_TX_Data <= i_TX_Byte;
r_SM_Main <= TX_START_BIT;
end
else
r_SM_Main <= IDLE;
end
else
begin
r_SM_Main <= IDLE;
end
end // case: IDLE
// Send out Start Bit. Start bit = 0
TX_START_BIT :
begin
o_TX_Serial <= 1'b0;
// Wait CLKS_PER_BIT-1 clock cycles for start bit to finish
if (r_Clock_Count < CLKS_PER_BIT-1)
begin
r_Clock_Count <= r_Clock_Count + 1;
r_SM_Main <= TX_START_BIT;
end
else
begin
r_Clock_Count <= 0;
r_SM_Main <= TX_DATA_BITS;
end
end // case: TX_START_BIT
// Wait CLKS_PER_BIT-1 clock cycles for data bits to finish
TX_DATA_BITS :
begin
o_TX_Serial <= r_TX_Data[r_Bit_Index];
if (r_Clock_Count < CLKS_PER_BIT-1)
begin
r_Clock_Count <= r_Clock_Count + 1;
r_SM_Main <= TX_DATA_BITS;
end
else
begin
r_Clock_Count <= 0;
// Check if we have sent out all bits
if (r_Bit_Index < 7)
begin
r_Bit_Index <= r_Bit_Index + 1;
r_SM_Main <= TX_DATA_BITS;
end
else
begin
r_Bit_Index <= 0;
r_SM_Main <= TX_STOP_BIT;
end
end
end // case: TX_DATA_BITS
// Send out Stop bit. Stop bit = 1
TX_STOP_BIT :
begin
o_TX_Serial <= 1'b1;
// Wait CLKS_PER_BIT-1 clock cycles for Stop bit to finish
if (r_Clock_Count < CLKS_PER_BIT-1)
begin
r_Clock_Count <= r_Clock_Count + 1;
r_SM_Main <= TX_STOP_BIT;
end
else
begin
r_TX_Done <= 1'b1;
r_Clock_Count <= 0;
r_SM_Main <= CLEANUP;
r_TX_Active <= 1'b0;
end
end // case: TX_STOP_BIT
// Stay here 1 clock
CLEANUP :
begin
r_TX_Done <= 1'b1;
r_SM_Main <= IDLE;
end
default :
r_SM_Main <= IDLE;
endcase
end
end
assign o_TX_Active = r_TX_Active;
assign o_TX_Done = r_TX_Done;
endmodule